CN216377824U - Intensive industrial recirculating aquaculture system based on ecological environment protection - Google Patents

Abstract

The application relates to an intensive industrial recirculating aquaculture system based on ecological environment protection, and belongs to the field of ecological environment protection. The system comprises a solid-liquid separation device, a protein separation device, an ammonia-nitrogen separation device, an ultraviolet treatment device, a novel purification device, an ozone generation device, a circulating water culture pond, an oxygenation device, a control system, a treatment pond, biomass and a water collecting pond; the protein separation device comprises an aeration pump, an aeration generator and an aeration tank; the oxygenation device comprises an oxygenation pool, a liquid oxygen storage tank, a liquid oxygen control valve and a tail gas pipeline. Compared with the prior art, the beneficial effects of this application are: the treatment efficiency of the aquaculture tail water is high, the oxygen content of the circulating water is high, the content of suspended particles is low, and the content of ammonia nitrogen is low. This application can reduce tail water treatment cost, improve the quality of water and the efficiency of handling the tail water, is a novel aquaculture technique that has market and application prospect.

Description

Intensive industrial recirculating aquaculture system based on ecological environment protection

Technical Field

The application relates to an intensive industrial recirculating aquaculture system based on ecological environment protection, and belongs to the field of ecological environment protection.

Background

The aquatic culture is artificially controlled to breed and cultivate so as to harvest aquatic animals and plants, and the aquatic culture has become a main force for promoting the rapid and stable development of fishery in China. In 2019, the total output of aquaculture in China exceeds 5000 ten thousand tons, which accounts for more than 60% of the total amount of aquaculture in the world (Wangying, forest Bin, Chenlianfei, and the like, the development status and application suggestion of aquaculture equipment in Guangdong province [ J ] modern agricultural equipment, 2021, 42(04): 86-89).

Based on the condition of water resource utilization rate, the aquaculture mode can be divided into extensive type, semi-extensive type and intensive type. The first two culture modes have more dependence on land resources, water resources and natural environment resources, and extremely cause culture water body pollution, and do not accord with the scientific concept of sustainable development. The recirculating aquaculture utilizes physical filtration, biological filtration, disinfection, oxygenation and other treatments, and the treated water is input into the aquaculture pond again for recycling. However, the existing recirculating aquaculture has the problems of low treatment efficiency of aquaculture tail water, low circulating water dissolved oxygen, overhigh suspended particulate matter content, high ammonia nitrogen content and the like.

Therefore, an aquaculture system with high aquaculture tail water treatment efficiency, high circulating water dissolved oxygen content, low suspended particulate matter content and low ammonia nitrogen content is needed.

SUMMERY OF THE UTILITY MODEL

The application aims to provide an intensive industrial circulating water culture system based on ecological environment protection so as to solve a plurality of problems faced by the traditional aquaculture system. The intensive industrial recirculating aquaculture system based on ecological environment protection has the advantages of high treatment efficiency of aquaculture tail water, high oxygen content of circulating water, low content of suspended particles, low content of ammonia nitrogen and the like.

In order to achieve the above purpose, the present application provides the following technical solutions:

an intensive industrial recirculating aquaculture system based on ecological environment protection is characterized by comprising a solid-liquid separation device, a protein separation device, an ammonia nitrogen separation device, an ultraviolet treatment device, a novel purification device, an ozone generation device, a recirculating aquaculture pond, an oxygenation device, a control system, a treatment pond, biomass and a water collecting pond;

the protein separation device comprises an aeration pump, an aeration generator and an aeration tank, wherein a jet port of the aeration generator is positioned at the bottom of the aeration tank; the aeration pump drives the aeration generator to operate to generate micro bubbles;

the oxygenation device comprises an oxygenation pool, a liquid oxygen storage tank, a liquid oxygen control valve and a tail gas pipeline; liquid oxygen enters the oxygenation pool from the liquid oxygen storage tank through the liquid oxygen control valve, and the aquaculture tail water entering the oxygenation pool is oxygenated; wherein oxygen which is not melted into the tail water enters the gas collection tank through the tail gas pipeline;

