CN220823826U - Automatic feeding barn for henhouse - Google Patents

Abstract

The utility model discloses an automatic feeding barn for a henhouse, which comprises the following steps: a bin column; the storage bin is arranged on the bin column, a plurality of storage areas are arranged in the storage bin, and each storage area is correspondingly provided with a storage valve for opening or closing the storage area; a stirring area is also arranged in the storage bin and is positioned at the bottom of the storage area; the feeding valve is arranged at the bottom of the stirring area; the feeding groove is arranged at the bottom of the bin column, and corresponds to the storage bin in the height direction so as to contain the stirred feed in the stirring area; and the controller is arranged on the storage bin and is used for controlling the storage area and the stirring area to be opened or closed within preset time. According to the utility model, by controlling the feed throwing time and throwing amount, automatic feeding is conveniently realized by farmers according to the throwing proportion of the thrown feed types, uniform mixing distribution of the feed is ensured, the breeding effect and feeding efficiency are improved, and the time and energy of manual feeding are reduced.

Description

Automatic feeding barn for henhouse

Technical Field

The utility model relates to the technical field of henhouse granary manufacturing, in particular to an automatic feeding granary for henhouses.

Background

In modern agricultural production, automation and intelligent management of farms are increasingly gaining importance. An efficient and easy-to-operate automated feeding barn can save a lot of time and effort for farmers and improve feeding efficiency and production level.

Traditional granary systems often require manual feeding, stirring and dispensing of the feed, which is not only labor intensive, but also difficult to ensure uniform mixing and dispensing of the feed. Aiming at the feed feeding problem of the walking chickens, according to the research results, the time and the type of feed feeding have great influence on the breeding effect. Typically, dry ingredients are fed in the morning and wet ingredients are fed in the noon. The wet material needs to be prepared into certain humidity, and when the wet material is kneaded into clusters by hands, the scattering can be carried out by the scattering hands. The wet feed is beneficial to digestion and absorption of the chickens in the ground and is beneficial to improving the cultivation effect.

Disclosure of utility model

The utility model aims to provide a novel technical scheme for automatically feeding a barn in a henhouse, which at least can solve the problems that the barn system in the prior art needs to manually throw feed, stir and distribute, so that the labor intensity is high, and the uniform mixing and distribution of the feed are difficult to ensure.

In a first aspect of the utility model, there is provided an automatic feeding barn for a chicken house comprising: a bin column; the storage bin is arranged on the bin column, a plurality of storage areas are arranged in the storage bin, each storage area is respectively used for containing feed, and each storage area is respectively and correspondingly provided with a storage valve so as to open or close the storage area; the storage bin is internally provided with a stirring area, and the stirring area is positioned at the bottom of the storage area so as to stir the feed after the storage area is opened; the feeding valve is arranged at the bottom of the stirring area so as to open or close the storage area; the feeding groove is arranged at the bottom of the bin column, and corresponds to the storage bin in the height direction so as to contain the stirred feed in the stirring area; and the controller is arranged on the storage bin and is used for controlling the storage area and the stirring area to be opened or closed within preset time.

Optionally, the number of the storage areas is four, the four storage areas are arranged in a row in the storage bin, a sliding door is arranged at the top of the storage bin, and the sliding door is used for opening or closing the storage areas; each storage area is arranged to be funnel-shaped, and the radial dimension of one side of the storage area facing the stirring area is smaller than the radial dimension of one side of the storage area facing away from the stirring area.

Optionally, the automatic feeding barn of the chicken house further comprises: the first driving parts are steering engines and are respectively arranged on the inner wall of the storage bin, each first driving part is respectively connected with the controller, and each first driving part is respectively used for opening or closing a corresponding storage valve.

Optionally, be equipped with second driving piece and agitator in the stirring district, the second driving piece is the motor, the second driving piece with the agitator is connected, just the second driving piece with the agitator all is located the central point in stirring district puts.

Optionally, the stirrer comprises a plurality of stirring blades, wherein a part of the stirring blades are close to the second driving piece position and are distributed at intervals around the circumference of the stirrer, and the other part of the stirring blades are far away from the second driving piece position and are distributed at intervals around the circumference of the stirrer, and the length of the stirring blades close to the second driving piece is greater than the length of the stirring blades far away from the second driving piece.

