CN213939377U - Distributed circulating water industrial intelligent mariculture device - Google Patents

Abstract

The utility model discloses a decentralized circulating water industrial intelligent mariculture device, which comprises a culture barrel, an intelligent device, a water treatment device and an oxygenation device, the breeding barrel is a conical barrel with big top and small bottom, the bottom of the conical barrel is conical, a feeding tray and an oxygen adding pipe are arranged in the barrel, a water feeding pipe and an escape-proof net are arranged on the top of the barrel, a water outlet is arranged at the lowest part of the conical barrel bottom, an anti-overflow drain pipe is arranged above the water outlet, a water outlet pipe with a control switch is arranged below the water outlet, the water outlet pipe is communicated with the water treatment device through a backwater main pipe, a plurality of culture barrels are arranged in a multi-row and multi-row distribution manner, a glass fiber reinforced plastic grid type pedestrian frame is arranged between every two rows, the intelligent device comprises a water quality monitoring device, an automatic feeder, a control box, a heat pump, a pH value regulation and control barrel, a salinity regulation and control barrel and a dissolved oxygen degree regulation and control device, and is arranged on the corresponding positions of the breeding barrel and the water treatment device.

Description

Distributed circulating water industrial intelligent mariculture device

Technical Field

The utility model belongs to the technical field of aquaculture, concretely relates to distributed circulating water batch production intelligent mariculture device.

Background

Aquaculture is the production activity of breeding, cultivating and harvesting aquatic animals and plants under artificial control. Generally comprises the whole process of cultivating aquatic products from seedlings under artificial feeding management. The method can also be used for the proliferation of aquatic resources in a broad sense, and aquaculture can be realized by means of rough culture, intensive culture, high-density intensive culture and the like. The rough culture is to put seedlings in medium and small natural waters and to culture aquatic products such as fish in lakes and reservoirs, shellfish in shallow seas and the like by completely relying on natural baits. Intensive culture is to culture aquatic products such as pond fish culture, net cage fish culture, fence culture and the like in a small water body by using bait casting and fertilizing methods.