the tail gas pipeline is connected with the treatment pool sequentially through the gas collecting tank and the oxygen control valve; the oxygen in the gas collecting tank is used for providing heat energy for the treatment tank;

the ammonia nitrogen separation device comprises 6-8 rows of vertically placed bio-based carriers, and nitrobacteria are cultured on the bio-based carriers;

the control system comprises a control host and a control panel;

the circulating water culture pond generates a first precipitate, the solid-liquid separation device generates a second precipitate, and the protein separation device generates floating impurities;

the first precipitate, the second precipitate and the floating impurities form an effluent;

pretreating the discharged material and the biomass to obtain a puffed product;

the puffed product enters a treatment tank to carry out physical and chemical reaction and generate adsorption granules;

the adsorption granules are crushed and sieved by a 0.15mm sieve sheet, and the crushed and sieved adsorption granules are used as the adsorption material of the novel purification device.

Preferably, the biomass comprises 50% of corn straw, 30% of wheat straw and 20% of cottonseed meal.

Preferably, the pretreatment comprises the following steps: step one, cleaning biomass to remove impurities, crushing, and screening by using a 2.5mm sieve sheet; step two, taking 5-8 parts of the treated biomass and 2-3 parts of the discharged materials, uniformly mixing, and extruding and puffing the mixture by using a screw extrusion puffing machine to obtain a puffed product; the rotating speed of the extruded and puffed screw is 220-260 r/min, the working temperature is 160-180 ℃, the indoor pressure is 2-3 MPa, the processing time is 30-40 s, the diameter of a die hole is 2-4 mm, and the pressure is quickly released within 0.5 s.

Preferably, the puffed product enters a treatment tank to carry out a physical and chemical reaction under the following conditions: the operating temperature is 420-460 ℃ and the operating time is 20-30 min in an oxygen-free environment.

Preferably, in the second step of the pretreatment, 6 parts of the treated biomass and 2 parts of the discharged material are uniformly mixed and extruded and expanded by a screw extrusion expander to obtain an expanded product; the rotating speed of the screw for extrusion and expansion is 240r/min, the working temperature is 170 ℃, the indoor pressure is 2.5MPa, the processing time is 38s, the diameter of a die hole is 3mm, and the pressure is rapidly released within 0.5 s.

Preferably, the puffed product enters a treatment tank to carry out a physical and chemical reaction under the following conditions: the operating temperature is 450 ℃ and the operating time is 22min in an anaerobic environment.

Preferably, the cyprinus carpio is cultured in the circulating water culture pond.

The application also provides a working method of the intensive industrial recirculating aquaculture system based on ecological environment protection, which comprises the following steps: the culture tail water in the circulating water culture pond sequentially passes through a solid-liquid separation device, a protein separation device, an ammonia-nitrogen separation device, an ultraviolet treatment device, a novel purification device and an ozone generation device and enters an oxygenation pond; the oxygenation device is used for oxygenating the treated aquaculture tail water; and the oxygenated water body enters a water collecting tank, and flows back to enter a circulating water culture tank after being detected to be qualified, so that the tail water circulation of primary culture is realized.

According to the intensive industrialization recirculating aquaculture system based on environmental protection, compare with prior art and have following advantage:

1. the method comprises the steps of pretreating effluent and biomass to obtain a puffed product; the puffed product is subjected to physical and chemical reaction to generate adsorption granules for preparing the adsorption material of the novel purification device. This application is when clean aquaculture tail water, handles processing with matters such as fodder residue, excrement and urine and living beings in recirculating water aquaculture pond bottom, realizes carbonization and cyclic utilization of organic matter for changing waste into valuables has realized the cyclic utilization of resource.

