CN219894250U

CN219894250U - Poultry house temperature compensating device

Info

Publication number: CN219894250U
Application number: CN202321583956.XU
Authority: CN
Inventors: 李静研; 于洪超; 丁世哲
Original assignee: Kaiyuan Shengyuan Bird Breeding Co ltd
Current assignee: Kaiyuan Shengyuan Bird Breeding Co ltd
Priority date: 2023-06-20
Filing date: 2023-06-20
Publication date: 2023-10-27
Anticipated expiration: 2033-06-20

Abstract

The utility model relates to a poultry house temperature compensating device which comprises a ground compensating unit, an air inlet unit, a manifold unit, a temperature compensating cavity and a control unit, wherein the ground compensating unit is arranged outside the poultry house, the ground compensating unit is sequentially provided with a first vertical shaft and a second vertical shaft, a communicated transverse pipeline is arranged between the first vertical shaft and the second vertical shaft, the air inlet unit is in pipeline type communication with the manifold unit through the ground compensating unit and the temperature compensating cavity, and the control unit is respectively and electrically connected with the ground compensating unit, the air inlet unit, the manifold unit and the temperature compensating cavity. The branch manifolds of the manifold units are uniformly distributed on the ground of the poultry house, and the uniformity of air supply from bottom to top is excellent on the ground of each part in the poultry house; and the air that the manifold unit sent into the poultry house can be cooled through the ground compensation unit and the temperature compensation cavity, so that the poultry house can be still subjected to effective emergency cooling after the cooling equipment is damaged in summer, and the emergency cooling in summer is good in regulation.

Description

Poultry house temperature compensating device

Technical Field

The utility model belongs to the technical field of poultry houses, and particularly relates to a poultry house temperature compensating device.

Background

In recent years, with the continuous improvement of living standard, the market demand of poultry is continuously increasing. Nowadays, the raising of poultry in a poultry house is more intensive, and the temperature in the poultry house is generally regulated and controlled by air conditioning equipment or water curtain, boiler heating and other modes, so that the bred animals in the poultry house are in a more proper temperature environment. Xia Tianshi when the temperature of the poultry house is increased to 32-40 ℃, birds with high concentration in the poultry house are extremely easy to die in a large area within a few hours or more than ten hours.

In general, the walls and the roof of the poultry house are provided with ventilation and exhaust windows or hoods and the like for ventilation and ventilation, and an air conditioner or a water curtain device is generally arranged on the walls on one side around the poultry house. However, the poultry house is blocked by objects such as a cage frame, and the structural form of side wall air supply is difficult to uniformly supply cool air to all positions in the poultry house, so that the uniformity of air supply is extremely poor; in addition, in summer, wen Tianqi is high, and once the refrigerating equipment of the poultry house air conditioner or the water curtain device is damaged, the temperature in the poultry house can be quickly increased, and the emergency regulation of the temperature in the poultry house is poor.

Disclosure of Invention

The utility model provides a temperature compensating device for a poultry house, which aims to improve the uniformity of air supply to all parts in the poultry house, ensure that the temperature in the poultry house can be quickly adjusted in an emergency when a refrigerating device is damaged by faults in summer, and quickly cool the poultry house.

The technical scheme adopted for solving the technical problems is as follows: a poultry house temperature compensating device, comprising:

the ground repair unit is arranged outside the poultry house and is sequentially provided with a first vertical shaft and a second vertical shaft, and a communicated transverse pipeline is arranged between the first vertical shaft and the second vertical shaft;

the air inlet unit is arranged on the wellhead of the first vertical shaft of the ground supplementing unit in a pipeline communication mode;

a manifold unit disposed in a lower portion of the poultry house and in pipelined communication with the second shaft of the compensator unit, the manifold unit including a main pipe and a branch manifold;

the temperature compensation cavity is communicated with a main pipe of the manifold unit in a pipeline type, a heat insulation layer wall is arranged outside the temperature compensation cavity, and a heat exchange meson, an electric heating wire and a refrigerating coil component are respectively arranged in the temperature compensation cavity;

the control unit is arranged inside the poultry house and is respectively and electrically connected with the ground supplementing unit, the air inlet unit, the manifold unit and the temperature supplementing cavity.

Preferably, water level sensors are arranged in the first vertical shaft and the second vertical shaft of the ground supplementing unit, the first vertical shaft and the second vertical shaft are communicated through the horizontal pipeline, and floating pipe orifices are arranged at two ends of the horizontal pipeline.

Preferably, the floating pipe orifice in the first vertical shaft is arranged at the upper part of the liquid level, and the floating pipe orifice in the second vertical shaft is arranged at the lower part of the liquid level by 1cm to 5cm.