Wherein the large-scale discharge is still the main mode of seawater ponds and industrial aquaculture water in China, the aquaculture tail water contains a large amount of excrement of aquaculture organisms and feed which is not ingested, and the aquaculture tail water is discharged into the environment, thus endangering the surrounding ecology. The high-density intensive culture adopts methods of flowing water, controlling temperature, increasing oxygen, feeding high-quality baits and the like to carry out high-density culture in a small water body so as to obtain high yield, such as flowing water high-density fish culture, shrimp culture and the like. Water is an environmental condition for survival and growth of aquatic products, and the quality of water quality directly influences the culture yield. How to adjust the water quality and promote the quick and healthy growth of aquatic products is a problem which always troubles farmers. In the whole culture process, the key and difficult point of the water product technology is to build good and stable water quality. The aquatic product culture is a pollution process, in the middle and later stages of pond culture, the aquatic products are mainly fed with artificial compound feed, residual baits and excrement of the aquatic products are continuously accumulated, animal and plant corpses are continuously increased, the residual baits, the excrement and the animal and plant corpses are deposited at the bottom of a pond to be subjected to anaerobic decomposition, a large amount of harmful substances are generated, water quality and substrate are spoiled, and the culture environment is deteriorated, and the process is mainly characterized in that: 1. the biological oxidation and decomposition at the bottom of the pool consumes a large amount of oxygen, so that aquatic products are in a low-oxygen environment, and the physique and disease resistance of the aquatic products are reduced; 2. excessive nutrition remains, and a large amount of facultative anaerobes decompose organic substances in a low-oxygen environment to generate a large amount of intermediate products such as ammonia nitrogen, nitrite, hydrogen sulfide, organic acid and the like, so that serious toxic effects on aquatic products are caused; 3. excessive nutrition in the bottom mud is released, so that water eutrophication is caused, meanwhile, trace nutrients such as calcium, magnesium, iron, manganese and the like are deposited on the bottom mud in the form of insoluble salt and are difficult to release due to acidification at the bottom, so that nutrition imbalance is caused, the growth of beneficial algae is inhibited, and the blue algae, dinoflagellate and the like which like abundant nutrition become dominant species, so that the water quality is deteriorated; 4. the environment with low oxygen and high nutrition enables pathogenic bacteria such as vibrio and the like to be rapidly propagated, so that diseases and even death of aquatic products occur. At present, the purpose of regulating and controlling the water quality of aquatic product culture is to reduce organic matters in a water body, and further reduce the biological oxygen consumption and the nutrient balance of a pond. The improvement of dissolved oxygen can inhibit the propagation of anaerobic bacteria such as vibrio, simultaneously reduce the accumulation of reductive toxic substances, inhibit the growth of blue-green algae and dinoflagellate, facilitate the growth of beneficial algae such as green algae and diatom, stabilize bacterial phase and algal phase and improve the disease resistance of aquatic products. The existing water quality regulation and control methods for aquatic product pond culture mainly comprise three water quality regulation and control methods of a physical method, a chemical method and a biological method, wherein the biological method is commonly used, but the methods have high treatment cost, low success rate, poor operability or insignificant effect. The most commonly used method for regulating and controlling the water quality of the pond culture of aquatic products is the algae bacteria regulating and controlling technology, which degrades and converts culture metabolites and residual baits through the combined action of floating microalgae and beneficial bacteria, regulates the water quality, inhibits the breeding of harmful bacteria and harmful microorganisms, and creates an ecological environment suitable for the growth of aquatic products. The main technical scheme is as follows: selecting the weather with sufficient sunlight, putting inorganic composite nutrients, organic composite nutrients and trace elements with good solubility and proper proportion into the pond, and culturing beneficial microalgae; regularly and uniformly putting bacillus into the pond in the culture process, putting photosynthetic bacteria, lactic acid bacteria and the like according to the water quality condition, and keeping the dominant ecological niche of the beneficial bacteria in the pond; and the molasses is used for supplementing a carbon source in the middle and later stages of cultivation, so that the stability of a bacterial phase and an algae phase is promoted. However, the stability of the phycomycete regulation and control technology is poor, and common farmers are difficult to master; during algae cultivation, most of the matched nutrients thrown into the pond are agricultural fertilizers, so that the agricultural fertilizers are difficult to uniformly spread, only a small part of the nutrients are utilized by the algae, and most of the nutrients are absorbed by bottom mud, so that more organic matters are generated at the bottom of the pond, the deterioration of the bottom is caused, and the excessive propagation of harmful algae such as blue algae is easily caused; the microalgae population structure in the pond is easy to change along with the change of environmental conditions, and the 'algae phase' is unstable; when beneficial bacteria and photosynthetic bacteria are put into the pond, most organic matters to be degraded are positioned at the bottom of the pond and are not uniformly distributed, and fungi cannot be purposefully scattered to a target substrate, so that resources are wasted; the lactobacillus belongs to anaerobic bacteria, and the activity of the lactobacillus in the upper layer of the water body, particularly in oxygen-enriched areas such as the vicinity of an aerator and the like, is greatly reduced; the photosynthetic bacteria lack substrates for decomposition when in the upper layer of water, and cannot play a role because of insufficient light when the bottom of the pool is close to the substrates; in addition, some microorganisms such as bacillus consume oxygen seriously in the nitrification process, dissolved oxygen in a water body can be consumed directly in the pond, the growth of water products is not facilitated, meanwhile, the labor cost is increased, the requirement for industrial culture is high, and people require the intellectualization of culture.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problem and providing a distributed circulating water industrial intelligent mariculture device.

The purpose of the utility model is realized through following mode:

a distributed circulating water factory-like intelligent mariculture device comprises a culture barrel, an intelligent device, a water treatment device and an oxygenation device, wherein the culture barrel is a conical barrel with a big top and a small bottom, the bottom of the conical barrel is conical, a feeding disc is arranged in the barrel, the oxygenation tube is arranged in the barrel, a water supply pipe and an anti-escape net are arranged on the barrel top, a water outlet is arranged at the lowest position of the conical barrel bottom, an anti-overflow drain pipe is arranged above the water outlet, a water outlet pipe with a control switch is arranged below the water outlet pipe, the water outlet pipe is communicated with the water treatment device through a backwater main pipe, a plurality of culture barrels are arranged in a multi-row distribution layout, a glass fiber reinforced plastic grid type pedestrian frame is arranged between every two rows, the intelligent device comprises a water quality monitoring device, an automatic feeder, a control box, a heat pump, a PH value regulation barrel, a salinity regulation barrel and a dissolved oxygen regulation device, and is arranged at corresponding positions of the culture barrel and the water treatment device, the water treatment device comprises a micro-filter, a protein separator, a sewage suction device and a biological biochemical pool, wherein the micro-filter can be fully automatically backwashed and is provided with a water inlet pipe and a water outlet pipe, the water inlet pipe is communicated with a backwater main pipe, a barrel is arranged in the pipe to install a water quality monitoring device and a water pump, the water outlet pipe is communicated with the protein separator, a heat pump and the biological biochemical pool through a pipeline, the biological biochemical pool is respectively divided into a biological filtering area, a sterilizing area and a water feeding area from left to right, each area partition plate is provided with a water inlet and a sewage suction device at the bottom, the heat pump, a PH value regulating and controlling barrel, a salinity regulating and controlling barrel and a dissolved oxygen regulating and controlling device are respectively arranged at the periphery of the outer side, the oxygen suction device comprises a fan and an oxygen adding main pipe, and the fan is communicated with an aeration pipe through the oxygen adding main pipe to add oxygen to the culture barrel and the biological biochemical pool.

