CN218969042U - Fishing light integrated low-carbon aquaculture farm - Google Patents

Abstract

The utility model discloses a fishing and light integrated low-carbon aquaculture farm, which comprises an aquaculture pond, a photovoltaic assembly, a tail water purification area and a circulating pump, wherein the photovoltaic assembly is arranged above the aquaculture pond, the tail water purification area is arranged on one side of the aquaculture pond, the tail water purification area comprises a sedimentation area, a filtering dam and an ecological pond, the sedimentation area is provided with a mud pipe, the sedimentation area is communicated with the aquaculture pond, the ecological pond is communicated with the aquaculture pond through the circulating pump, and the aquaculture pond Gao Chengda is arranged at the elevation of the tail water purification area. By utilizing the elevation difference between the culture pond and the tail water purifying area, water flows from the culture pond to the tail water purifying area in a self-flowing mode, tail water is purified in the tail water purifying area, the circulating pump is used for communicating the tail water purifying area with the culture pond, so that the water recycling is realized, the problems that in the prior art, the water body pollution caused by artificial feed residues and aquatic excrement affects the aquaculture and the water consumption is large are solved, and the technical effects of purifying the water body of the culture pond and saving water are realized.

Description

Fishing light integrated low-carbon aquaculture farm

Technical Field

The utility model relates to the technical field of aquaculture, in particular to a fishing light integrated low-carbon aquaculture farm.

Background

The 'fishing light integration' refers to a mode of combining aquaculture and photovoltaic power generation industry, namely, when the aquaculture is developed in a pond water body, a photovoltaic panel is erected above the pond to perform solar power generation, so that a new production mode of 'lower fish-farming and upper power generation' is formed; the 'fishing light integration' can fully utilize land and space resources, realize three harvest of fish, electricity and environmental protection, can fully utilize space and save land resources, and the photovoltaic panel utilizes solar power generation to provide required electric energy for aquaculture industry, thereby being beneficial to environmental protection, energy conservation and emission reduction; the photovoltaic panel is erected to effectively reduce the temperature of the pond water area in summer and reduce the illumination intensity, so that the growth of harmful algae in the pond is inhibited, the ammonia nitrogen content in the water area is changed, and the water quality environment of cultivation is improved.

However, in the prior art of 'fishing light integration', problems still exist, and artificial feed residues and aquatic excrement pollute the water body of the aquaculture pond to a certain extent, the polluted water body can influence the aquaculture phase rate, in order to improve the aquaculture efficiency, living water aquaculture can be generally used, the water consumption is too large, the aquaculture cost is increased, and the energy conservation and emission reduction are not facilitated.

Disclosure of Invention

The utility model aims to solve the problems that water pollution affects aquaculture efficiency and water consumption is large in the prior art, and provides a fishing light integrated low-carbon aquaculture farm which can purify water, improve aquaculture water environment, improve aquaculture efficiency, recycle water resources and achieve the effects of saving cost, saving energy and reducing emission.

The utility model adopts the following technical scheme:

the utility model provides a fishing light integrated low-carbon aquaculture farm, which comprises:

an aquaculture pond;

the photovoltaic modules are distributed above the culture pond;

the tail water purification area is arranged on one side of the culture pond and comprises a sedimentation area, a filtering dam and an ecological pond, the sedimentation area is provided with a sludge discharge pipe, the sedimentation area is communicated with the culture pond, a plurality of ecological floating beds are arranged in the ecological pond, and the ecological pond is communicated with the culture pond through a circulating pump;

and the culture pond Gao Chengda is arranged at the elevation of the tail water purifying area.

Preferably, the number of the culture ponds is more than two, the culture ponds are distributed side by side, and soil paths are paved between two adjacent culture ponds.

Preferably, the method further comprises:

a water inlet tank and a water outlet tank;

the water inlet pool is arranged on the other side of the cultivation ponds, opposite to the tail water purification area, and is communicated with each cultivation pond and is controlled to be on-off through a water inlet valve;

the water outlet pool is arranged between the culture ponds and the tail water purification area, is communicated with each culture pond, is controlled to be on-off through a water outlet valve, is arranged on one side of the water outlet pool, and is communicated with the sedimentation area;

and the heights of the water inlet tank, the culture pond, the water outlet tank and the tail water purification area are sequentially reduced.