Preferably, the wellhead of the second vertical shaft is in a sealed airtight shape, the main pipe of the manifold unit is communicated with the second vertical shaft, and the communicating position of the main pipe and the second vertical shaft is higher than the liquid level in the second vertical shaft.

Preferably, the branch manifolds are multiple, the lower ends of the branch manifolds are all in pipeline type communication with the main pipe, and the other ends of the branch manifolds are arranged on the ground in the poultry house and are uniformly distributed.

Preferably, a curtain net and an axial flow fan are sequentially arranged in the main pipe, a return blocking cover is arranged at one tail end in the poultry house of the branch manifold, and an air outlet channel and a rotary dial valve plate are arranged on the return blocking cover.

Preferably, the axial flow fan is arranged at the tail end of the main pipe, the control unit controls the axial flow fan to start, and air sequentially passes through the first vertical shaft, the transverse pipeline, the second vertical shaft, the main pipe, the temperature compensating cavity and the branch manifold after entering from the air inlet unit, and finally is sent into the poultry house through the branch manifold.

Preferably, the air inlet unit is provided with an air inlet, a baffle plate, a screen window and an air filter screen are sequentially arranged outside the air inlet, an inner anemometer is arranged in the air inlet unit, and the anemometer is electrically connected with the control unit.

Preferably, the air inlet unit, the first vertical shaft and the second vertical shaft of the ground repair unit, the temperature repair cavity and the poultry house are all provided with temperature sensors, and a plurality of temperature sensors are all electrically connected with the control unit.

The beneficial effects of the utility model are as follows: the branch manifolds of the manifold units are uniformly distributed on the ground of the poultry house to uniformly blow air into the poultry house, the uniformity of blowing air into the poultry house on the ground is excellent, the air in the poultry house can be cooled through the first vertical shaft, the second vertical shaft and the temperature supplementing cavity of the ground supplementing unit, the air blown into the poultry house is ensured to be cool air flow, the cooling regulation and control of the poultry house which can still be carried out for emergency after the refrigeration equipment is damaged in high temperature in summer is effectively ensured, and the emergency cooling performance in summer is good. In addition, the cooler air flow in the ground blown out from the manifold unit into the poultry house can help reduce the temperature in the poultry house, reduce the consumption of traditional refrigeration electric energy and reduce the electricity cost.

Drawings

FIG. 1 is a schematic diagram of a front view of an embodiment of the present utility model;

FIG. 2 is a partially enlarged schematic construction of FIG. 1 in accordance with an embodiment of the utility model;

FIG. 3 is a schematic diagram of a temperature compensating cavity according to an embodiment of the present utility model;

FIG. 4 is a schematic diagram of the front view of a reverse plug according to an embodiment of the present utility model;

FIG. 5 is a schematic top-down appearance of FIG. 4 in accordance with an embodiment of the utility model;

FIG. 6 is a schematic cross-sectional view taken along A-A of FIG. 4 in accordance with an embodiment of the present utility model;

FIG. 7 is a schematic diagram of the structural principles of FIG. 6 in accordance with an embodiment of the present utility model;

FIG. 8 is a schematic diagram of the flow direction of an air flow of an embodiment of the present utility model;

in the figure: 1 poultry house, 11 ventilation hood, 2 ground supplement unit, 21 first vertical shaft, 211 water level sensor, 22 second vertical shaft, 221 liquid level, 23 horizontal pipeline, 231 floating pipe orifice, 232 corrugated pipe, 3 air inlet unit, 31 air inlet, 32 baffle plate, 33 screen window, 34 air filter screen, 35 anemometer, 4 manifold unit, 41 main pipe, 411 curtain net, 412 axial fan, 42 branch manifold, 43 back cover, 431 air outlet channel, 432 rotary dial valve plate, 5 temperature supplement cavity, 51 heat insulation layer wall, 511 check valve, 52 heat exchange meson, 53 electric heating wire, 54 refrigeration coil assembly, 6 control unit, 61 temperature sensor.

Detailed Description

The technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model, and it should be understood that the preferred embodiments described herein are only for illustrating and explaining the present utility model, not for limiting the present utility model, and obviously, the described embodiments are only some embodiments of the present utility model, not all embodiments. The components of the embodiments of the present utility model generally described and illustrated in the figures herein may be arranged in a variety of different configurations. All other embodiments, which can be made by a person skilled in the art without making any inventive effort, are intended to be within the scope of the present utility model. In the embodiments, the components of the embodiments of the present utility model generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the utility model, as presented in the figures, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model.

