Livestock breeding greenhouse
By installing upper and lower water tanks in livestock breeding sheds and using a water-air dual-purpose pump to regulate light and temperature and generate white noise, the problems of light, temperature and noise control have been solved, improving the growth and health of livestock.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- HAINAN BOTAI AGRI DEV CO LTD
- Filing Date
- 2024-09-30
- Publication Date
- 2026-06-26
Smart Images

Figure CN119111400B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of livestock breeding technology, and in particular to a livestock breeding shed. Background Technology
[0002] In livestock farming, greenhouses serve as crucial breeding environments, and the control of light, temperature, and noise directly impacts the growth rate, health, and production efficiency of livestock. This is especially true during the brooding stage of young animals, where careful control of environmental conditions such as light, temperature, and noise is paramount. Insufficient light can lead to slow growth and poor development, while excessive light can cause stress and affect health. Temperatures that are too high or too low can also cause slow growth, weakened immunity, and even disease in young poultry and livestock, while noise can disrupt their sleep. Summary of the Invention
[0003] In view of the above-mentioned prior art, the present invention provides a livestock breeding shed that absorbs sunlight by aerating the water tank, thereby regulating the temperature and light intensity inside the shed. At the same time, the white noise generated by the bubbles can promote the sleep of livestock.
[0004] To achieve the above objectives, the technical solution of this invention is implemented as follows:
[0005] A livestock breeding shed includes a shed body, an upper water tank at the top of the shed body, and a lower water tank at the bottom of the shed body. The bottom of the upper water tank has several first pipes with several through holes, and the first pipes are connected to second pipes. The second pipes are connected to a water-air dual-purpose pump located in the lower water tank, and the second pipes have valves. The lower and upper water tanks are filled with sterilized transparent or semi-transparent liquids. The top of the upper water tank has a third pipe connected to the top of the lower water tank.
[0006] Furthermore, the upper water tank, lower water tank, first pipe, second pipe, and third pipe constitute a closed cavity, which is a sterile environment, and the cavity is connected to a sterile elastic breathing canister.
[0007] Furthermore, the water-air dual-purpose pump is fixed inside the lower water tank; when the liquid in the lower water tank enters the upper water tank, such that the distance between the liquid level and the top surface of the upper water tank is less than 1-2 cm, the liquid level in the lower water tank is lower than the fluid inlet of the water-air dual-purpose pump.
[0008] Furthermore, a light intensity sensor is installed inside the greenhouse body, the light intensity sensor is connected to the controller, and the controller is connected to the water-air dual-purpose pump.
[0009] Furthermore, the lower water tank is equipped with an underwater electric telescopic rod, the water-air dual-purpose pump is connected to the underwater telescopic rod, and the underwater electric telescopic rod is signal-connected to the controller.
[0010] Furthermore, a temperature sensor is installed inside the greenhouse body, and the temperature sensor is signal-connected to the controller.
[0011] Furthermore, the greenhouse body is fixed to the ground, the water tank is located below the ground, and the top surface of the water tank forms a support surface for livestock.
[0012] Furthermore, a support beam is provided below the top surface of the lower water tank.
[0013] The beneficial effects of this invention are as follows: A dual-purpose water-air pump pumps water into the upper water tank, raising the liquid level and thus regulating the amount of light entering the greenhouse. The pump also pumps gas into the upper water tank, which exits through the opening in the first pipe, forming numerous bubbles. These tiny bubbles scatter sunlight as they rise, creating a dynamic light barrier that effectively regulates the intensity of light entering the greenhouse. The formation of bubbles in the upper water tank promotes the absorption of solar radiation by the liquid. As a natural heat storage medium, the liquid allows heat accumulated during the day to be released into the greenhouse at night through natural convection or additional heat exchange devices, providing a suitable heating environment for livestock. Furthermore, the aeration process promotes internal convection within the liquid, improving heat exchange efficiency. The continuous, subtle sound of bursting bubbles during aeration creates a natural white noise environment, helping to mask external noise and providing a quieter, more conducive sleeping environment for livestock, thereby promoting their healthy growth. Attached Figure Description
[0014] Figure 1 This is a schematic diagram of the structure of a livestock breeding shed in an embodiment of this application;
[0015] Explanation of icon numbers:
[0016] 1. Greenhouse body; 2. Upper water tank; 3. Lower water tank; 4. First pipe; 5. Through hole; 6. Second pipe; 7. Water-air dual-purpose pump; 8. Valve; 9. Third pipe; 10. Flexible breathing canister; 11. Linear strength sensor; 12. Controller; 13. Underwater electric telescopic rod; 14. Temperature sensor; 15. Support beam. Detailed Implementation
[0017] The technical solution of the present invention will be further described in detail below with reference to the accompanying drawings and specific embodiments. Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention pertains. The terminology used in this specification is for the purpose of describing particular embodiments only and is not intended to limit the invention. In the following description, the expression "some embodiments" refers to a subset of all possible embodiments; however, it should be understood that "some embodiments" can be the same subset or different subsets of all possible embodiments and can be combined with each other without conflict.
