TWI780632B - Aquaculture Recirculating Culture System - Google Patents

Abstract

The present invention refers to an aquaculture circulation system, wherein, in the aquaculture system, the aquaculture tank is provided with a tank wall above the base, the tank wall is separately provided with a vertical wall, and a temperature insulation space is maintained between the vertical walls. The variable temperature container is provided with a variable temperature chamber connected with a temperature raising machine and a cooling machine. Filtration and recovery devices are distributed around the culture tank. The chamber of the filtration and recovery devices is embedded with a filter area, a filter clean room and a de-float chamber. The de-float chamber is connected with a de-float recovery container. The air tank is connected with a non-powered hydraulic pump, and the non-powered hydraulic pump is upwardly connected with a driving water tank, and a hydraulic generator is connected with a hydraulic generator below the driving water tank, and the hydraulic generator is connected with a storage battery. The ultra-microbubble device is distributed with high-pressure components, the Venturi hole of the high-pressure component is connected to the driving water tank, a pressurized narrow section is arranged in the middle of the Venturi hole, and the gas pre-storage element is connected to it, and the other end of the Venturi hole is connected to the culture tank.

Description

Aquaculture Recirculation System

The present invention relates to an aquaculture circulation system, wherein the culture tank is provided with a culture space for containing water, and the water is circulated and filtered while driving a hydraulic generator to generate electric energy.

The first button refers to the current land-based aquatic product A0 farming, which mainly uses the fish farm 10 to breed aquatic products A0. Before the fish farm 10 is established, an open-air pit 101 needs to be dug. It takes at least three months after the pit 101 is dug. After exposure to the sun and making the bottom, enter the water B0 into the pit 101 to raise the water B0, and then enter the aquatic product A0 culture, so as to minimize the loss of aquatic product A0. However, due to the open air, climate change and natural disasters will directly invade the fish farm 10, the loss of aquatic products A0 cannot be predicted, and the water pump C0 and breeding equipment D0 for the quality control of the water B0 need to be purchased in large quantities at high prices. Only by selling electricity can we barely maintain the normal operation of fish farm 10. Moreover, aquatic A0 farming is easily affected by nutrient feeding and sinking to the bottom, the pollution and abnormal changes of pit 101, and climate interference factors. As a result, aquatic A0 farming must follow: The larvae, subadults and adults should be kept in different ponds in different stages. At the same time, the number of aquatic products A0 must be strictly limited (as shown in Figure 1).

Therefore, there is the birth of the intensive tank 20 for indoor cultivation. The intensive tank 20 is equipped with a filter 201 to stabilize the water quality, so that the aquatic products A0 are cultivated in the intensive tank 20 without having to endure: feeding and ingesting the water B0 that sinks to the bottom is of high quality, oxidized, Pollution and mutation of water B0, larvae, subadults, and adults are kept in different ponds, as well as climate change and natural disasters. In addition, the use of filter 201, water dispenser C0 and breeding equipment D0 is still It is necessary to purchase a large amount of high-priced commercial electricity to maintain the normal operation of the intensive tank 20, so that the operating cost of the intensive tank 20 cannot be effectively reduced (as shown in Figure 2).

In addition, if the intensive tank 20 needs to control the temperature of the water B0, most of them will choose the commercially available heater 202, but the heater 202 is not suitable for use in the intensive tank 20 with a large amount of water B0, the reason is that the heater 202 will cause: Consuming a large amount of purchased high-priced commercial electricity, the local water B0 temperature in the intensive tank 20 is too high to easily damage the aquatic product A0, and the uneven temperature of the water B0 will make the aquatic product A0 unable to adjust and adapt. Therefore, how to save electricity costs, how to effectively and evenly regulate the water B0 temperature, and how to expand the cultivation to different environmental areas are already issues that need to be solved urgently (such as: shown in Figure 2).

In view of the above-mentioned fact that conventional farming consumes a large amount of purchased high-priced commercially available electricity and the benefits of water temperature control are extremely low, therefore, the inventors of this case are driven to reduce and eliminate the purchase of high-priced commercially available electricity and stable control of water temperature The direction of research and development, and through the inventor of this case thinks in many ways, then thinks, it is best to drive the hydroelectric generator to generate electric energy system while utilizing water circulation to filter and use.