Preferably, the anti-overflow drain pipe divide into inner tube, outer tube and filter screen, the inner tube cover on the delivery port of breeding the bucket, the pipe lower extreme is equipped with the pore apopore all around, the overcoat has the outer tube, the pipe lower extreme of outer tube be equipped with the macropore apopore all around, the apopore outside is wrapped and is had the filter screen.

Preferably, the biological filtration area is divided into four chambers, namely a water transfer chamber, a volcanic rock culture chamber, a hairbrush culture chamber and a polyethylene or polypropylene suspension filler culture chamber from left to right, wherein water passing ports are formed in the partition plates between the four chambers at intervals from the front top to the rear bottom respectively to enable the culture chambers to be communicated with each other, and the leftmost water transfer chamber is communicated with a water outlet pipe of the heat pump.

Preferably, the bottom of each cultivation room is designed into a V-shaped bottom, and the lowest part of each cultivation room is provided with a sewage suction pipe.

Preferably, the water pump is a horizontal pushing type water pump, water in the cultivation barrel is pumped to the water treatment device for treatment, the water level kept in the cultivation barrel cannot be higher than the water level kept in the water supply area, and the height difference between the cultivation barrel and the water supply area cannot be larger than 50 CM.

Preferably, the water quality monitoring device is provided with a plurality of water quality probes for monitoring the quality of water in the culture area, the detection data of the water quality probes are connected with the host and the display screen to convert the water quality data and display the water quality value, and the water quality value can be connected with and displayed by various remote terminals.

Preferably, the control box is preset with basic required values of water quality and can receive detection data of the water quality monitoring device, after the detection data of the monitoring device is compared with the basic required values of the set water quality, the corresponding heat pump, the pH value regulating barrel, the salinity regulating barrel and the dissolved oxygen degree regulating device are controlled to stop and start according to comparison results, and therefore the purposes of regulating the temperature, the pH value, the salinity and the dissolved oxygen degree of the water quality are achieved.

Compared with the prior art, the beneficial effects of the utility model are that: 1. the aquaculture area is divided into a plurality of aquaculture barrels, so that risks can be dispersed, risks, cost and aquaculture management can be better controlled, if the problem that aquatic products in one aquaculture barrel are sick is found, the aquatic products can be treated independently by closing a control valve for water inlet and outlet, and other aquaculture barrels are prevented from being influenced; 2. the power of the water pump is about 25 percent of the commonly used power under the same flow by using a flat push type, so that the power consumption is greatly reduced, the resource waste is reduced, and the industrial culture becomes a low-energy-consumption culture mode; 3. the water treatment device is formed by sequentially arranging three bacteria culture materials of volcanic rock, brush, polyethylene or polypropylene suspended filler, is very beneficial to the reproduction of nitrobacteria, nitrosobacteria and denitrifying bacteria and can accelerate the improvement of water treatment capacity, so that the water treatment device can treat various harmful substances (such as ammonia nitrogen, nitrite, hydrogen sulfide, protein and the like) generated in the culture process, the water quality after treatment is very suitable for the growth of aquatic products, meanwhile, the water body can be kept stable for a long time, the water treatment device is very suitable for the factory-like and high-density culture of the aquatic products, and the waste of water resources is greatly reduced by using circulating water culture; 4. the whole process is the cultivation without algae, so that the harm of the algae to aquatic products is greatly reduced; 5. the water quality monitoring device is arranged to display the water quality in real time, meanwhile, the water quality condition of the cultivation can be monitored through terminals such as a mobile phone, value setting and early warning can be achieved, so that the water quality change can be known in advance, prevention can be made, the corresponding temperature of the water quality, the pH value, the salinity and the dissolved oxygen degree can be automatically adjusted according to the detected water quality condition, the automatic feeder is arranged at the same time, and the labor cost can be reduced.