2. This application is through retrieving the oxygen that does not fuse into the tail water among the oxygenation device, has avoided direct outer arranging of oxygen to cause danger and energy waste like this, can also reduce production energy consumption, reduce running cost for handling the pond provides heat energy.

3. The circulating water culture system can shorten the culture period; compared with the traditional breeding mode, the controllability of the breeding environment is enhanced, the conflict between the breeding time of the breeding environment and the time of the natural environment on the market can be avoided, the time of the breeding environment on the market can be flexibly adjusted, and the economic benefit is further improved.

4. The ultraviolet treatment device and the ozone generation device in the application play a role in killing pathogenic bacteria in tail water; the solid-liquid separation device filters solid particles with the particle size larger than 400 microns in the culture tail water; the nitrifying bacteria on the bio-based carrier can remove excessive ammonia nitrogen and nitrite ammonia in the culture tail water.

5. Pretreatment in this application is very important step, can kill the harmful substance in the living beings, utilizes high temperature high pressure release in the twinkling of an eye simultaneously, breaks through the tissue internal passage, forms the pore of various shapes and sizes, obtains loose, porous structure, enlarges the surface area and improves adsorption efficiency, further gets rid of the material such as ammonia nitrogen phosphorus in the tail water, reduces the ammonia nitrogen phosphorus content in the tail water.

6. The recycled culture tail water is clear and has a bottom, wherein the content of ammonia nitrogen is lower than 0.1mg/L, the content of nitrite is lower than 0.05mg/L, the content of suspended particles is lower than 1.6mg/L, the dissolved oxygen content is higher than 10mg/L, the pH value is 6.5-7.3, and the water quality index meets the requirement; the application is a novel aquaculture technology with market and application prospects.

Drawings

Fig. 1 is a schematic view of the overall structure of the present application.

FIG. 2 is a schematic view of a protein separation apparatus of the present application.

Figure 3 is an ammonia nitrogen separation device in the present application.

In the figure, 11-solid-liquid separation device; 12-a protein separation device; 121-aeration pump; 122-a gassing generator; 123-aeration pool; 13-ammonia nitrogen separation device; 131-a bio-based carrier; 132-nitrifying bacteria; 21-an ultraviolet treatment device; 22-a novel purification device; 23-an ozone generating device; 4-circulating water culture pond; 5-an oxygenation device; 50-an oxygenation pool; 51-a liquid oxygen storage tank; 52-liquid oxygen control valve; 53-tail gas pipeline; 54-a gas collection tank; 55-an oxygen control valve; 6-a control system; 61-a computer; 62-a control panel; 7-a treatment tank; 71-a first precipitate; 72-second precipitate; 73-floating impurities; 8-biomass; 9-a water collecting tank.

Detailed Description

As shown in fig. 1-3, intensive industrialized recirculating aquaculture system based on ecological environment protection: the system comprises a solid-liquid separation device 11, a protein separation device 12, an ammonia nitrogen separation device 13, an ultraviolet treatment device 21, a novel purification device 22, an ozone generation device 23, a circulating water culture pond 4, an oxygenation device 5, a control system 6, a treatment pond 7, biomass 8 and a water collecting pond 9;

the protein separation device 12 comprises an aeration pump 121, an aeration generator 122 and an aeration tank 123, wherein a jet port of the aeration generator 122 is positioned at the bottom of the aeration tank 123; the aeration pump 121 drives the aeration generator 122 to operate to generate micro bubbles;

the oxygenation device 5 comprises an oxygenation pool 50, a liquid oxygen storage tank 51, a liquid oxygen control valve 52 and a tail gas pipeline 53; liquid oxygen enters the oxygen increasing pool 50 from a liquid oxygen storage tank 51 through a liquid oxygen control valve 52, and the oxygen is increased for the culture tail water entering the oxygen increasing pool 50; wherein oxygen which is not melted into the tail water enters a gas collecting tank 54 through a tail gas pipeline 53;