The aquaculture circulation system of the present invention includes: a storage battery, a breeding tank, a temperature adjustment device, a filtration recovery device, a step circulation device, a hydroelectric generator, an ultramicro bubble device and a controller. The aquaculture system is provided with the storage battery that supplies all the power used. The culture tank is provided with a base, and a tank wall extending upwards is formed around the base. The tank wall surrounds a culture pond, and the culture pond contains For water and aquatic products, a temperature-regulating pipe for adjusting the temperature of the water is distributed in the culture pond, and a temperature-regulating liquid circulates inside the temperature-regulating pipe, and the temperature-regulating pipe is distributed with an inlet joint and an outlet joint protruding from the culture pond. Temperature-measuring elements for measuring the temperature of the water are distributed in the culture pond, and the tank wall is divided into three vertical walls, and a hollow temperature-insulation space is kept between the vertical walls. The temperature adjustment is distributed around the breeding tank device, the temperature adjustment device is distributed with a temperature variable container, the temperature variable container is provided with a variable temperature chamber containing the temperature regulating liquid, and the temperature variable container is connected with the temperature measuring element inserted into the temperature variable chamber to measure the temperature of the temperature regulating liquid , the temperature adjustment device is distributed with a first pump that draws the temperature adjustment liquid in the variable temperature chamber into the temperature adjustment tube by connecting the inlet joint, and the temperature adjustment tube circulates the temperature adjustment liquid back through the outlet joint The variable temperature chamber; the temperature adjusting device is distributed with a temperature raising machine and a cooling machine. For the second pump of the element, the temperature adjusting device is distributed with a temperature increasing circulation pipe connecting the temperature adjusting liquid of the temperature raising element into the variable temperature chamber. The cooling machine is provided with a cooling element for cooling the temperature-regulating liquid. The temperature-adjusting device is distributed with the third pump that draws the temperature-regulating liquid in the temperature-variable chamber into the cooling element. The temperature-adjusting device is distributed with a The temperature-regulating liquid in the element enters the cooling circulation pipe of the variable temperature chamber. The fourth pump for pumping the water is distributed around the culture tank, and the fourth pump is at least connected to the filter recovery device. The filter recovery device is distributed with a chamber, and a filter body is embedded in the chamber. The chamber is divided into a filter chamber and a defloatization chamber by the filter body. The defloatization chamber is at least connected to a defloatation recovery container, and the fifth pump for pumping the water is distributed around the filter chamber. The chamber is connected to a step circulation device through the fifth pump, and the step circulation device is distributed with aeration tanks from high to low, and the aeration tank at the top of the step circulation device is connected to the fifth pump around the filter room. pump, the aeration tank is connected to the lower aeration tank from the height, at least the lowest aeration tank is connected to the culture pond, and the high aeration tank is connected to three to eight water tanks downward. Driven unpowered hydraulic pump, under the unpowered hydraulic pump, there is an overflow tank to accommodate the water, and the overflow tank indirectly draws the overflow pump of the full water, and the overflow pump faces upwards It is connected with a driving water tank for accommodating the water, and the unpowered hydraulic pump is connected with the driving water tank upwards, and the driving water tank is connected with the hydraulic generator driven by the water to generate electricity, and the hydraulic generator is connected with a storage place the accumulator generating electricity, and the hydroelectric generator The bottom communicates with the aeration tank. The aquaculture circulation system is provided with a gas control ratio device, the gas control ratio device is distributed with a gas pre-storage element, the gas pre-storage element stores: hydrogen, oxygen; A Venturi hole is provided, one end of the Venturi hole communicates with the sixth pump, and the sixth pump at least communicates with the driving tank. And the Venturi hole is provided with a small-diameter pressurized narrow section in the middle, and an air inlet is provided on the side of the pressurized narrow section, and the air inlet is connected with a solenoid valve, and the air inlet is connected with the gas pre-heater through the solenoid valve. storage element. The other end of the Venturi hole is connected to a solenoid valve, and the Venturi hole is connected to a pressure vessel through the solenoid valve. The pressure vessel is distributed with a water outlet pipe, and the water outlet pipe is connected to the solenoid valve. It communicates with a spray head, the spray head at least communicates with the aeration tank, and the spray head at least communicates with the culture pond. The controller uses the temperature measuring element to detect and set the predetermined temperature of the water in the culture pond and the temperature regulating liquid in the variable temperature chamber, and the temperature of the water and the temperature regulating liquid detected by the temperature measuring element makes the The controller at least activates and deactivates the temperature raising machine and the cooling machine.

