CN215605226U - Automatic meal distribution mechanism - Google Patents

Abstract

An automatic dish distribution mechanism comprises a storage hopper, wherein the storage hopper comprises a feeding hole, an accommodating cavity and a discharging hole; the distribution groove comprises an opening and a storage bin matched with the opening, the distribution groove can rotate between a first position and a second position, when the distribution groove is located at the first position, the opening faces the discharge hole, and when the distribution groove is located at the second position, the opening faces back to the discharge hole; the driving assembly comprises a rotating shaft connected with the material distributing groove. According to the utility model, the containing cavity is arranged to realize continuous dish distribution, so that the dish distribution efficiency is improved; through setting up rotatable branch silo for the transfer of cooked food between storage hopper and dinner plate can effectively improve branch dish efficiency. Moreover, the contact between a human body and dishes is reduced, the distance between the human body and the dishes is kept, and the sanitation problem brought to the dishes by human factors is reduced.

Description

Automatic meal distribution mechanism

Technical Field

The utility model belongs to the technical field of meal distribution equipment, and particularly relates to an automatic meal distribution mechanism.

Background

Dishes are consumed by people every day in daily life and exist in almost all kitchen scenes. The dish is generally made by kitchen equipment such as a frying machine, a large cooking range, a frying pan, a steaming cabinet and the like, and is widely applied to batch making of dishes by adopting large kitchen equipment in fast food and dining halls. Therefore, the dish distribution process is an indispensable step before meals.

In the prior art, manual dish separation is mainly adopted. In the occasion that a large number of people participate in dining, a plurality of dish-dividing personnel need to be equipped for manually dividing dishes, and more time and labor are consumed. The increase of the dish distribution personnel means the increase of the labor cost. And each dish distribution person judges the dish quantity by sense, and the dish quantity is inconsistent due to cognitive difference, so that the dish distribution quantity is inaccurate. Secondly, in the process of distributing the dishes for multiple times, the same dish quantity distributed every time cannot be completely guaranteed, the dish distribution needs to be judged every time, the dishes cannot be quantitatively and continuously distributed, the efficiency is low, and the condition of multiple or less dishes often occurs. Moreover, in the process of dish distribution, dishes are exposed in the external environment, so that sundries and germs in the environment are brought into the dishes inevitably, and in the dish distribution operation of dish distribution personnel, the dish distribution personnel and the dishes are in close contact, so that the possibility of the danger is increased.

At present, no automatic dish distribution equipment exists in the market, dish distribution equipment capable of accurately distributing dishes and simple in structure is urgently needed, manual dish distribution at the present stage is replaced, labor cost is reduced, efficiency is improved, and accurate dish distribution is achieved.

Disclosure of Invention

In view of the above-mentioned deficiencies of the prior art, the present invention provides an automatic meal distribution mechanism, comprising:

the storage hopper comprises a feeding hole, a containing cavity and a discharging hole;

the distribution groove comprises an opening and a storage bin matched with the opening, the distribution groove can rotate between a first position and a second position, when the distribution groove is located at the first position, the opening faces the discharge hole, and when the distribution groove is located at the second position, the opening faces back to the discharge hole;

the driving assembly comprises a rotating shaft connected with the material distributing groove.

According to the utility model, the containing cavity is arranged to realize continuous dish distribution, so that the dish distribution efficiency is improved; through setting up rotatable branch silo for the transfer of cooked food between storage hopper and dinner plate can effectively improve branch dish efficiency, and simultaneously, fixed branch silo can realize accurate branch dish, avoids relying on the uncertain condition of branch dish weight that the sense organ judgement leads to by manual operation. Moreover, the contact between a human body and dishes is reduced, the distance between the human body and the dishes is kept, and the sanitation problem brought to the dishes by human factors is reduced.

Further, automatic meal distribution mechanism includes vibrating motor, vibrating motor with the storage hopper transmission is connected.

Vibration motor transmits vibration to the storage hopper for the dish in the storage hopper reduces the contact with the inner wall of storage hopper, reduces the wall built-up phenomenon of dish, makes the dish in the storage hopper by make full use of, and the whereabouts of dish from the discharge gate can alleviate the cleaning work of later stage to the storage hopper simultaneously with higher speed.

