CN116798163A - Automatic quantitative dish dispenser - Google Patents

Abstract

The invention provides an automatic quantitative vegetable sorting machine, and relates to the field of vegetable sorting machines. The automatic quantitative dish dispenser comprises a dish storage component, a dish dispensing container and a quantitative dish dispensing component. The dish storage component is provided with a dish storage cavity, the dish distribution container is provided with a dish distribution cavity, a dish inlet and a dish outlet, the dish inlet and the dish outlet are communicated with the lower part of the dish storage cavity, and the dish outlet is positioned below the dish inlet. The quantitative dish-dividing assembly comprises a first quantitative dish-dividing part, a second quantitative dish-dividing part and a quantitative dish-dividing driving part, wherein the first quantitative dish-dividing part and the second quantitative dish-dividing part are vertically spaced and are connected with the dish-dividing container, and the quantitative dish-dividing driving part is in transmission connection with the first quantitative dish-dividing part and the second quantitative dish-dividing part and is used for enabling the first quantitative dish-dividing part or the second quantitative dish-dividing part to separate the dish-dividing cavity. The automatic quantitative dish distribution device can realize automatic quantitative dish distribution, is beneficial to reducing the manpower input and improves the dish distribution efficiency.

Description

Automatic quantitative dish dispenser

Technical Field

The invention relates to the field of automatic quantitative vegetable sorting machines, in particular to an automatic quantitative vegetable sorting machine.

Background

Along with the development of intellectualization, the degree of intellectualization and automation of kitchen equipment is higher and higher, but manual meal distribution is adopted in schools, armies, enterprises and public service canteens, large-scale catering chains and the like, so that a large amount of manpower and time are required, and the efficiency is not high.

Disclosure of Invention

The embodiment of the invention discloses an automatic quantitative vegetable sorting machine, which can realize automatic quantitative vegetable sorting, is beneficial to reducing manpower input and improves vegetable sorting efficiency.

The embodiment of the invention discloses an automatic quantitative vegetable sorting machine, which comprises:

the dish storage assembly is provided with a dish storage cavity;

the dish distribution container is provided with a dish distribution cavity, a dish inlet and a dish outlet, wherein the dish inlet and the dish outlet are communicated with the dish distribution cavity, the dish inlet is arranged corresponding to the dish storage cavity and is communicated with the dish storage cavity, and the dish outlet is arranged corresponding to the dish inlet, so that dishes in the dish storage cavity can enter the dish distribution cavity from the dish inlet, and dishes in the dish distribution cavity can be discharged through the dish outlet;

the quantitative dish distribution assembly comprises a first quantitative dish distribution part, a second quantitative dish distribution part and a quantitative dish distribution driving part, wherein the first quantitative dish distribution part and the second quantitative dish distribution part are mutually spaced and are connected with the dish distribution container, the quantitative dish distribution driving part is in transmission connection with the first quantitative dish distribution part and the second quantitative dish distribution part and is used for enabling the first quantitative dish distribution part or the second quantitative dish distribution part to separate the dish distribution cavity, the first quantitative dish distribution part is used for separating dishes above the first quantitative dish distribution part when the first quantitative dish distribution part separates the dish distribution cavity, and the second quantitative dish distribution part is used for separating dishes above the second quantitative dish distribution part when the second quantitative dish distribution part separates the dish distribution cavity.

As an alternative embodiment, the serving container includes:

the container body is provided with the dish separating cavity, the dish inlet and the dish outlet, a dish separating buffer opening is further formed in the side face of the container body, and the first quantitative dish separating piece is opposite to the dish separating buffer opening;

the dish separating buffer piece is arranged at the dish separating buffer opening.

As an alternative embodiment, the dish-sorting container further comprises an elastic reset member, and the elastic reset member is connected with the dish-sorting buffer member and the container main body, and is used for resetting the dish-sorting buffer member.

As an alternative embodiment, the container main body is further provided with a first mounting groove, the first quantitative dish-dividing piece is slidably connected with the first mounting groove, and the first quantitative dish-dividing piece is sealed with the first mounting groove; and/or the number of the groups of groups,

the container main body is also provided with a second mounting groove, the second quantitative dish-dividing piece is in sliding connection with the second mounting groove, and the second quantitative dish-dividing piece is sealed with the second mounting groove.

As an alternative embodiment, the first mounting groove and the second mounting groove are respectively located at opposite sides of the container body.

As an optional implementation manner, the quantitative dish-dividing driving piece is used for enabling the first quantitative dish-dividing piece to be located outside the dish-dividing cavity and the second quantitative dish-dividing piece to be located in the dish-dividing cavity, so that dishes enter the dish-dividing cavity from the dish inlet and are blocked by the second quantitative dish-dividing piece; the quantitative dish-dividing driving piece is further used for enabling the second quantitative dish-dividing piece to be located outside the dish-dividing cavity and the first quantitative dish-dividing piece to be located in the dish-dividing cavity, so that dishes leave the dish-dividing cavity from the dish outlet and are blocked by the first quantitative dish-dividing piece.

As an optional implementation manner, the quantitative dish distribution assembly further comprises a mounting piece, the first quantitative dish distribution piece and the second quantitative dish distribution piece are both connected with the mounting piece, and the quantitative dish distribution driving piece is in transmission connection with the mounting piece.

