CN117617793A - Feeding device, feeding bottle and feeding mechanism applied by feeding device and cooking system - Google Patents

Abstract

The application discloses feedway and material bottle and feeding mechanism, cooking system of using thereof. The material bottle is provided with a first positioning structure and a second positioning structure which are spaced from each other, and the feeding mechanism is provided with a first limiting structure and a second limiting structure which are spaced from each other. The first location structure cooperates with the first limit structure, and the second location structure cooperates with the second limit structure, so that at least two-point supports are formed between the material bottle and the feeding mechanism, the material bottle can be stably assembled on the feeding mechanism, and shaking of the material bottle on the feeding mechanism is avoided as much as possible.

Description

Feeding device, feeding bottle and feeding mechanism applied by feeding device and cooking system

Technical Field

The application relates to the technical field of cooking equipment, in particular to a feeding device, a material bottle and a feeding mechanism for the feeding device, and a cooking system.

Background

Along with the improvement of living standard, the demands of people on kitchen appliances are higher and higher, and the intelligent electric rice cooker is as small as an intelligent kitchen so as to meet the intelligent demands of modern people on the appliances. Taking cooking as an example, traditional cooking needs manual feeding, and the manual feeding mostly needs experience to control feeding amount, so that standardization and intellectualization are difficult to realize. In order to solve the problems, a dish frying machine as an intelligent household appliance is generated. The frying machine solves the problems of poor control of the feeding amount in the seasoning adding process, and is convenient for standardization and intellectualization.

Currently, most cooking opportunities are equipped with a feeding mechanism. The feeding mechanism is equipped with a plurality of material bottles, and every material bottle is used for holding different seasonings. The flavoring in the material bottle is conveyed to the cooking machine through the feeding mechanism, so that automatic flavoring addition is realized, and the feeding amount of various flavoring can be accurately controlled. However, the current material bottle is unreasonable in design, so that the material bottle cannot be stably assembled in the feeding mechanism, and the material bottle is easy to shake.

Disclosure of Invention

The application provides a feedway and feed mechanism, cooking system of material bottle and feeding of using thereof can make the material bottle assemble in feeding mechanism steadily.

The application provides a material bottle, this material bottle includes: the bottle body is internally provided with a storage cavity for storing auxiliary materials; the first positioning structure is arranged on the bottle main body; the second positioning structure is arranged on the bottle main body and is spaced from the first positioning structure; wherein, first location structure and second location structure are used for the cooperation to assemble bottle main part in feeding mechanism, and the auxiliary material in the storage chamber exports cooking equipment through feeding mechanism.

In an embodiment of the present application, the vial further comprises: the third positioning structure is arranged on the bottle main body and is respectively arranged at intervals with the first positioning structure and the second positioning structure; wherein, first location structure, second location structure and third location structure are used for the cooperation to assemble bottle main part in feeding mechanism.

In an embodiment of the present application, the first positioning structure, the second positioning structure and the third positioning structure are sequentially and alternately distributed along the first linear direction.

In one embodiment of the present application, the outer wall of the bottle body has connected side and bottom walls; the first positioning structure is close to the connecting position of the side wall and the bottom wall, and extends along the direction perpendicular to the side wall and the direction perpendicular to the bottom wall respectively; the second positioning structure is positioned on the bottom wall and extends along the direction perpendicular to the bottom wall.

In an embodiment of the present application, the first positioning structure and the second positioning structure are both groove structures.

In an embodiment of the present application, the first positioning structure and the second positioning structure are both located at the bottom of the bottle body; the third positioning structure is arranged far away from the bottom of the bottle main body; wherein, the material bottle still includes: and the switching assembly is arranged on the bottle main body and is communicated with the storage cavity, and auxiliary materials in the storage cavity are output to the feeding mechanism through the switching assembly, wherein the switching assembly comprises a third positioning structure.

In one embodiment of the present application, a switching assembly includes: an adapter, remote from the bottom of the bottle body; at least part of the adapter extends to the outside relative to the bottle main body so as to be spliced with the feeding mechanism, so that the adapter is matched with the first positioning structure and the second positioning structure to assemble the bottle main body to the feeding mechanism; the material sucking pipe is arranged in the material storage cavity and is communicated with the adapter, and the material sucking pipe extends towards the bottom of the material storage cavity; wherein the suction pipe is configured to be capable of sucking auxiliary materials in the storage cavity to the adapter for output in response to a pressure difference effect between the adapter and the storage cavity.

In one embodiment of the application, a discharging cavity with an outlet at one end is arranged in the adapter, the suction pipe is communicated with the discharging cavity, and auxiliary materials from the suction pipe are output through the outlet; the adapter assembly further comprises: the sealing piece is arranged in the discharging cavity; and the elastic piece is arranged in the discharging cavity and is connected with the sealing piece, and the elastic piece is used for enabling the sealing piece to have a trend of moving towards the outlet.

In an embodiment of the present application, the suction tube is made of a flexible material.

In an embodiment of the present application, the bottle body further comprises: the main body part is provided with a first positioning structure and a second positioning structure; an extension part extending outwards from one side of the main body part and being close to the top of the main body part; wherein, the adapter stretches out to outside from extension.

In an embodiment of the present application, the bottle body further comprises: a bottle body; the bottom cover is arranged at the bottom of the bottle body and is in butt joint with the bottle body to form a storage cavity; wherein, the second location structure is located the bottom.

Correspondingly, the application still provides a feeding mechanism, and this feeding mechanism includes: a feeding main body provided with a feeding pipe group; the first limiting structure is arranged on the feeding main body; the second limiting structure is arranged on the feeding main body and is spaced from the first limiting structure; wherein, first limit structure and second limit structure are used for the cooperation to be bottled to be joined in marriage in the feed main part with the material, and the auxiliary material in the material bottle is exported to cooking equipment through the feed pipe group.

In an embodiment of the present application, the feeding mechanism further includes: the third limiting structure is arranged on the feeding main body and is respectively arranged at intervals with the first limiting structure and the second limiting structure; the first limiting structure, the second limiting structure and the third limiting structure are used for matching the feeding main body with the feeding bottle.

In an embodiment of the present application, the feeding mechanism includes at least two sets of limiting structure combinations, each set of limiting structure combinations includes a first limiting structure, a second limiting structure and a third limiting structure, so that different material bottles are assembled on the feeding main body through different limiting structure combinations; the feeding mechanism is defined with a first linear direction and a second linear direction which are perpendicular to each other; the first limit structure, the second limit structure and the third limit structure which belong to the same limit structure combination are sequentially distributed at intervals along the first straight line direction, and each group of limit structure combination is sequentially distributed at intervals along the second straight line direction.

In one embodiment of the present application, the feed body comprises: the support seat is internally provided with a pipe group cavity for accommodating a feeding pipe group; and a weighing tray comprising: the first bearing part is arranged on the supporting seat; the second bearing part is arranged on the first bearing part and extends along the direction away from the supporting seat relative to the first bearing part; wherein, first limit structure is close to the hookup location of first supporting portion and second supporting portion, and second limit structure is located first supporting portion, and third limit structure is located second supporting portion.

In an embodiment of the present application, the first limiting structure is located at a connection position of the first supporting portion and the second supporting portion; the second limit structure is far away from the second bearing part relative to the first limit structure; the third limit structure is located at the end part of the second bearing part far away from the first bearing part.

In one embodiment of the present application, a transition cavity is provided inside the second support portion, which is communicated with the tube set cavity; the end part of the second bearing part, which is far away from the first bearing part, is provided with a material drawing opening, and the material drawing opening is used for being spliced with a material bottle, so that the material drawing opening is matched with the first limiting structure and the second limiting structure to match the material bottle with the material feeding main body; the feed pipe group includes: one end of the pumping pipe is communicated with the pumping port, and the other end of the pumping pipe extends into the pipe group cavity through the transition cavity; the negative pressure pump is arranged in the pipe group cavity and is connected with the other end; the negative pressure pump is used for creating a negative pressure environment in the material pumping pipe, so that auxiliary materials in the material bottle are output through the material pumping port and the material pumping pipe.

