BLENDER
A food-processing device for blending and mixing food comprises a mixing vessel, a blade holder, and a motor base. The motor is a high power motor. The device has various safety features designed for the high power motor. The blade holder comprises a safety mechanism that prevents the motor base from operating without the mixing vessel covering the blade. The mixing vessel also contains emitters that interact with detectors on the motor base that can allow a user to select an alternate blend speed according to the mixing vessel that is attached.
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This application is a continuation of Ser. No. 15/838,217, filed on Jan. 11, 2018, which is in turn a continuation of Ser. No. 14/507,180, filed on Oct. 6, 2014, which is in turn a continuation-in-part of Ser. No. 14/047,954, filed on Oct. 7, 2013.
FIELD OF THE INVENTIONThe present invention relates to household and kitchen appliances. In particular, the present invention relates to blenders and food processors. Even more particularly, the present invention relates to high performance blenders with various safety features and alternate blending speeds.
BACKGROUNDTraditionally, blenders are mainly used for blending liquid or relatively soft solid such as fruits and vegetables. Over the years, different receipts with more solid food, such as meats and ice, for blenders have been developed. These solid or dry foods are significantly more difficult to break and mix together. Therefore, there are increasing demands for high performance blenders with more rigid blades that are capable of mixing and blending different kinds of food. To break different kinds of solid foods, a strong and powerful motor must be used to drive the blades of the blender. Yet, various problems associated with a high power motor limit the design and the functionality of blenders.
One obvious problem associated with a powerful motor is the significant increase in size and weight of the blender. Since the weight of the blender increases with the size of the motor and the size of the blender also increases with the size the housing that holds the motor, the use of a large motor makes the blender less desirable for many consumers due to the size and the weight. To limit the size, the motor will have to be confined in a smaller housing. Yet, this reduces the ventilation of the housing, causing potential overheating the motor.
Overheating of the motor poses different safety and durability concerns to a blender. The overheating of a powerful motor confined in small housing could damage the components of the motor. The heat could melt the plastic and the electrical wires inside or nearby the motor housing, causing to emit hazardous and highly unpleasant smell. The melting or even burning of the electrical wires could also significantly increase the chance of electricity leakage and even cause the burning of the blender. The heat from the motor could also be transferred to the outer housing or the shell of the blender. This could melt the external design of the blender and potentially burn and injure the user.
Another type of overheating associated with a powerful motor is the overheating of the blade assembly. The blades in a blender rotate in a significantly higher speed when it is driven by a powerful motor. The friction associated with the high-speed rotation often generates a large amount of heat. When liquid or semi-liquid foods are put in the blender, the heat of the blades can usually quickly disperse over the foods. However, when solid and dry foods are being processed, heat accumulates around the moving part of the blade assembly and transfer to other parts of the blender. The heat could melt the plastic parts of the blender, releasing hazardous gas and endangering the health of the users. Any damage to the blade assembly could also affect the rotational speed of the blades, cause the blade to vibrate irregularly and vigorously, and even change the blade's rotation path. This affects the efficiency of the blender and sometimes renders the blender inoperable.
Another problem associated with a powerful motor is the vibration of motor and the blender. For a small motor, such as a 200-watt motor, the vibration is usually hardly noticeable. However, when a more powerful motor is used, the vibration increases significantly. Not only does the vibration cause unpleasant sound and unwanted movement of the blender, but it also creates other safety and design issues. In general, a blender with notable vibration is undesirable and perceived as unreliable by the customers. Unmanageable vibration could cause the blender to topple and fall. Vibration could also affect the normal horizontal rotation of the blades and reduce the efficiency of the blender.
Blenders with powerful motors are subject to heavy usage. They are often used for crushing ice and breaking rigid and dry foods. The blades become an expensive part of the blender because it must be durable and have the quality required for crushing and breaking hard objects. The blades must also be sharp and rigid for their usage. This raises safety concerns to the blender with powerful motors since the blades could severely injure the users if the users accidentally contact the blades. Even if a blender is properly designed, it could still pose a threat to the users, especially children, because of improper installation or unintended use. This safety concern is of particular importance for high performance blender because of its enhanced ability in cutting through more solid objects.