the tail gas pipeline 53 is connected with the treatment pool 7 through a gas collecting tank 54 and an oxygen control valve 55 in sequence; the oxygen in the gas collection tank 54 is used for providing heat energy for the treatment tank 7;

the ammonia nitrogen separation device 13 comprises 6-8 rows of vertically placed bio-based carriers 131, and nitrobacteria 132 are cultured on the bio-based carriers 131;

the control system 6 comprises a control host 61 and a control panel 62;

the recirculating aquaculture pond 4 generates a first precipitate 71, the solid-liquid separation device 11 generates a second precipitate 72, and the protein separation device 12 generates floating impurities 73;

the first precipitate 71, the second precipitate 72 and the floating impurities 73 form an effluent;

the effluent and the biomass 8 are pretreated to obtain a puffed product;

the puffed product enters a treatment tank 7 to carry out physical and chemical reaction and generate adsorption granules;

the adsorption granules are crushed and sieved by a 0.15mm sieve sheet, and the crushed and sieved adsorption granules are used as the adsorption material of the novel purification device 22.

The working method of the intensive industrial recirculating aquaculture system based on ecological environment protection comprises the following steps: the culture tail water in the circulating water culture pond 4 sequentially passes through the solid-liquid separation device 11, the protein separation device 12, the ammonia-nitrogen separation device 13, the ultraviolet treatment device 21, the novel purification device 22 and the ozone generation device 23 and enters the oxygenation pond 50; the oxygenation device 5 is used for oxygenating the treated aquaculture tail water; the water body after oxygenation enters a water collecting tank 9, and flows back to enter a circulating water culture tank 4 after being detected to be qualified, so that the tail water circulation of primary culture is realized.

Preferably, the biomass 8 comprises 50% of corn stover, 30% of wheat straw, and 20% of cottonseed meal.

Preferably, the pretreatment comprises the following steps: step one, cleaning biomass 8 to remove impurities, crushing and sieving by a 2.5mm sieve sheet; step two, taking 5-8 parts of the treated biomass 8 and 2-3 parts of the discharged materials, uniformly mixing, and extruding and puffing the mixture by using a screw extrusion puffing machine to obtain a puffed product; the rotating speed of the extruded and puffed screw is 220-260 r/min, the working temperature is 160-180 ℃, the indoor pressure is 2-3 MPa, the processing time is 30-40 s, the diameter of a die hole is 2-4 mm, and the pressure is quickly released within 0.5 s.

Preferably, the puffed product enters the treatment tank 7 to perform a physical and chemical reaction under the following conditions: the operating temperature is 420-460 ℃ and the operating time is 20-30 min in an oxygen-free environment.

Preferably, in the second step of the pretreatment, 6 parts of the treated biomass 8 and 2 parts of the discharged material are uniformly mixed and extruded and expanded by a screw extrusion expander to obtain an expanded product; the rotating speed of the screw for extrusion and expansion is 240r/min, the working temperature is 170 ℃, the indoor pressure is 2.5MPa, the processing time is 38s, the diameter of a die hole is 3mm, and the pressure is rapidly released within 0.5 s.

Preferably, the puffed product enters the treatment tank 7 to perform a physical and chemical reaction under the following conditions: the operating temperature is 450 ℃ and the operating time is 22min in an anaerobic environment.

Preferably, the cyprinus carpio is cultured in the circulating water culture pond 4.

The following are several specific examples of the present application to further illustrate the present application, but the present application is not limited to these examples.