As an optional implementation manner, the mounting piece includes a first mounting portion, a second mounting portion and a connecting portion, the first mounting portion and the second mounting portion are respectively disposed at two ends of the connecting portion, the first mounting portion is higher than the second mounting portion, the first quantitative dish-dividing piece and the second quantitative dish-dividing piece are respectively connected with the first mounting portion and the second mounting portion, and the first quantitative dish-dividing piece and the second quantitative dish-dividing piece are vertically opposite, and the quantitative dish-dividing driving piece is connected with the first mounting portion or the second mounting portion.

As an optional implementation manner, the automatic quantitative dish dispenser further comprises a sliding rail assembly, wherein the sliding rail assembly comprises a first sliding rail and a second sliding rail which are in sliding fit with each other, and the first sliding rail is arranged on the connecting portion.

As an optional implementation manner, the automatic quantitative dish dispenser further comprises a turnover assembly, wherein the turnover assembly is installed in the dish storage cavity and is used for enabling dishes in the dish storage cavity to enter the dish inlet and enter the dish distribution cavity.

As an optional implementation manner, the automatic quantitative dish dispenser further comprises a sensor group, wherein the sensor group is electrically connected with the quantitative dish dispensing driving component, so that the quantitative dish dispensing driving component is opened or closed according to detection information of the sensor group.

Compared with the prior art, the invention has the beneficial effects that:

the embodiment of the invention provides an automatic quantitative dish dispenser which comprises a dish storage component, a dish dispensing container and a quantitative dish dispensing component. The dish storage assembly is provided with a dish storage cavity for storing dishes, the dish distribution container is provided with a dish distribution cavity, a dish inlet and a dish outlet, the dish inlet and the dish storage cavity are communicated, dishes in the dish storage cavity are guided to the dish distribution cavity, the dish distribution cavity is used for providing space for quantitatively distributing dishes, and the dish outlet is used for discharging dishes. The quantitative dish-dividing assembly comprises a first quantitative dish-dividing part, a second quantitative dish-dividing part and a quantitative dish-dividing driving part, wherein the first quantitative dish-dividing part and the second quantitative dish-dividing part are arranged in the dish-dividing cavity at intervals up and down, the upper and lower distances between the first quantitative dish-dividing part and the second quantitative dish-dividing part are fixed, and quantitative dish-dividing of dishes can be realized. The first quantitative dish separating piece can separate dishes above the dish separating piece, and the dishes are positioned at the position of the dish separating cavity close to the dish inlet; the second quantitative serving piece can block dishes above the second quantitative serving piece. The quantitative dish-dividing driving piece enables one of the first quantitative dish-dividing piece and the second quantitative dish-dividing piece to play a role in blocking the dish-dividing cavity. When the automatic quantitative dish sorting machine works, dishes in the dish storage cavity enter the dish sorting cavity through the dish inlet, at the moment, the second quantitative dish sorting piece obstructs the dish sorting cavity, the first quantitative dish sorting piece does not obstruct the dish sorting cavity, and the dishes enter the dish sorting cavity from the dish inlet until falling above the second quantitative dish sorting piece. The dishes continue to enter the dish separating cavity from the dish inlet until the dish separating cavity is filled. At this time, under the effect of ration dish drive piece, first ration divides dish piece separation to divide the dish chamber, second ration divides the dish piece not to separate the dish chamber, and first ration divides the dish piece to separate the dish separation of dish chamber in first ration dish piece top, and second ration divides the dish piece not to separate the dish, and first ration divides dish piece and second ration to divide dishes between the dish piece to go out dishes along the dish export to realize the automatic ration of dish and divide dishes, promote and divide dish efficiency.

Drawings

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

FIG. 1 is a schematic diagram of an automatic quantitative dish dispenser according to an embodiment of the present invention;

FIG. 2 is a schematic cross-sectional view of the automatic quantitative vegetable dispenser of FIG. 1;

FIG. 3 is a schematic view of the serving container of FIG. 1;

FIG. 4 is a schematic view of the positions of a first quantitative serving member and a second quantitative serving member during a serving process;

FIG. 5 is a schematic view of the positions of a first quantitative serving member and a second quantitative serving member during quantitative serving;

FIG. 6 is a schematic view of the serving container of FIG. 3 from another perspective;

FIG. 7 is a schematic view of the automatic quantitative vegetable divider of FIG. 1 in another view;

FIG. 8 is a schematic cross-sectional view of the automatic quantitative vegetable dispenser of FIG. 1;

FIG. 9 is a schematic view of the mounting member of FIG. 2;

FIG. 10 is a schematic view of the mount of FIG. 9 from another perspective;

fig. 11 is a schematic diagram of connection relation between a controller and a sensor group of the automatic quantitative dish dispenser according to the embodiment of the invention.

