This invention relates generally to the field of food preparation, and more specifically to a new and useful system and method for bagging a food item.
The following description of the embodiment of the invention is not intended to limit the invention to these embodiments, but rather to enable any person skilled in the art to make and use this invention.
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Generally, the system 100 functions to contain a set of fresh bags, to dispense a bag into a load position, to receive a completed hamburger (or other foodstuff), to load the completed hamburger into the bag in the load position, and to dispense the bagged hamburger for delivery to a customer, as shown in
The system 100 can package the hamburgers into stock (or standard) paper bags, such as white, wax-coated paper bags approximately four inches square with offset edges on each side of the bags proximal mouths of the bags. The system 100 can additionally or alternatively package hamburgers into custom bags designed for or specific to the system 100. For example, the system 100 can package hamburgers into bags with including custom labels, metallic or conductive inserts, custom holes for alignment in a bag dispenser 120, and/or custom mouth geometries, etc. as described below.
Furthermore, the system 100 can execute the method S100 to automatically load (or “bag”) a completed hamburger into a fresh bag prior to delivery of the completed hamburger to a customer. In particular, elements within the system 100 can execute the method S100 to dispense a fresh bag into a load position, to open a mouth of the bag, to insert a freshly cooked and assembled hamburger into the bag, and to dispense the bag—now containing the hamburger—for subsequent delivery to a patron, as shown in
Though the system 100 and the method S100 and are described herein as packaging hamburgers into bags, the system 100 and the method S100 can similarly package sandwiches, hotdogs, burritos, tacos, wraps, salads, and/or other foodstuffs into bags of the same, similar, or different geometries and materials. The system 100 and the method S100 can also be incorporated into an automated foodstuff machine to package one or more distinct types of foodstuffs, such as hamburger, hamburger and lettuce wraps, or burritos.
The bag dispenser 120 of the system 100 is adjacent and aligned longitudinally with the ramp no and dispenses a bag into a load position, the bag closed with a mouth of the bag substantially aligned with a top surface of the ramp no in the load position. Generally, the bag dispenser 120 functions to dispense a fresh bag into the load position once a previous bag is loaded with a foodstuff (e.g., a hamburger) and drawn out of the bag dispenser 120. The bag dispenser 120 can therefore contain multiple bags, such as in a stack, can incorporate passive or active actuators or features to sequentially guide fresh bags into the load position, and can incorporate geometry to retain a bag in the load position until the bag is loaded with a hamburger and removed from the bag dispenser 120.
In one implementation, the bag dispenser 120 is configured to dispense bags vertically upward. In this implementation, the bag dispenser 120 can be arranged substantially “inside” the conveyor 150—that is, contained substantially within a boundary of the conveyor 150—as shown in
In one example implementation of the foregoing implementation, the bag dispenser 120 dispenses bags of non-uniform bag thickness (shown in
Furthermore, in the foregoing example implementation in which a bag loaded into the bag dispenser 120 is thicker along its lateral edges) than at or around its center, a stack of these bags may exhibit a total height proximal its center less than its total height along its lateral edges; the bag dispenser 120 can therefore incorporate a static or dynamic feature under the stack of bags to raise the center of the stack of bags such that the center and lateral sides of a bag in the load position are substantially planar, that is, such that a bag currently in the load position is substantially planar and flat prior to opening, such as by the paddle 130 in Block S120. In one example, the bag dispenser 120 includes a platform 124 arranged under and supporting (vertically) a stack of bags, the platform 124 defining an undulating profile with a peak along its center axis, substantially parallel a direction of motion of the conveyor 150, and substantially aligned with a longitudinal center of the stack of bags, such as shown in
Alternatively, the bag dispenser 120 can be configured to receive and to dispense bags of substantially uniform bag thickness. For example, the system 100 can load a recently-assembled hamburger into a custom bag, such as a custom bags including a pair of rectangular folded sheets bonded together along three sides with a food-safe adhesive, each rectangular folded sheet including a series of linear folds along its length perpendicular to the mouth of the bag, as shown in
In an alternative implementation, the bag dispenser 120 is configured to dispense bags downward. In this implementation, the bag dispenser 120 can be arranged substantially “outside” of the conveyor 150—that is, contained substantially outside of the boundary of the conveyor 150—as shown in
In one example implementation in which the bag dispenser 120 dispenses bags of non-uniform thickness, as described above, the bag dispenser 120 can include a hopper defining an arcuate in profile, as shown in
In the foregoing implementation, the bag dispenser 120 can feed fresh bags into the load position via gravity. For example, the bag dispenser 120 can include a weight (e.g., a free weighted platen or piston) that rests on the top of the stack of bags to force the stack of bags downward, therefore motivating a bag at the bottom of the stack into the load position. Alternatively, the bag dispenser 120 can include a pneumatic ram, an electromechanical linear actuator, or any other suitable actuator arranged over the stack of bags (e.g., within the hopper) and configured to actively drive the stack of bags through the hopper and toward the load position. For example, the bag dispenser 120 can include a pneumatic ram that applies a downward force to a piston running in the hopper over the stack of bags, and the bag dispenser 120 can execute Block S110 (described below) to manipulate air pressure supplied to the pneumatic ram to maintain a substantially constant aggregate force on a bag at the bottom of the stack and entering the load position as each successive bag in the stack of bags in shifted into the load position. In particular, the bag dispenser 120 can adjust (e.g., increase) a force applied by the pneumatic ram onto the piston to compensate for a reduced total weight of the stack as successive bags are drawn out of the bag dispenser 120.
However, the bag dispenser 120 can include a hopper of any other form and arranged in any other way fully or partially inside or outside of the conveyor 150, and the bag dispenser 120 can execute Block S110 in any other way to control dispensation of each successive bag into the load position.
