RU2632224C2 - Device for unloading poultry from cages - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: device comprises a cage battery divided into a plurality of sections by means of a plurality of mesh walls installed in parallel at an equal distance in the horizontal direction such that the plurality of sections are arranged one after another in the horizontal direction. The device comprises a mesh bottom layer arranged at the cage bottom. The mesh bottom layer comprises a blocking part and a hollow part. The blocking part of the mesh bottom forms the lower cage surface in the form of a panel, the size of which is equal to the sum of the bottom areas of the plurality of sections, and slides horizontally so as to linearly move relative to the cage. The hollow part of the mesh bottom is represented by an opening of the same size as the bottom area of one of the plurality of sections, and is arranged linearly relative to the blocking part of the mesh bottom, so as to move together with the blocking part of the mesh bottom. The device comprises the upper layer of the mesh bottom and the lower layer of the mesh bottom. The upper and the lower mesh bottom layers are driven by various drive mechanisms.

EFFECT: ensuring simple unloading of chickens for emptying the cage.

3 cl, 11 dwg

Description

FIELD OF THE INVENTION

The invention relates to poultry houses and, in particular, to a device and method for unloading poultry from a cage, and falls within the classification index IPC A01K 31.

BACKGROUND OF THE INVENTION

Recently, all modern automated poultry farms have been using a progressive method of breeding chickens with a constant volume of production, and after unloading chickens from their cages, they are directly fed to the slaughter place in the workshop or on the slaughterhouse. Catching chickens in a cage by hand is a time-consuming process, and it is sometimes difficult to catch chickens from the depths of the cage, as it is difficult to reach them with your hands. In a cage with a retractable mesh bottom, an employee can push the bottom, but this is not an easy job. In addition, since the mesh bottom needs to be extended a considerable distance in a direction substantially perpendicular to the front door of the cage in order to ensure that the chickens fall on a horizontal conveyor belt or in another container under the cage, if the chickens are bred in large volumes, there is a need for large labor costs.

The cage construction described in CN 102893903 A is currently known as a battery of sections that can be emptied by automatically collecting the bird, such as a “broiler cage suitable for emptying”. However, since such a broiler cage design is equipped with a rotatable mesh bottom, one side of such a bottom should be lifted when it capsizes. Moreover, the height of such a rise varies depending on the angle of rise and the distance between the side and the axis of rotation, and if the angle of rise is too small, the automatic fall of the bird is not achieved. Since the lifting angle has a lower limit, and each tier of the battery is limited in height, this distance should not be too large, because with a large distance, the height of the battery is also large, which reduces the number of tiers with cages that can be placed within the same height, which affects the efficiency of using the area of cages for hens. At the same time, since the area of the rising part of the cage is small, and the falling part is large, the fall height of the bird increases, and it can be harmed if it falls, which, in turn, affects the quality of the bird. Therefore, the rising half of each mesh bottom and its lowering half should not be too wide, and the width of each mesh bottom should also not be too large. Since several rotary mechanisms are required to empty the cage and collect the entire bird into one receiver, the system becomes complex and maintenance is quite time-consuming. In addition, even when using a rotary mesh bottom, it is impossible to automatically move all the hens into the receiver, and the remaining hens must be unloaded manually (paragraph [0007]), which causes difficulty for the worker and reduces the effectiveness of the automatic mechanism.

LINKS TO THE SOURCES OF INFORMATION TAKEN INTO ACCOUNT AT EXAMINATION

(Patent Document 1) Publication of the application which has not passed examination for the Chinese patent No. 102893903 (January 30, 2013)

SUMMARY OF THE INVENTION

The essence of the invention is to provide a device and method for unloading birds from the cage, providing a simple unloading of chickens to empty the cage.