Icon: 100. automatic quantitative vegetable separating machine; 101. a main body frame of the vegetable sorting machine; 110. a dish storage component; 111. a vegetable storage cavity; 120. a vegetable separating container; 121. a vegetable separating cavity; 122. a dish inlet; 123. a dish outlet; 124. a container body; 1241. a first mounting groove; 1242. a second mounting groove; 125. a dish separating buffer piece; 130. a quantitative dish distribution component; 131. a first quantitative dish separating piece; 132. a second quantitative dish separating piece; 133. quantitative dish-dividing driving piece; 134. a mounting member; 1341. a first mounting portion; 1342. a second mounting portion; 1343. a connection part; 140. a slide rail assembly; 141. a first slide rail; 142. a second slide rail; 150. a flip assembly; 152. turning over the blade.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the present invention, the terms "upper", "lower", "left", "right", "front", "rear", "top", "bottom", "inner", "outer", "middle", "vertical", "horizontal", "lateral", "longitudinal" and the like indicate an azimuth or a positional relationship based on that shown in the drawings. These terms are only used to better describe the present invention and its embodiments and are not intended to limit the scope of the indicated devices, elements or components to the particular orientations or to configure and operate in the particular orientations.

Also, some of the terms described above may be used to indicate other meanings in addition to orientation or positional relationships, for example, the term "upper" may also be used to indicate some sort of attachment or connection in some cases. The specific meaning of these terms in the present invention will be understood by those of ordinary skill in the art according to the specific circumstances.

Furthermore, the terms "mounted," "configured," "provided," "connected," and "connected" are to be construed broadly. For example, it may be a fixed connection, a removable connection, or a unitary construction; may be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements, or components. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

Furthermore, the terms "first," "second," and the like, are used primarily to distinguish between different devices, elements, or components (the particular species and configurations may be the same or different), and are not used to indicate or imply the relative importance and number of devices, elements, or components indicated. Unless otherwise indicated, the meaning of "a plurality" is two or more.

The technical scheme of the invention will be further described with reference to the examples and the accompanying drawings.

Referring to fig. 1 and 2, an automatic quantitative dish dispenser 100 according to an embodiment of the invention is shown. The automatic quantitative dish distribution machine 100 can realize automatic quantitative dish distribution, is beneficial to reducing manpower input and improving dish distribution efficiency.

In an embodiment of the present invention, the automatic quantitative dish dispenser 100 includes a dish storage assembly 110, a dish dispensing container 120, and a quantitative dish dispensing assembly 130. The dish storage assembly 110 has a dish storage cavity 111, referring to fig. 3, the dish distribution container 120 has a dish distribution cavity 121, a dish inlet 122 and a dish outlet 123, which are communicated with the dish distribution cavity 121, wherein the dish inlet 122 is communicated with the dish storage cavity 111, and the dish outlet 123 is positioned at the dish inlet 122, so that dishes in the dish storage cavity 111 can enter the dish distribution cavity 121 from the dish inlet 122, and dishes in the dish distribution cavity 121 can be discharged through the dish outlet 123 (i.e. leave the dish distribution cavity 121). As shown in fig. 2, the quantitative dish-dividing assembly 130 includes a first quantitative dish-dividing member 131, a second quantitative dish-dividing member 132 and a quantitative dish-dividing driving member 133, where the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 are spaced apart from each other and are connected to the dish-dividing container 120, the quantitative dish-dividing driving member 133 is in transmission connection with the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132, for making the first quantitative dish-dividing member 131 or the second quantitative dish-dividing member 132 block the dish-dividing cavity 121, the first quantitative dish-dividing member 131 is used for blocking dishes above the first quantitative dish-dividing member 131 when the first quantitative dish-dividing member 131 blocks the dish-dividing cavity 121, and the second quantitative dish-dividing member 132 is used for blocking dishes above the second quantitative dish-dividing member 132 when the second quantitative dish-dividing member 132 blocks the dish-dividing cavity 121.

Of course, as shown in fig. 1, the automatic quantitative dish dispenser 100 may further include a dish dispenser main body frame 101, and the dish dispenser main body frame 101 is used for mounting the dish storage assembly 110, the dish dispensing container 120, the quantitative dish dispensing assembly 130, and the like.