Drawings

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

Fig. 2 is a schematic structural view of the cultivation barrel of the utility model.

Fig. 3 is a schematic view of the anti-overflow drain pipe of the present invention.

Fig. 4 is a plan view of the water treatment apparatus of the present invention.

Fig. 5 is a schematic structural view of the biological filtration zone of the present invention.

In the figure, 1-culture barrel, 2-water supply pipe, 3-protein separator, 4-main water supply pipe, 5-escape-proof net, 6-glass fiber reinforced plastic grid type pedestrian frame, 7-feeding tray, 8-overflow-proof drain pipe, 9-main oxygen supply pipe, 10-sterilizing lamp, 11-water supply area, 12-sterilizing area, 13-biological filtering area, 14-polyethylene or polypropylene suspension filler, 15-brush, 16-biological biochemical tank, 17-main water return pipe, 18-control box, 19-micro-filter, 20-fan, 21-water pump, 22-water quality monitoring equipment, 23-automatic feeder, 24-dissolved oxygen cone, 25-pure oxygen tank, 26-water pump, 27-heat pump, 28-PH value regulation barrel, 29-salinity regulating barrel and 30-volcanic rock.

Detailed Description

Referring now to the drawings in further detail, it is noted that the terms "front," "back," "left," "right," "upper" and "lower" used in the following description refer to directions in the drawings, and the terms "inner" and "outer" refer to directions toward and away from, respectively, the geometric center of a particular component.

As shown in fig. 1-5, the cultivation barrel 1 is a conical barrel with a large top and a small bottom, a feeding tray 7 and an oxygen adding pipe 901 are arranged in the barrel, a water supply pipe 2 and an escape-proof net 5 are arranged on the top of the barrel, a water outlet is arranged at the lowest conical position of the barrel bottom 101, an overflow-proof drain pipe 8 is arranged above the water outlet, a water outlet pipe 102 is arranged below the water outlet, a control switch 103 is arranged on the water outlet pipe 102 communicated with a water treatment device through a return water main pipe 17, a plurality of cultivation barrels 1 are arranged in multiple rows and multiple rows, and a glass fiber reinforced plastic grid type pedestrian frame 6 is arranged between every two rows. The water supply pipe 2 is provided with a switch 201 for controlling the water supply quantity, and the front and the back of the glass fiber reinforced plastic grid type pedestrian frame 6 are provided with an upper step 601 and a lower step 601.

The anti-overflow drain pipe 8 divide into inner tube 801, outer tube 802 and filter screen 803, inner tube 801 cover on breeding the delivery port of bucket 1, be equipped with pore apopore 805 around the pipe lower extreme, the overcoat has outer tube 802, the pipe lower extreme of outer tube 802 be equipped with macropore apopore 804 all around, the apopore outside is wrapped with filter screen 803, can prevent like this that aquatic products from running out from the delivery port, anti-overflow drain pipe 8 highly will be than breeding bucket 1 low 10-20 cm.

The water treatment device comprises a micro-filter 19, a protein separator 3, a sewage suction device and a biological biochemical pool 16, wherein the micro-filter 19 can be fully automatically back flushed and is provided with a water inlet pipe 1902 and a water outlet pipe 1901, the water inlet pipe 1902 is communicated with a water return main pipe 17, a round barrel 1903 is arranged in the pipe to install a water quality monitoring device 22 and a water pump 21, the water outlet pipe 1901 is communicated with a water inlet pipe 301 of the protein separator 3, and the water outlet pipe 302 is communicated with a heat pump 27.

The protein separator 3 is used for treating protein in water and is provided with a water inlet pipe 301 and a water outlet pipe 302 which are communicated with the heat pump 27 for supplying water.

The water pump 21 is a flat push type water pump, water in the breeding barrel 1 is pumped to the water treatment device for treatment, the water level kept in the breeding barrel 1 cannot be higher than the water level kept in the water supply area 11, and the height difference between the water level and the water level cannot be larger than 50 CM.