Preferably, the water inlet tank is also provided with an overflow weir, and the overflow weir is arranged at one side of the water inlet tank, which is communicated with the ecological pond.

Preferably, the method further comprises:

a water inlet pipe and a water outlet pipe;

the water inlet pipe is communicated with the culture pond or the water inlet pool;

the water outlet pipe is communicated with the ecological pond.

Preferably, the connection part of the culture pond and the tail water purifying area or the water outlet pond is also provided with a plurality of blocking nets, and the blocking nets are arranged on one side of the culture pond.

Preferably, the photovoltaic module comprises a supporting rod and a photovoltaic plate, and the power supply room is electrically connected with the photovoltaic plate and the circulating pump.

Preferably, the device further comprises a plurality of water quality sensors, a control box and an aeration device, wherein the water quality sensors are arranged at one end of the support rods below the water surface of the culture pond, the control box is arranged at one end of the support rods above the water surface of the culture pond, the aeration device is arranged at one end of the support rods below the water surface of the culture pond, and the water quality sensors, the control box, the aeration device and the power supply room are electrically connected.

Preferably, the culture pond also comprises a plurality of isolation nets, wherein the isolation nets are fixedly arranged in the culture pond and are arranged on the periphery of the support rods, and the heights of the isolation nets are at least equal to the water level of the culture pond.

Preferably, the power supply system further comprises a control room, wherein the control room is electrically connected with the power supply room and the plurality of control boxes.

Compared with the prior art, the utility model has the following beneficial effects:

according to the utility model, the tail water purification area comprising the sedimentation area, the filtering dam and the ecological pond is arranged, the sedimentation area is utilized to sediment artificial feed residues and aquatic excrement, sediment is periodically discharged through the mud discharging pipe of the sedimentation area, suspended matters and colloid in water are removed by the filtering dam, and nitrogen and phosphorus nutritive salt in the water body is absorbed by the ecological pond, so that nutritive substances in the water body are consumed; by arranging the culture pond Gao Chengda at the elevation of the tail water purification area, water can flow from the culture pond to the tail water purification area in a self-flowing mode; the tail water purification area and the aquaculture pond are communicated through the circulating pump, so that water recycling is realized, the problems that in the prior art, the aquaculture and the water consumption are large due to the fact that artificial feed residues and aquatic excrement pollute the water are effectively solved, and then the technical effects of purifying the water body of the aquaculture pond and saving water are realized.

Drawings

The following drawings are merely corresponding to some of the embodiments of the present utility model and are not intended to be drawn to scale. In the drawings, each identical or nearly identical component that is illustrated in various figures may be represented by a like numeral. For purposes of clarity, not every component may be labeled in every drawing. Embodiments of various aspects of the utility model will now be described, by way of example, with reference to the accompanying drawings, in which:

fig. 1 is a schematic top view of a first embodiment of the present utility model.

Fig. 2 is a schematic perspective view of a first embodiment of the present utility model.

Fig. 3 is a schematic top view of a second embodiment of the present utility model.

Fig. 4 is a schematic perspective view of a second embodiment of the present utility model.

Reference numerals illustrate:

1. a water inlet pipe; 2. a water outlet pipe; 10. an aquaculture pond; 11. a support rod; 12. a photovoltaic panel; 13. a soil path; 14. an isolation net; 15. a water quality sensor; 16. a control box; 17. an aeration device; 20. a water inlet tank; 201. a first water inlet valve; 202. a second water inlet valve; 203. a third water inlet valve; 21. an overflow weir; 30. a water outlet tank; 301. a first water outlet valve; 302. a second water outlet valve; 303. a third water outlet valve; 31. a barrier web; 40. tail water purifying area; 41. a precipitation zone; 411. a mud pipe; 42. a filtering dam; 43. an ecological pond; 431. an ecological floating bed; 50. a circulation pump; 60. a power supply room; 70. and controlling the house.

