PACKAGING OBJECT SUPPLYING APPARATUS, BOX BODY SUPPLYING APPARATUS, BOXING APPARATUS, PACKAGING SYSTEM AND PACKAGING METHOD
A packaging object supplying apparatus for supplying a packaging object to a packaging unit for packaging the packaging object into a predetermined fashion and specifically, a packaging object supplying apparatus comprising a packaging object combining portion for forming a combination of the packaging objects by combining two or more kinds of the packaging objects by a predetermined quantity in a predetermined array and a packaging object introducing portion for introducing the packaging objects combined by the packaging object combining portion to the packaging unit, a boxing apparatus comprising foldable box body supplying means, opening forming means, box body holding means, packaging object loading means, and lid forming means, a box body supplying apparatus for supplying a box body to the boxing apparatus.
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This is a divisional of application Ser. No. 10/434,467 filed May 9, 2003. The entire disclosures of prior application Ser. No. 10/434,467, claiming the benefit of JP 2002-134360, filed May 9, 2002, JP 2002-198947, filed Jul. 8, 2002, JP 2002-352066, filed Dec. 4, 2002, JP 2003-58188, filed Mar. 5, 2003, JP 2003-88083, filed Mar. 27, 2003 and JP 2003-126240, filed May 1, 2003 are all hereby incorporated by reference.
BACKGROUND OF THE INVENTION1. Field of the Invention
The present invention relates to a packaging object supplying apparatus, box body supplying apparatus, boxing apparatus, packaging system and packaging method and particularly to a packaging object supplying apparatus for supplying two or more kinds of packaging objects to the packaging unit in a predetermined array, a box body supplying apparatus capable of treating boxes of various sizes and shapes with single equipment, a boxing apparatus having the box body supplying apparatus and a packaging system capable of automatically packing small boxes of various shapes and sizes into corrugated board boxes according to a predetermined pattern.
2. Description of the Related Art
Usually, a film cartridge containing a photographic roll film is incorporated in a plastic film case and the film case is sold in a form of a carton which is a sack carton made of coated board.
Although conventionally, a carton generally adopts a small box type in which one film case is accommodated in each small box, recently, production number of a package so-called multi-small box type package in which two or more film cases are accommodated therein have increased.
A small box with a single film-type package is a standard packaging style for a film cartridge and its production amount is large with a small deflection in its quantity. Thus, a small box with a single film-type package can be automatically manufactured.
On the other hand, as for a multi-small box type-package, although production amount for one packaging style is not so large, there is a huge deflection in production quantity between different packaging styles. Further, this type has various packaging styles depending on the quantity of the film cases accommodated therein, presence/absence of a header which is a tab-like member and position thereof.
Therefore, it is difficult to manufacture a multi-small box type-package automatically and thus, packages of this type often are manufactured by hand or a semi-automatic packaging machine. Therefore, there is such a problem that its production efficiency is not raised.
Although conventionally, a packaging unit capable of coping with various styles of the multi-small boxes has been demanded, there are following problems in realizing such kind of packaging unit.
(1) Sack cartons used for the conventional multi-small box, that is, small boxes made of coated board are separated into two types; a type in which a film case is loaded from opening portions on both ends, and a type in which a film case is loaded from an opening portion on the side face thereof. A cartoner, which is a packaging unit for packaging the film case in the sack carton, cannot cope with two kinds of the sack cartons easily.
(2) In a conventional multi-small box, bar code sizes and printing positions are not made uniform.
(3) Even among multi-small boxes in which the same number of film cases are loaded, there is a difference in header positions and sizes.
(4) Multi-small boxes are often gathered together in a specified number and shrink-packaged. Upon shrink packaging, the multi-small box needs to be assembled in a different pattern in accordance with a presence/absence of its mount paper, header position, size, number of film cases loaded therein and the like.
(5) When the multi-small boxes are packaged in a corrugated board box, they need to be packaged in a different pattern in accordance with a packaging style of the multi-small boxes.
Among the above-described problems, it is considered the problem (1) and the problem (2) can be solved by making uniform the direction of loading the film cases in the sack carton and unifying the size and printing position of the bar code to be printed on the multi-small box.
SUMMARY OF THE INVENTIONAn object of the present invention is to provide a packaging system capable of solving the problems (3) to (5) and a corrugated board box for use in the packaging system.
Another object of the invention is to provide a packaging system and a packaging method by which packed products can be manufactured in a short period, which are efficient in there is no need of maintaining a large stock in manufacturing process, and which facilitates tracking if a defect is found in any package.
Still another object of the invention is to provide a packaging object supplying apparatus available for establishing a packaging system corresponding to a packaging configuration in which two or more kinds of plastic case packed products are loaded into a carton and a packaging system having the packaging object supplying apparatus and capable of corresponding to the packaging configuration.
To achieve the above-described objects, according to a first aspect, there is provided a packaging object supplying apparatus for supplying packaging objects to a packaging unit for packaging in a predetermined fashion, comprising: a packaging object combining portion for forming a combination of the packaging objects by combining two or more kinds of the packaging objects by a predetermined quantity thereof in a predetermined arrangement; and a packaging object introducing portion for introducing the packaging objects combined by the packaging object combining portion to the packaging unit.
An example in which three kinds of packaging objects, A, B, and C are packaged in an array of ABC by the packaging unit will be described below.
Each of the packaging objects A, B and C is introduced into the packaging object arraying portion.
The packaging object arraying portion arrays the introduced packaging objects A, B and C in the array of ABC.
The packaging object introducing portion introduces the packaging objects A, B and C arrayed in the order of ABC to the packaging unit while maintaining the array of ABC.
Because the packaging unit packages the packaging objects A, B and C arranged in the array of ABC, the packaging objects A, B and C are packaged in an order of ABC.
It is permissible to introduce the packaging object into a small chamber in the packaging object combining portion, combine them into a predetermined array in the small chamber and introduce them into the packaging object introduction portion or it is permissible to form that combination by introducing the packaging objects to the packaging object introducing portion according to a predetermined array.
To achieve the above-described object, according to a second aspect of the invention, there is provided a boxing apparatus wherein a box body having folding portions, which are developed to form a rectangular parallelepiped-shaped structure, and having flap portions for forming an opening portion and a lid portion for covering the opening portion on both ends is constructed from a folded state so as to form the opening portions, with the box body having the opening portions held such that one of the opening portion faces upward while the other one faces downward, a packaging object is loaded into the main body through one of the opening portion and the flap portions are constructed to form the lid so that the packaging object is packaged in the box, the boxing apparatus comprising foldable box body supplying means, opening forming means, box body holding means, packaging object loading means and lid forming means, wherein: the foldable box body supplying means accommodates the box body in a folded state and supplying the accommodated box body to the box body holding means one by one, the opening forming means constructing a box body supplied by the foldable box body supplying means to the box body holding means from a folded state to form the opening portion, the box body holding means holding the foldable box body having the opening portion formed at the opening forming portion with one of the opening portions facing upward while the other one facing downward, the packaging object loading means loading the packaging object through an opening portion of the box body held by the box body supplying means, the lid forming means folding the flap portions of the foldable box body after the packaging object is loaded into the packaging object loading means, so as to form a lid portion for covering the opening portion.
In the above-described boxing apparatus, the box body accommodated in the folding condition by the foldable box body supplying means is opened by the opening forming means and then supplied to the box body holding means. Therefore, after the opening is formed, the box body is held by the box body holding means such that one of the opening portion faces upward while the other opening portion faces downward. Then, the packaging object loading means loads the packaging object into the box body and the lid portion is formed by the lid forming means and finally, the packaging object is packed into the box body.
In this way, the boxing apparatus is capable of automatically carrying out a sequential processing of formation of the opening in the box body, loading of the packaging object and formation of the lid portion.
According to a third aspect of the invention, there is provided a box body supplying apparatus for supplying the box body to the boxing apparatus, wherein the foldable box body supplying means comprises a foldable box body accommodating portion which accommodates the box body in a folded state and has a box body pickup port for picking up the accommodated box body at an end thereof and a box body supplying portion for supplying a box body accommodated in the foldable box body accommodating portion to the boxing apparatus one by one, the box body supplying portion comprising: box body holding means for holding the box body and capable of approaching/leaving the box body pickup port and the boxing apparatus; and box body moving means for moving the box body holding means between a box body pickup position for picking up the box body from the box body pickup port and a box body loading position in which the picked up box body is loaded on the boxing apparatus.
In the box body supplying apparatus of the present aspect, the box body holding means located at the box body pickup position approaches the box body pickup port and picks up the box body accommodated in the foldable box body accommodating portion from the box body pickup port. The box body holding means is moved from the box body pickup port to the box body loading position by the box body moving means while holding the picked up box body. After the box body holding means is moved to the box body loading position, it approaches the boxing apparatus and loads the held box body on the boxing apparatus.
The box body supplying apparatus automatically carries out all scanning from pick-up of the box body to loading on the boxing apparatus.
According to a fourth aspect of the invention, there is provided a packaging system comprising: a small box package forming portion for forming a small box package in which one or multiple packaging objects is/are accommodated in the small box thereof; an assembly forming portion for forming a small box assembly by assembling according to an assembly pattern indicating the presence/absence, position and size of a header of the small box package and the size of the small box package; and an exterior packaging forming portion for forming an exterior packaging by loading the small box assembly into an exterior packaging box according to a predetermined loading pattern set depending on the assembly pattern.
In the packaging system of the present aspect, the assembly forming portion assembles a predetermined quantity of the small boxes, for example, five small boxes into a predetermined fashion according to the assembling pattern. The exterior packaging forming portion loads the small box assembly into the exterior packaging box according to a predetermined loading pattern.
The small box mentioned here includes a small box of a type having a header which is a tab-like member, a small box of a type having no header, a small box of a type in which the header is provided on an edge, a small box of a type in which the header is provided on a side edge, a small box of a type in which the width of the header is equal to that of the small box, a small box of a type in which the width of the header is larger than that of the small box, a small box of a type accommodating only a packaging object such as a film case therein, a small box of a type accommodating two or more packaging objects and the like.
However, by the packaging system of the present aspect, small boxes can be automatically accommodated in the exterior packaging box according to the packaging pattern in accordance with absence/presence of a header, position and size of the header and the size of the small boxes themselves.
According to a fifth aspect of the invention, there is provided a corrugated board box comprising a rectangular parallelepiped-shaped box body including a rectangular bottom portion and four side plates formed continuously with the bottom portion at each side of the bottom portion, with a top face of the box body being open, an intermediate partition for dividing the interior of the box body into two sections and four flap portions formed continuously from the side plates along top edges of the four side plates and folded inward along the continuous portions so as to form lid portions for covering the open top face, the intermediate partition being fixed at an inside face of one side plate through an end portion thereof and extending toward another side plate opposing the one side plate, so that the other end is formed as a free end.
The corrugated board box has a partition. Therefore, when shrink packages are loaded, the positions of the loaded shrink packages are stabilized and the shrink packages never move laterally in the corrugated board box. Thus, the shrink packages never interfere with each other to be damaged.
Because the front end of the partition is free, if the assembly loading means of the packaging system contacts the partition during loading of the small box assembly or the shrink package, the partition is moved with little resistance. Then, as the small box assembly is loaded on both sides of the partition, the partition is moved to the central portion of the corrugated board box. Therefore, if the corrugated board box is employed in a packaging system which uses a multi-articulate robot as the assembly loading means, a stable loading is facilitated.
According to a sixth aspect of the invention, there is provided a packaging system comprising: a packaging object manufacturing portion for manufacturing a packaging object; and a packaging portion for packaging the packaging object manufactured by the packaging object manufacturing portion in a predetermined fashion, wherein the packaging object manufactured by the packaging object manufacturing portion is packaged by the packaging portion without being deposited between being manufactured and being packaged.
In the packaging system of the present aspect, the packaging object manufactured by the packaging object manufacturing portion is supplied to the packaging portion immediately without being deposited between being manufactured and being packaged, in other words, processing from manufacturing of the packaging object in the packaging object manufacturing portion to packaging of the packaging object by the packaging portion is executed as a sequential process.
Therefore, because no accumulating portion is necessary between the packaging object manufacturing portion and the packaging portion unlike a conventional plastic case packed product packaging unit, there is no room of producing any stock in the process. Thus, a period from reception of an order for the packaging object to shipment to a customer can be reduced largely. Further, because a time in which the packaging object remains in the process can be reduced, the efficiency of the entire packaging system is improved largely.
Additionally, because the packaging object manufactured by the packaging object manufacturing portion is supplied to the packaging portion immediately without being deposited between being manufactured and being packaged, a packaging object manufactured by the packaging object manufacturing portion first is supplied and packaged earlier than a packaging object manufactured later, so that so-called “first-in first-out” can be achieved completely.
Therefore, because tracking can be carried out easily if any defect is found out in inspection process after packaging at the packaging portion, the cause for that defect can be grasped easily.
The packaging object mentioned under the present invention includes commodity in which one or two products are accommodated in a small box package such as a film cartridge, various kinds of canned beverages, copier toner container, as well as the aforementioned plastic case packed product.
As for the style of packaging the packaging objects by the packaging portion, for example, one or multiple packaging objects are loaded in such a small box as the sack carton so as to form a small box package and then, the small box assembly is formed based on a predetermined pattern and packed into a corrugated board box.
A carton supplying unit, which is an example of the box body supplying apparatus of the present invention, and a cartoner which is an example of the boxing apparatus of the invention and has the carton supplying unit will be described as follows.
The cartoner refers to a boxing apparatus for packaging a film cartridge accommodated in a moisture-proof case in a sack carton and the carton supplying unit is a box body supplying apparatus for supplying the sack carton to the cartoner.
1-1 CartonerAs shown in
As shown in
A hot melt adhesive injecting gun 20 is disposed between the upper lid constructing portion 10 and the bottom lid constructing portion 12 to apply hot melt adhesive to a flap portion C12 constituting an upper lid C8 of the sack carton C. On the other hand, a hot melt adhesive injecting gun 22 is disposed between a first pusher 12C and a second pusher 12D located downstream thereto in the bottom lid constructing portion 12. The hot melt adhesive injecting gun 22 applies hot-met adhesive to an inside surface of an outside flap C22.
The rotation table 4, the carton opening forming portion 6, the a plastic case-packed product packing portion 8, the upper lid constructing portion 10, the bottom lid constructing portion 12 and the carton discharging portion 14 are mounted at a specific location on a base (not shown).
As shown in
As shown in
The flap portion C12 has a pair of inner flaps C16 which form an inside portion of the upper lid C8 and a folding portion and further contains an outside flap C18 which forms an outside portion of the upper lid C8. The outside flap C18 is provided at a position opposing a header C2.
Likewise, the flap portion C14 has a pair of inside flaps C20 which form the inside portion of the bottom lid C10 and a pair of the outside flaps C22 which form an outside portion of the bottom lid C10.
As the sack carton C, in addition to the type shown in
As shown in
The index tables 4A, 4B are constructed to be capable of approaching or leaving each other in the vertical direction so as to hold upper end and lower end of the carton when a carton of a different size is transported.
The carton opening forming portion 6 is, as shown in
As shown in
The opening-forming guide member 6A2 has a guide surface 6A6 shaped in a taper at one end and is located at a location wherein a corner portion of a sack carton C supplied by the carton supplying unit 2 and shown in two-dot chain line in
The opening-forming pusher member 6A4 is provided in a tangential direction to the index table 4A so as to push the sack carton C at its tip portion. At its root portion, a slider 6A8 sliding on the slide guide 6A10 is provided.
When a folded sack carton C is approaching to a carton-setting portion 42 of the index table 4 by the carton supplying unit 2, as shown in two-dot chain line in
Them as shown in bold line in
As shown in
By retracting the piston 6B12, the flap folding arm 6B rotates in a direction that the front-end portion 6B2 approaches to an inner flap C16 located in the upstream side, and thus, the inner flap C16 is folded toward the downstream side so as to cover the opening portion C4.
The flap folding plate 6C is extended from the carton opening forming portion 6 to the upper lid constructing portion 10. When the rotation table 4 rotates in the direction of an arrow a, the inside flap C16 in the downstream side is folded to the upstream side so as to overlap the inside flap C16 in the upstream side. When the inside flap C16 on the downstream side is folded, the inside flap C16 is held from downward not so as to open until the sack carton C reaches the upper lid constructing portion 10 from the carton opening forming portion 6 through the plastic case-packed product packing portion 8.
As shown in
As shown in
When providing the plastic case packed products P from the plastic case supplying unit 8B to the plastic case pressing device, the open-close accepting guide 828A opens and the plastic case packed products P are delivered to the plastic case supplying shoot 828F in an specific number. At that time, the open-close guide 828G is closed.
After the plastic case packed products P are supplied to the plastic case supplying chute 828F, the open-close accepting guide 828A closes and the pusher 8A2 descends to press the plastic case packed product to the downward. Thus, the open-close guides open and the plastic case packed products in the plastic case supplying chute 828F are loaded in the sack carton C.
The upper lid constructing portion 10 comprises an outside flap folding member 10A which is located at a standby position inside of the flap folding plate 6C or a flap folding position outside of the flap folding plate 6C and folds the outside flap C18 of the flap portion C12 toward the header C2 when it moves from the standby position outward toward the flap folding position, a header supporting plate 10B which supports the header C2 from outside not so as to be folded outward when the outside flap C18 is folded by the outside flap folding member 10A, an upper lid folding unit 10M which forms the upper lid C8 by folding upward the outside flap C18 bent by the outside flap folding member 10A and the header supporting plate 10B.
As shown in
Below the guide 10C, a swing arm 10E is mounted on the base by an axis 10F. At one end of the swing arm 10E, a pin 10E2 is disposed and at the other end thereof, a pin 10E4 is disposed.
An engaging portion 10D having an L-shape is provided on the slider 10A2 and a helical spring 10G is disposed between the slider 10A2 and the guide 10C and thus, the helical spring 10G urges the slider 10A2 and the outside flap folding member 10A so that the engaging portion 10D touches the pin 10E2.
The slider 10B2 incorporates an engaging portion 10H having an L-shape and a helical spring 10I is provided between the slider 10B2 and the guide 10C. The helical spring 10I urges the slider 10B2 and the header supporting plate 10B so that the engaging portion 10H touches the pin 10E4.
A pocket 10E6 in which the pin 10E4 is retracted is provided on the swing arm 10E at a portion below the pin 10E4. Below the pocked 10E6, an air cylinder 10E8 popping and retracting the pin 10E4 is fixed. The pin 10E4 is fixed on the piston 10E10 of the air cylinder 10E8 so as to pop out of the pocket 10E6 when the piston 10E10 is expanded and to be retracted inside of the pocket 10E6 when the piston 10E10 is contracted.
When the sack carton has a pair of outside flap C18 instead of the header C2 located adjacent to the upper lid C8, at the swing arm 10E, the piston 10E10 is expanded and the pin 10E4 pops over the swing arm 10E. Thus, when the swing arm 10E rotates contra-clockwisely in
On the other hand, when the sack carton C has a header C2 adjacent to the upper lid C8, at the swing arm 10E, the piston 10E10 is contracted and the pin 10E4 is retracted into the pocket 10E6. Thus, the force of rotation from the swing arm 10E is not transferred to the header supporting plate 10B and therefore, the header supporting plate 10B is urged by the helical spring 10I to contact to the stopper 10K to stand at a location A in
As shown in
A guide 10M10 is fixed on the base and a slider 10M12 is fixed to the horizontal pusher 10M6. By the slider 10M12 sliding on the guide 10M10, the horizontal pusher 10M6 approaches and parts from the guide plate 10M4. Additionally, the horizontal pusher 10M6 is connected to the spline shaft 12A2 by a spline nut 10M14 and an arm 10M16. Thus, by the spline shaft 12A2 rotating, the horizontal pusher 10M6 moves reciprocally between a rest position shown in bold line and a folding position shown in two-dot chain line in
By the horizontal pusher 10M6 moving from the rest position to the folding position, the outside flap C18 of the sack carton C is guided along the guide surface 10M2 of the guide plate 10M4 to a folding position shown in two-dot chain line in
Then, the vertical pusher 10M8 ascends from a rest position shown in broken line to a folding position shown in two-dot chain line in
The bottom lid constructing portion 12 is provided such that it adjoins the index table 4B above the upper lid folding unit 10M. The bottom lid constructing portion 12 comprises a flap folding arm 12A which folds one inside flap 20 of the bottom lid C10 toward the opening portion C6, a flap folding plate 12B which is a circular plate-like member adjacent to the downstream side of the flap folding arm 12A and extended along the outer periphery of the index table 4B, a roller-like first pusher 12C adjacent to the downstream side of the flap folding plate 12B and a second pusher 12D adjacent to the downstream side of the first pusher 12C.