[0018] It should also be noted that when an element is referred to as being "fixed to" another element, it can be directly attached to the other element or there may be an intervening element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or there may be an intervening element. The terms "vertical," "horizontal," "inner," "outer," "left," "right," and similar expressions used herein are for illustrative purposes only and do not represent the only possible implementation.
[0019] Please refer to the attached document. Figure 1 This application provides a livestock breeding shed, including a shed body 1. The upper part of the shed body 1 is provided with an upper water tank 2, and the bottom of the shed body 1 is provided with a lower water tank 3. The bottom of the upper water tank 2 is provided with a plurality of first pipes 4, and the first pipes 4 are provided with a plurality of through holes 5. The first pipes 4 are connected to second pipes 6. The second pipes 6 are connected to a water-air dual-purpose pump 7 located in the lower water tank 3. The second pipes 6 are provided with valves 8. The lower water tank 3 and the upper water tank 2 are filled with sterilized transparent or semi-transparent liquid. The top of the upper water tank 2 is provided with a third pipe 9, and the third pipe 9 is connected to the top of the lower water tank 3.
[0020] The upper water tank 2 and the lower water tank 3 are interconnected. A water-air dual-purpose pump 7 can be used to pump liquid and gas from the lower water tank 3 into the upper water tank 2, while gas from the upper water tank 2 can flow into the lower water tank 3 through the third pipe 9. After the water-air dual-purpose pump 7 stops working, the liquid in the upper water tank 2 can be allowed to flow back into the lower water tank 3 through the first pipe 4 and the second pipe 6 by opening valve 8, or the liquid in the upper water tank 2 can be prevented from flowing back into the lower water tank 3 by closing valve 8.
[0021] The top of the greenhouse body 1 can be supported by a light-transmitting material, or the top of the greenhouse can have light-transmitting holes. Sunlight passes through these holes and then through the upper water tank 2 into the greenhouse body 1. Alternatively, the upper water tank 2 can be the top of the greenhouse body 1. A water-air pump 7 pumps water into the upper water tank 2, raising the liquid level and thus regulating the amount of light entering the greenhouse body 1. The water-air pump 7 also pumps gas into the upper water tank 2. The gas exits through the through-hole 5 of the first pipe 4, forming several bubbles. These tiny bubbles scatter sunlight as they rise, creating a dynamic light barrier that effectively regulates the intensity of light entering the greenhouse. The bubbles formed in the upper water tank 2 promote the absorption of solar radiation by the liquid. As a natural heat storage medium, the liquid allows heat accumulated during the day to be released into the greenhouse at night through natural convection or additional heat exchange devices, providing a suitable heating environment for livestock. Furthermore, the aeration process promotes internal convection within the liquid, improving heat exchange efficiency. The continuous, subtle sound of bubbles bursting during aeration creates a natural white noise environment, which helps to mask external noise and provides livestock with a quieter, more restful sleeping environment, thereby promoting their healthy growth.
[0022] Specifically, the upper water tank 2, lower water tank 3, first pipe 4, second pipe 6, and third pipe 9 constitute a closed cavity, which provides a sterile environment. This cavity is connected to a sterile, flexible breathing canister 10. Sterilization is achieved by adding a sterilizing agent or using high temperature or ultraviolet light, ensuring a sterile environment within the cavity and the flexible breathing canister 10. This prevents the formation of a bacterial film on the inner surface during prolonged use and maintains high light transmittance. The cavity is connected to the flexible breathing canister 10, allowing for pressure release during thermal expansion and contraction. The flexible breathing canister 10 is an elastic canister.
[0023] Specifically, the water-air dual-purpose pump 7 is fixed inside the lower water tank 3. When the liquid in the lower water tank 3 enters the upper water tank 2, such that the distance between the liquid level and the top surface of the upper water tank 2 is less than 1-2 cm, the liquid level in the lower water tank 3 is lower than the fluid inlet of the water-air dual-purpose pump 7. The water-air dual-purpose pump 7 pumps water from the lower water tank 3 to the upper water tank 2, and the light transmittance is adjusted by changing the liquid level in the upper water tank 2. When the liquid level in the upper water tank 2 is less than 1-2 cm from the top surface, the liquid level in the lower water tank 3 is lower than the fluid inlet of the water-air dual-purpose pump 7. At this time, the gas in the lower water tank 3 enters the water-air dual-purpose pump 7, and the gas is discharged from the bottom of the upper water tank 2, thereby forming several bubbles. The generated tiny bubbles scatter sunlight during their ascent, forming a dynamic light barrier, further regulating the light intensity entering the greenhouse.
