Shuttle envelope feeder with suction cup assist

Abstract

An envelope feeder for removing envelopes from an envelope stack. The envelope feeder comprises a shuttle plate and a suction cup assembly. The shuttle plate translates between a position under the envelope stack and another position partially remote from the envelope stack. The shuttle plate includes an orifice passing through its surface and an envelope gripping mechanism in connection with a vacuum valve. The suction cup assembly has a suction cup connected to a hollow rod that is in connection with another vacuum valve. An actuator engages the suction cup and moves the suction cup between an extended position and a retracted position. The suction cup attaches to an envelope at the bottom of the envelope stack when it is in the extended position, and pulls the envelope toward the shuttle plate as it moves to the retracted position. Then the envelope gripping mechanism retains the envelope, allowing the shuttle plate to remove the envelope from the envelope stack.

Description

TECHNICAL FIELD

This invention generally relates to machines that operate at a very high speed to insert sheets of paper or other items into envelopes. More particularly, it relates to a shuttle envelope feeder that transports the envelopes to be inserted.

BACKGROUND ART

Machines for automatically inserting items such as sheets of paper into envelopes are known in the art. A state-of-the-art mail inserting machine such as the Pitney Bowes Flowmaster™ FX14 can perform 12,000 insertions per hour when properly maintained and adjusted.

A typical high-speed inserting machine comprises several modules. A first module transports an elongate horizontal queue of envelopes to an envelope stack. An envelope feeder located at the bottom of the envelope stack delivers the envelopes one by one to an envelope insertion station. A second module delivers individual groups of stacked sheets to the envelope insertion station. A third module, the envelope insertion station, includes clamps carried by an elongate sprocket chain that sequentially receives envelopes from the envelope feeder and pulls them past an envelope flap-opening structure and a sheet inserting structure where the envelopes are opened and inserted with stacked sheets. The envelopes are then pulled past an envelope closing structure and an envelope sealing structure before been ejected to a collection station. envelope closing structure and an envelope sealing structure before been ejected to a collection station.

FIG. 1 schematically shows an arrangement of a prior art envelope feeder. The envelope feeder comprises a shuttle plate 150 that moves back and forth (direction shown as doted arrow line 152) to transport envelopes 140 to be grasped by clamps 190 on an elongate sprocket chain 160 of the insertion station. The shuttle plate has a recessed area in which a vacuum gripping mechanism 180 is arranged. The negative pressure form the vacuum gripping mechanism 180 pulls the part of the envelope directly above the recessed area toward the recessed area so as to temporarily secure the envelope to the upper surface of the shuttle plate. When the shuttle moves toward the sprocket chain 160, a stripper bar 170 located above the recessed area separates the secured bottom envelope from the envelope stack and allows it to move forward with the shuttle.

The vacuum envelope feeder of the above arrangement works well when envelopes are substantially flat. If, however, some of the envelopes are significantly curled or bent, the shuttle vacuum may not have sufficient suction to pull down these envelopes, causing a failure in the shuttle feed.

Some methods have been proposed in order to solve the above problem. One is to add pressure to the top of the envelope stack to help flatten the envelopes. This method is somewhat ineffective, because an improperly applied stack pressure can also cause a failure in the shuttle feed or multiple envelope feedings.

Another method uses a thumper to add stack pressure when the shuttle vacuum is turned on. When the shuttle moves forward, the thumper retracts and the shuttle vacuum holds the curled envelope. The disadvantages of this method are that the thumper disturbs the stack and the flow of envelopes from the envelope transport module, and it requires constant mechanical adjustment.

What is needed is a vacuum shuttle feeder that is capable of feeding curled envelopes without failure. Preferably, the operation of such feeder will not interfere with existing configuration of the envelope stack or envelope flow. In addition, the feeder should be operative over a wide range of envelope dimensions.

SUMMARY OF THE INVENTION

The invention provides an envelope feeder in an envelope insertion machine for removing envelopes from an envelope stack. The envelope feeder comprises a shuttle plate and a suction cup assembly.

The shuttle plate is operable between a first position under the envelope stack and a second position at least partially remote from the envelope stack. The shuttle plate has an orifice passing through its upper surface, and an envelope gripping mechanism that is in communication with a shuttle vacuum valve.