The bag dispenser 120 can also include a hook 122 (or post, stud, pin 122, etc.) to engage a hole (i.e., bore) in each bag in the stack of bags loaded into the bag dispenser 120. For example, each bag loaded into the bag dispenser 120 can feature a pair of holes near its mouth and spaced apart by a width greater than a typical or maximum width of a hamburger assembled within the automated foodstuff assembly apparatus, and bag dispenser can feature a pair of pins extending from a base of the hopper (containing the bags) toward and passed the load position, the pins passing through the bores in the bags, and the conveyor 150 executing Block S130 of the method S100 to sequentially advance hamburgers between the pair of pins and into corresponding bags. In this example, the conveyor 150 can continue to advance a hamburger forward once inserted into a bag thus retained by the pair of pins—as in Block S140—to tear the bag around the pins, thereby releasing the bag from the bag dispenser 120; the bag dispenser 120 can thus load a subsequent bag into the load position, and the pair of pins can similarly retain the subsequent bag. In this example, the pair of pins can alternatively extend a minimal distance past a plane of a flat bag in the load position such that the holes in a bag are elevated off of the pins when deformed during insertion of a hamburger into the bag. In another example, the bag dispenser 120 can incorporate a hook 122 supported off of a side of the hopper and looping downward (or upward for the bag dispenser 120 that dispenses bags downward) toward a platform 124 at the base of the hopper. In this example, a portion of the hook 122 extend downward toward the base of the hopper can be of a minimal length (e.g., 1.0″) to engage bores in bags at the top of the stack of bags loaded into the hopper, as shown in
In the foregoing implementation, the bag dispenser 120 can incorporate one or more pins, hooks, or similar features that are circular in cross-section, tapered in cross-section, define a knifed edge, or are of any other suitable geometry or cross-section. For example, as shown in
In the foregoing implementation, the bag dispenser 120 can be configured to dispense a bag that includes a section along its bottom layer that extends beyond its top layer across the mouth of the bag (or vice versa for a bag dispenser 120 than dispenses bags downward) as shown in
The bag dispenser 120 can also include a lip extending from the ramp no toward the bag, the lip retaining a lower layer of a bag—in the load position—along the mouth of the bag, as shown in
In a similar implementation, the bag dispenser 120 can additionally or alternatively define a lip extending longitudinally along each side of the outlet of the hopper and across the load position, the lips configured to retain the left and right sides of a bag in the load position. For example, the bag dispenser 120 can be configured to dispense a bag featuring a set of folds on its left and on its right side, left and right folds along the top surface of the bag (i.e., the exposed surface of the bag in the load position) inset from adjacent folds of the bag along its bottom surface (i.e., a surface facing a top surface of a lower bag in the stack of bags), such as shown in
The bag dispenser 120 can similarly include a set of rollers—with axes perpendicular to the direction of motion of the conveyor 150—arranged along the load position of the bag dispenser 120. In this implementation, the rollers can function like the pair of lips described above to retain the opposing edges of folds along the sides of a bag in the load position until the bag is pulled out of the bag dispenser 120 by the conveyor 150, as in Block S140. However, the bag dispenser 120 can include any other component or feature to guide a bag into the load position and to support and/or retain the bag in the load position.
The bag dispenser 120 can therefore execute Block S110 of the method S100, which recites dispensing a bag into the load position, a mouth of the bag substantially aligned longitudinally with a foodstuff and facing the foodstuff in the load position. Generally, the bag dispenser 120 executes Block S110 to move bags into position to be opened (in Block S120) to accept hamburgers (in Block S130) as subsequent hamburgers are conveyed into the system 100, bagged, and dispensed or delivery to customer. For example, the bag dispenser 120 can actively implement Block S110 by activating an actuator—such as according to closed feedback control—coupled to the platen supporting a stack of bags to elevate the platen toward the load position, thereby shifting a bag arranged at the top of the stack of bags into the load position and aligning the bag with an advancing hamburger.
As shown in
In the implementations described above in which bags are dispensed into the load position from the bottom up (shown in
In another implementation, the bag dispenser 120 can execute Block S112 to feed a stack of fresh bags laterally into the hopper. For example, the bag dispenser 120 can execute Block S112 by controlling various actuator integrated thereinto: to drive a bottom of the hopper (i.e., platform 124) into a fully-retracted position (e.g., fully downward) once the hopper is (sufficiently) emptied; to open a door on a lateral side of the hopper; to retract one or more pins from the hopper or to transition the pin(s) into a reload position; to insert a fresh stack of bags laterally into the hopper, such as from a magazine of fresh bags; to transition the one or more pins back into a dispense position; to close the door of the hopper; and to raise the platform 124 within the hopper until the pins engage corresponding bores in the bags now loaded into the hopper and to move a top bag in the stack of bags in to the load position (as in Block S110).
In another example in which the bag dispenser 120 dispenses bags featuring a notch, groove, or other feature along its perimeter (e.g., on its left and right edges), the bag dispenser 120 can include a pin 122, guide, rail, or other mechanism or feature that engages this feature in bags loaded into the hopper to align these bags. In this example, a first rail can be mounted on a door of the hopper, a second rail can be mounted at a far side of the hopper opposite the door, and the bag dispenser 120 can execute Block S112 to open the door, insert a stack of bags into the hopper with the stack of bags engaging the second rail, and then close the door such that the first rail coupled to the door engages the corresponding feature defined by the stack of bags.