The heating element of the present invention is provided with a heating chamber for containing the temperature-regulating liquid. The heating chamber is equipped with a temperature-raising tube for raising the temperature of the temperature-regulating liquid. The temperature-raising tube circulates a medium oil. The temperature-raising tube is outside the temperature-raising element. It is connected with a thermal medium heater which circulates and heats the medium oil. The thermal medium heater is provided with a solar heat collecting umbrella, and the center of the solar heat collecting umbrella is upwardly connected with a heat collector. The heat medium part of the device, there is an oil medium chamber inside the heat medium part, the oil medium chamber contains medium oil, and the heat medium heater distributes the oil medium that draws the medium oil in the oil medium chamber to the heat collector pump, the heat collector is connected with an oil medium conduit that is connected in series with the heat collector and circulates the medium oil back to the oil medium chamber. The heat medium part is provided with a temperature-regulating pump for circulating the medium oil to the heating tube in the oil medium chamber, and the heating tube is connected with a temperature rising return pipe for circulating the medium oil back to the oil medium chamber, and the controller is based on the Control the temperature of the temperature-regulating liquid measured by the temperature-measuring element, and start and stop the oil-medium pump and the temperature-regulating pump.

The temperature adjustment device of the present invention is distributed with a heat medium heater, and the heat medium heater is provided with a solar heat collecting umbrella, and the center of the sun heat collecting umbrella is upwardly connected with a heat collector, and the heat medium heater is distributed with a The heat medium part of the heater, the heat medium part is provided with an oil medium chamber inside, the oil medium chamber contains medium oil, and the heat medium heater distributes the oil that draws the medium oil in the oil medium chamber to the heat collector Medium pump, the heat collector is connected with the oil medium pipe which is connected in series with the heat collector and circulates the medium oil back to the oil medium chamber; the heat medium part is provided with a heating interface for circulating the temperature regulating liquid in the oil medium chamber The heating interface tube is connected with a temperature-regulating liquid pump that circulates the temperature-regulating liquid to the variable temperature chamber outside the heat medium part, and the controller controls and starts and shuts down the temperature-adjusting liquid according to the temperature measured by the temperature-measuring element. Oil-medium pumps and the temperature-regulated liquid pumps. The cooling element is equipped with a cooling chamber for containing the temperature-regulating liquid, and the cooling chamber is equipped with a cooling pipe for cooling the temperature of the temperature-regulating liquid. The cooling pipe circulates a refrigerant liquid, and the cooling pipe is connected to a loop outside the cooling element. A refrigerant cooler for cooling the refrigerant liquid.

The bottom side of the culture pond of the present invention is coiled with the temperature regulating pipe, and the bottom side of the culture pond is coiled with the temperature regulating pipe in a circular spiral manner. And the cultivation pool is distributed with planting supports laid floating on the water surface, planting tanks are distributed above the planting supports, water permeable holes are pierced under the planting tanks, planting inlays are embedded in the planting tanks, and planting inlays are embedded in the planting tanks. Inlays are planted with the hydroponic crops. In addition, the spiral temperature-regulating tube is distributed in the culture pond, and the temperature-regulating pipe is hung around the culture pond.

The aquaculture circulation system of the present invention is distributed with a solar panel capable of generating electricity, a wind power generator capable of generating electricity, and a solar heat collection sleeve group. The solar panel and the wind generator are connected with the storage battery that stores the generated electricity. Inside the heating element is a heating chamber for containing the temperature-regulating liquid. The heating chamber is equipped with a heating tube to increase the temperature of the temperature-regulating liquid. The heating tube circulates a medium oil, and the heating tube is connected to a loop A solar heat collecting sleeve group for heating the medium oil, the solar heat collecting sleeve group is distributed with a solar heat collecting tube, and the solar heat collecting sleeve group is distributed with a The heat medium part, the heat medium part is equipped with an oil medium chamber, the oil medium chamber contains medium oil, and the heat medium part is distributed with an oil medium pump that pumps the medium oil in the oil medium chamber to the solar heat collecting tube , the solar heat collecting tube is also connected with the heat collecting tube oil medium conduit which is connected in series with the solar heat collecting tube and circulates the medium oil back to the oil medium chamber. The heat medium part is provided with a temperature-regulating pump for circulating the medium oil to the heating tube in the oil medium chamber, and the heating tube is connected with a temperature rising return pipe for circulating the medium oil back to the oil medium chamber, and the controller is based on the The temperature of the temperature-regulating liquid measured by the temperature-measuring element controls and activates and shuts down the oil-medium pump and the temperature-regulating pump.

