CN218664347U - Material distributing device - Google Patents

Abstract

The application is applicable to the automation equipment field, provides a distributing device, including frame, storage hopper, vibrator and rabbling mechanism. The storage hopper can be vibrationally installed on the frame, the storage hopper is provided with a feeding hole and a discharging hole which are distributed at intervals, the vibrator is installed on the storage hopper and used for driving the storage hopper to vibrate, and the stirring mechanism partially extends into the storage hopper and is used for stirring materials in the storage hopper. So set up for when feed divider is applied to and divides the dish, even the mobility of dish is relatively poor or the dish intertwine, also can disperse under vibrator and rabbling mechanism's combined action, in order to realize even ejection of compact, so can realize the effect of even branch dish.

Description

Material distributing device

Technical Field

The application belongs to the automation equipment field, and more specifically says, relates to a distributing device.

Background

In the related art, in places such as dining halls or fast food restaurants, large dishes are generally divided into small portions and put into meal boxes.

However, in general, dishes have poor fluidity, and some dishes are intertwined with each other, so that there is a problem that more dishes are needed and less dishes are needed when the dishes are distributed, and it is difficult to uniformly distribute the dishes, thus resulting in poor dish distribution effect.

SUMMERY OF THE UTILITY MODEL

The purpose of the embodiment of the application is as follows: the utility model provides a divide material device to solve the inhomogeneous technical problem of branch dish that exists among the correlation technique.

In order to achieve the purpose, the technical scheme adopted by the application is as follows:

providing a dispensing device comprising:

a frame;

the storage hopper is arranged on the rack in a vibrating manner and is provided with a feeding hole and a discharging hole which are distributed at intervals;

the vibrator is arranged on the storage hopper and is used for driving the storage hopper to vibrate;

and the part of the stirring mechanism extends into the storage hopper and is used for stirring the materials in the storage hopper.

In one embodiment, the feed divider further comprises elastic members respectively connected to the frame and the storage hopper.

In one embodiment, the frame is provided with a load cell, the storage hopper is mounted to the load cell, and the load cell is used to detect the weight of the storage hopper.

In one embodiment, the number of the weighing sensors is multiple, the storage hopper is connected with a plurality of pressing plates distributed at intervals, and the plurality of pressing plates are abutted to the detection surfaces of the weighing sensors respectively.

In one embodiment, the stirring mechanism includes a driver and a stirrer, the stirrer is connected to an output end of the driver, the stirrer is at least partially positioned in the storage hopper, and the driver is mounted to the storage hopper and is used for driving the stirrer to rotate.

In one embodiment, the agitator comprises:

the rotating shaft is connected to the output end of the driver and can rotate under the driving of the driver, and at least part of the rotating shaft is positioned in the storage hopper;

a blade provided on the rotating shaft and capable of rotating with the rotating shaft to perform stirring; at least a portion of the vanes are located in the storage hopper.

In one embodiment, the blades are helical and spirally wound on the outer circumferential side of the rotating shaft;

or the number of the blades is multiple, and the multiple blades are distributed on the outer periphery side of the rotating shaft at intervals along the circumferential direction;

alternatively, the number of the blades may be plural, and the plural blades may be arranged on the outer circumferential side of the rotating shaft at intervals in a spiral manner.

In one embodiment, the size of the storage hopper gradually decreases from the feeding port to the discharging port, the stirrer extends along the distribution direction of the feeding port and the discharging port, and the size of the stirrer gradually decreases from the feeding port to the discharging port.

In one embodiment, the output end of the driver is connected with a coupler, and the coupler is detachably connected with the stirrer.

In one embodiment, the coupler is provided with a limiting groove, the stirrer is connected with a connecting piece, the stirrer is in plug-in fit with the coupler, and the connecting piece is plugged in the limiting groove so as to limit the stirrer and the coupler from being separated from each other in a back direction; the connecting piece can be removed from the limiting groove.

The application provides a feed divider's beneficial effect lies in:

the feed divider that this application embodiment provided, when dividing the material, the vibrator starts, vibrate for the frame with the drive storage hopper, rabbling mechanism stirs the material in the storage hopper, thus, material in the storage hopper can disperse under vibrator and rabbling mechanism's effect, thereby can carry out the ejection of compact uniformly, therefore, when feed divider is applied to and divides the dish, even the mobility of dish is relatively poor or dish intertwine, also can disperse under vibrator and rabbling mechanism's combined action, in order to realize the even ejection of compact, so can realize the effect of evenly dividing the dish.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings required to be used in the embodiments or the related technical descriptions will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise.