In accordance with one general aspect of the invention, there is provided a device for unloading poultry from a cage, comprising: a cage battery divided into a plurality of spatial sections using a plurality of mesh walls mounted at an equal distance in a horizontal direction, such that a plurality of spatial sections are arranged behind another in the horizontal direction; and a mesh bottom layer located at the bottom of the cell, wherein the mesh layer at the bottom contains a blocking portion of the mesh bottom and a hollow portion of the mesh bottom, the blocking portion of the mesh bottom forming a lower surface of the cell in the form of a panel, the size of which is equal to the sum of the areas of the bottom of the plurality of spatial sections , and slides in the horizontal direction, so as to linearly move relative to the cell battery, and the hollow part of the mesh bottom is an opening of the same size as the bottom area of one and h multiple sections in space, and is linearly relative to the blocking part of the mesh bottom, so as to move with the blocking part of the mesh bottom.

In accordance with another aspect of the invention, there is provided a device for unloading a bird from a cage, comprising: a cell battery divided into a plurality of sections in space using a plurality of mesh walls mounted in parallel in the horizontal direction, such that the plurality of sections in space are arranged one after another in the horizontal direction; the upper layer of the mesh bottom and the lower layer of the mesh bottom are located on the bottom of the cell and, respectively, contain the blocking part of the mesh bottom and the hollow part of the mesh bottom, and the blocking part of the mesh bottom forms a lower surface of the cell in the form of a panel, the size of which is an integer multiple of the bottom area of one of the many sections in the battery value, and slides in the horizontal direction, so as to linearly move relative to the cell battery, and the hollow part of the mesh bottom is an opening of the same the size of the bottom area of one of the many sections, and is located linearly relative to the locking part of the mesh bottom, so as to move together with the locking part of the mesh bottom, and the upper layer of the mesh bottom and the lower layer of the mesh bottom are driven by various drive mechanisms.

In the device of the present invention for unloading poultry from a cage battery, it is preferable that the sum of the areas of the blocking part of the mesh bottom on the upper layer of the mesh bottom and the blocking part of the mesh bottom on the lower layer of the mesh bottom is greater than or equal to the sum of the areas of the bottom of all sections of the plurality of sections in the battery, and the blocking parts of the mesh bottom could move to a position in which they form the bottom surface of the entire cell.

The advantages and technical result of the present invention is achieved through the application of the technical features of the present invention described above, since the present invention allows to completely empty the bottom of the battery section due to the location of the hollow part of the mesh bottom at the bottom of the section by horizontal movement of the mesh bottom layer, with the hens above the interlock part of the mesh bottom is blocked by the mesh wall, while the mesh bottom layer moves in the horizontal direction, all chickens S from each section can be reset. Thanks to the parallel movement method, it is not necessary to vertically lift the mesh bottom layer, the mesh bottom layer area is not limited by the height of each section in the cell, the space occupied by the cell is reduced, and the system is simplified. In addition, the installation of the blocking parts of the mesh bottom of both the upper and lower layers of the mesh bottom, as well as setting the interval between the hollow parts of the mesh bottom, can solve the problem of unloading birds from many sections of the battery, using only two layers of the mesh bottom.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic front view of a device according to Embodiment 1 of the present invention.

FIG. 2 is a partial perspective view illustrating one position when using the embodiment shown in FIG. one.

FIG. 3 is a schematic front view of a device according to Embodiment 2 of the present invention.

FIG. 4 is a partial perspective view illustrating one position when using the embodiment shown in FIG. 3.

FIG. 5 is a partial perspective view illustrating a different position when using the embodiment shown in FIG. 3.

FIG. 6 is a schematic front view of a device according to Embodiment 3 of the present invention.

FIG. 7 is a partial perspective view illustrating one position when using the embodiment shown in FIG. 6.

FIG. 8 is a partial perspective view illustrating a usage state when a bird is unloaded from the first and third sections according to the embodiment shown in FIG. 6.

FIG. 9 is a partial perspective view illustrating a usage state when a bird is unloaded from the second and fourth sections according to the embodiment shown in FIG. 6.