Detailed Description

The embodiment of the application is used for solving the problems of water pollution, influence on aquaculture efficiency, overlarge water consumption, water saving, energy saving and emission reduction of the conventional 'fishing light integrated' aquaculture technology by providing the fishing light integrated low-carbon aquaculture farm, and the problems of pollution to the aquaculture pond water body due to artificial feed residues and aquatic excrement.

The conception of this embodiment is through setting up a tail water purification zone, the tail water purification zone includes sedimentation zone, filtering dam and ecological pond, utilize precipitation, filtration, ecological purification's method, get rid of suspended solid in the breed pond tail water, remaining fodder, excrement and absorb the nitrogen phosphorus nutrient salt in the water, reach tail water purification's purpose, secondly through setting up breed pond Gao Chengda in tail water purification zone elevation, make the water can follow the breed pond with flowing freely the form flow to tail water purification zone, communicate tail water purification zone and breed pond through the circulating pump, realize cyclic utilization of water, reach water economy's purpose.

In order to make the objects, technical solutions and advantages of the embodiments of the present utility model more clear, 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. It will be apparent that the described embodiments are some, but not all, embodiments of the utility model. All other embodiments, which can be made by a person skilled in the art without creative efforts, based on the described embodiments of the present utility model fall within the protection scope of the present utility model. Unless defined otherwise, technical or scientific terms used herein should be given the ordinary meaning as understood by one of ordinary skill in the art to which this utility model belongs.

The terms "first," "second," and the like in the description and in the claims, are not used for any order, quantity, or importance, but are used for distinguishing between different elements. Also, unless the context clearly indicates otherwise, singular forms "a," "an," or "the" and similar terms do not denote a limitation of quantity, but rather denote the presence of at least one. The terms "comprises," "comprising," or the like are intended to cover a feature, integer, step, operation, element, and/or component recited as being present in the element or article that "comprises" or "comprising" does not exclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. "up", "down", "left", "right" and the like are used only to indicate a relative positional relationship, and when the absolute position of the object to be described is changed, the relative positional relationship may be changed accordingly.

Example 1

This example is merely one specific example of an embodiment of the present utility model, and the present utility model will be described in further detail below with reference to the accompanying drawings and specific examples. It should be understood that the particular embodiments described herein are illustrative only and are not limiting upon the utility model.

Referring to fig. 1 and 2, a fishing light integrated low-carbon aquaculture farm according to an embodiment of the present utility model includes: the system comprises a water inlet pipe 1, a water outlet pipe 2, an aquaculture pond 10, four groups of photovoltaic modules, four isolation nets 14, four water quality sensors 15, four control boxes 16, four aeration devices 17, a tail water purification area 40, a circulating pump 50, a power supply room 60 and a control room 70.

In this embodiment, photovoltaic module includes bracing piece 11 and photovoltaic board 12, four bracing piece 11 is fixed to be arranged in the breed aquatics pond 10 left and right sides, photovoltaic board 12 is arranged in bracing piece 11 stretches out the top of breed aquatics pond 10 surface of water one end, four photovoltaic board 12 all inclines to same direction, forms large tracts of land to the surface of water and shelters from, effectively reduces breed aquatics pond water temperature, does benefit to aquaculture. In other embodiments, which will be appreciated by those skilled in the art, the number of photovoltaic modules is not fixed, and may be increased or decreased as appropriate, depending on the circumstances.

