CN210804516U - Unmanned catering system - Google Patents

Abstract

The utility model discloses an unmanned catering system, which comprises a cooking device, a conveying mechanism and a serving device; the conveying mechanism is arranged in an annular structure formed by the cooking device and the meal delivery device; the conveying mechanism is electrically connected with a controller; the controller may issue a transport instruction to the transport mechanism, and the transport mechanism transports the item from the cooking device to the meal delivery device according to the transport instruction; the catering system further comprises a data processing end, and the data processing end is used for receiving the order information sent by the user end and then sending a catering instruction to the controller. Through the technical scheme, the beneficial effects of high meal delivery efficiency, low space occupation and the like of the unmanned catering system can be realized.

Description

Unmanned catering system

Technical Field

The utility model relates to an intelligence food and beverage technical field especially relates to an unmanned food and beverage system.

Background

With the faster and faster urban rhythm life, people can more and more often choose to have meals outside, and the Chinese catering industry faces a wide development space, but the competition is more and more intense, and the urban catering industry has higher requirements. But since traditional restaurants exist: the speed of artificially making dishes is slow, and the efficiency is low; the labor cost is higher and higher; the risk of secondary pollution of food in the process of manual catering and meal delivery is passed; the method has no interaction with diners, the defects that the dining preference of the diners cannot be accurately counted by a traditional restaurant, healthier diet suggestions cannot be provided for each diner and the like are overcome, and the improvement on the defects is always a technical problem to be solved in the related technical field.

Chinese patent CN106516229A discloses an unmanned kitchen, including clean dish cabinet, clean dish box meal delivery device, the rack, the device is put in to condiment, first transport platform, the machine of cooking, the platform is carried to the second, cutlery box sorting device, clean dish cabinet is formed by the integrative connection of main cabinet and the supplementary cabinet of taking the sliding door, clean dish box conveying system is by the support, sucking disc ware and mount interconnect form, install on the rack and throw the material device, rack one side house friend condiment and put in the device, the machine of cooking is located the right side below that the device was put in to condiment, first transport bench is installed a plurality of boxes of control consoles and dress meal device, the terminal end side of first transport platform is equipped with cutlery box closing device, the second is carried the platform and is located cutlery box closing device's rear.

The prior art solves the problems of service and product efficiency of the traditional catering at present, but how to count the dining preferences of diners on the basis, and the proposal of healthier diet for each diner is not related, which is the direction that the persons in the related technical field want to improve.

Disclosure of Invention

In order to overcome the defects of the prior art, the utility model provides an unmanned catering system capable of improving the dining efficiency and a working method thereof; furthermore, the catering system and the working method thereof can also achieve the technical effect of small occupied space.

In order to solve the first aspect of the above technical problem, the present invention adopts the following technical solutions:

an unmanned catering system comprises a cooking device, a conveying mechanism and a serving device; the conveying mechanism is arranged in an annular structure formed by the cooking device and the meal delivery device;

the conveying mechanism is electrically connected with a controller; the catering system also comprises a data processing end, wherein the data processing end is used for receiving order information sent by the user end and then sending a catering instruction to the controller;

the controller sends a conveying instruction to the conveying mechanism according to the food preparation instruction, and the conveying mechanism conveys the articles from the cooking device to the food serving device according to the conveying instruction.

In order to achieve the purpose of the technical scheme, the inventor firstly arranges the conveying mechanism in an annular structure formed by the cooking device and the meal delivery device, so that the space can be saved to a greater extent, and the operation efficiency is improved; in addition, the controller and the data processing end are arranged, so that ordering of a user and distribution of dishes can be directly realized, and the operation of the whole catering process of the unmanned restaurant is completed.

Preferably, the article is a bowl.

Preferably, the item is a dish on which at least one bowl is placed.

Preferably, the cooking device is a cooking robot;

more preferably, the cooking robot further comprises a gripping mechanism.

It should be noted that the articles may be bowls in which dishes are placed, or dishes in which a plurality of bowls are placed. The conveying mechanism can take out a single bowl or the whole dish.

The dish cooking robot comprises a clamping mechanism for clamping dishes out and placing the dishes in a bowl or a dish to complete the dish splitting or distributing process. In a particular embodiment, the gripping mechanism may be a gripping robot.