In the description of the present utility model, it should be noted that the terms "center," "upper," "lower," "left," "right," "vertical," "horizontal," "inner," "outer," "front," "rear," and the like indicate an azimuth or a positional relationship based on that shown in the drawings, and are merely for convenience of description and to simplify the description, but do not indicate or imply that the apparatus or elements to be referred to must have a specific azimuth, be configured and operated in a specific azimuth, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; may be a mechanical connection; may be an electrical connection; can be connected by a hydraulic oil way; 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 will be understood in specific cases by those of ordinary skill in the art.

Referring to fig. 1 to 8, an aspect of the present utility model provides a poultry house temperature compensating apparatus, comprising: a poultry house 1, a ground supplementing unit 2, an air inlet unit 3, a manifold unit 4, a temperature supplementing cavity 5 and a control unit 6.

Hereinafter, a partial structure and principle of the above-described components according to the present temperature compensating device will be described in detail.

As an example, as shown in fig. 1, 2 and 8, the ceiling of the poultry house 1 is uniformly distributed with an automatically ventilated hood 11 made of white steel for exhausting the air flow in the poultry house 1 from the upper ceiling to the outside. The ground supplement unit 2 is arranged outside the poultry house 1 and underground, the ground supplement unit 2 comprises a first vertical shaft 21, a second vertical shaft 22 and a transverse pipeline 23, the first vertical shaft 21 and the second vertical shaft 22 are both water-well-shaped and are arranged underground, water level sensors 211 can be arranged in the first vertical shaft 21 and the second vertical shaft 22 of the ground supplement unit 2, and are used for monitoring water levels in the two shafts in real time and transmitting water level data information to the control unit 6, the first vertical shaft 21 and the second vertical shaft 22 are communicated through the transverse pipeline 23, the transverse pipeline 23 is in a horizontal or inclined pipeline shape, and the transverse pipeline 23 can be arranged above the water level 221 in the first vertical shaft 21 or the second vertical shaft 22; both ends of the horizontal pipeline 23 can be provided with a floating pipe orifice 231 and a corrugated pipe 232, wherein the floating pipe orifice 231 is in a floating shape capable of floating, the center of the floating pipe orifice 231 is in a metal pipe shape, the corrugated pipe 232 is a telescopic nonmetallic pipe, and the floating pipe orifice 231 is communicated with the horizontal pipeline 23 through the corrugated pipe 232.

In an embodiment, one end of the horizontal pipe 23 in the first shaft 21 may be provided with the floating pipe orifice 231 and the bellows 232, the metal pipe of the floating pipe orifice 231 in the first shaft 21 may have a U-shape, and the pipe orifice of the floating pipe orifice 231 may float above the liquid surface 221 in the first shaft 21, preventing water in the first shaft 21 from entering the floating pipe orifice 231 on the side; the U-shaped heat exchange metal pipe of the floating pipe orifice 231 in the first shaft 21 may be placed in water, and may exchange heat with the air flow in the pipe. The other end of the horizontal pipe 23 in the second shaft 22 may be provided with the floating pipe orifice 231 and the bellows 232, the floating pipe orifice 231 in the second shaft 22 may be inserted into the water in the well, and the floating pipe orifice 231 in the second shaft 22 may be placed at a lower portion of the liquid surface 221 of the second shaft 22 by 1cm to 5cm. The well head department on the ground of first shaft 21 is provided with air inlet unit 3, the well head of second shaft 22 is filled with earth or the airtight form of heat preservation laminar, and manifold unit 4 is arranged in the lower part of birds house 1, second shaft 22 pass through manifold unit 4 with birds house 1 carries out pipeline formula intercommunication, manifold unit 4 with the mouth of pipe of the lateral wall intercommunication department of second shaft 22 is higher than liquid level 221 in the second shaft 22. Outdoor air can enter the first vertical shaft 21 through the air inlet unit 3, and flows into the second vertical shaft 22 through the transverse pipeline 23 after heat exchange of well water, and air flow in the second vertical shaft 22 enters the manifold unit 4 and is sent into the poultry house 1 after heat exchange of well water again. The air inlet unit 3 comprises an air inlet 31, a baffle plate 32, a screen window 33, an air filter screen 34 and an anemometer 35, the air inlet unit 3 can be in a square airtight building shape built by bricks and cement, the air inlet 31 can be arranged on a vertical wall of the air inlet unit 3, and the air inlet 31 is communicated with the first vertical shaft 21; the outermost side of the air inlet 31 can be provided with the baffle plate 32, the baffle plate 32 can be in a louver-shaped bar hole shape, a large object can be blocked, the screen 33 made of white steel is arranged on the inner side of the baffle plate 32, the air filter screen 34 is arranged on the inner side of the screen 33, the baffle plate 32, the screen 33 and the air filter screen 34 can be arranged outdoors to protect the air inlet 31 from sundries blocking the air inlet 31, the air inlet unit 3 is internally provided with an inner anemometer 35, and the anemometer 35 transmits wind speed data information of the air inlet 31 to the control unit 6.