The tail water purification area 40 is arranged on the right side of the culture pond 10, the tail water purification area 40 comprises a sedimentation area 41, a filtering dam 42 and an ecological pond 43, the sedimentation area 41 is communicated with the bottom of the right side wall of the culture pond 10 through a drainage canal, a blocking net 31 is arranged on one side of the culture pond 10 at the communicating position so as to prevent aquatic products from flowing out of the culture pond 10 along with pond water, and a mud discharging pipe 411 is further arranged on the right side of the sedimentation area 41. When the device is used, a flocculating agent is added into the sedimentation area 41, so that the flocculation of artificial feed residues and aquatic excrement is promoted, the sedimentation speed is increased, and the sediment is discharged and cleaned by using the mud discharge pipe 411 periodically; the filtering dam 42 adopts a trapezoid structure, the gradient of the filtering dam is 30-40 degrees, the inside of the filtering dam 42 is filled with fillers in a layered manner, the settling zone 41 is defined to be in front of the filtering dam, the ecological pond 43 is arranged behind the filtering dam 42 is divided into three areas according to the water flow direction (from front to back), gravel, zeolite, ceramsite mixture and gravel are sequentially filled, namely, according to the trapezoid structure, the first triangular area is filled with gravel, the particle size of the gravel filled in the first triangular area is 10-30mm, and the second rectangular area is filled with the volume ratio of 1:1 zeolite and haydite mixture, the grain size of the mixture is 20-40mm, the third section of triangular area is filled with gravel, the grain size of the gravel filled in the section is 30-50mm, when water flows through the filtering dam 42, large particles which are not precipitated in the precipitation area 41 can be effectively intercepted, and microorganisms attached to the surface of the filler of the filtering dam 42 perform denitrification and dephosphorization biochemical reaction, so that the effect of purifying tail water is achieved; a plurality of ecological floating beds 431 are arranged on the water surface of the ecological pond 43, submerged plants are planted at the bottom of the ecological pond 43 and snails are put in to absorb and utilize nitrogen and phosphorus nutritive salts in water, organic matters in tail water are consumed, the effect of further purifying the tail water is achieved, the ecological pond 43 and the culture pond 10 are communicated through the circulating pump 50, the culture pond 10 Gao Chengda is located at the elevation of the tail water purifying area 40, water can flow from the culture pond 10 to the tail water purifying area in a self-flowing mode, water recycling is achieved, and the technical effect of saving water is achieved.

The water quality sensor 15 is fixedly installed at the bottom of one end below the water surface of the culture pond 10, the control box 16 is fixedly installed at the bottom of one end below the water surface of the culture pond 10, the support rod 11 is placed at one end above the water surface of the culture pond 10, the control box 16 is located below the photovoltaic panel 12, the aeration device 17 is fixedly installed at the bottom of one end below the water surface of the culture pond 10, the support rod 11 is symmetrically installed with the water quality sensor 15, the control box 16 and the aeration device 17 are electrically connected, the control box 16 comprises a controller, a memory, a power module and a communication module, the controller is used for regulating the aeration device 17, the memory is used for storing dissolved oxygen content data acquired by the water quality sensor 15, the power module is used for providing electric energy for the controller, the memory and the communication module, and the communication module is used for transmitting data stored in the memory. When the water quality sensor 15 is used, the water quality sensor 15 collects the dissolved oxygen content data in the aquaculture pond 10 in real time, the control box 16 carries out aeration regulation and control on the aeration device 17 according to the data collected by the water quality sensor 15, so that the oxygen content of the water body in the aquaculture pond 10 is increased, the aquatic products in the water body are ensured not to be lack of oxygen, and meanwhile, the growth of anaerobic bacteria in the water is inhibited, and the water body in the aquaculture pond 10 is prevented from deteriorating to threaten the aquatic product living environment. In the embodiment of the present application, the photovoltaic module and the water quality sensor 15, the control box 16 and the aeration device 17 are in one-to-one correspondence in number, but in other embodiments that can be easily thought by those skilled in the art, the number of the water quality sensor 15, the control box 16 and the aeration device 17 can be changed according to the actual situation, that is, the photovoltaic module and the water quality sensor 15, the control box 16 and the aeration device 17 need not be in one-to-one correspondence in number.

The control house 70 is disposed behind the aquaculture pond 10 and is electrically connected to the control box 16. When in use, the control room 70 is used for displaying and monitoring the content of the dissolved oxygen in the aquaculture pond 10 in real time, and remotely setting the parameter indexes required by the control box 16 for performing aeration regulation and control on the aeration device 17, so that aquaculture personnel can more intuitively know the water quality condition in the aquaculture pond 10.

The power supply room 60 is disposed behind the control room 70, the power supply room 60 is electrically connected with the photovoltaic panel 12, the water quality sensor 15, the control box 16, the aeration device 17, the circulation pump 50 and the control room 70, an inverter and a step-up transformer are installed in the power supply room 60, and the power supply room 60 is configured to convert direct current generated by solar energy of the photovoltaic panel 12 into alternating current and convert low-value alternating voltage into high-value alternating voltage suitable for use by the water quality sensor 15, the control box 16, the aeration device 17, the circulation pump 50 and the control room 70. In use, the power supply room 60 converts the direct current generated by the photovoltaic panel 12 by solar energy into alternating current to supply electric power to the water quality sensor 15, the power module, the aeration device 17, the circulating pump 50 and the control room 70, wherein the power module supplies electric power to the controller, the memory and the communication module.