In some preferred technical solutions, the cooking apparatus includes at least one set of cooking cabinets; the cooking cabinet comprises at least one storage layer;

preferably, the cooking cabinet is a steaming cabinet or a heat-preserving cabinet or an oven;

preferably, the reservoir layers each have a fixed coordinate position;

preferably, the cooking cabinet is provided with an automatic opening and closing door.

It should be noted that the cooking device may be a cooking robot or a cooking cabinet with a storage function. The cooking cabinet can be a steaming cabinet or a heat preservation cabinet or an oven and the like.

It should be noted that the storage layers are all provided with fixed coordinate positions, and the conveying mechanism can take out corresponding dishes according to coordinate position information, so that the accuracy of dish positioning and taking out is realized.

It should be noted that, the cooking cabinet is provided with an automatic opening and closing door, and the door is correspondingly opened and closed in cooperation with the taking-out of the conveying mechanism, so that the cleanness and the temperature of dishes can be guaranteed.

In some preferred technical solutions, the system further comprises a walking guide rail for enlarging the working path of the conveying mechanism;

it should be noted that, when a plurality of groups of cooking cabinets (steaming cabinets or heat preservation cabinets) are placed, the working space required by the conveying mechanism becomes large, and at this time, the conveying mechanism of the fixing base cannot meet the space, so that a walking guide rail on which the conveying mechanism can move is added, that is, the conveying mechanism can move on the walking guide rail, and thus, the working space of the conveying mechanism can be enlarged to meet the space requirement.

Preferably, the transport mechanism is a six-axis robot;

more preferably, a first clamp is installed at the end station end of the six-axis robot;

further, the first clamp is a U-shaped clamp;

further, the six-axis robot further comprises a first moving mechanism for driving the first clamp to move; the first clamp comprises a first manipulator and a second manipulator; the first manipulator and the second manipulator grab the object from different angles or positions in a clamping or supporting mode respectively;

furthermore, the first moving mechanism comprises a first x-axis moving component, a first y-axis moving component and a first z-axis moving component, and the first clamp is moved in at least one direction of the x-axis, the y-axis and the z-axis through the first moving mechanism.

Further, at least one end of the first clamp is provided with an air cylinder.

It should be noted that, at least one end of the first clamp is provided with a cylinder, which can be used to fix the edge of an appliance (such as a dish) for carrying an object (dish), so that the appliance is fixed on the first clamp.

As a more preferable embodiment, the first clamp includes a first robot and a second robot; the first mechanical arm and the second mechanical arm respectively grab the object from different angles or positions in a clamping or supporting mode, and stability and accuracy of the object can be achieved.

In some preferred technical solutions, the meal delivery device comprises a meal delivery table;

preferably, the meal delivery device is electrically connected with the controller; the controller sends a meal sending instruction to the meal sending device; the meal delivery device completes meal delivery according to the meal delivery instruction;

preferably, the meal delivery device comprises a meal plate providing mechanism;

preferably, the meal delivery device further comprises a grabbing mechanism;

more preferably, the meal delivery mechanism further comprises a placing table; the conveying mechanism is used for placing the articles on the placing table; the grabbing mechanism comprises a first grabbing part and a second grabbing part; the first gripping part is used for gripping the dinner plate from the dinner plate providing mechanism to the dinner plate; the second grabbing part is used for placing the articles on the placing table on the dinner plate;

further, the grabbing mechanism also comprises a second moving mechanism for driving the first grabbing part and the second grabbing part to move in at least one direction of an x axis, a y axis and a z axis;

further, the first gripping member is a suction cup;

further, the second gripping member is a second gripper;

more preferably, the grasping mechanism is a scara robot.

It should be noted that the service plate providing mechanism is used for providing a service plate for bearing dishes. In one embodiment, the grasping mechanism can draw a dish from the dish supply mechanism and place the dish on the serving table, and then place the item on the table in the dish on the serving table. By the technical scheme, the high efficiency of meal delivery can be realized.

In some preferred technical solutions, the dinner plate providing mechanism includes a dinner plate stacking support, a motor, a synchronizing wheel and a screw rod; slide rails are respectively arranged on two sides of the dinner plate stacking support, slide blocks are arranged on the slide rails, and the dinner plate stacking support is fixed through the slide blocks; the screw rod is provided with a fixed block; the motor can drive the synchronous wheel; the synchronizing wheel is fixed on the screw rod;

preferably, the dinner plate providing mechanism comprises a detection component for detecting whether a dinner plate is arranged at the corresponding position of the dinner plate stacking support.