It should be noted that in an embodiment of the present invention, the dish storage assembly 110 is used to store dishes, i.e. dishes are stored in the dish storage cavity 111. The dish separating container 120 is used for providing a space for automatic quantitative dish separating, the dish separating container 120 is provided with a dish separating cavity 121, a dish inlet 122 and a dish outlet 123, wherein the dish inlet 122 is communicated with the dish storing cavity 111, so that dishes in the dish storing cavity 111 are guided to the dish separating cavity 121, and the dish outlet 123 is used for discharging dishes. The dish distribution cavity 121 is matched with the quantitative dish distribution component 130 to realize automatic quantitative dish distribution. In the embodiment of the present invention, the quantitative dish-dividing assembly 130 includes a first quantitative dish-dividing member 131, a second quantitative dish-dividing member 132 and a quantitative dish-dividing driving member 133, wherein the quantitative dish-dividing driving member 133 is in transmission connection with the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132, and the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 realize automatic dish-dividing. The first quantitative dish-dividing piece 131 and the second quantitative dish-dividing piece 132 are arranged in the dish-dividing cavity 121 at intervals up and down, and the up-down distance between the first quantitative dish-dividing piece 131 and the second quantitative dish-dividing piece 132 is fixed, so that quantitative dish-dividing of dishes can be realized; that is, in a space region where the distance between the first quantitative dish member 131 and the second quantitative dish member 132 is high with the cross section of the dish distribution chamber 121 as the bottom surface (or the top surface), the volume thereof is fixed, thereby achieving the quantitative distribution of dishes. The first quantitative dish separating component 131 can separate dishes above the dish separating component, and the dishes are positioned at the position of the dish separating cavity 121 close to the dish inlet 122; the second portion 132 may block the dishes above it. In the working process, as shown in fig. 4, the second quantitative dish-dividing member 132 firstly plays a role of blocking dishes, but the first quantitative dish-dividing member 131 does not block dishes, and dishes enter the dish-dividing cavity 121 along with the dish inlet 122 until above the second quantitative dish-dividing member 132, and are blocked by the second quantitative dish-dividing member 132. As shown in fig. 5, after the dishes are basically filled in the dish-dividing cavity 121, the first quantitative dish-dividing member 131 is driven by the quantitative dish-dividing driving member 133, so that the first quantitative dish-dividing member 131 plays a role in blocking, and the dishes are divided into an upper part and a lower part of the first quantitative dish-dividing member 131, at this time, the second quantitative dish-dividing member 132 can not play a role in blocking the dishes, and under the action of gravity, the dishes are discharged downwards through the dish outlet 123, and as the first quantitative dish-dividing member 131 plays a role in blocking the dishes above, the dishes above the first quantitative dish-dividing member 131 cannot move downwards, so that the dishes discharged completely come from the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132, and the volume (capacity) of the dishes is fixed, thereby realizing automatic quantitative dish-dividing of the dishes and improving the dish-dividing efficiency.

Meanwhile, it should be noted that, when the automatic quantitative dish dispenser 100 is in operation, dishes in the dish storage cavity 111 enter the dish distribution cavity 121 through the dish inlet 122, at this time, the second quantitative dish distribution member 132 blocks the dish distribution cavity 121, the first quantitative dish distribution member 131 does not block the dish distribution cavity 121, and dishes enter the dish distribution cavity 121 from the dish inlet 122 until falling above the second quantitative dish distribution member 132. The dishes continue to enter the dish separating compartment 121 from the dish inlet 122 until the dish separating compartment 121 is filled. At this time, under the action of the quantitative dish-dividing driving part 133, the first quantitative dish-dividing part 131 blocks the dish-dividing cavity 121, the second quantitative dish-dividing part 132 does not block the dish-dividing cavity 121, the first quantitative dish-dividing part 131 blocks the dishes of the dish-storing cavity 111 above the first quantitative dish-dividing part 131, the second quantitative dish-dividing part 132 does not block the dishes, and the dishes between the first quantitative dish-dividing part 131 and the second quantitative dish-dividing part 132 are discharged along the dish outlet 123, so that automatic quantitative dish-dividing of the dishes is realized, and the dish-dividing efficiency is improved.

In addition, it should be noted that, in the embodiment of the present invention, by driving the quantitative dishes while being in transmission connection with the first quantitative dish dispensing member 131 and the second quantitative dish dispensing member 132, one of the first quantitative dish dispensing member 131 and the second quantitative dish dispensing member 132 is implemented to block the dish dispensing cavity 121. The first quantitative dish-dividing part 131 and the second quantitative dish-dividing part 132 are driven by the same driving, so that the structure of the dish-dividing machine is simpler and more compact, and the cost of equipment is reduced.

Referring to fig. 3 and 6, in the embodiment of the present invention, the serving container 120 may include a container body 124 and a serving buffer 125. The container body 124 has a dish separating cavity 121, a dish inlet 122 and a dish outlet 123, and a dish separating buffer opening is further provided on a side surface of the container body 124, the first quantitative dish separating member 131 is opposite to the dish separating buffer opening, and the dish separating buffer member 125 is provided on the dish separating buffer opening.

It should be noted that the dish separating buffer opening is disposed on a side of the container body 124 and is generally opposite to the first quantitative dish separating member 131, and the dish separating buffer member 125 is mounted on the dish separating buffer opening and is opposite to the first quantitative dish separating member 131, so as to buffer the hard dishes. When the first quantitative dish separating member 131 blocks the dish separating cavity 121, the dish separating buffer member 125 installed at the dish separating buffer opening can play a buffering effect on the first quantitative dish separating member 131, and for certain hard dishes such as bones and the like, when the first quantitative dish separating member 131 blocks the dish separating cavity 121 under the driving of the quantitative dish separating driving member 133, if hard dishes such as bones and the like exist between the first quantitative dish separating member 131 and the inner wall of the dish separating cavity 121, the dish separating buffer member 125 can deform or displace when the first quantitative dish separating member 131 extrudes, so that the first quantitative dish separating member 131 better blocks the dish separating cavity 121, gaps between the first quantitative dish separating member 131 and the inner wall of the dish separating cavity 121 are avoided or reduced, and accordingly, the gap leakage of dishes from the first quantitative dish separating member 131 and the gap between the dish separating cavity 121 is avoided or reduced, and the dish separating precision is improved.