The isolation net 14 is vertically installed on the periphery of the supporting rod 11, the lower end of the isolation net 14 is fixedly connected with the aquaculture pond 10, the height of the isolation net is kept level with the highest water level of the aquaculture pond 10, the isolation net 14 divides the aquaculture pond 10 into an aquaculture area and a control area, aquatic products are prevented from moving nearby the supporting rod 11, aquaculture personnel are prevented from being influenced to catch the aquatic products, and the fishing efficiency of the aquaculture personnel is improved.

One end of the water inlet pipe 1 is communicated with the aquaculture pond 10, tap water is introduced from the outside into the other end of the water inlet pipe, the water outlet pipe 2 is communicated with the ecological pond 43, the water inlet pipe 1 and the water outlet pipe 2 are controlled to be on-off through valves, and the water inlet pipe 1 and the water outlet pipe 2 are matched to control the water quantity in the aquaculture pond 10. According to different aquaculture types, the water demand in the aquaculture pond 10 is different, for example, the water level in the aquaculture pond is 20cm when the aquaculture in the current batch is required, the water level demand of the aquatic product in the next batch is 30cm, at this time, water can be added through the water inlet pipe 1, and if the water level demand in the next batch is 10cm, the surplus water is discharged through the water outlet pipe 2.

The technical scheme in the embodiment of the application at least has the following technical effects:

according to the embodiment of the application, the tail water purification area is arranged, the aquaculture pond Gao Chengda is arranged at the elevation of the tail water purification area, the tail water purification area is communicated with the aquaculture pond by the circulating pump, the purification of tail water of the aquaculture pond and the recycling of water are realized, and the problems that aquatic product survival and large water consumption are influenced due to feed residues and excrement pollution of the aquaculture water in the prior art are effectively solved; the isolation net is arranged on the periphery of the support rod to divide the cultivation pond into an aquatic product active area and a control area, so that the difficulty of fishing operation of cultivation personnel is effectively reduced; the water quality sensor is arranged to detect the dissolved oxygen content of water quality in real time, the aeration device is subjected to aeration regulation and control through the control box, the oxygen content in water is increased, the growth of anaerobic bacteria in the water body is inhibited, the deterioration of the water body is prevented, and the aquaculture environment is improved; through with photovoltaic board, power supply room, quality of water sensor, control box, aeration equipment, circulating pump and control room electric connection, the photovoltaic board utilizes solar energy power generation to carry the power supply room, and the power supply room provides the electric energy for quality of water sensor, control box, aeration equipment, circulating pump and control room after converting the direct current into alternating current again, energy saving and consumption reduction.

Example two

This example is merely one specific example of an embodiment of the present utility model, and the present utility model will be described in further detail below with reference to the accompanying drawings and specific examples. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

As shown in fig. 3 and 4, a fishing light integrated low-carbon aquaculture farm according to an embodiment of the present utility model comprises: the system comprises a water inlet pipe 1, a water outlet pipe 2, three aquaculture ponds 10, six groups of photovoltaic modules, six isolation nets 14, six water quality sensors 15, six control boxes 16, six aeration devices 17, a water inlet tank 20, an overflow weir 21, a water inlet valve, a water outlet tank 30, a water outlet valve, a blocking net 31, a tail water purifying area 40, a circulating pump 50, a power supply room 60 and a control room 70.