It should be noted that, as a preferred embodiment, the dish providing mechanism is composed of a motor, a slide rail, and further includes a mounting bracket such as a detection component, and is used for carrying the dish to stack and lift. In a specific working mode, after the scara robot sucks one dinner plate, when the detection component on the dinner plate providing mechanism detects that the current height is not provided with a plate, the dinner plate providing mechanism can conveniently suck the next dinner plate by stacking the dinner plates to the specified height, and the supply efficiency and the automation of the dinner plate providing mechanism can be improved.

In some preferred technical solutions, the meal delivery device further comprises a dish recovery device;

preferably, the vegetable retrieval device comprises a retrieval basket;

more preferably, the recycling basket is further provided with a buffer mechanism;

more preferably, the recovery basket is further provided with an anti-collision mechanism;

preferably, when the article conveyed by the conveying mechanism is a dish on which at least one bowl is placed, after the bowl on the dish is grabbed, the grabbing mechanism or the conveying mechanism grabs the dish into the dish recycling device.

It should be noted that, in an optimal technical scheme, after the bowl on the dish is grabbed, the grabbing mechanism may detect whether the bowl is not grabbed continuously, at this time, the grabbing mechanism grabs the dish into the dish recovery device, and the conveying mechanism is convenient to acquire the next dish to place on the serving device. In a more specific embodiment, the gripping mechanism is further provided with sensing means for sensing whether an object, such as a bowl, is gripped. Through the mode, the grabbing automation can be realized, and the meal delivery efficiency of the unmanned catering system is improved.

In a preferred embodiment, the recycling basket is further provided with a buffer mechanism for preventing the recycled dinner plate and the like from being crushed by collision.

In some preferred technical solutions, the meal outlet table comprises a table top and a detection device for detecting whether the table top has meal trays or not;

preferably, the detecting device is further configured to detect whether the dish contains dishes;

preferably, the meal outlet table further comprises an indicator light; the indicator light is electrically connected with the detection device. It should be noted that the detection device is used for detecting whether a dinner plate is on the dining table top or not, if no dinner plate is on the dining table, the first step of catering is to suck a dinner plate and place the dinner plate on the dining table top; when the diner takes the dinner plate with the prepared meal, the detection device detects that the dinner table surface has no dinner plate, and the sucking disc of the scara robot is supplemented with a dinner plate to be placed on the dinner table. The indicating lamp is electrically connected with the detecting device to realize that the indicating lamp prompts the diner to take the plate information when the dinner plate is prepared, so that the diner can take the plate in advance or in a delayed manner.

In some preferred embodiments, the data processing end executes one or more of the following instructions:

receiving meal ordering information of a user side, and analyzing meal using preference of the user according to the meal ordering information of the same user; pushing dining preference information to the user when the user uses the user side to order the next time; alternatively, the first and second electrodes may be,

receiving one or more of dish information and promotion information input by a manager, and sending meal recommendation information to a user in time by combining the meal preference information; alternatively, the first and second electrodes may be,

recording meal ordering information of a user side, and analyzing calorie data ingested by each meal ordering of the user according to the meal ordering information of the same user; and pushing the calorie data to the user; alternatively, the first and second electrodes may be,

receiving meal ordering information of a user side, obtaining payment information according to the meal ordering information, and returning the payment information to the user side.

It should be noted that, in order to further facilitate the use of the user and the interaction with the unmanned catering system, in some preferred embodiments, the system may push dining preference information to the user; and/or pushing the meal recommendation information to the user in time; and/or pushing the calorie data to the user; and/or obtaining payment information according to the meal ordering information, and returning the payment information to the user side to realize information analysis and interaction with the consumer.

It should be noted that, if the above functions are implemented in the user side, such as being implemented on the APP of the unmanned catering system, the functions belong to equivalent replacements of the above technical solutions.

In order to solve the second aspect of the above technical problem, the present invention adopts the following technical solutions:

a working method of the unmanned catering system comprises the following steps:

after receiving the order information sent by the user end, the data processing end sends a food preparation instruction to the controller;

after receiving the meal preparation instruction, the controller sends a conveying instruction to the conveying mechanism, and the conveying mechanism conveys the articles from the cooking device to the meal delivery device for meal delivery according to the conveying instruction;

in the conveying process, the conveying mechanism takes out the articles according to the conveying instruction and the coordinate position of the storage layer in the cooking device;

in the meal delivery process, the data processing terminal distributes meal delivery positions according to meal delivery conditions and sends the meal delivery position information to the user terminal.