Fig. 1 is a schematic structural diagram of a material separating device provided in an embodiment of the present application;

FIG. 2 is an enlarged view of a portion of FIG. 1 at A;

FIG. 3 is an enlarged view of a portion of FIG. 1 at B;

FIG. 4 is a partial front view of the feed divider provided in FIG. 1;

fig. 5 is a partial cross-sectional view of the feed divider provided in fig. 1.

Wherein, in the figures, the respective reference numerals:

100-a frame; 200-a storage hopper; 210-a feed inlet; 220-a containment chamber; 230-a discharge hole; 300-a vibrator; 400-a stirring mechanism; 410-a driver; 420-a stirrer; 421-a rotation axis; 422-blade; 500-an elastic member; 600-a weighing sensor; 700-a coupling; 710-a limiting groove; 720-transition groove; 730-a notch; 800-pressing plate; 900-a connecting part; 1000-connecting piece.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present application clearer, the present application is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of and not restrictive on the broad application.

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

It will be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in an orientation or positional relationship indicated in the drawings for convenience in describing the application and to simplify the description, and are not intended to indicate or imply that the device or element so referred to must have a particular orientation, be constructed in a particular orientation, and be constructed in operation as a limitation of the application.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

The feed divider of this application implementation is now explained:

referring to fig. 1, an embodiment of the present application provides a material dividing device for dividing a large dish into small parts. For example, the material dividing device can divide a large dish with poor fluidity into small dishes uniformly, so that the dishes can be placed into the lunch box conveniently. In addition, the material separating device can also be used for separating materials of other types, such as sticky fertilizer, concrete and the like.

Specifically, the material separating device comprises a frame 100, a storage hopper 200, a vibrator 300 and a stirring mechanism 400, wherein the storage hopper 200 is vibratably mounted on the frame 100, and the storage hopper 200 is provided with a feeding hole 210 and a discharging hole 230 which are distributed at intervals. The vibrator 300 is mounted to the storage hopper 200 and is configured to drive the storage hopper 200 to vibrate, and the stirring mechanism 400 partially extends into the storage hopper 200 and is configured to stir the material in the storage hopper 200.

Referring to fig. 1, the storage hopper 200 has a containing cavity 220, and the containing cavity 220 has the above-mentioned inlet 210 and outlet 230. When the feed divider uses, can carry the cooked food to holding the chamber 220 from the feed inlet 210 that holds the chamber 220 in, the vibrator 300 sends the vibration, and drive storage hopper 200 takes place the vibration, and rabbling mechanism 400 stirs the cooked food, through rabbling and the propelling movement of rabbling mechanism 400, then carry out the ejection of compact from the discharge gate 230 that holds the chamber 220. When the dishes are distributed, the dish distribution process is more continuous due to the matching of the feed inlet 210, the accommodating cavity 220 and the discharge hole 230, and the dish distribution efficiency is improved.

Specifically, when the material distribution device is in use, the storage hopper 200 can be set in a state that the discharge port 230 is located at the bottom of the storage hopper 200, and the feed port 210 is located above the discharge port 230, so that a worker pours dishes into the feed port 210, the dishes enter the containing cavity 220 from the feed port 210 under the action of gravity, and the containing cavity 220 contains the dishes and conveys the dishes to the discharge port 230.

In the present embodiment, the vibrator 300 may employ a vibration motor; it is understood that in other embodiments, the vibrator 300 may be selected from a device capable of driving the storage hopper 200 to vibrate using a pneumatic vibrator 300 or the like.

The vibrator 300 is arranged to facilitate the separation of dishes on the inner wall of the storage hopper 200 from the inner wall of the storage hopper 200, so that the dropping speed of the dishes is increased, and the dishes are prevented from remaining on the inner wall of the storage hopper 200; meanwhile, the vibration of the vibrator 300 is not too violent, and when the material distribution device is applied to distributing dishes, dishes on the inner wall of the storage hopper 200 can be separated from the inner wall of the storage hopper 200, so that the dropping speed of the dishes is accelerated, and the dishes cannot be damaged.

