An egg collecting system for automated layer farming
By designing an automated egg collection system, the problems of high breakage rate and low efficiency of traditional egg collection methods have been solved. The system enables automatic cleaning, drying and weighing of eggs, improving production efficiency and reducing labor costs.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- NINGXIA FURUISHENG AGRI DEV CO LTD
- Filing Date
- 2025-08-04
- Publication Date
- 2026-07-14
AI Technical Summary
Traditional egg collection methods are labor-intensive, costly, have a high breakage rate, are inefficient, and cannot be cleaned or weighed during the collection process.
An automated egg collection system was designed, including a conveying device, a cleaning device, a drying device, a suction cup, and a weighing device. Eggs are transported by a conveyor belt and cleaned and dried during the transport process. The suction cup is used to automatically weigh and classify the eggs.
It enables automated collection, cleaning, drying, and weighing of eggs, reducing breakage rates, improving production efficiency, and lowering labor costs.
Smart Images

Figure CN224482580U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of egg collection equipment technology, and in particular to an automated egg collection system for laying hen farming. Background Technology
[0002] In large-scale egg-laying hen farming, the traditional method of manually collecting eggs has significant drawbacks, including high labor intensity, high costs, high breakage rates, high hygiene risks, and low efficiency. With the expansion of farming scale and the increasing demands for production efficiency, egg quality, and biosecurity, the development of automated egg collection systems has become an inevitable trend. Traditional conveyor systems often use conveyor belts to collect eggs, but these belts are prone to causing eggs to collide during transport, posing a risk of breakage. Furthermore, traditional egg collection equipment can only perform simple collection tasks and cannot clean or weigh the eggs during transport, requiring additional cleaning and weighing operations, significantly increasing production steps and time. Therefore, we propose an automated egg collection system for egg-laying hen farming to address these problems. Utility Model Content
[0003] This invention provides an automated egg collection system for laying hen farming, which solves the problems of traditional egg collection systems where eggs are easily broken by collisions during collection, cannot be automatically cleaned, and cannot be automatically weighed.
[0004] This utility model provides an automated egg collection system for laying hen farming, comprising two symmetrically installed chicken cages. Each chicken cage has an elongated hole at its bottom end, and a conveying device is located below the hole. A cleaning chamber is connected to the end of the conveying device. A cleaning device and a drying device are installed inside the cleaning chamber, with a first partition between them. A drive roller and a driven roller are rotatably mounted at both ends of the bottom of the cleaning chamber, and a mesh conveyor belt is sleeved between the drive roller and the driven roller. The drive roller is driven by a first motor installed on the outer wall of the cleaning chamber. A guide plate is installed on the top of the inner wall of the cleaning chamber. A transfer device is connected to the end of the cleaning chamber, and a weighing device is connected to the end of the transfer device. The weighing device has a shell, on the top of which a first cylinder is installed. The first cylinder is connected to a slider, which is slidably embedded in the top of the shell. A second cylinder is installed on the slider, and the end of the second cylinder extends into the interior of the shell where an air chamber is installed. Several suction cups are installed on the air chamber, which is connected to a vacuum pump via an air supply pipe. The vacuum pump is installed on the top of the shell. A weighing pan is located below each suction cup, and a baffle is provided between the weighing pans. An electric push rod corresponding to the weighing pan is installed on the side of the shell, and a push plate is installed at the end of the electric push rod. A collection chamber corresponding to the weighing pan is installed at an angle on the opposite side of the electric push rod.
[0005] Preferably, the conveying device includes a conveying device cover located below the elongated hole. Several first round rods are rotatably installed inside the conveying device cover. A second partition is installed in the middle of the conveying device cover. Two first gears are symmetrically fixedly sleeved on the first round rods about the second partition. A first chain is sleeved between the first gears on the same side. Several connecting rods are connected between the first chains on the same side. One of the first round rods is driven by a second motor installed on the conveying device cover.