In yet another implementation, the hopper can be configured to accept a bag cartridge 128, the bag dispenser 120 can execute Block S112 to replace a spent bag cartridge 128 with a full bag cartridge 128 filled with fresh bags. For example, the secondary dispenser can be configured to index a full bag cartridge 128 laterally and into the hopper to both expel a spent bag cartridge 128 out of the hopper and to load a fresh (i.e., full) bag cartridge 128 into the hopper. In this implementation, a bag cartridge 128 containing a stack of bags can define a keystone geometry, as described above, with open top and sides to accommodate bags of non-uniform thickness, and the cartridge 128 can engage one or more features in the hopper to lock into position once inserted therein in Block S112, such as shown in
Yet alternatively, the bag dispenser 120 can reset a position of the hopper to accept new bags or a fresh cartridge 128 and then prompt manual reload of the hopper with a stack of fresh bags or a full bag cartridge 128, such as by triggering an alarm or triggering delivery or an electronic communication to an operator of the automated foodstuff assembly apparatus in Block S112.
However, the bag dispenser 120 can include any other suitable type of reloading subsystem and can execute Block S112 in any other way to reload the hopper with fresh bags or prompt manual reload of fresh bags into the hopper.
The system 100 also includes a ramp no arranged ahead of the bag dispenser 120. Generally, the ramp 110 is functions to support the leading edge of the paddle 130 as the paddle 130 is driven toward and into the bag, as in Block S120. For example, the ramp 110 can be physically coextensive (i.e., define a unitary structure) with the lip of the bag dispenser 120 arranged along the inlet side of the bag dispenser 120 at the load position.
In one implementation in which the bag dispenser 120 dispenses bags upwardly, the ramp 110 can be arranged substantially inline with the conveyor 150 and below the paddle 130. In this implementation, the ramp 110 can also provide vertical support to hamburger as the conveyor 150 advances hamburger forward toward the bag dispenser 120, such as shown in
Alternatively, in one implementation in which the bag dispenser 120 dispenses bags downwardly, the ramp no can be arranged just ahead of the bag dispenser 120 over the conveyor 150 and above the paddle 130, such as shown in
The paddle 130 of the system 100 is aligned longitudinally with the ramp 110, is pivotable about a hinge 132 arranged above the ramp 110, and includes a leading edge opposite the hinge and engaging the ramp 110, the paddle 130 extensible between a retracted setting and an extended setting, the leading edge of the paddle 130 in contact with the ramp 110 in the retracted setting and inserted into the mouth of the bag, in the load position, in the extended setting. The actuator 140 of the system 100 is coupled to the paddle 130 and extends the paddle 130 between the retracted setting and the extended setting, the paddle 130 running along the ramp 110 and into the mouth of the bag between the retracted setting and the extended setting. Generally, the actuator 140 functions to transition the paddle 130 into the extended setting to insert the leading edge of the paddle 130 into the mouth of a bag in the load position, and the paddle 130 functions to separate adjacent layers of the bag to enable the hamburger (or other foodstuff) to be inserted in to the bag. In particular, the paddle 130 can be supported on its trailing end (opposite the leading edge) by a hinge 132 and can thus pivot as the leading edge of the paddle 130 runs along the ramp 110 when the actuator 140 transitions the paddle 130 from the retracted setting into the extended setting. As the paddle 130 is contacted by the conveyor 150, a carriage 152 on the conveyor 150, a finger suspended from a carriage 152 on the conveyor 150, or directly by a hamburger advanced toward the bag by the conveyor 150, the paddle 130 can further pivoted about the hinge as the leading edge of the paddle 130 translates away from the bag dispenser 120 to further open the mouth of the bag in preparation to receive the hamburger. The leading edge of the paddle 130 can therefore run along the ramp 110, over the lip, and into the mouth of a bag—in the load position—between a lower layer of the bag and an upper layer of the bag as the paddle 130 transitions from the retracted setting into the extended setting.
In one implementation in which the bag dispenser 120 dispenses bags from the bottom up (as described above), the trailing end of the paddle 130 is hinged over the conveyor 150 with ample space for a completed hamburger to pass between the conveyor 150 (and/or the ramp no) and the paddle 130. In this implementation, when the paddle 130 is retracted, the leading edge of the paddle 130 rests on the ramp no. The system 100 can thus execute Block S120 to trigger the actuator 140 to extend a length of the paddle 130, thereby causing the paddle 130 to rotate about the hinge driving the leading edge of the paddle 130 forward along the ramp 110 and into the mouth of a bag in the load position, as shown in
In a similar implementation, the bag dispenser 120 is substantially inverted and dispenses bags downward into the load position, as shown in
The paddle 130 can therefore incorporate a hinged component defining the trailing edge of the paddle 130 and constrained in translation and in two degrees of rotation within the automated foodstuff assembly apparatus. The paddle 130 can therefore also include an interaction component coupled to the hinged component and free to translate longitudinally relative to the hinged component. The actuator 140 can thus be coupled on one end to the hinged component and on an opposite end to the interaction component, thereby extending and retracting the interaction component relative to the hinged component when activated. Alternatively, the actuator 140 can be pivotably coupled to a rigid frame, crossmembers, or other structure within the system 100 or within the automated foodstuff assembly apparatus and can be pivotably coupled on an opposite end to the interaction component, thereby extending and retracting the interaction component relative to the hinged component when activated. The actuator 140 can thus function to increase and decrease a total effective length of the paddle 130 by transitioning the paddle 130 into the extended setting and into the retracted setting, respectfully.