Referring to fig. 1, the vibrator 300 is mounted on the outer surface of the storage hopper 200, so that the vibrator 300 does not occupy the space of the receiving chamber 220 inside the storage hopper 200. Of course, in other embodiments, the vibrator 300 may be disposed inside the storage hopper 200, and even the vibrator 300 may be partially disposed outside the storage hopper 200 and partially disposed inside the storage hopper 200.

In this embodiment, rabbling mechanism 400 sets up on storage hopper 200, and inside some extensions of rabbling mechanism 400 got into storage hopper 200, when reinforced, rabbling mechanism 400 drove the inside dish of stirring storage hopper 200 through rotating, and the relatively poor dish of mobility is dispersed through the stirring of rabbling mechanism 400, is more easily dispersed by the propelling movement entering discharge gate 230 to guarantee the sustainable clear and accuracy nature of branch dish.

The feed divider that the embodiment of this application provided, when dividing the material, vibrator 300 starts, vibrate for frame 100 with drive storage hopper 200, rabbling mechanism 400 stirs the material in the storage hopper 200, thus, the material in the storage hopper 200 can disperse under vibrator 300 and rabbling mechanism 400's effect, thereby can carry out the ejection of compact uniformly, consequently, when feed divider is applied to and divides the dish, even the mobility of dish is relatively poor or the dish intertwine, also can disperse under vibrator 300 and rabbling mechanism 400's combined action, in order to realize even ejection of compact, so can realize the effect of evenly dividing the dish.

Alternatively, a vibration plate may be installed between the vibrator 300 and the outer surface of the storage hopper 200, the vibration plate may be connected to the storage hopper 200 by using a connector 1000 such as a bolt, and the vibrator 300 transmits the vibration to the storage hopper 200 through a plane where the vibration plate is located, so that the vibration generated by the vibrator 300 is better transmitted to the storage hopper 200.

In an embodiment of the present application, referring to fig. 1, the material separating device further includes an elastic member 500, one end of the elastic member 500 is connected to the frame 100, and the other end of the elastic member 500 is connected to the storage hopper 200.

The elastic member 500 may be a spring, a tension spring, a spring plate, rubber, or silica gel.

The number of the elastic members 500 may be one or more. When the number of the elastic members 500 is plural, each elastic member 500 is connected to the frame 100 and the storage hopper 200. For example, as shown in fig. 1, the number of the elastic members 500 is 4, 4 elastic members 500 are distributed around the storage hopper 200 at intervals, and two opposite ends of four elastic members 500 are respectively connected to the storage hopper 200 and the frame 100. Like this, all fix on frame 100 through elastic component 500 around storage hopper 200, storage hopper 200 neither can break away from frame 100 when the vibration, also can not drive frame 100 and vibrate together for equipment overall structure is more stable.

So set up, connect through elastic component 500 between storage hopper 200 and the frame 100, when vibrator 300 sends the vibration, storage hopper 200 vibrates under the drive of vibrator 300, elastic component 500 can absorb the vibration and the impact energy of storage hopper 200, make frame 100 can not follow the vibration of storage hopper 200, reduce the impact of storage hopper 200 to frame 100, and, storage hopper 200 passes through elastic component 500 and connects in frame 100, so that storage hopper 200 can vibrate at certain within range, and can not break away from frame 100 completely, guarantee complete machine stationarity.

Optionally, referring to fig. 1, a connecting portion 900 is disposed on an outer periphery of the storage hopper 200, the elastic member 500 is connected to the connecting portion 900 through a mounting seat, a gasket, and the like, and the connecting portion 900 is disposed to facilitate fixing the elastic member 500 to the storage hopper 200. Of course, in other embodiments, the elastic member 500 can also be directly connected to the storage hopper 200. For example, the storage hopper 200 is directly connected to the elastic member 500 by snapping, welding, bonding, or sleeving.

The connection 900 is located between the outlet 230 and the inlet 210, as shown in fig. 1, or, in other embodiments, may be located at the opening edge of the outlet 230.