Example 1

An intensive industrial recirculating aquaculture system based on ecological environment protection comprises a solid-liquid separation device 11, a protein separation device 12, an ammonia nitrogen separation device 13, an ultraviolet treatment device 21, a novel purification device 22, an ozone generation device 23, a recirculating aquaculture pond 4, an oxygenation device 5, a control system 6, a treatment pond 7, biomass 8 and a water collecting pond 9;

the protein separation device 12 comprises an aeration pump 121, an aeration generator 122 and an aeration tank 123, wherein a jet port of the aeration generator 122 is positioned at the bottom of the aeration tank 123; the aeration pump 121 drives the aeration generator 122 to operate to generate micro bubbles;

the oxygenation device 5 comprises an oxygenation pool 50, a liquid oxygen storage tank 51, a liquid oxygen control valve 52 and a tail gas pipeline 53; liquid oxygen enters the oxygen increasing pool 50 from a liquid oxygen storage tank 51 through a liquid oxygen control valve 52, and the oxygen is increased for the culture tail water entering the oxygen increasing pool 50; wherein oxygen which is not melted into the tail water enters a gas collecting tank 54 through a tail gas pipeline 53;

the tail gas pipeline 53 is connected with the treatment pool 7 through a gas collecting tank 54 and an oxygen control valve 55 in sequence; the oxygen in the gas collection tank 54 is used for providing heat energy for the treatment tank 7;

the ammonia nitrogen separation device 13 comprises 6-8 rows of vertically placed bio-based carriers 131, and nitrobacteria 132 are cultured on the bio-based carriers 131;

the control system 6 comprises a control host 61 and a control panel 62;

the recirculating aquaculture pond 4 generates a first precipitate 71, the solid-liquid separation device 11 generates a second precipitate 72, and the protein separation device 12 generates floating impurities 73;

the first precipitate 71, the second precipitate 72 and the floating impurities 73 form an effluent;

the effluent and the biomass 8 are pretreated to obtain a puffed product; the pretreatment comprises the following steps: step one, cleaning biomass 8 to remove impurities, crushing and sieving by a 2.5mm sieve sheet; step two, taking 5-8 parts of the treated biomass 8 and 2-3 parts of the discharged materials, uniformly mixing, and extruding and puffing the mixture by using a screw extrusion puffing machine to obtain a puffed product; the rotating speed of the extruded and expanded screw is 220r/min, the working temperature is 160 ℃, the indoor pressure is 2MPa, the processing time is 40s, the diameter of a die hole is 2mm, and the pressure is quickly released within 0.5 s;

the puffed product enters a treatment tank 7 to carry out physical and chemical reaction and generate adsorption granules; the conditions of the physical and chemical reaction are as follows: in an anaerobic environment, the operation temperature is 420 ℃, and the operation time is 30 min;

the adsorption granules are crushed and sieved by a 0.15mm sieve sheet, and the crushed and sieved adsorption granules are used as the adsorption material of the novel purification device 22.

Example 2

An intensive industrial recirculating aquaculture system based on ecological environment protection comprises a solid-liquid separation device 11, a protein separation device 12, an ammonia nitrogen separation device 13, an ultraviolet treatment device 21, a novel purification device 22, an ozone generation device 23, a recirculating aquaculture pond 4, an oxygenation device 5, a control system 6, a treatment pond 7, biomass 8 and a water collecting pond 9;

the protein separation device 12 comprises an aeration pump 121, an aeration generator 122 and an aeration tank 123, wherein a jet port of the aeration generator 122 is positioned at the bottom of the aeration tank 123; the aeration pump 121 drives the aeration generator 122 to operate to generate micro bubbles;

the oxygenation device 5 comprises an oxygenation pool 50, a liquid oxygen storage tank 51, a liquid oxygen control valve 52 and a tail gas pipeline 53; liquid oxygen enters the oxygen increasing pool 50 from a liquid oxygen storage tank 51 through a liquid oxygen control valve 52, and the oxygen is increased for the culture tail water entering the oxygen increasing pool 50; wherein oxygen which is not melted into the tail water enters a gas collecting tank 54 through a tail gas pipeline 53;

the tail gas pipeline 53 is connected with the treatment pool 7 through a gas collecting tank 54 and an oxygen control valve 55 in sequence; the oxygen in the gas collection tank 54 is used for providing heat energy for the treatment tank 7;

the ammonia nitrogen separation device 13 comprises 6-8 rows of vertically placed bio-based carriers 131, and nitrobacteria 132 are cultured on the bio-based carriers 131;