Optionally, a first pressure sensor is further arranged in the stirring area, the first pressure sensor is arranged on the bottom wall of the stirring area, and the first pressure sensor is connected with the controller, so that when the weight in the stirring area is greater than the preset weight, the first driving piece drives the material storage valve to be closed.

Optionally, the feeding valve forms the bottom wall of the storage area, the first pressure sensor is arranged on the feeding valve, a part of the feeding valve extends out of the storage bin, and the feeding valve is rotationally connected with the storage bin through a hinge.

Optionally, the outer wall of storage silo is equipped with the third driving piece, the third driving piece is the motor, the third driving piece with throw the material valve with first pressure sensor is connected, in order to drive throw the material valve open or close.

Optionally, a second pressure sensor is arranged in the feeding groove, and the second pressure sensor is connected with the controller.

Optionally, a display screen is further arranged on the outer wall of the storage bin, the display screen is provided with a display area corresponding to each storage area, and control buttons are further arranged on the display screen.

According to the automatic feeding barn for the chicken house, the plurality of storage areas are arranged in the storage bin and are used for containing different types of feeds, the controller is used for controlling the opening and closing of each storage valve, the corresponding feeds can be automatically put into the stirring areas for mixing and stirring, and after stirring is finished, the feeds can be put into the feeding groove by controlling the opening and closing of the feeding valves, so that feeding is convenient. The feeding time and the feeding amount of the feed are controlled by the controller, so that farmers can automatically feed according to the feeding proportion of the fed feed types, the uniform mixing distribution of the feed is ensured, the breeding effect and the feeding efficiency are improved, and the time and the energy of manual feeding are reduced.

Other features of the present utility model and its advantages will become apparent from the following detailed description of exemplary embodiments of the utility model, which proceeds with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description, serve to explain the principles of the utility model.

FIG. 1 is a schematic view of a structure of an automatic feeding barn for a chicken house according to an embodiment of the present utility model;

fig. 2 is a schematic diagram of a storage bin of an automatic feeding barn for a chicken house according to an embodiment of the present utility model.

Reference numerals:

a bin column 10;

A storage bin 20; a storage area 21; a storage valve 22; a stirring zone 23; a sliding door 24;

A feed valve 30;

a feeding trough 40;

A first driving member 51; a second driving member 52; a third driving member 53;

A stirrer 60; a stirring blade 61;

a first pressure sensor 71; a second pressure sensor 72;

a display screen 80; a display area 81; control button 82.

Detailed Description

Various exemplary embodiments of the present utility model will now be described in detail with reference to the accompanying drawings. It should be noted that: the relative arrangement of the components and steps, numerical expressions and numerical values set forth in these embodiments do not limit the scope of the present utility model unless it is specifically stated otherwise.

The following description of at least one exemplary embodiment is merely exemplary in nature and is in no way intended to limit the utility model, its application, or uses.

Techniques, methods, and apparatus known to one of ordinary skill in the relevant art may not be discussed in detail, but are intended to be part of the specification where appropriate.

In all examples shown and discussed herein, any specific values should be construed as merely illustrative, and not a limitation. Thus, other examples of exemplary embodiments may have different values.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further discussion thereof is necessary in subsequent figures.

In the description and claims of the present utility model, the terms "first," "second," and the like, if any, may include one or more of those features, either explicitly or implicitly. In the description of the present utility model, unless otherwise indicated, the meaning of "a plurality" is two or more. Furthermore, in the description and claims, "and/or" means at least one of the connected objects, and the character "/", generally means that the associated object is an "or" relationship.

In the description of the present utility model, it should be understood that, if the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. are referred to, the positional relationship indicated based on the drawings is merely for convenience of description and simplification of the description, and does not indicate or imply that the apparatus or element referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the utility model.

In the description of the present utility model, it should be noted that the terms "mounted," "connected," and "connected" are to be construed broadly, unless otherwise specifically defined and limited. For example, the connection can be fixed connection, detachable connection or integrated connection; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

The following describes the automatic feeding barn of the henhouse according to the embodiment of the utility model in detail with reference to the accompanying drawings.

As shown in fig. 1, the automatic feeding barn for chicken houses according to the embodiment of the present utility model includes a barn post 10, a storage silo 20, a feeding valve 30, a feeding groove 40 and a controller.