Optionally, as shown in fig. 1, a preset included angle is formed between the connecting portion 900 and the wall surface of the storage hopper 200, where the preset included angle may be an included angle greater than 0 ° and smaller than 180 °. Reinforcing ribs are arranged at the included angle between the surface of the storage hopper 200 and the connecting part 900. The rational arrangement of strengthening rib makes more even distribution in connecting portion 900 of load, has strengthened the stability and the bearing capacity of storage hopper 200, has improved the structural strength of storage hopper 200, is favorable to elastic component 500 fixed.

In one embodiment of the present application, referring to fig. 1 and 2, a load cell 600 is disposed on the frame 100, the storage hopper 200 is mounted on the load cell 600, and the load cell 600 is used for detecting the weight of the storage hopper 200.

Wherein, load cell 600 is pressure sensor, and load cell 600 is used for acquireing the pressure of storage hopper 200, and then acquires the weight of storage hopper 200.

Alternatively, referring to FIG. 2,

specifically, as shown in fig. 1 and 2, when the storage hopper 200 is connected with the elastic member 500, one end of the elastic member 500 away from the storage hopper 200 abuts against the detection surface of the load cell 600. Of course, in other embodiments, when the storage hopper 200 is not provided with the elastic member 500, the storage hopper 200 may directly abut against the detection surface of the load cell 600.

In actual design, feed divider when dividing the dish, before dividing the dish every time and after dividing the dish every time, weighing sensor 600's setting can real-time supervision store up the weight of dish fill, and after the material of certain weight of discharging, the weight that stores up the dish fill is less than the default, will remind operating personnel to carry out timely interpolation this moment, has avoided storing up the dish fill and has lacked the dish and cause and divide the dish unusual. The amount of the dishes in the storage hopper 200 does not need to be monitored manually, and labor and time are saved. Meanwhile, the weighing time is set before and after the dishes are distributed each time, the vibrator 300 does not vibrate at the moment, the vibration of the elastic piece 500 is stopped, and the influence of the vibration generated by the vibrator 300 on the accuracy of the weighing is avoided when the dishes are distributed.

Optionally, the feed divider further comprises a controller and an alarm box (not shown in the figures). The controller respectively with load cell 600, alarm box electric connection, as shown in fig. 2, load cell 600 is located the frame 100, and the storage hopper 200 is installed in load cell 600. In the material distribution process, in order to monitor the weight of the materials in the storage hopper 200, the weighing sensor transmits the sensed weight to the controller, and after the materials with certain weight are discharged, the weight is lower than a preset value, the controller controls the alarm box to give an alarm to remind workers of timely filling.

In an embodiment of the present application, please refer to fig. 1, the number of the load cells 600 is plural, the storage hopper 200 is connected to the plurality of pressing plates 800, the plurality of pressing plates 800 are distributed at intervals, and the plurality of pressing plates 800 respectively abut against the detecting surfaces of the plurality of load cells 600.

Adopt above-mentioned technical scheme, storage hopper 200 is connected in load cell 600 through a plurality of clamp plates 800 to make storage hopper 200's weight can transmit to load cell 600 through clamp plate 800 on.

In addition, weighing sensor 600's quantity sets up to a plurality ofly, and weighing sensor 600 is at the even symmetric interval distribution of all directions of storage hopper 200 for weighing sensor 600's atress is more even in all directions, and the weighing sensor 600 atress of being convenient for has avoided the inaccurate problem of weighing result that the unbalance loading brought as far as possible.

It should be added that, as shown in fig. 1 and fig. 2, when the storage hopper 200 is connected with the elastic member 500, the pressing plate 800 is disposed at one end of the elastic member 500 away from the storage hopper 200, and the other end of the pressing plate 800 abuts against the detection surface of the weighing sensor 600, so that the pressing plate 800 abuts against the weighing sensor 600 instead of the elastic member 500 directly abutting against the weighing sensor 600, thereby avoiding the effect that the elastic member 500 is deformed during vibration, and the gravity transmission of the storage hopper 200 is not accurate.

In one embodiment of the present application, referring to fig. 5, the stirring mechanism 400 includes a driver 410 and a stirrer 420, the stirrer 420 is connected to an output end of the driver 410, the stirrer 420 is at least partially located in the storage hopper 200, the driver 410 is installed in the storage hopper 200, and the stirrer 420 is driven by the driver 410 to rotate.