Further, automatic meal distribution mechanism includes the vibration board, vibrating motor installs vibration board is last, vibration board includes the through-hole, the storage hopper sets up in the through-hole.

The vibration motor is arranged on the vibration plate, and installation and replacement of the vibration motor are facilitated. Meanwhile, the storage hopper is arranged in the through hole of the vibrating plate. The storage hopper can be passed to with the vibration in the planar circumference of vibration board to vibrating motor, is favorable to the separation of diversified cooked food and storage hopper, and the dish falls from the discharge gate with higher speed, reduces the wall built-up phenomenon.

Further, the automatic meal distribution mechanism comprises a meal distribution barrel, and an opening of the meal distribution groove is formed in the surface of the meal distribution barrel.

The distributing groove is arranged on the distributing cylinder, so that the distributing groove is convenient to install, plays a supporting role, is beneficial to maintaining the stability of the distributing groove structure, and is convenient to use for a long time.

Preferably, the material separating barrel is a cylinder and comprises two end faces and a curved surface between the two end faces, the opening is formed in the curved surface, and the rotating shaft vertically penetrates through the end faces.

The distributing cylinder is arranged to be a cylinder, the curved surface is attached to the edge of the discharging port, so that the distributing groove is in a closed state before dishes are transferred, the dishes in the distributing groove are prevented from being leaked and contacting with the outside, the accuracy of distributing the dishes is improved, the waste of the dishes is avoided, and the sanitation of the dishes is guaranteed.

Further, the edge of the discharge hole is attached to the curved surface.

Preferably, the opening is circular, rectangular or cambered surface type, and the bin is a cuboid, a cone, a cylinder or a segment.

When dishes to be distributed fall easily and the resistance is low, if the dishes to be distributed are spherical or diced dishes such as peanuts, soybeans and diced lotus roots, the distributing trough with a rectangular opening and a cuboid bin is adopted.

When dishes to be served are radish slices, asparagus lettuce slices and the like, which have large frictional resistance, and cavities are easily formed among materials, the arc-shaped opening is adopted, and the material bin is a ball-segment material distributing groove, which is more suitable.

Preferably, when the opening is the rectangle, when the feed bin is the cuboid, the opening is 60 ~ 120X 40 ~ 100 millimeters²And the depth of the cuboid is 30-70 mm.

The length of the opening is less than 60 mm, the width of the opening is less than 40 mm, and when the depth of the cuboid is more than 70 mm, the opening is too small, so that dishes are not transferred easily, and the efficiency is low; open-ended length is greater than 120 millimeters, and the width is greater than 100 millimeters, and when the cuboid degree of depth was less than 30 millimeters, because wait to divide the cooked food to drop easily, little with the frictional force of storage hopper, the opening is too big, causes the cooked food to scatter the place outside the dinner plate easily at the transfer in-process, is unfavorable for shifting the location of cooked food, and then influences the precision of cooked food weight.

Preferably, when the opening is circular and the bin is a segment, the diameter of the opening is 60-120 mm, and the depth of the segment is 30-70 mm.

When the diameter of the opening is less than 60 mm and the depth of the spherical segment is more than 70 mm, because the friction resistance between the materials of the dish is large, a cavity is easily formed between the materials, the opening is too small, the cavity is easily formed in the filling process of the dish, and the dish is quantified by volume, so that the dish is not precisely quantified; when the diameter of the opening is larger than 120 mm and the depth of the spherical segment is smaller than 30 mm, dishes are easily scattered to the place outside the dinner plate in the transferring process, the dishes are not favorably positioned and transferred, and the accuracy of dish weight is further influenced.

Preferably, when the opening is cambered and the bin is a segment, the diameter of the opening is 60-120 mm, and the depth of the segment is 30-70 mm.