In an embodiment of the application, be equipped with the ejector pin in the drawing port, the ejector pin is used for making the interior space of drawing port intercommunication material bottle when drawing port and material bottle are pegged graft mutually.

In an embodiment of the present application, the suction tube is made of a flexible material.

In an embodiment of the present application, the feeding mechanism further includes: the cover body is covered on the supporting seat to form a cavity for accommodating the weighing tray and the material bottle with the supporting seat.

In an embodiment of the present application, the feeding mechanism includes at least two sets of limit structure combinations, each set of limit structure combinations includes a first limit structure and a second limit structure, so that different material bottles are assembled on the feeding main body through different limit structure combinations; wherein, different limit structure combinations have different second limit structures for every group limit structure combination is used for assembling corresponding material bottle.

In an embodiment of the present application, the second limiting structure is a columnar structure protruding on the surface of the feeding main body, and the outer peripheral surface of the second limiting structure has a foolproof plane; wherein, the second limit structure of different limit structure combinations has foolproof plane of different orientation.

Correspondingly, the application also provides a feeding device, which comprises a material bottle and a feeding mechanism; the material bottle includes: the bottle body is internally provided with a storage cavity for storing auxiliary materials; the first positioning structure is arranged on the bottle main body; the second positioning structure is arranged on the bottle main body and is spaced from the first positioning structure; and the feeding mechanism includes: a feeding main body provided with a feeding pipe group; the first limiting structure is arranged on the feeding main body; the second limiting structure is arranged on the feeding main body and is spaced from the first limiting structure; wherein, first limit structure cooperation first limit structure, and second limit structure cooperation second limit structure to assemble bottle main part in the feed main part, auxiliary material in the storage cavity is through feed pipe group output to cooking equipment.

Correspondingly, the application also provides a cooking system, which comprises cooking equipment and a feeding device, wherein the feeding device comprises a material bottle and a feeding mechanism; the material bottle includes: the bottle body is internally provided with a storage cavity for storing auxiliary materials; the first positioning structure is arranged on the bottle main body; the second positioning structure is arranged on the bottle main body and is spaced from the first positioning structure; and the feeding mechanism includes: a feeding main body provided with a feeding pipe group connected with the cooking equipment; the first limiting structure is arranged on the feeding main body; the second limiting structure is arranged on the feeding main body and is spaced from the first limiting structure; wherein, first limit structure cooperation first limit structure, and second limit structure cooperation second limit structure to assemble bottle main part in the feed main part, auxiliary material in the storage cavity is through feed pipe group output to cooking equipment.

The beneficial effects of this application are: different from the prior art, the application provides a feedway and material bottle and feeding mechanism, cooking system of using thereof. The material bottle is provided with a first positioning structure and a second positioning structure which are spaced from each other, and the feeding mechanism is provided with a first limiting structure and a second limiting structure which are spaced from each other. The first location structure cooperates with the first limit structure, and the second location structure cooperates with the second limit structure, so that at least two-point supports are formed between the material bottle and the feeding mechanism, the material bottle can be stably assembled on the feeding mechanism, and shaking of the material bottle on the feeding mechanism is avoided as much as possible.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the description of the embodiments will be briefly introduced below, it being obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of an embodiment of a feeding device of the present application;

FIG. 2 is a schematic view of another embodiment of the feeding device of the present application;

FIG. 3 is a schematic view of an embodiment of a bottle of the present application;

FIG. 4 is a schematic view showing a sectional structure of the feeding device in the direction A-A shown in FIG. 2;

FIG. 5 is a schematic view of the structure of the feeding device B in FIG. 2;

FIG. 6 is a schematic top view of an embodiment of a feed mechanism of the present application;

fig. 7 is a schematic view of the structure of the feeding device in the region C shown in fig. 4.

Reference numerals illustrate:

10 feeding device, 20 material bottles, 21 bottle main body, 211 storage cavity, 212 side wall, 213 bottom wall, 214 main body part, 215 extension part, 22 first location structure, 23 second location structure, 24 third location structure, 25 switching component, 251 switching head, 2511 discharging cavity, 2512 outlet, 252 material sucking pipe, 253 sealing piece, 254 elastic piece, 30 feeding mechanism, 31 feeding main body, 311 feeding pipe group, 3111 material sucking pipe, 3112 negative pressure pump, 312 supporting seat, 3121 pipe group cavity, 313 weighing tray, 3131 first supporting part, 3132 second supporting part, 3133 transition cavity, 3134 material sucking port, 3135 ejector rod, 32 first limiting structure, 33 second limiting structure, 331 fool-proof plane, 34 third limiting structure and 35 cover body.

Detailed Description

The following description of the embodiments of the present application will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all, of the embodiments of the present application. All other embodiments, based on the embodiments herein, which are within the scope of the protection of the present application, will be within the skill of the art without inventive effort. Furthermore, it should be understood that the detailed description is presented herein for purposes of illustration and explanation only and is not intended to limit the present application. In this application, unless otherwise indicated, terms of orientation such as "upper", "lower", "left" and "right" are generally used to refer to the directions of the drawings in which the device is actually used or in an operating state.

The application provides a feedway and material bottle and feeding mechanism, cooking system of using thereof, the following respectively detailed description. It should be noted that the following description order of the embodiments is not intended to limit the preferred order of the embodiments of the present application. In the following embodiments, the descriptions of the embodiments are focused on, and for the part that is not described in detail in a certain embodiment, reference may be made to the related descriptions of other embodiments.

Referring to fig. 1, fig. 1 is a schematic structural diagram of an embodiment of a feeding device of the present application.

In one embodiment, the cooking system includes a cooking apparatus and a feeding apparatus 10. The cooking equipment is connected with the feeding device 10 through a pipeline, and the feeding device 10 conveys auxiliary materials to the cooking equipment through a pipeline between the feeding device and the cooking equipment. The cooking apparatus is a main element for performing cooking operations in the cooking system. The servicer 10 provides auxiliary materials to the cooking apparatus that assist the cooking apparatus in cooking the food materials, including but not limited to, frying, boiling, steaming, frying, etc. The working principle of the cooking device is understood by those skilled in the art, and will not be described here again. The auxiliary materials can comprise salt, monosodium glutamate, soy sauce and other seasonings, and the auxiliary materials can also be clear water and the like, and are not limited herein.

The feeding device 10 of the embodiment of the present application is explained below.

In one embodiment, the feeding device 10 includes a bottle 20 and a feeding mechanism 30. The material bottle 20 is used for storing auxiliary materials, and the feeding mechanism 30 is connected with the cooking equipment through a pipeline. The material bottle 20 can be assembled to the feeding mechanism 30, and the auxiliary materials in the material bottle 20 are conveyed to the cooking equipment through the feeding mechanism 30.

The auxiliary material in the material bottle 20 is in a liquid state. When the auxiliary materials are solid seasonings such as salt and monosodium glutamate in normal state, the solid seasonings are dissolved in clear water to form liquid seasonings such as salt water and monosodium glutamate water, and the liquid seasonings are stored in the material bottle 20. When the auxiliary materials are vinegar, soy sauce, light soy sauce, dark soy sauce and other seasonings which are normally liquid, the liquid seasonings can be directly stored in the material bottle 20. The feeding device 10 is typically provided with at least two vials 20, each vial 20 being adapted to store a different auxiliary material.