Optionally, the driver 410 is an electric motor, and in other embodiments, the driver 410 may alternatively be a hydraulic driver 410, a gear train, or the like.

It can be understood that, when dishes with poor fluidity, such as slices, strips, threads and the like, need to be distributed in the dish distribution process, the driver 410 drives the stirrer 420 to stir, so that the dishes with poor fluidity can be dispersed, the dish distribution can be carried out continuously and accurately, and the problem of small dish distribution is solved.

In one embodiment of the present application, referring to fig. 5, the agitator 420 includes a rotating shaft 421 and a blade 422. The rotating shaft 421 is connected to the output end of the driver 410 and can rotate under the driving of the driver 410, and at least a part of the rotating shaft 421 is located in the storage hopper 200. The blade 422 is provided to the rotating shaft 421, and can rotate with the rotating shaft 421 to perform stirring, and at least a part of the blade 422 is located in the storage hopper 200.

The rotating shaft 421 and the blade 422 may be connected by welding, clamping, integral casting, or the like. The rotating shaft 421 partially extends into the feed port 210; alternatively, the rotating shaft 421 may extend entirely into the feed port 210. The vanes 422 extend fully into the feed inlet 210; alternatively, the vanes 422 extend entirely into the feed port 210.

Wherein, the extension of rotation axis 421 and blade 422 is not beyond discharge port 230, so can avoid discharge port 230 to be blockked to be convenient for the material to flow out discharge port 230.

Through adopting above-mentioned scheme, when feed divider feed, rotatory time-carrying blade 422 of rotation 421 rotates together, and then turns over the material of required mixture, and the material can outwards move under blade 422's drive, piles up the back and inwards collapses, forms inside and outside and turns over, makes the mixing stirring more abundant, when dividing the dish, even the mobility of dish is relatively poor or the dish intertwine, also can make the dish separate for divide the dish even. In addition, the blade 422 of the stirrer 420 has simple structure, convenient manufacture and wide viscosity range of applicable materials, and can disperse dishes with different viscosities, and the blade 422 type stirrer 420 has excellent fluid dispersing performance and is suitable for dispersing dishes.

In one embodiment of the present application, referring to fig. 5, the blades 422 are spirally wound around the outer circumference of the rotating shaft 421.

Referring to fig. 5, the blades 422 may be an integrated screw structure, the screw thread of the screw is formed by spirally spreading the blades 422, the blades 422 are integrated, and the integrated blades 422 are spirally wound on the outer circumferential side of the rotating shaft 421 to form a spiral surface contacting with the material.

Alternatively, in other embodiments, the blades 422 are not helical, and the number of the blades 422 is plural, and the plural blades 422 are distributed at intervals on the outer circumferential side of the rotating shaft 421 in the circumferential direction.

The plurality of blades 422 are distributed on the outer peripheral side of the rotating shaft 421 along the circumferential direction, a certain interval is provided between adjacent blades 422, and the blades 422 make a circumferential motion along with the stirring shaft to form a rotating surface. The blades 422 may form a plurality of rotating surfaces along the rotating shaft 421 with a certain interval between adjacent rotating surfaces.

Alternatively, in other embodiments, the blade 422 is not spiral, and the number of the blades 422 is plural, and the plural blades 422 are spaced at the outer periphery side of the rotating shaft 421 in a spiral manner.

The plurality of blades 422 are spirally and alternately distributed on the outer peripheral side of the rotating shaft 421, a certain interval is formed between adjacent blades 422, and the plurality of blades 422 form a spiral surface along the rotating shaft 421.

Alternatively, the blade 422 may be attached to the rotating shaft 421 using a connection structure such as an engaging mechanism or a coupling mechanism. The size and shape of the blades 422 are not particularly limited, and may be appropriately selected according to the size of the storage hopper 200, the viscosity of the material, and the like.

It can be understood that the blade 422 is mainly used for conveying materials with high viscosity and compressibility, and the rotating blade 422 simultaneously performs the functions of stirring, mixing and the like on the materials in the stirring and pushing process. When being applied to and dividing the dish, even the mobility of dish is relatively poor or dish intertwine, also can make the dish separately, makes to divide the dish even, and is connected for dismantling between rotation axis 421 and the blade 422, connects and dismantles the convenience, convenient maintenance and washing.