Specifically, the storage bin 20 is arranged on the bin column 10, a plurality of storage areas 21 are arranged in the storage bin 20, each storage area 21 is respectively used for containing feed, and each storage area 21 is correspondingly provided with a storage valve 22 for opening or closing the storage area 21; the storage bin 20 is also internally provided with a stirring area 23, and the stirring area 23 is positioned at the bottom of the storage area 21 so as to stir the feed after the storage area 21 is opened. A charging valve 30 is provided at the bottom of the agitation area 23 to open or close the storage area 21. The feeding groove 40 is arranged at the bottom of the bin column 10, and the feeding groove 40 corresponds to the storage bin 20 in the height direction so as to hold the stirred feeding materials in the stirring area 23. A controller is provided on the storage bin 20 for controlling the opening or closing of the storage area 21 and the agitation area 23 for a preset time.

In other words, referring to fig. 1, the automatic feeding barn for the chicken house according to the embodiment of the present utility model is mainly composed of a barn post 10, a storage silo 20, a feeding valve 30, a feeding groove 40 and a controller. The number of the bin columns 10 is four, the four bin columns 10 are used for supporting the storage bin 20, the storage bin 20 is arranged on the bin columns 10, a plurality of storage areas 21 are arranged in the storage bin 20, each storage area 21 is respectively used for containing feeding, and each storage area 21 can be respectively used for feeding rice, corn, bran, water and the like.

Each storage area 21 is respectively and correspondingly provided with a storage valve 22, and the storage areas 21 can be opened or closed through the storage valves 22 so as to facilitate automatic feeding. The storage bin 20 is also internally provided with a stirring area 23, the stirring area 23 is arranged at the bottom of the storage area 21, and after the storage area 21 is opened, the feed enters the stirring area 23 for mixing and stirring. A charging valve 30 is installed at the bottom of the stirring zone 23, and the charging valve 30 can open or close the storage zone 21. The feeding groove 40 is arranged at the bottom of the bin column 10, the feeding groove 40 corresponds to the storage bin 20 in the height direction, and the feeding groove 40 can hold the stirred feed in the stirring area 23. A controller (not shown) is installed on the storage bin 20 for controlling the opening or closing of the storage area 21 and the agitation area 23 for a preset time. The feeding time and the feeding amount of the feed are controlled by the controller, so that farmers can automatically feed according to the feeding proportion of the fed feed types, the uniform mixing distribution of the feed is ensured, the breeding effect and the feeding efficiency are improved, and the time and the energy of manual feeding are reduced.

In the utility model, the time and type of feed feeding have a great influence on the cultivation effect, and in general, dry feed is fed in the morning and wet feed is fed in the noon. The wet material needs to be prepared into certain humidity, and when the wet material is kneaded into clusters by hands, the scattering can be carried out by the scattering hands. The wet feed is beneficial to digestion and absorption of the chickens in the ground and is beneficial to improving the cultivation effect. The automatic feeding barn for the henhouse can realize automatic stirring and feeding of dry materials and wet materials. Through introducing automatic stirring and moisture control system, make the fodder throw-in process become more convenient and fast, ensure the quality and the standardization of fodder simultaneously.

Therefore, according to the automatic feeding barn of the chicken house disclosed by the embodiment of the utility model, the storage bin 20 is internally provided with the plurality of storage areas 21 for containing different types of feeds, the controller is used for controlling the opening and closing of each storage valve 22, the corresponding feeds can be automatically put into the stirring area 23 for mixing and stirring, and after the stirring is finished, the feeds can be put into the feeding groove 40 by controlling the opening and closing of the feeding valve 30, so that the feeding is convenient. The feeding time and the feeding amount of the feed are controlled by the controller, so that farmers can automatically feed according to the feeding proportion of the fed feed types, the uniform mixing distribution of the feed is ensured, the breeding effect and the feeding efficiency are improved, and the time and the energy of manual feeding are reduced.

According to one embodiment of the utility model, the number of the storage areas 21 is four, the four storage areas 21 are arranged in rows in the storage bin 20, the top of the storage bin 20 is provided with a sliding door 24, and the sliding door 24 is used for opening or closing the storage areas 21; each storage area 21 is arranged in a funnel shape, and the radial dimension of the side of the storage area 21 facing the stirring area 23 is smaller than the radial dimension of the side of the storage area 21 facing away from the stirring area 23.