In this embodiment, three the breed aqua-Pond 10 distributes side by side, and two adjacent the soil way 13 is laid in the middle of the breed aqua-Pond 10, soil way 13 is used for the breed personnel to move about, is convenient for aquatic products to feed, catch, photovoltaic module includes bracing piece 11 and photovoltaic board 12, six photovoltaic module evenly distributed is in three in the breed aqua-Pond 10, the bracing piece 11 is fixed in the breed aqua-Pond 10 left and right sides, the photovoltaic board 12 is arranged in bracing piece 11 stretches out the top of breed aqua-Pond 10 surface of water one end, six the photovoltaic board 12 all inclines to same direction, forms large tracts of land to the surface of water and shelters from, effectively reduces breed aqua-Pond water temperature, does benefit to aquatic products growth. In other embodiments, the number of the culture ponds 10 may vary according to the actual scale of cultivation, and may be four, five or more.

The water inlet tank 20 is arranged on the left side of the culture pond 10, the water inlet tank 20 is communicated with three culture ponds 10, on-off is controlled by the water inlet valves, each water inlet valve comprises a first water inlet valve 201, a second water inlet valve 202 and a third water inlet valve 203, the first water inlet valve 201, the second water inlet valve 202 and the third water inlet valve 203 respectively control on-off of the water inlet tank 20 and three passages of the culture pond 10, the first water inlet valve 201, the second water inlet valve 202 and the third water inlet valve 203 are arranged on one side of the water inlet tank 20, influence of the water inlet valves on the aquaculture environment is avoided, the overflow weir 21 is arranged in the water inlet tank 20 and is close to one side of the water inlet, water passes through the overflow weir 21, water and air are fully mixed, and the dissolved oxygen content of the water is increased.

The water outlet tank 30 is arranged on the right side of the culture pond 10, the water outlet tank 30 is communicated with the bottoms of the right side walls of the culture pond 10, and is controlled to be on or off by the water outlet valves, the water outlet valves comprise a first water outlet valve 301, a second water outlet valve 302 and a third water outlet valve 303, the first water outlet valve 301, the second water outlet valve 302 and the third water outlet valve 303 are respectively used for controlling the water outlet tank 30 to be on or off with the three passages of the culture pond 10, the first water outlet valve 301, the second water outlet valve 302 and the third water outlet valve 303 are respectively arranged on one side of the water outlet tank 30 so as to avoid the influence of the water outlet valves on the aquaculture environment, the water outlet tank 30 and the three water outlet valves 10 are arranged at the communicated positions of the culture pond 10, and the barrier net 31 is arranged on one side of the culture pond 10.

The water inlet valve and the water outlet valve are remote manual valves, so that the operation of cultivation personnel is facilitated.

The tail water purifying area 40 is similar to the first embodiment in structure, except that the settling area 41 is communicated with the water outlet tank 30, and the ecological pond 43 is communicated with the water inlet tank 20 through the circulating pump 50.

The water inlet tank 20, the culture pond 10, the water outlet tank 30 and the tail water purifying area 40 are sequentially lowered from left to right, water can flow from the water inlet tank 20 to the tail water purifying area 40 in a self-flowing mode, water recycling is achieved on the premise of saving energy and reducing consumption, and the technical effects of saving energy and saving water are achieved.

The inlet pipe 1 and the outlet pipe 2 are similar to the first embodiment in structure, except that the inlet pipe 1 communicates with the inlet tank 20.

The isolation net 14, the water quality sensor 15, the control box 16, the aeration device 17, the power supply room 60 and the control room 70 are similar to those of the first embodiment, and will not be described herein.

Compared with the prior art, the embodiment of the application has the advantages that the embodiment I has the advantages that the plurality of culture ponds are arranged, the water inlet pond and the water outlet pond are combined to be communicated with the plurality of culture ponds, the water body flow on-off is controlled through the water inlet valve and the water outlet valve, the water inlet and the water outlet of a single culture pond can be independently controlled while the culture scale is enlarged, and the control of culture staff on the culture ponds is facilitated; by arranging the overflow weir on the water inlet side of the water inlet tank, water and air can be fully fused, the dissolved oxygen content of the water body is increased, and the aquaculture system is beneficial.

While the utility model has been described with reference to preferred embodiments, it is not intended to be limiting. Those skilled in the art to which the utility model pertains will appreciate that numerous variations and modifications can be made without departing from the spirit and scope of the utility model. Accordingly, the scope of the utility model is defined by the appended claims.