In some preferred technical solutions, during the meal delivery process, the method further includes:

placing corresponding articles on corresponding limiting positions of the placing table according to the coordinate positions of the storage layers; and the grabbing mechanism grabs the object according to the limiting position.

Compared with the prior art, the beneficial effects of the utility model reside in that:

1. the unmanned catering system of the utility model arranges the conveying mechanism in the annular structure formed by the cooking device and the meal delivery device, thus saving space to a greater extent and improving operation efficiency; in addition, the controller and the data processing end are arranged, so that ordering of a user and distribution of dishes can be directly realized, and the operation of the whole catering process of the unmanned restaurant is completed;

2. the unmanned catering system of the utility model arranges the storage layers with fixed coordinate positions, and the conveying mechanism can take out corresponding dishes according to the coordinate position information, thus realizing the accuracy of dish positioning and taking out;

3. the utility model discloses an unmanned catering system, the six-axis robot also comprises a first moving mechanism for driving the first clamp to move; the first clamp comprises a first manipulator and a second manipulator; the first manipulator and the second manipulator grab the object from different angles or positions in a clamping or supporting mode respectively;

4. the utility model discloses an unmanned catering system, the first clamp comprises a first mechanical arm and a second mechanical arm; the first mechanical arm and the second mechanical arm respectively grab the object from different angles or positions in a clamping or supporting mode, and stability and accuracy of the object can be achieved.

The foregoing description is only an overview of the technical solutions of the present invention, and in order to make the technical means of the present invention more clearly understood, the present invention may be implemented according to the content of the description, and in order to make the above and other objects, features, and advantages of the present invention more obvious and understandable, the following preferred embodiments are described in detail with reference to the accompanying drawings.

Drawings

FIG. 1 is a schematic structural view of a preferred embodiment of the unmanned catering system of the utility model;

FIG. 2 is a schematic structural view of a preferred embodiment of a first clamp in the unmanned catering system;

fig. 3 is a schematic structural diagram of a scara robot in an unmanned catering system according to a preferred embodiment of the invention;

fig. 4 is a schematic structural view of a preferred embodiment of a food serving device in the unmanned catering system;

FIG. 5 is a schematic structural view of a preferred embodiment of a dish supplying apparatus in the unmanned catering system according to the present invention;

FIG. 6 is a schematic diagram of a preferred embodiment of the retrieval basket of the tray providing apparatus of FIG. 5;

FIG. 7 is a schematic flow chart of a preferred embodiment of the working method of the unmanned catering system according to the invention;

wherein the reference symbols are: 1. a six-axis robot; 2. steaming the cabinet; 3. a steam generating device; 4. a scara four-axis robot; 5. a service plate providing mechanism; 6. a placing table; 7. taking out the meal; 11. a connecting flange; 12. a cushion pad; 13. mounting a plate; 14. cushion blocks; 15. a cylinder; 16. a support frame; 21. grabbing a dish clamp; 22. sucking the dinner plate part; 41. mounting a plate; 42. a lifting cylinder; 43. a sucker connecting pipe; 44. mounting a plate; 45. a suction cup; 46. grabbing a cylinder installation pipe; 47. a clamping jaw cylinder; 48. a clamping jaw; 49. a rubber pad; 51. a dinner plate stacking support; 52. a motor; 53. a synchronizing wheel; 54. a screw rod; 55. a slider; 26. a photodetector; 61. a recycling basket; 62. a buffering brush; 63. an anti-collision plastic cushion.

Detailed Description

To further illustrate the technical means and effects of the present invention adopted to achieve the predetermined objects, the following detailed description of the embodiments, structures, features and effects according to the present invention with reference to the accompanying drawings and preferred embodiments is as follows:

fig. 1 is a schematic structural diagram of a preferred embodiment of the unmanned catering system, which includes a multi-group steaming cabinet 2 as a cooking device, a six-axis robot 1 as a conveying mechanism, and a scara four-axis robot 4 as a serving device; a dinner plate providing mechanism 5, a placing table 6 and a dinner table 7; the six-axis robot is positioned in the middle of the steaming cabinet, the scara four-axis robot, the dinner plate providing mechanism, the placing table and the dinner table; more specifically, a plurality of groups of steaming cabinets (or heat preservation cabinets) are positioned on the left, right and back of the six-axis robot; the placing table is positioned right in front of the six-axis robot; the dinner plate providing mechanisms are positioned at two ends of the placing table; one or more scara robots are positioned above the placing table; one or more meal dispensing tables are positioned in front of the placing table.