The flap folding arm 12A is a plate-like member which is extended from outside to inside of the index table 4B while its front end is formed in a hook like shape. Then, this is formed rotatably around the rotation axis provided on a root portion which is an end portion opposite to the side formed in the hook-like shape. When the flap folding arm 12A rotates toward downstream side, the hook-shaped end portion abuts on the inside flap C20 in the upstream so that it folds the inside flap C20 toward the downstream so as to cover the opening portion C6.
When the rotation table 4 rotates in the direction of an arrow a, the flap folding plate 12B folds the inside flap C20 on the downstream side of the sack carton C toward the upstream side so as to overlap the inside flap C20 on the upstream side. If the inside flap C20 on the downstream side is folded, the pair of the inside flaps C20 are held from upward not so as to open until the sack carton C reaches the first pusher 12C.
The first pusher 12C is formed so as to be capable of advancing or retracting along the radius direction of the index table 4B. When it advances toward the center of the index table 4B, one outside flap C22 located outside of the pair of the outside flaps C22 is folded inward so as to overlap the inside flap C20.
The second pusher 12D is also formed so as to be capable of advancing or retracting along the radius direction of the index table 4B similarly to the first pusher 12C. If it retracts toward the outer periphery of the index table 4B, it folds and bond the outside flap C22 so as to overlap the outside flap C22 thereby forming the bottom lid C10.
As shown in
The walking table 14A and the pick-up forks 14B walk in a synchronized manner between a sack carton accepting position shown in
The slider mechanism 14E comprises a linear guide 14G, a slider 14F with the walking table 14A and the pick-up fork 14B fixed thereon and sliding on the linear guide 14G, a driving lever 14H driving the slider 14F, a slider 14I fixed to the upper pick-up fork 14B and a linear guide 14J on which the slider 14I slides.
On the other hand, the discharging fork 14C walks by a slider mechanism 14K in a direction approaching the discharging conveyer 14D or in a direction parting therefrom.
The slider mechanism 14K has a linear guide extending in a direction parallel to the discharging conveyer 14D and a slider 14L with the discharging fork 14C fixed thereon and sliding on the linear guide 14M.
Additionally, at the tip portion of the discharging fork 14C, claws 14A2 and 14A4 are provided.
An operation of the carton discharging portion 14 is described in the below.
When the sack carton with its bottom lid C10 constructed at the bottom lid constructing portion 12 is moved to the carton discharging portion 14 by the index tables 4A and 4B, the walking table 14A and the pick-up forks are at the sack carton accepting position shown in
When the sack carton C is mounted on the walking table 14A, the walking table 14A and the pick-up forks 14B moves by the slider mechanism 14E to the sack carton delivering position as shown in
Finally, as shown in
The sack carton C discharged on the discharging conveyer 14D is discharged out of the cartoner 400 by the discharging conveyer 14D.
The entire operation of the cartoner 400 is described below. In the meantime, a flow of the carton and the plastic case packed products in the cartoner 400 is shown in
As shown in
The opening is formed in the carton opening forming portion 6 and after the opening portion C8 is covered, the sack carton C is transported to the plastic case-packed product packing portion 8. Then, a predetermined quantity of the plastic case packed products are loaded in the plastic case packing portion C8.
After the predetermined quantity of the plastic case packed products are loaded in the plastic case packing portion C8, the sack carton C is transported to the upper lid constructing portion 10. There, the outside flap C18 is folded and bonded to the inside flap thereby forming the upper lid C8.
In the sack carton C, at the same time when the upper lid C8 is formed by the upper lid constructing portion 10, the inside flap C20 is folded at the bottom lid forming portion 12 so as to cover the opening portion C6. Then, the outside flap C22 is folded successively and bonded so as to form the bottom lid C10.
After the bottom lid C10 is formed, the sack carton C is transported to the carton discharging portion 14 and discharged from the cartoner 400 and sent to a post process.
1-2 Carton Supplying UnitAs shown in
The carton supplying chute 100 corresponds to the box body accommodating portion in the box body supplying unit of the invention. As shown in
A supplying chute front end portion 106 is formed in the vicinity of the carton pickup port 104 of the carton supplying conveyor portion 102.
The carton supplying conveyor portion 102 comprises a main belt conveyor 108 constituted of three belt conveyors arranged in parallel, a pair of end plates 112 provided in parallel to the main belt conveyor 108 so as to sandwich the main belt conveyor 108 in the width direction and a horizontal guide 110 disposed between the end plate 112 and the main belt conveyor 108 in parallel to the main belt conveyor 108. The horizontal guide 110 corresponds to the horizontal guide member according to the invention. The carton supplying conveyor 102 is fixed on the base 180 at the end plate 112.
A drive roller 108A for supporting the main belt conveyor 108 and a driven roller 108B are pivoted by the end plate 112.
The horizontal guide 110 is comprised of a reference side guide member 110A fixed to the carton supplying conveyor portion 102 and a moving side guide member 110B formed so as to be capable of approaching or leaving the reference side guide member 110A.
The horizontal guide 110 is provided with a width adjusting guide 114 for guiding the main belt conveyor 108 along the width direction when the moving side guiding member 10B is moved relative to the reference side guiding member 110A such that it is at right angle to the main belt conveyor 108 when it passes through the main belt conveyor 108. Two pieces of the width adjusting guides 114 are arranged along the longitudinal direction of the main belt conveyor 108. An end of the width adjusting guide 114 is fixed on the reference side guide member 110A while the other end is fixed to the moving side guide member 110B. A horizontal guide width adjusting motor 1116 for moving the moving side guide member 110B is provided below the end plate 112.
As shown in
Three auxiliary belt conveyors 118 are provided and two of them are provided in the main conveyor 108 while the other one is provided between the main conveyor 108 and the reference side guide member 110A. The auxiliary belt conveyor 118 is wound around the drive roller 118A and the driven roller 118B. The drive roller 118A has the same diameter as the drive roller 108A and is provided coaxially with the drive roller 108A such that it is sandwiched by the drive roller 108A.
The drive roller 108A and the drive roller 118A are driven by the belt conveyor drive unit 108C fixed to the end plate 112.
The belt conveyor drive unit 108C is formed such that one of rotating one of the drive roller 108A and the drive roller 118A, and rotating the both is selectable. Such a belt conveyor drive unit 108C comprises a motor 108D, a first clutch 108E for transmitting a rotation of the motor 108D to the drive roller 108A and a second clutch 108F for transmitting a rotation of the motor 108D to the drive roller 118A.
In the belt conveyor drive unit 108C, if the motor 108D is rotated with only the first clutch 108E set to “in contact”, only the drive roller 108A is rotated and then only the main belt conveyor 108 is driven. If the motor 108D is rotated with only the second clutch 108F set to “in contact”, only the drive roller 118A is rotated and then only the auxiliary belt conveyor 118 is driven. Then, if both the first clutch 108E and the second clutch 108F are set to “in contact”, the drive rollers 108A and 118A are rotated at the same velocity, so that the main belt conveyor 108 and the auxiliary belt conveyor 118 are driven at the same transfer velocity.
If other transmission gear is employed instead of the first clutch 108E and the second clutch 108F, the main belt conveyor 108 and the auxiliary belt conveyor 118 are driven at different transfer velocities.
As the belt conveyor drive unit 108C, a first motor for driving the drive roller 108A and a second motor for driving the drive roller 118A, provided independently of the first motor may be provided.
Preferably, the auxiliary belt conveyor 118 is composed of material having a low friction coefficient such as fluororesin in order to protect the sack carton C from being damaged when it slips.
The actuator supporting base 124 is fixed on the end plate 112 by means of four supporting columns 126 above the auxiliary belt conveyor 118 and an upper guide plate 146, which will be described later, is mounted on an actuator supporting base 124 through the upper guide plate mounting portion 122 such that it is capable of rising or falling and an upper guide plate 160, which will be described later, is mounted through the upper guide plate mounting portion 120 such that it is capable of rising or falling. Two supporting columns 126 are mounted on a supporting column receiving plate 128 fixed on an upper edge of the end plate 112 such that they are located outside the horizontal guide 110.
An pickup port guide plate 130 is provided on the side of the carton pickup port 104 of the auxiliary belt conveyor 118 to prevent the sack carton C transported by the auxiliary belt conveyor 118 from dropping through a gap in the end plate 112. Edges on the side of the carton pickup port 104 of the end plate 112 are connected to each other through the end plate 132. An upper edge of the end plate 132 is in contact with the bottom face of the pickup port guide plate 130.
The upper guide plate 146 is held below the actuator supporting base 124 such that it is capable of rising or falling so as to form the carton pickup port 104.
An edge on the side of the carton pickup port 104 of the upper guide plate 146 is provided with upper pawls 134, 136 for holding an upper edge portion of the sack carton C as shown in
The side pawls 142, 144 can be provided at a front end of each of the reference guide member 110A and the moving side guide member 110B. However, if the sack carton C has a header C2 projecting from the flap portion C12, as shown in
The structure of the upper pawl 134 and an upper guide plate 146, which will be described later, and their surrounding portion are shown in
As shown in
A rod-like ram member 148A and an auxiliary ram member 148B are projected from a bottom face of the actuator 148. The upper guide plate 146 is fixed to a bottom end of each of the ram member 148A and the auxiliary ram member 148B. The actuator 148 incorporates various kinds of actuator mechanisms for hydraulic pressure, air pressure and ball screws. The ram member 148A is raised and dropped by the actuator mechanism. The auxiliary ram member 148B is a guide member which is provided adjacent to the ram member 148A for guiding the upper guide plate 146 in the vertical direction in order to prevent the upper guide plate 146 from rotating around the ram member 148A. If the ram member 148A rises or falls, the upper guide plate 146 is raised or dropped.
A carton arranging plate 149 is provided substantially in parallel to the upper guide plate 146 below the upper guide plate 146. A rubber plate 149A is fixed on a front edge of the carton arranging plate 149 in order to protect the sack carton C from slipping relative to the carton arranging plate 149.
An actuator 152 for lifting up and down the carton arranging plate 149 is fixed on a top face of the upper guide plate 146 through a fixing member 151. By moving the carton arranging plate 149 up and down by the actuator 152, heights of the upper edges of the sack cartons C can be arranged in line.
A bearing member 154 having a horizontal rotation axis is fixed on a front edge on the top face of the upper guide plate 146 and the upper pawl 134 is pivoted by a bearing member 154 so that its bottom portion is projected about 1 to 3 mm below an upper guide plate 146. Therefore, the upper pawl 134 rotates to approach or leave the front edge of the upper guide plate 146 as indicated with two-dot chain line in
As shown in
If a pressure is applied to the upper pawl 134 from the sack carton C, as indicated with two-dot chain line in
The upper guide plate 160 is also a height direction guide member abutted on an upper edge of the sack carton C for guiding the sack carton C. As shown in
The plate-like upper pawl 136 projected downward is fixed at a front end of the upper guide plate 160. Preferably, a projection amount of the upper pawl 136 is 1 to 3 mm.
As shown in
A load sensor fixing plate 168 is fixed below the end plate 132 and a load sensor 166 for detecting a pressure applied to the lower pawl 138 from the sack carton C is fixed on the load sensor fixing plate 168 so that it opposes a bottom end portion of the lower pawl 138. The lower pawl 138 and the load sensor 166 correspond to a pressure detecting means in the box body supplying apparatus of the invention.
If a pressure is applied from the sack carton C to the lower pawl 138, as indicated by two-dot chain line in
As shown in
Further, the moving side guide member 110B moves in a direction approaching or leaving the reference side guide member 110A so as to abut on the side edge of one flap portion of the sack carton C.
The carton supplying shoot 100 includes a transporting velocity control system 170 for controlling the transfer velocities of the main belt conveyor 108 and the auxiliary belt conveyor 118 based on a signal from the load sensors 156, 166 as shown in
The transporting velocity control system 170 comprises an amplifier 172 for amplifying a voltage output from the load sensor 156, an amplifier 174 for amplifying a voltage output from the load sensor 166, a meter relay 176 for controlling output voltages amplified by the amplifiers 172, 174 with a reference voltage, a meter relay 176 for controlling a sequencer 178 based on a result of the aforementioned comparison and a sequencer 178 for controlling a belt conveyor drive unit 108C based on a control instruction from the meter relay 176.
As shown in
If both the output voltage V1 and output voltage V2 are below the reference voltage V, no pressure over the reference pressure is detected by the load sensors 156, 166 so that the sequencer 178 judges that no pressure higher than the reference pressure is applied to the upper pawl 134 and the lower pawl 138.
Therefore, the sequencer 178 turns on the motor 108D of the belt conveyor drive unit 108C, the first clutch 108E and the second clutch 108F.
Consequently, both the drive rollers 108A and 118A are driven so that the main belt conveyor 108 and the auxiliary belt conveyor 118 are both driven at the same transfer velocity. Therefore, the sack carton C is transported to the carton pickup port 104 by the main belt conveyor 108 and the auxiliary belt conveyor 118.
If the output voltage V1 is higher than the reference voltage V and the output voltage V2 is below the reference voltage V, the load sensor 156 for detecting a pressure of the upper pawl 134 detects a pressure higher than the reference pressure and then the sequencer 178 judges that the sack carton C is inclined as if the top edge of the sack carton C falls forward or the sack carton C falls down forward at the supplying shoot front end portion 106.
Therefore, the sequencer 178 turns on the motor 108D and the second clutch 108F of the belt conveyor drive unit 108C and turns off the first clutch 108F so as to stop the drive roller 108A while rotating only the 118A. Consequently, transporting by the main belt conveyor 108 is stopped and only transporting by the auxiliary belt conveyor 118 is continued. Thus, the bottom edge of the sack carton C is transported to the carton pickup port 104 at the supplying chute front end portion 106 so as to eliminate the forward inclination of the sack carton C.
If the output voltage V1 is below the reference voltage V while the output voltage V2 is higher than the reference voltage V, the load sensor 166 for detecting a pressure of the lower pawl 138 detects a pressure over the reference voltage and therefore the sequencer 178 judges that the sack carton is inclined as if the bottom edge of the sack carton C falls forward, that is, the sack carton C falls backward at the supplying shoot front end portion 106.
Therefore, the sequencer 178 turns on the motor 108D and the first clutch 108F of the belt conveyor drive unit 108C and turns off the second clutch 108F so as to stop the drive roller 118A while rotating only the drive roller 108A. Consequently, only transporting by the main belt conveyor 108 is continued and transporting by the auxiliary belt conveyor 118 is stopped. As a result, the bottom edge of the sack carton C is stopped at the supplying shoot front end portion 106 and the upper half portion of the sack carton C is pressed forward by a pressure supplied from the main belt conveyor 108 so as to eliminate the backward falling.
If both the output voltage V1 and the output voltage V2 are higher than the reference voltage V, the load sensors 156, 166 detect a pressures over the reference pressure and therefore, the sequencer 178 judges that the sack carton C is pressed against the upper pawl 134 and the lower pawl 138 by an excessive pressure at the supplying chute front end portion 106.
Thus, the sequencer 178 turns off the motor 108D of the belt conveyor drive unit 108C, the first clutch 108F and the second clutch 108F so as to stop both the drive rollers 108A, 118A. Because the sack carton C is picked up one by one continuously from the carton pickup port 104 by means of the carton supplying portion 200, the quantity of the sack cartons C at the supplying chute front end portion 106 is decreased, so that a condition in which an excessive supply pressure is applied to the upper pawl 134 and the lower pawl 138 is eliminated.
The carton supplying chute 101 shown in
A transporting velocity control system 171 is equal to the transporting velocity control system 170 of the carton chute 100 in that it compares the output voltage V1 from the load sensor 156 and the output voltage V2 from the load sensor 166 with the reference voltage V so as to control the sequencer 178 based on a result of the aforementioned comparison. However, this is different from the transporting velocity control system 170 in that when any one of the output voltage V1 and the output voltage V2 is higher than the reference voltage V, the sequencer 178 turns off both the motor 108D and the first clutch 108E in the same manner as when both the output voltage V1 and the output voltage V2 are higher than the reference voltage V.
The carton supplying chute 101 has the same configuration as the carton chute 100 except the above-described points.
In the carton supplying chute 103 shown in
The carton supplying chute 103 has the same configuration as the carton supplying chute except these points.
The transporting velocity control system 173 has the same configuration as the transporting velocity control system 171 included by the carton supplying chute 101 and the sequencer 178 controls the belt conveyor drive unit 108C according to the same sequence.
(B) Carton Supplying PortionAs shown in
An index unit 208 for rotating the rotation shaft 202 intermittently and a motor 210 for supplying the index unit with a rotation force are provided at a root of the rotation shaft 202.
The suction head 204 corresponds to box body holding means included by the box body supplying means of the invention, and the rotation shaft 202, the suction head supporting portion 206, the index unit 208 and the motor 210 correspond to a holding portion moving means included by the box body supplying means.
The suction head 204 is pivoted by a suction head supporting portion 206 on the shaft 212 provided in parallel to the suction plane.
The suction head supporting portion 206 comprises a suction head supporting plate 206A fixed on the rotation shaft 202 at its central portion, a pair of first holding member 206B whose end is fixed to both end portions of the suction head supporting plate 206A and a pair of second holding members 206C whose end is fixed to a portion nearer the front end portion than the suction head supporting plate 206A on the rotation shaft 202.
A pair of the shafts 212 are provided and each of them is held at an angle of 45° relative to the rotation shaft 202 by the first holding member 206B and the second holding member 206C.
An end of a crank member 212A is fixed on an end on the side of the first holding member 206B on the shaft 212. A spring 212B for urging the crank member 212A in a direction rotating the shaft 212 so as to turn the suction head 204 upward is provided between the crank member 212A and the first holding member 206B. A crank pushing member 230 for pushing the crank member 212A from downward and rotating the suction head 204 downward is provided adjacent to a bottom portion of the other end portion of the crank member 212A. Unless the crank member 212 is pushed by the crank pushing member 230 as indicated with two-dot chain line in
As shown in
The frame body 214 comprises side plates 214A, 214B which are fixed on the shaft 212 inside of the portion held by the first holding member 206B and the second holding member 206C for forming a side wall of the frame body 214 and guide plates 214C, 214D which form a ceiling plate and a bottom plate of the frame body 214, are projected from the side plates 214A, 214B forward or in the direction toward the suction plane and guides the sack carton C toward the carton receiving portion 216. Here, the side plate 214A is a side plate adjacent to the first holding member 206B and the side plate 214B is a side plate adjacent to the second holding member 206C.
As shown in
As shown in
In the suction cup 218, a trumpet like cup portion 218A for sucking and holding the sack carton C is formed at an end thereof and a tubular portion 218B extending from the cup portion 218A to the other end is formed at the other end. Further, a spring 218C for urging the suction cup 218 backward is mounted between the suction cup mounting plate 216A and the suction cup pressing member 216D in the suction cup 218.
As shown in
A spring 228 for urging the carton receiving portion 216 in a direction parting from the suction plane is provided between the rear end portion of the slide guide member 224 and the slide guide receiver 214F.
A projecting portion 216F projecting forward is formed on an opposite side of the slide guide member 224 across the suction cup 218 in the guide plate 216B.
As shown in
As shown in
The receiving drive force transmission unit 280 comprises a pressing rod 282 which presses the pressing pin 216E of the suction head 204 toward the carton pickup port 104 with a pressing force from the suction cup receiving drive unit 240, a pressing rod supporting member 284 having a leg portion 284A fixed to the suction head supporting plate 206A and for supporting the pressing rod 282 slidably relative to the pressing pin 216E and a spring 286 for urging the pressing rod 282 in a direction parting from the pressing pin 216E.