In some embodiments, referring to fig. 1, the size of the storage hopper 200 decreases from the inlet 210 to the outlet 230. It can be understood that the size of the feeding port 210 is larger than that of the discharging port 230, the feeding port 210 is larger, so that the workers can pour dishes conveniently, a large amount of feeding is facilitated, and meanwhile, the discharging port 230 is smaller, so that the discharging amount is not too large, and dishing is facilitated. The design that the size of the feeding port 210 is larger than that of the discharging port 230 enables the inner wall surface of the storage hopper 200 to be inclined inwards in the direction from the feeding port 210 to the discharging port 230, so that dishes can slide downwards along the inclined inner wall of the accommodating cavity 220 more easily.

As shown in fig. 5, the stirrer 420 is extended along the distribution direction of the inlet 210 and the outlet 230, and the size of the stirrer 420 is gradually reduced from the inlet 210 to the outlet 230.

The size of the stirrer 420 is the size of the stirrer 420 in a direction parallel to the inlet 210 and the outlet 230 when the stirrer 420 extends from the inlet 210 to the outlet 230.

As shown in fig. 5, when the stirrer 420 includes the rotating shaft 421 and the blades 422, the size of the stirrer 420 refers to the diameter of the rotating plane on which the blades 422 are located. The diameter of the rotating plane where the blades 422 are located gradually decreases with the decrease of the size of the storage hopper 200, and the blades 422 are gradually densely distributed as the rotating shaft 421 extends from the feeding port 210 to the discharging port 230.

Through adopting above-mentioned technical scheme, agitator 420's size reduces gradually and is favorable to the better shape that adapts to storage hopper 200 of agitator 420, and the agitator 420 of being convenient for stretches into inside the storage hopper 200. When the stirrer 420 includes the above-mentioned rotating shaft 421 and the blade 422, when the rotating shaft 421 drives the blade 422 to rotate, the material is conveyed to the discharge port 230 by the rotating blade 422, and then is output from the discharge port 230. Along with the distribution of the blades 422 becoming dense gradually, the conveying speed of the material is increased gradually from the feeding port 210 to the discharging port 230, and the conveying amount is increased gradually, so that the density of the material at the discharging port 230 is increased greatly, and thus, the full distribution of the material can be ensured during each distribution.

In one embodiment of the present application, referring to fig. 1 and 3, the output end of the driver 410 is connected to a coupling 700, and the coupling 700 is detachably connected to the agitator 420.

The driver 410 and the stirrer 420 can be firmly connected by the coupler 700 to rotate together and transmit movement and torque, the structure is firm, meanwhile, the stirrer 420 can be detached from the driver 410 due to the arrangement of the coupler 700, the stirrer 420 can be detached to be cleaned independently during cleaning or maintenance, and the design is simple and convenient.

In an embodiment of the present application, referring to fig. 1 and fig. 3, the coupler 700 is provided with a limiting groove 710, the stirrer 420 is connected with the connecting member 1000, the stirrer 420 and the coupler 700 are inserted and matched, and the connecting member 1000 is inserted and matched in the limiting groove 710 to limit the stirrer 420 and the coupler 700 from being separated from each other in a back direction; the connector 1000 is removable from the retaining groove 710.

The stirrer 420 is provided with a through hole, the connecting piece 1000 is arranged in the through hole in a penetrating manner, and the coupler 700 is provided with a limiting groove 710. When the coupler 700 and the stirrer 420 are in splicing fit, when the connecting piece 1000 is spliced to the limiting groove 710 and the through hole is aligned, the connecting piece 1000 is spliced in the through hole, then the connecting piece 1000 is spliced with the limiting groove 710, and the connecting piece 1000 can simultaneously penetrate through the limiting groove 710, so that the splicing fit of the connecting piece 1000 and the limiting groove 710 is realized, and the relative limit between the coupler 700 and the stirrer 420 can be indirectly realized. When the connecting piece 1000 is pulled out from the through hole, the connecting piece 1000 is correspondingly pulled out from the stirrer 420 to be separated from the limiting groove 710 of the coupler 700, so that the limiting relation between the stirrer 420 and the coupler 700 is removed, the stirrer 420 and the coupler 700 can be directly pulled out in the back direction, and the stirrer 420 can be detached.