[0006] Preferably, the cleaning device includes a spray pipe installed inside the cleaning chamber, a plurality of spray heads installed on the spray pipe, the spray pipe being connected to a water tank via a connecting pipe, a water pump being installed on the connecting pipe, and a drain pipe being installed at the bottom of the cleaning chamber.
[0007] Preferably, the drying device is installed in the air jet pipe inside the cleaning chamber. The air jet pipe is equipped with several air jet nozzles. The air jet pipe is connected to an air pump through an air supply pipe. A heating pipe is provided on the lower side of the air jet pipe. The heating pipe is installed on the inner wall of the cleaning chamber.
[0008] Preferably, the transfer device includes a transfer device bracket located at the end of the cleaning chamber. Two second round rods are rotatably installed inside the transfer device bracket. Two second gears are sleeved on the second round rods. A second chain is sleeved on the same side of the second gears. Several fixed columns are connected between the second chains. A groove is opened in the middle of the fixed columns. One of the second round rods is driven by a third motor installed on the side wall of the transfer device bracket.
[0009] Preferably, the number of suction cups is three.
[0010] Preferably, the weighing pan has a circular groove corresponding to the shape of an egg.
[0011] Preferably, shock-absorbing pads are installed on both sides of the second partition.
[0012] As can be seen from the above technical solution, this utility model provides an automated egg collection system for laying hen farming. In use, eggs slide out from the elongated hole along the bottom of the cage and fall into the gap of the connecting rod, preventing the eggs from moving during transport. The second motor is activated, driving the first round rod to rotate, which in turn drives the first gear to rotate synchronously. The first gear drives the first chain to rotate, causing the first round rod mounted on the first chain to move, thus moving the eggs until they fall onto the mesh conveyor belt. The third motor is then activated, driving the drive roller to rotate, thereby moving the mesh conveyor belt. As the mesh conveyor belt moves... The water pump is started, spraying clean water through the spray pipes and nozzles to clean the eggs on the mesh conveyor belt. Once the eggs reach the area below the drying unit, the heating element is activated, and simultaneously, the air pump is started. The air pump dries the egg surface through the air nozzles. As the mesh conveyor belt moves, the eggs are collected by the guide plate, allowing for individual passage. At the same time, the third motor is activated, driving the second gear on the second rod to rotate. The second chain on the second gear rotates synchronously, causing the fixed posts to move. The eggs fall one by one into the grooves between the fixed posts, thus transporting the eggs individually. At the end of the transfer device, the first cylinder is activated, driving the slider forward. Then, the second cylinder is activated, moving the air chamber forward and downward. When the suction cup contacts the egg, the vacuum pump is activated, creating negative pressure in the air chamber through the air supply pipe, sucking the egg up. The second cylinder then contracts, followed by the first cylinder, and then the second cylinder is activated again. The vacuum pump stops working, and the egg is placed on the weighing pan. The egg begins to be weighed. Before weighing, the weighing pans need to be set so that the mass range of the weighing pans increases sequentially. During weighing, if the mass sensed by the first weighing pan is exactly within the set range, the electric... The electric pusher pushes the eggs into the first collection bin via a push plate. If the weight of the eggs exceeds the set value of the weighing pan, the electric pusher does not move. The egg handling process is repeated, but during handling, not only are the eggs moved from the groove into the first weighing pan, but the eggs in the first weighing pan are also moved into the second weighing pan. The eggs on the second weighing pan are then judged again. If they meet the requirements, they are pushed into the second collection bin by the electric pusher. Otherwise, the system will eventually move them to the third weighing pan and push them into the second collection bin by the electric pusher. This completes one workflow cycle.
[0013] Compared with the prior art, the beneficial effects of this utility model are:
[0014] 1. The conveyor device can automatically collect the eggs in the chicken cage, and during collection, it can prevent the eggs from shaking and colliding with each other.