The biological biochemical pool 16 is divided into three areas from left to right, namely a biological filtering area 13, a disinfecting and sterilizing area 12 and a water supply area 11, each partition plate is provided with a water passing port 136, the bottom of each partition plate is provided with a sewage suction device, and the outer side of the partition plate is provided with a heat pump 27, a PH value regulating barrel 28, a salinity regulating barrel 29 and dissolved oxygen degree regulating equipment 25.

Water quality monitoring facilities 22, be equipped with a plurality of water quality probes 2201 and monitor the breed district quality of water, its detection data of water quality probe 2201 is through connecting host computer and display screen, convert water quality data and show quality of water quality value, quality of water quality value simultaneously with can be connected and show with other various remote terminal, can establish the early warning value simultaneously, surpass and send the warning, water quality probe 2201 include temperature probe, PH value probe, salinity probe, nitrite and nitrate sum probe, dissolved oxygen volume probe, ORP redox potential probe, dissolved solids total amount probe and ammonia nitrogen probe etc..

The control box 18 controls the operation of the protein separator 3, the microfilter 19, the fan 20, the water pump 21, the water quality monitoring device 22, the heat pump 27, the pH value regulation and control barrel 28, the salinity regulation and control barrel 29, the 26-water pump, the dissolved oxygen degree regulation and control device and the automatic feeder 23, wherein the control box is preset with basic required values of water quality and can receive the detection data of the water quality monitoring device 22, and after the detection data of the monitoring device is compared with the basic required values of the set water quality, the control box controls the start of the corresponding heat pump 27, the pH value regulation and control barrel 28, the salinity regulation and control barrel 29 and the dissolved oxygen degree regulation and control device according to the comparison result to regulate the temperature, the pH value, the salinity and the dissolved oxygen degree of the water quality.

The heat pump 27 is one of an air energy heat pump, a water source heat pump and a ground source heat pump, and is selected according to local climate, when the temperature detected by the temperature probe in the water quality probe 2201 is lower than a set value, the control box 18 starts the heat pump 27 to heat the water body, the highest heating temperature cannot exceed 15% of the set value, the water body cannot be heated to the set value once during heating, but the set value is adjusted by heating, temperature measuring and heating water for multiple times, and the influence on the cultured aquatic products is reduced.

The pH value regulating barrel 28 comprises an alkaline water barrel and an acid-alkali regulating pump 281, the alkaline water barrel and the acid-alkali regulating pump 281 are installed on the outer side of the water regulating area 161, when the salinity probe in the water quality probe 2201 detects that the pH value is lower than a set value, the control box 18 starts the acid-alkali regulating pump 281 to add high alkaline water in the alkaline water barrel of the pH value regulating barrel 28 to the water regulating area 161, the high alkaline water cannot be added to the set value once, but the set value is regulated to the set value through multiple cycles of high alkaline water, pH value measurement and high alkaline water, and the influence on cultured aquatic products is reduced.

The salinity regulating barrel 29 comprises a brine barrel and a salinity regulating pump 291, the salinity regulating pump 291 is arranged outside the water regulating area 161, when the salinity value detected by the salinity probe in the water quality probe 2201 is lower than a set value, the control box 18 starts the salinity regulating pump 291 to add the high salinity water in the brine barrel of the salinity regulating barrel 29 into the water regulating area 161, the high salinity water cannot be added to the set value once, but the set value is regulated by circulating the high salinity water, the salinity value detected and the high salinity water for multiple times, and the influence on the cultured aquatic products is reduced.

The dissolved oxygen degree regulating and controlling equipment comprises a dissolved oxygen cone 24 and a pure oxygen tank 25 which are arranged outside the water supply region 11, wherein the dissolved oxygen cone 24 is provided with a water inlet pipe 242 and a water outlet pipe 241, the water inlet pipe 242 takes water from the bottom of the front side of the water supply region 11, and the water supply port of the water outlet pipe 241 is arranged near the water outlet 401 of the water supply region 11 and is connected with the pure oxygen tank 25; when the dissolved oxygen amount detected by the dissolved oxygen amount probe in the water quality probe 2201 is lower than a set value, the control box 18 starts the salinity dissolved oxygen cone 24 to add oxygen to the water body through the dissolved oxygen cone 24 and the pure oxygen tank 25, the water body with the height in the water supply area 11 can not be added to the set value once when the water is added with oxygen, but the set value can be adjusted by multiple times of cycles of adding oxygen, detecting the dissolved oxygen amount and adding oxygen, the waste of the pure oxygen is reduced, and the culture cost is increased.