That is, referring to fig. 1, the number of storage areas 21 may be four, and four storage areas 21 are arranged in a row within the storage bin 20. The four storage areas 21 can be respectively provided with rice, corn, bran, water and the like. The top of the storage bin 20 is provided with a sliding door 24, and the sliding door 24 is used for opening or closing the storage area 21. The farmer opens the upper grain discharging door (sliding door 24) to discharge grains. Each storage zone 21 is arranged in a funnel shape, wherein the radial dimension of the side of the storage zone 21 facing the stirring zone 23 is smaller than the radial dimension of the side of the storage zone 21 facing away from the stirring zone 23. The hopper-shaped storage area 21 can enable the feed throwing speed to be low, all feeds cannot be poured out at one time, and the accuracy of feeding is improved.

According to one embodiment of the utility model, the automatic feeding barn for henhouses further comprises a plurality of first driving members 51, the first driving members 51 are steering engines, the first driving members 51 are respectively arranged on the inner wall of the storage bin 20, each first driving member 51 is respectively connected with the controller, and each first driving member 51 is respectively used for opening or closing a corresponding storage valve 22.

In other words, referring to fig. 1, the automatic feeding barn for chicken houses further includes a plurality of first driving members 51, the first driving members 51 may employ steering gears, the first driving members 51 are respectively disposed on the inner wall of the storage bin 20, each first driving member 51 is respectively connected with the controller, and each first driving member 51 may be respectively used to open or close a corresponding one of the storage valves 22. The steering wheel is installed at the lateral wall of storage silo 20, and storage valve 22 is controlled by the steering wheel. The steering engine drives the valve of the storage valve 22 to move rightwards by a certain angle, the valve is opened, and the feed is poured into the stirring area 23. The steering engine moves leftwards by a certain angle, returns to the original position, the valve is closed, and the feed stops pouring.

In some embodiments of the present utility model, the stirring area 23 is provided with a second driving member 52 and a stirrer 60, the second driving member 52 is a motor, the second driving member 52 is connected to the stirrer 60, and the second driving member 52 and the stirrer 60 are both located at the center of the stirring area 23. The agitator 60 includes a plurality of agitating blades 61, wherein a portion of the agitating blades 61 are positioned adjacent to the second driver 52 and are spaced circumferentially about the agitator 60 and another portion of the agitating blades 61 are positioned adjacent to the second driver 52 and are spaced circumferentially about the agitator 60 and the length of the agitating blades 61 adjacent to the second driver 52 is greater than the length of the agitating blades 61 remote from the second driver 52.

That is, referring to fig. 1, the second driving member 52 and the pulsator 60 are provided in the pulsator area 23, and the second driving member 52 is removable using a motor. The second driving member 52 is connected to the agitator 60, and both the second driving member 52 and the agitator 60 are located at the center of the agitation area 23. The agitator 60 may be driven by a motor to agitate the feed material in the agitation zone 23.

The agitator 60 includes a plurality of agitating blades 61, wherein a portion of the agitating blades 61 are positioned proximate the second driver 52 and are spaced apart about the circumference of the agitator 60. The other part of the stirring blades 61 are located away from the second driving member 52 and are distributed at intervals around the circumference of the stirrer 60, and the length of the stirring blades 61 close to the second driving member 52 is longer than that of the stirring blades 61 far away from the second driving member 52, so that the stirrer 60 can better touch each area in the granary by adopting stirring blades 61 with different lengths, and the full stirring of the feed is realized.

In the present utility model, the agitator 60 is driven by a motor mounted on a partition plate at the bottom of the storage area 21. The stirrer 60 employs six stirring rods (stirring blades 61), including three long stirring rods and three short stirring rods. By using different length stirring bars, the stirrer 60 is better able to reach various areas in the grain bin, achieving adequate stirring of the feed. The long stirring rod is arranged in the middle of the stirring shaft, so that the feed on the periphery, the bottom and the upper part can be fully turned during stirring. The short stirring rod is arranged at the lower position of the stirring shaft, so that the feed at the lower and central positions can be fully stirred during stirring. The stirrer 60 adopts stirring rods with different lengths to realize full stirring and uniform mixing, so that the adhesion of feed is avoided, the structure is simplified, the stirring efficiency is improved, and the performance of a feeding system is optimized.