[0015] 2. The collected eggs can be automatically cleaned and dried using cleaning and drying devices, which can prevent chicken manure from contaminating the eggs and prevent impurities on the outside of the chicken shell from interfering with the weighing of the eggs.
[0016] 3. With the cooperation of suction cups, weighing plates and electric push rods, eggs can be automatically weighed and eggs of the same weight range can be automatically collected.
[0017] In summary, by using this application, eggs can be automatically collected, effectively preventing breakage during collection. After collection, the eggs are automatically cleaned, their surfaces washed and dried, and after cleaning, they are automatically weighed and classified according to their weight, which can significantly improve production efficiency. Attached Figure Description
[0018] To more clearly illustrate the technical solution of this utility model, the drawings used in the implementation examples will be briefly introduced below. Obviously, for those skilled in the art, other drawings can be obtained based on these drawings without any creative effort.
[0019] Figure 1 A schematic diagram of the overall structure of an automated egg collection system for laying hen farming proposed in this utility model;
[0020] Figure 2 This is a schematic diagram (B) of the overall structure of an automated egg collection system for laying hen farming proposed in this utility model;
[0021] Figure 3 This is a schematic diagram of the structure of a conveying device for an automated egg collection system for laying hen farming proposed in this utility model;
[0022] Figure 4 This is a schematic diagram A of the cleaning and drying device of an automated egg collection system for laying hen farming proposed in this utility model;
[0023] Figure 5 This is a schematic diagram (B) of the cleaning and drying device of an automated egg collection system for laying hen farming proposed in this utility model;
[0024] Figure 6 Schematic diagram A shows the structure of an automated egg collection and transfer device for laying hen farming proposed in this utility model;
[0025] Figure 7 This is a schematic diagram (B) of an automated egg collection and transfer device for laying hen farming proposed in this utility model.
[0026] In the diagram: 1. Chicken cage; 2. Elongated hole; 3. Conveying device; 301. Conveying device cover; 302. First round rod; 303. Second partition; 304. First gear; 305. First chain; 306. Connecting rod; 307. Second motor; 4. Cleaning chamber; 5. Cleaning device; 501. Spray pipe; 502. Spray head; 503. Connecting pipe; 504. Water tank; 505. Water pump; 506. Sewage pipe; 6. Drying device; 601. Air jet pipe; 602. Air nozzle; 603. Air supply pipe; 604. Air pump; 605. Heating pipe; 7. First partition. ; 8. Driven roller; 9. Driven roller; 10. Mesh conveyor belt; 11. First motor; 12. Guide plate; 13. Transfer device; 131. Support; 132. Second round rod; 133. Second gear; 134. Second chain; 135. Fixed column; 136. Groove; 137. Third motor; 14. Weighing device housing; 15. First cylinder; 16. Slider; 17. Second cylinder; 18. Air chamber; 19. Suction cup; 20. Weighing pan; 21. Baffle; 22. Electric push rod; 23. Push plate; 24. Collection chamber; 25. Air supply pipe; 26. Air pump. Detailed Implementation
[0027] To enable those skilled in the art to better understand the technical solutions of this utility model, the technical solutions in the embodiments of this utility model will be clearly and completely described below with reference to the accompanying drawings.