The automatic feeder 23 is arranged above the feeding tray 7, and can feed at regular time points or regular periods and also can be additionally provided with corresponding feeding channels.

The biological filtering area 13 is divided into four chambers, which are a water adjusting chamber 161, a volcanic rock bacteria cultivating chamber 131, a hairbrush bacteria cultivating chamber 132 and a polyethylene or polypropylene suspended filler bacteria cultivating chamber 133 from left to right, wherein water passing ports 136 are formed in the partition plates from the front top to the rear bottom alternately to enable the bacteria cultivating chambers to be communicated with each other, and the leftmost water adjusting chamber 161 is communicated with a water outlet pipe 271 of the heat pump 27. The biological filter area 13 is formed by sequentially arranging three bacteria culture materials, namely, volcanic rock 30, brush 15 and polyethylene or polypropylene suspension filler 14, so that propagation of nitrobacteria, nitrosobacteria and denitrifying bacteria is facilitated, the water treatment capacity can be improved, the bacteria culture quantity ensures that water treated by various harmful substances (such as ammonia nitrogen, nitrite and hydrogen sulfide) generated in the culture process is suitable for growth of aquatic products, and the water outlet 136 is designed from the front top to the rear bottom in a staggered mode to increase the water stroke, so that the harmful substances are treated more fully by the water body.

The bottoms of the volcanic rock bacteria cultivating room 131, the brush bacteria cultivating room 132, the polyethylene or polypropylene suspension filler bacteria cultivating room 133 and the disinfection and sterilization area 12 are all set to be V-shaped 135, the lowest part of the volcanic rock bacteria cultivating room is provided with a sewage suction pipe 262 to pump away the old and dead bacteria and prevent the old and dead bacteria from influencing water, and the sewage suction pipe 262 is provided with a pore.

The volcanic rock cultivation room 131 is provided with a supporting plate 137 above the conical bottom 135, the volcanic rock 30 is placed, and the brush 15 is arranged above the volcanic rock 30.

The soil pick-up device include suction pump 26 and soil pick-up pipe 262, suction pump 26 be equipped with inlet tube 261 and outlet pipe 263, outlet pipe 261 and soil pick-up pipe 262 intercommunication, outlet pipe 263 gives microstrainer 19 feedwater, lets microstrainer 19 filter the waste of clean back reuse reduction to water.

The sterilizing lamp 10 comprises an ultraviolet sterilizing lamp and an ozone sterilizing lamp, and if the ozone sterilizing lamp is placed in the last process, redundant ozone is removed to prevent the influence on aquatic products.

The oxygenation device comprises a fan 20 and an oxygenation main pipe 9, the fan 20 supplies oxygen to the culture barrel and the biological biochemical pool 16 through oxygenation pipes 901 communicated with the oxygenation main pipe 8 and a plurality of oxygenation pipes 903, and each oxygenation pipe 901 (903) is a nano aeration pipe for water and is provided with a switch 902 for controlling the air volume.

The water circulation process: the sewage in each breeding barrel 1 enters a return main pipe 17 through a water outlet and enters a micro-filter 19 for physical filtration through a water inlet pipe 1902 of a water supply micro-filter of a water pump 21, a filtered water outlet pipe 1901 enters a protein separator 13, the water is deproteinized and then is supplied to a heat pump 27 from a water outlet pipe 302 and then is communicated with a biological filtration area 13 for water supply, ammonia nitrogen and nitrite are removed through bacteria cultured by an indoor water volcanic rock 30, a brush 15 and a polyethylene or polypropylene suspension filler 14, so that the ammonia nitrogen and the nitrite are reasonably ranged, the treated water enters a disinfection and sterilization area from a right water gap 136 and is disinfected and sterilized by a plurality of disinfection light pipes 10, then enters a water supply area 11 through a water gap, and the clean water flows into a water main pipe 4 from the water outlet 401 and then is distributed to each water supply pipe 2 to supply water to each breeding barrel 1.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of modifications and variations can be made without departing from the technical principle of the present invention, and these modifications and variations should also be regarded as the protection scope of the present invention.