The suction cup receiving drive unit 240 comprises a receiving drive rod 242 for pressing the pressing pin 216E through the pressing rod 282, a receiving drive rod supporting member 244 for supporting the receiving drive rod 242 slidably along the axial direction at an angle inclined at 40° upward from a horizontal plane, a reciprocating rod 246 for reciprocating vertically as indicated with an arrow a in
As shown in
In the suction cup mounting drive unit 260, the swing motion of the drive crank 270 is converted to a reciprocating motion indicated with an arrow c in
If a predetermined quantity of the sack cartons C are accommodated in the carton supplying chute 100 and the main belt conveyor 108 is driven, the sack carton C is moved to the supplying chute front end portion 106.
In the supplying chute front end portion 106, the sack carton C tries to be moved further toward the carton pickup port 104 by the auxiliary belt conveyor 118. Therefore, at the carton pickup port 104, the sack carton C is pressed by the upper pawls 134, 136 and the lower pawls 138, 140 so that a pressure along the direction of picking out the sack carton C is applied to the upper pawls 134, 136 and the lower pawls 138, 140. The aforementioned pressure is detected by the load sensors 156, 166 and then, the feedings of the main belt conveyor 108 and the auxiliary belt conveyor 118 are controlled by the transporting velocity control system 170 so that the aforementioned pressure is below a predetermined value.
Since as shown in
If the crank pushing member 230 rises and pushes the crank member 212A included by the suction head 204, the suction head 204 is moved from the carton receiving preparation position to a carton receiving position opposing the carton pickup port 104 as shown in
If the suction head 204 is located at the above-described carton receiving position, the receiving drive rod 242 in the suction cup receiving drive unit 240 is projected toward the suction head 204 as shown in
After the sack carton C is sucked by the suction cup 218, the receiving drive unit 240 presses the carton receiving portion 216 inward of the supplying chute front end portion 106 as shown in
If the carton receiving portion 216 is pressed, the sack carton C is pressed into the inside of the supplying chute 100.
With this condition, the carton arranging plate 149 is descended to the sack carton C by the actuator 152. Consequently, the second or third and following sack cartons C from the most forward side are pressed and held by the rubber plate 149A of the carton arranging plate 149. If the heights of the top edges of the sack cartons C are not in line, the heights of the top edges of the sack cartons C can be arranged by pressing the top edges of the sack cartons C by means of the carton arranging plate 149.
If the sack carton C is pressed and held by the carton arranging plate 149, the receiving drive rod 242 is moved in a direction leaving the suction head 204 and then, as shown in
An operation of the carton receiving portion when taking out the sack carton C will be described further.
Since a projecting portion 216F is formed at a front end of the guide plate 216B provided on the carton receiving portion 216, if the carton receiving portion 216 approaches the sack carton C, first, the projecting portion 216F is brought into contact with the sack carton C as shown in
If the projecting portion 216F abuts on the outside flap C22, the carton receiving portion 216 advances from the above-described condition to inside of the supplying chute front end portion 106 and presses the sack carton C into the inside of the supplying chute front end portion 106. When the sack carton C is pressed into the inside of the supplying chute front end portion 106 by a predetermined amount, the sack carton C is pressed and held by the carton arranging plate 149 as described above. Consequently, the carton receiving portion 216 cannot advance further. Therefore, as shown in
If the suction cup 218 adheres to the side face a of the sack carton C by suction, the suction cup 218 is retracted by an urging force from the spring 218C while adhering to the sack carton C as shown in
By bringing the carton receiving portion 216 apart from the carton pickup port 104, the sack carton C can be taken out of the carton pickup port 104 with a condition that a slight opening is formed as shown in
As shown in
Therefore, the side face a moves toward the forward side, that is, downward to the left in
If the sack carton C is taken out of the carton pickup port 104, the crank pushing member 230 descends and then, the crank member 212 is rotated counterclockwise by an urging force from the spring 212B as indicated with two-dot chain line in
If the shaft 202 is rotated by 1800 from this condition, the suction head 204 moves from the carton receiving preparation position to the carton mounting position.
As shown in
Therefore, if the suction cup mounting drive unit 260 is actuated and the main drive rod 262 presses the pressing portion 226 toward the carton opening forming portion 6 of the cartoner 400, the carton receiving portion 216 is moved toward the carton opening forming portion 6 through the slide guide connecting member 224 fixed on the pressing portion 226. Here, because in the carton receiving portion 216, the cartoner C adheres to the suction cup 218 by suction, the cartoner C is mounted on the carton opening forming portion 6 after an opening is formed by the opening forming unit 6A halfway.
1-3 Characteristic of the Cartoner and Carton Supplying Unit According to a First EmbodimentIn the carton supplying unit 2, the sack carton C is accommodated in the carton supplying chute 100 such that it is located sideway of the flap portions C12, C14. Therefore, even a carton having a large header at its one end portion or an elongated carton can be loaded easily. Further, even if a carton, in which the flap portions C12, C14 have an overlapping portion and a non-overlapping portion in a folding condition and there is a difference in thickness between the folding portion a and the folding portion d, is loaded, the sack carton C is held on the carton pickup port 104 at right angle to the pickup direction. Consequently, the sack carton C is taken out stably.
Further, the sack carton C is taken out stably because the main belt conveyor 108 and the auxiliary belt conveyor 118 are controlled so that pressure applied to the upper pawls 134, 136 and the lower pawls 138, 140 are within a predetermined range.
Further, because as described above, when the sack carton C is taken out, the second, third and following cartons from the most forward side are pressed by the carton arranging plate 149 and the sack carton C is taken out with a slight opening formed, the sack carton C is prevented from making into firm contact with the upper pawls 134, 136 and the lower pawls 138, 140 thereby protecting from a damage. Further, even if an old carton or a warped carton is loaded, the sack carton C is taken out smoothly.
Further, because the carton supplying unit 2 has not only the main conveyor 108 but also the auxiliary conveyor 118, cartons each having a different thickness can be fed to the carton pickup port 1104 Stably.
Additionally, because in the carton supplying portion 200, one of a pair of the suction heads is located at the carton receiving preparation position relative to an axis inclined at 45° with respect to a horizontal plane while the other one is fixed at the carton mounting position line symmetrically to the former, reception of a carton from the carton supplying chute 100 and supply of the carton to the cartoner 400 can be carried out in parallel.
Further, because the opening is formed in the carton halfway when the sack carton C is taken out, no failure occurs in the carton opening forming portion 6 of the cartoner 400.
Because the cartoner 400 utilizes the carton supplying unit 2 in order to supply the cartons and the rotation table 4 for holding the sack carton C is made of a pair of index table 4A and index table 4B which are formed so as to be capable of approaching or leaving, it can cope with various shapes and lengths of the sack cartons flexibly.
Further, because the carton supplying unit 2, the carton opening forming portion 6, the plastic case-packed product packing portion 8, the upper lid constructing portion 10, the bottom lid constructing portion 12 and the carton discharging portion 14 are disposed around the rotation table 4, the entire apparatus can be constructed in a compact fashion.
Additionally, because the sack carton C is supplied to the carton opening forming portion 6 with one of opening portions of both the ends facing upward and the other one facing downward and after the opening is formed with this condition, the plastic case packed product is loaded through the opening portion facing upward without changing the posture of the sack carton C, the boxing and packaging can be carried out efficiently.
A Second EmbodimentAnother example of a cartoner included in the boxing apparatus related to the present invention is shown in
A cartoner 402 related to the second embodiment is an example of a cartoner incorporating a sack carton holding unit 350 and a sack carton pick-up and supplying unit 300 in place of the carton supplying chute 100 and the carton supplying portion 200 in the cartoner 400 related to the first embodiment. As shown in
As shown in
In the sack carton holding unit 350, folded sack cartons C are stored in the stocker 356. Then, the height of the bottom guide 358 is adjusted in accordance with the height of the sack cartons C. At the same time, a piston of the air cylinder 360 is expanded or contracted in accordance with the width of the sack cartons C to move the guide plate 354 so as to change the width and height dimensions of the stocker 356. Thus, the width and height dimensions of the stocker 356 can be adjusted in accordance with a sack carton C having a different height or lateral dimension.
As shown in
The sack carton pick-up and supplying unit 300 has a rotating table 302, suction cups 304 and 306 that are mounted on the rotating table 302. The suction cups 304 and 306 are disposed on the rotating table 302 with an axis 312 of the rotating table 302 between them. The rotating table 302 rotates intermittently around the axis 312 by 180 degrees so that one of the suction cups 304 and 306 faces the carton setting portion 42 of the index table 4A and the other faces the stocker 356.
The suction cups 304 and 306 are fixed on sliders 316 and 318, respectively, the sliders 316 and 318 sliding on a linear guide 314 fixed on the rotating table 302. The suction cups 304 and 306 are also connected and urged by helical springs 320 so as to approach each other.
Outside of the rotating table 302, suction cup-driving levers 308 and 310 are provided. The suction cup-driving levers 308 and 310 drive the suction cups 304 and 306 against the urging forces of the helical springs 320 so that the suction cup 304 parts from the suction cup 306. The suction cup-driving levers 308 and 310 rotate with the rotating table 302. Additionally, the slider 316 on which the suction cup 304 is fixed and the slider 318 on which the suction cup 306 is fixed are pressed to the suction cup-driving levers 308 and 310, respectively by the urging force from the helical springs 320.
The sack carton pick-up and supplying unit 300 operates as follows.
Firstly, the suction cup-driving lever 308 drives the suction cup 304 to approach the stocker 356. Then, the suction cup 304 sucks a sack carton C located at the front of the stocker 356.
Then, the rotating table 302 rotates in 180 degrees around the axis 312 to and stands for a predetermined time so that the sack carton C sucked by the suction cup 304 stands at a position facing the carton setting portion 42 of the index tables 4A and 4B. The opening forming device 6A opens the sack carton C in the time when the sack carton C is standing at said position. After the sack carton C is opened, the suction cup 304 is moved toward the carton setting portion 42 and set therein by the suction cup-driving lever 308. At the same time, the suction cup 306 moves toward the stocker 356 and sucks a sack carton C located at the front of the stocker 356.
A Third EmbodimentAn adhesive-injection inspection system 3300 related to the third embodiment is an example an adhesive-injection inspection system that can be disposed close to hot melt adhesive injecting gun 20 and 22 incorporated in the cartoner 400.
As shown in
As shown in
The light-emitting unit 3302A and the light-receiving unit 3302B are fixed on the base portion 3302C so that a beam emitted from the light-emitting unit 3302A hit a light-receiving device of the light-receiving unit 3302B straightly.
A flange portion 3302D is provided at one end of the base portion 3302C. The flange portion 3302D is fixed on the cartoner 400 at a location close to the hot melt adhesive-injecting gun 20 by bolts 3302E and 3302F. As shown in
As shown in
An optical fiber sensor mount 3304D is fixed at its one end on the cartoner 400 at a location close to the hot melt adhesive-injecting gun 22 by a pair of bolts 3304E at a root portion thereof so that a tip portion thereof extends toward the hot melt adhesive-injecting gun 22. The base portion 3304C is fixed on the tip portion of the optical fiber sensor mount 3304D. At the root portion of the optical fiber sensor mount 3304D, an adjusting bolt 3304F is provided adjacent to the bolts 3304E for adjusting the height of the end portion of the optical fiber sensor mount 3304D on which the base portion 3304C is mounted. By turning the adjusting-bolt 3304F in the clockwise direction or the counter clockwise direction to raise or lower the base portion 3304C, the optical axis of the beam from the light-emitting unit 3304A to the light-receiving unit 3304B can be adjusted to the injection path d.
As shown in
To the analogue input unit 3306A, analogue signal of light reception intensity from the optical sensors 3302 and 3304 is input through the sensor amplifiers 3308 and 3310, respectively.
To the digital input unit 3306B, injection command to the hot melt adhesive injecting guns 20 and 22 (hereinafter, only referred to ‘injection command’) from a controlling computer (not shown) controlling the cartoner 400 is input.
The digital output unit 3306C outputs alarms 1 to 4 (bottom lid) relating to the hot melt adhesive injecting gun 22 and alarms 1 to 4 (upper lid) relating to the hot melt adhesive injecting gun 20 on the command from the COU unit 3306D. These alarms are displayed on an appropriate device such as a display.
The CPU unit 3306D determinates whether hot melt adhesive is normally injected by the hot melt adhesive-injecting guns 20 and 22 on the basis of the analogue signal input to the analogue input unit 3306A and the injection command input to the digital input unit 3306B and controls the digital output unit 3306C to generate the above alarms on the basis of the determination thereof.
In
Schemes for determination and for generating alarms 1 to 4 are described below.
As shown in
When the ‘light reception intensity at light transmittance t1’ is input, the CPU unit determinates whether the light reception intensity is not less than a predetermined value t0 at a step S6.
As shown in
On the contrary, if the light reception intensity at light transmittance t1′ is equal to or lower than the predetermined value t0, the data mean that there is a possibility that the intensity of the light from the light-emitting unit 3302A is too weak, or that there would be some malfunction in the light receiving device of the light-receiving unit 3302B, or that hot melt adhesive has stuck on the light-receiving unit 3302B and the beam from the light-emitting unit 3302A is interfered. There would also be possibly some malfunction in the sensor amplifier 3308 and no analogue signal would not be input from the light-receiving unit 3302B into the analogue input 3306A. Thus, the CPU unit 3306D determinates that there would be some malfunction at least at the light-emitting unit 3302A, the light receiving unit 3302B and the sensor amplifier 3308. Based on said determination by the CPU unit 3306D, the digital output unit 3306C outputs the alarm 3 indicating that the amplifying level of the sensor amplifier 31308 is too low, then, shows the alarm 3 on a display (not shown).
When determining that the optical fiber sensor 3302 and the sensor amplifier 3308 function normally at the step S6, the CPU unit 3306D calculate an average A by averaging previous five data of ‘light reception intensity at light transmittance t1’ at a step S8 and store the average A into a memory.
At the hot melt adhesive injecting guns 20 and 22, there is some lag between the time when a command of injection is input and the time when injection of the hot melt adhesive is actually initiated. Thus, as shown in
As shown in
When determining that both the light-receiving unit 3302B and the hot melt adhesive injecting gun 20 are functioning normally, the CPU unit 3306D calculate an average B by averaging previous five data of ‘light reception intensity at injection t2’ and store the average B in the memory.
Then, at a step S18, the CPU unit 3306D reads the averages A and B out of the memory and determinates a value obtained by adding the average A to the average B and dividing by 2 as a threshold value tv. However, the process for determinating the threshold value tv based upon the average A and the average B is mot limited in the above.
When the threshold value tv is determined at the step S18, the CPU unit 3306D determinates whether the first ‘light reception intensity at injection t2’ is lower than the threshold value. As shown in
When determining that the hot melt adhesive is injected in a sufficient flow, the CPU unit 3306D waits for 10 ms and then, confirms that the injection command is still ON at a step S22. If it is confirmed that the injection command is still ON, at a step S24, the CPU unit 3306D reads out the ‘light reception intensity at injection t2’ through the analogue input unit 3306A and determinates whether the hot melt adhesive is injected in a sufficient flow or not at the step S20. Thus, the CPU unit 3306D repeats the steps S20, S22 and S24 in an order of step S20, step S22 and then step S24. When carrying out the steps S20, S22 and S24 repeatedly, as shown in
When the injection command turns from ON to OFF, the CPU unit 3306D stands without carrying out the next step. After passing 150 ms, which is a time necessary for stopping injecting the hot melt adhesive after the injection command turns OFF, at a step S26, the CPU unit 3306D read out a light reception intensity at the optical fiber sensor 3302 as a ‘light reception intensity at injection stoppage t3’ through the analogue input unit 3306A. At a step S28, the CPU unit 3306D determinates whether the ‘light reception intensity at injection stoppage t3’ is higher than a reference value td, which is determined separately from the predetermined value t0 and has a value closer to the ‘light reception intensity at light transmittance t1’ than the threshold value tv.
As shown in
On the other hand, as shown in
Thus, the scheme of determination and outputting alarms is described. For the hot melt adhesive injecting gun, the CPU 3306 carries out determination and outputting of alarms in the same scheme from input from the optical fiber sensor 304.
According to the adhesive-injection inspection system 3300 of the third embodiment, it can be detected whether hot melt adhesive is normally injected at the hot melt adhesive injecting guns 20 and 22. When hot melt adhesive is not normally injected, alarms are output and the cartoner stops its operation. Thus, it can be prevented that a carton having flap portions C12 not glued to an outside flap C18 and having upper lid C8 left open or a carton having outside flaps C22 not glued to each other and having a bottom lid C10 left open is discharged from the carton discharging portion 14 of the cartoner 400.
Additionally, it can be detected whether cobwebbing does not take place after stopping hot melt adhesive injection and thus, it can be prevented that hot melt adhesive sticks out of an intentioned area of a sack carton C and deteriorate its quality and that the cartoner 400, the hot melt adhesive injecting gun 20 and the hot melt adhesive injecting gun 22 are stained with injected adhesive. It is also prevented that the optical fiber sensors 3302 and 3304 are stained with hot melt adhesive and sensitivity thereof deteriorates.
Further, malfunction of the optical fiber sensors 3302 and 3304 and sensor amplifies 3308 and 3310 can be easily detected.
Furthermore, different alarms are displayed for different malfunction and thus, operators can learn a type of malfunction from the type of displayed alarm and can take an appropriate measure swiftly.
A Fourth EmbodimentAn example of a plastic case packed product supplying unit incorporated in the packaging system of the present invention is described in the following.
A plastic case packed product supplying unit 800 that relates to the fourth embodiment is an example of the plastic case supplying unit 8B in the cartoner 400 and is located above the cartoner 400 as shown in
As shown in
The first plastic case packed product supplying line 830 and the second plastic case packed product supplying line 840 correspond to a first introduction line and a second introduction line included by the packaging object supplying apparatus of the invention. Then, the plastic case packed product arraying portion 810 corresponds to a packaging object combination portion in the packaging object supplying apparatus and further corresponds to a distributing means. The plastic case packed product introducing portion 820 corresponds to a packaging object introduction portion in the packaging object supplying apparatus.
Hereinafter, respective components of the plastic case packed product supplying unit 800 will be described.
1-1 First Plastic Case Packed Product Supplying LineA first plastic case packed product supplying line 830, as shown in
A pusher 835 for pushing the plastic case packed product P carried by the first conveyor to the vertical conveyor 834 is provided between the first conveyor 832 and the vertical conveyor 834.
The first plastic case packed product supplying line 830 includes a folded pipe like plastic case packed product introduction duct 831 for introducing the plastic case packed product manufactured by the winding machine 900 onto the first conveyor 832.
Hereinafter, the structure of the respective components will be described.
(A) First Horizontal Conveyor and Vertical ConveyorThe first horizontal conveyor 832 comprises a belt conveyor portion 832A for carrying the plastic case packed product P and a pair of guide plates 832B which are provided on both sides of the belt conveyor portion 832A for holding the plastic case packed product P from falling. An end portion in the downstream of the first horizontal conveyor 832 has a block type stopper 832C for stopping the plastic case packed product P carried by the belt conveyor portion 832A. The guide plate 832B has a cutout in the vicinity of the stopper 832C in order to prevent the pusher 835 from obstructing pushing of the plastic case packed product P by the pusher 835 to the vertical conveyor 834.
The vertical conveyor 834 includes a belt 834A provided substantially vertically and a shelf plate 834B provided at right angle to the front face of the belt 834A and at a specified interval. A pair of guide plates 834C are provided on both sides of the belt 834A in order to prevent the plastic case packed product P from dropping to the right or the left relative to transporting direction. As shown in
The pusher 835 comprises a pusher member 835A for pushing the plastic case packed product P and an air slider 835B for moving the pusher member 835A in a direction approaching the vertical conveyor 834 and in a direction leaving the vertical conveyor 834.
As shown in
The inclined chute 833 is supplied with plastic case packed products P conveyed by the first horizontal conveyor 832 by the pusher 835 not synchronously with the vertical conveyor.
The self plates 834B are provided in a pitch that one plastic case packed product can be inserted but 2 or more plastic cases cannot be inserted between any two adjacent self plates 834B. Thus, plastic case packed products sliding down the inclined chute 833 is picked up one by one and not synchronously by the vertical conveyor 834.