FIG. 10 is a schematic front view of a device according to Embodiment 4 of the present invention.

FIG. 11 is a schematic front view illustrating the replacement of a closed-circuit electromechanism according to Embodiment 2 of the present invention with an open-circuit electromechanism.

CONVENTIONS

1: mesh wall 2.12: mesh bottom blocking part 2 ', 12': the hollow part of the mesh bottom 3, 13: chain 4, 14: chain sprocket 5, 15: drive mechanism 6: first section of the cell battery 7: second section of the cell battery 8: third section of the cell battery 9: fourth section of the cell battery

EMBODIMENTS FOR CARRYING OUT THE INVENTION

The following is a detailed description of embodiments of the present invention with reference to the accompanying drawings, which more fully discloses the content, features and technical result of the invention.

Incarnation 1

In FIG. 1 and FIG. 2 shows a device for unloading a bird from a cage battery in accordance with the present embodiment, including a cage in which a front door F, mesh walls 1 are installed, wherein the mesh bottom layers 2 and 2 ′ are located at the bottom of the cage. The plurality of mesh walls 1 are equally spaced in the horizontal direction, thereby dividing the cell battery into a plurality of sections 7. Despite the fact that in FIG. 1 and FIG. 2 shows an embodiment in which the cell consists of one section 7, but if the cell consists of many sections in space according to other embodiments, then the corresponding sections can be arranged one after another in the horizontal direction.

The front door F is generally a wire mesh, or a plurality of horizontal or vertical rods located on the front surface of section 7, and is mounted with the possibility of opening when the bird is in the spatial section or, if necessary, accessing the inside of section 7 for maintenance purposes. The side net 1 is rigidly fixed and can be made of wire mesh or multiple rods similar to the front door F, but can also be a panel, as shown in the drawings, which prevents contact between birds in adjacent sections. The back wall In section 7, it can be made similar to the front door F or the mesh wall 1, and next to it can be placed a ventilation duct, a device for removing excrement, etc., which are required, for example, in large poultry farms.

Layers 2 and 2 'of the mesh bottom capable of linearly sliding in the horizontal direction are located at the bottom of section 7 and include the interlocking part 2 of the mesh bottom and the hollow part 2' of the mesh bottom arranged in a row. When viewed from above, the mesh bottom blocking part 2 is a panel having the same shape and size as the section bottom, and the mesh bottom hollow part 2 ′ is an opening having the same shape and size as the mesh bottom blocking part 2 and layers 2 and 2 'of the mesh bottom are connected to the chain 3 through the chain sprocket 4 and the drive mechanism 5. In FIG. 1 and FIG. 2, the locking part 2 of the mesh bottom is depicted in the form of a board solely for the convenience of illustration and visual difference, and can be made in the form of a wire mesh, as in a regular cage. In addition, in the drawings, the mesh bottom blocking portion 2 is horizontal, however, it can be tilted so that its side facing the front door F is lowered to collect eggs.

The principle of operation of the invention is as follows.

If the drive mechanism 5 drives the drive sprocket 4, the drive sprocket moves the chain 3, while the chain pushes the mesh bottom layers 2 and 2 ', the mesh bottom layers 2 and 2' move to the left, as shown in the drawings. When the blocking part 2 of the mesh bottom completely leaves the bottom of the space of the section 7, the bottom of the corresponding section is replaced by the hollow part 2 'of the mesh bottom, and at this time the mesh wall 1 is blocked so that the chicken located on the blocking part 2 of the mesh bottom cannot move further along with the blocking part 2 of the mesh bottom. Accordingly, the chicken falls on a conveyor belt or in a portable container (not shown) located under the cage for further transportation of the bird.

The locking part 2 of the mesh bottom in this embodiment is moved in the horizontal direction and, therefore, is not related to the rotary method. Therefore, it is not necessary to extend the mesh bottom layer, and the mesh bottom area is no longer limited by the height of each section of the cell. Moreover, it is not necessary to provide in advance the space under the mesh bottom layer for turning down the mesh bottom layer, which allows to reduce the height of the bird’s fall and prevent its damage.