In the foregoing implementation, the trailer edge of the paddle 130 can additionally or alternatively be supported along a linear or curvilinear slide (or by a similar linkage), and the actuator 140 can motivate the trailing end of the paddle 130 forward along the slide to transition the paddle 130 between the retracted setting and the extended setting. In this implementation, contact by the conveyor 150, the carriage 152, the hamburger, etc. on the paddle 130 can further shift the trailing end of the paddle 130 along the slide as the leading edge of the paddle 130 separates adjacent layers of the bag. For example, the paddle 130 can define a fixed length, the trailing end of the paddle 130 can be hinged and can run inside a linear slide supported over the conveyor 150, the slide constraining translation of the trailing edge of the paddle 130 to a linear direction longitudinally aligned with and inclined over the conveyor 150, and the actuator 140 can drive the trailing end of the paddle 130 forward along the linear slide to transition the paddle 130 from the retracted setting into the extended setting, and vice versa.
Furthermore, because the paddle 130 may contact hamburgers (or other foodstuffs) output by the automated foodstuff assembly apparatus directly as the conveyor 150 advances the hamburgers into the bag dispenser 120, the paddle 130 can be of a food-safe material base material, such as stainless steel, and/or include a food-safe coating, such as Teflon.
The actuator 140 can include any one or more pneumatic, electromechanical, hydraulic, or other suitable type of linear or rotational actuator. The system 100 can also incorporate one or more limits switches or other sensors that output signals corresponding to a position of the actuator 140 and/or a position of the paddle 130, and the system 100 can implement closed loop feedback to control the actuator 140.
The paddle 130 and the actuator 140 can therefore cooperate to execute Block S120 of the method S100, which recites separating an upper layer of the bag from a lower layer of the bag across the mouth of the bag in Block S120, the lower layer of the bag constrained in to the bag dispenser 120. In particular, the actuator 140 can execute Block S120 to extend a leading edge of the paddle 130 into the mouth of the bag, thereby separating a free lip of the bag from a retained lip of the bag proximal the open side of the bag.
In one variation of the system 100, as shown in
In another variation shown in
In a similar variation, each of the one or more pins aligning all or a subset of bags in the bag dispenser 120 can be hollow and feature a nozzle 127 along its length that intersects an internal volume of a bag—between the top and bottom layers of the bag—in the load position. Thus, in this implementation, the system 100 can trigger a valve coupled to the pin(s) to release a blast of air through the nozzles in the pins to expand (and to therefore open) the bag, as in Block 8120. As in the foregoing variation, the system 100 can also control a duration of time that the valve is opened, a volume of air dispensed through the nozzles, etc. to substantially fully open but not tear the bag in the load position.
In another variation, the system 100 includes a friction roller, and the system 100 drives the friction roller across the exposed outer surface of a bag in the load position, in Block 8120, to wrinkle the bag, thereby lifting an exposed layer of the bag, such as around the mouth of the bag. In a similar variation, the system 100 includes a rotating brush with an axis substantially parallel to the length of the mouth of the bag, and the system 100 selectively actuates an actuator coupled to the rotating brush such that the brush contacts, catches on, and pulls a free lip of the bag in the load position, thereby opening the mouth of the bag.
In yet another variation, as shown in
In the foregoing implementation, the bag dispenser 120 can thus be loaded with custom bags, each custom bag featuring a conductive element. For example, the bag dispenser 120 can be configured to receive a custom bag including an aluminum strip arranged on or within a top layer of the bag, such as along a free lip of the mouth of the bag.
Alternatively, the system 100 can apply the conductive element to the bag, such as before the bag is dispensed from the bag dispenser 120. Therefore in one variation, the system 100 can execute Block 8122 of the method 8100, which recites applying a sticker to the bag. In this variation, the system 100 can apply a metalized or conductive sticker to the bag once the bag is dispensed into the load position in Block 8122, and the system 100 can subsequently induce an electric field between the sticker and the electrode 138 to open the bag in Block 8120. In this variation, the system 100 can also print customized stickers for each bag, such as based on a patron's name and/or a customer order number associated with a hamburger designated for a particular bag. In particular, the system 100 can print customized stickers including a restaurant name, a customer or group name, a customer or order number, order details (e.g., hamburger topping, condiment, meat, doneness, bun toast, etc.), nutritional information for the hamburger (e.g., for a customized hamburger order), a QR code or barcode, an image, a time, an order cost, etc. For example, the system 100 can print a recipe for the corresponding hamburger and/or a barcode or QR code linked to the recipe for the hamburger corresponding to a bag currently in the load position to provide a final customer of the hamburger with receipt of the hamburger recipe, such as for quick reordering and/or modification at a later date. Once printed, the system 100 can apply the sticker to an available (i.e., exposed) surface of the bag in the load position, such as by applying the adhesive-backed sticker face down onto a roller and then advancing the roller across an exposed surface of the bag, thereby applying the sticker to the bag. For example, the system 100 can apply an adhesive-backed sticker to the exposed surface of the bag with a portion of the sticker hanging off an edge of the bag—such as across the mouth of the bag; the sticker can be subsequently wrapped around the bag, such as automatically or manually, to close the bag once a hamburger is loaded thereinto.
In the foregoing variation, the system 100 can print a logo, product information, or other details general and/or specific to the hamburger onto a sticker before applying the sticker to the bag. Alternatively, the system 100 can print any one or more of order details, customer information, and/or other hamburger-related data directly onto a bag substantially in real-time as the bag is loaded into the load position, such as by applying a food-safe ink onto a roller and then passing the roller across the exposed surface of the bag. In one example, in Block 8122, the system 100 interfaces with an ink applicator to spray food-safe ink onto the exposed surface of the bag. In this example, the system 100 can apply a conductive ink on the bag in Block 8122, and the system 100 can then charge a conductor arranged over (or under) the bag—once dry the ink—to open the bag, similar to one variation of Block 8120 described above. The system 100 can alternatively induce an Eddy current within the ink to attract the exposed surface of the bag toward the electrode 138, thus opening the bag, as described above. Yet alternatively, in this example, the ink can be electrostatically charged prior to or during application of the ink onto the exposed surface of the bag, and the system 100 can manipulate electrically charge the electrode 138, as described above in Block 8120, to draw the bag open.