In a preferred embodiment, the steam generator 3 is further provided for cooking the dishes in the steam cabinet, and for example, the steam generator may provide steam to the steam cabinet to steam the dishes in the steam cabinet and complete the cooking process.

The catering system further comprises a data processing end, and the data processing end is used for receiving the order information sent by the user end and then sending a catering instruction to the controller.

The six-axis robot is electrically connected with a controller; and the controller sends a conveying instruction to the six-axis robot according to the catering instruction, and the six-axis robot conveys the articles to the placing table from the steaming cabinet according to the conveying instruction.

With reference to the foregoing embodiment, in a first preferred aspect, the positions of the multiple groups of steaming cabinets in the unmanned catering system are fixed, the steaming cabinets are divided into multiple storage layers with equal intervals to carry dishes, the coordinate positions of the dishes in the steaming cabinets are fixed, and the dishes on each layer have the fixed coordinate positions. And the six-axis robot takes out the dish according to the coordinate position.

In a second preferred aspect in combination with the above embodiment, the steam cabinet may also be a thermal cabinet; in other preferred embodiments, the steamer is provided with an automatic door opening and closing device.

In a third preferred aspect, in combination with the above embodiment, the six-axis robot located in the middle of the catering system is configured with a fixed base or enlarges the working path of the robot by using a fixed walking guide rail according to the requirements of the working space.

In a fourth preferred aspect in combination with the above embodiment, as shown in fig. 2, a U-shaped clamp is installed at the end of the last station of the six-axis robot as the first clamp, the support frame 16 is under the dish, and an air cylinder 15 is disposed at one end of the U-shaped clamp for fixing the edge of the dish and fixing the dish on the U-shaped clamp. The connecting flange 11 is positioned at the tail end of a sixth shaft of the six-shaft robot and is used for connecting the fixing clamp with the robot, the buffer cushion 12 is made of soft plastic and is positioned in the middle of the connecting flange, and the buffer cushion is firstly contacted with the edge of a dish before the edge of the dish is contacted with the flange when the dish is clamped so as to buffer the impact force of metal impacting metal; the cushion blocks 14 are made of plastic materials and are fixed on the mounting plate 13, the mounting plate is fixed on the air cylinder, the air cylinder is fixed on two sides of the rear end of the U-shaped clamp, when the U-shaped clamp enters the bottom of a dish, the edge of the dish contacts with the connecting flange, the air cylinder moves downwards at the moment, the cushion blocks on the air cylinder press the edge of the dish, the dish is fixed on the U-shaped clamp, and when the U-shaped clamp moves along with the six-axis robot, the relative position of the dish on the U-shaped clamp and the U-shaped clamp is unchanged. The working process of the six-axis robot is as follows: firstly, placing a dish in a steaming cabinet or a heat preservation cabinet from a raw material rack; then, clamping and taking a dish from the steaming cabinet or the heat preservation cabinet and placing the dish on a placing table; then, when the bowl cannot be further grabbed on the dish plate on the placing table, no bowl exists on the surface dish plate at the moment, and the six-axis robot grabs the dish plate and places the dish plate in the dish plate recovery device; and then a new dish plate is grabbed from the steaming cabinet or the heat preservation cabinet to fill the vacant space of the placing table.

In a fifth preferred aspect, in combination with the above embodiment, as shown in fig. 3, the scara robot end station is provided with a dish-grasping clamp 21 as a second grasping part for grasping a dish and a dish-sucking part 22 as a first grasping part for sucking a dish. More specifically, referring to fig. 4, a lifting cylinder 42 is disposed below the mounting plate 41 for driving a suction cup connecting pipe 43 and a mounting plate 44, thereby driving a suction cup 45 disposed on the mounting plate to lift. On the other hand, mounting panel 41 has the cylinder installation pipe 46 of snatching, snatchs cylinder installation pipe and has clamping jaw cylinder 47, and clamping jaw cylinder has clamping jaw 48, and the clamping jaw still is equipped with the cushion, conveniently presss from both sides article. The working process of the scara robot is as follows: firstly, a dinner plate is sucked from the dinner plate supply mechanism and placed on the dinner table, and then a corresponding dish bowl is grabbed from a dish plate on the placing table and placed in the dinner plate on the dinner table.