As an example, as shown in fig. 1, 2, 3, 4, 5, 6, 7 and 8, the manifold unit 4 includes a main pipe 41, a branch manifold 42 and a back cover 43, where a metal screen window type curtain 411 and an axial flow fan 412 are installed in the main pipe 41, the axial flow fan 412 is disposed at the end of the main pipe 41, the main pipe 41 is in a thick pipe shape, the branch manifold 42 is in a plurality of thin pipes shapes, one end of the main pipe 41 is in pipeline type communication with the second shaft 22, and a plurality of branch manifolds 42 are all in pipeline type communication connection with the other end of the main pipe 41; the outer ends of the branch manifolds 42 are uniformly arranged on the ground in the poultry house 1, and can also be arranged in a drainage tank of the poultry house 1, and the outlets of the branch manifolds 42 can be higher than the bottom of the drainage tank and lower than floor drain grate on the indoor ground of the poultry house 1, so that the branch manifolds 42 can be used for discharging air and cannot be higher than the ground of the poultry house 1; or the outer ends of the plurality of branch manifolds 42 are uniformly disposed at predetermined positions within the poultry house 1, above the ground of the poultry house 1 but not disposed on the walking area; the outer ends of the branch manifolds 42 are respectively provided with the blocking-back cover 43, and the blocking-back covers 43 prevent foreign matters from entering the branch manifolds 42; the air outlet channel 431 and the rotary dial valve plate 432 are arranged on the back plug cover 43, the air outlet channel 431 is uniformly distributed on the outer side wall of the back plug cover 43, the rotary dial valve plate 432 is arranged in the back plug cover 43 through a sealed rubber pad, and air outlets uniformly distributed on the rotary dial valve plate 432 and air outlets uniformly distributed in the back plug cover 43 can be closed or communicated, so that the back plug cover 43 can enable the air outlet channel 431 to be opened or closed through the rotary dial valve plate 432. The control unit 6 may control the axial flow fan 412 to start, and air passes through the first shaft 21, the horizontal pipeline 23, the second shaft 22, the main pipe 41 and the branch manifold 42 in sequence after entering from the air inlet unit 3, and finally is sent into the poultry house 1 by the branch manifold 42.

In an embodiment, a temperature compensating cavity 5 may be disposed at the lower part of the ground of the poultry house 1, the temperature compensating cavity 5 may be connected in series to the main pipe 41 for pipeline type communication, a check valve 511 for an air passage of a submarine brand may be added at a position where the main pipe 41 is connected with the temperature compensating cavity 5, the temperature compensating cavity 5 is in a closed cavity shape, a heat insulating layer wall 51 is disposed outside the temperature compensating cavity 5, the heat insulating layer wall 51 may be made of a polymer material with good water resistance and good heat insulation, heat exchange mesons 52 are disposed in the temperature compensating cavity 5, the heat exchange mesons 52 may be water, a liquid level of the heat exchange mesons 52 is disposed below the main pipe 41, an electric heating wire 53 and a refrigeration coil assembly 54 may be disposed in the heat exchange mesons 52, the electric heating wire 53 may be an electric heating rod, and the refrigeration coil assembly 54 may be a pipeline of a compressor refrigeration system; the control unit 6 may be disposed in an electrical box inside the poultry house 1, and the control unit 6 may be electrically connected to the electrical components in the ground repair unit 2, the air intake unit 3, the manifold unit 4, and the temperature repair cavity 5, respectively; the air inlet unit 3, the first shaft 21 and the second shaft 22 of the ground repair unit 2, the temperature repair cavity 5 and the poultry house 1 can be provided with temperature sensors 61, and a plurality of temperature sensors 61 can be electrically connected with the control unit 6.

In an embodiment, when the temperature is below zero in winter, and the poultry house 1 does not heat, the temperature below 2 m of the ground is above zero, the control unit 6 may control the axial flow fan 412 to start, outdoor air may be sucked from the air inlet 31 of the air inlet unit 3 to the first vertical shaft 21, the second vertical shaft 22 and the temperature compensating cavity 5 to perform repeated heat exchange for multiple times, so that the air is warmed, and the warmed air flows out from the branch manifolds 42 evenly distributed on the ground of the poultry house 1 into the poultry house 1, and warms the poultry house 1, so that the poultry house is warmed to about 2 to 10 ℃ and the phenomenon of extremely low temperature of the poultry house 1 is avoided.