The suction cup assembly comprises a suction cup that has an upper rim and a lower neck with an opening formed therein, the opening is connected to a hollow rod. The rod, in turn, is in communication with a suction cup vacuum valve. An actuator engages the suction cup and moves the suction cup between an extended position that passes through the orifice in the shuttle plate to a retracted position that the upper rim of the suction cup is at least flush with the upper surface of the shuttle plate.

The suction cup vacuum valve is activated at least when the suction cup is in the extended position so that the suction cup attaches to an envelope at the bottom of the envelope stack. The suction cup pulls the envelope toward the upper surface of the shuttle plate as the actuator moves from the extended position to the retracted position.

The shuttle vacuum valve is activated at least when the envelope is pulled toward the upper surface of the shuttle plate. By doing so, the envelope is retained by the envelope gripping mechanism, allowing the shuttle plate to remove the envelope from the envelope stack as the shuttle plate moves to its second position.

The invention further provides a method for an above-described envelope feeder in an envelope insertion machine to remove an envelope from an envelope stack. The method comprising the steps of: placing the shuttle plate in the first position, moving the suction cup between the retracted position that is at least flush with the upper surface of the shuttle plate and the extended position that is in contact with an envelope at the bottom of the envelope stack, and controlling the air pressure within the suction cup so that the suction cup has a lower air pressure than the ambient air pressure when the suction cup is in the extended position and while it moves from the extended position to the retracted position.

In accordance with the method, the envelope at the bottom of the envelope stack is pulled down toward the upper surface of the shuttle plate so as to facilitate the acquisition of said envelope by the envelope gripping mechanism.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other objects, features and advantages of the invention will become apparent from a consideration of the subsequent detailed description presented in connection with accompanying drawings, in which:

FIG. 1 is a schematic illustration of a prior art shuttle feeder part of an envelope insertion station.

FIG. 2A is a schematic top view of a shuttle envelope feeder with vacuum suction assist, according to a first embodiment of the invention.

FIG. 2B is a schematic cross-sectional view of a shuttle envelope feeder with vacuum suction assist, taken along line 2B in FIG. 2A, according to the first embodiment of the invention.

FIG. 3 is a block diagram of the shuttle envelope feeder with vacuum suction cup assist, including valves and controlling mechanism, according to the first embodiment of the invention.

FIG. 4 is a three-dimensional view of the shuttle envelope feeder, according to the first embodiment of the invention.

FIG. 5 is a three-dimensional view of the shuttle envelope feeder, according to a second embodiment of the invention.

FIG. 6 is a three-dimensional view of the shuttle envelope feeder, according to a third embodiment of the invention.

FIG. 7 is a block diagram of the shuttle envelope feeder with vacuum suction cup assist, including valves and controlling mechanism, according to the third embodiment of the invention.

DETAILED DESCRIPTION OF THE INVENTION

Referring to FIG. 2A, a shuttle envelope feeder 200, according to the present invention comprises a shuttle plate 150 operable between a first position under an envelope stack and a second position that is at least partially remote from the envelope stack. The shuttle plate 150 has a surface 252 dimensioned for receipt of an envelope. The surface 252 has a leading edge 254. The shuttle plate 150 has an orifice 240 passing through the surface 252. The shuttle plate 150 further has a recessed area 280 formed in its surface 252 in proximity to the orifice 240 and extending at one end to the leading edge 254 of the surface 252. The recessed area 280 has at least one orifice 181 passing therethrough and in communication with a shuttle vacuum valve 256 (seen in FIG. 3) to form a vacuum gripping mechanism 180.

Referring now to FIG. 2B, the vacuum envelope feeder further comprises a suction cup 230 having an upper rim 232 and a lower neck 234. The lower neck 234 has an opening formed therein, which is connected to a hollow rod 233, the rod, in turn, is in communication with a suction cup vacuum valve 238 (seen in FIG. 3).

The suction cup 230 is thus in cooperative engagement with an actuator or air cylinder 236, which, in turn, is in communication with an air cylinder valve 262 (seen in FIG. 3). The actuator 236 moves the rod 233 and thus the suction cup 230 between an extended position that passes the suction cup through the orifice 240 in the shuttle plate 150 and a retracted position so that the suction cup resides inside the orifice and the upper rim 232 of the suction cup 230 is at least flush with the surface 252. The orifice 240 is dimensioned so that the suction cup 230 and/or the hollow rod 233 is not in contact with the orifice and not in obstruction with the movement of the shuttle plate.