Alternatively, in the present embodiment, the dish separating buffer 125 may be a buffer rubber pad. Of course, the present invention is not limited thereto, and the serving buffer 125 may be in other structures in other embodiments of the present invention, which are not specifically limited and required by the embodiments of the present invention.

Alternatively, in the present embodiment, the cross-sectional shape of the container body 124 is substantially square (square or rectangular, etc.), and the cross-sectional area is substantially uniform in the height direction. That is, in the present embodiment, the container body 124 is substantially rectangular. Of course, not limited thereto, in other embodiments of the present invention, the container body 124 may be a cylinder or a cube of other cross-sectional shapes.

Optionally, in the embodiment of the present invention, the dish dispensing container 120 may further include an elastic restoring member, where the elastic restoring member is connected to the dish dispensing buffer member 125 and the container body 124, so as to restore the dish dispensing buffer member 125. It should be noted that, for the serving buffer 125, it may deform and displace when a hard dish is present, and the elastic reset element may enable the serving buffer 125 to reset rapidly when the first quantitative serving 131 exits (i.e. the first quantitative serving 131 does not block the serving cavity 121).

Alternatively, in this embodiment, the elastic restoring member may be a restoring spring for restoring the serving buffer 125. The return force of the spring can be used to realize the rapid return of the dish separating buffer 125 so as to provide continuous buffering effect for the hard dishes.

As shown in fig. 6, in the present embodiment, the container body 124 is further provided with a first mounting groove 1241, the first quantitative dish-dividing member 131 is slidably connected with the first mounting groove 1241, and the first quantitative dish-dividing member 131 is sealed with the first mounting groove 1241; and/or, the container body 124 is further provided with a second mounting groove 1242, the second quantitative dish-dividing member 132 is slidably connected with the second mounting groove 1242, and the second quantitative dish-dividing member 132 is sealed with the second mounting groove 1242.

That is, for the assembly mode of the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 with the container body 124, the first mounting groove 1241 and the second mounting groove 1242 may be formed on the container body 124, and the first quantitative dish-dividing member 131 is mounted in the first mounting groove 1241 and can move relative to the first mounting groove 1241 under the driving of the quantitative dish-dividing driving member 133 so as to block or leave the dish-dividing cavity 121; the second quantitative dish-dividing member 132 is mounted in the second mounting groove 1242, and can move relative to the second mounting groove 1242 under the driving of the quantitative dish-dividing driving member 133, so as to block or leave the dish-dividing cavity 121.

Optionally, in order to ensure sealing between the first quantitative dish member 131 and the first mounting groove 1241, a sealing structure or a sealing ring may be provided; likewise, a sealing structure or a sealing ring for sealing may be provided between the second quantitative dish member 132 and the second mounting groove 1242. Of course, other sealing forms may be used to seal the first quantitative dish member 131 from the first mounting groove 1241 and the second quantitative dish member 132 from the second mounting groove 1242.

Alternatively, in the present embodiment, the first and second mounting grooves 1241 and 1242 are located at opposite sides of the container body 124, respectively. That is, for the first and second quantitative mountings 134 and 134, respectively, movement is from opposite directions and is engaged with the first and second mounting grooves 1241 and 1242, respectively, so that the structure can be made compact.

Referring to fig. 2 and 9, in the embodiment of the present invention, the quantitative dish-dividing driving member 133 is configured to locate the first quantitative dish-dividing member 131 outside the dish-dividing cavity 121 and the second quantitative dish-dividing member 132 inside the dish-dividing cavity 121, so that dishes enter the dish-dividing cavity 121 from the dish inlet 122 and the second quantitative dish-dividing member 132 blocks the dishes; the quantitative dish-dividing driving part 133 is further configured to locate the second quantitative dish-dividing part 132 outside the dish-dividing cavity 121 and locate the first quantitative dish-dividing part 131 inside the dish-dividing cavity 121, so that dishes leave the dish-dividing cavity 121 from the dish outlet 123 and the first quantitative dish-dividing part 131 blocks the dishes. Optionally, the quantitative dish dispensing assembly 130 may further include a mounting member 134, where the first quantitative dish dispensing member 131 and the second quantitative dish dispensing member 132 are connected to the mounting member 134, and the quantitative dish dispensing driving member 133 is in driving connection with the mounting member 134. That is, the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 are connected through the mounting member 134, and are driven by the quantitative dish-dividing driving member 133 and the mounting member 134, and simultaneously the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 are driven to move, so that one of the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 blocks the dish-dividing cavity 121, and automatic quantitative dish-dividing is realized.

As shown in fig. 9 and 10, alternatively, in the embodiment of the present invention, the mounting member 134 may include a first mounting portion 1341, a second mounting portion 1342, and a connecting portion 1343, where the first mounting portion 1341 and the second mounting portion 1342 are respectively disposed at two ends of the connecting portion 1343, and the first mounting portion 1341 is higher than the second mounting portion 1342, the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 are respectively connected to the first mounting portion 1341 and the second mounting portion 1342, and the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 are vertically opposite, and the quantitative dish-dividing driving member 133 is connected to the first mounting portion 1341 or the second mounting portion 1342.