Incarnation 2

Presented in FIG. 3 and FIG. 4, embodiment 2 differs from option 1 in that the cell battery consists of two sections, the first section 6 and the second section 7, the mesh walls 1 are installed in each section, and the distance between the mesh walls is the same. The layer of the mesh bottom is made of several layers due to the upper layers 2 and 2 'of the mesh bottom and the lower layers 12 and 12' of the mesh bottom. In these drawings, the cage is shown in the position intended for breeding birds, where the blocking part 2 of the mesh bottom on the upper layers 2 and 2 'of the mesh bottom is located on the bottom of the second section of the battery 7 on the right, and the hollow part 2' of the mesh bottom on the upper layers 2 and 2 'mesh bottom is located on the bottom of the first section of the battery 6 on the left. Accordingly, the mesh bottom blocking portion 12 on the lower mesh bottom layers 12 and 12 ′ is located below the bottom of the first battery section 6 on the left, namely, under the hollow mesh bottom portion 2 ′ on the upper mesh bottom layers 2 and 2 ′, and the hollow part 12 'mesh bottom on the lower layers 12 and 12' of the mesh bottom is located under the bottom of the second section of the battery 7 on the right, namely, under the blocking part 2 of the mesh bottom on the upper layers 2 and 2 'of the mesh bottom. The area of each hollow part 2 'of the mesh bottom and each blocking part 2 of the mesh bottom on the upper and lower layers 2 and 2' of the mesh bottom corresponds to the area of the bottom of a separate section between the respective mesh walls.

The principle of operation of the embodiment of the invention 2 is as follows.

As shown in FIG. 4 and FIG. 5, when it is required to unload the bird from the first section of the cage battery 6 on the left, the lower layers of the mesh bottom 12 and 12 ′ move to the right until the blocking part 12 of the mesh bottom on the lower layers 12 and 12 ′ of the mesh bottom is completely blocked by the blocking part 2 mesh bottom on the upper layers 2 and 2 "mesh bottom, and the corresponding hollow parts 2 'and 12' mesh bottom on the lower layers 12 and 12 'mesh bottom and the upper layers 2 and 2' mesh bottom do not overlap completely with each other. bird support element under the first crate section of the primary battery 6 is removed, and the chicken from the first section 6 falls onto the conveyor belt or portable container under the cage. As shown in Fig. 4, when you want to unload the bird from the second section of the cage battery 7, the upper layers 2 and 2 'of the mesh bottom are moved to the left to until the mesh bottom blocking part 2 on the upper mesh bottom layers 2 and 2 ′ does not move to a position above the mesh bottom locking part 12 on the lower mesh bottom layers 12 and 12 ′, and the corresponding hollow mesh bottom parts 2 ′ and 12 ′ the lower layers 12 and 12 'of the mesh bottom and erhnie layers 2 and 2 'of the mesh bottom is not completely overlap with each other and installed below the second battery cell section 7. In this case, they go into the position shown in FIG. 5, and the chicken from the second section 7 of the battery falls down.