Referring further to FIG. 3, the vacuum envelope feeder also comprises a controlling mechanism including a computer 300 (or other programmable logical device) that coordinates an input/output control module 310 by monitoring the shuttle position via an up/down counter 320 in communication with an encoder 330 equipped with a position sensor 331 via a position circuit. The position circuit may consist of an up/down counter 320 in communication with an encoder 330 equipped with a position sensor 331 or an input port that allows the computer to directly read position of the shuttle plate from an absolute encoder or positional resolver.

With the shuttle plate 150 at the first position and the trailing edge of the previous envelope off of the suction cup 230, the actuator 236 moves the cup 230 toward the extended position and the suction cup vacuum valve 238 is activated (vacuum ON). Once the suction cup 230 reaches the extended position, a small time delay is used to insure that the suction cup 230 attaches to an envelope at the bottom of the envelope stack. The actuator then pulls the suction cup 230 toward the retracted position.

Once the suction cup 230 reaches the retracted position, the shuttle vacuum valve 256 is activated to allow the envelope gripping mechanism 180 to acquire the envelope. The suction cup vacuum valve can be deactivated (turned OFF) immediately after envelope is acquired. The shuttle plate 150 then moves toward the second position with the envelope going under a stripper bar 170 so that it is separated from the remaining envelopes in the envelope stack. After clamps 190 (see FIG. 1) on the mail insertion station have grasped the envelope, the shuttle feeder returns to its initial position, ready to acquire the next envelope.

The computer 300 stores parameters such as the real-time shuttle position acquired via a position circuit with an position encoder or resolver 330 having a position sensor 331, envelope width, the distance D between the leading edge 254 of the shuttle plate and the center of the suction cup 230, air valve latencies, air cylinder latencies and system latencies. Based on the parameters pre-stored in the computer and acquired by the computer, the computer calculates a time sequence for actuating the suction cup and activating/deactivating the suction cup vacuum valve for the input/output control module 310 to coordinate the operation of the valves. The specific computer programming and controlling procedures of vacuum and air valves according to such specific parameters is known to people of ordinary skills in the art.

First Embodiment of the Invention

In a first embodiment of the invention as shown in FIG. 4, the shuttle plate 150 comprises an orifice 240 passing through the surface 252. The shuttle plate 150 and the actuator 236 that supports the suction cup 230 are mounted rigidly on a frame 392. The frame moves from a first position to a second position by a rolling mechanism 394 on a horizontal bar 396. The orifice 240 is dimensioned larger than the outer dimension of the suction cup 230 so as to allow the suction cup to reside inside the orifice when the suction cup is in the retracted position.

Second Embodiment of the Invention

In a second embodiment of the invention as shown in FIG. 5, the shuttle plate 150 comprises an orifice 440 passing through the surface 252. The shuttle plate 150 and the actuator 436 that supports the suction cup 430 are mounted on two separate frames 392 and 498, respectively. The shuttle plate 150 mounted on the frame 392 moves from a first position to a second position by a rolling mechanism 394 on a horizontal bar 396. Frame 498 is stationary in relationship to the insertion station. The orifice 440 is in an elongated shape and is dimensioned larger than the outer dimension of the suction cup 430. The suction cup 430 resides inside the orifice when it is in the retracted position, and the suction cup is not in obstruction with the movement of the shuttle plate.

Third and Preferred Embodiment of the Invention

In a third and preferred embodiment of the invention as shown in FIG. 6, the shuttle plate 150 comprises a first orifice 240 and a second orifice 440, both passing through the surface 252. The shuttle plate 150 and a first actuator 236 that supports a first suction cup 230 are mounted rigidly on a frame 392. A second actuator 436 that supports a second suction cup 430 is mounted on a frame 498. Frame 392 moves from a first position to a second position by a rolling mechanism 394 on a horizontal bar 396. Frame 498 is stationary in relationship to the mail insertion station.