Blenders with powerful motors are usually relatively large in size. Its blade holder and the mixing vessel are also larger than those in regular blenders. Owing to their size, it can be difficult for users to attach the mixing vessel to the blade holder because the users may not be able to firmly grip the large mixing vessel with one hand. One common difficulty is not being able to screw the blade holder from the mixing vessel to a satisfactory tightness. If the blade holder is not screwed on tight enough, liquid may seep out of the mixing vessel through the blade holder into the motor unit of the blender. However, if the blade holder is screwed onto the mixing vessel too tightly, after the blending is done, it may be difficult to unscrew the blade holder from the mixing vessel. In particular, after each blending, the mixing vessel contains the blended food or liquid. Users would normally be hesitant to forcefully turn the blade holder due to the concern that the content in the mixing vessel may splash at the moment the blade holder starts unscrewing from the mixing vessel. The blending of the liquid content in the mixing vessel could also cause some of the liquid to go into the junction of the mixing vessel and the blade holder, sealing the mixing vessel and causing the blade holder even more difficult to unscrew. Moreover, the exterior of the mixing vessel is often wet and slippery. Thus, screwing and unscrewing the blade holder and the mixing vessel could be extremely difficult, especially for high power blenders with large mixing vessels.
Blenders with powerful motors are difficult to build and it is extremely challenging to address all safety and design problems associated with a large motor. Accordingly, a long-felt need remains for a high performance blender system that is safe, convenient to use and easy to clean.
SUMMARYThe embodiments of the present invention relate to a food processing device preferably with a high power motor. The food processing could be a blender or other similar devices. Some embodiments comprises a mixing vessel. The mixing vessel has a wall that defines an opening that can be connected to a blade holder. The blade holder has a top surface and a bottom surface. It is capable of removably attached to the mixing vessel by some mechanism such as a screw means.
In some embodiments, the top surface of the blade holder has a blade rotatably mounted on the blade holder and a pin mechanism with a movable pin. The bottom surface has a couple gear and a recess with a particular shape. The pin mechanism is also visible from the bottom surface of the blade holder. The pin mechanism is located at a first particular location on the bottom surface. The pin mechanism operates across the top surface and the bottom surface. The pin is capable of protruding from the top surface or from the bottom surface, depending on whether it is being depressed. When the pin is not depressed, its natural position is being protruding from the top. When it is depressed, it moves from the top surface to the bottom surface and becomes protruding from the bottom.
In some embodiments, the coupling gear and the blade are connected through an axis. The axis is surrounded by a plurality of ball bearings, which are confined by a sleeve. The ball bearings reduce the friction and heat generated by the high-speed rotation of the blade and the coupling gear.
In some embodiments, the food processor also has a motor base having a bottom cover removably attached, a skirt removably attached, a motor housing with a motor located therein, and a well located on top of the motor housing. The well is capable of allowing the blade holder to be inserted therein.
The motor housing has a ceiling and a bottom entrance. In some embodiments, the motor is mounted only on the ceiling of the motor housing but not other locations. It is mounted on the ceiling indirectly through a motor bracket. The motor bracket is mounted on the ceiling through a plurality of dampers. The dampers being located between the ceiling and the motor bracket and located underneath the motor bracket. The bottom entrance of the motor housing is smaller than the motor to prevent the motor from falling outside of the motor housing. The motor is connected to a fan at its bottom end and is also connected to an electrical circuit that controls the motor. The fan is located outside the motor housing and below the bottom entrance.
In some embodiments, the motor has a high power, preferably over 950 watts. In an embodiment, the motor is a 1200 watt motor.
The well of the motor base has a well surface with a raised area, an impeller, an actuator, and a drainage hole on the surface. The raised area complementarily matches the particular shape of the recess on the bottom surface of the blade holder. The impeller is connected to the motor such that it is being driven by the motor. The actuator is connected to the circuit and is located at a second particular location on the surface of the well. When the actuator is pressed, the actuator closes the circuit. The drainage hole is connected to a third location below the motor housing through a tunnel.
When the mixing vessel is connected to the blade holder, the wall of the mixing vessel causes the pin to protrude from the bottom surface. The matching in shape of the recess and the raised area aligns the blade holder and the motor base when the blade holder is inserted into the well of the motor base. The position of the actuator and the pin mechanism also matches when the blade holder and the motor base align. This causes the protruding pin to depress the actuator. The food processor is capable of automatically being turned on when the blade holder connected to the mixing vessel is inserted into the well of the motor base.
The bottom cover of the motor base comprises a plate and a cup shaped housing. The plate has a plurality of openings thereon. The cup shaped housing is partially located inside the motor housing when the bottom cover is attached to the motor base, and housing substantially isolates the motor housing from the third location, preventing liquid from the drainage hole from entering the motor housing. The skirt of the motor base is located in between the motor housing and the bottom cover. The skirt is removably attached to the plate of the bottom cover and to the motor housing. It is larger than the entrance to provide mechanical support to the motor base.