Embodiment 3

Presented in FIG. 6 and FIG. 7, embodiment 3 differs from embodiment 2 in that the cell battery consists of four sections, a first section 6, a second section 7, a third section 8 and a fourth section 9, arranged in order from left to right, the upper layers 2 and 2 ′ of the mesh bottom comprise, respectively, two locking parts 2 of the mesh bottom and two hollow parts 2 'of the mesh bottom, with two locking parts 2 of the mesh bottom on the upper layers 2 and 2' of the mesh bottom during the breeding process, respectively, located below the second section 7 and fourth section 9 , and two hollow h The parts 2 'of the mesh bottom on the upper layers 2 and 2' of the mesh bottom are respectively located at the bottom of the first section 6 and the third section 8, and the lower layers 12 and 12 'of the mesh bottom also include, respectively, two blocking parts 12 of the mesh bottom and two hollow sections 12 'of the mesh bottom, the two locking parts 12 of the mesh bottom on the lower layers 12 and 12' of the mesh bottom during the breeding process, respectively, located below the first section 6 and the third section 8, namely, under the hollow parts 2 'of the mesh bottom on the upper layers 2 and 2 'of the mesh bottom, and two hollow parts 12 'of the mesh bottom on the lower layers 12 and 12' of the mesh bottom are located, respectively, at the bottom of the second section 7 and the fourth section 9, namely, under the blocking parts 2 of the mesh bottom on the upper layers 2 and 2 'of the mesh bottom. In this position, the locking parts 2 and 12 of the mesh bottom are located at the bottom of all sections. At the same time, the lower layers of the mesh bottom 12 and 12 'are separately separated from the upper layers of the mesh bottom 2 and 2' using various drive mechanisms. In other words, the lower layers of the mesh bottom 12 and 12 ′ can be controlled by a chain 13, a chain sprocket 14 and a drive mechanism 15, which are different from a chain 3, a chain sprocket 4 and a drive mechanism 5 used to move the upper layers 2 and 2 ′ of the mesh bottom.

The principle of operation of Embodiment 3 is as follows.

As shown in FIG. 6 and FIG. 7, since during the breeding process, one blocking part of the mesh bottom is installed in each section, the bird remains inside the cage. If, if necessary, the bird is unloaded from the first section 6 and the third section 8, the lower layers of the mesh bottom 12 and 12 'are moved to the right until the blocking part 12 of the mesh bottom on the lower layers 12 and 12' of the mesh bottom is completely blocked by the blocking part 2 of the mesh the bottom on the upper layers 2 and 2 'of the mesh bottom, and the hollow parts 2' and 12 'of the mesh bottom on the lower layers 12 and 12' of the mesh bottom and the upper layers 2 and 2 'of the mesh bottom do not overlap completely with each other, as shown in FIG. . 8, the bird supporting member under the first section 6 and the third section 8 is pushed back, and the bird from the first section 6 and the third section 8 falls onto the conveyor belt or into a portable container under the cage. As shown in FIG. 9, if, if necessary, unload the bird from the second section of the battery 7 and the fourth section 9, the upper layers 2 and 2 'of the mesh bottom move to the left until the blocking part 2 of the mesh bottom on the upper layers 2 and 2' of the mesh bottom is completely blocked by the blocking part 12 mesh bottom on the lower layers of the mesh bottom 12 and 12 ', and the hollow parts 2' and 12 'of the mesh bottom on the lower layers 12 and 12' of the mesh bottom and the upper layers 2 and 2 'of the mesh bottom do not overlap completely with each other, then supporting the bird element under the second section is battery 7 and the fourth section s battery 9 is removed, and the bird from the second section 7 and the fourth section 9 falls down. If it is required to unload the bird from the second section 7 and the fourth section 9, and immediately before this, the bird was unloaded from the first section 6 and the third section 8, as shown in FIG. 8, the upper and lower layers of the mesh bottom 2, 2 'and 12, 12' together move to the left to the width of one section, which allows you to free the bottom of the second section 7 and fourth section 9 and, thus, unload the bird.

In this embodiment, only four sections in a sectional battery are considered as an example, however, one of ordinary skill in the art can use six, nine, ten, twenty, or tens of sections, provided that the blocking portion of the mesh bottom on the upper layer of the mesh bottom is located below the cell section batteries with an odd number, the hollow part of the mesh bottom on the upper layer of the mesh bottom is located at the bottom of the battery section with an even number, the blocking part of the mesh bottom on the lower layer of the mesh bottom olozhena section under the even-numbered mesh bottom hollow portion on the bottom layer located beneath the mesh bottom section with an odd number, and wherein the power drive mechanism is sufficient for driving the bottom layers of the mesh. At this stage, you can swap the upper layer of the mesh bottom and the lower layer of the mesh bottom.

