CN219710460U

CN219710460U - Water storage system for farm

Info

Publication number: CN219710460U
Application number: CN202321322548.9U
Authority: CN
Inventors: 杜静芳; 易少文; 张小波; 郑建玉; 朱华伟; 高超毅
Original assignee: Muyuan Foods Co Ltd
Current assignee: Muyuan Foods Co Ltd
Priority date: 2023-05-29
Filing date: 2023-05-29
Publication date: 2023-09-19
Anticipated expiration: 2033-05-29

Abstract

The utility model relates to the technical field of livestock breeding, and particularly discloses a water storage system for a farm, which comprises a water storage tank arranged above the ground and a water delivery mechanism for delivering water in the water storage tank into a breeding unit, wherein the water storage tank comprises a water inlet, a water outlet and a sewage outlet, and the water outlet is connected with the water delivery mechanism; the water storage tank is divided into at least 2 compartments, the compartments are respectively connected with the sewage outlet and the water outlet, overflow holes are formed in the compartments, and the overflow holes are used for communicating water in the compartments on two sides of the partition. The utility model can reduce the construction cost of the reservoir, is beneficial to the pollution discharge of the reservoir, and does not influence the water supply in the unit during the pollution discharge.

Description

Water storage system for farm

Technical Field

The utility model belongs to the technical field of livestock breeding, and particularly relates to a water storage system for a farm.

Background

With the improvement of national living standard, the livestock industry in China is greatly developed, and the cultivation level is also continuously improved. The water supply for livestock and poultry is indispensable in the livestock breeding industry, most of water is supplied by a water storage system in the prior art, and the water storage system used in the farm at present generally uses a semi-underground water storage pool, the underground part is 2 meters, the ground is 1.5 meters, and no pollution discharge design exists.

The cistern of this kind of design is when being under construction, because need dig 2 meters down, so need do precipitation construction, and later stage underground part need do waterproof, consequently, prior art's cistern, and not only construction cost is high, and the cistern does not have the blowdown design moreover, uses after a period, needs the manual work to get into the cistern and carries out the blowdown, and still need close water supply system, stops supplying water to the unit in.

Therefore, how to design a reservoir can reduce the construction cost of the reservoir, is beneficial to the pollution discharge of the reservoir, does not influence the water supply in the unit during the pollution discharge, and becomes a relevant subject in the prior art.

Disclosure of Invention

In order to overcome the defects in the prior art, the utility model provides a water storage system for a farm, and solves the problems.

To achieve the above object, the present utility model discloses a water storage system for a farm, comprising:

the reservoir is arranged above the ground and comprises a water inlet for externally connecting a water inlet mechanism;

a partition wall of at least 1 dividing the reservoir into at least 2 compartments;

the water delivery device comprises compartments, wherein each compartment is provided with a sewage outlet and a water outlet, and the water outlet is connected with a water delivery mechanism;

a water feeding mechanism for feeding water in the compartment to a designated location;

and overflow holes are arranged on the partition wall and are used for realizing the intercommunication flow of water in the compartments at two sides of the partition wall.

Compared with the prior art, the utility model has the following effects: compared with the prior art, the reservoir is arranged above the ground, and does not need to be dug deeply below the ground, so that the reservoir does not need to be used for precipitation construction and waterproof treatment, and the construction cost is low; the sewage outlet arranged at the bottom of the water storage tank can timely discharge sewage, sludge and the like at the bottom of the water storage tank out of the water storage tank, so that the sewage does not need to enter the water storage tank manually for sewage discharge; by the design of at least 2 compartments, when one compartment is in blowdown, the other compartment can also continue to supply water into the unit, i.e. blowdown and water supply can be performed simultaneously, without affecting the water supply in the unit.

In addition, the technical scheme provided by the utility model can also have the following technical characteristics:

further, the partition wall is 1, and it will the cistern is divided into 2 compartments, and 2 the compartment is primary sedimentation tank and clean water basin respectively, primary sedimentation tank is connected the water inlet, primary sedimentation tank with the delivery port of clean water basin is all connected water supply mechanism, in order to when the clear water after the water is in primary sedimentation tank deposit is passed through the overflow aperture can get into the clean water basin.