Claims (7)

1. A distributed circulating water factory-like intelligent seawater culture device comprises a culture barrel, an intelligent device, a water treatment device and an oxygenation device, and is characterized in that the culture barrel is a conical barrel with a large upper part and a small lower part and a conical bottom, a feeding disc and an oxygenation pipe are arranged in the barrel, a water supply pipe and an anti-escape net are arranged on the top of the barrel, a water outlet is arranged at the lowest part of the conical barrel bottom, an anti-overflow drain pipe is arranged above the water outlet, a water outlet pipe with a control switch is arranged below the water outlet pipe, the water outlet pipe is communicated with the water treatment device through a backwater main pipe, a plurality of culture barrels are arranged in a multi-row and multi-row distribution manner, a glass fiber reinforced plastic grid type pedestrian frame is arranged between every two rows of pedestrian frames, the intelligent device comprises a water quality monitoring device, an automatic feeder, a control box, a heat pump, a PH value regulation barrel, a salinity regulation barrel and an oxygen solubility regulation device, and is arranged at corresponding positions of the culture barrel and the water treatment device, the water treatment device comprises a micro-filter, a protein separator, a sewage suction device and a biological biochemical pool, wherein the micro-filter can be fully automatically backwashed and is provided with a water inlet pipe and a water outlet pipe, the water inlet pipe is communicated with a backwater main pipe, a barrel is arranged in the pipe to install a water quality monitoring device and a water pump, the water outlet pipe is communicated with the protein separator, a heat pump and the biological biochemical pool through a pipeline, the biological biochemical pool is respectively divided into a biological filtering area, a sterilizing area and a water feeding area from left to right, each area partition plate is provided with a water inlet and a sewage suction device at the bottom, the heat pump, a PH value regulating and controlling barrel, a salinity regulating and controlling barrel and a dissolved oxygen regulating and controlling device are respectively arranged at the periphery of the outer side, the oxygen suction device comprises a fan and an oxygen adding main pipe, and the fan is communicated with an aeration pipe through the oxygen adding main pipe to add oxygen to the culture barrel and the biological biochemical pool.

2. The distributed circulating water industrial intelligent mariculture device according to claim 1, wherein the anti-overflow drain pipe is divided into an inner pipe, an outer pipe and a filter screen, the inner pipe is sleeved on a water outlet of the culture barrel, fine water outlet holes are formed in the periphery of the lower end of the inner pipe, the outer pipe is sleeved outside the inner pipe, large holes are formed in the periphery of the lower end of the outer pipe and serve as water outlet holes, and the filter screen is wrapped outside the water outlet holes.

3. The distributed circulating water industrial intelligent mariculture device according to claim 1, wherein the biological filtering area is divided into four chambers, namely a water adjusting chamber, a volcanic rock bacteria culturing chamber, a hairbrush bacteria culturing chamber and a polyethylene or polypropylene suspended filler bacteria culturing chamber from left to right, water passing ports are formed in the partition plates of the chambers at intervals from the front top to the rear bottom respectively to enable the bacteria culturing chambers to be communicated with each other, and the leftmost water adjusting chamber is communicated with a water outlet pipe of the heat pump.

4. The distributed circulating water industrial intelligent mariculture device according to claim 3, wherein the bottoms of the volcanic rock culture rooms, the brush culture rooms and the polyethylene or polypropylene suspension filler culture rooms are tapered, and a sewage suction pipe is installed at the lowest position of each culture room.

5. The distributed circulating water industrial intelligent mariculture device according to claim 1, wherein the water pump is a horizontal pushing type water pump, water in the culture barrel is pumped to the water treatment device for treatment, the water level in the culture barrel cannot be higher than the water level in the water supply area, and the height difference between the water level in the culture barrel and the water level in the water supply area cannot be larger than 50 CM.

6. The distributed circulating water industrial intelligent mariculture device according to claim 1, wherein the water quality monitoring device is provided with a plurality of water quality probes for monitoring the quality of water in the culture area, the detection data of the water quality probes are converted into water quality data and display parameter values for measuring the quality of the water quality by connecting a host and a display screen, and the parameter values for measuring the quality of the water quality can be connected with various remote terminals and displayed at the remote terminals.

7. The distributed circulating water industrial intelligent mariculture device according to claim 1, wherein the control box is preset with basic required values of water quality and can receive detection data of a water quality monitoring device, and after the detection data of the monitoring device is compared with the basic required values of the water quality, the control box controls the corresponding heat pump, the pH value regulating barrel, the salinity regulating barrel and the dissolved oxygen regulating device to stop and start according to the comparison result, so that the aims of regulating the temperature, the pH value, the salinity and the dissolved oxygen of the water quality are fulfilled.

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