Claims (10)

1. A fishing light integrated low carbon aquaculture farm, comprising:

an aquaculture pond;

the photovoltaic modules are distributed above the culture pond (10);

tail water purification zone (40), tail water purification zone (40) are arranged in breed aquatics pond (10) one side, tail water purification zone (40) are including sedimentation zone (41), filtering dam (42) and ecological pond (43), sedimentation zone (41) are equipped with mud pipe (411), sedimentation zone (41) with breed aquatics pond (10) intercommunication, be provided with a plurality of ecology floating beds (431) in ecological pond (43), ecological pond (43) with breed aquatics pond (10) are through circulating pump (50) intercommunication;

an aquaculture pond (10) Gao Chengda is elevated above the tail water purification zone (40).

2. The fishing and lighting integrated low-carbon aquaculture farm according to claim 1, characterized in that the number of the aquaculture ponds (10) is more than two, the aquaculture ponds (10) are distributed side by side, and soil paths (13) are paved between two adjacent aquaculture ponds (10).

3. The fishing light integrated low carbon aquaculture farm of claim 2, further comprising:

a water inlet tank (20) and a water outlet tank (30);

the water inlet pool (20) is arranged on the other side of the culture pond (10) opposite to the tail water purifying area (40), the water inlet pool (20) is communicated with each culture pond (10) and is controlled to be on-off through a water inlet valve, the water inlet valve is arranged on one side of the water inlet pool (20), and the water inlet pool (20) is communicated with the ecological pond (43) through the circulating pump (50);

the water outlet pool (30) is arranged between the culture ponds (10) and the tail water purifying area (40), the water outlet pool (30) is communicated with each culture pond (10) and is controlled to be on-off through a water outlet valve, the water outlet valve is arranged at one side of the water outlet pool (30), and the water outlet pool (30) is communicated with the sedimentation area (41);

the heights of the water inlet tank (20), the culture pond (10), the water outlet tank (30) and the tail water purifying area (40) are sequentially reduced.

4. A fishing and lighting integrated low-carbon aquaculture farm according to claim 3, characterized in that the water intake tank (20) is further provided with an overflow weir (21), and the overflow weir (21) is arranged at one side of the water intake tank (20) communicating with the ecological pond (43).

5. A fishing light integrated low carbon aquaculture farm according to claim 1 or 3, further comprising:

a water inlet pipe (1) and a water outlet pipe (2);

the water inlet pipe (1) is communicated with the culture pond (10) or the water inlet pond (20);

the water outlet pipe (2) is communicated with the ecological pond (43).

6. A fishing light integrated low-carbon aquaculture farm according to claim 1 or 3, characterized in that the connection between the aquaculture pond (10) and the tail water purification area (40) or the water outlet pond (30) is further provided with a plurality of barrier nets (31), and the barrier nets (31) are arranged on one side of the aquaculture pond (10).

7. The fishing and lighting integrated low-carbon aquaculture farm according to claim 1, further comprising a power supply room (60), wherein the photovoltaic assembly comprises a support rod (11) and a photovoltaic panel (12), and the power supply room (60) is electrically connected with the photovoltaic panel (12) and the circulating pump (50).

8. The fishing and lighting integrated low-carbon aquaculture farm according to claim 7, further comprising a plurality of water quality sensors (15), a control box (16) and an aeration device (17), wherein the water quality sensors (15) are arranged at one end of the support rods (11) below the water surface of the aquaculture pond (10), the control box (16) is arranged at one end of the support rods (11) above the water surface of the aquaculture pond (10), the aeration device (17) is arranged at one end of the support rods (11) below the water surface of the aquaculture pond, and the water quality sensors (15), the control box (16), the aeration device (17) and the power supply room (60) are electrically connected.

9. The fishing and lighting integrated low-carbon aquaculture farm according to claim 8, further comprising a plurality of isolation nets (14), wherein the isolation nets (14) are fixedly arranged in the aquaculture pond (10) and are arranged at the periphery of the support rods (11), and the height of the isolation nets (14) is at least equal to the water level of the aquaculture pond (10).

10. The fishing and lighting integrated low-carbon aquaculture farm according to claim 8, further comprising a control room (70), wherein the control room (70) is electrically connected to the power supply room (60) and to the plurality of control boxes (16).

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