In some embodiments, the circuit has a soft start function and a timer that automatically turns off the motor after the motor has been operating for a predetermined amount of time. The circuit being connected to a switch mounted on the motor base. The switch has three different status positions—a released position, a first depressed position and a second depressed position. The released position opens the circuit while both the first depressed position and the second depressed position close the circuit, wherein the first depressed position automatically returns to the released position once the switch is no longer depressed, but the second depressed position stays the circuit closed when the switch is no longer depressed.
Some embodiments of the present invention also relate to system for unscrewing a mixing vessel from a blade holder. It is an object of the present invention to provide a tool for use with a mixing vessel and blade holder to unscrew from mixing vessel from the blade holder. The tool is a wrench that has an elongated handle and a socket complementarily shaped to the bottom surface of the blade holder, such that when the socket is placed on the bottom surface of the blade holder, the socket engages the blade holder. When the handle of the wrench is rotated, a torque is applied to the blade holder, thus enabling the user to unscrew the blade holder from the mixing vessel when rotated in one direction (e.g. clockwise), and tighten the mixing vessel to the blade holder when rotated in the opposite direction (e.g. counter-clockwise). Features of the mixing vessel that also aid in unscrewing the blade holder from the mixing vessel include one or more protrusions on the outer surface of the mixing vessel that allow the user to more easily grip the mixing vessel while applying torque to the blade holder via the wrench handle.
In one aspect, the system for opening a mixing vessel has a wrench, a blade holder and a mixing vessel. The wrench has an elongated member having a first end portion and an opposing second end portion. Attached to the opposing second end portion is a head region that has a bottom surface and a top surface. The bottom surface of the head region has a recessed socket.
The blade holder has a top surface, a bottom surface, and an inner threaded surface. The bottom surface has at least one protruding member complementarily shaped to a recessed region of the socket on the wrench, which permits the socket to engage with the bottom surface of the blade holder. A mixing blade is attached to the blade holder via a blade attachment member that runs substantially through the central vertical axis of the blade holder. This blade attachment member secures the blade to the blade holder.
The mixing vessel has a closed top region, an open top when unscrewed from the blade holder, and an outer surface. The outer surface of the mixing vessel has an lower threaded portion adapted to engage the blade holder inner surface. The outer surface of the mixing vessel also has at least one gripping member protruding from the mixing vessel outer surface. The user can screw on the blade holder to the mixing vessel by hand or by using the wrench clockwise (or counterclockwise, should the threading of the mixing vessel and blade holder be reversed from a traditional configuration). To disengage the blade holder from the mixing vessel, the user places the socket over the bottom surface of the blade holder. A horizontal rotation of the wrench rotates the blade holder due to complimentary shape of socket and the bottom of the blade holder, which prevents mere spinning of the wrench without also rotating the blade holder. To aid in disengaging the mixing vessel from the blade holder, the user grips the gripping members of the mixing vessel while rotating the wrench to unscrew the blade holder from mixing vessel.
In other embodiments of the invention the gripping member on the outer surface of the mixing vessel is a plurality of ribs extending substantially form the top of the mixing vessel to the bottom of the mixing vessel.
In other embodiments of the invention, the plurality of gripping members are four ribs substantially equally spaced, running lengthwise from the top of the mixing vessel to the bottom of the mixing vessel.
In yet other embodiments of the invention, the gripping member is a handle on the outer surface of the mixing vessel. The socket on the wrench is characterized as having a central recessed region having an outer periphery, and a plurality of recessed grooves extending radially outward from the outer periphery of the central recessed region, and the protruding member on the blade holder bottom surface is a protruding circular region complementarily shaped to the recessed inner circular region of the socket. The central recessed region and plurality of grooves in the socket are adapted to engage the at least one protruding member on the bottom surface of the blade holder.
In some embodiments of the invention the protruding member on the bottom surface of the blade holder further comprises a plurality of protruding members extending radially form a periphery of the protruding circular region on the blade holder.
The wrench, blade holder, and mixing vessel have several advantages over the prior art. Since the socket is complimentarily shaped to the bottom surface of the blade holder, the wrench can easily be placed over the blade holder and easily removed from the blade holder. While easily removable, by having the complimentary shaped structures, the wrench and blade holder do not slip off each other when the wrench is rotated either clockwise (to loosen), or counterclockwise (to tighten) the blade holder and the mixing vessel. After the blade holder and mixing vessel are either tightened or loosed to the user's preference, the wrench is simple lifted off bottom surface of the blade holder. In this way, the user can tighten the mixing vessel and blade holder enough so that the contents of the mixing vessel will not leak out without having to worry about over tightening the mixing vessel, which would later make it difficult to remove the mixing vessel from the blade holder.