(B) Plastic Case Packed Product Direction Conversion UnitThe plastic case packed product direction conversion unit 838 includes a chute portion 838A which forms a downward pitch from the vertical conveyor 834 to the second horizontal conveyor 836 as shown in
End portions on the upstream side and downward side relative to the transporting direction of the chute portion 838A are formed in a width enough large to allow the plastic case packed product P carried by the vertical conveyor 834 to pass through in a condition that it lies at right angle to the transporting direction. A plastic case packed product direction conversion unit 838C larger than both ends is formed in the center of the chute portion 838A.
A plastic case packed product direction conversion member 838D, which is a plate-like member provided in parallel to a drop path of the plastic case packed product P, is provided in the plastic case packed product direction conversion portion 838C. The plastic case packed product direction conversion member 838D slides laterally from the center of the chute portion 838A by an pneumatic-slider (air slider) not shown. By a setting signal from a control computer (not shown) for controlling the packaging system 2000 set in accordance with a variety of the plastic case packed products, the plastic case packed product direction conversion member 838D slides toward a predetermined position to control the direction of the plastic case packed product.
A plastic case packed product detecting portion 838E and a plastic case packed product detecting portion 838F for detecting optically whether or not the plastic case packed product P passes are provided at an inlet and an outlet of the plastic case packed product direction conversion portion 838C. The plastic case packed product detecting portion 838E and the plastic case packed product detecting portion 838F are connected to the control computer. If the plastic case packed product detecting portion 838E and the plastic case packed product detecting portion 838F detect any plastic case packed product P, the control computer judges that the plastic case packed product P has passed through the plastic case packed product direction conversion unit 838 normally and continues the operation of the plastic case packed product supplying unit 800. On the other hand, if the plastic case packed product detecting portion 838F does not detect any plastic case packed product P although the plastic case packed product detecting portion 838E detects the plastic case packed product P, the control computer judges that the plastic case packed product direction conversion portion 838C is clogged with the plastic case packed product P and stops the operation of the plastic case packed product supplying unit 800 and the winding machine 900.
The plastic case packed product P carried by the vertical conveyor 834 is introduced into the chute portion 838A of the plastic case packed product direction conversion unit 838 in a condition that it is directed at right angle relative to the transporting direction. As indicated with a solid line in
As shown in
The winding machine 900, as shown in
The plastic case packed product moving unit 920 comprises an arm member 922 having a V shaped plan shape, a plastic case packed product suction portion 924A and a plastic case packed product suction portion 924B, which are provided on both ends of the arm member 922 for sucking the plastic case packed product P. The arm member 922 is fixed to a rotation shaft 926 provided vertically through a V-shaped bottom portion. The rotation shaft 926 is provided so as to be capable of expanding and contracting and rotated by a drive means (not shown). If the rotation shaft 926 is expanded, the arm member 922 rises and if the arm member 926 is contracted, the arm member 922 falls.
(D) Operation of First Plastic Case Packed Product Supplying LineThe plastic case packed product moving unit 920 carries a plastic case packed product P determined to be acceptable by the inspection portion 918 to an intake of the plastic case packed product introduction duct 831 at the same time when the plastic case packed product P located at an end of the plastic case packed product transporting line 916 is moved to the inspection portion 918.
Specifically, as indicated with an arrow in
The plastic case packed product P fallen into the plastic case packed product introduction duct 831 is carried by the first horizontal conveyor 832 and abuts the stopper 832C and stops. The plastic case packed product P which stops because it abuts the stopper 832C is transferred to the vertical conveyor 834 by the pusher 835 and brought upward by the vertical conveyor 834. Then, that plastic case packed product P is turned at 900 by the plastic case packed product direction conversion unit 838, introduced into the second horizontal conveyor 836 and then introduced into the plastic case packed product arraying portion 810 by the second horizontal conveyor 836.
1-2 Plastic Case Packed Product Arraying PortionAs shown in
The plastic case packed product arraying portion 810 comprises a first pusher 812 for supplying a plastic case packed product P supplied from the first plastic case packed product supplying line 830 to the plastic case packed product introducing portion 820, a second pusher 813 for supplying a plastic case packed product P′ supplied from the second plastic case packed product supplying line 840 to the plastic case packed product introducing portion 820, and a base 811 which holds the first pusher 812, the second pusher 813, an outlet portion of the second horizontal conveyor 836 and an outlet portion of the second plastic case packed product supplying line 840 at predetermined positions.
The first pusher 812 is provided at an outlet of the second horizontal conveyor 836 and the second pusher 813 is provided at an outlet of the second plastic case packed product supplying line 840.
The base 811 comprises a base portion 811A extended in a L shape from the second pusher 813 to the first pusher 812 and a pusher supporting portion 811B which supports the outlet portions of the first pusher 812 and the second horizontal conveyor 836. The base portion 811A is provided with a plastic case packed product introduction opening portion 811C for introducing the plastic case packed product P to the plastic case packed product introducing portion 820. A portion between the plastic case packed product introduction opening portion 811C and the second horizontal conveyor 836 at the base portion 811A is formed in a circular shape along a trajectory of the first pusher member 812C, which will be described later, of the first pusher 812 and a guide wall 811D for holding the plastic case packed product P from dropping is provided on an outside edge. A guide wall 811E and a guide wall 811F are provided on both side edge portions between the second plastic case packed product supplying line 840 and the plastic case packed product introduction opening portion 811C at the base portion 811A.
As shown in
An actuator 812E for rotating the arm member 812B is mounted on the other end of the arm member 812B. The actuator 812E is mounted rotatably on the pusher supporting portion 811B through the arm member 812H. Further, an automatic switch 812E2 detecting the rotating position of the arm member 812E is provided on the actuator 812E.
The pusher supporting portion 811B has rotation range setting screw 812J and rotation range setting screw 812K for setting a rotation range of the arm member 812B.
When the arm member 812B is rotated by the actuator 812E, the first pusher member 812C is moved on the base 811 while drawing a circular trajectory so that it is located at a first position adjacent to an end of the second horizontal conveyor 836 or a second position adjacent to the plastic case packed product introduction opening portion 811C. In the meantime, the first position in which the first pusher member 812C is located is indicated with a solid line while the second position in which it is located is indicated with a two-dot chain line in
At a portion of the second horizontal conveyor 836 below the first pusher 812, a stopper 812N retaining plastic case packed products P conveyed by the second horizontal conveyor 836 and a pneumatic slider 812M popping the stopper 812N onto the second horizontal conveyor 836 and retract it therefrom are provided.
Plastic case arrival detecting sensors 812F and 812G photo-electrically detecting the arrival of plastic case packed products Pare provided adjacent to the stopper 812N in the upstream side therefrom so as to have the second horizontal conveyor 836 between the two sensors 812F and 812G.
The second pusher 813 has a second pusher member 813A for pushing the plastic case packed product P′. The second pusher member 813A is reciprocated on the base 811 by an air slider 813B in the direction at right angle to the second horizontal conveyor 836 and then, located at a first position adjacent to an end of the second plastic case packed product supplying line 840 and a second position adjacent to the plastic case packed product introduction opening portion 811C. In the meantime, the first position in which the second pusher 813A is located is indicated with a solid line and the second position is indicated with a two-dot chain line in
The plastic case packed product P carried by the second horizontal conveyor 836 passes between the plastic case packed product stopper wall 811D and the plastic case packed product holding wall 812L and is stopped by being retained by the stopper 812N. Then, the arrival of the plastic case packed product P is detected by the plastic case arrival detecting sensors 812F and 812G and a direction of the plastic case packed product P is detected by a direction-detecting sensor (not shown) provided on the stopper 812N.
If the plastic case arrival detecting sensors 812F and 812G detect the arrival of the plastic case packed product P and the direction-detecting sensor provided on the stopper 812N detects that the plastic case packed product P is in a correct direction, the arm member 812B is rotated in the direction indicated with an arrow in
After the plastic case packed product P drops on the plastic case packed product-introducing portion 820, the arm member 812B is rotated to an opposite direction to the aforementioned arrow, so that the first pusher member 812C is returned to the first position.
On the other hand, if the stopper 812N is opened, the plastic case product P passes between the plastic case packed product stopper wall 811D and the plastic case packed product holding wall 812L, moves into a product-collecting conveyor (not shown) located downstream from the second horizontal conveyor and discharged into a smaller silo (not shown).
While the first pusher 812 is moved from the first position to the second position and returned to the first position again, the plastic case packed product P is carried by the second horizontal conveyor 836. However, because the outlet of the second horizontal conveyor 836 is covered with the plastic case packed product stopper wall 812D if the first pusher 812 is not located at the first position, the plastic case packed product P is stopped before the plastic case packed product arraying portion 810.
If the first pusher 812 is returned to the first position, a next plastic case packed product P located most near the outlet on the second horizontal conveyor 836 is pushed out to the base 811. Then, the plastic case packed product P is pushed by the first pusher member 812C according to the above-described procedure and dropped on the plastic case packed product introduction opening portion 811C.
If a predetermined quantity of the plastic case packed products, for example, three plastic case packed products P are supplied to the plastic case packed product introducing portion 820, a plastic case packed product P′ is supplied to the plastic case packed product introducing portion 820 by the second pusher 813.
The plastic case packed product P′ is carried to the plastic case packed product arraying portion 810 by the second plastic case packed product supplying line 840 and abuts an end face of the second pusher member 813A located at the first position and the guide wall 811F on the base 811, and stopped.
After the plastic case packed product P′ is stopped at the aforementioned position, the second pusher member 813A is moved to the second position indicated with a two-dot chain line in
After the plastic case packed product P′ drops on the plastic case packed product introducing portion 820, the second pusher member 813A is returned to the first position.
While the second pusher member 813A is moved from the first position to the second position and returned to the first position, the plastic case packed product P′ is carried by the second plastic case packed product supplying line 840. However, because the second pusher member 813A covers the outlet of the second plastic case packed product supplying line 840 when it is not located at the first position, the plastic case packed product P′ is stopped before the plastic case packed product arraying portion 810.
The first pusher 812 and the second pusher 813 repeat the above-described operation so as to supply the plastic case packed product P and plastic case packed product P′ to the plastic case packed product introducing portion 820 so as to obtain a predetermined combination.
1-3 Second Plastic Case Packed Product Supplying LineAs shown in
The lift-up conveyor 841 is an elevating conveyor having a width capable of placing five or six plastic case packed products P′ horizontally and its bottom end portion is located near a bottom portion of the plastic case packed product silo 850. It comprises a shelf plate 841A which is provided horizontally and grabs the plastic case packed product P′ from the plastic case packed product silo 850 and a drive chain 841B on which the shelf plate 841A is fixed at a predetermined interval. As shown in
As shown in
A vertical brush 841H is provided along a driving direction of the lift-up conveyor 841 below the horizontal brush 841E on an inner wall of the plastic case packed product silo 850. The vertical brush 841H comprises a brush base 841i fixed in a driving direction of the lift-up conveyor 841 and brush fibers 841J stretched from the brush base portion 841i toward the central portion of the lift-up conveyor 841. The vertical brush 841H has a function of hitting down the plastic case packed product P′ placed on the shelf plate 841A such that it projects from both ends thereof.
A portion of the lift-up conveyor 841 above the plastic case packed product silo 850 is covered with a cover 841K in order to prevent the plastic case packed product P′ grabbed from the plastic case packed product silo 850 from falling from the shelf plate 841A.
(B) Plastic Case Packed Product Arranging PortionAs shown in
As shown in
The inclined chute 843D has side plates 843D2 disposed so that the plastic case packed product P′ can pass between them and a bottom plate 843D4 disposed between the side plates 843D2 and form a bottom of the inclined chute 843D. The bottom of the plastic case packed product P′ is supported by the bottom plate 843D4. Thus, pendulous motion of the plastic case packed product P′ is prohibited and the plastic case packed product P′ smoothly slides down the inclined chute 843D.
A plastic case packed product stopper 843Y for holding the plastic case packed product P′ which slides down on the inclined chute 843D at its bottom end and introduces into the vertical duct 843F at a predetermined time interval is provided at a bottom end of the inclined chute 843D. The plastic case packed product stopper 843Y includes a roller 843Z which presses the plastic case packed product P′ from above and by rotating the roller 843Z at a predetermined time interval, the plastic case packed product P′ is introduced into the vertical duct 843 at the predetermined time interval.
As shown in
The plastic case packed product introduction portion 843A and the plastic case packed product direction conversion arranging portion 843B are partitioned by a movable partition plate 843J. As shown in
As shown in
A pair of the guide plates 843M are provided above the arranging plate 843L and a pair of the guide plates 843N are provided below the arranging plate 843L. An interval between the guide plates 843M is set to a size as large as allows the plastic case packed product P′ to be passed through and the an interval between the guide plates N is set substantially equal to the interval between the arranging plates 843L.
As shown in
As shown in
Because in the lift-up conveyor 841, the drive chain 841B is rotated clockwise in
After the plastic case packed product P′ carried upward by the lift-up conveyor 841 is introduced into the plastic case packed product introduction portion 843A, the movable partition plate 843J is moved so that the plastic case packed product introduction portion 843A communicates with the plastic case packed product direction conversion arranging portion 843B as shown in
Next, if the discharge conveyor 843C is rotated counterclockwise in
The plastic case packed product P′ introduced to the inclined chute 843D slides down to a bottom end portion of the inclined chute 843D in a condition that its lid portion is directed upward and introduced to the vertical duct 843F at a predetermined interval by the plastic case packed product stopper 843Y. Therefore, the plastic case packed product P′ is introduced into the vertical duct 843F in such a condition that its main body reaches it earlier than its lid portion. Then, it is introduced into the arrangement transporting conveyor 843E with this posture. Therefore, as shown in
The plastic case packed product P′ is carried by the arrangement transporting conveyor 843E with the aforementioned posture and abuts the stopper 843X and stopped. Then, the plastic case packed product P′ stopped by the stopper 843X is introduced to the vertical conveyor 842 by the pusher 843G in a condition that its transporting direction is maintained by the arrangement transporting conveyor 843E. Because the transporting direction of the vertical conveyor 842 is at right angle to the transporting direction of the arrangement transporting conveyor 843E, the plastic case packed product P′ introduced to the vertical conveyor 842 is held horizontally and carried upward with its lid portion directed in a specific direction.
The plastic case packed product P′ lifted up by the vertical conveyor 842 is turned in its direction by the plastic case packed product direction conversion unit 844 and introduced into the horizontal conveyor 845 such that its axial direction is along the transporting direction. Here, the plastic case packed product direction conversion unit 844 has the same structure as the plastic case packed product conversion unit 838 in the first plastic case packed product supplying line 830. Therefore, in the plastic case packed product direction conversion unit 844, the plastic case packed product P′ introduced from the vertical conveyor 842 is introduced to the horizontal conveyor 845 such that its main body is directed to the transporting direction and carried to the plastic case packed product arraying portion 810.
1-4 Plastic Case Packed Product Supplying PortionAs shown in
The plastic case packed product introducing portion 820 has a plate-like base 821 erected vertically on a floor face and the plastic case packed product chute 822, the transporting conveyor 824, the transfer portion 826 and the direction detecting portion 827 are fixed at predetermined positions on the base 821. The plastic case packed product chute 822, the transporting conveyor 824, the transfer portion 826, and the direction detecting portion 827 correspond to the packaging object drop chute, the packaging object transporting means, the transfer means and the direction detection means includes by the packaging object supplying apparatus of the invention.
Respective components of the plastic case packed product introducing portion 820 will be described in detail as follows.
(A) Plastic Case Packed Product ChuteThe plastic case packed product chute 822 has a zigzag-like path 822A inclined at a gradient of 30° downward. The plastic case packed product introduction opening portion 811C provided in the plastic case packed product arraying portion 810 communicates with an opening portion at a top end of the path 822A. The plastic case packed product P and plastic case packed product P′ introduced from the plastic case packed product introduction opening portion 811C are introduced into the path 822A from the top end opening portion and naturally drops onto the transporting conveyor 824 with a condition that it is loaded in the path 822A without any gap as shown in
The transporting conveyor 824 is a belt conveyor for transporting the plastic case packed product P and the plastic case packed product P′ by means of an iron rubber belt 824A. The iron rubber belt 824A has partitions 824B provided at a specified interval, so that the plastic case packed product P and the plastic case packed product P′ are held between the adjacent two partitions. The iron rubber belt 824A is held by three driven pulleys fixed on the base 821 and a drive pulley 824D driven by a motor M and rotated clockwise as indicated with an arrow in
The guide plates 824F for guiding the plastic case packed product P(P′) from falling are provided on both sides of the transporting conveyor 824. The guide plate 824E located in the closer side relative to the surface of
A transporting failure detecting portion 823 for detecting whether or not the plastic case packed product P(P′) is being transported normally by the iron rubber belt 824A is provided between the plastic case packed product chute 822 and the transporting conveyor 824. The guide plate 824E located in the further side relative to the surface of
Additionally, as shown in
As shown in
The first failure detecting portion 823A, as shown in
As shown in
When the plastic case packed product P (P′) is being transported normally on the transporting conveyor 824, in the first failure detecting portion 823A, the arm member 823C urged in a direction rotating downward by the spring 823E is held at a position indicated with a solid line in
If there takes place a transporting failure such that a plastic case packed product P (P′) is transported with placing on two adjacent plastic case packed products P (P′) carried by the transporting conveyor 824, as indicated with a two-dot chain line in
On the other hand, when no plastic case packed product P (P′) exists between the two adjacent partitions 824B of the transporting conveyor 824 or a plastic case packed product P (P′) without a lid is transported, as indicated with a two-dot chain line in
If at least one of the first failure detecting portion 823A and the second failure detecting portion 823B detects any transporting failure, the transporting failure detecting portion 823 inputs a relating signal into the control computer. If the aforementioned signal is inputted into the control computer, the entire plastic case packed product supplying unit 800 is stopped.
(C) Direction Detecting PortionThe direction detecting portion 827, as shown in
As shown in
The dog position detecting sensor 827K is comprised of a light shielding element 827i and a light projecting/receiving element 827 J and the light shielding element 827i is fixed on a rear end portion of each probe portion 827E through a mounting plate 827H and the light projecting/receiving element 827J is fixed on the direction detecting base 827B. The light projecting/receiving element 827i comprises a light emission device and a light receiving device for receiving light from the light emission device and the light emission device and the light receiving device are provided at positions opposing each other. The light shielding element 827i is a plate-like member entirely having a U-like or inverted U like plan shape as shown in
The direction determining dog 827A has a pair of guide rods 827L which slides inside the guide member 827D for guiding the direction determining dog 827A in a direction approaching/leaving the transporting conveyor 824. An end of the guide rod 827L is fixed on the base 827F and the other end is fixed on a plate-like guide rod fixing member 827M.
As shown in
The direction determining dog 827A is located at a position far from the plastic case packed product P (P′) at standby time as shown in
When determining the direction of the plastic case packed product P(P′), the direction determining dog 827A is advanced toward the plastic case packed product P(P′) being carried by the transporting conveyor 824 as shown in
Because the light shielding element 827i is advanced if the direction determining dog 827A is advanced, light from the light emission device is detected by the light receiving device in the light projecting/receiving element 827J. However, if the direction determining dog 827A is advanced to its maximum extent, no light is detected because the light projecting/receiving element 827J is shielded by the light shielding element 827i again as shown in
Because a circular groove is provided in the lid of the plastic case packed product P(P′), when the lid of the plastic case packed product P (P′) is directed to the direction determining dog 827A, a periphery of the cup portion 827E2 is engaged with the groove in the id of the plastic case packed product P(P′) if the direction determining dog 827A is advanced as shown in
On the other hand, when the bottom side of the plastic case packed product P(P′) is directed to the direction determining dog 827A, if the direction determining dog 827A is advanced as shown in
By advancing the direction determining dog 827A toward the transporting conveyor 824 in the direction detecting portion 827 and then checking whether or light detection is achieved in the light projecting/receiving element 827J provided on each probe portion 827E, the direction of the plastic case packed product P(P′) can be determined.