According to one embodiment of the present utility model, a first pressure sensor 71 is further disposed in the stirring zone 23, the first pressure sensor 71 is disposed on the bottom wall of the stirring zone 23, and the first pressure sensor 71 is connected to the controller to drive the storage valve 22 to be closed by the first driving member 51 when the weight in the stirring zone 23 is greater than the preset weight.

In other words, referring to fig. 1, a first pressure sensor 71 is further provided in the agitation area 23, the first pressure sensor 71 is provided on the bottom wall of the agitation area 23, and the first pressure sensor 71 is connected to the controller. By providing the first pressure sensor 71, it is possible to indicate that the amount of feed to be fed reaches a certain amount when the weight in the stirring zone 23 is greater than the preset weight, and at this time, the first driving member 51 is used to drive the storage valve 22 to be closed, so that continuous feeding is avoided.

According to one embodiment of the utility model, the feed valve 30 forms the bottom wall of the storage area 21, the first pressure sensor 71 is arranged on the feed valve 30, a part of the feed valve 30 extends out of the storage bin 20, and the feed valve 30 is rotatably connected with the storage bin 20 by a hinge. The outer wall of the storage bin 20 is provided with a third driving piece 53, the third driving piece 53 is a motor, and the third driving piece 53 is connected with the feeding valve 30 and the first pressure sensor 71 so as to drive the feeding valve 30 to open or close.

That is, referring to fig. 1, the feed valve 30 may constitute a bottom wall of the storage area 21, and the first pressure sensor 71 is mounted on the feed valve 30. A portion of the feed valve 30 extends out of the storage bin 20, and the feed valve 30 is pivotally connected to the storage bin 20 by a hinge. The feeding valve 30 is generally composed of a hinge, a wire, a motor, a partition plate and the like, the outer wall of the storage bin 20 is provided with a third driving member 53 (see fig. 2), the third driving member 53 is a motor, and the third driving member 53 is connected with the feeding valve 30 and the first pressure sensor 71 to drive the feeding valve 30 to be opened or closed.

After the first pressure sensor 71 below the feeding valve 30 of the stirring area 23, the steering engine of the storage area 21 rotates to close the storage valve 22, and food dumping is stopped. The feed valve 30 is fully opened so that all of the feed in the mixing zone 23 can be poured out. The feeding valve 30 can be composed of a hinge, a wire, a motor and a partition plate, the motor rotates rightwards, the wire is loosened, and the feeding valve 30 is opened. The motor rotates to the left, the wire is pulled taut, and the feed valve 30 is closed. The motor is installed at the outer wall.

According to one embodiment of the present utility model, referring to fig. 1, the feeding trough 40 may be designed to be high in the middle and low in the periphery, and feed flows around to facilitate pecking by chickens. A second pressure sensor 72 is disposed within the feeding trough 40, the second pressure sensor 72 being connected to the controller. When the second pressure sensor 72 at the feeding trough 40 senses that the pressure is too low and no food is present, the motor of the storage area 21 drives the storage valve 22 to open, the feed is poured into the stirring area 23, and when the first pressure sensor 71 reaches a certain value, i.e. the fed feed reaches a certain amount, the storage valve 22 is closed. The stirrer 60 rotates to stir, improving uniformity of feed mixing and distribution.

According to one embodiment of the utility model, the outer wall of the storage bin 20 is further provided with a display screen 80, the display screen 80 having a display area 81 corresponding to each storage area 21, and control buttons 82 are further provided on the display screen 80.

That is, referring to fig. 2, the outer wall of the storage bin 20 may also be provided with a display screen 80, the display screen 80 having a display area 81 corresponding to each storage area 21, labeled as area 1, area 2, area 3, area 4. The partition is displayed above the screen, and the time is displayed in the middle. Control buttons 82 are also provided on the display 80. Wherein "-" indicates a decrease time and "+" indicates an increase time. The display 80 will display the time of opening the storage valves 22 in the four storage areas 21 (storage areas 211, 2, 3, 4), and the farmer clicks the screen to set up, and the time of opening the valves determines how much of each feed is put in. The feed delivery ratio will vary depending on the type of feed delivered by the farmer, and therefore the system does not fix the time each storage valve 22 is open.