The following description is made for the purpose of illustrating the general principles of the invention and should not be taken in a limiting sense. The scope of the invention is best determined by reference to the appended claims.
The invention now will be described more fully hereinafter with reference to the accompanying drawings, in which embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art.
Exemplary embodiments of the present invention are described herein with reference to idealized embodiments of the present invention. As such, variations from the shapes of the illustrations as a result, for example, of manufacturing techniques and/or tolerances, are to be expected. Thus, embodiments of the present invention should not be construed as limited to the particular shapes of regions illustrated herein but are to include deviations in shapes that result, for example, from manufacturing.
Turning to the drawings,
Turning to
Similar to the first mixing vessel 202, the second mixing vessel 204 also has ridges 224 on its external and internal walls. The second vessel 204 has only one opening 222, which contains screw threads 228 for the blade holder 104 to engage with the second vessel 204. The second vessel 204 shows a dome shape. The second vessel 204 is resting on external ridges 224. The external ridges 224 are shaped so as to permit the second vessel 204 to rest on the apex of the dome shaped vessel 204 without tipping over. As those skilled in the art will appreciate, the number of ridges 224 may be varied so long as the vessel 204 can stand upright.
The third vessel 206 shown is similar to the second vessel 204 except it has a handle 262 for users to grip the vessel 206. The external ridges 224 are no longer needed for anti-slippery reason but they could still be present in some embodiments of third vessel 206 for aesthetic reasons. The fourth vessel 208 also has a handle 262 on its side. It has two openings 220 and 222, one at the top and one at the bottom. The bottom opening 224, similar to that of the first vessel 202, has a connection mechanism such as screw threads 228 that pair with the screw threads of the blade holder 104. The fourth vessel 208 has a spout 282 at the top opening 222. A lid not shown in the figure can be used to cover the top opening 222 when the blender 100 is in operation. The designs of the third vessel 206 and the fourth vessel 208 allow users to carry the vessels and to pour out the contents in the vessels more conveniently. As described in greater detail below, the lift up of the mixing vessel 102 with blade holder 104 triggers a safety mechanism of the blender 100 and stops the blender 100 from operating immediately. Thus, a mixing vessel 102 with a handle 262 provides a safe but convenient way to operate the blender 100.
While four different embodiments of the mixing vessel 102 are shown in
Turning to
Below the screw threads 422, a plurality of rectangular safety pins 426 are adjustable mounted on and engaged with the blade holder 104. The number of safety pins 426 can vary based on the design of the embodiments of the invention. The safety pins 426 are located inside a plurality of pin housing 427. The pin housing 427 is a cavity that creates an opening on the top surface of the blade holder 104 and an opening on the bottom surface of the blade holder 104. The safety pins 426 can slide vertically across the plastic base 402 but they are locked such that they cannot detach from the plastic base 402. When a safety pin 426 slides to its uppermost position, it protrudes from the top inner surface of the plastic base 402 while it is completely hidden on the bottom surface of the plastic base 402. When a safety pin 426 slides to its lowermost position, it protrudes from the bottom surface of the plastic base 402 while it is completely hidden on the top inner surface of the plastic 402. The protrusion of the safety pins 426 is best shown in
The internal design of the blade holder 104 provides different features that are particularly suitable for a high power blender. When a high power motor drives the coupling gear 442 of the blade holder 104, all moving components of the blade holder 104 are moving with a high rotational speed. This generates friction and a large amount of heat that could damage or even melt the plastic base 402. The central axis 474 is particularly dangerous because largely its entire surface area is inside the plastic base 402. To resolve the overheating problem, in some embodiments of the present invention, ball bearings 482 are used along the central axis 474. The ball bearings 482 reduce the surface area of the central axis 474 that is contact with other surfaces during rotation. Hence, any rotational friction is significantly reduced. Although two lawyers of ball bearings 482 are shown in the preferred embodiments, those skilled in the art will appreciate that any number of ball bearing layers can be used. The ball bearings 482 are confined by the sleeve 476. The sleeve 476 can be made of stainless steel, nylon or other effective heat dissipating materials known or developed in the art. By using effective heat dissipating materials, any heat generated by the moving components of the blade holder 104 can be dissipated quickly. Overheating can thus be prevented.