When the diameter of the opening is less than 60 mm and the depth of the spherical segment is more than 70 mm, because the friction resistance between the materials of the dish is large, a cavity is easily formed between the materials, the opening is too small, the cavity is easily formed in the filling process of the dish, and the dish is quantified by volume, so that the dish is not precisely quantified; when the diameter of the opening is larger than 120 mm and the depth of the spherical segment is smaller than 30 mm, dishes are easily scattered to the place outside the dinner plate in the transferring process, the dishes are not favorably positioned and transferred, and the accuracy of dish weight is further influenced.

For dishes to be distributed, which are easy to turn and fill, a narrow-mouth and deep trough is adopted, so that the dish distribution precision is easy to improve.

A distributing groove with a large opening and a shallow depth is suitable for dishes to be distributed, which are easy to form large gap resistance, and the dish distributing precision is easy to improve.

Preferably, the number of the distributing grooves is two, three or four, and the distributing grooves are circumferentially distributed on the same plane.

When the number of the distributing grooves is two, three or four, when one of the distributing grooves is in the step of filling dishes, the other distributing grooves can transfer the filled dishes to the dinner plate, so that the dish distribution can be continuously carried out, and the efficiency is improved. The number of the material distributing grooves can be set according to the required vegetable distributing speed.

Further, automatic meal distribution mechanism still includes the sealing washer, drive assembly still includes rolling bearing, the sealing washer sets up rolling bearing with in the middle of the terminal surface.

The sealing ring can avoid the leakage of the lubricating oil on the rotating shaft.

Further, automatic meal distribution mechanism includes vibrating spring, passes through vibrating spring elastic connection between storage hopper and the frame.

The vibration of the vibration motor can drive the storage hopper to have a better vibration amplitude, so that the falling of the material is ensured. Because the storage hopper is elastically connected with the rack through the vibrating spring, the spring absorbs the vibration of the storage hopper, so that the rack cannot vibrate along with the storage hopper, and the stability of the whole machine is guaranteed.

By adopting the automatic meal distribution mechanism provided by the utility model, a large amount of manpower and time occupied by manual meal distribution can be reduced, and the labor cost is reduced; the accuracy and consistency of the amount of the dishes are ensured, and the dish distribution efficiency is improved; the contact between human body and dishes is reduced, the distance between human body and dishes is kept, and the sanitation problem brought to dishes by human factors is reduced.

Drawings

FIG. 1: the utility model provides a structural schematic diagram of an automatic meal distribution mechanism body;

FIG. 2: the utility model provides another angle structure schematic diagram of the automatic meal distribution mechanism body;

FIG. 3: the utility model provides a schematic partial half-section structure of an automatic meal distribution mechanism body;

FIG. 4: the utility model provides a structural schematic diagram of an automatic meal distribution mechanism;

FIG. 5: the structure schematic diagram of the distributing trough is provided by the utility model.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present invention more clearly apparent, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

It will be understood that the terms "upper," "lower," "front," "back," "top," "bottom," "inner," "outer," and the like are used in the orientation or positional relationship indicated in the drawings for convenience in describing the utility model and to simplify the description, and do not indicate or imply that the referenced device or element must have a particular orientation, be constructed in a particular orientation, and be constructed in a particular operation, and are therefore not to be considered limiting of the utility model.

The present invention will be described in further detail with reference to the following examples and accompanying drawings.

In fast food and dining halls, large kitchen equipment is widely used for batch cooking. The dish distribution process is an indispensable step before meals. In the prior art, manual dish separation is mainly adopted. The manual dish distribution needs to consume more time and labor, the dish quantity distributed each time cannot be accurately grasped, and the condition of more or less dishes is often generated; moreover, no equipment for automatically distributing the dishes is available in the market.

The utility model provides an automatic meal distribution mechanism which can continuously distribute dishes, ensure the accuracy and consistency of the quantity of the distributed dishes, keep the distance between a person and a dish, reduce contact, reduce the sanitary problem caused by thought factors, reduce the use of manpower, reduce the cost and improve the efficiency.