Referring to fig. 2 and 5 together, fig. 2 is a schematic structural diagram of another embodiment of the feeding device of the present application, fig. 3 is a schematic structural diagram of an embodiment of a bottle of the present application, fig. 4 is a schematic sectional structural diagram of the feeding device A-A shown in fig. 2, and fig. 5 is a schematic structural diagram of the feeding device B shown in fig. 2.

In one embodiment, the vial 20 includes a vial body 21. The bottle main body 21 is the main part of the material bottle 20, and the inside storage cavity 211 that is used for storing auxiliary material that is equipped with of bottle main body 21, auxiliary material in the storage cavity 211 exports cooking equipment through feeding mechanism 30. The material bottle 20 further comprises a first positioning structure 22 and a second positioning structure 23, the first positioning structure 22 and the second positioning structure 23 are both arranged on the bottle main body 21, the first positioning structure 22 and the second positioning structure 23 are spaced from each other, and the first positioning structure 22 and the second positioning structure 23 are used for being matched to assemble the bottle main body 21 on the feeding mechanism 30, namely, the material bottle 20 is assembled on the feeding mechanism 30.

The feeding mechanism 30 includes a feeding body 31. The feeding main body 31 is a main part of the feeding mechanism 30, the feeding main body 31 is provided with a feeding pipe group 311, the feeding pipe group 311 is used for connecting cooking equipment, and auxiliary materials in the material bottle 20 are output to the cooking equipment through the feeding pipe group 311. The feeding mechanism 30 further includes a first limiting structure 32 (as shown in fig. 5) and a second limiting structure 33, the first limiting structure 32 and the second limiting structure 33 are both disposed on the feeding main body 31, the first limiting structure 32 and the second limiting structure 33 are spaced apart from each other, and the first limiting structure 32 and the second limiting structure 33 are used for matching to assemble the material bottle 20 on the feeding main body 31, i.e. assemble the material bottle 20 on the feeding mechanism 30.

Through the above manner, the first positioning structure 22 is matched with the first limiting structure 32, and the second positioning structure 23 is matched with the second limiting structure 33, so that at least two-point supports are formed between the material bottle 20 and the feeding mechanism 30, the material bottle 20 can be stably assembled on the feeding mechanism 30, and shaking of the material bottle 20 on the feeding mechanism 30 is avoided as much as possible.

In one embodiment, the vial 20 further comprises a third positioning structure 24. The third positioning structure 24 is disposed on the bottle main body 21, and the third positioning structure 24 is disposed at intervals from the first positioning structure 22 and the second positioning structure 23, respectively. Wherein the first positioning structure 22, the second positioning structure 23 and the third positioning structure 24 are used for matching and assembling the bottle main body 21 to the feeding mechanism 30. In this way, in the present embodiment, through the first positioning structure 22, the second positioning structure 23 and the third positioning structure 24, a three-point support is formed between the material bottle 20 and the feeding mechanism 30, and the material bottle 20 is further stably assembled on the feeding mechanism 30, so as to further avoid shaking of the material bottle 20 on the feeding mechanism 30.

Similarly, the feeding mechanism 30 further includes a third limiting structure 34. The third limiting structure 34 is disposed on the feeding body 31, and the third limiting structure 34 is disposed at intervals with the first limiting structure 32 and the second limiting structure 33, respectively. The first limiting structure 32, the second limiting structure 33 and the third limiting structure 34 are used for assembling the material bottle 20 to the material feeding main body 31 in a matching manner. In this way, in the present embodiment, through the first limiting structure 32, the second limiting structure 33 and the third limiting structure 34, a three-point support is formed between the material bottle 20 and the feeding mechanism 30, and the material bottle 20 is further stably assembled on the feeding mechanism 30, so as to further avoid shaking of the material bottle 20 on the feeding mechanism 30. Specifically, the third limiting structure 34 on the feeding mechanism 30 is configured to cooperate with the third positioning structure 24 on the material bottle 20 to assemble the material bottle 20 to the feeding mechanism 30.

Of course, in other embodiments of the present application, the bottle 20 may include only the first positioning structure 22 and the second positioning structure 23, and the feeding mechanism 30 may include only the first limiting structure 32 and the second limiting structure 33, which are not limited herein.

Further, for the example of the above-described feeding device 10 provided with at least two vials 20, each vial 20 has a corresponding first positioning structure 22, second positioning structure 23 and third positioning structure 24. Correspondingly, the feeding mechanism 30 comprises at least two groups of limiting structure combinations, and each group of limiting structure combination comprises a first limiting structure 32, a second limiting structure 33 and a third limiting structure 34, so that different material bottles 20 are assembled on the feeding main body 31 through different limiting structure combinations. In other words, in each set of positioning structure combinations, the first positioning structure 32 cooperates with the first positioning structure 22 on the corresponding material bottle 20, the second positioning structure 33 cooperates with the second positioning structure 23 on the corresponding material bottle 20, and the third positioning structure 34 cooperates with the third positioning structure 24 on the corresponding material bottle 20, and each set of positioning structure combinations is used for assembling the material bottle 20 uniquely corresponding thereto to the feeding body 31.

The feeding mechanism 30 defines a first straight direction (indicated by an arrow X in fig. 2, the same applies hereinafter) and a second straight direction (indicated by an arrow Y in fig. 2, the same applies hereinafter) which are perpendicular to each other. The first positioning structure 22, the second positioning structure 23 and the third positioning structure 24 on the same material bottle 20 are sequentially and alternately distributed along the first straight line direction. The first limiting structure 32, the second limiting structure 33 and the third limiting structure 34 belonging to the same limiting structure combination are sequentially and alternately distributed along the first straight line direction. The distribution modes of the first positioning structure 22, the second positioning structure 23 and the third positioning structure 24 belonging to the same material bottle 20 are matched with the distribution modes of the first limiting structure 32, the second limiting structure 33 and the third limiting structure 34 belonging to the same limiting structure combination, so that the material bottle 20 and the limiting structure combination which correspond to each other can be mutually matched for assembly. The limiting structure combinations of each group are sequentially distributed at intervals along the second linear direction.

It should be noted that the first and second straight directions should be understood as the planes defined by the first and second straight directions are parallel to the horizontal plane when the feeding mechanism 30 is properly placed during the process of applying the feeding device 10 to the cooking apparatus.

The first positioning structure 22, the second positioning structure 23 and the third positioning structure 24 are sequentially and alternately distributed along the first straight line direction, preferably, the first positioning structure 22, the second positioning structure 23 and the third positioning structure 24 are strictly distributed along the first straight line direction, that is, the central axis of the first positioning structure 22, the central axis of the second positioning structure 23 and the central axis of the third positioning structure 24 are coplanar, and the planes defined by the three are parallel to the first straight line direction. Similarly, the first limiting structure 32, the second limiting structure 33 and the third limiting structure 34 are sequentially and alternately distributed along the first straight line direction, preferably, the first limiting structure 32, the second limiting structure 33 and the third limiting structure 34 are strictly distributed along the first straight line direction, that is, the central axis of the first limiting structure 32, the central axis of the second limiting structure 33 and the central axis of the third limiting structure 34 are coplanar, and the planes defined by the three are parallel to the first straight line direction. In this way, the user can conveniently align and match the first positioning structure 22, the second positioning structure 23 and the third positioning structure 24 on the material bottle 20 with the corresponding first limiting structure 32, second limiting structure 33 and third limiting structure 34 on the feeding mechanism 30, so as to facilitate the user to assemble the material bottle 20 on the feeding mechanism 30.

Of course, in other embodiments of the present application, the first positioning structure 22, the second positioning structure 23 and the third positioning structure 24 may also be distributed along the first linear direction, that is, some of the first positioning structure 22, the second positioning structure 23 and the third positioning structure 24 may be allowed to deviate from the first linear direction to some extent. Similarly, the first limiting structure 32, the second limiting structure 33 and the third limiting structure 34 may be substantially distributed along the first straight line direction, i.e. some of the first limiting structure 32, the second limiting structure 33 and the third limiting structure 34 are allowed to deviate from the first straight line direction to some extent.