The driving water tank of the present invention is connected with a water delivery pipe from one to three inches and downwards to output the water. The water delivery pipe is connected with the impeller added to the hydroelectric generator. There is a flat impeller chamber inside the impeller chamber. The lower side is provided with an outlet pipe for outputting the water to the aeration tank; the impeller chamber is pivotally connected with an impeller driven by the water, and the center of the impeller has an impeller mandrel protruding downward from the impeller machine, and the impeller mandrel At least one gravity maglev group is connected under the impeller, and the gravity maglev group is distributed with a fixed homopolar magnetic part and a rotating homopolar magnetic part. The fixed homopolar magnetic part is provided with a concave magnetic chamber, and the central magnetic chamber The magnetic floating shaft hole is pierced, and the nanomagnetic chamber is distributed with magnets of the same polarity. The center of the rotating homopolar magnetic part is fixed with the impeller mandrel, and the rotating homopolar magnetic part is distributed with the impeller mandrel. Weight plate, counterweight blocks are distributed around the counterweight plate, the rotating homopolar magnetic part has a homopolar rotating part extending into the nano-magnetic chamber, and the homopolar rotating part is fixed with a rotating part corresponding to the homopolar magnet Homopolar magnets, and the homopolar rotating part has a magnetic floating shaft passing through the gravity magnetic floating group through the magnetic floating shaft hole. The magnetic floating shaft is fixed with a transmission rotating body under the gravity magnetic floating group. There are two to four hydroelectric generators capable of generating electric energy, and the hydroelectric generators are additionally provided with a generator rotating body screwed to the transmission rotating body, and the electricity generated by each hydroelectric generator is stored in the storage battery. The accumulator drives the stored electric power to have three to six multiplier power generators, and the multiplier power generators are additionally provided with: a motor, a counterweight magnetic levitation device and a rear generator. The electric power stored in the storage battery at least drives the motor, and the motor drives at least one counterweight magnetic levitation device, and the counterweight magnetic levitation device is distributed There are: a fixed magnetic levitation unit with the same polarity and a magnetic levitation unit with the same polarity rotated. The fixed homopolar magnetic floating part is provided with a magnetic receiving part, and the central magnetic receiving part is pierced with a magnetic receiving part perforation, and the magnetic receiving part is distributed with the same magnetic body; the center of the rotating magnetic floating part with the same polarity is provided with the motor The rotating mandrel, the rotating copolar magnetic levitation part is distributed with the rotating counterweight plate pierced by the rotating mandrel, and the rotating counterweight is distributed on the periphery of the rotating counterweight, and the rotating copolar The magnetic levitation part has a co-rotating co-polar part extending into the magnetic receiving part, and the co-rotating co-polar part is fixed with a co-rotating co-polar magnet corresponding to the co-magnetic body, and the co-rotating part has A rotating mandrel of the counterweight maglev is perforated by the magnetic receiving part, and the rotating mandrel is fixed with a rotating transmission rotating body outside the counterweight maglev, and the rotating transmission rotating body is screwed to Drive a rear generator that can generate electric energy. The rear generator is provided with a rear generator rotor that is screwed to the rotating drive and has a rotation ratio of three to one to four to one. Each of the rear generators Generated electricity is stored in the battery.

The main purpose of the present invention is: the aquaculture circulation system is provided with the storage battery that supplies all the electricity used, and the aquaculture tank is provided with the tank wall above the base to surround the aquaculture pond, and the aquaculture pond contains water and aquatic products. A temperature-regulating tube for adjusting the temperature of the water is distributed in the culture pond, the temperature-regulating liquid circulates inside the temperature-regulating pipe, and the temperature-measuring element for measuring the temperature of the water is distributed in the culture pond. The temperature-variable container is assembled with the temperature-measuring element inserted into the temperature-variable chamber to measure the temperature of the temperature-regulating liquid, and the temperature adjustment device is distributed with the first device for extracting the temperature-regulated liquid in the temperature-variable chamber into the temperature-regulating tube. pump, the temperature regulating tube circulates the temperature regulating liquid back to the variable temperature chamber. The temperature adjusting device is distributed with a temperature raising machine and a cooling machine. Control the temperature of the temperature-regulating liquid, and then use the temperature-regulating liquid to circulate and adjust the temperature of the water in the culture pond; The preset temperature of the warming liquid, and the temperature of the water and the temperature-regulating liquid detected by the temperature measuring element makes the controller operate the heating element and the Substantial benefits of cooling elements.