The system 100 can print ink containing ferrous or magnetic particulate onto the bag or onto the sticker applied to the bag, and the system 100 can drive an electromagnet (e.g., rather than an electrode 138) adjacent (e.g., over) the load position of the bag dispenser 120 to attract the ferrous or magnetic particulate, thereby opening the bag in Blocks 120. The system 100 can alternatively apply a sticker or label containing a ferrous insert onto an exposed surface of a bag in the load position and similarly drive an electromagnet adjacent the bag, thereby opening the bag as described above. Similarly, the bag dispenser 120 can be configured to dispense a bag containing ferrous or magnetic insert embedded in one side or layer of the bag, such as in the top layer of the bag along the mouth of the bag, and the system 100 can drive the electromagnet adjacent the bag to attract the insert, thereby opening the bag.
However, the system 100 can execute Block 8122 to apply a sticker—such as including any suitable preprinted information and/or custom, hamburger-specific information—onto the bag in any other suitable way, and the system 100 can execute Block 8120 to manipulate the sticker in any other suitable way to open the bag. The system 100 can also execute Block 8122 to print or otherwise apply any other hamburger-related information onto the bag, such as for use by a customer to identify his hamburger or contents of his hamburger or by an operator or server to manage hamburgers output from the automated foodstuff assembly apparatus.
The system 100 can also implement any combination of the foregoing methods and techniques to open the bag. For example, the system 100 can charge an electrode 138 arranged over the load position to induce an electric field over the exposed surface of a bag in the load position, the electric field drawing the mouth of the bag open by a limited distance (e.g., 0.30″ to 0.50″); the system 100 can then actuate a valve to send a blast of air through a nozzle 127 facing the mouth of the bag, the blast of air thus opening the bag further to accept a hamburger in Block S130. In another example, the paddle 130 can include a nozzle 127 adjacent its leading edge, and the system 100 can actuate a valve to send a blast of air through the nozzle 127 and into the bag once the leading edge of the paddle 130 is extended into the mouth of the bag. However, the system 100 can execute Block S120 in any other way to open the mouth of a bag in the load position in preparation to receive a hamburger.
The system 100 also includes the conveyor 150 aligned with the ramp 110 and the bag dispenser 120, supporting a foodstuff, and advancing the foodstuff toward the bag dispenser 120. Generally, the conveyor 150 functions to advance a sequence of hamburgers (or other foodstuffs) forward toward the bag dispenser 120 for insertion into corresponding bags.
In one variation, the conveyor 150 supports a sequence of hamburgers in various stages of assembly, as described in U.S. patent application Ser. No. 13/911,637. For example, a series of topping dispensation modules and condiment dispensation modules can be arranged over the conveyor 150, a bun dispenser within the automated foodstuff assembly apparatus can sequentially load bun heels onto carriages along the conveyor 150, and the conveyor 150 can index the carriages—now loaded with heel buns—forward along the series of topping dispensation modules and condiment dispensation modules. The automated foodstuff assembly apparatus can then selectively and sequentially trigger the topping dispensation modules and the condiment dispensation modules according to a custom hamburger order assigned to each bun heel loaded into the conveyor 150. Once toppings, condiments, a patty, and a bun crown, etc. specified in a hamburger order are assembled onto a corresponding bun heel, the conveyor 150 can index the completed hamburger forward and into a corresponding bag, such as a bag preprinted with order details and/or a customer's name specific to the hamburger. Once the bag and hamburger are released from a corresponding carriage 152 and onto the chute 160, the conveyor 150 can return the carriage 152 back to an initial position within the automated foodstuff assembly apparatus, such as to receive a fresh bun heel or for cleaning (e.g., by spraying with compressed air) before receiving a fresh bun heel.
For example, the conveyor 150 can thus return a receptacle 152 (e.g., the carriage 152) to an initial position in response to dispensation of the foodstuff and the bag onto the chute 160; and the automated foodstuff assembly apparatus can dispense a first food element (e.g., a heel bun) of a second foodstuff (e.g., hamburger) into the receptacle 152 in the initial position; index the receptacle 152 forward to a second position; and dispense a second food element (e.g., a slice of tomato) of the second foodstuff onto the first food element. Meanwhile, the bag dispenser 120 can dispense a second bag into the load position; and the paddle 130 and the actuator 140 can cooperate to separate an upper layer of the second bag from a lower layer of the second bag across the mouth of the second bag. The conveyor 150 can then advance the receptacle 152 toward the bag dispenser 120 to insert the receptacle 152 and the second foodstuff into the mouth of the second bag and then advance the receptacle 152 further forward once the second foodstuff is substantially fully contained within the second bag, thereby drawing the second bag out of the bag dispenser 120. In this example, the conveyor 150 can advance a foodstuff forward, once inserted fully into a bag in the load position, to tear the bag around a hook 122 retained the bag, thereby drawing the bag out of the bag dispenser 120. The conveyor 150 can additionally or alternatively advance the foodstuff forward, once inserted fully into a bag in the load position, to draw a lower layer of the bag from a lip defined by the bag dispenser 120, as described above, thereby removing the bag from the bag dispenser 120. The conveyor 150 can then release the receptacle 152 from the second foodstuff to deposit the second foodstuff and the second bag onto the chute 160 for delivery to a second customer. The conveyor 150, the bag dispenser 120, the paddle 130, the actuator 140, and/or other systems and subsystems within the automated foodstuff assembly apparatus can repeat this cycle to continually assemble, bag, and dispenser assembled foodstuffs. The conveyor 150 can therefore also incorporate multiple receptacles (or carriages) supporting a sequence of hamburgers in various stages of assembly with a most completed hamburger approaching the bag dispenser 120 and a hamburger in an initial stage furthest from the bag dispenser 120, and the conveyor 150 can index the receptacles forward in unison to align the sequence of hamburgers with corresponding topping dispensers, condiment dispensers, bun crown dispensers, and/or the bag dispenser 120, etc.