Turning to
In some alternative embodiments of the present invention, the raised areas 604 are on the inner wall of the well 600. In these alternative embodiments, the recesses 444 are also on the outer wall of the blade holder 104 rather than underneath the blade holder 104. The idea for the alternative embodiments is similar to the idea in
In some embodiments, the surface of the well 600 also contains an impeller 602 at its center. Underneath the surface of well 600, the motor base 106 includes a motor 640 (shown in
In some embodiments, the surface of the well 600 also contains a plurality of drainage holes 630. Since the motor housing 106 contain different electrical components such as the motor 640, washing it is usually not recommended to protect the electrical components from any damages. Yet, the usage of the blender 100 would accumulate dirt in the well 600 and sometimes the contents in the mixing vessel 102 may drop onto the surface of the well 600. For example, liquid may leak from the mixing vessel 102 to the well 600 during blending due to worn out of the material, defective gasket or improper installation. Owing to the features of the well 600, such as various raised areas 604, liquid can easily accumulate in the well 600 if the well 600 is not properly and complete dried. Any liquid accumulated could slowly create rusting of the metallic components on the well 600, such as the impeller 602. Moreover, liquid could slowly enter the internal housing 610 of the motor base 106 through the impeller 602 because impeller 602 is a rotational component that cannot be completely sealed. Any liquid entered the internal housing 610 could damage the impeller 602 and the motor 640 and affect the lubrication of the impeller 602. This severely affects the blender's functionality and durability. The drainage holes 630 allow any liquid to be drained from the surface of the well 600 to travel through the drainage holes 630 and tunnels 632 (shown in
In some embodiments, the surface of the well 600 also contains a plurality of safety actuators 670 extending upward from the surface of the well 600. The safety actuators 670 are pressure-activated switches. The safety actuators 670 is connected to a mechanism, which will be discussed in greater detail below, to complete the circuit of the motor 640 when the safety actuators 670 are pressed downward. In preferred embodiments, all safety actuators 670 must be pressed downward in order to complete the circuit. The motor 640 can only operate when its circuit is complete. Hence, if any one of the safety actuators 670 is not pressed, the motor will not be turn on even though the user turns on the blender.
The safety actuators 670 and the safety pins 426 (shown in
If the mixing vessel 102 is not screwed into the blade holder 104, the safety pins 426 are at its natural uppermost position. They do not extend out from the bottom of the blade holder 104. They are unable to depress the safety actuators 670. Alternatively, in some other embodiments, the safety pins 426 can slide freely when the mixing vessel 102 is not screwed into the blade holder 104. Thus, these safety pins 426 do not exert sufficient pressure or force to depress the safety actuators 670. These safety mechanisms prevent the motor 640 from turning on unless the mixing vessel 102 is screwed into the blade holder 104 before placing it on the motor base 106. This prevents the blade 404 from moving when it is not covered by the mixing vessel 102. Hence, a user cannot insert only the blade holder 104 alone into the well 600, turn on the motor 640, and cause the blade 404 to rotate without a cover. This significantly reduces the chance of injury caused by the blade 404.
Besides the safety mechanism, the interaction between the safety actuators 670 and the safety pins 426 also allows the blender 100 to be used more conveniently. In some embodiments, unlike many electrical appliances, the default status of the blender 100 is set as “on,” meaning the user is not required press any button to cause the blender to operate. The user is only required to put the food into the mixing vessel 102, screw the blade holder 104 in to connect it to the mixing vessel 102, insert the blade holder 104 into the well 600 of the motor base 106 to align the blade holder 104 with the motor base 106, then the motor 640 will automatically be turned on and the blade 404 will start rotating to blend the contents in the mixing vessel 102. This is because when the blade holder 104 is properly aligned with the motor base 106, the extended safety pins 426 will depress the safety actuators 670 to complete the motor's circuit, causing the motor with default “on” status to operate. In some preferred embodiments, the blade holder 104 is not locked to the motor base 106 by any means. Users can freely and immediately lift the blade holder 104 and the mixing vessel 102 at any time. Hence, when the blender 100 is operating to blend the contents in the mixing vessel 102, the user can remove stop the blender 100 by simply removing the blade holder 104 and the mixing vessel 102 from the motor base 106. Since it is normally difficult to see the content in turbulence when it is being blended, such mechanism allows the user to examine the content more conveniently. The user may simply lift the mixing vessel 102 so that the blade 404 stops rotating, examine the extent of blending of the content, put the mixing vessel 102 and the blade holder 104 back into the well 600 for more blending if necessary. The entire process is automatic because the user is not required to press any button. The motor is set as default “on,” unless the user turns the switches of the blender to “off.”