Another object of the present invention is: the cultivation tank is connected with the filter recovery device, the filter recovery device is embedded with the filter body in the container, and the filter body is used to partition the filter room and the removal chamber. Floating chamber, the defloating chamber communicates with the defloating recovery container, and the filter chamber communicates with the aeration tank of the step circulation device, and the aeration tank at the top of the step circulation device communicates with the fifth pump, The aeration tank is connected with the aeration tank at the lower part by the high part, and the aeration tank at the high part is connected with three to eight non-powered hydraulic pumps driven by the water downwards. The hydraulic pump communicates upward with the drive water tank, and the water drive water tank below communicates with the water-driven generator that generates electricity, and the hydraulic generator is connected with the substantial benefit of storing the battery that generates electricity.

Another purpose of the present invention is: the tank wall is divided into three vertical walls, and the substantial benefit of maintaining a hollow temperature-insulating space between the vertical walls.

Another object of the present invention is: the gas pre-storage element is distributed in the gas control ratio device to store hydrogen and oxygen. The ultramicrobubble device is distributed with a high-voltage element, the high-voltage element is provided with the Venturi hole, and one end of the Venturi hole is connected with the driving water tank. And the pressurized narrow section with a small diameter is provided in the middle of the Venturi hole, and the air inlet hole is provided on the side of the pressurized narrow section to communicate with the gas pre-storage element. The other end of the Venturi hole is communicated with the pressure vessel, and the pressure vessel is communicated with the substantial benefits of the aeration tank and the culture pond through the electromagnetic valve.

Yet another object of the present invention is: the heat medium heater is provided with the solar heat collecting umbrella with the center facing upwards to connect the heat collector, the oil medium chamber of the heat medium part contains the medium oil, and the oil medium chamber in the oil medium chamber The medium oil circulates back to the oil medium chamber from the heat collector; the heat medium part is equipped with the temperature regulating pump that circulates the medium oil to the heating pipe in the oil medium chamber, and the heating pipe is connected to circulate the medium oil The substantive benefit of the temperature rise return pipe back to the oil medium chamber.

Another object of the present invention is: the heat medium heater is provided with the solar heat collecting umbrella with the center upwardly connected to the heat collector, the oil medium chamber of the heat medium part contains the medium oil, and the oil medium chamber in the oil medium chamber The medium oil is circulated back to the oil medium chamber from the heat collector; the heat medium part is provided with the heated interface tube circulating the temperature regulating liquid in the oil medium chamber, and the heated interface pipe circulates the temperature regulating liquid to the variable temperature capacitor chamber; the cooling element is provided with the cooling chamber containing the temperature-regulating liquid, and the cooling chamber is equipped with the cooling tube for cooling the temperature of the temperature-regulating liquid to circulate the refrigerant liquid, and the cooling tube is connected with a circulation loop outside the cooling element. Substantial benefit of the refrigerant cooler for cooling the refrigerant liquid.

Yet another object of the present invention is: the cultivation pond is distributed with the planting support floating on the water surface, and the substantive benefits of the hydroponic crops are planted on the planting support.

Another object of the present invention is: the heating chamber is set up with the heating tube to circulate the kerosene, the heating tube is connected with the solar heat collection sleeve group that circulates and heats the kerosene, and the solar heat collection sleeve set is distributed with communication channels. The heat medium part of the solar heat collecting tube, the oil medium chamber of the heat medium part contains the medium oil, and the circulation between the heat medium part and the solar heat collecting tube has the substantial benefit of the medium oil.