The first orifice 240 is dimensioned larger than the outer dimension of the first suction cup 230 so as to allow the first suction cup to reside inside the orifice when the first suction cup is in the retracted position. The second orifice 440 is in elongated shape and is dimensioned larger than the outer dimension of the second suction cup 430. The second suction cup 430 resides inside the second orifice 440 when the second suction cup is in the retracted position, and the second suction cup is not in obstruction with the movement of the shuttle plate.

As shown in FIG. 7, the first suction cup 230 is connected via a hollow rod to a first suction cup vacuum valve 238. A first actuator or air cylinder 236 that moves the first suction cup is in communication with a first air cylinder valve 262. The second suction cup 430 is connected via a hollow rod to a second suction cup vacuum valve 438. A second actuator or air cylinder 436 that moves the second suction cup is in communication with a second air cylinder valve 462.

A computer 300 (or other programmable logical device) stores parameters such as the real-time shuttle position acquired via a up/down counter 320 in communication with a position encoder 330 having a position sensor 331, envelope width, the distance D between the leading edge 254 of the shuttle plate 150 to the center of the first suction cup 230, air valve latencies, air cylinder latencies and system latencies. Based on the parameters pre-stored in the computer and acquired by the computer, the computer calculates a time sequence for actuating the suction cups and activating/deactivating the suction cup vacuum valves for the input/output control module 310′ to coordinate the operation of the valves.

Alternative Embodiments of the Invention

The vacuum suction mechanism of present invention may be replaced by other 15 mechanisms that temporarily acquire envelope through a moving part that is in corporation with the shuttle plate. Examples include a receiving member in place of the suction cup that is charged with static electrons. The static electrons attract the envelope at the bottom of the envelope stack when the receiving member is in close proximity of the envelope. Thereby temporarily secure the envelope onto the receiving member.

In summary, the present invention relates to a shuttle envelope feeder with a vacuum suction cup assist mechanism. The present invention has the advantage of acquiring cupped or bent envelopes in an envelope stack in a very repeatable fashion. The suction cup controlling mechanism is separable from the controlling mechanism of the shuttle plate. One or more suction cups can be individually enabled or disabled according to the conditions of the envelopes in the envelope stack.

Although the invention has been described and illustrated with respect to exemplary embodiments thereof, the foregoing and various other additions and omissions may be made therein without departing from the spirit and scope of the present invention.

Claims

1. An envelope feeder in an envelope insertion machine for removing envelopes from an envelope stack, comprising:

a shuttle plate operable between a first position under said envelope stack and a second position at least partially remote from the envelope stack, the shuttle plate having a surface dimensioned for receipt of an envelope, said surface having a leading edge, the shuttle plate having a first orifice passing through said surface, the shuttle plate further having an envelope gripping mechanism extended to the leading edge and in communication with a shuttle vacuum valve;

a first suction cup having an upper rim and a lower neck with an opening formed therein, said first opening connecting to a first hollow rod and said first hollow rod in communication with a first vacuum valve;

a first actuator in cooperative engagement with the first suction cup for moving the first suction cup between an extended position that passes through the first orifice in the shuttle plate to a retracted position where the upper rim is at least flush with the surface;

means for activating the first vacuum valve at least when the first suction cup is in the extended position so that the first suction cup attaches to an envelope at the bottom of the envelope stack and so that the first suction cup pulls said envelope toward the surface of the shuttle plate as the first actuator moves from the extended position to the retracted position; and

means for activating the shuttle vacuum valve at least when said envelope is pulled toward the surface of the shuttle plate so that the envelope is retained by the envelope gripping mechanism; thereby allowing the shuttle plate to remove said envelope from the envelope stack as the shuttle plate moves to its second position.

2. The envelope feeder according to claim 1, wherein the first suction cup and the first actuator are translationally stationary in relationship to the shuttle plate, and the first orifice is dimensioned so that the first suction cup resides inside the first orifice when the suction cup is in the retracted position.

3. The envelope feeder according to claim 1, wherein the first suction cup and the first actuator are translationally stationary in relationship to the envelope insertion machine, and the first orifice is dimensioned so that the first suction cup resides inside the first orifice when the suction cup is in the retracted position in a manner so that the first suction cup is not in obstruction with the movement of the shuttle plate.