In some embodiments, a special type of switch is used to control the operation of the blender 100 in additional to or in replace of the default “on” system. The special switch is a push button switch where the button can be pushed in halfway as a pulse function. Thus, the special switch has at least three positions, a released position, a first depressed position and a second depressed position. When the button is pushed halfway, it is at its first depressed position. The switch will complete the circuit and the motor 640 will operate. Yet, as soon as the button is release, the button will return to its released position, opening the circuit and turning the motor 640 off. Thus, when the button is pushed only to its first depressed position, the user is required to hold the button in position in order for the motor 640 to continue to operate. The button can also be pushed fully to reach its second depressed position, then the switch will be locked in the “on” position and will not automatically return to its released position. The user now is not required to hold the button for the motor 640 to operate. In order to turn the motor 640 off, the button must be fully pushed again. Since pushing the button fully to turn on or off the motor creates a time delay in operating the blender 100, the halfway button feature provides a convenient means for the user to stop the blender 100 to examine the contents in the mixing vessel 102 and restart the blender 100 to perform more blending. In these embodiments, lifting the mixing vessel 102 is no longer required to turn off the blender, the mixing vessel 102 and the blade holder 104 can be locked to the motor base 106 by any means that is known and developed in the art.
Now turning to
The motor housing 610 is the main house of the blender 100 at which the motor 640 locates. The motor 640 is connected to a fan 626. The fan is located outside the motor housing 610 at a position outside the motor housing entrance that is defined by the metallic ring 664. The location of the fan 626 allows the fan 626 to operate at a less confined space to maximize its cooling effect.
Now turning to
The motor 640 is not directly mounted on any wall of the motor housing 610. Instead, it is mounted on a motor bracket 652. The motor bracket 652 is only connected to the ceiling of the motor housing 610 through a plurality of rubber dampers 654. The motor 640 with the motor bracket 652 is not connected to any other part of the motor housing 610. In other words, the rubber dampers 654 are the only connection points between the motor bracket 652 and the motor housing 610. Hence, the motor 640 suspends from the ceiling of motor housing 610. The motor 640 drives the impeller 602 through an axis 656.
The connection of the motor 640 to the motor housing 610 through the motor bracket 652 is best illustrated by
Although the motor 640 can be connected to the motor housing 610 by other means, the arrangement of the motor housing 610 suspending from the ceiling of the motor housing 610 through the motor bracket 652 at the connection points of rubber dampers 654 produces least amount of vibration to the blender 100 and significantly reduces the size of the motor housing 610. The feature is of particular importance when a high power motor 640 is used in a confined motor housing 610, such as the ones that have the cone shape or inverted dome shape. Another advantage of the motor 640 suspending from the ceiling of the motor housing 610 is that it allows maximum ventilation from the fan 626. It is because no structural element or bracket that would block some of the ventilation are present at the bottom of the motor housing 610. Since a relatively large fan 626 is required to be used to provide sufficient cooling of the high power motor 640, the fan 626 is located outside the motor housing 610 to limit the size of the blender 100 by limiting the size of the motor housing 610 without compromising the cooling effect of the fan 626.
The motor housing 610 also contains other components. Tunnels 632 are connected to the drainage holes 630 and have outlets at the bottom of the motor housing 610. The outlets are connected to the tubes 650 on the metallic ring 644. Hence, liquid can travel from the drainage holes 630, through the tunnels 632 and the tubes 650, to the bottom cover 616 and escape the motor base 106 through the openings 668. The motor housing 610 also contains switch means 658 that are connected to the motor 640. The switch means 658 are part of the circuit of the motor 640. The switch means 658 are underneath the safety actuators 670. When the safety actuators 670 are pressed by the safety pins 426 by the mechanism discussed in detail above, the safety actuators 670 in turn press the switch means 658, causing all switch means 658 to complete the circuit of the motor 640.
In some embodiments of the present invention, the electronic design of the circuit of the motor 640 provides features that prevent overheating and improves the durability of the blender 100. In some embodiments, the circuit of the motor 640 is a printed circuit board programmed with a soft start function that allows the motor 640 to start slower than its maximum speed, regardless the start is caused by completion of the circuit through the safety actuators 670 or users manually pressing the switches 612. The motor starts with a slower rotational speed then gradually increases its speed to maximum in a short duration. Yet, the duration is longer than that of a motor with a general circuit to reach its maximum speed. Normally, for a high power motor 640, the maximum rotational speed is very high. Turning on a high power motor 640 will result in a surge in torque to move all moving components of the blender 100 from stationary to their maximum rotational speed. The surge in torque entails high mechanical stress on the machine, which results in increased wear of all moving components of the blender 100. It also generates a large amount of heat and could result in overheating. The soft-start circuit of the blender 100 allows the torque and rotational speed of the moving components to build up in a relatively gradual fashion. This prevents excessive torque that initially occurs when the motor 640 is first turned on, thereby preventing damage to the blades 404, the impeller 602, the ball bearings 482 and/or motor 640 and overheating of any components of the blender 100.