Further, the overflow holes are arranged at the height of the partition wall, which is lower than the set liquid level of the clean water tank.

Further, a liquid level detection mechanism for detecting the liquid level of the clean water tank is arranged in the clean water tank, and the liquid level detection mechanism is electrically connected with a water inlet mechanism for supplying water to the reservoir through the water inlet.

Furthermore, an overflow pipe is arranged at the overflow hole.

Further, the water inlet end of the overflow pipe is wrapped by a nylon net.

Further, the number of overflow pipes is 5.

Furthermore, the primary sedimentation tank and the clean water tank are both provided with an access hole.

Further, the water delivery mechanism comprises a pump room and a centrifugal pump arranged in the pump room, one end of the centrifugal pump is connected with the water outlet through a water outlet pipe, the other end of the centrifugal pump delivers water into each cultivation unit through a water separator, and a water outlet valve is arranged on the water outlet pipe.

Further, the water outlet pipe is a flexible waterproof sleeve.

Further, a drain pipe connected with the drain outlet is pre-buried in the bottom of the reservoir, a drain valve is arranged on the drain pipe, and the drain pipe is externally connected with a drain channel.

Further, the bottom surfaces of the primary sedimentation tank and the clean water tank face the sewage outlet to be inclined with a drainage gradient of 2% -3%.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic illustration of a water storage system for a farm in accordance with an embodiment of the present utility model;

fig. 2 is a cross-sectional view of a reservoir according to an embodiment of the present utility model.

The reference numerals are as follows:

1. a reservoir; 2. a water inlet; 3. a water outlet; 4. a sewage outlet; 5. partition walls; 6. an overflow aperture; 7. a primary sedimentation tank; 8. a clean water tank; 9. an access opening; 10. a pump house; 11. a centrifugal pump; 12. a water outlet pipe; 13. a water separator; 14. a blow-down pipe; 15. a blow-down valve; 16. a water outlet valve; 17. a liquid level float valve.

Description of the embodiments

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1-2, the utility model discloses a water storage system for a farm, which comprises a water storage pool 1 arranged above the ground and a water delivery mechanism for delivering water in the water storage pool 1 into a cultivation unit, wherein the water storage pool 1 comprises a water inlet 2, a water outlet 3 and a sewage outlet 4, and the water outlet 2 is connected with the water delivery mechanism; the water storage tank 1 is divided into at least 2 partition walls 5, the partition walls are respectively connected with the sewage outlet 4 and the water outlet 3, the partition walls 5 are provided with overflow holes 6, and the overflow holes 6 are used for communicating water in the partition walls on two sides of the partition walls 5 to flow.

When in use, water enters one compartment in the reservoir 1 through the water inlet 2, and as the water in the compartment continuously rises, when the water level overflows through the overflow holes 6, the water enters the other corresponding compartment through the overflow holes 6, and on the basis of the principle, the water is contained in the compartment in the reservoir according to the height of the overflow holes 6, and after the water level reaches the water level height of the compartment, the water supply to the reservoir is stopped; when the sewage is discharged or water is sent, as each compartment is provided with the sewage outlet 4 and the water outlet 3, all compartments can be used for discharging sewage and water; wherein, when one compartment is in sewage, the dirt in the compartment can be discharged by only closing the water inlet 2 and opening the sewage outlet 4, and meanwhile, the other compartments can also continue to supply water to the unit.

In connection with the above embodiment, more specifically, a partition wall 5 is selected in the present utility model to divide the reservoir into 2 compartments, namely a primary sedimentation tank 7 and a clean water tank 8. Wherein, the primary sedimentation tank 7 is connected with the water inlet 2, the overflow hole 6 is arranged at the high end of the partition wall 5, external water firstly enters the primary sedimentation tank 7 through the water inlet 2, sediment such as sediment in external water is ensured to be statically precipitated in the primary sedimentation tank 7, and clear water precipitated in the primary sedimentation tank 7 enters the clear water tank 8 through the overflow hole 6 after the water level in the primary sedimentation tank 7 highly overflows the overflow hole 6.