[0028] See Figure 1-7An automated egg collection system for laying hen farming is disclosed, applying the field of egg collection equipment technology. It can automatically collect eggs, automatically clean them after collection, automatically weigh them after cleaning, and classify them according to their weight. Specifically, it includes two symmetrically installed chicken cages 1. Each chicken cage 1 has an elongated hole 2 at its bottom end. The bottom of the chicken cage 1 is inclined, allowing eggs to slide through the elongated hole 2. A conveying device 3 is located below the elongated hole 2, and the end of the conveying device 3 is connected to a cleaning chamber 4. The conveying device 3 transports eggs to the cleaning chamber 4. The cleaning chamber 4 is equipped with a cleaning device 5 and a drying device 6. The cleaning device 5 washes the eggs, and the drying device 6 dries the washed eggs. A first partition 7 is installed between the cleaning device 5 and the drying device 6 to prevent water from the cleaning device 5 from splashing onto the dried eggs. Active rollers 8 are rotatably installed at both ends of the bottom of the cleaning chamber 4. A mesh conveyor belt 10 is sleeved between the driven roller 9, the driving roller 8, and the driven roller 9. The mesh conveyor belt 10 allows for the normal flow of cleaning water and drying gas, preventing vibration of the conveyor belt. The driving roller 8 is driven by a first motor 11 installed on the outer wall of the cleaning chamber 4. To ensure the stable operation of the mesh conveyor belt 10, multiple driven rollers 9 can be added for support. A guide plate 12 is installed on the top of the inner wall of the cleaning chamber 4. The guide plate 12 can guide the eggs, so that the eggs scattered on the mesh conveyor belt 10 eventually pass in a single row. A transfer device 13 is connected to the end of the cleaning chamber 4. The eggs on the mesh conveyor belt 10 will fall into the transfer device 13. The end of the transfer device 13 is connected to a weighing device. The weighing device housing 14 has a first cylinder 15 mounted on its top. The first cylinder 15 is connected to a slider 16, which is slidably embedded in the top of the housing 14. Activating the first cylinder 15 causes the slider 16 to reciprocate. A second cylinder 17 is mounted on the slider 16, with its end extending into the housing 14 where an air chamber 18 is installed. The second cylinder 17 causes the air chamber 18 to move up and down. Several suction cups 19 are mounted on the air chamber 18, which is connected to a vacuum pump 26 via an air supply pipe 25. The vacuum pump 26 is mounted on the top of the housing 14. During use, activating the vacuum pump 26 generates negative pressure within the air chamber 18. The suction cups 19 are pressed together to generate suction. This application uses three suction cups 19, which can transport three eggs at once. A weighing pan 20 is located below each suction cup 19. The weighing pan 20 has circular grooves corresponding to the shape of the eggs to prevent them from rolling during weighing. There are also three weighing pans 20. Before use, they need to be set to different weight ranges, preferably from bottom to top, for easy egg sorting. Baffles 21 are provided between the weighing pans 20 to separate them and collect eggs of different weights. An electric push rod 22 corresponding to the weighing pan 20 is installed on the side of the weighing device housing 14.A push plate 23 is installed at the end of the electric push rod 22. A collection chamber 24 corresponding to the weighing pan 20 is installed at an angle on the opposite side of the electric push rod 22. When weighing eggs, the eggs are transported to the end of the transfer device 13, and the first cylinder 15 is activated. The first cylinder 15 drives the slider 16 to move forward, and then the second cylinder 17 is activated. The second cylinder 17 drives the air chamber 18 to move forward and downward. When the suction cup 19 contacts the egg, the vacuum pump 26 is activated. The vacuum pump 26 generates negative pressure in the air chamber 18 through the air supply pipe 25, sucking up the egg. Then, the second cylinder 17 is retracted first, and then the first cylinder 15 is retracted. Then the second cylinder 17 is activated again, and the vacuum pump 26 stops working. The egg is placed on the weighing pan 20, and the egg begins to be weighed. Before weighing, the weighing pan 20 needs to be set so that the mass range set on the weighing pan 20 increases sequentially. During weighing, if the mass sensed by the first weighing pan 20 is within the set range, the electric pusher 22 is activated. The electric pusher 22 pushes the egg into the first collection bin 24 via the push plate 23. If the mass of the egg is greater than the set value of the weighing pan 20, the electric pusher 22 does not move. The egg handling process is repeated, but during handling, not only are eggs moved from the groove 136 into the first weighing pan 20, but eggs from the first weighing pan 20 are also moved into the second weighing pan 20. The eggs on the second weighing pan 20 are then re-evaluated. If they meet the requirements, they are pushed into the second collection bin 24 by the electric pusher 22; otherwise, the system moves them to the third weighing pan 20 and pushes them into the second collection bin 24 by the electric pusher 22. This completes the egg weighing and distribution process. This application allows for the automatic collection, cleaning, drying, and sorting of eggs, significantly reducing labor costs and increasing production efficiency.