Another object of the present invention is that the driving water tank is connected with the water supply pipe and the impeller, the impeller chamber is pivotally connected with the impeller inside the impeller, the gravity maglev assembly is connected with the impeller mandrel in the center of the impeller, and the gravity The fixed homopolar magnetic part of the maglev group is provided with the nano-magnetic chamber, the nano-magnetic chamber is distributed with the homopolar magnet, the center of the rotating homopolar magnetic part is fixed with the impeller mandrel, and the rotating homopolar magnetic part is distributed There is the counterweight disc driven by the impeller spindle, the counterweight is distributed around the counterweight disc, the rotating homopolar magnetic part has the homopolar rotating part extending into the nano-magnetic chamber, and the homopolar rotating part The same polarity magnet of the rotation part corresponding to the same polarity magnet is fixed on the part of the rotation part, and the magnetic levitation shaft of the same polarity rotation part is fixed with the transmission rotation body under the gravity maglev group, and the transmission rotation body is screwed to drive two To four hydroelectric generators capable of generating electric energy, the hydroelectric generator is additionally provided with a generator swivel that is screwed to the transmission swivel, and each of the hydroelectric generators generates electricity The substantial benefits stored in the accumulator.

Yet another object of the present invention is: the storage battery pack drives three to six power multiplication generators, and the motor of the power multiplication generator drives the counterweight magnetic levitation device with the power stored in the storage battery. The fixed homopolar magnetic levitation part of the heavy magnetic levitation device is provided with the magnetic receiving part, and the magnetic receiving part is distributed with the same magnetotropic body. In the center of the rotating homopolar magnetic levitation part, the rotating mandrel that is screwed to the motor passes through the rotating weight plate, and the rotating weight plate is distributed with the rotating weights on the periphery. The pole magnetic levitation part has the rotating homopolar part extending into the magnetic receiving part, and the rotating homopolar part is fixed with the rotating homopolar magnet corresponding to the same magnetic direction body, and the rotating homopolar The revolving mandrel on the head is fixed with the revolving transmission rotating body outside the counterweight magnetic levitation device, the revolving transmission rotating body is screwed to the rear generator, and the rear generator generates electricity and stores it into the storage battery. .

[knowledge]

A0: Aquatic products

B0: water

C0: water dispenser

D0: farming equipment

10: Fish farm

101: Pit

20: Intensive slot

201: filter

202: heater

〔this invention〕

A: water

A1: Aquatic products

A11: Defloating

A12: Micro bubbles

A2: Tempering liquid

A3: Crops

B: temperature measuring element

C: pump

D: Solenoid valve

E: kerosene

F1: solar panel

F2: wind turbine

1: Aquaculture Recirculating Culture System

11: Battery

12: breeding tank

121: base

122: groove wall

1221: vertical wall

1222: Insulation space

123: Breeding pond

124: thermostat tube

1241: import connector

1242: lead out connector

125: planting carrier

1251: planting tank

1252: water hole

1253: Implant inlay

13: Temperature adjustment device

131: variable temperature container

1311: variable temperature chamber

132: Heating machine

1321: heating element

13211: liter greenhouse

13212: heating tube

1322: warming circulation tube

133: cooling machine

1331: cooling element

13311: cooling room

13312: cooling tube

13313: Refrigerant liquid

13314: Refrigerant cooler

1332: cooling circulation tube

14: Filtration recovery device

141: Containment room

1411: clean room

1412: Defloating chamber

1413: Defloat recovery container

142: filter body

15: Class cycle device

151: Aeration tank

152: Unpowered hydraulic pump

153: overflow tank

154:Overflow pump

155: drive sink

1551: water pipe

16: Hydroelectric Generator

16A: Generator swivel

161: impeller

1611: impeller chamber

1612: outlet pipe

1613: impeller

1614: impeller mandrel

17: Ultramicro Bubble Device

171: High voltage components

1711: Venturi hole

1712: pressurized narrow section

1713: air intake

172: Pressure vessel

1721: outlet pipe

1722: Nozzle

18: Controller

19: Air control proportional device

191: Gas pre-storage element

2: heat medium heater

21: Solar umbrella

211: Collector

22:Heat Media Department

221: Oil media room

222: Heating interface tube

23:Oil medium pump

24: oil medium conduit

25:Temperature pump

26: Heating return tube

27:Temperature liquid pump

3: Solar collector sleeve group

31: Solar collector tube

4: heat collector tube oil medium conduit

5: Gravity maglev group

51: Fixed homopolar magnetic part

511: nanomagnetic chamber

512: Magnetic shaft hole

513: Homopolar magnets

52: Rotating homopolar magnetic part

53: Counterweight plate

531: Counterweight

532: homopolar spin

533: Spinning Homopolar Magnets

534: Maglev shaft

535: Transmission rotary body

6: Multiplier Power Generator

61: motor

62: counterweight maglev

621: fixed homopolar magnetic levitation part

6211:Nanomagnetic Department

6212: Nano magnetic part perforation

6213: Isotropic body

622: Rotate the magnetic levitation part of the same pole

6221: Spin the mandrel

6222: Rotate the balance plate

6223: Rotate counterweight

6224: Rotate the homopolar spin part

6225: Rotate to the same polarity magnet

6226: Rotating transmission rotary body

63: rear generator

631: Rear generator rotating body

[Picture 1] is a schematic diagram of a commonly used fish farm.