Alternatively, in the present embodiment, the connection portion 1343 is used to connect the first mounting portion 1341 and the second mounting portion 1342, the connection portion 1343 is substantially inclined, the first mounting portion 1341 and the second mounting portion 1342 are located at opposite ends of the connection portion 1343, the first mounting portion 1341 is higher in horizontal position than the second mounting portion 1342, the first mounting portion 1341 is used to mount the first quantitative dish-dividing member 131, and the second mounting portion 1342 is used to mount the second quantitative mounting member 134, so that the first quantitative dish-dividing member 131 is located above the second quantitative dish-dividing member 132.

Optionally, the first mounting portion 1341 is provided with a mounting hole, and the first quantitative dish-dividing piece 131 is mounted on the first mounting portion 1341 by a screw or bolt; the second mounting portion 1342 is provided with a mounting hole, and the second quantitative dish member 132 is mounted on the second mounting portion 1342 by a screw or bolt. Of course, the first quantitative dish member 131 and the second quantitative dish member 132 may be mounted on the first mounting portion 1341 and the second mounting portion 1342 by other connection methods, such as clamping, bonding, welding, etc.

Alternatively, the mounting member 134 is generally frame-like in configuration, and the connecting portion 1343 includes two opposing mounting portions 1341 and 1342, each of which is connected to the first mounting portion. Setting the mounting member 134 to be a frame-like structure can be more stable when the mounting member 134 moves relative to the outer wall of the dish distribution chamber 121, so that the first quantitative dish distribution member 131 and the second quantitative dish distribution member 132 have better quantitative dish distribution effects.

It should be noted that, in the embodiment of the present invention, the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 are respectively disposed at two ends of the dish-dividing cavity 121 through the first mounting portion 1341 and the second mounting portion 1342, and under the action of the quantitative dish-dividing driving member 133, the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 move in the first mounting groove 1241 and the second mounting groove 1242 of the dish-dividing cavity 121, so that one of the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 blocks the dish-dividing cavity 121, thereby realizing quantitative dish-dividing. As shown in the figure, when the quantitative dish-dividing driving member 133 drives the mounting member 134, the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 to move in the first direction, the first quantitative dish-dividing member 131 exits the dish-dividing cavity 121, and the second quantitative dish-dividing member 132 enters the dish-dividing cavity 121, so that the second quantitative dish-dividing member 132 plays a blocking role on the dish-dividing cavity 121, dishes enter the upper portion of the second quantitative dish-dividing member 132, and the dish-dividing cavity 121 above the second quantitative dish-dividing member 132 is filled. At this time, the quantitative dish-dividing driving member 133 drives the mounting member 134, the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 to move in the second direction, the first quantitative dish-dividing member 131 enters the dish-dividing cavity 121, the second quantitative dish-dividing member 132 exits the dish-dividing cavity 121, so that the first quantitative dish-dividing member 131 plays a role in blocking the dish-dividing cavity 121, dishes are blocked above the second quantitative dish-dividing member 132, and dishes between the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 are discharged through the dish outlet 123.

Optionally, the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 are both plate-shaped or block-shaped structures, so as to achieve better dish-dividing effect. In addition, a chute for sliding the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 may be provided on the inner wall of the dish-dividing chamber 121, so as to further ensure that the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 slide stably.

Referring to fig. 7 to 10, in the embodiment of the invention, the automatic quantitative dish dispenser 100 may further include a slide rail assembly 140, wherein the slide rail assembly 140 includes a first slide rail 141 and a second slide rail 142 that are slidably engaged with each other, and the first slide rail 141 is disposed on the connecting portion 1343.

It should be noted that, the slide rail assembly 140 is configured to limit sliding of the first quantitative dish dispensing member 131 and the second quantitative dish dispensing member 132, and the first slide rail 141 and the second slide rail 142 are mutually matched, where the first slide rail 141 is disposed on the connecting portion 1343 and can slide synchronously along with the connecting portion 1343, and the second slide rail 142 can be mounted on the main body frame 101 of the dish dispensing machine, and meanwhile, the first slide rail 141 and the second slide rail 142 can also support the mounting member 134, the first quantitative dish dispensing member 131 and the second quantitative dish dispensing member 132.

Referring to fig. 2 and 8, in an embodiment of the present invention, the automatic quantitative dish dispenser 100 may further include a turnover assembly 150, where the turnover assembly 150 is installed in the dish storage chamber 111, and is used for allowing dishes in the dish storage chamber 111 to enter the dish inlet 122 and enter the dish dispensing chamber 121.

The turnover assembly 150 may include a turnover motor and a turnover blade 151, the turnover blade 151 is located in the dish storage chamber 111 and is rotatably connected with the dish storage assembly 110, and the turnover blade 151 is located approximately at a bottom opening of the dish storage chamber 111 and is used for rotating under the driving of the turnover motor, so that dishes in the dish storage chamber 111 enter the dish inlet 122 and the dish distribution chamber 121 below the dish storage chamber 111. That is, the flipping assembly 150 may power the entry of the dishes into the dish dispensing chamber 121. If quantitative dish distribution is needed, the overturning assembly 150 is started to enable dishes to enter the dish distribution cavity 121 to distribute dishes and discharge dishes, so that the dish distribution and discharge efficiency is improved.