In the embodiment, when the temperature is high in summer, the air in the poultry house 1 can be cooled through the first vertical shaft 21, the second vertical shaft 22 and the temperature compensating cavity 5 of the ground compensating unit 2, so that the air blown into the poultry house 1 is ensured to be cool air flow, the temperature in the poultry house 1 can be reduced, the long-time starting of an air conditioner is avoided, the electricity saving performance is good, the consumption of the traditional refrigerating electric energy is reduced, and the electricity consumption cost can be greatly reduced; and compare with the cascade cooling of prior art, the cooling effect of this device is better than the cascade cooling, and is better than the cooling effect of cascade mode to each pipeline is easy to freeze when driven cascade heat sink winter, and this heat sink pipeline is placed underground, can not take place the phenomenon that the pipeline freezes and take place. In addition, in extremely high temperature weather in summer and when the air conditioning equipment fails and needs maintenance, the device can cool the air flow blown into the poultry house 1, the air flow flows out of the ground of the poultry house 1, the original air with higher temperature in the poultry house 1 can rise, the ventilation hood 11 at the upper part of the poultry house 1 is discharged, the fluidity of the air flow is smooth, and the cooling effect on the poultry house 1 is better; the control unit 6 can start auxiliary refrigeration to the refrigeration coil assembly 54 in the temperature supplementing cavity 5 according to the required temperature in the poultry house 1, so that the cooling regulation and control of the poultry house 1 which can be subjected to emergency after the refrigeration equipment is damaged in high temperature in summer is effectively ensured, and the emergency cooling performance in summer is good.

The foregoing is merely illustrative of the present utility model, and the present utility model is not limited thereto, and any person skilled in the art will readily recognize that changes and substitutions are within the scope of the present utility model. Therefore, the protection scope of the utility model should be mainly that of the claims.

Claims

1. A poultry house temperature compensating device, comprising:

2. The poultry house temperature compensating apparatus of claim 1, wherein: the first vertical shaft and the second vertical shaft of the ground repair unit are internally provided with water level sensors, the first vertical shaft and the second vertical shaft are communicated through the horizontal pipeline, and the two ends of the horizontal pipeline are respectively provided with a floating pipe orifice.

3. The poultry house temperature compensating apparatus of claim 2, wherein: the floating pipe orifice in the first vertical shaft is arranged at the upper part of the liquid level, and the floating pipe orifice in the second vertical shaft is arranged at the lower part of the liquid level by 1cm to 5cm.

4. The poultry house temperature compensating apparatus of claim 2, wherein: the wellhead of the second vertical shaft is sealed and airtight, the main pipe of the manifold unit is communicated with the second vertical shaft, and the communicating position of the main pipe and the second vertical shaft is higher than the liquid level in the second vertical shaft.

5. The poultry house temperature compensating apparatus of claim 1, wherein: the branch manifold is a plurality of, and the lower extreme of every branch manifold all with the house steward carries out pipeline formula intercommunication, a plurality of branch manifold's the other end is arranged in the subaerial in the birds house and is even distributed.

6. The poultry house temperature compensating apparatus of claim 5, wherein: the main pipe is internally provided with a curtain net and an axial flow fan in sequence, one tail end of the poultry house of the branch manifold is provided with a return blocking cover, and the return blocking cover is provided with an air outlet channel and a rotary dial valve plate.

7. The poultry house temperature compensating apparatus of claim 6, wherein: the control unit controls the start of the axial flow fan, and air sequentially passes through the first vertical shaft, the transverse pipeline, the second vertical shaft, the main pipe, the temperature compensating cavity and the branch manifold after entering from the air inlet unit and is finally sent into the poultry house by the branch manifold.

8. The poultry house temperature compensating apparatus of claim 7, wherein: the air inlet unit is provided with an air inlet, a baffle plate, a screen window and an air filter screen are sequentially arranged outside the air inlet, an inner anemometer is arranged in the air inlet unit, and the anemometer is electrically connected with the control unit.

9. The poultry house temperature compensating apparatus of claim 1, wherein: the air inlet unit, the first vertical shaft and the second vertical shaft of the ground supplementing unit, the temperature supplementing cavity and the poultry house are all provided with temperature sensors, and a plurality of temperature sensors are electrically connected with the control unit.