The conveyor 150 can also include a static or dynamic elevator subsystem 180 that functions to elevate receptacles—supporting hamburgers in various stages of assembly along the conveyor 150—toward the topping dispensation modules and/or toward the condiment dispensation modules. In particular, the elevator subsystem 180 can shift the vertical position of a receptacle 152 toward a condiment or topping dispensation module to reduce a vertical distance between a hamburger supported within the receptacle 152 and an output end of an adjacent topping dispensation module, thereby enabling a relatively high accuracy and repeatability in gravity-feeding toppings from the adjacent topping dispensation module onto hamburgers.
In one example implementation, the conveyor 150 includes a set of carriages (or receptacles) and a stepped track 159 (the elevator subsystem 180) arranged under a series of topping dispensation modules, each carriage 152 configured to support a hamburger bun (loaded with additional toppings, condiments, patties, etc. by subsequent topping dispensation modules) laterally and longitudinally along the stepped track 159, and the stepped track 159 configured to support the hamburger bun vertically, as shown in
In the foregoing example implementation, the stepped track 159 can thus directly provide vertical support to bun heels of hamburgers assembled within the automated foodstuff assembly apparatus, and the stepped track 159 can terminate at the ramp no (and/or at the inlet of the bag dispenser 120); the ramp no (and/or the bag dispenser 120) can thus provide vertical support to hamburgers loaded into bags dispensed from the bag dispenser 120, and bags filled with hamburgers can then drop onto a chute 160 behind the bag dispenser 120 once extracted from the bag dispenser 120, as in Blocks S140 and S150.
Alternatively, the conveyor 150 can incorporate a series of receptacles, each receptacle 152 including a horizontal base platform configured to support bun heels and coupled to a piston that engages the stepped track 159 (the elevator subsystem 180) arranged therebelow, as shown in
In an alternative example implementation, the conveyor 150 can incorporate a series of independently-controlled actuators (the elevator subsystem 180), each actuator arranged below (or otherwise adjacent) a corresponding topping dispensation module and independently extensible to various offset distances from the corresponding topping dispensation module. In this example implementation, the conveyor 150 can advance a series of receptacles forward to distinct positions under a series of topping dispensation modules within the automated foodstuff assembly apparatus and over the series of actuators. The automated foodstuff assembly apparatus can then selectively adjust a height of each actuator to drive the receptacles toward adjacent topping dispensation modules prior to actuation of the topping dispensation modules to dispense topping servings onto hamburgers (in various stages of assembly) supported in the adjacent receptacles. In particular, the automated foodstuff assembly apparatus can track a position of each hamburger passing through the conveyor 150, control operation of the topping dispensation modules to dispense select toppings onto each hamburger based on topping orders corresponding to each hamburger, and selectively adjust the vertical position of each actuator along the conveyor 150 based on a height of each hamburger overhead the actuator such that a top surface of each hamburger is offset below an adjacent topping dispensation module by a target distance despite which toppings have or have not been previously dispensed onto each hamburger. For example, the automated foodstuff assembly apparatus can interface with an optical sensor (e.g., a camera) a depth gauge, or any other suitable sensor to detect a total height of each hamburger supported on the conveyor 150, such as as the conveyor 150 advances the hamburger forward into positions under subsequent topping dispensation modules (e.g., according to machine vision techniques), and the automated foodstuff assembly apparatus can implement these detected hamburger heights to adjust the heights of the actuators. Alternatively, the automated foodstuff assembly apparatus can track which toppings have thus far been dispensed onto each hamburger loaded into the conveyor 150 and apply a known or average height of bun heels and topping types supported by the automated foodstuff assembly apparatus to estimate a total current height of each hamburger currently within the conveyor 150.
However, the conveyor 150 and/or the automated foodstuff assembly apparatus can incorporate any other suitable elevator subsystem 180, actuator, passive component, or active component to set a height of a hamburger loaded into the conveyor 150 below an adjacent topping dispensation module in preparation for dispensation of a corresponding topping serving onto the hamburger.
As described above, the conveyor 150 can also include one or more carriages that engage hamburgers to provide lateral and/or longitudinal support to the hamburgers as the hamburgers are advanced toward the bag dispenser 120.
As shown in
In yet another example, each finger in the set of fingers 154 is flexible and closes around the hamburger in a default configuration, and the corresponding carriage 152 further includes a cable arranged over the outside of each finger, as shown in
In another example, the paddle 130 can define one or more cams along its length, and each finger can include a follower that engages the cams on the paddle 130 to expand the fingers as the hamburger is driven into a bag and passed the bag dispenser 120 by the conveyor 150; once opened, the fingers can thus release the bag and the inserted hamburger. In this example (and in other implementations of the system 100), the paddle 130 can feature vertical fins that extend downward (or upward) along its length to provide additional lateral support to a hamburger during insertion of the hamburger into the bag. In this example, fins extending from the paddle 130 can further define linear cams directly or indirectly engaged by the fingers to transition the fingers from a closed configuration into an open configuration as a hamburger is shifted along the paddle 130 by the conveyor 150. Alternatively, the carriage 152 (exclusive of fingers described above) can contact a rear side of the hamburger to push the hamburger forward into the bag dispenser 120, and the fins extending from the paddle 130 can act directly on the hamburger to provide lateral support to the hamburger as the hamburger is inserted into a bag in the load position. However, one or more fingers suspended off of a carriage 152 within the conveyor 150 can be passively or actively transitioned from a closed configuration into an open configuration in any other way to release a hamburger and a bag from the conveyor 150, as in Block S150.