Referring to fig. 11, in an embodiment of the present invention, the automatic quantitative dish dispenser 100 may further include a sensor group, and the sensor group is electrically connected to the quantitative dish dispensing driving unit 133, so that the quantitative dish dispensing driving unit 133 is turned on or off according to detection information of the sensor group.

The sensor group is helpful for realizing more intelligent dish distribution and dish discharge. The sensor group is used for detecting whether dish distribution is needed, such as whether dishes are placed at the dish outlet 123, and if dishes are placed, the dish distribution is needed. At this time, the quantitative dish-dividing driving member 133 first makes the second quantitative dish-dividing member 132 located in the dish-dividing cavity 121 to separate dishes, and then makes the first quantitative dish-dividing member 131 located in the dish-dividing cavity 121 and makes the second quantitative dish-dividing member 132 leave a channel communicated with the dish outlet 123, so as to realize intelligent dish-discharging of dishes. In addition, the sensor group can also be linked with the overturning motor of the overturning assembly 150, and when dishes are needed to be discharged, the overturning motor is controlled to work, so that the dishes enter the dish distributing cavity 121.

Optionally, in the embodiment of the present invention, the automatic quantitative dish dispenser 100 may further include a controller, and the sensor group, the quantitative dish dispenser driving unit 133, the turnover motor and other electronic devices are electrically connected to the controller, where the controller is used to control the working states of the electronic devices.

Referring to fig. 1 to 11 in combination, an automatic quantitative vegetable sorting machine 100 according to an embodiment of the present invention: the dish storage assembly 110 is provided with a dish storage cavity 111 for storing dishes, the dish distribution container 120 is provided with a dish distribution cavity 121, a dish inlet 122 and a dish outlet 123, the dish inlet 122 is communicated with the dish storage cavity 111, so that dishes in the dish storage cavity 111 are guided to the dish distribution cavity 121, the dish distribution cavity 121 is used for providing space for quantitatively distributing dishes, and the dish outlet 123 is used for discharging dishes. The quantitative dish-dividing assembly 130 comprises a first quantitative dish-dividing member 131, a second quantitative dish-dividing member 132 and a quantitative dish-dividing driving member 133, wherein the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 are arranged in the dish-dividing cavity 121 at intervals up and down, the upper and lower distances between the first quantitative dish-dividing member 131 and the second quantitative dish-dividing member 132 are fixed, and quantitative dish-dividing of dishes can be realized. The first quantitative dish separating component 131 can separate dishes above the dish separating component, and the dishes are positioned at the position of the dish separating cavity 121 close to the dish inlet 122; the second portion 132 may block the dishes above it. The quantitative dish-dividing driving part 133 makes one of the first quantitative dish-dividing part 131 and the second quantitative dish-dividing part 132 act as a barrier to the dish-dividing cavity 121. When the automatic quantitative dish dispenser 100 works, dishes in the dish storage cavity 111 enter the dish distribution cavity 121 through the dish inlet 122, at this time, the second quantitative dish distribution piece 132 blocks the dish distribution cavity 121, the first quantitative dish distribution piece 131 does not block the dish distribution cavity 121, and the dishes enter the dish distribution cavity 121 from the dish inlet 122 until falling above the second quantitative dish distribution piece 132. The dishes continue to enter the dish separating compartment 121 from the dish inlet 122 until the dish separating compartment 121 is filled. At this time, under the action of the quantitative dish-dividing driving part 133, the first quantitative dish-dividing part 131 blocks the dish-dividing cavity 121, the second quantitative dish-dividing part 132 does not block the dish-dividing cavity 121, the first quantitative dish-dividing part 131 blocks the dishes of the dish-storing cavity 111 above the first quantitative dish-dividing part 131, the second quantitative dish-dividing part 132 does not block the dishes, and the dishes between the first quantitative dish-dividing part 131 and the second quantitative dish-dividing part 132 are discharged along the dish outlet 123, so that automatic quantitative dish-dividing of the dishes is realized, and the dish-dividing efficiency is improved.

The above describes in detail an automatic quantitative vegetable dispenser disclosed in the embodiment of the present invention, and specific examples are applied to illustrate the principle and implementation of the present invention, and the description of the above examples is only used to help understand an automatic quantitative vegetable dispenser and its core ideas: meanwhile, as those skilled in the art will vary in the specific embodiments and application scope according to the idea of the present invention, the present disclosure should not be construed as limiting the present invention in summary.