In some embodiments, besides the soft-start feature, the circuit of the motor 640 also includes an internal timer that is programmed to automatically turn off the motor 640 after a predetermined duration. In some embodiments of the present invention, the motor 640 has over a thousand watts of power. The motor 640 and all moving components generate large amount of heat even with various features to dissipate heat and proper lubrication. Prolonged operation of the blender 100 could cause overheating and damages to the components of the blender 100. The timer limits the operation of the motor 640 to a predetermined duration. The circuit is programmed to cut off the power to the motor 640 when the motor 640 continuously operates for more than the duration. The motor 640 will be turned off until the user manually turn off the circuit by lifting the blade holder 104 to release the safety actuators 670 and restart the motor again by re-pressing the safety actuators 670 or by manually pressing the button of the switch again. This prevents the blender 100 from continuously operating in the situation such as when the users forget to turn off the blender 100.
In an embodiment of the invention shown in
As shown in
As shown in
The embodiment of the invention as described by blender 800 has emitters 870 and detectors 880. In the preferred embodiment, the blender 800 is automatically activated as follows. When the mixing vessel 810, with the attached blade holder 104, is placed into the well 600 of the motor base 820, the motor base 820 is automatically activated. In this preferred embodiment, the mixing vessel 810 has at least one emitter 870 embedded in the lip 840. One skilled in the art may position the emitter 870 in other positions on the mixing vessel 810. In a preferred embodiment of the invention as shown in
In this preferred embodiment, the motor base 820 has detectors 880 corresponding to the emitters 870 in lip 840 of the mixing vessel 810.
In this embodiment, when the mixing vessel 810, with the attached blade holder 104, is placed into the well 600 of the motor base 820, the protrusion 830 orients the mixing vessel 810 when it is engaged with the recess 860 such that the emitters 870 on the lip 840 of the mixing vessel 810 are positioned to interact with the detectors 880 embedded in the well wall 850. When the emitters 870 interact with the detectors 880, the blender 800 is automatically activated to blend the contents in the mixing vessel 810. In an alternative embodiment of the invention, a user could manually actuate a switch to activate the blender if detectors 880 detect emitters 870.
As shown in
The motor base 820 has at least one detector 880 corresponding to at least one emitter 870 on the mixing vessel 910. In a preferred embodiment of the invention as illustrated in
In this preferred embodiment, when the mixing vessel 910, with the attached blade holder 104, is placed into the well 600 of the motor base 820, the emitters 870 on the lip 840 of the mixing vessel 910 interact with the detectors 880 embedded in the well wall 850 to automatically activate the blender 900.
In the preferred embodiment as shown in
As shown in
In this preferred embodiment, when the mixing vessel 910, with the attached blade holder 104, is placed into the well 600 of the motor base 820, the protrusion 830 functions to secure the mixing vessel 910 in the operating position by engaging the rectangular recess 860. The protrusion 830 rests within the recess 860 so the mixing vessel 910 does not move when the blender 900 is activated. The protrusion 830 orients the mixing vessel 910 when resting in the recess 860 so that the emitter 930 interacts with the detector 890.
Also in this preferred embodiment, the emitter 930 embedded inside the protrusion 830 functions to control the operating speed of the motor base 820. When the emitter 930 interacts with the detector 890, the detector 890 allows the blender 900 to blend at an alternate speed when the user also depresses switch 612. Those skilled in the art will appreciate that more than one type of emitter 930 and detector 890 can be used. Thus, different mixing vessels may have different combinations/numbers of emitters 930 and detectors 890 to allow blender 900 to further differentiate between different types of mixing vessels.
In the preferred embodiment of blender 900, for a user to activate the alternative blend speed, the detector 890 must detect emitter 930 and the user must depress switch 612. In an alternative embodiment, the blender 900 can be operated at the alternative blend speed without requiring the user to depress switch 612. When the alternative blend speed is active, an indicator 821 may indicate to the user that an alternative blend speed is active. The indicator 821 can take the form of an LED that changes color, and those skilled in the art can appreciate that the indicator may be a mechanical indicator that changes position when the user activates switch 612.
Alternative blending speeds can include any speed, known by those skilled in the art that can change the consistency or temperature of the blended contents. For example, the blending speed can be increased dramatically such that the friction from the blades can increase the temperature of the blended contents, resulting in a warm soup as a finished product. Or the blending speed may be slow to facilitate ice cream or sorbet making.