4. The envelope feeder according to claim 1, further comprising:

a second orifice passing through said surface of said shuttle plate;

a second suction cup having an upper rim and a lower neck with an opening formed therein, said opening connecting to a second hollow rod and said second hollow rod in communication with a second vacuum valve;

a second actuator in cooperative engagement with the second suction cup for moving the second suction cup between an extended position that passes through the second orifice in the shuttle plate to a retracted position where the upper rim is at least flush with the surface;

means for activating the second vacuum valve at least when the second suction cup is in the extended position so that the second suction cup attaches to an envelope at the bottom of the envelope stack and so that the second suction cup pulls said envelope toward the surface of the shuttle plate as the second actuator moves from the extended position to the retracted position.

5. The envelope feeder according to claim 4, wherein

the first suction cup and the first actuator are translationally stationary in relationship to the shuttle plate, and the first orifice is dimensioned so that the first suction cup resides inside the first orifice when it is in the retracted position; and

the second suction cup and the second actuator are translationally stationary in relationship to the envelope insertion machine, and the second orifice is dimensioned so that the second suction cup moves within the second orifice when it is in the retracted position in a manner so that the second suction cup is not in obstruction with the movement of the shuttle plate.

6. The envelope feeder according to claim 1, wherein the means for activating the first vacuum valve includes an input/output control module in communication with a programmable logical device for controllably activating the first vacuum valve.

7. The envelope feeder according to claim 6, further comprising a first air cylinder valve connected to the first actuator, said first air cylinder valve controllable by said input/output control module.

8. The envelope feeder according to claim 1, wherein the means for activating the shuttle vacuum valve includes an input/output control module in communication with a programmable logical device for controllably activating the shuttle vacuum valve.

9. The envelope feeder according to claim 4, wherein the means for activating the second vacuum valve includes an input/output control module in communication with a programmable logical device for controllably activating the second vacuum valve.

10. The envelope feeder according to claim 9, further comprising a second air cylinder valve connected to the second actuator, said second air cylinder valve controllable by said input/output control module.

11. A method for an envelope feeder in an envelope insertion machine to remove an envelope from an envelope stack, said envelope feeder having a suction cup operable between an extended position and a retracted position, and a shuttle plate operable between a first position under the envelope stack and a second position at least partially remote from said envelope stack, said shuttle plate having a surface dimensioned for receipt of an envelope, an orifice passing through the shuttle plate, and an envelope gripping mechanism in communication with a shuttle vacuum valve, said method comprising the steps of:

placing the shuttle plate in the first position,

moving the suction cup positioned within said orifice between a retracted position that is at least flush with the surface of the shuttle plate and an extended position that is in contact with an envelope at the bottom of the envelope stack, and

controlling the air pressure within the suction cup so that the suction cup has a lower air pressure than the ambient air pressure when the suction cup is in the extended position and while it moves from the extended position to the retracted position;

whereby the envelope at the bottom of the envelope stack is pulled down toward the surface of the shuttle plate so as to facilitate the acquisition of said envelope by the envelope gripping mechanism.

12. A method for an envelope feeder in an envelope insertion machine to remove an envelope from an envelope stack, said envelope feeder having a first suction cup operable between an extended position and a retracted position, a second suction cup operable between an extended position and a retracted position, and a shuttle plate operable between a first position under the envelope stack and a second position at least partially remote from said envelope stack, said shuttle plate having a surface dimensioned for receipt of an envelope, a first and a second orifice each passing through the shuttle plate, and an envelope gripping mechanism in communication with a shuttle vacuum valve, said method comprising the steps of:

placing the shuttle plate in the first position,

moving the first suction cup positioned within said first orifice between a retracted position that is at least flush with the surface of the shuttle plate and an extended position that is in contact with an envelope at the bottom of the envelope stack, and

controlling the air pressure within the first suction cup so that the first suction cup has a lower air pressure than the ambient air pressure when the first suction cup is in the extended position and while it moves from the extended position to the retracted position;

moving the second suction cup positioned within said second orifice between a retracted position that is at least flush with the surface of the shuttle plate and an extended position that is in contact with an envelope at the bottom of the envelope stack, and

controlling the air pressure within the second suction cup so that the second suction cup has a lower air pressure than the ambient air pressure when the second suction cup is in the extended position and while it moves from the extended position to the retracted position;

whereby the envelope at the bottom of the envelope stack is pulled down toward the surface of the shuttle plate so as to facilitate the acquisition of said envelope by the envelop gripping mechanism.