[0029] In this invention, the conveying device 3 includes a conveying device cover 301 located below the elongated hole 2. Several first round rods 302 are rotatably mounted inside the conveying device cover 301. A second partition 303 is installed in the middle of the conveying device cover 301. To prevent the egg from breaking upon impact with the second partition 303, shock-absorbing pads are installed on both sides of the second partition 303. Two first gears 304 are symmetrically fixedly fitted onto the first round rods 302 about the second partition 303. A first chain 305 is fitted between the first gears 304 on the same side. The several first round rods 302 in the middle cooperate with the first gears 304, thereby... The first chain 305 provides effective support. Several connecting rods 306 are connected between the first chains 305 on the same side. One end of the first round rod 302 is driven by a second motor 307 installed on the outer cover 301 of the conveyor. In use, the egg rolls down from the elongated hole 2 between the two first round rods 302. The second motor 307 is started, driving the first round rod 302 to rotate, which in turn drives the first gear 304 to rotate synchronously. The first gear 304 drives the first chain 305 to rotate, thereby causing the first round rod 302 installed on the first chain 305 to start moving, thus moving the egg.
[0030] In this invention, the cleaning device 5 includes a spray pipe 501 installed inside the cleaning chamber 4. Several spray heads 502 are mounted on the spray pipe 501. The spray pipe 501 is connected to a water tank 504 via a connecting pipe 503, and a water pump 505 is mounted on the connecting pipe 503. A drain pipe 506 is installed at the bottom of the cleaning chamber 4. In use, when the eggs move along the mesh conveyor belt 10 to below the cleaning device 5, the water pump 505 is activated. The water pump 505 sprays cleaning water through the spray pipe 501 and the spray heads 502 to clean the eggs on the mesh conveyor belt 10. Wastewater flows out from the drain pipe 506 at the bottom.
[0031] In this invention, the drying device 6 is installed inside the cleaning chamber 4 via an air jet pipe 601. Several air jet nozzles 602 are installed on the air jet pipe 601. The air jet pipe 601 is connected to an air pump 604 via an air supply pipe 603. A heating pipe 605 is provided on the lower side of the air jet pipe 601. The heating pipe 605 is installed on the inner wall of the cleaning chamber 4. When the eggs are moved to the bottom of the drying device 6, the heating pipe 605 is activated, and the air pump 604 is activated at the same time. The gas sprayed by the air pump 604 is heated by the heating pipe 605, and finally the surface of the eggs is dried by the air jet nozzles 602.
[0032] In this invention, the transfer device 13 includes a transfer device bracket 131 located at the end of the cleaning chamber 4. Two second round rods 132 are rotatably installed inside the transfer device bracket 131. Two second gears 133 are sleeved on the second round rods 132. A second chain 134 is sleeved on the same side of the second gears 133. Several fixed posts 135 are connected between the second chains 134. A groove 136 is opened in the middle of the fixed posts 135. One of the second round rods 132 is driven by a third motor 137 installed on the side wall of the transfer device bracket 131. When in use, the third motor 137 is started, and the third motor 137 drives the second gears 133 on the second round rods 132 to rotate. The second chains 134 sleeved on the second gears 133 rotate synchronously, thereby driving the fixed posts 135 to start moving. The eggs will fall one by one into the grooves 136 between the fixed posts 135, and the eggs will be transported one by one. The transport speed needs to be matched with the weighing speed of the eggs, so that the eggs can be continuously weighed without stopping the transport.