Specifically, the height of the overflow hole 6 arranged at the partition wall 5 is lower than the liquid level set by the clean water tank 8, so that the liquid level in the clean water tank 8 can not exceed a set value, the liquid level is actually the maximum water filling of the reservoir 1, and the height of the overflow hole 6 is slightly lower than the high liquid level. When the normal unit supplies water, the water supply mechanism preferably supplies clear water in the clear water tank 8 to the unit, so that the design prevents the problem of biosafety caused by the fact that sediment such as sediment contained in water is easily supplied into a pig house when the water is directly pumped from the primary sedimentation tank 7; when the clean water tank 8 needs to be drained, the water in the primary sedimentation tank 7 is conveyed to the unit. It should be noted that, in this embodiment, the height of the liquid level set by the clean water tank 8 is 2.8 meters, the higher the overflow hole 6 is, the better the sedimentation effect of the primary sedimentation tank 7 is, the more water is stored in the reservoir 1, but the height of the overflow hole 6 is lower than 2.8 meters.

In the above embodiment, it is more preferable that, in order to ensure that the liquid level in the reservoir 1 is higher than the overflow hole 6, the liquid level heights at both sides of the primary sedimentation tank 7 and the clean water tank 8 are identical, so that the liquid level of the reservoir 1 is prevented from exceeding a specified value, a liquid level detection mechanism for detecting the liquid level of the clean water tank is provided in the clean water tank 8, and the liquid level detection mechanism is electrically connected with a water inlet mechanism for supplying water to the reservoir 1 through the water inlet 2.

More specifically, the liquid level detecting mechanism may be a liquid level ball float valve 17, an electronic liquid level meter, etc., and the water inlet mechanism may include a water pump and a water well, and the water pump sends water in the water well into the reservoir 1 through the water inlet 2. In the embodiment, the liquid level float valve 17 is selected, the liquid level float valve 17 is installed according to the liquid level designed by the water reservoir 1, and the liquid level float valve 17 is electrically connected with a controller for controlling the start and stop of the water pump. When the liquid level in the clean water tank 8 reaches the high liquid level of the liquid level floating ball valve 17, the liquid level floating ball valve 17 sends a signal to the controller, the controller controls the water pump to stop working, namely, water supply to the reservoir 1 is stopped, and at the moment, the liquid levels at the two sides of the primary sedimentation tank 7 and the clean water tank 8 are consistent in height and the liquid level is lower than a specified value; when the water in the clean water tank 8 reaches the low liquid level of the liquid level ball float valve 17, the liquid level ball float valve 17 sends a signal to the controller, and the controller controls the water pump to start working, namely, water supply to the reservoir 1 is started. Therefore, the above process is repeated, so that the water in the clean water tank 8 can be continuously supplied to the unit, and the liquid level height meets the regulation. It should be noted that, the controller is a PLC controller in the prior art, is a digital logic controller for automatic control, can load control instructions into the memory at any time for storage and execution, and is formed by modularizing and combining an internal CPU, an instruction and data memory, an input/output unit, a power module, a digital analog unit and other units, and is widely applied to the field of industrial control, and belongs to the prior art, and the above embodiments are not repeated.

More specifically, the overflow pipe is arranged at the overflow hole 6, and water higher than the overflow hole 6 in the primary sedimentation tank 7 can be rapidly discharged into the clean water tank 8 through the overflow pipe.

In the above embodiment, more preferably, in order to further improve the quality of the clean water in the clean water tank 8, the water inlet end of the overflow pipe is wrapped by a nylon net, and impurities in the water are filtered by the nylon net, so as to improve the quality of the clean water in the clean water tank 8. In the embodiment, the nylon net can be 100 meshes, so that the filtering effect can be ensured, and the flow rate of water can be ensured.

In the above embodiment, more preferably, the number of overflow pipes is 5, and the requirement of 60 square flows in one hour can be met through 5 overflow pipes, so as to meet the design requirement of the reservoir 1.

In connection with the above embodiment, it is more preferable that an access hole 9 is provided on both the primary sedimentation tank 7 and the clean water tank 8 in order to facilitate the maintenance of the reservoir 1.