In a sixth preferred aspect in combination with the above embodiment, as shown in fig. 5, the tray providing mechanism comprises a tray stacking rack 51, a motor 52, a synchronizing wheel 53, a lead screw 54 and a slide block 55, the tray stacking rack is used for carrying tray stacking and tray lifting, after the scara robot sucks a tray, preferably, when the photo detector 56 on the tray providing mechanism detects that the tray is not at the current height, the motor drives the tray stacking mechanism to lift the tray to the designated height. The structural relationship and the working process of the motor and other components are as follows:

the motor rotates, the synchronizing wheel is driven by the synchronous belt, the synchronizing wheel fixed on the screw rod drives the screw rod to rotate, the copper block fixed on the screw rod moves upwards or downwards along with the rotation of the screw rod, the copper block is fixed at the central part of the dinner plate stacking support, the two side parts of the dinner plate stacking support are respectively fixed on the sliding blocks on the sliding rails on the two sides, the rotation of the screw rod drives the dinner plate stacking support to move up and down, the sliding blocks on the two sides fix the dinner plate stacking support to vertically move up and down without inclination, and a scara robot can conveniently absorb a next dinner plate.

With reference to the foregoing embodiment, in a seventh preferred aspect, the meal delivery apparatus further comprises a dish recovery apparatus; referring to fig. 6, a preferred embodiment of the dish recycling device comprises one or more recycling baskets 61, preferably, a buffer brush 62 is arranged on the inner wall of the recycling basket as a buffer mechanism, and further preferably, a crashworthy plastic pad 63 is arranged on the bottom surface of the recycling basket as a crashworthy mechanism to protect the recycled dishes.

Further, an embodiment of a working method of the unmanned catering system is also provided, and a preferred embodiment of a working process of the unmanned catering system shown in fig. 7 is as follows:

acquiring order information of a user through an unmanned catering system APP at a user side; the obtaining mode can be that a user carries out ordering operation by scanning and downloading the unmanned catering system APP;

calculating the total cost of the dishes according to the order information to obtain payment information;

the user side pays the total cost of the dishes by using the mobile payment to complete the payment step;

the user side transmits the order information to a cloud server serving as a data processing side;

the cloud server transmits a food preparation instruction to an artificial intelligence control system serving as a controller according to the order information;

the artificial intelligence distributes tasks to all stations according to the food preparation instruction, such as robots at all stations in a conveying mechanism and a food delivery device;

each station robot respectively completes respective tasks: taking a dish, taking a dinner plate, preparing a meal, taking a meal and the like;

the artificial intelligence control system distributes a meal-out window number and a meal-taking number according to the meal-out condition;

the artificial intelligence control part transmits the meal-out window number and the meal-taking number to the cloud server;

the cloud server transmits the meal-out window number and the meal-taking number to the user side;

and the user takes the dishes from the corresponding meal-taking window according to the meal-taking number.

The above embodiments are only preferred embodiments of the present invention, and the protection scope of the present invention cannot be limited thereby, and any insubstantial changes and substitutions made by those skilled in the art based on the present invention are all within the protection scope of the present invention.

Claims (35)

1. An unmanned catering system is characterized by comprising a cooking device, a conveying mechanism and a serving device; the conveying mechanism is arranged in an annular structure formed by the cooking device and the meal delivery device;

the conveying mechanism is electrically connected with a controller; the catering system also comprises a data processing end, wherein the data processing end is used for receiving order information sent by the user end and then sending a catering instruction to the controller;

the controller sends a conveying instruction to the conveying mechanism according to the food preparation instruction, and the conveying mechanism conveys the articles from the cooking device to the food serving device according to the conveying instruction.

2. The unmanned catering system of claim 1, wherein the item is a bowl.

3. The unmanned catering system of claim 1, wherein the item is a dish having at least one bowl disposed therein.

4. The unmanned catering system of claim 1, wherein the cooking device is a cooking robot.

5. The unmanned catering system of claim 4, wherein the cooking robot further comprises a gripper mechanism.

6. The unmanned catering system of claim 1, wherein the cooking device comprises at least one set of cooking cabinets; the cooking cabinet comprises at least one reservoir layer.