Claims (11)

1. An automatic quantitative dish dispenser, comprising:

-a dish storage assembly (110), the dish storage assembly (110) having a dish storage cavity (111);

a dish separating container (120), wherein the dish separating container (120) is provided with a dish separating cavity (121), a dish inlet (122) and a dish outlet (123), the dish inlet (122) is communicated with the dish separating cavity (121), the dish inlet (122) is arranged corresponding to the dish storing cavity (111) and is communicated with the dish storing cavity (111), the dish outlet (123) is arranged corresponding to the dish inlet, so that dishes in the dish storing cavity (111) can enter the dish separating cavity (121) from the dish inlet (122), and dishes in the dish separating cavity (121) can leave the dish separating cavity (121) through the dish outlet (123);

the quantitative dish distribution assembly (130), quantitative dish distribution assembly (130) includes first quantitative dish distribution spare (131), second quantitative dish distribution spare (132) and quantitative dish distribution driving piece (133), first quantitative dish distribution spare (131) with second quantitative dish distribution spare (132) interval each other and all with divide dish container (120) to be connected for the separation dish in dish distribution chamber (121), first quantitative dish distribution spare (131) are used for when first quantitative dish distribution spare (131) separation divide dish distribution chamber (121) time, with dish separation in the top of first quantitative dish distribution spare (131), second quantitative dish distribution spare (132) are used for in second quantitative dish distribution spare (132) separation divide dish chamber (121) time, with dish separation in the top of second quantitative dish distribution spare (132), quantitative dish distribution driving piece (133) with first quantitative dish distribution spare (131) and second quantitative dish distribution spare (132) are used for dividing dish distribution (121) or the transmission of second quantitative dish distribution spare (132) to divide dish distribution chamber (121).

2. The automatic quantitative dish dispenser according to claim 1, wherein the dish dispenser container (120) comprises:

the container body (124), the container body (124) is provided with the dish distribution cavity (121), the dish inlet (122) and the dish outlet (123), the side surface of the container body (124) is also provided with a dish distribution buffer opening, and the first quantitative dish distribution piece (131) is opposite to the dish distribution buffer opening;

the dish separating buffer piece (125), the dish separating buffer piece (125) is arranged at the dish separating buffer opening.

3. The automatic quantitative serving machine according to claim 2, wherein the serving container (120) further comprises an elastic return member connected to the serving buffer member (125) and the container body (124) for returning the serving buffer member (125).

4. The automatic quantitative dish dispenser according to claim 2, wherein the container body (124) is further provided with a first mounting groove (1241), the first quantitative dish dispenser (131) is slidably connected with the first mounting groove (1241), and the first quantitative dish dispenser (131) is sealed with the first mounting groove (1241); and/or the number of the groups of groups,

the container main body (124) is further provided with a second mounting groove (1242), the second quantitative dish-dividing piece (132) is in sliding connection with the second mounting groove (1242), and the second quantitative dish-dividing piece (132) is sealed with the second mounting groove (1242).

5. The automatic quantitative dish dispenser according to claim 4, wherein the first and second mounting grooves (1241, 1242) are provided at opposite sides of the container body (124), respectively.

6. The automatic quantitative dish dispenser according to any one of claims 1-5, wherein the quantitative dish dispenser drive (133) is configured to position the first quantitative dish dispenser (131) outside the dish dispenser cavity (121) and the second quantitative dish dispenser (132) inside the dish dispenser cavity (121) such that dishes enter the dish dispenser cavity (121) from the dish inlet (122) and the second quantitative dish dispenser (132) blocks dishes; the quantitative dish-dividing driving piece (133) is further used for enabling the second quantitative dish-dividing piece (132) to be located outside the dish-dividing cavity (121) and the first quantitative dish-dividing piece (131) to be located inside the dish-dividing cavity (121), so that dishes leave the dish-dividing cavity (121) from the dish outlet (123), and the first quantitative dish-dividing piece (131) blocks the dishes.

7. The automatic quantitative dish dispenser according to claim 6, wherein the quantitative dish dispenser assembly (130) further comprises a mounting member (134), the first quantitative dish dispenser (131) and the second quantitative dish dispenser (132) are both connected with the mounting member (134), and the quantitative dish dispenser driving member (133) is in transmission connection with the mounting member (134).

8. The automatic quantitative dish dispenser according to claim 7, wherein the mounting member (134) comprises a first mounting portion (1341), a second mounting portion (1342) and a connecting portion (1343), the first mounting portion (1341) and the second mounting portion (1342) are respectively disposed at two ends of the connecting portion (1343), the first mounting portion (1341) is higher than the second mounting portion (1342), the first quantitative dish dispensing member (131) and the second quantitative dish dispensing member (132) are respectively connected with the first mounting portion (1341) and the second mounting portion (1342), the first quantitative dish dispensing member (131) and the second quantitative dish dispensing member (132) are vertically opposite, and the quantitative dish dispensing driving member (133) is connected with the first mounting portion (1341) or the second mounting portion (1342).

9. The automatic quantitative dish dispenser according to claim 8, wherein the automatic quantitative dish dispenser (100) further comprises a slide rail assembly (140), the slide rail assembly (140) comprises a first slide rail (141) and a second slide rail (142) which are in sliding fit with each other, and the first slide rail (141) is disposed on the connecting portion (1343).

10. The automatic quantitative dish dispenser according to any one of claims 1-5, wherein the automatic quantitative dish dispenser (100) further comprises a flipping assembly (150), the flipping assembly (150) being mounted in the dish storage chamber (111) for allowing dishes in the dish storage chamber (111) to enter the dish inlet (122) and into the dish dispensing chamber (121).

11. The automatic quantitative dish dispenser according to any one of claims 1 to 5, wherein the automatic quantitative dish dispenser (100) further comprises a sensor group electrically connected to the quantitative dish dispenser driving part (133) to turn on or off the quantitative dish dispenser driving part (133) according to detection information of the sensor group.