In summary, according to the automatic feeding barn of the embodiment of the utility model, the storage bin 20 is internally provided with the plurality of storage areas 21 for containing different types of feeds, the controller controls the opening and closing of each storage valve 22, so that the corresponding feeds can be automatically put into the stirring area 23 for mixing and stirring, and after the stirring is finished, the feeds can be put into the feeding groove 40 by controlling the opening and closing of the feeding valve 30, thereby facilitating feeding. The feeding time and the feeding amount of the feed are controlled by the controller, so that farmers can automatically feed according to the feeding proportion of the fed feed types, the uniform mixing distribution of the feed is ensured, the breeding effect and the feeding efficiency are improved, and the time and the energy of manual feeding are reduced.

Of course, other structures of the automatic feeding barn of the chicken house and the working principle thereof can be understood and realized by those skilled in the art, and detailed description thereof is omitted in the present utility model.

While certain specific embodiments of the utility model have been described in detail by way of example, it will be appreciated by those skilled in the art that the above examples are for illustration only and are not intended to limit the scope of the utility model. It will be appreciated by those skilled in the art that modifications may be made to the above embodiments without departing from the scope and spirit of the utility model. The scope of the utility model is defined by the appended claims.

Claims (10)

1. An automatic feeding barn for a henhouse, comprising:

A bin column;

The storage bin is arranged on the bin column, a plurality of storage areas are arranged in the storage bin, each storage area is respectively used for containing feed, and each storage area is respectively and correspondingly provided with a storage valve so as to open or close the storage area; the storage bin is internally provided with a stirring area, and the stirring area is positioned at the bottom of the storage area so as to stir the feed after the storage area is opened;

The feeding valve is arranged at the bottom of the stirring area so as to open or close the storage area;

The feeding groove is arranged at the bottom of the bin column, and corresponds to the storage bin in the height direction so as to contain the stirred feed in the stirring area;

And the controller is arranged on the storage bin and is used for controlling the storage area and the stirring area to be opened or closed within preset time.

2. The automatic chicken house feeding barn of claim 1, wherein the number of the storage areas is four, the four storage areas are arranged in a row in the storage bin, a sliding door is arranged at the top of the storage bin, and the sliding door is used for opening or closing the storage areas; each storage area is arranged to be funnel-shaped, and the radial dimension of one side of the storage area facing the stirring area is smaller than the radial dimension of one side of the storage area facing away from the stirring area.

3. The automated chicken house feeding barn of claim 1, further comprising: the first driving parts are steering engines and are respectively arranged on the inner wall of the storage bin, each first driving part is respectively connected with the controller, and each first driving part is respectively used for opening or closing a corresponding storage valve.

4. The automatic chicken house feeding barn of claim 1, wherein the second driving part and the stirrer are arranged in the stirring area, the second driving part is a motor, the second driving part is connected with the stirrer, and the second driving part and the stirrer are both positioned at the center of the stirring area.

5. The automated chicken house feeding grain bin of claim 4, wherein the agitator comprises a plurality of agitator blades, wherein a portion of the agitator blades are positioned adjacent the second drive member and are circumferentially spaced about the agitator, and a portion of the agitator blades are positioned away from the second drive member and are circumferentially spaced about the agitator, and wherein the length of the agitator blades adjacent the second drive member is greater than the length of the agitator blades away from the second drive member.

6. The automatic chicken house feeding barn of claim 3, wherein the stirring area is further provided with a first pressure sensor, the first pressure sensor is arranged on the bottom wall of the stirring area, and the first pressure sensor is connected with the controller, so that the first driving piece drives the storage valve to be closed when the weight in the stirring area is larger than the preset weight.

7. The automatic chicken house feeding barn of claim 6, wherein the feeding valve forms the bottom wall of the storage area, the first pressure sensor is arranged on the feeding valve, a part of the feeding valve extends out of the storage bin, and the feeding valve is rotatably connected with the storage bin through a hinge.

8. The automatic chicken house feeding barn of claim 6, wherein a third driving piece is arranged on the outer wall of the storage silo, the third driving piece is a motor, and the third driving piece is connected with the feeding valve and the first pressure sensor to drive the feeding valve to be opened or closed.

9. The automatic chicken house feeding barn of claim 1, wherein a second pressure sensor is arranged in the feeding groove, and the second pressure sensor is connected with the controller.

10. The automatic chicken house feeding barn of claim 1, wherein the outer wall of the storage silo is further provided with a display screen, the display screen is provided with a display area corresponding to each storage area, and the display screen is further provided with a control button.