[0033] As can be seen from the above technical solution, during use, the eggs slide out from the elongated hole 2 along the bottom of the chicken cage 1 and fall into the gap of the connecting rod 306, which can prevent the eggs from moving during the conveying process. The second motor 307 is started, which drives the first round rod 302 to rotate, and then drives the first gear 304 to rotate synchronously. The first gear 304 drives the first chain 305 to rotate, so that the first round rod 302 installed on the first chain 305 starts to move, thereby moving the eggs until they fall onto the mesh conveyor belt 10. The third motor 137 is started, which drives the drive roller 8 to rotate, thereby moving the mesh conveyor belt 10. As the mesh conveyor belt 10 moves, the water pump 505 is started, and the water pump 505 sprays cleaning water. The spray nozzle 501 sprays water from the spray head 502 to clean the eggs on the mesh conveyor belt 10. When the eggs move to the bottom of the drying device 6, the heating element 605 is activated, and the air pump 604 is activated simultaneously. The air pump 604 dries the surface of the eggs through the air nozzle 602 via the air spray pipe 601. As the mesh conveyor belt 10 moves, the eggs are collected by the guide plate 12, forming a single-pass state. At the same time, the third motor 137 is activated, which drives the second gear 133 on the second round rod 132 to rotate. The second chain 134 fitted on the second gear 133 rotates synchronously, thereby driving the fixed column 135 to start moving. The eggs will fall one by one into the groove 136 between the fixed columns 135, and the eggs are transported one by one. When the egg is transported to the end of the transfer device 13, the first cylinder 15 is activated, which drives the slider 16 forward. Then, the second cylinder 17 is activated, which drives the air chamber 18 forward and downward. When the suction cup 19 contacts the egg, the vacuum pump 26 is activated. The vacuum pump 26 creates a negative pressure in the air chamber 18 through the air supply pipe 2, sucking up the egg. Then, the second cylinder 17 is contracted first, followed by the first cylinder 15. Then, the second cylinder 17 is activated again, and the vacuum pump 26 stops working. The egg is then placed on the weighing pan 20, and the egg begins to be weighed. Before weighing, the weighing pan 20 needs to be set so that the mass range set on the weighing pan 20 increases sequentially. During weighing, if the mass sensed by the first weighing pan 20 is exactly within the set range... If the egg's mass exceeds the set value of the weighing pan 20, the electric push rod 22 is activated, pushing the egg into the first collection bin 24 via the push plate 23. If the egg's mass exceeds the set value of the weighing pan 20, the electric push rod 22 remains stationary. The egg handling process is repeated, but during handling, not only is the egg moved from the groove 136 into the first weighing pan 20, but it is also moved from the first weighing pan 20 into the second weighing pan 20. The eggs on the second weighing pan 20 are then re-evaluated. If they meet the requirements, the electric push rod 22 pushes them into the second collection bin 24. Otherwise, the system moves the eggs to the third weighing pan 20 and pushes them into the second collection bin 24 via the electric push rod 22. This completes one workflow cycle.
[0034] Other embodiments of the present invention will readily occur to those skilled in the art upon consideration of the specification and practice of the invention disclosed herein. The present invention is intended to cover any variations, uses, or adaptations of the invention that follow the general principles of the invention and include common knowledge or customary techniques in the art not disclosed herein. The specification and examples are to be considered exemplary only, and the true scope of the invention is indicated by the claims.
[0035] It should be understood that this utility model is not limited to the precise structure described above and shown in the accompanying drawings, and various modifications and changes can be made without departing from its scope. The embodiments of this utility model described above do not constitute a limitation on the scope of protection of this utility model.