Embodiment 4

Presented in FIG. 10, this embodiment differs from option 3 in that the mesh bottom blocking portion 12 on the lower mesh bottom layers 12 and 12 ′ is continuously formed at the bottom of the first section of the cell battery 6 and the second section of the cell battery 7, the size of the mesh blocking portion 12 is the sum of the areas the bottom of the first section 6 and the second section 7, the mesh bottom blocking part 2 on the upper mesh bottom layers 2 and 2 ′ is continuously formed at the bottom of the third section 8 and the fourth section 9, and the size of the mesh blocking part 2 is equal to the sum of the areas on the third section 8 and the fourth section 9. On the other hand, the hollow part 2 'of the mesh bottom on the upper layers 2 and 2' of the mesh bottom is continuously formed so as to correspond to the third section 8 and the fourth section 9, and the hollow part 12 'of the mesh bottom on the lower layers 12 and 12 'of the mesh bottom is located so as to correspond to the first section 6 and the second section 7.

The principle of operation of this embodiment is as follows.

If, if necessary, the bird is unloaded from the first section of the cage battery 6 and the second section of the cage battery 7, the lower layers of the mesh bottom 12 and 12 'are moved to the right to the width of two sections until the blocking part 12 of the mesh bottom on the lower layers 12 and 12' of the mesh bottom will not be completely blocked by the blocking part 2 of the mesh bottom on the upper layers 2 and 2 'of the mesh bottom, and the hollow part 12' of the mesh bottom on the lower layers 12 and 12 'of the mesh bottom will not completely overlap with the hollow part 2' of the mesh bottom on the upper layers 2 and 2 'mesh bottom, then support the bird-growing element under the first section 6 and the second section 7 is pushed back, and the bird from the first section 6 and the second section 7 falls onto the conveyor belt or into a portable container under the cage. If, if necessary, the bird is unloaded from the third section of the cage battery 8 and the fourth section of the cage battery 9, the upper layers of the mesh bottom 2 and 2 'are moved to the left to the width of two sections until the blocking part 2 of the mesh bottom on the upper layers 2 and 2' of the mesh bottom it does not completely overlap with the mesh blocking part 12 on the lower mesh bottom layers 12 and 12 ', and the hollow mesh bottom parts 2' and 12 'on the mesh bottom lower layers 12 and 12' and the upper mesh layers 2 and 2 'do not completely overlap with a friend then a bird supporting ele the cop under the third section 8 and the fourth section 9 is moved away, and the bird from the third section 8 and the fourth section 9 falls down.

In this embodiment, only four sections are considered as an example, however, the blocking part of the mesh bottom at the bottom of the first and second sections and the blocking part of the mesh bottom at the bottom of the third and fourth sections can be accordingly extended. For example, one blocking part of the mesh bottom can block from the first to the tenth section, and the second blocking part of the mesh bottom can block from the eleventh to the twentieth section, which allows solving the problem of unloading birds from twenty sections as a whole.

The present invention, the embodiments of which are described with reference to the drawings, is not limited to specific options, and specialists in the art can implement the present invention in various ways using ideas known from the present invention, without deviating from its essence and scope, since the described embodiments are shown purely by way of example and are not intended to limit the scope of the present invention.