If dragging occurs between the shaft portion 827E4 and the bearing member 827G, when the direction determining dog 827A is retracted to the maximum extent as shown in
By retracting the direction determining dog 827A to the maximum extent after the direction of the plastic case packed product P(P′) is determined and checking whether or not light detection is achieved in the light projecting/receiving element 827J, it is possible to see whether or not dragging occurs between the shaft portion 827E4 and the bearing member 827G.
(D) Transfer Portion and Nest PortionAs shown in
Two rotation shafts 826E for pivoting the sending side opening/closing guide 826B are provided vertically at a front end of the base 826A. Each of the sending side opening/closing guide 826B is fixed to the rotation shaft 826E through the arm member 826F. Taper is provided on an outside face at an end of a side on which the sending side opening/closing guide 826B is fixed of the arm member 826F such that it narrows as it goes toward its front end. A coil spring 826G for urging the arm member 826F in a direction opening the sending side opening/closing guide 826B is provided at an end portion opposite to the side on which the sending side opening/closing guide 826B is fixed of the arm member 826F. A guide opening/closing restriction member 826H which engages with the lower base 826A for restricting an opening size of the sending side opening/closing guide 826B is fixed on a bottom end portion of the rotation shaft 826E. The guide opening/closing member 826D, the arm member 826F and the coil spring 826G correspond to the guide opening/closing means.
The transfer portion 826 comprises a pusher advancing/retracting crank 826i for advancing/retracting the plastic case packed product pusher 826C toward the nest portion 828 and a guide opening/closing member advancing/retracting crank 826J for advancing/retracting the guide opening/closing member 826D to/from the nest portion 828. A motion of the pusher advancing/retracting crank 826i is transmitted to the plastic case packed product pusher 826C through a pair of the rods 826L and a linking rod 826K. Similarly, the motion of the guide opening/closing member advancing/retracting crank 826J is transmitted to the guide opening/closing member 826D through the linking rod 826M. In the meantime, the rod 826L is guided by a cylindrical guide 826P fixed to a guide supporting member 826N provided vertically between upper and lower bases 826A in a direction advancing/retracting to/from a sending side opening/closing guide 826B. A linking rod mounting member 826Q is fixed on a terminal of the rod 826L and the linking rod 826K is mounted rotatably on the linking rod mounting member 826Q. An end of the coil spring 826R for urging the plastic case packed product pusher 826C to the nest portion 828 is fixed on the linking rod mounting member 826Q.
As shown in
The receiving side opening/closing guide 828A is pivoted by the rotation shaft 828B between the upper table 400A and the lower table 400B. The receiving side opening/closing guide 828A is fixed on the rotation shaft 828B by the arm member 828C. A cam follower member 828D is fixed on a bottom end portion of the rotation shaft 828B such that when the guide opening/closing member 826D included by the transfer portion 826 advances to abut the cam follower member 828D, the same cam follower member 828D is opened outward to the transfer portion 826. A coil spring 828E for urging the receiving side opening/closing guide 828A in a closing direction is provided on each of an end on a side on which the receiving side opening/closing guide 828A is fixed of the arm member 828C and an end on its opposite side.
As shown in
Because when the transfer portion 826 is in its standby condition, as shown in
If with this condition, a predetermined quantity of the plastic case packed products P(P′) are sent from the direction detecting portion 827 above and introduced into the inside of the sending side opening/closing guide 826B, the guide opening/closing member 826D is advanced to the nest portion 828. Referring to
When the guide opening/closing member 826D is advanced, the arm member 826F is opened outward by an urging force from the coil spring 826Gas shown in
When the guide opening/closing member 826D is advanced further from the position shown in
When the receiving side opening/closing guide 828A is opened outward, the plastic case packed product pusher 828C is advanced to the nest portion 828 as shown in
If the plastic case packed product P (P′) is transferred to the nest portion 828, the guide opening/closing member 826D is retracted to a position shown in
The plastic case packed product P and plastic case packed product P′ arrayed by the plastic case packed product arraying portion 810 in a predetermined array pass through the plastic case packed product introduction opening portion 811C and are introduced into the path 822A from a top end opening portion of the plastic case packed product chute 822 and finally drops to the transporting conveyor 824 in a condition the path 822A is filled there with without any gap as shown in
The plastic case packed product P and plastic case packed product P′, after fall naturally from the plastic case packed product chute 822, are transported to the direction detecting portion 827 by the transporting conveyor 824 in a condition in which they are loaded in every interval between the partitions 824B of the transporting conveyor 824.
If the direction detecting portion 827 recognizes that the plastic case packed product P and plastic case packed product P′ are arranged in a predetermined array order, for example, they forms a group of four pieces arranged like “PPP′P”, they are transported to the transfer portion 826 by the transporting conveyor 824. Here, “P” indicates plastic case packed product P while “P′” indicates plastic case packed product P′.
Then, the group of the plastic case packed product P(P′) is transferred to the nest portion 828 at the transfer portion 826, it is loaded in the sack carton by the cartoner 400.
1-5 Operation of Entire SystemThe plastic case packed product P manufactured by the winding machine 900 is transported to the plastic case packed product arraying portion 810 by the first plastic case packed product supplying line 830. At the same time, the plastic case packed product P′ accommodated in the plastic case packed product silo 850 is also transported to the plastic case packed product arraying portion 810 by the second plastic case packed product supplying line 840.
In the plastic case packed product arraying portion 810, the plastic case packed product P from the winding machine 900 and plastic case packed product P′ from the plastic case packed product silo 850 are transported to the plastic case packed product introducing portion 820 in a predetermined order, for example, in an array of four pieces like “PPPP′P”.
The plastic case packed product introducing portion 820 transfers the plastic case packed product P and plastic case packed product P′ to the cartoner 400 in a predetermined array. Therefore, in the cartoner 400, the plastic case packed product P and plastic case packed product P′ are inserted into the sack carton in an order of four piece of “PPP′P”.
In the plastic case packed product supplying unit of the fourth embodiment, as described above, the plastic case packed product P manufactured by the winding machine 900 and plastic case packed product P′ accommodated in the plastic case packed product silo 850 are automatically combined in a predetermined array and supplied to the cartoner 400 and then packed in the sack carton.
A Fifth EmbodimentAn example of the packaging system according to the invention will be described below.
1. Configuration of Packaging SystemThe packaging system 2000 of the fifth embodiment, as shown in
The winding machine 900 manufactures a plastic case packed product P which is an example of a case incorporated film of the invention by making perforations in a side edge portion of a long film according to an instruction from the control computer 500, cutting a photographic film having perforations to a predetermined length, winding this photographic film around a spool, accommodating the spool around which the photographic film is wound in a cartridge, and accommodating the cartridge in a plastic made film case.
The plastic case packed product transporting supplying unit 800 has a function of supplying the plastic case packed products manufactured by the winding machine 900 to the cartoner 400 in a condition in which they are arranged in line. Additionally, it has a function of combining the plastic case packed product P manufactured by the winding machine 900 with another plastic case packed product P having a different quantity of photographable frames or a different photographic film appropriately, arraying them in a predetermined pattern and supplying to the cartoner 400. In any case, the plastic case packed product transporting supplying unit 800 supplies the plastic case packed product P manufactured by the winding machine 900 to the cartoner 400 without any deposit between the winding machine 900 and the cartoner 400. Here, “without any deposit between being manufactured and being packaged” means that a plastic case packed product P manufactured ahead by the winding machine 900 is always supplied to the cartoner 400 ahead of a plastic case packed product manufactured after (first in and first out). In other words, the plastic case packed product P is always supplied to the cartoner 400 in their manufacturing order.
The cartoner 400 manufactures a carton 700 by packing the plastic case packed products manufactured by the winding machine 900 into a sack carton.
In the carton arraying unit 1100, a predetermined quantity of the cartons 700 are arrayed in a predetermined form so as to form a carton assembly 720. If the aforementioned carton 700 is a type which should be subjected to shrink packaging, the carton assembly 720 is carried on the shrink packaging unit 1200 and if the carton 700 is a type which is not subjected to shrink packaging, the carton assembly 720 is transported directly to the corrugated board casing unit 1300.
The shrink packaging unit 1200 is provided adjacent to the carton arraying unit 1100 and has a function of forming a shrink-wrapped package 740 by shrink-packaging the carton assembly 720 transferred from the carton arraying unit 1100 and then transporting this to the corrugated board casing unit 1300.
The corrugated board casing unit 1300 has a function of packing the carton assembly 720 transported from the carton arraying unit 1100 or the shrink-wrapped package 740 transported from the shrink packaging unit 1200 in a corrugated board box in a predetermined fashion. Here, the carton 700 corresponds to the small box package under the invention, the carton assembly 720 corresponds to the small box assembly under the invention, and the shrink-wrapped package 740 corresponds to the shrink-wrapped package under the invention.
The control computer 500 has a function of controlling the carton arraying unit 1100, the shrink packaging unit 1200, the corrugated board casing unit 1300, the cartoner 400, the plastic case packed product transporting supplying unit 800 and the winding machine 900 according to a production plan inputted from the a host computer.
Hereinafter the carton arraying unit 1100, the shrink packaging unit 1200, the corrugated board casing unit 1300, the cartoner 400, the plastic case packed product transporting supplying unit 800 and the winding machine 900 will be described in detail.
1-1 Winding MachineThe winding machine 900, as shown in
The film feeding portion 902 comprises a film roll portion 902A in which a film roll R around which a long photographic film F is wound and a film joining portion 902B for joining together a terminal of the fed film roll R with a front end of a new film roll R.
The perforating portion 904 comprises a die block 904A fixed below a transporting plane for transporting the photographic film and a punch block 904B capable of rising/falling relative to the die block 904A. An intermittent feeding roller 904C is disposed on the upstream side (hereinafter referred to as “upstream side”) and the downstream side (hereinafter referred to as “downstream side”) along the transporting direction of the photographic film of each of the die block 904A and the punch block 904B and a suction chamber 904D is disposed below the die block 904A.
The side print portion 906 comprises a constant velocity transporting roller 906C disposed on the upstream side, a first print portion 906A disposed corresponding to the constant velocity transporting roller 906C, a constant size transporting sprocket 906D disposed on the downstream side relative to the constant velocity transporting roller 906C and a second print portion 906B disposed corresponding to the constant size transporting sprocket 906D.
The cutting portion 908 includes a movable blade 908A and a fixed blade 908B disposed so as to oppose each other vertically across the transporting path of the photographic film F. A nip roller 908C is disposed in the downstream of the movable blade 908A and the fixed blade 908B.
The winding portion 910 comprises a turn table 910A for winding the photographic film F around a spool, a transfer turn table 910B adjacent to in the downstream the winding turn table 910A, a transfer unit 910C provided adjacent to in the downstream the transfer turn table 910B and for transferring a spool around which the photographic film F is wound to the cartridge loading portion 912 and a pair of insert rollers 910E, 910F located on the upstream side of the winding turn table 910A. A guide plate 910K and an opening/closing guide plate 910L are provided between the pair of the insert rollers 910E and 910F, and between the pair of the insert rollers 910E and the winding turn table 910A. Further, a guide plate 910M is provided between the nip roller 908C and the pair of insert rollers 910F.
The winding turn table 910A is a disc rotating clockwise in
The transfer unit 910C comprises a horizontal arm member 910H rotating vertically around a rotation axis and a spool holding portion 910J provided on both ends of the horizontal arm member 910H.
The cartridge loading portion 912 includes a disc like turn table 912A in which cartridge holding portions 912B for holding a cartridge are formed at an equal interval on a periphery thereof.
In the winding machine 900, all its components except the case packing portion 914 are accommodated in a dark room so as to protect the photographic film F from outside light.
In the winding machine 900, a film roll R around which a photographic film of a predetermined type, for example, ISO400 or ISO800 is wound is automatically loaded on a film roll portion 902A of the film feeding portion 902. Then, the photographic film F is fed from the film roll R at a predetermined velocity.
The photographic film F fed from the film feeding portion 902 is fed intermittently by an intermittent feeding roller 904C and pressed against the die block 904A by a suction force of the suction chamber 904D. Therefore, the punch block 904B goes up and down relative to the die block 904A, so that perforations are formed on both side edges of the photographic film at a specified interval.
The photographic film F, after the perforations are formed by the perforating portion 904, is sent to the side print portion 906. Then, a belt-like side print latent image is formed depending on its film type on one or both side edge portions of the first print portion 906A and such latent images as a DX code, frame number figure, frame number code, product name are recorded depending on a film size of the photographic film F on the second print portion 906B.
On the other hand, in the spool supplying station ST1 of the winding portion 910, a spool is mounted on the spool holding means 910D of the winding turn table 910A.
If the spool is mounted on the spool holding means 910D, the winding turn table 910A rotates by 60° clockwise and then, a preliminary positioning of the spool is carried out by the spool positioning station ST2. Then, the winding turn table 910A rotates further by 60° clockwise so as to send the spool to a film end insertion station ST3.
If the film end insertion station ST3 is sent to the spool, an opening/closing guide plate 910L is closed so as to form a film path for the photographic film F to pass through and at the same time, the spool is nipped at ST3, so that final positioning of the spool is carried out mechanically to prepare for insertion of the photographic film.
After the predetermined latent images are formed, the photographic film F is sent to the film end insertion station ST3 by the nip roller 908C, a pair of the insert rollers 910E and a pair of the insert rollers 910F, then guided by the guide plate 910K, the opening/closing guide plate 910L and the guide plate 910M through a specified path and an end of the photographic film F is inserted into the spool located at the film end insertion station ST3.
When the end of the photographic film F is inserted into the spool in the film end insertion station ST3, the guide plate 910M is opened and the photographic film F is fed by a specified length to the turn table 910A by the nip roller 908C. Consequently, as shown in
After the photographic film F is cut, the nip roller 908C, a pair of the insert rollers 910F, a pair of the insert rollers 910E and the guide plates 910K, 910L are released and the winding turn table 910A rotates further by 60° so as to carry the spool to the preliminary winding station ST4. Then, the cut photographic film F is hung above the film guide 910G.
The photographic film F is wound up to hallway in the preliminary winding station ST4. If the photographic film is wound up to halfway without any abnormality, the winding turn table 910A rotates further by 60° and the spool moves to the winding station ST5. Then, it is wound on the spool completely in the winding station ST5.
When the winding in the winding station ST5 is terminated, the winding turn table 910A rotates further by 60° so that the spool in which the photographic film F is wound is moved to the transfer station ST6. In the transfer station ST6, it is transferred to the transfer turn table 910B in a horizontal condition.
The transfer turn table 910B rotates counterclockwise in
In the transfer unit 910C, the spool received from the transfer turn table 910B is moved to the cartridge loading portion 912 in a condition that it is held by the spool holding portion 910J.
In the cartridge loading portion 912, a half open cartridge is loaded in the cartridge holding portion 912B. The spool transferred by the transfer unit 910C is loaded into the half open cartridge in the cartridge holding portion 910B. A cartridge cap is loaded in a remaining opening portion of the half open cartridge in which the spool is loaded and then crimped so as to form a cartridge.
The cartridge formed in this way is placed on the transfer conveyor 912C as indicated with an arrow in
The constitution and the operation of the plastic case packed product transporting supplying unit 800 are the same as described in the fourth embodiment.
1-3 CartonerThe cartoner 400 packages the plastic case packed products P (and different type plastic case packed product P′) supplied from the plastic case packed product transporting supplying unit 800 into the inside of the sack carton 710, which is a foldable box body having an opening portion and a flap portion forming a lid portion for covering the opening portion on each of both ends thereof as shown in
As shown in
The carton supplying unit 402, the rotation table 404, the carton opening forming portion 406, the plastic case packed product loading portion 408, the upper lid constructing portion 410, the lower lid constructing portion 412, and the carton discharging portion 414 are the same as the carton supplying unit 2, the rotation table 4, the carton opening forming portion 6, the plastic case-packed product packing portion 8, the upper lid constructing portion 10, the lower lid constructing portion 12, and the carton discharging portion 14 of the cartoner relating to the fifth embodiment, respectively.
1-4 Carton Arraying UnitAs shown in
As shown in
Because the cartoner 400 changes over the type of the plastic case packed product with the top face of the carton 700 as a reference level as shown in
The frame body 1102B of the first conveyor 1102 is mechanically joined to the lower conveyor 414A so that it ascends or descends interlockingly with the lower conveyor 414A. Then, the belt conveyor 1102A is held such that the top face thereof coincides with the top face of the lower conveyor 414A.
Because the frame body 1102B goes up and down interlockingly with the lower conveyor 414A and the belt conveyor 1102A goes up and down accompanied therewith, feeding of the carton 700 from the cartoner 400 is carried out smoothly when the lower conveyor 414A is high or low.
The belt conveyor 1102A comprises a drive roller 1102E, four driven rollers 1102F, and a belt 1102D wound around the drive roller 1102E and the driven roller 1102F. The drive roller 1102E is driven by a drive motor 1102G. Of the four driven rollers 1102F, two ones are located at end portions of the upstream side and downstream side of the belt conveyor 1102A while the remaining two ones are located near the drive roller 1102E. The belt 1102D is formed of material having a small friction coefficient. The carton 700 sent from the cartoner 400 is placed on the top face of the belt conveyor 1102A.
The frame body 1102B comprises a frame plate 1102H located at a position backward relative to this paper in
As shown in
A guide plate 1102M having a C-shaped section is fixed on a top edge of the frame plate 1102H. On the other hand, a guide plate 1102N is erected on a side opposite to the guide plate 1102M across the belt conveyor 1102A. As shown in
As shown in
The cutter stopper 1102U and the cutter holder 1102S are driven by the air slide table 1102T in a direction projecting or retracting over/from the belt conveyor 1102A through the guide plate 1102M.
The cutter stopper 1102U is located on the downstream side in the transporting direction a (hereinafter referred to as “downstream side”) of the belt conveyor 1102A with respect to the cutter holder 1102S.
The cutter stopper 1102U has a function of stopping the carton 700 at a position allowing a bar code attached to the carton 700 to be read by a bar code reader 1102Q, which will be described later.
On the other hand, the cutter holder 1102S has a function of holding a carton located in the upstream to the carton 700 stopped by the cutter stopper 1102U to prevent it from moving to the downstream side in cooperation with the guide plate 1102N.
A bar code reader 1102Q is provided at a position opposing the air slide table 1102T across the belt conveyor 1102A and a metal detector 1102P and a positioning sensor 1102R are provided on the downstream side of the bar code reader 1102Q.
The bar code reader 1102Q has a function of reading a bar code attached to the carton 700 to detect for a mixture of a different type carton.
The metal detector 1102P has a function of detecting whether or not a predetermined quantity of the plastic case packed products are packed in the carton 700.
1-4-B Second ConveyorThe second conveyor 1104 has a function of arraying the cartons 700, which are carried by the first conveyor 1102 and turned at 90° or 180° around the Y axis by the first robot, which will be described later so as to form a carton assembly 720 in which a predetermined quantity of the cartons 700 are arrayed in a predetermined style.
The second conveyor 1104, as shown in
As shown in
The belt conveyor 1104A′ and belt conveyor 1104A″ comprise belt 1104D′ and belt 1104D″, drive roller 1104E′ for driving the drive roller 1104D′ and drive roller 1104E″ for driving the belt 1104D″, and a driven roller 1104F′ holding the belt 1104D′ and a driven roller 1104F″ holding the belt 1104D″, respectively. The drive roller 1104E′ and the drive roller E″ are driven by the drive motor 1104G. Because as shown in
The drive roller 1104E′ and drive roller 1104E″ and the driven roller 1104F′ and driven roller 1104F″ are pivoted by a frame plate on a side opposing the first robot 1112 of the frame plates which form the frame body 1104B.
An arraying portion 1104H for arraying the cartons 700 is formed on the downstream side of the belt conveyor unit 1104A, that is, near the third conveyor 1106 and an introduction portion 1104i for introducing the carton 700 is formed near the upstream side of the arraying portion 1104H.