Alternatively, in other embodiments, the connector 1000 is secured to the agitator 420. The coupler 700 is further provided with a notch 730, a transition groove 720 is arranged between the notch 730 and the limiting groove 710, the transition groove 720 and the notch 730 are sequentially communicated. When the coupler 700 and the stirrer 420 are in inserted fit, the connecting piece 1000 can be aligned with the notch 730 to enter the notch 730, and then the coupler 700 and the stirrer 420 are relatively rotated to enable the connecting piece 1000 to enter the limiting groove 710 from the transition groove 720. During disassembly, the coupler 700 and the stirrer 420 rotate in opposite directions, so that the connecting piece 1000 enters the gap 730 from the transition groove 720, the coupler 700 is separated from the stirrer 420, and the stirrer 420 can be disassembled.

By adopting the technical scheme, the driver 410 and the stirrer 420 can be detachably connected. When dishes with poor fluidity, such as slices, strips, threads and the like, need to be divided, the stirrer 420 is arranged, and the vibrator 300 and the stirrer 420 are driven together, so that the dishes are divided more uniformly, and the problem of more or less dishes is solved; when dishes to be distributed are dish with good fluidity, such as small blocks and diced dishes, the stirrer 420 can be omitted, the vibrator 300 is directly used for vibrating the storage hopper 200, the dishes cannot be damaged due to violent stirring, and the protection effect on the dishes is good. Meanwhile, when the material distributing device is cleaned or maintained, the stirrer 420 can be detached for cleaning alone or maintenance, and the use is convenient.

The present invention is not intended to be limited to the particular embodiments shown and described, but is to be accorded the widest scope consistent with the principles and novel features herein disclosed.

Claims (10)

1. A dispensing device, comprising:

a frame;

the storage hopper is arranged on the rack in a vibrating manner and is provided with a feeding hole and a discharging hole which are distributed at intervals;

the vibrator is arranged on the storage hopper and is used for driving the storage hopper to vibrate;

and the part of the stirring mechanism extends into the storage hopper and is used for stirring the materials in the storage hopper.

2. The feed divider of claim 1, further comprising springs connected to the frame and the storage hopper, respectively.

3. The material dividing device as claimed in claim 1, wherein the frame is provided with a load cell, the storage hopper is mounted on the load cell, and the load cell is used for detecting the weight of the storage hopper.

4. The material distributing device according to claim 3, wherein the number of the weighing sensors is multiple, the storage hopper is connected with a plurality of pressing plates distributed at intervals, and the plurality of pressing plates are respectively abutted to the detection surfaces of the plurality of weighing sensors.

5. A distributor device according to any one of claims 1 to 4, characterised in that the stirring mechanism comprises a drive and an agitator, the agitator being connected to an output of the drive and being located at least partly in the storage hopper, the drive being mounted to the storage hopper and being adapted to drive the agitator in rotation.

6. The dividing apparatus of claim 5, wherein the agitator comprises:

the rotating shaft is connected to the output end of the driver and can rotate under the driving of the driver, and at least part of the rotating shaft is positioned in the storage hopper;

a blade provided on the rotating shaft and capable of rotating with the rotating shaft to perform stirring; at least part of the vanes are located in the storage hopper.

7. The dividing device as claimed in claim 6, wherein the blades are helical and are helically wound around the outer periphery of the rotating shaft;

or the number of the blades is multiple, and the multiple blades are distributed on the outer periphery side of the rotating shaft at intervals along the circumferential direction;

alternatively, the number of the blades may be plural, and the plural blades may be arranged on the outer circumferential side of the rotating shaft at intervals in a spiral manner.

8. The material distributing device according to claim 5, wherein the size of the storage hopper is gradually reduced from the feeding port to the discharging port, the stirrer extends along the distribution direction of the feeding port and the discharging port, and the size of the stirrer is gradually reduced from the feeding port to the discharging port.

9. The dividing device as claimed in claim 5, wherein a coupling is connected to the output end of the driver, and the coupling is detachably connected to the stirrer.

10. The distributing device according to claim 9, wherein the coupler is provided with a limiting groove, the stirrer is connected with a connecting piece, the stirrer is in plug-in fit with the coupler, and the connecting piece is plugged in the limiting groove to limit the stirrer and the coupler from being separated from each other in a back direction; the connecting piece can be removed from the limiting groove.

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