In the above embodiment, more preferably, the water delivery mechanism includes a pump room 10 and a centrifugal pump 11 disposed in the pump room 10, one end of the centrifugal pump 11 is connected to the water outlet 3 through a water outlet pipe 12, the other end sends water into each cultivation unit through a water separator 13, and a water outlet valve 16 is disposed on the water outlet pipe 12, and the water outlet valve 16 may be a gate valve. Compared with the prior art, the prior art often adopts a submersible pump which is put into the reservoir 1, and the submersible pump feeds the water in the reservoir 1 into the unit; however, because the reservoir 1 often needs to be added with disinfectant, water in the reservoir 1 can corrode the submersible pump, causing failure of the submersible pump, which in turn needs to be frequently maintained, thereby affecting the unit water supply; in the embodiment, the centrifugal pump 11 arranged outside the reservoir 1 is adopted, so that the problem in the prior art is well solved.

In connection with the above embodiment, more specifically, the water outlet pipe 12 is a flexible waterproof sleeve, so that the water outlet pipe 12 is convenient to install.

In the above embodiment, more specifically, the drain pipe 14 connected with the drain outlet 4 is pre-buried at the bottom of the reservoir 1, the drain pipe 14 is provided with the drain valve 15, and the drain pipe 14 is externally connected with the drain canal. Specifically, the dirty water of the reservoir 1 flows to a designated position through the drain 4, the drain pipe 14 and the drain channel. Wherein, the drain pipe can be stainless steel pipe, and the drain valve 15 can be a gate valve.

In the above embodiment, more preferably, in order to improve the sewage draining effect of the primary sedimentation tank 7 and the clean water tank 8, when sewage is drained from the primary sedimentation tank 7 and the clean water tank 8, no water is accumulated at the bottom of the tank, and the bottom of the primary sedimentation tank 7 and the clean water tank 8 is inclined towards the sewage outlet 4 with a drainage gradient of 2% -3%. According to a large number of experiments, the pollution discharge gradient is too small, the flow speed is too low, the problem of incomplete discharge is easy to occur, the gradient is too large, the gradient is more severe, the construction difficulty is increased, the pollution discharge pipe needs to be buried deeper, and the sewage can not be connected into the pollution discharge pipe; therefore, in the embodiment, the water discharge gradient of 3% can be selected, and the water discharge effect is good.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present utility model. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the utility model. Thus, the present utility model is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims

1. A water storage system for a farm, comprising:

2. A water storage system for a farm according to claim 1, wherein the number of the partition walls is 1, the water storage is divided into 2 compartments, the 2 compartments are a primary sedimentation tank and a clean water tank respectively, the primary sedimentation tank is connected with the water inlet, and water outlets of the primary sedimentation tank and the clean water tank are connected with the water delivery mechanism, so that clean water after water is precipitated in the primary sedimentation tank can enter the clean water tank through the overflow holes.

3. A water storage system for a farm according to claim 2, wherein the overflow aperture is provided at a level below the level set by the clean water basin at the level of the partition wall.

4. A water storage system for a farm according to claim 3, wherein a liquid level detection mechanism for detecting the liquid level of the clean water tank is arranged in the clean water tank, and the liquid level detection mechanism is electrically connected with a water inlet mechanism for supplying water to the water storage tank through the water inlet.

5. A water storage system for a farm according to claim 1, wherein the overflow aperture is provided with an overflow pipe.

6. A water storage system for a farm according to claim 5, wherein the water inlet end of the overflow tube is wrapped with nylon mesh.

7. A water storage system for farms according to claim 2, wherein the primary sedimentation tank and the clean water tank are each provided with an access opening.

8. A water storage system for a farm according to claim 1, wherein the water supply mechanism comprises a pump room and a centrifugal pump arranged in the pump room, one end of the centrifugal pump is connected with the water outlet through a water outlet pipe, the other end of the centrifugal pump is used for supplying water into each cultivation unit through a water separator, and a water outlet valve is arranged on the water outlet pipe.

9. The water storage system for a farm according to claim 1, wherein a drain pipe connected with the drain outlet is pre-buried at the bottom of the water storage tank, a drain valve is arranged on the drain pipe, and the drain pipe is externally connected with a drain channel.

10. A water storage system for farms according to claim 2, wherein the bottom of the primary and clean water tanks is inclined at a drain slope of 2% -3% toward the drain.