[Picture 2] is a schematic diagram of a commonly used intensive tank.

[Fig. 3] is a partially enlarged schematic diagram of the aquaculture recirculating culture system of the present invention.

[Fig. 4] is a schematic diagram of the unpowered hydraulic pump of the present invention.

[Fig. 5] is a schematic diagram of the heating machine and the solar heat collecting umbrella of the present invention.

[Fig. 6] is a schematic diagram of a temperature-variable container and a solar heat-collecting umbrella of the present invention.

[Fig. 7] is a schematic diagram of the cooling machine of the present invention.

[Fig. 8] is a schematic diagram of the culture pond of the present invention [the first top view.

[Fig. 9] is a schematic diagram of the culture pond of the present invention [the second top view.

[Fig. 10] is a schematic diagram of the planting support of the cultivation tank of the present invention.

[Fig. 11] is another schematic diagram of the aquaculture recirculation system of the present invention.

[Fig. 12] is a schematic diagram of the heating machine and the solar heat collecting sleeve assembly of the present invention.

[Fig. 13] is a schematic diagram of the impeller machine and gravity maglev assembly of the present invention.

[Fig. 14] is a schematic cross-sectional view of the gravitational maglev unit according to the present invention.

[Fig. 15] is a combined schematic view of the hydroelectric generator of the present invention.

[Fig. 16] is a schematic diagram of the power multiplication generator of the present invention.

In order to make your examiners have a further understanding of the present invention, the following examples are hereby described.