the control system 6 comprises a control host 61 and a control panel 62;

the recirculating aquaculture pond 4 generates a first precipitate 71, the solid-liquid separation device 11 generates a second precipitate 72, and the protein separation device 12 generates floating impurities 73;

the first precipitate 71, the second precipitate 72 and the floating impurities 73 form an effluent;

the effluent and the biomass 8 are pretreated to obtain a puffed product; the pretreatment comprises the following steps: step one, cleaning biomass 8 to remove impurities, crushing and sieving by a 2.5mm sieve sheet; step two, taking 5-8 parts of the treated biomass 8 and 2-3 parts of the discharged materials, uniformly mixing, and extruding and puffing the mixture by using a screw extrusion puffing machine to obtain a puffed product; the rotating speed of the extruded and expanded screw is 240r/min, the working temperature is 170 ℃, the indoor pressure is 2.5MPa, the processing time is 38s, the diameter of a die hole is 3mm, and the pressure is quickly released within 0.5 s;

the puffed product enters a treatment tank 7 to carry out physical and chemical reaction and generate adsorption granules; the conditions of the physical and chemical reaction are as follows: in an anaerobic environment, the operation temperature is 450 ℃, and the operation time is 22 min;

the adsorption granules are crushed and sieved by a 0.15mm sieve sheet, and the crushed and sieved adsorption granules are used as the adsorption material of the novel purification device 22.

The above description is only for the preferred embodiment of the present application, but the scope of the present application is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present application should be covered within the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims (2)

1. Intensive industrial recirculating aquaculture system based on environmental protection, its characterized in that: comprises a solid-liquid separation device (11), a protein separation device (12), an ammonia nitrogen separation device (13), an ultraviolet treatment device (21), a novel purification device (22), an ozone generation device (23), a circulating water culture pond (4), an oxygenation device (5), a control system (6), a treatment pond (7), biomass (8) and a water collecting pond (9);

the protein separation device (12) comprises an aeration pump (121), an aeration generator (122) and an aeration tank (123), wherein a jet opening of the aeration generator (122) is positioned at the bottom of the aeration tank (123); the aeration pump (121) drives the aeration generator (122) to operate to generate micro bubbles;

the oxygenation device (5) comprises an oxygenation pool (50), a liquid oxygen storage tank (51), a liquid oxygen control valve (52) and a tail gas pipeline (53); liquid oxygen enters the oxygen increasing pool (50) from a liquid oxygen storage tank (51) through a liquid oxygen control valve (52) to increase oxygen in the culture tail water entering the oxygen increasing pool (50); wherein oxygen which is not melted into the tail water enters a gas collecting tank (54) through a tail gas pipeline (53);

the tail gas pipeline (53) is connected with the treatment pool (7) through a gas collection tank (54) and an oxygen control valve (55) in sequence; the oxygen in the gas collecting tank (54) is used for providing heat energy for the treatment tank (7);

the ammonia nitrogen separation device (13) comprises 6-8 rows of vertically placed bio-based carriers (131), and nitrobacteria (132) are cultured on the bio-based carriers (131);

the control system (6) comprises a control host (61) and a control panel (62);

the recirculating aquaculture pond (4) generates a first precipitate (71), the solid-liquid separation device (11) generates a second precipitate (72), and the protein separation device (12) generates floating impurities (73);

the first precipitate (71), the second precipitate (72) and the floating impurities (73) form a discharge;

the effluent and biomass (8) are pretreated to obtain a puffed product;

the puffed product enters a treatment tank (7) to carry out physical and chemical reaction and generate adsorption granules;

the adsorption granules are crushed and sieved by a 0.15mm sieve sheet, and the crushed and sieved adsorption granules are used as an adsorption material of a novel purification device (22).

2. The eco-friendly intensive industrial recirculating aquaculture system of claim 1, wherein: the cyprinus carpio is cultured in the circulating water culture pond (4).

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