As shown in
As shown in
A pin 1104L is provided between the belt conveyor 1104A′ and the belt conveyor 1104A″ at a portion provided with the move guide plate 1104J of the belt conveyor unit 1104A. As shown in
As shown in
The introduction portion 1104i has a stopper plate 1104Q, which is provided on the belt conveyor 1104A and capable of projecting/retracting along the width direction of the belt conveyor unit 1104A. The guide plate 1104C has an opening portion which allows the stopper plate 1104Q to pass through. The stopper plate 1104Q is moved along the aforementioned direction by the air slide table 1104R.
As shown in
The third conveyor 1106 has a function of sorting the carton assemblies 720 formed by the second conveyor to ones which should be transported to the shrink packaging unit 1200 and ones which should be transported directly to the corrugated board casing unit 1300.
As shown in
The belt conveyor 1104A comprises a drive roller 1106E, four driven rollers 106F and a belt 1106D which is wound around the drive roller 1106E and the driven roller 1106F. The drive roller 1106E is driven by a drive motor 1106G. The drive roller 1106E and the driven roller 1106F are pivoted by the frame plate 1106B in a cantilever style. A drive motor 1106G for driving the drive roller 1106E is fixed on a face on a side opposite to the side in which the drive roller 1106E and the driven roller 1106F are pivoted of the frame plate 1106B.
A guide plate 1106H having a C-shaped section is fixed on a top face of the frame plate 1106B.
A carton arranging plate 1106i is provided at an end portion on the upstream side of the third conveyor 1106, this carton arranging plate 1106i pressing the cartons 700 at right angle to the transporting direction after introduced in a condition that they are arrayed by the arraying portion 1104H of the second conveyor 1104 in parallel to the guide plate 1106H across the belt conveyor 1106A so as to arrange the cartons in line. As shown in
An opening portion which allows two stoppers 1106K and 1106L to project over the belt conveyor 1106A is provided at an end on the downstream side of the carton arranging plate 1106i.
The stoppers 1106K and 1106L have a function of holding any introduced carton 700 from being pushed from the upstream side and moved to the downstream side and are projected or retracted at right angle to the moving of the belt conveyor 1106A by the air slide table 1106M and the air slide table 1106N.
The guide plate 1106C is erected adjacent to the carton arranging plate 1106i and in the downstream thereof. The guide plate 1106C has an inverted L shaped section, so that a gap which allows the header 704 of the carton 700 to pass through is formed between the guide plate 1106C and the belt conveyor 1106A.
1-4-D Fourth ConveyorThe fourth conveyor 1108 has a function for transporting the carton assemblies 720 sorted to the ones which should be carried directly to the corrugated board casing unit 1300 by the third conveyor 1106, to the fifth conveyor 1110.
1-4-E Fifth ConveyorThe fifth conveyor 1110 has a function of recognizing the quantity of the carton assemblies 720 transported by the fourth conveyor 1108 and arranging in line the carton assemblies 720 for the product loading robot loading robot 1302 of the corrugated board casing unit 1300.
As shown in
The belt conveyor 1110A comprises a belt 1110D, a driving roller 1110E for driving the belt 1110D and a driven roller 110F for holding the belt 1110D. The driving roller 1110E is driven by the drive motor 1110G.
A guide wall 1110H and a guide wall 1110i are erected on both sides of the belt conveyor 1110A. The guide wall 1110H and the guide wall 1110i are guides for preventing the carton assembly 720 carried by the belt conveyor 1110A from dropping from the belt 1110D. A gap is formed between the guide wall 1110H and the belt conveyor 1110A to allow the header 704 to pass through when the carton 700 having the header 704 is transported. A pair of the carton pressing plates 1110J are provided on an end portion on a side in which the carton arranging portion 1110B is provided of the belt conveyor 1110A instead of the guide wall 1110H and the guide wall 1110i such that they sandwich the belt conveyor 1110A. The carton pressing plate 1110J has a function of arranging the carton assemblies 720 transported by the belt conveyor 1110A along the width direction by pressing from both sides and is capable of being moved by an air slide unit 1110K and an air slide unit 1110K′ provided so as to oppose each other across the belt conveyor 1110A along a direction at right angle to the transporting direction of the carton assembly 720. A table 1110S for storing the carton assemblies 720 arranged by the carton pressing plate 1110J temporarily is provided on the left side of the carton pressing plate 1110J with respect to the advancement direction in
The carton detecting portion 1110C comprises five light emission portions 110L erected on a top edge of the guide wall 1110H along the transporting direction of the carton 700, a carton detecting unit 1110N which is provided on the upper edge of the guide wall 1110i and constituted of a light-receiving unit 1110M for receiving light from each light emission portion 1110L and a stopper plate 1110P provided adjacent to the downstream side of the carton detection unit 110N. The stopper plate 1110P is moved by the air slide unit 1110Q in the direction at right angle to the transporting direction of the carton assembly 720, projected over the belt conveyor 1110A through a slit-like opening portion formed in the guide wall 1110i and then pulled outward of the belt conveyor 1110A through the opening portion. A carton detecting sensor 1110R for detecting whether or not a predetermined quantity of the cartons, for example, five cartons exist in the carton detecting portion 1110C photo-electrically is provided adjacent to the light emission portion 1110L and light-receiving unit 1110M on the highest upstream.
Adjacent the upstream side of the carton detecting sensor 1110R are provided a carton holding unit 1110T capable of projecting/retracting the belt conveyor 1110A and an air slide unit 110U for moving the carton holding unit 1110T in the direction at right angle to the transporting direction of the carton 700. The carton holding unit 1110T has a function of holding the sixth carton if counted from the downstream side not so as to be carried to the downstream side in cooperation with the guide wall 1110H and introducing only a predetermined quantity, for example, five cartons 700 into the carton arranging portion 1110B.
When the carton assemblies 720 sorted to the one which should be transported directly to the corrugated board casing unit 1300 on the third conveyor 1106 are transported on the fourth conveyor 1108 and the fifth conveyor 1110, the stopper plate 1110P on the fifth conveyor 1110 is ejected on the belt conveyor 1110A as indicated with a two-dot chain line in
The carton assembly 720 carried by the fourth conveyor 1108 and the fifth conveyor 1110 abuts the stopper plate 1110P and is stopped at the carton detecting unit 1110N. The carton detecting unit 1110N detects whether or not the transported carton 700 is located properly in the vertical direction depending on which light from the light emission portion 1110L is received by the light-receiving unit 1110M or interrupted.
If the carton detecting sensor 1110R detects that the fifth carton 700 is carried to the carton detecting unit 1110N, the stopper plate 1110P is retracted as indicated with a solid line in
The carton assembly 720 is pressed from both sides by the carton pressing plate 1110J at the carton arranging portion 1110B so as to eliminate a disorder in the direction at right angle to the transporting direction. At the same time, the carton assembly 720 is positioned. When the carton assembly 720 is formed by stacking two carton groups each composed of five cartons 700 vertically, after the first carton group is carried to the carton arranging portion 1110B, that carton group is sandwiched by the carton pressing plate 1110J and moved in the direction at right angle to the transporting direction and then placed on the table 1110S so as to inhibit from obstructing an introduction of the second carton group to the carton arranging portion 1110B.
1-4-F First RobotThe first robot 1112, as shown in
The suction/rotation portion 1112A comprises a suction portion 1112E having a sucker 1112D for sucking and holding the side face of the carton 700, and abase 1112F which holds the suction portion 1112E such that it is rotatable around the Y-axis with respect to its central point.
The Z-axis guide portion 1112B comprises a guide rail 1112G erected vertically and a guide block 1112H movable vertically in engagement with the guide rail 1112G. The guide block 1112H is moved through a ball screw provided vertically within the guide rail 1112G. The suction/rotation portion 1112A is fixed on the guide block 1112H.
The X-axis guide portion 1112C comprises a guide rail 1112i provided in parallel to the first conveyor 1102, a traveling base 1112J which travels in the direction of the X-axis in engagement with the guide rail 1112i, and an air slide table 1112K which is fixed on the traveling base 1112J for holding the guide rail 1112G on the Z-axis guide 1112B. The guide rail 1112G is held vertically by the air slide table 1112K and moved in directions of approaching/leaving the first conveyor 1102 in the direction of the Y-axis.
If the positioning sensor 1102R provided on the first conveyor 1102 detects a carton 700, the Z-axis guide 1112B, the X-axis guide portion 1112C and the air slide table 1112K are actuated, so that the suction/rotation portion 1112A approaches the carton 700. The sucker 1112D of the suction/rotation portion 1112A adheres to the side face of the carton 700 by suction. After the sucker 1112D adheres to the side face of the carton 700 by suction, the base 1112E is rotated by 90° or 180° or not rotated according to an instruction from the control computer 500, moved in the height direction by the Z-axis guide 1112B and at the same time, moved by the X-axis guide portion 1112C along the X-axis. Consequently, the carton 700 is moved from the first conveyor 1102 To the second conveyor 1104.
After the carton 700 is placed on the second conveyor 1104, the suction/rotation portion 1112A is returned to its original position.
1-4-G Second RobotThe second robot 1114 has a function of rotating the carton 700 transported by the first conveyor 1102 and the second conveyor 1104 around the Z-axis.
The second robot 1114 is provided above the stopper plate 1104Q of the second conveyor 1104 as shown in
The second robot 1114 comprises a carton holding portion 1114A for sucking/holding the carton 700, a vertical-moving guide 1114B for guiding the carton holding portion 1114A vertically and a holding member 1114C for holding the vertical-moving guide 1114B vertically.
The carton holding portion 1114A comprises a suction holding portion 1114D for sucking/holding the carton 700, and a suction holding portion rotating motor 1114E which holds the suction holding portion 1114D rotatably around a rotation axis in the vertical direction.
The suction holding portion 1114D comprises a suction cup 1114F and a guide member 1114G for introducing the top of the carton 700 to the suction cup 1114F.
A suction pipe 1114H is connected to the suction holding portion rotating motor 1114E. The suction pipe 1114H communicates with the suction cup 1114F through a rotation shaft of the suction motor 1114E.
The vertical-moving guide 1114B comprises a guide rail 1114i held vertically by the holding member 1114C and a guide block 1114J which moves vertically in engagement with the guide rail 1114i. The suction holding portion rotating motor 1114E is fixed on the guide block 1114J through a mounting metal 1114K.
After the stopper plate 1104Q is ejected over the belt conveyor unit 1104A of the second conveyor 1104 and the carton 700 is stopped, the carton holding portion 1114A descends to the carton 700, so that the guide member 1114G engages with the top of the carton 700. If a top face of the carton 700 is sucked by the suction cup 1114F, the guide block 1114J ascends along the guide rail 1114i so that the carton 700 is raised. Then, the suction holding portion 1114D is also rotated by 180° by the suction holding portion rotating motor 1114E. Consequently, the carton 700 is rotated by 180° around the Z-axis. After the carton 700 is rotated by 180° around the Z-axis, the carton holding portion 1114A descends, so that the carton 700 is placed on the belt conveyor unit 1104A and then, depressurization of the suction cup 1114F is released.
1-4-H Third RobotThe third robot 1116 has a function of transporting the carton assembly 720 formed by the second conveyor 1104 to the shrink packaging unit 1200.
As shown in
As shown in
As shown in
The chuck portion 1116A comprises a pair of chuck pawls 1116E for chucking the carton 700, a chuck width setting unit 1116F for setting the chuck width x of the chuck pawl 1116E and a pair of air slide units 1116G for chucking the carton 700 by bringing the chuck pawls 1116E in which the chuck width x is set by the chuck width setting unit 1116F near each other.
Each of the chuck pawls 1116E is fixed on the air slide unit 1116G. The air slide units 1116G are fixed symmetrically on a belt 1116H having the chuck width setting unit 1116F.
The carton positioning pawls 1116N are provided inside of the respective chuck pawls 1116E such that they oppose each other. The carton positioning pawl 1116N is provided at right angle to the chuck pawl 1116E and has a function of restricting the depth of gripping the carton assembly 720 by the chuck pawl 1116E.
The belt 1116H is wound around a pair of belt wheels 1116i and driven. Rack-like protrusions are provided on an inner peripheral face of the belt 1116H. On the other hand, thread-like protrusions, which engage the protrusions on the inner peripheral face of the belt 1116H, are provided on the outer peripheral face of the belt wheel 1116i. One of the belt wheels 1116i is rotated clockwise or counterclockwise by the motor 1116P.
A guide rail 1116J for guiding the air slide unit 1116G along the traveling direction of the belt 1116H is provided inside of the belt 1116H.
The air slide unit 1116G comprises a guide block portion 1116G′ and a slide portion 1116G″ which slides on the guide block portion 1116G′ in parallel to the belt 1116H in engagement with the guide block portion 1116G′. The guide block portion 1116G′ is fixed on the belt 1116H and slides on the guide rail 1116J in engagement with the guide rail 1116J. A pneumatic actuator (not shown) for moving the slide portion 1116G″ with respect to the guide block portion 1116G′ is provided between the guide block portion 1116G′ and the slide portion 1116G″. Further, the chuck pawl 1116E is fixed on the slide portion 1116G″.
If the belt wheel 1116i is rotated counterclockwise in
When the carton assembly 720 is gripped by the third robot, the Y-axis guide block 1116L slides on the Y-axis guide rail 1116K in the guide unit 1116B to adjust the position of the chuck portion 1116A so as to be located above the carton assembly 720. At this time, the chuck pawl 1116E is held such that it faces downward in the vertical direction as shown in
If the chuck portion 1116A is located just above the carton assembly 720, the Z-axis guide rail 1116M descends and therefore, the chuck portion 1116A also descends to the carton assembly 720.
If the carton positioning pawl 1116N included by the chuck portion 1116A abuts the carton assembly 720, the Z-axis guide rail 1116M stops descending.
Next, the belt wheel 1116i rotates clockwise so that the chuck pawls 1116E approach each other so as to grip the carton assembly 720. If the carton assembly 720 has the header 704, when it is gripped by the chuck pawls 1116E, the header 704 is located below and the carton positioning pawl 1116N makes a contact with a face opposite to a side containing the header 704 of the carton assembly 720.
When the chuck pawls 1116E grip the carton assembly 720, the Z-axis guide rail 1116M ascends and correspondingly, the chuck portion 1116A also ascends.
Next, the chuck portion 1116A is rotated by the chuck rotation unit 1116D around the X-axis to the left side in
If the chuck pawl 1116E is set horizontal, the Y-axis guide block 1116L slides on the Y-axis guide rail 1116K so that the chuck portion 1116A is moved upward of the shrink packaging unit 1200 along the Y-axis.
If the carton assembly 720 has no header 704 or the header 704 does not need to be folded even if that header 704 is possessed, the chuck portion 1116A descends as it is so as to place the carton assembly 720 on an introduction conveyor 1202A, which will be described later, of the shrink packaging unit 1200.
Of the carton 700 constituting the carton assembly 720 has the header 704 while the header 704 needs to be folded, the chuck portion 1116A is moved in the direction of the Y-axis and brings the header 704 into a firm contact with the guide plate 202B provided along the introduction conveyor 1202A of the shrink packaging unit 1200 shown in
The shrink packaging unit 1200, as shown in
The introduction portion 1202 comprises an introduction conveyor 1202A on which the carton assembly 720 moved by the third robot 1116 is to be placed in order to transport that placed carton assembly 720 to the covering portion 1204 and a guide plate 202B provided along a side edge on a side opposite to the side facing the third robot 1116 of the introduction conveyor 1202A.
The covering portion 1204 contains a shrink film supplying portion 1216, which covers around the carton assembly 720 introduced by the introduction conveyor 1202 with shrink film supplied from the shrink film supplying portion 1216. A heat sealing portion 1206 heat-seals the shrink film along the periphery of the carton assembly 720 covered with the shrink film by the covering portion 1204 and cuts. The carton assembly 720, after the shrink film is heat-sealed by the heat sealing portion 1206, is heated in a shrink tunnel 1208 so that the shrink film is contracted or tensed to form the shrink-wrapped package 740.
The height arranging portion 1210 arranges the shrink-wrapped packages 740 formed in the shrink tunnel 1208 in line in the height direction. An end arranging transporting unit 1212 arranges the end portions of the shrink-wrapped packages after an unevenness in the height direction is removed by the height arranging portion 1210 in line and at the same time, transports to the corrugated board casing unit 1300.
When the shrink-wrapped package 740 in which the carton 700 is placed on a mount thereof is formed, the mount is supplied to the introduction conveyor 1202 from a mount supplying unit 1214.
1-5-A Introduction Conveyor, Covering Portion, Heat-Sealing Portion, Shrink Portion and the LikeThe shrink film supplying portion 1216 supplies a shrink film to the covering portion 1204 along a direction at right angle to the transporting of the carton assembly 720 as shown in
The shrink film supplying portion 1216 comprises an original roll 1216A which shrink film original twice-folded along the longitudinal direction is wound around, a pair of film placing rollers 1216B for supporting the original roll 1216A from downward, a tension roller 1216C and a nip roller 1216D which apply a tension to the shrink film S fed from the original roll 1216A in the twice-folding condition and transport the shrink film S to the covering portion 1204, a film boring roller 1216E which is comprised of four needle-like protrusions for boring air bleeding holes which allow inside air to escape at the time of contraction by heating, in the shrink film transported by the nip roller 1216D, the needle-like holes being formed along the circumferential direction, and a pass roller 1216F and a pass roller 1216G which are located in the downstream of the film boring roller 1216E for introducing the shrink film S to the covering portion 1204. The pass roller 1216H is provided between the tension roller 1216C and the film placing roller 1216B. The pass roller 1216H applies a tension to the shrink film S and introduces the shrink film S so that a winding angle of the shrink film S to the tension roller 1216C is enlarged.
A disc-like perforation blade 1216i for applying perforations to an upper shrink film of the shrink film S supplied in the twice-folding condition and a perforation receiving roller 1216J which opposes the perforation blade 1216i across a transporting path for the shrink film to be perforated are provided between the pass roller 1216G and the covering portion 1204. A belt 1216K for transmitting a rotation force of the film boring roller 1216E to the perforation receiving roller 1216J is provided between the perforation receiving roller 1216J and the film boring roller 1216E.
The perforation blade 1216i is a square cut blade which is driven and rotated while pressed against the surface of the perforation receiving roller 1216J so as to press and cut the shrink film S.
The covering portion 1204 comprises a pair of triangular formers 1204A disposed in parallel and above and below a product conveyor 1204B.
The triangular former 1204A is a right-angled isosceles triangular plate-like member. Of the shrink film S supplied from the shrink film supplying portion 1216 in the twice-folding condition, a half portion located up is wound around the upper triangular former 1204A while a half portion located down is wound around the lower triangular former 1204A. The shrink film S is applied around the upper triangular former 1204A such that it passes from its top face to its lower face through its oblique side. On the other hand, the lower triangular former 1204A is loaded with the shrink film S such that it passes from the lower face to the upper face through the oblique side. Consequently, the shrink film S is opened into a C-shape from the twice-folding condition and further, its traveling direction is converted to the same direction as the transporting direction of the carton assembly 720 on the product conveyor 1204B.
The sealing portion 1206 comprises an L seal bar 1206A located above the transporting path for the carton assembly 720, an L seal bar receiver 1206B located below the L seal bar 1206A across the transporting path for the carton assembly 720, an L seal conveyor 206C disposed between the L seal bar 1206A and the L seal bar receiver 1206B and film drive chains 1206D, 1206E provided adjacent to the L seal bar 1206A.
The L seal bar 1206A has a L-shaped flat configuration and seals along the periphery of the carton assembly 720 with the shrink film S and cuts into a L shape in cooperation with the L seal bar receiver 1206B. Heat resistant rubber is bonded to a top face of the L seal bar receiver 1206B.
The film drive chains 1206D, 1206E transport the shrink film S along the transporting direction of the carton assembly 720 and the shrink film S on the L seal conveyor 1206C while nipping a side edge portion opposite to a folded side of the shrink film S. The film drive chain 1206E is driven by such an appropriate drive means as a motor and the film drive chain 1206D is driven following the film drive chain 1206E.
A shrink film take-up portion 1206F for taking up the remainder of the shrink film S left after the sealing by the L seal bar 1206A is provided adjacent to the film drive chain 1206E.