The conveyor 150 can include a (continuous) chain, cable, tread, or other continuous drive mechanism suspended across one or more idler sprockets and one or more driven sprockets, as shown in
In one implementation, the bag dispenser 120 is arranged within the conveyor 150, the paddle 130 in including downward toward the bag dispensers, and the conveyor 150 drives the foodstuff into the paddle 130, thereby causing the paddle 130 to pivot and the leading edge of the paddle 130 to shift increasingly upward as the foodstuff is driven into the paddle 130. The leading edge of the paddle 130—previously displaced into the mouth of the a bag in the load position—thus elevates by a sufficient distance to enable the foodstuff to pass between the bottom surface of the paddle 130 and the top of the ramp no, the top of the lip, and/or the lower layer of the bag; the lip, hook 122, and/or other feature within the bag dispenser 120 retains the bottom layer of the bag; and the conveyor 150 forces the foodstuff into the mouth of the bag. The bag dispenser 120 can retain the bag with sufficient force to prevent ejection of the bag from the load position until the foodstuff is fully inserted into the bag, and the conveyor 150 can continue to advance the foodstuff forward once fully inserted into the bag to rip, tear, or otherwise eject the bag from the bag dispenser 120.
In the foregoing implementation, the carriage 152 (or the fingers connected thereto) supporting the foodstuff can alternatively contact the paddle 130 to pivot the paddle 130 about the hinge to thus open a bag. Yet alternatively, the carriage 152 (or the fingers connected thereto) supporting the foodstuff can make initial contact with the paddle 130 to pivot the paddle 130 about the hinge, and the foodstuff (e.g., the bun crown of a hamburger) can make subsequent contact with the paddle 130 to further pivot the paddle 130 to open the bag.
In an alternative implementation, the ramp 110 is arranged over the conveyor 150, the bag dispenser 120 is arranged over the conveyor 150 and dispenses bags downward into the load position over the conveyor 150; and the paddle 130 is sprung upward toward a bag in the load position by a spring. In this implementation, once the paddle 130 is extended into the mouth of a bag in the load position, the carriage 152, a finger extending from the carriage 152, and/or a foodstuff supported within the carriage 152 can contact the paddle 130 and act against the spring to lower the leading edge of the paddle 130, thereby further opening the bag as the foodstuff is advanced through the bag dispenser 120 by the conveyor 150.
However, the conveyor 150 can incorporate any other suitable component or subsystem, can be oriented relative to other systems within the automated foodstuff assembly apparatus in any other way, and can function in any other way to support a hamburger bun (and eventually a completed hamburger) throughout operation of the automated foodstuff assembly apparatus and throughout execution of the method S100.
One variation of the system 100 further includes a chute 160 and a plunger 170, the chute 160 aligned longitudinally with the conveyor 150 and adjacent the bag dispenser 120 opposite the ramp 110, and the plunger 170 arranged over the chute 160. In this variation, the conveyor 150 can advance the foodstuff and the bag over the chute 160, and the plunger 170 can extend downward toward the chute 160 to thrust the foodstuff and the bag from the conveyor 150 onto the chute 160. For example, the plunger 170 can include a platter coupled to a linear actuator, such as a pneumatic ram, and the system 100 can trigger the linear actuator to drive the platter downward toward chute 160 to drive a bagged hamburger off of the conveyor 150 and onto the chute 160.
As shown in
The conveyor 150 (and other subsystems within the automated foodstuff assembly apparatus) can therefore execute: Block S110 of the method S100, which recites constraining the foodstuff within the receptacle 152; Block S130 of the method S100, which recites advancing the receptacle 152 into the first position to insert the receptacle 152 and the foodstuff into the mouth of the bag; Block S140 of the method S100, which recites advancing the conveyor 150 to insert the hamburger into the bag, the conveyor 150 supporting the hamburger in alignment with the bag; and Block S150 of the method S100, which recites releasing the receptacle 152 from the foodstuff to deposit the foodstuff and the bag onto the chute 160 for delivery to the customer in Block S150. Generally, the conveyor 150 executes Blocks S110, S130, S140, and S140 to move hamburgers through assembly, bagging, and dispensing stages within the automated foodstuff assembly apparatus.
In one implementation, the conveyor 150 executes Block S150 by continuing advancement of a carriage 152 forward passed the bag dispenser 120, and a cam, bumpstop, or other feature within the conveyor 150 triggers a set of fingers 154—coupled to a carriage 152 and arranged about a hamburger—to release the hamburger, as described above. As the conveyor 150 continues to advance the carriage 152 forward, the bagged hamburger progresses over a curved track, and a sprocket supporting the continuous drive mechanism of the conveyor 150 rotates the carriage 152 arcuately downward before returning the carriage 152 back to the front of the automated foodstuff assembly apparatus. As the carriage 152 rotates downward, the bagged hamburger is thus released from the carriage 152 and dispensed onto the chute 160 outside of the conveyor 150, such as via a curved track.