The manner of engagement between the first positioning structure 22 and the first limiting structure 32, the manner of engagement between the second positioning structure 23 and the second limiting structure 33, and the manner of engagement between the third positioning structure 24 and the third limiting structure 34 in the embodiment of the present application will be described below. It is to be understood that the three sets of engaging means are not limited to the following, and the three sets of engaging means may be interchanged.

Please continue to refer to fig. 3. In one embodiment, the outer wall of the bottle body 21 of the vial 20 has associated side walls 212 and a bottom wall 213. The first positioning structure 22 is near the connection position of the side wall 212 and the bottom wall 213, the first positioning structure 22 is located on the side wall 212 and/or the bottom wall 213, and further the first positioning structure 22 is located at the connection position of the side wall 212 and the bottom wall 213. And, the first positioning structure 22 extends in a direction perpendicular to the side wall 212 and a direction perpendicular to the bottom wall 213, respectively.

With continued reference to fig. 2 and 4, the feed body 31 includes a support base 312 and a weighing tray 313. The supporting seat 312 is a basic carrier of the feeding body 31, and plays a role in bearing other parts of the feeding body 31. The support base 312 has a tube set cavity 3121 therein for receiving the feed tube set 311. The weighing tray 313 is used for holding the vials 20, i.e. the vials 20 are mounted to the weighing tray 313 of the feeding mechanism 30. The weighing tray 313 is matched with a weighing scale for weighing the weight of the material bottle 20 supported on the weighing tray 313 so as to obtain the weight change of the material bottle 20 and further obtain the charging amount of the auxiliary materials.

The weighing tray 313 includes a first bearing 3131 and a second bearing 3132. The first bearing portion 3131 is disposed on the support base 312. The second bearing portion 3132 is disposed on the first bearing portion 3131 and extends along a direction away from the supporting seat 312 relative to the first bearing portion 3131, so that the second bearing portion 3132 is embodied as a step structure protruding from a surface of the first bearing portion 3131 facing away from the supporting seat 312. The connection position of the first bearing portion 3131 and the second bearing portion 3132 is a corner position, the first limiting structure 32 is close to the connection position of the first bearing portion 3131 and the second bearing portion 3132, the first limiting structure 32 is located on the first bearing portion 3131 and/or the second bearing portion 3132, and further the first limiting structure 32 is located at the connection position of the first bearing portion 3131 and the second bearing portion 3132, as shown in fig. 5. When the material bottle 20 is assembled to the weighing tray 313, the bottom wall 213 of the bottle body 21 of the material bottle 20 faces the first bearing portion 3131, the side wall 212 faces the second bearing portion 3132, and the first positioning structure 22 and the first limiting structure 32 cooperate with each other to enable the material bottle 20 to be reliably assembled to the weighing tray 313.

Specifically, the first positioning structure 22 is a groove structure recessed relative to the outer wall surface of the bottle main body 21, and the first limiting structure 32 is convexly arranged on the surface of the weighing tray 313. When the bottle 20 is assembled on the weighing tray 313, the first positioning structure 22 and the first limiting structure 32 are in concave-convex jogged with each other, so that the bottle 20 is reliably assembled on the weighing tray 313. In this embodiment, the first positioning structure 22 and the first limiting structure 32 cooperate with each other to limit the shake of the material bottle 20 in the second linear direction, which is further beneficial to stably assembling the material bottle 20 to the feeding mechanism 30.

Of course, in other embodiments of the present application, the first positioning structure 22 may be protruding from the outer wall surface of the bottle main body 21, and the first limiting structure 32 may be a groove structure recessed relative to the surface of the weighing tray 313. Even further, the first positioning structure 22 and the first limiting structure 32 are not limited to the manner of matching the groove structure and the protrusion structure, which is not limited herein.

It should be noted that, for the example where the feeding device 10 is provided with at least two bottles 20, the at least two bottles 20 share a weighing scale, that is, the feeding mechanism 30 of the present embodiment is provided with a weighing scale for weighing the weight of all the bottles 20 on the weighing tray 313. In this embodiment, different material bottles 20 are fed in a time-sharing manner, that is, only one material bottle 20 outputs auxiliary materials at the same time, so that the weight change information obtained by the weighing scale is only the weight change of one material bottle 20, and thus the embodiment can obtain the weight change of each material bottle 20 through one weighing scale, that is, the feeding amount of the auxiliary materials stored in each material bottle 20.

And, the feeding mechanism 30 further includes a cover 35, as shown in fig. 1. The cover 35 covers the supporting seat 312 to form a cavity for accommodating the weighing tray 313 and the bottle 20 in cooperation with the supporting seat 312. The cover body 35 is used for accommodating all the material bottles 20 on the feeding mechanism 30 in the cavity, meanwhile, the cover body 35 is also used for accommodating the weighing tray 313 in the cavity, and the cover body 35 is used for preventing a user from mistakenly touching the material bottles 20 or the weighing tray 313 in the feeding process to influence weighing, so that the feeding precision is guaranteed.

Please continue to refer to fig. 3. In an embodiment, the second positioning structure 23 is located at the bottom wall 213 of the bottle body 21 of the material bottle 20, and the second positioning structure 23 extends along a direction perpendicular to the bottom wall 213. With continued reference to fig. 2, the second limiting structure 33 is located at the first supporting portion 3131, and the second limiting structure 33 is far away from the second supporting portion 3132 relative to the first limiting structure 32. When the bottle 20 is assembled to the weighing tray 313, the second positioning structure 23 and the second limiting structure 33 cooperate with each other, so that the bottle 20 is reliably assembled to the weighing tray 313.

Specifically, the second positioning structure 23 is a groove structure recessed relative to the outer wall surface of the bottle main body 21, and the second limiting structure 33 is convexly arranged on the surface of the weighing tray 313. When the bottle 20 is assembled on the weighing tray 313, the second positioning structure 23 and the second limiting structure 33 are engaged with each other in a concave-convex manner, so that the bottle 20 is reliably assembled on the weighing tray 313.

Of course, in other embodiments of the present application, the second positioning structure 23 may be protruding from the outer wall surface of the bottle main body 21, and the second limiting structure 33 may be a groove structure recessed relative to the surface of the weighing tray 313. Even though the second positioning structure 23 and the second limiting structure 33 are not limited to the way of matching the groove structure and the protrusion structure, the present invention is not limited thereto.

Referring to fig. 6, for the above example of the feeding mechanism 30 including at least two sets of limiting structure combinations, each set of limiting structure combinations includes a first limiting structure 32 and a second limiting structure 33, so that different material bottles 20 are assembled on the feeding body 31 through different limiting structure combinations. Wherein the different limit structure combinations have different second limit structures 33 such that each set of limit structure combinations is used for assembling a corresponding vial 20.

In other words, the different limit structure combinations of the present embodiment implement the fool-proof effect by designing the different second limit structures 33 so that each group of limit structure combinations is only used for assembling the material bottle 20 uniquely corresponding thereto. The structure of the second positioning structure 23 on each material bottle 20 is matched with the structure of the second limiting structure 33 of the corresponding limiting structure combination, so that the second positioning structure 23 can only be matched with the corresponding second limiting structure 33, each group of limiting structure combination is only used for assembling the material bottle 20 which is uniquely corresponding to the second positioning structure, and the fool-proof effect is realized. Since the auxiliary materials stored in different material bottles 20 are not identical, the material bottles 20 storing the corresponding auxiliary materials need to be correctly assembled at the corresponding positions on the feeding mechanism 30. In order to avoid a user from placing the material bottle 20 by mistake, the present embodiment realizes the fool-proof effect by designing the second limit structure 33 differently.