[0024] Specifically, a light intensity sensor 11 is installed inside the greenhouse body 1. The light intensity sensor 11 is connected to a controller 12, and the controller 12 is connected to the water-air dual-purpose pump 7. The light intensity sensor 11 detects the light intensity inside the greenhouse body 1 and transmits the detected signal to the controller 12. The controller 12 adjusts the operation of the water-air dual-purpose pump 7 according to the light intensity.
[0025] Specifically, the lower water tank 3 is equipped with an underwater electric telescopic rod 13, the water-air dual-purpose pump 7 is connected to the underwater telescopic rod, and the underwater electric telescopic rod 13 is signal-connected to the controller 12. The raising and lowering of the underwater telescopic rod is adjusted according to the light intensity, thereby controlling the conditions for bubble formation, allowing bubbles to form when the liquid level in the upper water tank 2 is low. When the light intensity is low, the liquid level in the upper water tank 2 can be lowered while simultaneously generating bubbles, creating a natural white noise environment with the continuous and subtle sound of bubble bursting.
[0026] Specifically, a temperature sensor 14 is installed inside the greenhouse body 1, and the temperature sensor 14 is connected to the controller 12 via a signal. The temperature sensor 14 detects the temperature inside the greenhouse body 1. When the temperature is high, the amount of bubbles and the liquid level in the upper water tank 2 are increased; when the temperature is low, the amount of bubbles and the liquid level in the upper water tank 2 are decreased.
[0027] Specifically, the greenhouse body 1 is fixed to the ground, and the water tank 3 is located below the ground. The top surface of the water tank 3 forms a support surface for the livestock. The heat stored in the water tank 3 can be slowly released to warm the livestock. By adjusting the water level in the water tank 3, the efficiency of heating the livestock can be adjusted, thereby regulating the perceived temperature of the livestock.
[0028] Specifically, a support beam 15 is provided below the top surface of the lower water tank 3. This increases the strength of the top surface of the lower water tank 3 and effectively supports the livestock above it.
[0029] The above are merely specific embodiments of the present invention, but the scope of protection of the present invention is not limited thereto. Any variations or substitutions that can be easily conceived by those skilled in the art within the technical scope disclosed in the present invention should be included within the scope of protection of the present invention. The scope of protection of the present invention should be determined by the scope of the claims.
Claims
1. A livestock breeding shed, characterized in that, The system includes a greenhouse body, an upper water tank at the top of the greenhouse body, and a lower water tank at the bottom of the greenhouse body. The bottom of the upper water tank has several first pipes with several through holes. The first pipes are connected to second pipes, which are connected to a water-air dual-purpose pump located in the lower water tank. The water-air dual-purpose pump pumps gas into the upper water tank, and the gas exits through the through holes of the first pipes, forming several bubbles. The second pipe has a valve. The lower and upper water tanks are filled with sterilized transparent or semi-transparent liquid. The top of the upper water tank has a third pipe connected to the top of the lower water tank.
2. The livestock breeding shed according to claim 1, characterized in that, The upper water tank, lower water tank, first pipe, second pipe, and third pipe constitute a closed cavity, which is a sterile environment. The cavity is connected to a sterile elastic breathing canister.
3. The livestock breeding shed according to claim 1, characterized in that, The water-air dual-purpose pump is fixed inside the lower water tank; when the liquid in the lower water tank enters the upper water tank, such that the distance between the liquid level and the top surface of the upper water tank is less than 1~2CM, the liquid level in the lower water tank is lower than the fluid inlet of the water-air dual-purpose pump.
4. The livestock breeding shed according to claim 1, characterized in that, The greenhouse body is equipped with a light intensity sensor, which is connected to a controller, and the controller is connected to the water-air dual-purpose pump.
5. A livestock breeding shed according to claim 4, characterized in that, The lower water tank is equipped with an underwater electric telescopic rod, the water-air dual-purpose pump is connected to the underwater telescopic rod, and the underwater electric telescopic rod is signal-connected to the controller.
6. A livestock breeding shed according to claim 4 or 5, characterized in that, The greenhouse body is equipped with a temperature sensor, which is connected to the controller via a signal.
7. A livestock breeding shed according to claim 1, characterized in that, The greenhouse body is fixed to the ground, the water tank is located below the ground, and the top surface of the water tank forms a support surface for livestock.
8. A livestock breeding shed according to claim 7, characterized in that, A support beam is provided below the top surface of the lower water tank.