 1) The present invention can be used not only for breeding chickens, but for fattening ducks. 2) The thrust can be transmitted not through a chain and a chain sprocket, but due to a combination of a gate and a wire, or a combination of a belt with a pulley can be used to transmit a transmission. 3) The mesh bottom layer can be moved horizontally using a ball screw pair or a screw nut. 4) In all embodiments of the present invention, a so-called closed-circuit electromechanism is used, in which the circuit operates in a closed circuit, however, an open-circuit electromechanism can also be used, in which case each layer of the mesh bottom can be moved horizontally with two drive mechanisms 5, 15, 5 ', 15', as shown in FIG. 11. 5) In accordance with embodiments of the present invention, each section of the cell battery is rectangular in plan view, however, each section may instead be in the form of a parallelogram. 6) The locking part of the mesh bottom and the hollow part of the mesh bottom described in Embodiment 3 may be extended. For example, the top layer of the mesh bottom may include (a blocking part of the mesh bottom that corresponds to the length of five sections) + (a hollow part of the mesh bottom that corresponds to the length of five sections) + (a locking part of the mesh bottom that corresponds to the length of five sections ) + (the hollow part of the mesh bottom, the size of which corresponds to the length of five sections), and the lower layer of the mesh bottom can also be made similar to the upper layer of the mesh bottom, so that the hollow part of the mesh bottom and the blocking part etchatogo bottom alternate with the topsheet mesh bottom. This allows you to use the present invention for keeping and unloading chickens from twenty consecutive sections, as well as to increase the size of the sections, which is also included in the scope of the present invention.

From the foregoing, it is obvious that each section of the cell battery used for rearing poultry must have its bottom, therefore, for any cell battery, the sum of the areas of the corresponding blocking parts of the mesh bottom on the upper layer of the mesh bottom and the lower layer of the mesh bottom should be greater than or equal to the sum the bottom areas of the corresponding sections of the cell battery, and the upper layer of the mesh bottom and the lower layer of the mesh bottom should be located so as to horizontally move to the bottom of each section. On the other hand, on the upper layer of the mesh bottom and the lower layer of the mesh bottom, it is sufficient to place one hollow part of the mesh bottom or more, respectively. However, the hollow parts of the mesh bottom should be arranged to overlap and move to the bottom of all sections of the cell battery.

Claims (3)

1. A device for unloading poultry from a cage battery, comprising a cage battery divided into a plurality of sections using a plurality of mesh walls mounted at an equal distance in the horizontal direction such that the plurality of sections are arranged one after the other in the horizontal direction; a mesh bottom layer located at the bottom of the cell, characterized in that the mesh bottom layer comprises a blocking portion of the mesh bottom and a hollow portion of the mesh bottom, wherein the blocking portion of the mesh bottom forms a lower surface of the cell in the form of a panel, the size of which is equal to the sum of the areas of the bottom of the plurality of sections, and slides in the horizontal direction so as to linearly move relative to the cell, while the hollow part of the mesh bottom is an opening of the same size as the bottom area of one of the many sections, and is located linearly relative to the blocking part of the mesh bottom so as to move with the blocking part of the mesh bottom. 2. A device for unloading poultry from a cage battery, comprising a cage battery divided into a plurality of sections by a plurality of mesh walls mounted in parallel in a horizontal direction such that a plurality of sections are arranged in a horizontal direction one after another; the upper layer of the mesh bottom and the lower layer of the mesh bottom located on the bottom of the cell, characterized in that the upper layer of the mesh bottom and the lower layer of the mesh bottom respectively comprise a blocking part of the mesh bottom and a hollow part of the mesh bottom, while the blocking part of the mesh bottom forms the lower surface of the cell in the form of a panel, the size of which is a multiple of the integer value of the bottom area of one of the many sections, and slides in the horizontal direction so as to linearly move relative to the cell, and the hollow part of the net the bottom is a hole of the same size as the bottom area of one of the many sections of the cell battery, and is linearly relative to the blocking part of the mesh bottom so as to move together with the blocking part of the mesh bottom, with the upper layer of the mesh bottom and the lower layer of the mesh bottoms are driven by various drive mechanisms. 3. The device according to claim 2, characterized in that the sum of the areas of the blocking part of the mesh bottom on the upper layer of the mesh bottom and the blocking part of the mesh bottom on the lower layer of the mesh bottom is not less than the sum of the areas of the bottom of all sections of the plurality of sections of the cell battery so that the cell battery moves in a position in which the bottom surface is located throughout the cell.

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