Specifically, the second limiting structure 33 is a columnar structure protruding from the surface of the feeding body 31, and the outer peripheral surface of the second limiting structure 33 has a foolproof plane 331. The second positioning structure 23 on the material bottle 20 is a groove structure, the inner wall of the second positioning structure 23 is provided with a plane corresponding to the fool-proof plane 331, and the plane is attached to the fool-proof plane 331 after the second positioning structure 23 and the second limiting structure 33 are mutually embedded. The second limiting structures 33 of different limiting structure combinations have foolproof planes 331 with different orientations. The second limiting structures 33 of each group of limiting structure combination can only be embedded into the second positioning structures 23 of the material bottles 20 uniquely corresponding to the second limiting structures, and the fool-proof effect is realized by distinguishing the second limiting structures 33 of different limiting structure combinations through fool-proof planes 331 with different orientations.

For example, since the cooking apparatus generally requires a higher amount of clean water than other auxiliary materials, the material bottle 20 for storing clean water has a larger volume than other material bottles 20, meaning that the material bottle 20 for storing clean water can realize foolproof through the difference between the material bottle 20 and other material bottles 20. As for the other bottles 20 except for the bottles 20 storing clean water, the respective corresponding second limiting structures 33 have foolproof planes 331 with different orientations, specifically, in the second straight direction, the foolproof planes 331 of the corresponding second limiting structures 33 of the adjacent bottles 20 are different by 45 ° as shown in fig. 6.

The second limiting structures 33 of the different limiting structure combinations have foolproof planes 331 with different orientations, and the second limiting structures 33 of the different limiting structure combinations have relatively consistent dimensions. Of course, in other embodiments of the present application, the second limiting structure 33 of different limiting structure combinations may be provided to have different shapes and/or sizes to achieve the fool-proof effect.

Further, the bottle body 21 further includes a bottle body and a bottom cap. The bottom cover is arranged at the bottom of the bottle body, and the bottom cover is in butt joint with the bottle body to form a storage cavity 211. Wherein the second positioning structure 23 is located at the bottom cover. Considering that the present embodiment achieves a foolproof design by means of different second limit structures 33, it means that the second positioning structures 23 of different vials 20 are also different from each other. In this embodiment, the main body 21 of the material bottle 20 is designed into a body and a bottom cover, and the difference of the second positioning structures 23 between different material bottles 20 only causes the difference of the structures of the bottom cover, and the body cannot be affected, which means that the bodies of different material bottles 20 in this embodiment have the same structure, at least the bodies of different material bottles 20 can be manufactured by sharing the same mold, so that the structural design of the material bottle 20 can be simplified and the production cost of the material bottle 20 can be reduced.

Referring to fig. 7, fig. 7 is a schematic structural diagram of a feeding device C shown in fig. 4.

In an embodiment, the first positioning structure 22 and the second positioning structure 23 are both located at the bottom of the bottle body 21, and the third positioning structure 24 is located away from the bottom of the bottle body 21, specifically the third positioning structure 24 is located at the top of the bottle body 21. Correspondingly, the first limiting structure 32 is located at a connection position between the first supporting portion 3131 and the second supporting portion 3132, the second limiting structure 33 is located at the first supporting portion 3131, and the third limiting structure 34 is located at an end portion of the second supporting portion 3132 away from the first supporting portion 3131. In this way, when the material bottle 20 is assembled in the feeding mechanism 30, the first positioning structure 22 can be correspondingly matched and connected with the first limiting structure 32, the second positioning structure 23 can be correspondingly matched and connected with the second limiting structure 33, and the third positioning structure 24 can be correspondingly matched and connected with the third limiting structure 34.

The vial 20 also includes an adapter assembly 25. The switching subassembly 25 is located bottle main part 21, and switching subassembly 25 intercommunication storage chamber 211, the auxiliary material in the storage chamber 211 exports to feeding mechanism 30 through switching subassembly 25. Wherein the adapter assembly 25 comprises a third positioning structure 24.

Specifically, the adapter assembly 25 includes an adapter 251. The adaptor 251 is far away from the bottom of the bottle body 21, specifically, the adaptor 251 is located at the top of the bottle body 21, and the adaptor 251 is the third positioning structure 24. At least a portion of the adaptor 251 protrudes to the outside relative to the bottle body 21 to be plugged with the feeding mechanism 30, so that the adaptor 251 cooperates with the first positioning structure 22 and the second positioning structure 23 to assemble the bottle body 21 to the feeding mechanism 30. The adapter assembly 25 also includes a suction tube 252. The suction pipe 252 is arranged in the storage cavity 211, and the suction pipe 252 is communicated with the adapter 251, and the suction pipe 252 extends towards the bottom of the storage cavity 211. The suction pipe 252 is configured to be able to suck the supplementary material in the storage cavity 211 to the adaptor 251 for output in response to the pressure difference between the adaptor 251 and the storage cavity 211, and then to the cooking apparatus through the feeding mechanism 30.

In the prior art, a check valve is usually arranged at the bottom of a material bottle, and auxiliary materials in the material bottle are output through the check valve at the bottom of the material bottle. Auxiliary materials in the material bottle are accumulated at the bottom of the material bottle under the action of gravity, the opening and closing process of the one-way valve has a certain degree of hysteresis, the auxiliary materials are easy to accumulate at the one-way valve, and the accumulated auxiliary materials at the one-way valve can influence the feeding precision of the auxiliary materials output next time by the one-way valve. In contrast, in the present embodiment, an adapter 251 is provided at the top of the bottle body 21 of the material bottle 20, and the auxiliary material is outputted through the adapter 251. In other words, in this embodiment, the top discharging mode is adopted, because the stacking degree of the auxiliary materials at the top of the material bottle 20 is lower, which means that the stacking auxiliary materials at the position of the adaptor 251 are less, the influence of the opening and closing process of the one-way valve at the bottom of the material bottle 20 on the feeding precision in the prior art is avoided, and the feeding precision is guaranteed. In addition, the adapter 251 of the material bottle 20 of the present embodiment can also cooperate with the feeding mechanism 30 to support and fix the material bottle 20, which is further beneficial for the material bottle 20 to be stably assembled in the feeding mechanism 30.

The end portion, far away from the first bearing portion 3131, of the second bearing portion 3132 of the feeding mechanism 30 is provided with a material drawing port 3134, and the material drawing port 3134 is used for being inserted into the material bottle 20, so that the material drawing port 3134 is matched with the first limiting structure 32 and the second limiting structure 33 to assemble the material bottle 20 to the feeding main body 31. The material extracting opening 3134 is the third limiting structure 34. When the material bottle 20 is assembled to the feeding mechanism 30, the portion of the adaptor 251 extending to the outside is inserted into the material extracting port 3134, and the adaptor 251 and the material extracting port 3134 cooperate to support and fix the material bottle 20, so as to stably assemble the material bottle 20 to the feeding mechanism 30.

The interior of the second support 3132 is provided with a transition chamber 3133 which communicates with the tube set chamber 3121. The feed pipe group 311 includes a suction pipe 3111 and a negative pressure pump 3112. One end of the suction pipe 3111 is communicated with the suction port 3134, and the other end extends into the pipe group cavity 3121 through the transition cavity 3133. A negative pressure pump 3112 is provided in the tube set chamber 3121, and is connected to the other end of the suction tube 3111. The negative pressure pump 3112 is configured to create a negative pressure environment inside the suction pipe 3111, so that a pressure difference is formed between the adapter 251 and the storage cavity 211 of the material bottle 20, and then the auxiliary materials in the material bottle 20 sequentially pass through the suction pipe 252, the adapter 251, the suction port 3134 and the suction pipe 3111 to be output to the negative pressure pump 3112 in response to the pressure difference, and then output to the cooking apparatus via the negative pressure pump 3112.