Now turning
The complimentarily shaped wrench 700 with the bottom surface of a blade holder 104 allows the user to tighten the blade holder 104 to the mixing vessel 102 more tightly, especially with combination of the use of the elongated ridges 224 on the outer surface of the mixing vessel 102. Using the wrench 700 to tighten the mixing vessel 102 before the mixing vessel 102 is placed on the motor base 106 prevents spillage of the contents within the mixing vessel 102 to the motor base 106. After the contents of the mixing vessel 102 are mixed, the user removes the mixing vessel 102 and blade holder 104 from the motor and disengages the blade holder 104 from the mixing vessel 102 by gripping with one hand the elongated ridges 224 on the mixing vessel 102, placing the wrench 700 over the bottom surface of the blade holder 104, and applying torque to the blade holder 104 by rotating the handle 702 on the wrench 700 counter clockwise.
The invention has been described in terms of preferred embodiments thereof, but is more broadly applicable as will be understood by those skilled in the art. The scope of the invention is only limited by the scope of the following claims and equivalents thereof.
Claims
1. A food processing device, comprising:
- a plurality of mixing vessels, said mixing vessels having: at least one open end; a protrusion located proximately to said at least one open end, said protrusion having at least one emitter embedded in said protrusion;
- a blade holder having at least one blade, said blade holder is capable of being removably affixed to said at least one open end of said mixing vessels,
- a motor base capable of receiving said blade holder affixed to said mixing vessels, said motor base having: a motor for driving said at least one blade of said blade holder; a top surface for receiving said blade holder, a recess on said top surface for receiving said protrusion of said mixing vessels; wherein said recess has at least one detector embedded in said recess for detecting a signal from said at least one emitter in said protrusion of said mixing vessels to power on the motor; and,
- wherein said at least one emitter embedded in said protrusion is capable of emitting a signal to said at least one detector embedded in said recess to activate an alternative blend speed depending on the mixing vessel that is attached.
2. The device of claim 1, wherein:
- The plurality of mixing vessels has at least two open ends;
- Wherein said first open end of said mixing vessel is adapted to be affixed to said blade holder; and,
- said second open end of said mixing vessel is adapted to be affixed to a removable lid.
3. The device of claim 1, wherein:
- Said mixing vessel has a lip located proximately to said at least one open end and extending radially outward from an exterior surface of said mixing vessel, said lip having at least a second emitter embedded in said lip.
4. The device of claim 3, wherein:
- Said motor base has at least a second detector embedded on the top surface of said motor base for detecting a signal from said at least one emitter in said lip of said mixing vessel;
- Wherein the motor base differentiates said plurality of said mixing tables through the interaction between said second emitter and said second detector.
5. The device of claim 2, wherein at least one alternative blending speed blends the container content at a rate such that contents in said mixing vessel can be heated.
6. The device of claim 1, further comprising a user interface located on said motor base, said user interface capable of activating an alternative blend speed of said motor depending on said signal from said emitter in said protrusion in said mixing vessel to said detector in said recess of said motor base.
7. The device of claim 1, wherein said at least one emitter is a magnet.
8. The device of claim 1, wherein said at least one detector embedded in the motor base is a hall sensor.
9. The device of claim 4, wherein said user interface displays the blending speed that is active.
10. A food processing device, comprising:
- a plurality of mixing vessels, said mixing vessels having: at least one open end; a protrusion located in proximity to said at least one open end, said protrusion having at least one emitter embedded in said protrusion;
- a blade holder having at least one blade, said blade holder is capable of being removably affixed to said at least one open end of said mixing vessels,
- a motor base capable of receiving said blade holder affixed to said mixing vessel, said motor base having: a motor for driving said at least one blade of said blade holder; a top surface for receiving said blade holder, a recess on said top surface for receiving said protrusion on said mixing vessel; wherein said recess has at least one detector embedded in said recess for detecting a signal from said at least one emitter in said protrusion of said mixing vessel to power on the motor; and, wherein said at least one emitter embedded in said protrusion is capable of emitting a signal to said at least one detector embedded in said recess to activate an alternative blend speed depending on the mixing vessel that is attached; and, wherein the motor base further comprises a user interface capable of activating an alternative blend speed of said motor depending on said signal from said emitter in said protrusion in said mixing vessel to said detector in said recess of said motor base.
Type: Application
Filed: Apr 13, 2020
Publication Date: Jul 30, 2020
Applicant: Capbran Holdings, LLC (Los Angeles, CA)
Inventor: Colin Sapire (Los Angeles, CA)
Application Number: 16/847,518