Please refer to fig. 1, fig. 2, fig. 3 and fig. 4, in which fig. 1 is a schematic structural diagram of an automatic meal distribution mechanism body according to the present invention, fig. 2 is a schematic structural diagram of another angle of the automatic meal distribution mechanism body according to the present invention, fig. 3 is a schematic partial half-sectional structural diagram of the automatic meal distribution mechanism body according to the present invention, and fig. 4 is a schematic structural diagram of the automatic meal distribution mechanism according to the present invention. In one embodiment of the present invention, the automatic meal distribution mechanism 1 comprises an automatic meal distribution mechanism body 10 and a frame 20, and the automatic meal distribution mechanism body 10 comprises a storage hopper 11, a material distribution cylinder 12, a driving assembly 13, a sealing ring 15, a vibration motor 16, a vibration plate 17 and a vibration spring 18.

The storage hopper 11 includes a feeding port 111, a receiving chamber 112 and a discharging port 113.

The aperture of the feeding hole 111 is larger, which is beneficial to filling dishes to be distributed.

The containing cavity 112 is set to be a cone, the feeding hole 111 is arranged on the bottom surface of the cone, the discharging hole 113 is arranged at the tip of the cone, dishes to be distributed enter the containing cavity 112 from the feeding hole 111 under the action of gravity and slide down along the inclined inner wall of the containing cavity 112, and then the dishes are collected and fully filled in the charging barrel 12. The containing cavity 112 is convenient for storing a large amount of dishes at one time, is beneficial to the continuous discharge of the discharge port 113, improves the dish transfer efficiency, and is suitable for distributing a large amount of dishes in batches in fast food and canteens.

The holding cavity can be arranged into other shapes such as a sphere, a cylinder, a cube and the like. When the containing cavity is set to be a cone or a sphere, dishes easily slide down along the inner wall of the containing cavity under the action of gravity.

The diameter of the discharge port 113 is small, which is beneficial for the dishes falling down to be collected and enter the separating cylinder 12. The discharge port 113 has an arc-shaped edge corresponding to the feed cylinder 12, so that when the feed cylinder 12 rotates, the cylinder body is attached to the edge of the discharge port 113.

Please refer to fig. 2 and fig. 3, wherein fig. 2 is another angle structure diagram of an automatic meal distribution mechanism body according to the present invention, and fig. 3 is a partial half-section structure diagram of the automatic meal distribution mechanism body according to the present invention. The material separating barrel 12 is arranged below the storage hopper 11 and is used for receiving dishes falling from the discharge port 113. The dispensing barrel 12 is a cylinder and includes two end surfaces 121 and a curved surface 122 between the two end surfaces 121.

The barrel body of the material distribution barrel 12 is attached to the edge of the material outlet 113, so that dishes are in a closed state before being transferred to the dinner plate, the dishes are prevented from being leaked and contacting the outside, the dish distribution accuracy is improved, and the sanitation problem caused by human factors is avoided.

Be equipped with two branch silos 123 on dividing feed cylinder 12, divide silo 123 to include opening 1231 and with opening 1231 complex feed bin 1232. The opening 1231 is provided on the curved surface 122 of the component barrel 12, and is of an arc surface type, i.e., a shape in which a circle or a polygon is curved along an arc of the curved surface 122 of the component barrel 12.

Likewise, the openings may also be provided in the shape of rectangles, circles, and the like. Preferably, the opening 1232 is provided with an arc surface shape, which is more beneficial to the entering and transferring of the dishes in the storage bin 1232.

The bin 1232 is formed by inwards sinking the inner curved surface of the opening 1231, has a structure of an accommodating space, and is used for accommodating dishes.

When the dispensing cartridge has a three-dimensional structure including a plane, the cartridge may be formed by a plane recess, and has a structure of a receiving space.

The bins 1232 of the plurality of distributing grooves 123 are not communicated with each other, and have independent accommodating spaces.

The two distributing grooves 123 are arranged at any interval angle in the circumferential direction of the cylinder. Preferably, the two distributing grooves 123 are distributed symmetrically about the center of the cylindrical shaft. When one of the distributing troughs 123 rotates to the first position, the opening 1231 faces the discharge port 113 and is located below the discharge port 113, the bin 1232 receives the falling dish, and at this time, the other distributing trough 123 is located at the second position, and the opening 1231 faces away from the discharge port 113, so that the dish in the bin 1232 is transferred to the dinner plate.