Since the adaptor 251 is located at the top of the material bottle 20 and the negative pressure pump 3112 is located in the tube cavity 3121 below the weighing tray 313, which means that a long distance exists between the adaptor 251 and the negative pressure pump 3112, the impact of vibration generated by the operation of the negative pressure pump 3112 on the discharging process of the adaptor 251 is small, which is further beneficial to ensuring the discharging precision. The check valve is arranged at the bottom of the material bottle, the distance between the check valve and the negative pressure pump is relatively short, and vibration generated by the operation of the negative pressure pump easily influences the discharging process of the check valve, so that the feeding precision is reduced.

Further, the suction tube 252 and/or the suction tube 3111 are made of flexible materials, for example, the suction tube 252 and the suction tube 3111 are made of flexible materials such as silica gel. In this way, the suction pipe 252 and the pumping pipe 3111 can buffer the vibration generated by the operation of the negative pressure pump 3112, so as to further reduce the influence of the vibration generated by the operation of the negative pressure pump 3112 on the discharging process of the adapter 251, which is further beneficial to ensuring the discharging precision.

Alternatively, the negative pressure pump 3112 may be a peristaltic pump or the like, which is not limited herein.

In one embodiment, the adapter 251 is provided with a discharge cavity 2511 having an outlet 2512 at one end, the suction tube 252 is connected to the discharge cavity 2511, and the auxiliary material from the suction tube 252 is output through the outlet 2512. The adapter assembly 25 further includes a seal 253 and an elastic member 254. A seal 253 is provided in the discharge chamber 2511. An elastic member 254 is provided in the discharge chamber 2511, and the elastic member 254 is connected to the sealing member 253, and the elastic member 254 serves to cause the sealing member 253 to have a tendency to move toward the outlet 2512. Correspondingly, a push rod 3135 is arranged in the material extracting opening 3134 of the feeding mechanism 30, and the push rod 3135 is used for enabling the material extracting opening 3134 to be communicated with the inner space of the material bottle 20 when the material extracting opening 3134 is connected with the material bottle 20 in an inserting mode.

Specifically, when the material bottle 20 is assembled to the feeding mechanism 30, the adaptor 251 on the material bottle 20 is inserted into the material extracting port 3134, the ejector rod 3135 abuts against the sealing member 253 and pushes the sealing member 253 away from the outlet 2512, so that the discharging cavity 2511 inside the adaptor 251 is communicated with the material extracting port 3134, and the material extracting port 3134 is further communicated to the material storage cavity 211, i.e. the material extracting port 3134 is communicated with the internal space of the material bottle 20. The negative pressure pump 3112 is then operated to create a negative pressure environment inside the suction pipe 3111, so that the auxiliary material in the storage chamber 211 is output. When the material bottle 20 is removed from the feeding mechanism 30, the adaptor 251 is separated from the material outlet 3134, and the sealing member 253 moves towards the outlet 2512 under the action of self gravity and elastic restoring force provided by the elastic member 254 to reset, so as to reseal the outlet 2512, avoid the leakage of the auxiliary materials in the material bottle 20 from the outlet 2512, and reduce the residual auxiliary materials.

Optionally, the elastic member 254 is located on a side of the seal 253 facing away from the outlet 2512. When the ram 3135 abuts the seal 253 and pushes the seal 253 away from the outlet 2512, the seal 253 compresses the resilient member 254, causing the resilient member 254 to elastically deform. When the adapter 251 is disengaged from the tap 3134, the elastic member 254 expands, and the sealing member 253 is driven toward the outlet 2512 to reseal the outlet 2512. The elastic member 254 may be a spring or the like. Of course, in other embodiments of the present application, when the ejector rod 3135 abuts against the sealing member 253 and pushes the sealing member 253 away from the outlet 2512, the sealing member 253 may also stretch the elastic member 254, and only the setting position of the elastic member 254 needs to be correspondingly adjusted, which is not limited herein.

Please continue to refer to fig. 3. In one embodiment, the bottle body 21 further includes a body portion 214 and an extension 215. The extension 215 extends outwardly from one side of the body portion 214, and the extension 215 is near the top of the body portion 214. The storage cavity 211 is mainly located in the main body 214, and the main body 214 is provided with the first positioning structure 22 and the second positioning structure 23. The third positioning structure 24 is located in the extending portion 215, specifically, the adapter 251 is disposed in a space inside the extending portion 215, and the adapter 251 extends from the extending portion 215 to the outside for plugging with the feeding mechanism 30.

The technical scheme provided by the embodiment of the application is explained below in combination with a specific application scene.

Application scenario one:

the material bottle 20 comprises a bottle main body 21, and a material storage cavity 211 for storing auxiliary materials is formed inside the bottle main body 21. The material bottle 20 further comprises a first positioning structure 22, and the first positioning structure 22 is arranged on the bottle main body 21. The vial 20 further includes a second positioning structure 23, the second positioning structure 23 being disposed on the vial body 21. The vial 20 further includes a third positioning structure 24, the third positioning structure 24 being disposed on the vial body 21. Wherein, the first positioning structure 22, the second positioning structure 23 and the third positioning structure 24 are used for matching the bottle main body 21 assembled on the feeding mechanism 30, and the auxiliary materials in the storage cavity 211 are output to the cooking device through the feeding mechanism 30.

Through the above manner, the material bottle 20 and the feeding mechanism 30 form three-point support through the first positioning structure 22, the second positioning structure 23 and the third positioning structure 24, so that the material bottle 20 can be stably assembled on the feeding mechanism 30, and the material bottle 20 is prevented from shaking on the feeding mechanism 30 as much as possible.

And (2) an application scene II:

the feeding mechanism 30 includes a feeding body 31, and the feeding body 31 is provided with a feeding pipe group 311. The feeding mechanism 30 further includes a first limiting structure 32, where the first limiting structure 32 is disposed on the feeding body 31. The feeding mechanism 30 further includes a second limiting structure 33, where the second limiting structure 33 is disposed on the feeding main body 31. The feeding mechanism 30 further includes a third limiting structure 34, where the third limiting structure 34 is disposed on the feeding body 31. The first limiting structure 32, the second limiting structure 33 and the third limiting structure 34 are used for matching the material bottle 20 assembled on the feeding main body 31, and the auxiliary materials in the material bottle 20 are output to the cooking device through the feeding pipe group 311.

Through the above mode, the material bottle 20 and the feeding mechanism 30 form three-point support through the first limiting structure 32, the second limiting structure 33 and the third limiting structure 34, so that the material bottle 20 can be stably assembled on the feeding mechanism 30, and the material bottle 20 is prevented from shaking on the feeding mechanism 30 as much as possible.

And (3) an application scene III:

the feeding device 10 is used for providing auxiliary material to the cooking apparatus. Specifically, the feeding device 10 includes a bottle 20 and a feeding mechanism 30. The material bottle 20 comprises a bottle main body 21, and a material storage cavity 211 for storing auxiliary materials is formed inside the bottle main body 21. The material bottle 20 further comprises a first positioning structure 22, and the first positioning structure 22 is arranged on the bottle main body 21. The vial 20 further includes a second positioning structure 23, the second positioning structure 23 being disposed on the vial body 21. The vial 20 further includes a third positioning structure 24, the third positioning structure 24 being disposed on the vial body 21. The feeding mechanism 30 includes a feeding body 31, and the feeding body 31 is provided with a feeding pipe group 311. The feeding mechanism 30 further includes a first limiting structure 32, where the first limiting structure 32 is disposed on the feeding body 31. The feeding mechanism 30 further includes a second limiting structure 33, where the second limiting structure 33 is disposed on the feeding main body 31. The feeding mechanism 30 further includes a third limiting structure 34, where the third limiting structure 34 is disposed on the feeding body 31.