1-5-B Height Arranging PortionAs shown in
The package conveyor 1210A is a belt conveyor on which the shrink-wrapped package 740 formed in the shrink tunnel 1208 is placed and mounted on a supporting base 1210D so that its top face coincides with the same height as the transporting plane of the shrink-wrapped package 740 on the shrink tunnel 1208 and the end arranging transporting unit 1212. As indicated with a two-dot chain line in
The lid body 1210B includes a height arranging unit 1210H for arranging the heights of the shrink-wrapped packages 740 in line by pressing the shrink-wrapped packages 740 carried by the package conveyor 1210A from above.
The height arranging unit 1210H is located below the lid body 1210B and has a rectangular flat configuration and comprises a pressing pad 1210k for pressing the shrink-wrapped package 740 directly, an air slide unit 1210J for ascending/descending the pressing pad 1210i with compressed air and a base 210K for fixing the air slide unit 1210J above the lid body 1210B. The air slide unit 1210J is fixed on a fixing portion 1210J2 fixed on the base 210K and the pressing pad 1210k and includes a movable portion 1210J4 for sliding the fixing portion 1210J2 vertically. The lid body 1210B contains a square opening portion through which the movable portion 1210J4 passes.
When the shrink-wrapped package 740 is transported to below the lid body 1210B by the package conveyor 1210A, the height arranging unit 1210H descends the pressing pad 1210i toward the shrink-wrapped package 740 and presses the top face of the shrink-wrapped package 740. Here, because the shrink-wrapped package 740 is heated by the shrink tunnel 1208 so that it is plastic because it is just shrunk, an unevenness of the height existing just after the shrinking is removed when it is pressed by the pressing pad 1210i.
The product discharge chute 1210E is provided on the forward side of this paper in
If any trouble occurs in the downstream, the package conveyor 1210A is rotated downward to the product discharge chute 1210E as indicated with a two-dot chain line in
Therefore, as long as the shrink-wrapped package 740 remains within the shrink tunnel 1208, if the shrink-wrapped package 740 is fed to the downstream in the shrink tunnel 1208, the shrink-wrapped package 740 in the shrink tunnel 1208 is discharged out through the product discharge chute 1210E.
The optical detection portion 1210C is a laser transmission type displacement sensor comprising a light projection device 1210F disposed on an outlet of the shrink-wrapped package 740 and a light receiving device 1210G disposed on a side opposite to the light projection device 1210F across the package conveyor 1210A. The light projection device 1210F emits laser beam and the light receiving device 1210G receives the laser beam from the light projection device 1210F. The light projection device 1210F and the light receiving device 1210G are disposed at the same height as the shrink-wrapped package 740 and the carton 700 on the package conveyor 1210A so as to detect a deflection in the height direction of the shrink-wrapped package 740.
1-5-C End Arranging Transporting UnitAs shown in
The package conveyor 1212A is a belt conveyor having the same width and height as the package conveyor 1210A of the height arranging portion 1210 and provided in a horizontal direction.
The package rotating portion 1212B comprises a package gripping portion 1212D for gripping the shrink-wrapped package 740 and a lift-up and down/turn actuator 1212E which lifts up and down the package gripping portion 1212D and at the same time, turns it every 90° around its vertical rotation axis as indicated with a solid line and a two-dot chain line in
The package gripping portion 1212D comprises a pair of plate-like shrink-wrapped package gripping members 1212F for gripping the shrink-wrapped package 740, an actuator 1212G which holds the shrink-wrapped package gripping portions 1212F such that they oppose each other and at the same time, moves them in directions of approaching/leaving each other, and a shrink-wrapped package gripping plate 1212H which is fixed on the actuator 1212G for holding the shrink-wrapped package 740, after carried by the package conveyor 1212A, at a position which allows the shrink-wrapped package gripping portions 1212F to grip the same shrink-wrapped package 740. The rotation shaft of the lift-up and down/turn actuator 1212E is fixed on the actuator 1212G.
The transporting chute 1212C comprises a transporting conveyor 1212i for transporting the shrink-wrapped package 740 to the corrugated board casing unit 1300, a fall-down type drop chute 1212J for introducing the shrink-wrapped package 740 after transported by the package conveyor 1212A to the transporting conveyor 1212i, and a vertical guide 1212K which is a vertical wall opposing the drop chute 1212J across the transporting conveyor 1212i. A stopper for stopping the shrink-wrapped package 740 is provided at an end in the transporting direction of the transporting conveyor 1212i. The stopper has a function of positioning the shrink-wrapped package 740 in the transporting direction. The vertical guide 1212K has a function of guiding the shrink-wrapped package 740 not so as to fall from the transporting conveyor 1212i in cooperation with the drop chute 1212J in a standup condition and positioning the shrink-wrapped package in the direction at right angle to the transporting direction of the transporting conveyor 1212i.
After the deflection in the height direction is removed by the height arranging portion 1210, the shrink-wrapped package 740 is transported to the end arranging transporting unit 1212 by the package conveyor 1210A and then transported to the package rotating portion 1212B by the package conveyor 1212A and when it abuts the shrink-wrapped package gripping plate 1212H, stopped between the shrink-wrapped package gripping members 1212F.
If the shrink-wrapped package 740 should be turned at 90° before transported to the corrugated board casing unit, the actuator 1212G is actuated so that the shrink-wrapped package 740 is gripped on both sides by the shrink-wrapped package gripping members 1212F. Consequently, the deflection in the width direction of the shrink-wrapped package 740 is removed.
Next, the package gripping portion 1212D is ascended by the lift-up and down/turn actuator 1212E and the shrink-wrapped package 740 is departed from the package conveyor 1210A. Then, the package gripping portion 1212D turns at 90° around a vertical rotation axis as indicated with a two-dot chain line in
If the shrink-wrapped package 740 is placed on the package conveyor 1212A, the package gripping portion 1212D is ascended up to a position which does not obstruct transporting of the shrink-wrapped package 740 from being transported to the transporting chute 1212C.
At this time, the drop chute 1212J remains fallen against the package conveyor 1212A as indicated with a solid line in
After the shrink-wrapped package 740 drops on the transporting conveyor 1212i, the drop chute 1212J stands up as indicated with a two-dot chain line in
The shrink-wrapped package 740 placed on the transporting conveyor 1212i is transported to the product loading robot 1302 in the corrugated board casing unit 1300.
1-6 Corrugated Board Casing UnitAs shown in
The product loading robot 1302 is a vertically multi-articular robot, which comprises, as shown in
The base 1302A is a vertically erected cylinder, which comprises a base main body 1302D placed on the base 1302V and a horizontal cylindrical arm mounting portion 1302E located above the base main body 1302D. The arm mounting portion 1302E incorporates a motor or actuator for rotating the arm portion 1302B.
The arm portion 1302B comprises a first arm 1302F mounted rotatably on the arm mounting portion 1302E of the base 1302A, a second arm 1302G mounted on a front end of the hand portion 1302C and an articulation portion 1302H for connecting the first arm 1302F and the second arm 1302G through their end portions.
The first arm 1302F is mounted rotatably on the arm mounting portion 1302E through an end thereof and rotated around a horizontal rotation axis by a motor or an actuator in the arm mounting portion 1302E.
The articulation portion 1302H has three freedoms, which allow the second arm 1302G to rotate around three rotation axes comprised of a horizontal rotation axis and two rotation axes intersecting that horizontal rotation axis, those three rotation axes intersecting each other. The articulation portion 1302H is provided at the other end of the first arm 1302 rotatably around a horizontal rotation axis and comprises a first rotation portion 1302i which rotates the second arm 1302G in a vertical direction and a second rotation portion 1302J which is provided at the first rotation portion 1302i so as to be rotatable around a rotation axis intersecting the aforementioned rotation shaft for rotating the second arm 1302G in the right/left direction. The second arm 1302G is provided on the second rotation portion 1302J so as to be rotatable around a center line of the second arm 1302G.
A work holding portion 1302K is provided at an end portion on a side opposite to the side provided with the second rotating portion 1302J of the second arm 1302G such that it is rotatable around a rotation axis at right angle to the center line of the second arm 1302G. The work holding portion 1302K comprises a work fixing shaft 302L in which the hand portion 1302C is fixed on an end portion thereof and an arm mounting portion 1302M which is provided at the other end portion of the work fixing shaft 302L and held on the second arm 1302G rotatably. The work fixing shaft 302L is held rotatably by the arm mounting portion 1302M.
The hand portion 1302C, as shown in
The chuck width setting unit 1302P comprises a belt 1302R having rack-like protrusions on its inner peripheral face and a pair of belt wheels 1302S having thread-like protrusions engaging the aforementioned rack-like protrusions on its outer peripheral face. One of the belt wheels 1302S is rotated by a motor 1302T, so that the belt 1302R is also rotated. The belt 1302R includes a guide rail 1302U for guiding the air slide unit 1302Q along the traveling direction of the belt 1302R.
The air slide units 302Q are fixed symmetrically on the belt 1302R.
The air slide unit 1302Q is fixed on the belt 1302R and comprises a guide block portion 1302Q2 which engages the guide rail 1302U and a slide portion 1302Q4 which slides on the guide block portion 1302Q2 in parallel to the belt 1302R. A pneumatic actuator (not shown) is provided between the guide block portion 1302Q2 and the slide portion 1302Q4. The finger-like member 1302N is fixed on each slide portion 1302Q4.
As shown in
An optical sensor 1302N4 is provided at a front end of the finger-like member 1302N. Further, an overload detecting sensor 1302N4, which is an optical sensor, is provided between the root of the finger-like member 1302N and the holding member 1302V. The optical sensor 1302N2 has a function of detecting whether or not the carton assembly 720 or the shrink-wrapped package 740 is loaded in a corrugated board box 600, which will be described later, without any abnormality. The overload detecting sensor 1302N2 has a function of detecting that an overload is applied on the finger-like member 1302N by detecting that the finger-like member 1302N is moved upward.
An operation of the product loading robot's loading of the carton assembly 720 or the shrink-wrapped package 740 into the corrugated board box will be described below.
As shown in
When the hand portion 1302C grips the carton assembly 720 or the shrink-wrapped package 740, the product loading robot 1302 moves the hand portion 1302C up to near the corrugated board box 6000 so as to determine whether or not the carton assembly 720 or the shrink-wrapped package 740 is gripped properly.
When it is determined that the carton assembly 720 or the shrink-wrapped package 740 is gripped properly, the product loading robot 1302 proceeds to an operation of loading the carton assembly 720 or the shrink-wrapped package 740 into the corrugated board box 600.
On the other hand, when it is determined that the carton assembly 720 or the shrink-wrapped package 740 is not gripped properly, the product loading robot 1302 determinates that an abnormality occurs and stops its operation and then outputs an abnormality occurrence signal to the control computer 500.
When proceeding to the loading operation, the product loading robot 1302 determinates whether or not a position where the carton assembly 720 or the shrink-wrapped package 740 is loaded is at a final row of the corrugated board box 600.
When the aforementioned insertion position is at the final row of the corrugated board box 600, after the carton assembly 720 or the shrink-wrapped package 740 is loaded, as shown in
If the optical sensor 1302N2 detects nothing, it is determined that the loading into the entire corrugated board box is carried out properly and then all the loading operation is terminated.
On the other hand, if the optical sensor 1302N2 detects the carton assembly 720 or the shrink-wrapped package 740, it is determined that not loaded carton assembly or shrink-wrapped package 740 rides on the carton assembly 720 or the shrink-wrapped package 740 inserted in the corrugated board box 600 and all the operation is stopped and at the same time, the abnormality occurrence signal is output to the control computer 500.
Unless the insertion position is at the final row of the corrugated board box 600, the product loading robot 1302 loads the carton assembly or the shrink-wrapped package through the first or second action while preventing the hand portion 1302C, or the carton assembly 720 or the shrink-wrapped package 740 gripped by the hand portion from interfering with the flap portions of the corrugated board box 600.
As the first action, the product loading robot 1302 loads the gripped carton assembly 720 or shrink-wrapped package 740 while moving the hand portion 1302C so as to stretch the flap portion. On the other hand, as the second action, the hand portion 1302C is rotated so that the gripped carton assembly 720 or shrink-wrapped package 740 is located on a diagonal line of an opening portion of the empty corrugated board box 600 and then, the carton assembly 720 or the shrink-wrapped package 740 is loaded.
Every time when a single loading is carried out, the finger-like member 1302N is moved upward and pulled out from the corrugated board box 600. If the finger-like member 1302N reaches the flap portion folding position of the corrugated board box 600, it is stopped temporarily so as to detect whether or not the optical sensor 1302N2 senses the carton assembly 720 or the shrink-wrapped package 740.
If the optical sensor 1302N2 does not detect any carton assembly 720 or shrink-wrapped package 740, it is determined that the carton assembly 720 or the shrink-wrapped package 740 is loaded properly and the second loading action begins.
On the other hand, when the optical sensor 1302N2 detects the carton assembly 720 or the shrink-wrapped package 740, it is determined that the loaded carton assembly 720 or shrink-wrapped package 740 is hooked and brought out of the corrugated board box 600 and all the action is stopped and then the abnormality occurrence signal is output to the control computer 500.
Further, upon insertion, whether or not the optical sensor 1302N4 detects an upward motion of the finger-like member 1302N is determined. Here, if an end of the finger-like member 1302N or the carton assembly 720 or the shrink-wrapped package 740 gripped by the finger-like member 1302N abuts the carton assembly 720 or the shrink-wrapped package 740 already loaded, the finger-like member 1302N is moved upward resisting the urging force of the spring 1302W. Therefore, if the optical sensor 1302N4 senses the aforementioned motion, it can be determined that the aforementioned abutting is made.
If the optical sensor 1302N4 senses the above-described motion, the product loading robot 1302 stops its loading operation, raises the hand portion 1302C and stops it above the corrugated board box 600 so as to notify an operation of an occurrence of that abnormality. After that, this system waits for confirmation and restoration by the operation.
1-6-B Empty Corrugated Board Transporting PortionAs shown in
The turn table 1308A comprises a conveyor portion 1308D on which the empty corrugated board box 600 is to be loaded and a base 1308 for holding the conveyor portion 1308D rotatably.
The conveyor portion 1308D comprises six rollers 1308F disposed in parallel to each other and a frame body 1308G for supporting the roller 1308F rotatably around its axial line.
The frame body is a box whose top face is open and the roller 1308F is provided in parallel to a short side of the frame body 1308G. Thus, an empty corrugated board box 600 placed on the conveyor portion 1308D is transported along the longitudinal direction of the frame body 1308G as indicated with an arrow in
A corrugated board box stopper 1308H is provided along one of the short sides of the frame body 1308G which supports the empty corrugated board box 600 transported by the belt conveyor 1308B on the conveyor portion 1308D. On the other short side of the frame body 1308G is fixed a gangway plate 1308i whose outer side is formed circularly while its inner side is formed linearly.
The frame body 1308G is mounted rotatably on the base 1308E through a central portion of its bottom face. If the frame body 1308A is rotated on the base 1308E, the turn table 1308A takes the first position shown in
The roller conveyor 1308C transports the empty corrugated board box 600 in the direction at right angle to the transporting direction of the empty corrugated board box 600 on the belt conveyor 1308B and comprises, as shown in
A corrugated board pushing unit 1308N for pushing the empty corrugated board box 600 onto the roller conveyor 1308C is provided along the turn table 1308A and the roller conveyor 1308C. The corrugated board pushing unit 1308N is projected to the roller conveyor 1308C and comprises a pushing rod 1308P for pushing out the empty corrugated board box 600 and a pushing rod guide 1308L which is extended in parallel to the frame body 1308K for moving the pushing rod 1308P in the transporting direction of the roller conveyor 1308C.
An operation of the empty corrugated board box transporting portion 1308 will be described below.
An empty corrugated board box 600 made by the box making machine 1306 is transported to the turn table 1308A by the belt conveyor 1308B. Because at this time, the turn table 1308A takes the first position as shown in
After the empty corrugated board box 600 is placed on the turn table 1308A, the turn table 1308 rotates counterclockwise in
When the turn table 1308A takes the second position, the pushing rod 1308P pushes the empty corrugated board box 600 to the roller conveyor 1308C as shown in
However, depending on the configuration and type of the empty corrugated board box 600, after it is made by the box making machine 1306 and transported/placed to/on the turn table 1308A by the belt conveyor 1308B, the empty corrugated board box may be transported to the corrugated board box positioning portion 1304 by the roller conveyor 1308C without being turned by the turn table 1308A.
1-6-C Corrugated Board Positioning PortionAs shown in
The corrugated board box positioning portion 1304 is formed so as to be capable of inclining from its horizontal condition and comprises a corrugated board placing table 1304A which forms an end portion of the roller conveyor 1308C when it is set horizontal, as indicated with a solid line in
The corrugated board placing table 1304A comprises five rollers 1304D provided in parallel to the roller 1308J on the roller conveyor 1308C and a pair of frame members 1304E, 1304F for supporting the roller 1304D rotatably. The frame member 1304E is located adjacent to the discharge conveyor 1312A and the frame member 1304F is located on a side opposite to the frame member 1304E across the roller 1304D. The corrugated board placing table 1304A is rotated around a bottom edge of the frame member 1304F. Therefore, at the time of inclination, as indicated with a two-dot chain line in
An arrow in
The discharge unit 1304C comprises a pressing plate 1304i for pushing out the product packed corrugated board box 600 to the discharge conveyor 1312A and a guide unit 1304J for transporting the pressing plate 1304i along the width direction of the corrugated board placing table 1304A. The guide unit 1304J comprises a guide rail 1304K extended in the transporting direction of the empty corrugated board box 600 on the corrugated board placing table 1304A, and a guide block 1304L which slides on the guide rail 1304K in engagement with the guide rail 1304K. The pressing plate 1304i is fixed on the guide block 1304L. The pressing plate 1304i is provided with a pair of the suckers 1304M for sucking and holding the empty corrugated board box 600.
The discharge unit 1304C is so constructed to be inclined integrally with the corrugated board placing table 1304A as indicated with a two-dot chain line in
An operation of the corrugated board box positioning portion 1304 will be described below.
Initially, the corrugated board placing table 1304A is set horizontal. Therefore, the empty corrugated board box 600, after transported by the roller conveyor 304C, abuts the guide block 1304L and is stopped on the corrugated board placing table 1304A.
When the empty corrugated board box 600 is placed on the corrugated board placing table 1304A, the corrugated board placing table 1304A is inclined and the suckers 1304G, 1304H, 1304M suck the bottom face and side face of the empty corrugated board box 600 so as to fix the empty corrugated board box 600 on the corrugated board placing table 1304A.
Next, the carton assembly 720 or the shrink-wrapped package 740 is loaded into the empty corrugated board box 600 by the product loading robot 1302.
After the loading of the carton assembly 720 or the shrink-wrapped package 740 is terminated, the corrugated board placing base 304A is returned to a horizontal condition again, so that suction by the suckers 1304G, 1304H, 1304M is released. Then, they are discharged to the discharge conveyor 1312A by the discharge unit 1304C.
1-6-D Product Packed Corrugated Board Box Transporting PortionAs shown in
The discharge conveyor 1312A is a roller conveyor.
The corrugated board pressing unit 1312D is provided adjacent to the discharge conveyor 1312A and the belt conveyor 1312C and an ink jet printer 1312E is provided adjacent to the corrugated board pressing unit 1312D.
The corrugated board pressing unit 1312D comprises a guide rail 1312F extended along an edge of the discharge conveyor 1312A, and a guide block 1312G which slides on the guide rail 1312F in engagement with the guide rail 1312F as indicated with a two-dot chain line in
A positioning plate 1312H, which is capable of projecting/retracting to/from the discharge conveyor 1312A for positioning the product packed corrugated board box 600 discharged from the discharge conveyor 1312A on the belt conveyor 1312C properly, is provided below the guide rail 1312F. In
An operation of the product-packed corrugated board box transporting portion 1312 will be described below.
When a long side of the product packed corrugated board box 600 is at right angle to the discharge conveyor 1312A, while the discharge conveyor 1312A transports the product packed corrugated board box 600, the guide block 1312G stands by outside the discharge conveyor 1312A as shown in
On the other hand, if the long side of the product packed corrugated board box 600 is in parallel to the discharge conveyor 1312A, the guide block 1312G moves onto a side edge on a side opposite to a side adjacent to the belt conveyor 1312C of the conveyor 1312A. If the product packed corrugated board box 600 is transported on the discharge conveyor 1312A with this condition, the guide block 1312G abuts an edge of the product packed corrugated board box 600. Consequently, the product packed corrugated board box 600 is rotated by 900 in the direction to the guide rail 1312F around the Z-axis as indicated with an arrow in
The product packed corrugated board box 600 pushed out to the belt conveyor 1312C is transported to the weight detection unit 1312B.