The number of the distributing grooves can be set to other numbers. The dish transferring can be completed by one distributing groove, specifically, when the distributing groove rotates to the first position below the discharging port, the opening faces the discharging port, the storage bin receives dishes falling from the storage hopper, when the distributing cylinder continuously rotates to the second position, the dishes in the distributing groove are transferred to the dinner plate, the distributing groove continuously rotates and returns to the position below the discharging port, the dishes falling from the storage hopper are repeatedly received, and the dish transferring is continuously completed.

The number of the distributing troughs can also be three, four or other numbers larger than two according to the requirement. The increase of the number of the distributing grooves can realize continuous dish discharging and improve the dish transferring efficiency. The number of the material distributing grooves can be set according to the required vegetable distributing speed.

The distributing grooves are circumferentially distributed on the same plane. Preferably, the distributing grooves are uniformly distributed on the same plane in the circumferential direction. When the number of the distributing grooves is three, the included angle between every two adjacent distributing grooves is 120 degrees. When the number of the distributing grooves is four, the included angle between every two adjacent distributing grooves is 90 degrees.

When the distributing cylinder 12 is of a solid structure, the distributing groove 123 is a depression dug on the cylinder body of the distributing cylinder 12, the solid structure of the distributing cylinder 12 can ensure the shape and size of the distributing groove 123, the shape deformation of the distributing groove 123 caused by long-term use is avoided, and the distributing groove 123 is supported.

Referring to fig. 3, fig. 3 is a schematic partial half-sectional structure view of an automatic meal distribution mechanism body according to the present invention. The driving assembly 13 includes a rotation bearing 131 and a rotation shaft 132. The rotating shaft 132 vertically penetrates the end surfaces 122 of both ends of the dispensing barrel 12, is located at the axis of the cylinder, and is connected to the rotating bearings 131 at the end surfaces 122 of both sides.

The rotating shaft 132 rotates the material separating cylinder 12 to rotate the material separating groove 123 arranged on the material separating cylinder 12, so that the material separating groove 123 can rotate from the first position to the second position, and the processes of receiving dishes and transferring the dishes are completed.

In another embodiment, the feed cylinder may also be provided as a sphere. The rotating shaft penetrates through the center of the sphere to ensure that the material distribution groove can rotate to a first position below the discharge port, so that the opening faces the discharge port, and the storage bin receives dishes falling from the discharge port; the material distributing groove can also be rotated to the second position, so that the opening is back to the material outlet, and the dishes in the material bin can be conveniently transferred to the dinner plate. At this time, when the number of the distributing grooves is multiple, the distributing grooves are circumferentially distributed on the same plane passing through the center of the sphere.

In another embodiment, the automatic meal distribution mechanism does not include a distribution barrel, and the drive assembly directly rotates the distribution chute. When the number of the distributing grooves is multiple, the distributing grooves are circumferentially distributed on the same plane, and the rotating shaft is in transmission connection with the circle center of the plane.

The driving assembly 13 further includes a driving motor 133, and the driving motor 133 is disposed at one side of one of the end surfaces 122 and is drivingly connected to the rotating shaft 132.

In another embodiment, the rotating shaft can be rotated by other modes such as hand cranking without arranging a driving motor, so that the material distributing groove is driven to rotate.

A seal ring 15 is provided between the rotary bearing 131 and the feed cylinder 12 to prevent leakage of the lubricant on the rotary shaft.

Referring to fig. 2, fig. 2 is a schematic view of another angle structure of an automatic meal distribution mechanism body according to the present invention. The utility model is provided with a vibrating plate 17 and a vibrating motor 16 arranged on the vibrating plate 17, wherein the vibrating plate 17 comprises a through hole 171, and the storage hopper 11 is arranged in the through hole 171. Vibrating motor 16 transmits the vibration to storage hopper 11 through vibration board 17 at vibration board 17 place plane, and the separation of cooked food and storage hopper 11 inner wall is waited to divide in all directions on the plane of being convenient for the whereabouts speed, and the vegetable whereabouts and the utilization in each corner in storage hopper 11 are guaranteed, avoids the waste of food and alleviates the cleaning work of follow-up storage hopper 11. Meanwhile, the vibration motor 16 is arranged on the vibration plate 17, so that the installation, the disassembly and the maintenance of the vibration motor 16 are facilitated.