Through the above manner, the first positioning structure 22 is matched with the first limiting structure 32, the second positioning structure 23 is matched with the second limiting structure 33, and the third positioning structure 24 is matched with the third limiting structure 34, so that three-point support is formed between the material bottle 20 and the feeding mechanism 30, the material bottle 20 can be stably assembled on the feeding mechanism 30, and shaking of the material bottle 20 on the feeding mechanism 30 is avoided as much as possible.

Specifically, at least two vials 20 are individually assembled to the feed mechanism 30. The first positioning structure 22 on the material bottle 20 is aligned to the first limiting structure 32 at the corner position formed by the first bearing portion 3131 and the second bearing portion 3132 on the feeding mechanism 30, so that the first positioning structure 22 and the first limiting structure 32 are in concave-convex jogged with each other. And, the second positioning structure 23 on the material bottle 20 is aligned to the second limiting structure 33 on the first bearing portion 3131 of the feeding mechanism 30, so that the second positioning structure 23 and the second limiting structure 33 are in concave-convex jogged with each other. In addition, the adaptor 251 on the material bottle 20 is inserted into the material extracting opening 3134 at the end of the second bearing portion 3132 on the feeding mechanism 30, so as to play a role in supporting and fixing.

When the material bottle 20 is assembled to the feeding mechanism 30, the adaptor 251 on the material bottle 20 is inserted into the material extracting port 3134, the ejector rod 3135 in the material extracting port 3134 abuts against the sealing member 253 in the adaptor 251, and the sealing member 253 is lifted away from the outlet 2512, so that the discharging cavity 2511 inside the adaptor 251 is communicated with the material extracting port 3134. The negative pressure pump 3112 is then operated to create a negative pressure environment inside the suction pipe 3111, and suction the auxiliary material in the storage chamber 211 to the adaptor 251 through the suction pipe 252 for output. When the material bottle 20 is removed from the feeding mechanism 30, the adaptor 251 is separated from the material outlet 3134, and the sealing member 253 moves towards the outlet 2512 under the action of self gravity and elastic restoring force provided by the elastic member 254 to reset, so as to reseal the outlet 2512, avoid the leakage of the auxiliary materials in the material bottle 20 from the outlet 2512, and reduce the residual auxiliary materials.

And application scene IV:

the cooking system comprises a cooking device and a feeding device 10, the feeding device 10 being connected to the cooking device for providing auxiliary material to the cooking device. Specifically, the feeding device 10 includes a bottle 20 and a feeding mechanism 30. The material bottle 20 comprises a bottle main body 21, and a material storage cavity 211 for storing auxiliary materials is formed inside the bottle main body 21. The material bottle 20 further comprises a first positioning structure 22, and the first positioning structure 22 is arranged on the bottle main body 21. The vial 20 further includes a second positioning structure 23, the second positioning structure 23 being disposed on the vial body 21. The vial 20 further includes a third positioning structure 24, the third positioning structure 24 being disposed on the vial body 21. The feeding mechanism 30 includes a feeding body 31, and the feeding body 31 is provided with a feeding pipe group 311. The feeding mechanism 30 further includes a first limiting structure 32, where the first limiting structure 32 is disposed on the feeding body 31. The feeding mechanism 30 further includes a second limiting structure 33, where the second limiting structure 33 is disposed on the feeding main body 31. The feeding mechanism 30 further includes a third limiting structure 34, where the third limiting structure 34 is disposed on the feeding body 31.

Through the above manner, the first positioning structure 22 is matched with the first limiting structure 32, the second positioning structure 23 is matched with the second limiting structure 33, and the third positioning structure 24 is matched with the third limiting structure 34, so that three-point support is formed between the material bottle 20 and the feeding mechanism 30, the material bottle 20 can be stably assembled on the feeding mechanism 30, and shaking of the material bottle 20 on the feeding mechanism 30 is avoided as much as possible.

Specifically, at least two vials 20 are individually assembled to the feed mechanism 30. The first positioning structure 22 on the material bottle 20 is aligned to the first limiting structure 32 at the corner position formed by the first bearing portion 3131 and the second bearing portion 3132 on the feeding mechanism 30, so that the first positioning structure 22 and the first limiting structure 32 are in concave-convex jogged with each other. And, the second positioning structure 23 on the material bottle 20 is aligned to the second limiting structure 33 on the first bearing portion 3131 of the feeding mechanism 30, so that the second positioning structure 23 and the second limiting structure 33 are in concave-convex jogged with each other. In addition, the adaptor 251 on the material bottle 20 is inserted into the material extracting opening 3134 at the end of the second bearing portion 3132 on the feeding mechanism 30, so as to play a role in supporting and fixing.

When the material bottle 20 is assembled to the feeding mechanism 30, the adaptor 251 on the material bottle 20 is inserted into the material extracting port 3134, the ejector rod 3135 in the material extracting port 3134 abuts against the sealing member 253 in the adaptor 251, and the sealing member 253 is lifted away from the outlet 2512, so that the discharging cavity 2511 inside the adaptor 251 is communicated with the material extracting port 3134. The negative pressure pump 3112 is then operated to create a negative pressure environment inside the suction pipe 3111, and suction the auxiliary material in the storage chamber 211 to the adaptor 251 through the suction pipe 252 for output. When the material bottle 20 is removed from the feeding mechanism 30, the adaptor 251 is separated from the material outlet 3134, and the sealing member 253 moves towards the outlet 2512 under the action of self gravity and elastic restoring force provided by the elastic member 254 to reset, so as to reseal the outlet 2512, avoid the leakage of the auxiliary materials in the material bottle 20 from the outlet 2512, and reduce the residual auxiliary materials.

The above describes the feeding device, the feeding bottle, the feeding mechanism and the cooking system, and specific examples are used herein to illustrate the principles and embodiments of the present application, and the above examples are only used to help understand the method and core ideas of the present application; meanwhile, as those skilled in the art will have modifications in the specific embodiments and application scope in accordance with the ideas of the present application, the present description should not be construed as limiting the present application in view of the above.

Claims (24)

1. A bottle, comprising:

the bottle body is internally provided with a storage cavity for storing auxiliary materials;

a first positioning structure provided to the bottle body; and

the second positioning structure is arranged on the bottle main body and is spaced from the first positioning structure;

the first positioning structure and the second positioning structure are used for being matched with the bottle main body to be assembled on the feeding mechanism, and auxiliary materials in the storage cavity are output to the cooking equipment through the feeding mechanism.

2. The bottle according to claim 1, wherein,

the material bottle further comprises:

the third positioning structure is arranged on the bottle main body and is respectively arranged at intervals with the first positioning structure and the second positioning structure;

Wherein, first location structure the second location structure and the third location structure are used for the cooperation with the bottle main part is assembled in feeding mechanism.

3. The bottle according to claim 2, wherein,

the first positioning structure, the second positioning structure and the third positioning structure are sequentially distributed at intervals along the first straight line direction.

4. A bottle as claimed in any one of claims 1 to 3,

the outer wall surface of the bottle main body is provided with a side wall and a bottom wall which are connected; wherein,

the first positioning structure is close to the connecting position of the side wall and the bottom wall, and extends along the direction perpendicular to the side wall and the direction perpendicular to the bottom wall respectively;

the second positioning structure is positioned on the bottom wall and extends along the direction perpendicular to the bottom wall.

5. The bottle according to claim 4, wherein,

the first positioning structure and the second positioning structure are both groove structures.