The weight detection unit 1312B detects whether or not the content packed in the product packed corrugated board box 600 is short.
The weight detection unit 1312B may determinates that the product packed corrugated board box 600 is acceptable according to a fact that the weight of the product packed corrugated board box 600 is within a predetermined range.
However, if the quantity of types or the quantity of combinations is tremendously large, a working load for determining a criterion value is large. Even in case of the same type, if part lot changes to produce a difference in the weight of the product packed corrugated board box 600, so that a value serving as a criterion changes, a working load for determining the criterion value following that change is large also. In such a case, there is a method of determining that an product packed corrugated board box 600 is acceptable if a difference between the weight of an product packed corrugated board box 600 and the weight of an product packed corrugated board box 600 just before in a certain lot containing the same products is within a preliminarily set range between upper and lower limits. According to the above-described determination method, if the range between the upper and lower limits is set up to be smaller than the weight of a single carton assembly 720 or shrink-wrapped package 740, an product packed corrugated board box 600 having insufficiency of the quantity of the packaged carton assemblies 720 or shrink-wrapped packages 740 can be removed as defective products because such an product packed corrugated board box 600 is lighter than the lower limit. Further, even if different type product packed corrugated board boxes 600 are fed through a production line, it is not necessary to reset the weight criterion.
The product packed corrugated board box 60, after determined to be acceptable by the weight inspecting unit 312B, is transported to the sealing machine 1310.
1-7 Control ComputerAs shown in
The control computer 500 comprises a process personal computer 510 for inputting an operation instruction to the cartoner PLC 502, a process personal computer 516 for inputting an operation instruction to the winding machine PLC 514, and a host computer 512 for inputting production plan to the process personal computer 510 and the process personal computer 516.
The cartoner PLC 502, the carton packing unit PLC 504, the plastic case packed product transporting supplying unit PLC 506, the shrink packaging unit PLC 508 and the winding machine PLC 514 have a display for displaying condition setting instructions from the process personal computer 510 and the process personal computer 516 and a touch panel for inputting manufacturing condition.
If the production plan is inputted from the host computer 512 to the process personal computer 510 and the process personal computer 516, the process personal computer 510 inputs a condition setting instruction to the cartoner PLC 502 and the process personal computer 516 inputs a condition setting instruction to the winding machine PLC 514.
The cartoner PLC 502 displays the condition setting instruction inputted from the process personal computer 510 on a display.
If the cartoner PLC 502 displays the condition setting instruction on its display, an operator inputs various production condition through a display, a touch-up panel or a keyboard of the cartoner PLC 502.
The carton manufacturing/packaging condition which can be inputted to the cartoner PLC 502 includes a condition about supply of the plastic case packed product P, manufacturing of the carton 700, the carton assembly 720 and shrink-wrapped package 740, a condition about loading of the carton assembly 720 and the shrink-wrapped package 740 into the corrugated board 600.
The condition about the supply of the plastic case packed product P includes, for example, the type of the plastic case packed product to be supplied to the cartoner 400, the quantity of the plastic case packed products P per a single supply, a combination of the plastic case packed products in case where multiple kinds thereof are supplied.
The condition about the production of the carton 700 includes a formation of the sack carton 710, the quantity of the plastic case packed products which should be loaded in the sack carton 710, whether or not a different type plastic case packed product should be loaded into the sack carton and a combination of the plastic case packed products in case where different type plastic case packed products are loaded.
The condition about the carton assembly 720 and the shrink-wrapped package 740 includes the type, size and arrangement of the carton 700 and whether or not shrink should be applied to the carton assembly 720.
The condition for loading the carton assembly 720 and the shrink-wrapped package 740 into the carton assembly 720 includes loading patterns of the carton assembly 720 and the shrink-wrapped package 740, configuration of the corrugated board 600 for use and the like.
If a working instruction is inputted to the process personal computer 510, the process personal computer 510 inputs the condition setting instruction into the cartoner PLC 502 based on the above-described working instruction.
The cartoner PLC 502 controls the cartoner 400 based on a manufacturing condition of the carton 700 included in the inputted production condition. At the same time, the condition about the supply of the plastic case packed product is inputted to the plastic case packed product transporting supplying unit PLC 506. The condition about the carton assembly 720 and the shrink-wrapped package 740 and the condition about loading of the carton assembly 720 and the shrink-wrapped package 740 into the corrugated board 600 are inputted to the carton packing unit PLC 504. The plastic case packed product transporting supplying unit PLC 506 controls the plastic case packed product transporting supplying unit 800 based on the production condition inputted from the cartoner PLC 502. The carton packing unit PLC 504 controls the carton arraying unit 1100 of the carton packing unit 1000 and the corrugated board casing unit 1300 based on the production condition inputted from the cartoner PLC 502 and at the same time, controls the shrink packaging unit 1200 through the shrink packaging unit PLC 508 if the aforementioned production condition contains an instruction for manufacturing the shrink-wrapped package 740 by shrink-packaging the carton assembly 720.
By inputting the production condition into the cartoner PLC 502, units included in the plastic case packed product transporting supplying unit 800, specifically, the plastic case packed product transporting supplying unit 800, the cartoner 400, the carton arraying unit 1100, the shrink packaging unit 1200, and the corrugated board casing unit 1300 can be set up about their conditions and controlled.
By inputting production conditions independently through the display, touch-up panel, and keyboard, the plastic case packed product transporting supplying unit PLC 506, the carton packing unit PLC 504, and the shrink packaging unit PLC 508 can control the plastic case packed product transporting supplying unit 800, the carton arraying unit 1100, the corrugated board casing unit 1300, and the shrink packaging unit 1200 independently.
On the other hand, the winding machine PLC 514 displays a condition setting instruction inputted from the process personal computer 516 on a display like the cartoner PLC 502.
If the display of the winding machine PLC 514 displays the condition setting instruction, the operator inputs the plastic case packed product manufacturing condition about the plastic case packed products through the display, touch-up panel and keyboard. The plastic case packed product manufacturing condition includes condition about sensitivity and number of frames, a spool for use, a single-side opening cartridge, a cartridge cap, plastic case main body and plastic case. If these conditions are inputted to the winding machine PLC 514, the winding machine PLC 514 controls the winding machine 900 based on the inputted manufacturing condition.
Thus, if the production condition is inputted to the winding machine PLC 514, that condition is set up in the winding machine 900, so that the winding machine 900 is controlled independently of the plastic case packed product transporting supplying unit 800 and other units.
2. Corrugated Board Box 2-1 Configuration of Corrugated Board BoxAccording to the invention, the corrugated board box for use in the carton packing unit 1000 is classified to a corrugated board box having the partition and a corrugated board box having no partition.
As shown in
The main body 602 comprises a bottom face 602C, a width-direction side plate 602A which forms a side face in the width direction and a length-direction side plate 602B which forms a side face in the longitudinal direction.
Inside flaps 606A, which are located inside when folded, of the four flap portions 606 are provided on a top edge of the width direction side plate 602A of the corrugated board main body 602 and outside flaps 606B, which are located outside when folded, are provided on the top edge of the length-direction side edge 602B.
The partition 604 is extended along the longitudinal direction of the main body 602 and fixed on one of the width-direction side plate 602A at its proximal portion 604A. A vertical cutout is made between the partition 604 and the proximal portion 604A. Instead of providing with a cutout at the root portion as shown in
An end portion on an opposite side to the root portion, which is an end portion on the side having the proximal portion 604A of the partition 604, that is, a front end portion is not fixed on an inner wall face of the main body 602.
The height of the partition 604 is so set that a gap of 5 to 10 m is formed between the bottom and the lid of the corrugated board box 600 when the lid is formed by folding the flap portions 606.
Therefore, the front end portion of the partition 604 is movable freely along the width direction inside the main body 602 as indicated with both arrows in
As shown in
The corrugated board box 600 is partitioned to two rooms, a small room 600A and a small room 600B along the length side thereof by the partition 604.
As shown in
A second product is loaded on a side in which the proximal portion 604A of the partition 604 in the small room 600B is located as shown in
A third product is loaded to a position adjacent to the initial product in the small room 600A as indicated in
A fourth product is inserted into a position adjacent to the initial product in the small room 600B as indicated in
In this way, products are loaded into the small rooms 600A, 600B alternately and the partition 604 is fixed in the center of the corrugated board box 600 by the loaded products.
When the final products are loaded into each of the small rooms 600A, 600B, the final product is loaded into the small room 600A as indicated in
Although an example in which the product is loaded into the small room 600B after the product is loaded into the small room 600A first has been described, conversely, it is permissible to load the product into the small room 600B and then load the product into the small room 600A.
3. CartonA carton 700, which can be loaded into a corrugated board box by a carton boxing unit 1000, can accommodate 1 to 5 plastic case packed products.
Some carton 700 is composed of only a box-type main body 702 having no header as shown in
The carton 700 having the header 704 includes an example in which as shown in
If production plan is inputted to the process personal computers 510, 516 from the host computer 512 as described about the control computer 500, the process personal computer 510 and the process computer 516 output the condition setting instruction to the winding machine 514.
After the operator inputs the plastic case packed product manufacturing condition to the winding machine PLC 514, a film roll, spool, single-side opening cartridge, cartridge cap, plastic case and plastic case cap are automatically supplied continuously to the winding machine 900 according to the plastic case packed product manufacturing condition and then, the plastic case packed products are produced.
On the other hand, if the operator inputs carton manufacturing/packaging condition into the cartoner PLC 502, the plastic case packed product transporting supplying unit 800, the cartoner 400, the carton arraying unit 1100, the shrink packaging unit 1200 and the corrugated board casing unit 1300 are controlled according to the carton manufacturing/packaging condition, so that a process from loading the plastic case packed product into the sack carton 710 to loading of the carton assembly 720 or the shrink-wrapped package 740 into the corrugated board box 600 is controlled as a sequential process.
The winding machine 900 is controlled independently of the plastic case packed product transporting supplying unit 800 and subsequent units.
When packaging of a plastic case packed product P1, which is a type of the plastic case packed product, is terminated and packaging of a plastic case packed product P2, which is a new type of the plastic case packed product, is started, the manufacturing condition for the cartoner PLC 502 is maintained at a condition corresponding to the plastic case packed product P1 until a last product packed corrugated board box 600 is discharged out of the corrugated board casing unit 1300.
After the last product packed corrugated board box 600 is discharged out of the corrugated board casing unit 1300, it is verified that no material used for production and packaging of the plastic case packed product P1 or no product is left in the sequential units of the packaging system 2000 and if such material or product is left, it is removed.
After it is verified that no material or product is left as a result of the above-described verification, a new condition about packaging of the plastic case packed product P2 is inputted to the cartoner PLC 502 and next, a new condition about manufacturing of the plastic case packed product P2 is inputted to the winding machine PLC 514 and finally, the manufacturing and packaging of the plastic case packed product P2 is started.
Instead of inputting the new manufacturing condition into the cartoner PLC 502 so as to execute the verification securely, it is permissible to set up new conditions for respective units included in the plastic case packed product transporting supplying unit 800.
4-2 Carton Packaging ProcedureThe procedures for arraying the carton 700 in the carton packing unit 1000 included by the packaging system of the fifth embodiment so as to form the carton assembly 720 or the shrink-wrapped package 740 and packaging into the corrugated board box will be exemplified.
4-2-A Boxing Procedure Example 1The boxing procedure will be explained about the carton 700 shown in
As shown in
If the carton arraying unit 1100 receives the control instruction, it rotates the carton 700, after transported by the first conveyor 1102 Under a condition shown in
The cartons 700, after rotated by 90°, are arrayed on the second conveyor 1104 Such that the header 704 overlaps the main body 702 as shown in
The carton assemblies 720 formed by the second conveyor 1104 are transported to the third conveyor 1106 and arrayed there. As shown in
After placed on the mount, the carton assembly is introduced to the covering portion 1204 by the introduction conveyor 1202 and covered with shrink film from both faces. After that, the carton assembly passes through the heat sealing portion 1206 And the shrink tunnel 1208, so that as shown in
The shrink-wrapped package 740 is inspected by the height arranging portion 1210 and their ends are arranged in line by the end arranging transporting unit 1212. Then, they are transported to the corrugated board box positioning portion 1304 of the corrugated board casing unit 1300 by the transporting conveyor 1212i.
In the corrugated board box positioning portion 1304, the shrink-wrapped package 740 is loaded in the empty corrugated board box 600 by the product loading robot 1302 according to the procedure shown in
The procedure for arraying the carton 700 shown in
As shown in
The carton arraying unit 1100 transports the carton 700 after transported by the first conveyor 1102 To the second conveyor 1104 without turning it in the first robot 1112.
The second conveyor 1104 forms the carton assembly 720 by arraying five pieces of the cartons 700 after transported by the first conveyor 1102, as shown in
The carton assembly 720 formed by the second conveyor 1104 is transported to the third conveyor 1106 and arrayed there. As shown in
Next, as shown in
The shrink-wrapped package 740 is transported to the corrugated board casing unit 1300 through the height arranging portion 1210 and the end arranging transporting unit 1212 successively and loaded in the empty corrugated board box 600 by the product loading robot 1302 according to the procedure shown in
The carton 700 shown in
As shown in
The carton arraying unit 1100 rotates initial five cartons 700 by 180° by means of the first robot 1112 and places them on the second conveyor 1104 as shown in
In the second conveyor 1104, as shown in
On the other hand, as shown in
As shown in
The carton assembly 720 formed in this way is pressed from both its faces by the carton pressing plate 1110J so as to form a neat shape and brought upward by the product loading robot 1302 through both end faces and then, loaded into a corrugated board box at the corrugated board box positioning portion 1304.
4-2-D Boxing Procedure Example 4The procedure for arraying and boxing the carton 700 shown in
As shown in
As shown in
Side faces of the carton assemblies 720 formed by the second conveyor 1104 are arranged in line by the third conveyor 1106 and as shown in
The packaging system 2000 of the fifth embodiment is capable of automatically coping with the cartons 700 in which the quantity of the plastic case packed products accommodated inside thereof and the position and size of the header 704 are different. If the sizes of the main body 702 and the header 704 of the carton 700 are different, the quantity and combination of the cartons 700 are often different. In such a case also, this packaging system is capable of automatically forming the carton assembly 720 by combining a predetermined quantity of the cartons 700 in a predetermined combination.
The carton assembly 720 is packed into a corrugated board box as it is in some case or shrink-wrapped and packed in a box in some case. In this case, this packaging system is capable of automatically separating a carton assembly which should be shrink-wrapped and the one which should not after the carton assembly is formed by combining the cartons 700.
When boxing the carton assembly 720 or the shrink package 740, they need to be packaged in different patterns depending on the configuration and size of the carton 700. In this case, this packaging system is capable of automatically coping with the aforementioned pattern.
Thus, the packaging system 2000 is capable of executing entire process including manufacturing of the plastic case packed product P by the winding machine 900, manufacturing of the carton 700 by the cartoner 400, formation of the carton assembly 720 or the shrink-wrapped package 740 by the carton packing unit 1000 and packaging into the corrugated board box 600 sequentially. Therefore, a stock of the plastic case packed products P on a process can be eliminated. Accordingly, the period up to shipment can be reduced largely.
Further, the film rolls R supplied to the winding machine 900 flow through the winding machine 900, the plastic case packed product transporting supplying unit 800, the cartoner 400, the carton arraying unit 1100, the shrink-wrapping unit 200 and the corrugated board casing unit 1300 without any deposit halfway and stored in the corrugated board box 600 as a plastic case packed product P containing the carton 700 based on the principle “first-in first-out”. Therefore, it is possible to specify which carton 700 or which corrugated board box 600 is loaded a specific film roll R situated at which position.
Accordingly, if any abnormality in terms of performance is found out in films after they pass the packaging system and are packaged in a corrugated board box, the range of the cartons 700 or the product packed corrugated board boxes 600 which should be collected and abandoned can be specified with a small range. Additionally, if a trouble is found out in the market, it is easy to specify a problem by tracking its production process.
Claims
1. A boxing apparatus, wherein a box body having folding portions, which are developed to form a rectangular parallelepiped-shaped structure, and having an opening portion and a flap portion for forming a lid portion for covering the opening portion at each of both ends thereof is constructed from a folded state so as to form the opening portions, with the box body having the opening portions held such that one of the opening portions faces upward while the other one faces downward, a packaging object is loaded into a main body of the box body through one of the opening portions and the flap portions are constructed to form the lid portion so that the packaging object is packaged in the box body, the boxing apparatus comprising foldable box body supplying means, opening forming means, box body holding means, packaging object loading means, and lid forming means, wherein:
- the foldable box body supplying means accommodates the box body in a folded state and supplies the accommodated box body to the box body holding means one by one;
- the opening forming means constructs the box body supplied by the foldable box body supplying means to the box body holding means from the folded state to form the opening portions;
- the box body holding means holds the foldable box body having the opening portions f armed, with one of the opening portions f acing upward while the other one faces downward; and
- the packaging object loading means loads the packaging object through an opening portion of the box body held by the box body supplying means; and
- the lid forming means folds the flap portions of the foldable box body after the packaging object is loaded by the packaging object loading means, so as to form the lid for covering the opening portion.
2. A boxing apparatus according to claim 1, wherein:
- the box body holding means comprises a rotation table which rotates around a vertical line while holding a box body at an outer peripheral portion so that the flap portions of the box body are located vertically with respect to the main body of the box body and transports the box body successively to the opening forming means, the packaging object loading means and the lid forming means; and
- the opening forming means forms the opening in the box body supplied to the rotation table by the box body supplying means such that the flap portions are located vertically with respect to the main body.
3. A boxing apparatus according to claim 2, wherein the foldable box body supplying means comprises a foldable box body accommodating portion for accommodating the box body in a folded state and a box body supplying portion for supplying the accommodated box body to the box body holding means one by one,
- the foldable box body accommodating portion accommodating the box body in the folded state such that one of the folding portions is located downward and having a pickup port for the box body which opens downward or obliquely downward,
- the box body supplying portion comprising:
- box body holding means for holding the box body and the box body holding means being capable of approaching/leaving the box body pickup port of the foldable box body accommodating portion and the rotation table of the box body holding means; and
- box body moving means for moving the box body holding means between a box body pickup position for picking up the box body from the box body pickup port and a box body loading position at which the picked up box body is loaded on the rotation table,
- the box body moving means including:
- a rotation shaft on which the box body holding means is fixed and which is provided obliquely with respect to a horizontal plane; and
- rotation shaft driving means for rotating or pivoting the rotation shaft so as to position the box body holding means at either one of the box body pickup position and the box body loading position.
4. A boxing apparatus according to claim 2, wherein the foldable box body supplying means comprises a foldable box body accommodating portion for accommodating the box body in a folded state and a box body supplying portion for supplying the accommodated box body to the box body holding means one by one,
- the foldable box body accommodating portion having a box body pickup port which opens toward the rotation table,
- the box body supplying portion including:
- box body holding means for holding the box body, the box body holding means being capable of approaching/leaving the box body pickup port and the rotation table; and
- rotating means for rotating or turning the box body holding means around a vertical axis so as to position the box body holding means at either one of a first position opposing the box body pickup port and at a second position opposing the rotation table.
Type: Application
Filed: Apr 28, 2008
Publication Date: Aug 28, 2008
Applicant:
Inventors: Haruo Ichikawa (Kanagawa), Makoto Shimizu (Kanagawa), Kazuyuki Kosemura (Kanagawa), Akira Wakabayashi (Kanagawa), Katsutoshi Nakamura (Kanagawa), Masaharu Minagi (Kanagawa), Minoru Tamura (Kanagawa), Seiichi Yamashita (Kanagawa), Toshihide Sasaki (Kanagawa)
Application Number: 12/110,467
International Classification: B65B 5/02 (20060101);