Referring to fig. 4, a schematic structural diagram of an automatic meal distribution mechanism according to the present invention is shown. In this embodiment, a vibration spring 18 is provided, and the vibration spring 18 is used for connecting the storage hopper 11 and the frame 20. The storage hopper 11 is disposed in a through hole in a mounting plate, the vibrating spring 18 is disposed intermediate the mounting plate and the frame 20, and the mounting plate is located above the frame 20.

Alternatively, the mounting plate may be located below or within the housing 20.

Alternatively, the storage hopper 11 may be suspended from the frame 20 by a vibrating spring 18.

Alternatively, the mounting plate may not be provided and the vibrating spring 18 is directly connected to the storage hopper 11.

The vibration of the vibration motor 16 can drive the storage hopper 11 to have a better vibration amplitude, so as to ensure the falling of the material. Because the storage hopper 11 is elastically connected with the rack 20 through the vibrating spring 18, the vibrating spring 18 absorbs the vibration of the storage hopper 11, so that the rack 20 cannot vibrate along with the storage hopper 11, and the stability of the whole machine is guaranteed.

Referring to fig. 5, fig. 5 is a schematic structural diagram of a distributing trough according to the present invention. The bin 1232 of the distributing chute 123 is a cuboid 12321, a column 12322 or a segment 12323, and the opening 1231 is arc-shaped.

When dishes to be distributed easily fall and the resistance is low, if the dishes to be distributed are spherical and diced dishes such as peanuts, soybeans and diced lotus roots, the distributing groove 123 with the rectangular opening 1231 and the cuboid 1232 as the bin 1232 is adopted.

When dishes to be served are radish slices, asparagus lettuce slices and the like, which have large frictional resistance, and cavities are easily formed among materials, the feeding trough 123 with the arc-shaped opening 1231 and the spherical segment 12323 as the bin 1232 is suitable.

Preferably, when the opening is the rectangle, when the feed bin is the cuboid, the opening is 60 ~ 120X 40 ~ 100 millimeters²And the depth of the cuboid is 30-70 mm.

The length of the opening is less than 60 mm, the width of the opening is less than 40 mm, and when the depth of the cuboid is more than 70 mm, the opening is too small, so that dishes are not transferred easily, and the efficiency is low; open-ended length is greater than 120 millimeters, and the width is greater than 100 millimeters, and when the cuboid degree of depth was less than 30 millimeters, because wait to divide the cooked food to drop easily, little with the frictional force of storage hopper, the opening is too big, causes the cooked food to scatter the place outside the dinner plate easily at the transfer in-process, is unfavorable for shifting the location of cooked food, and then influences the precision of cooked food weight.

Preferably, when the opening is circular and the bin is a segment, the diameter of the opening is 60-120 mm, and the depth of the segment is 30-70 mm.

When the diameter of the opening is less than 60 mm and the depth of the spherical segment is more than 70 mm, because the friction resistance between the materials of the dish is large, a cavity is easily formed between the materials, the opening is too small, the cavity is easily formed in the filling process of the dish, and the dish is quantified by volume, so that the dish is not precisely quantified; when the diameter of the opening is larger than 120 mm and the depth of the spherical segment is smaller than 30 mm, dishes are easily scattered to the place outside the dinner plate in the transferring process, the dishes are not favorably positioned and transferred, and the accuracy of dish weight is further influenced.

Preferably, when the opening is cambered and the bin is a segment, the diameter of the opening is 60-120 mm, and the depth of the segment is 30-70 mm.

When the diameter of the opening is less than 60 mm and the depth of the spherical segment is more than 70 mm, because the friction resistance between the materials of the dish is large, a cavity is easily formed between the materials, the opening is too small, the cavity is easily formed in the filling process of the dish, and the dish is quantified by volume, so that the dish is not precisely quantified; when the diameter of the opening is larger than 120 mm and the depth of the spherical segment is smaller than 30 mm, dishes are easily scattered to the place outside the dinner plate in the transferring process, the dishes are not favorably positioned and transferred, and the accuracy of dish weight is further influenced.