In another implementation, once the conveyor 150 tears the bag from the bag dispenser 120 in Block S140, system drives a plunger 170 (shown in
In yet another implementation, each finger in a set of fingers 154 extending from the carriage 152 can be curved (e.g., semi-circular) and flexible, define an internal passage, and include a nozzle at a far end. In this implementation, once the conveyor 150 tears the bag from the bag dispenser 120, the system 100 can actuates a valve to drive a blast of air through the internal passages within the fingers and out through their corresponding nozzles, thereby causing the fingers to straighten momentarily, raising air pressure inside the bag, and forcing the hamburger and bag off of the set of fingers 154. The bagged hamburger can thus be deposited onto the chute 160 in Block S150, or the conveyor 150 can continue to advance the carriage 152 forward to push the bagged hamburger onto the chute 160.
However, the conveyor 150 and/or other systems and subsystems of the automated foodstuff assembly apparatus can execute Blocks of the method S100 in any other way to bag and then release a hamburger from the automated foodstuff assembly apparatus for delivery to a customer.
In one variation of the system 100, the paddle 130 is further operable in a discard setting, and the actuator transitions the paddle 130 into the discard setting in response to detection of misalignment of a bag in the load position in the bag dispenser 120 in order to remove the misaligned bag from the bag dispenser 120. In this variation, the system 100 can thus execute Block S160 of one variation of the method S100, which recites detecting misalignment of a bag in the load position in the bag dispenser 120 and extending the leading edge of the paddle 130 passed the extended setting into a discard setting to discard the second bag from the bag dispenser 120, as shown in
In one implementation, the system 100 interfaces with an optical sensor (e.g., a camera) arranged over the system 100 and implements machine vision and/or machine learning techniques to detect a bag improperly dispensed into the load position or a bag otherwise unfit for delivery to a customer. For example, the system 100 can implement machine vision to detect a torn bag, a crooked bag, a stained or soiled bag, a folded bag, a bag not properly constrained by one or more pins, rollers, or lips within the bag dispenser 120, a bag with misplaced application of a sticker, label, or printed text, etc. in Block S160 The system 100 can alternatively interface with any other suitable sensor to detect a misplaced or unfit bag in the load position.
Once the system 100 identifies an unfit or improperly-loaded bag in Block S160, the system 100 can trigger a subsystem within the automated foodstuff assembly apparatus to dispose of the bag prior to loading with a completed hamburger. For example, in the implementation described above in which the paddle 130 is extensible, the system 100 can trigger the actuator to extend the paddle 130 to a third extended length that causes the paddle 130 to tear the misaligned bag from the bag dispenser 120 and to drop the bag into a discard container. In another example, the system 100 advances a set of rollers onto the bag and then drives (i.e., rotates) the rollers to rip the bag from the bag dispenser 120. The system 100 can then repeat Block S110 to dispense a fresh bag into the load position.
However, the system 100 can implement any technique to identify a misplaced or unfit bag and can control and/or interface with any other actuator or disposal subsystem with the automated foodstuff assembly apparatus to remove the misaligned or unfit bag from the bag dispenser 120.
The system 100 can further interface with one or more sensors within the automated foodstuff assembly apparatus to detect dislocation (e.g., dislodgement) of contents of a hamburger before or during insertion of the hamburger into a bag, and the system 100 can discard the hamburger and the bag accordingly. The system 100 can then restore an order for the discarded hamburger to an assembly queue to remake the hamburger. In one example, the system 100 collects digital photographic images of hamburgers as the hamburgers are assembled along the conveyor 150 and implements machine vision techniques to detect disheveled hamburgers and/or hamburgers improperly loaded into corresponding bags from these digital photographic images. In particular, the system 100 can identify a hamburger that is unfit for delivery to a customer, such as a hamburger that is toppling over or disheveled, and the system 100 can actively discard the hamburger before delivery to a customer. In one example, the system 100 triggers a gate arranged within the chute 160 or within the trough described above to direct a disheveled or otherwise unfit hamburger into a trash collector. In this example, the system 100 can then reset an order for the disposed hamburger into a hamburger queue such that a replacement for the disposed hamburger can be made and bagged properly for delivery to the corresponding customer.
However, the system 100 can function in any other way to detect an improper or unfit hamburger and to dispose of the hamburger accordingly.
The method S100 and system of the embodiments can be embodied and/or implemented at least in part as a machine configured to receive a computer-readable medium storing computer-readable instructions. The instructions can be executed by computer-executable components integrated with an application, applet, host, server, network, website, communication service, communication interface, hardware/firmware/software elements of a user computer or mobile device, or any suitable combination thereof. Other systems and methods of the embodiments can be embodied and/or implemented at least in part as a machine configured to receive a computer-readable medium storing computer-readable instructions. The instructions can be executed by computer-executable components integrated by computer-executable components integrated with apparatuses and networks of the type described above. The computer-readable medium can be stored on any suitable computer readable media such as RAMs, ROMs, flash memory, EEPROMs, optical devices (CD or DVD), hard drives, floppy drives, or any suitable device. The computer-executable component can be a processor but any suitable dedicated hardware device can (alternatively or additionally) execute the instructions.
This application is a continuation of U.S. patent application Ser. No. 14/493,185 filed Sep. 22, 2014 (now U.S. Pat. No. 9,718,568), which claims the benefit of U.S. Provisional Patent Application No. 61/880,360 filed Sep. 20, 2013. The entire disclosures of the applications referenced above are incorporated by reference. This application is related by subject matter to U.S. patent application Ser. No. 13/911,637 filed Jun. 6, 2013 (now. U.S. Pat. No. 9,386,799), and to U.S. patent application Ser. No. 14/208,149, filed on Mar. 13, 2014 (now pending). The entire disclosures of these applications are incorporated by reference.
Number | Date | Country | |
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61880360 | Sep 2013 | US |
Number | Date | Country | |
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Parent | 14493185 | Sep 2014 | US |
Child | 15664502 | US |