Claims
1. An automated egg collection system for laying hen farming, comprising two symmetrically installed chicken cages (1), characterized in that: The bottom end of the chicken cage (1) has an elongated hole (2), and a conveying device (3) is provided on the lower side of the elongated hole (2). The end of the conveying device (3) is connected to a cleaning chamber (4). A cleaning device (5) and a drying device (6) are installed inside the cleaning chamber (4). A first partition (7) is installed between the cleaning device (5) and the drying device (6). An active roller (8) and a driven roller (9) are rotatably installed at both ends of the bottom of the cleaning chamber (4). A mesh conveyor belt (10) is sleeved between the active roller (8) and the driven roller (9). The active roller (8) is driven by a first motor (11) installed on the outer wall of the cleaning chamber (4). A guide plate (12) is installed on the top of the inner wall of the cleaning chamber (4). A transfer device (13) is connected to the end of the cleaning chamber (4). A weighing device housing (14) is connected to the end of the transfer device (13). A first cylinder (15) is installed on the top of the weighing device housing (14). 15) A slider (16) is connected, the slider (16) is slidably embedded in the top of the weighing device housing (14), a second cylinder (17) is installed on the slider (16), the end of the second cylinder (17) extends into the weighing device housing (14) and an air chamber (18) is installed inside, the air chamber (18) is equipped with several suction cups (19), the air chamber (18) is connected to a vacuum pump (26) through an air supply pipe (25), the vacuum pump (26) The suction cup (19) is installed on the top of the weighing device housing (14). A weighing plate (20) is located below the suction cup (19). A baffle (21) is provided between the weighing plates (20). An electric push rod (22) corresponding to the weighing plate (20) is installed on the side of the weighing device housing (14). A push plate (23) is installed at the end of the electric push rod (22). A collection bin (24) corresponding to the weighing plate (20) is installed at an angle on the opposite side of the electric push rod (22).
2. The automated egg collection system for laying hen farming according to claim 1, characterized in that, The conveying device (3) includes a conveying device cover (301) located below the elongated hole (2). Several first round rods (302) are rotatably installed inside the conveying device cover (301). A second partition (303) is installed in the middle of the conveying device cover (301). Two first gears (304) are symmetrically fixedly sleeved on the first round rods (302) about the second partition (303). A first chain (305) is sleeved between the first gears (304) on the same side. Several connecting rods (306) are connected between the first chains (305) on the same side. One of the first round rods (302) is driven by a second motor (307) installed on the conveying device cover (301).
3. The automated egg collection system for laying hen farming according to claim 1, characterized in that, The cleaning device (5) includes a spray pipe (501) installed inside the cleaning chamber (4), a number of spray heads (502) are installed on the spray pipe (501), the spray pipe (501) is connected to the water tank (504) through a connecting pipe (503), a water pump (505) is installed on the connecting pipe (503), and a sewage pipe (506) is installed at the bottom of the cleaning chamber (4).
4. The automated egg collection system for laying hen farming according to claim 2, characterized in that, The drying device (6) is installed in the air jet pipe (601) inside the cleaning chamber (4). Several air jet nozzles (602) are installed on the air jet pipe (601). The air jet pipe (601) is connected to an air pump (604) through an air supply pipe (603). A heating pipe (605) is provided on the lower side of the air jet pipe (601). The heating pipe (605) is installed on the inner wall of the cleaning chamber (4).
5. The automated egg collection system for laying hen farming according to claim 1, characterized in that, The transfer device (13) includes a transfer device bracket (131) located at the end of the cleaning chamber (4). Two second round rods (132) are rotatably installed inside the transfer device bracket (131). Two second gears (133) are sleeved on the second round rods (132). A second chain (134) is sleeved on the same side of the second gears (133). Several fixed columns (135) are connected between the second chains (134). A groove (136) is opened in the middle of the fixed column (135). One of the second round rods (132) is driven by a third motor (137) installed on the side wall of the transfer device bracket (131).
6. The automated egg collection system for laying hen farming according to claim 1, characterized in that, The number of suction cups (19) is three.
7. The automated egg collection system for laying hen farming according to claim 1, characterized in that, The weighing pan (20) is provided with a circular groove corresponding to the shape of an egg.
8. An automated egg collection system for laying hen farming according to claim 2, characterized in that, The second partition (303) has shock-absorbing pads installed on both sides.