For dishes to be distributed, which are easy to turn and fill, a narrow-mouth and deep trough is adopted, so that the dish distribution precision is easy to improve.

A trough with a large opening and a shallow depth is suitable for dishes to be distributed, which are easy to form large gap resistance, and the dish distribution precision is easy to improve.

The size of the chamber of the distribution chute 123 is generally in the range of 50 ml to 450 ml.

According to the utility model, the containing cavity is arranged to realize continuous dish distribution, so that the dish distribution efficiency is improved; through setting up rotatable branch silo for the transfer of cooked food between storage hopper and dinner plate can effectively improve branch dish efficiency, and simultaneously, fixed branch silo can realize accurate branch dish, avoids relying on the uncertain condition of branch dish volume that the sense organ judgement brought by manual operation. Moreover, the contact between a human body and dishes is reduced, the distance between the human body and the dishes is kept, and the sanitation problem caused by human factors to the dishes is reduced.

The above description is only for the purpose of illustrating an embodiment of the automatic meal distribution mechanism of the present invention, and since it will be obvious to those skilled in the art that various modifications and changes may be made therein, the description is not intended to limit the automatic meal distribution mechanism of the present invention to the related structural scope shown, and all modifications and equivalents that may be utilized are within the scope of the claims of the present invention.

Claims (11)

1. An automatic meal distribution mechanism is characterized by comprising,

the storage hopper comprises a feeding hole, a containing cavity and a discharging hole;

the distribution groove comprises an opening and a storage bin matched with the opening, the distribution groove can rotate between a first position and a second position, when the distribution groove is located at the first position, the opening faces the discharge hole, and when the distribution groove is located at the second position, the opening faces back to the discharge hole;

the driving assembly comprises a rotating shaft connected with the material distributing groove.

2. The automatic meal distribution mechanism of claim 1, wherein the automatic meal distribution mechanism comprises a vibration motor, and the vibration motor is in transmission connection with the storage hopper.

3. The automatic meal distribution mechanism of claim 2, wherein the automatic meal distribution mechanism comprises a vibrating plate, the vibrating motor is mounted on the vibrating plate, the vibrating plate comprises a through hole, and the storage hopper is disposed in the through hole.

4. The automatic meal distribution mechanism according to claim 1 or 2, wherein the automatic meal distribution mechanism comprises a meal distribution barrel, and an opening of the meal distribution groove is arranged on the surface of the meal distribution barrel.

5. The automatic meal distribution mechanism according to claim 4, wherein the meal distribution barrel is a cylinder and comprises two end faces and a curved surface between the two end faces, the opening is formed in the curved surface, and the rotating shaft perpendicularly penetrates through the end faces.

6. The automatic meal distribution mechanism of claim 5, wherein the edge of the discharge port is attached to the curved surface.

7. The automatic meal distribution mechanism of claim 1, wherein the opening is circular, rectangular or cambered, and the bin is a cuboid, a cone, a cylinder or a segment.

8. The automatic meal distribution mechanism according to claim 7, wherein when the opening is rectangular and the bin is rectangular, the opening is 60-120 x 40-100 mm²The depth of the cuboid is 30-70 mm; when the opening is circular and the bin is a segment, the diameter of the opening is 60-120 mm, and the depth of the segment is 30-70 mm; when the opening is cambered surface type, when the feed bin is the segment of a sphere, the diameter of the opening is 60-120 mm, and the depth of the segment of a sphere is 30-70 mm.

9. The automatic meal distribution mechanism of claim 1, wherein the number of the distribution grooves is two, three or four, and the distribution grooves are circumferentially distributed on the same plane.

10. The automated meal distribution mechanism of claim 6, further comprising a seal ring, wherein the drive assembly further comprises a rotary bearing, and wherein the seal ring is disposed intermediate the rotary bearing and the end surface.

11. The automatic meal distribution mechanism of claim 4, further comprising a frame, wherein the storage hopper is elastically connected to the frame.

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