7. The unmanned catering system of claim 6, wherein the cooking cabinet is a steam cabinet or a heat preservation cabinet or an oven.

8. The unmanned catering system of claim 6, wherein the storage layers each have a fixed coordinate location.

9. The unmanned catering system of claim 6, wherein the cooking cabinet is configured with an automatic opening and closing door.

10. The unmanned catering system of claim 1, further comprising a travel rail for enlarging the working path of the conveyor.

11. The unmanned catering system of claim 10, wherein the conveyor mechanism is a six-axis robot.

12. The unmanned catering system of claim 11, wherein the six-axis robot has a first clamp mounted at the end station end.

13. The unmanned catering system of claim 12, wherein the first clamp is a U-shaped clamp.

14. The unmanned catering system of claim 12, wherein the six-axis robot further comprises a first movement mechanism for driving the first clamp to move; the first clamp comprises a first manipulator and a second manipulator; the first mechanical arm and the second mechanical arm respectively grab the object from different angles or positions in a clamping or supporting mode.

15. The unmanned catering system of claim 14, wherein the first movement mechanism comprises a first x-axis movement assembly, a first y-axis movement assembly, and a first z-axis movement assembly, the first clamp effecting movement in at least one of the x-axis, y-axis, and z-axis directions via the first movement mechanism.

16. The unmanned catering system of claim 12, wherein at least one end of the first clamp is configured with a cylinder.

17. The unmanned catering system of claim 1, wherein the serving device is electrically connected to the controller; the controller sends a meal sending instruction to the meal sending device; and the meal delivery device finishes meal delivery according to the meal delivery instruction.

18. The unmanned catering system of claim 17, wherein the serving device comprises a serving plate providing mechanism.

19. The unmanned catering system of claim 17, wherein the serving device further comprises a grasping mechanism.

20. The unmanned catering system of claim 19, wherein the serving device further comprises a serving table.

21. The unmanned catering system of claim 20, wherein the serving device further comprises a holding table; the conveying mechanism is used for placing the articles on the placing table; the grabbing mechanism comprises a first grabbing part and a second grabbing part; the first gripping part is used for gripping the dinner plate from the dinner plate providing mechanism to the dinner plate; the second gripping member is used for placing the object on the placing table on the dinner plate.

22. The unmanned catering system of claim 21, wherein the gripper mechanism further comprises a second movement mechanism for driving the first gripper assembly and the second gripper assembly to move in at least one of an x-axis, a y-axis, and a z-axis.

23. The unmanned catering system of claim 21, wherein the first grasping member is a suction cup.

24. The unmanned catering system of claim 21, wherein the second gripper component is a second clamp.

25. The unmanned catering system of claim 19, wherein the grasping mechanism is a scara robot.

26. The unmanned catering system of claim 18, wherein the dish providing mechanism comprises a dish stacking rack, a motor, a synchronizing wheel, a lead screw; slide rails are respectively arranged on two sides of the dinner plate stacking support, slide blocks are arranged on the slide rails, and the dinner plate stacking support is fixed through the slide blocks; the screw rod is provided with a fixed block; the motor can drive the synchronous wheel; the synchronizing wheel is fixed on the screw rod.

27. The unmanned catering system of claim 26, wherein the dish providing mechanism comprises a detection component for detecting whether a dish is present at a corresponding position of the dish stacking rack.

28. The unmanned catering system of claim 19, wherein the serving means further comprises a dish retrieval means.

29. The unmanned catering system of claim 28, wherein the dish recovery device comprises a recovery basket.

30. The unmanned catering system of claim 29, wherein the retrieval basket is further provided with a cushioning mechanism.

31. The unmanned catering system of claim 29, wherein the retrieval basket is further provided with a bump guard mechanism.

32. The unmanned catering system according to claim 28, wherein when the object transported by the transporting mechanism is a dish on which at least one bowl is placed, the grasping mechanism or the transporting mechanism grasps the dish into the dish retrieving device after the bowl on the dish is grasped.

33. The unmanned catering system of claim 20, wherein the serving table includes a table top and a detection device for detecting whether a serving dish is on the table top.

34. The unmanned catering system of claim 33, wherein the detection device is further configured to detect whether the dish carries dishes.

35. The unmanned dining system of claim 33 wherein said dining table further comprises indicator lights; the indicator light is electrically connected with the detection device.

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