6. A bottle according to claim 2 or 3, wherein,

the first positioning structure and the second positioning structure are both positioned at the bottom of the bottle main body;

The third positioning structure is arranged far away from the bottom of the bottle main body;

wherein, the material bottle still includes:

the switching assembly is arranged on the bottle main body and communicated with the storage cavity, and auxiliary materials in the storage cavity are output to the feeding mechanism through the switching assembly, wherein the switching assembly comprises the third positioning structure.

7. The bottle according to claim 6, wherein,

the adapter assembly includes:

an adapter, remote from the bottom of the bottle body; wherein at least part of the adapter extends to the outside relative to the bottle main body so as to be spliced with the feeding mechanism, so that the adapter is matched with the first positioning structure and the second positioning structure to assemble the bottle main body to the feeding mechanism; and

the material sucking pipe is arranged in the material storage cavity and communicated with the adapter, and extends towards the bottom of the material storage cavity; wherein the suction pipe is configured to be capable of sucking auxiliary materials in the storage cavity to the adapter for output in response to the action of a pressure difference between the adapter and the storage cavity.

8. The bottle according to claim 7, wherein,

a discharging cavity with an outlet at one end is arranged in the adapter, the suction pipe is communicated with the discharging cavity, and auxiliary materials from the suction pipe are output through the outlet;

The adapter assembly further comprises:

the sealing piece is arranged in the discharging cavity;

and the elastic piece is arranged in the discharging cavity and connected with the sealing piece, and the elastic piece is used for enabling the sealing piece to have a trend of moving towards the outlet.

9. The bottle according to claim 7, wherein,

the material sucking pipe is made of flexible materials.

10. The bottle according to claim 7, wherein,

the bottle body further comprises:

a main body part provided with the first positioning structure and the second positioning structure;

an extension portion extending outward from one side of the main body portion and approaching a top of the main body portion; wherein the adapter extends from the extension portion to the outside.

11. A bottle as claimed in any one of claims 1 to 3,

the bottle body further comprises:

a bottle body;

the bottom cover is arranged at the bottom of the bottle body and is in butt joint with the bottle body to form the storage cavity; wherein, the second positioning structure is located at the bottom cover.

12. A feeding mechanism, characterized by comprising:

a feeding main body provided with a feeding pipe group;

the first limiting structure is arranged on the feeding main body; and

the second limiting structure is arranged on the feeding main body and is spaced from the first limiting structure;

The first limiting structure and the second limiting structure are used for matching the feeding main body with the feeding bottle, and auxiliary materials in the feeding bottle are output to the cooking equipment through the feeding pipe set.

13. The feeding mechanism as recited in claim 12, wherein,

the feeding mechanism further comprises:

the third limiting structure is arranged on the feeding main body and is respectively arranged at intervals with the first limiting structure and the second limiting structure;

the first limiting structure, the second limiting structure and the third limiting structure are used for matching the feeding main body with the feeding bottle.

14. The feeding mechanism as recited in claim 13, wherein,

the feeding mechanism comprises at least two groups of limit structure combinations, and each group of limit structure combinations comprises a first limit structure, a second limit structure and a third limit structure, so that different material bottles are assembled on the feeding main body through different limit structure combinations; wherein,

the feeding mechanism is defined with a first linear direction and a second linear direction which are perpendicular to each other;

the first limit structure, the second limit structure and the third limit structure which belong to the same limit structure combination are sequentially distributed at intervals along the first linear direction, and each group of limit structure combination is sequentially distributed at intervals along the second linear direction.

15. A feeding mechanism as claimed in claim 13 or 14, wherein,

the feed body includes:

a supporting seat, wherein a pipe group cavity for accommodating the feeding pipe group is formed in the supporting seat; and

a weighing tray comprising:

the first bearing part is arranged on the supporting seat; and

the second bearing part is arranged on the first bearing part and extends along the direction away from the supporting seat relative to the first bearing part;

the first limiting structure is close to the connecting position of the first bearing portion and the second bearing portion, the second limiting structure is located on the first bearing portion, and the third limiting structure is located on the second bearing portion.

16. The feeding mechanism as recited in claim 15, wherein,

the first limiting structure is positioned at the connecting position of the first bearing part and the second bearing part;

the second limiting structure is far away from the second bearing part relative to the first limiting structure;

the third limiting structure is located at the end portion, far away from the first bearing portion, of the second bearing portion.

17. The feeding mechanism as recited in claim 15, wherein,

a transition cavity communicated with the tube group cavity is arranged in the second bearing part; and is also provided with

The end part of the second bearing part, which is far away from the first bearing part, is provided with a material extracting opening, and the material extracting opening is used for being spliced with a material bottle, so that the material extracting opening, the first limiting structure and the second limiting structure are matched to match the material bottle with the material feeding main body;

the feed pipe group includes:

one end of the pumping pipe is communicated with the pumping port, and the other end of the pumping pipe extends into the pipe group cavity through the transition cavity; and

the negative pressure pump is arranged in the pipe group cavity and is connected with the other end; the negative pressure pump is used for creating a negative pressure environment in the material pumping pipe, so that auxiliary materials in the material bottle are output through the material pumping port and the material pumping pipe.

18. The feeding mechanism as recited in claim 17, wherein,

the material sucking port is internally provided with a push rod, and the push rod is used for enabling the material sucking port to be communicated with the inner space of the material bottle when the material sucking port is connected with the material bottle in an inserting mode.

19. The feeding mechanism as recited in claim 17, wherein,

the pumping pipe is made of flexible materials.

20. The feeding mechanism as recited in claim 15, wherein,

the feeding mechanism further comprises:

the cover body is covered on the supporting seat to be matched with the supporting seat to form a cavity for accommodating the weighing tray and the material bottle.

21. The feeding mechanism as recited in any one of claims 12 to 14, wherein,

the feeding mechanism comprises at least two groups of limit structure combinations, and each group of limit structure combinations comprises a first limit structure and a second limit structure, so that different material bottles are assembled on the feeding main body through different limit structure combinations; wherein,

different limit structure combinations have different second limit structures, so that each group of limit structure combinations is used for assembling corresponding material bottles.

22. The feeding mechanism as recited in claim 21, wherein,

the second limiting structure is a columnar structure protruding from the surface of the feeding main body, and the outer peripheral surface of the second limiting structure is provided with a foolproof plane; wherein,

the second limiting structures of different limiting structure combinations have foolproof planes with different orientations.

23. The feeding device is characterized by comprising a material bottle and a feeding mechanism;

the material bottle includes:

the bottle body is internally provided with a storage cavity for storing auxiliary materials;

a first positioning structure provided to the bottle body; and

the second positioning structure is arranged on the bottle main body and is spaced from the first positioning structure; and is also provided with

The feeding mechanism includes:

a feeding main body provided with a feeding pipe group;

the first limiting structure is arranged on the feeding main body; and

the second limiting structure is arranged on the feeding main body and is spaced from the first limiting structure;

wherein, first location structure cooperation first limit structure, just second location structure cooperation second limit structure, in order will the bottle main part assemble in the feed main part, auxiliary material in the storage cavity is passed through the output of feed group to cooking equipment.

24. A cooking system comprising a cooking device and a feeding device, wherein the feeding device comprises a material bottle and a feeding mechanism;

the material bottle includes:

the bottle body is internally provided with a storage cavity for storing auxiliary materials;

a first positioning structure provided to the bottle body; and

the second positioning structure is arranged on the bottle main body and is spaced from the first positioning structure; and is also provided with

The feeding mechanism includes:

a feeding main body provided with a feeding pipe group connected with the cooking equipment;

the first limiting structure is arranged on the feeding main body; and

the second limiting structure is arranged on the feeding main body and is spaced from the first limiting structure;

Wherein, first location structure cooperation first limit structure, just second location structure cooperation second limit structure, in order will the bottle main part assemble in the feed main part, auxiliary material in the storage cavity is passed through the feed pipe group output extremely cooking equipment.