The present invention refers to an aquaculture circulation aquaculture system 1, wherein the aquaculture circulation aquaculture system 1 at least includes: a battery 11 distributed, a culture tank 12 distributed, a temperature adjustment device 13 distributed, a filter recovery device 14 distributed, a The cascade circulation device 15 is distributed with a hydroelectric generator 16 , a nanobubble device 17 and a controller 18 are distributed therewith. The aquaculture system 1 is provided with the storage battery 11 that supplies all the electricity used. The aquaculture system 1 is provided with at least one base 121 on the culture tank 12, and at least one upwardly extending tank wall 122 is provided around the base 121. The tank wall 122 surrounds at least one breeding pond 123, which contains water A and aquatic products A1, and is distributed with a temperature-regulating tube 124 for adjusting the temperature of the water A in the breeding pond 123. The temperature-regulating tube There is a temperature-regulating liquid A2 circulated inside the 124. The temperature-regulating pipe 124 is distributed with an inlet joint 1241 and an outlet joint 1242 protruding from the culture tank 123. A temperature-measuring element B for measuring the temperature of the water A is distributed in the culture tank 123. , and the tank wall 122 is provided with at least three vertical walls 1221, and a hollow temperature-insulating space 1222 is maintained between the vertical walls 1221. The aquaculture recirculating culture system 1 in the culture The temperature adjustment device 13 is distributed around the tank 12, and the temperature adjustment device 13 is distributed with a temperature variable container 131. The temperature variable container 131 is provided with at least one temperature variable chamber 1311 for containing the temperature regulating liquid A2. The temperature variable container 131 is assembled with a The temperature measuring element B that enters the variable temperature chamber 1311 to measure the temperature of the temperature regulating liquid A2, the temperature regulating device 13 is distributed with the temperature regulating liquid A2 in the temperature variable chamber 1311 and enters the temperature regulating liquid A2 by connecting the introduction joint 1241 The first pump C1 in the pipe 124 , and the temperature regulating pipe 124 circulates the temperature regulating liquid A2 through the outlet joint 1242 to flow back to the temperature variable chamber 1311 . The temperature adjusting device 13 is distributed with a heating machine 132 and a cooling machine 133. The heating machine 132 is provided with at least one heating element 1321 for heating the temperature regulating liquid A2. The warm liquid A2 enters the second pump C2 of the temperature raising element 1321 , and the temperature adjustment device 13 is distributed with a temperature increasing circulation pipe 1322 connecting the temperature adjusting liquid A2 of the temperature raising element 1321 into the variable temperature chamber 1311 . The cooling machine 133 is provided with at least one cooling element 1331 for cooling the temperature-regulating liquid A2, and the temperature adjusting device 13 is distributed with the third pump C3 for pumping the temperature-regulating liquid A2 in the variable temperature chamber 1311 into the cooling element 1331 The temperature adjusting device 13 is distributed with a cooling circulation pipe 1332 that communicates the temperature regulating liquid A2 in the cooling element 1331 into the variable temperature chamber 1311 . The fourth pump C4 for extracting the water A is distributed around the culture tank 12, and the fourth pump C4 is at least connected to the filter recovery device 14, and the filter recovery device 14 is distributed with a chamber 141, and the chamber 141 Embedded with a filter body 142, the chamber 142 uses the filter body 142 to separate a filter chamber 1411 and a defloatation chamber 1412. The fifth pump C5 for pumping the water A is distributed around, and the filter chamber 1411 is connected to at least one stage circulation device 15 through the fifth pump C5, and the stage circulation device 15 has at least five stages from high to low. The aeration tank 151, the aeration tank 151 at the top of the step circulation device 15 is connected with the fifth pump C5 distributed around the filter chamber 1411, the aeration tank 151 is connected with the aeration tank at the lower level 151, at least the lowest aeration tank 151 is connected with the culture pond 123, and the aeration tank 151 in the high place is at least connected with three to eight motionless tanks driven by the water A downwards. Power water lifting pump 152, under this unpowered water lifting pump 152, there is an overflow capacity tank 153 for containing the water A, and the overflow capacity tank 153 indirectly draws the overflow capacity pump 154 of the water A that is full, the overflow capacity The pump 154 communicates upward with a drive water tank 155 for accommodating the water A, and the unpowered hydraulic pump 152 communicates with the drive water tank 155 upward, and the drive tank 155 communicates with the water A to drive the hydraulic power to generate electricity. Generator 16, the hydroelectric generator 16 is connected with the accumulator 11 storing the generated electricity, and the aeration tank 151 is communicated with the hydroelectric generator 16 below. The aquaculture system 1 is at least provided with a gas control proportional device 19, and the gas control proportional device 19 is distributed with a gas pre-storage element 191, and the gas pre-storage element 191 stores at least hydrogen and oxygen. The microbubble device 17 is distributed with a high-pressure element 171, and the high-pressure element 171 is provided with a Venturi hole 1711, and one end of the Venturi hole 1711 is connected to a sixth pump C6, and the sixth pump C6 is at least connected to the driving tank 155 and the middle of the Venturi hole 1711 is provided with a small-diameter pressurized narrow section 1712, and the side of the pressurized narrow section 1712 is provided with an air inlet 1713, and the air inlet 1713 communicates with a solenoid valve D, and the air inlet 1713 passes through The solenoid valve D communicates with the gas pre-storage element 191 . The other end of the Venturi hole 1711 is connected to a solenoid valve D, and the Venturi hole 1711 is connected to a pressure vessel 172 through the solenoid valve D. The pressure vessel 172 is distributed with a water outlet pipe 1721, and the water outlet pipe 1721 is connected to at least one electromagnetic valve. Valve D, the pressure vessel 172 communicates with at least one nozzle 1722 through the electromagnetic valve D, the nozzle 1722 communicates with the aeration tank 151 at least, and the nozzle 1722 communicates with the culture pond 123 at least. The controller 18 uses the temperature measuring element B to detect and set the predetermined temperature of the water A in the culture pond 123 and the temperature regulating liquid A2 in the variable temperature chamber 1311, and the water detected by the temperature measuring element B The temperature of A and the temperature-regulating liquid A2 makes the controller 18 at least activate and deactivate the temperature raising machine 132 and the cooling machine 133 (as shown in FIG. 3 ).

Yes, the tank wall 122 of the culture tank 12 is provided with the vertical wall 1221, and the hollow temperature insulation space 1222 is kept between the vertical walls 1221. The hollow temperature insulation space 1222 of the tank wall 122 is for Quite effective climate temperature isolation is set, and this breeding tank 12 is in order to guarantee the this breeding pond 123 accommodated The water A and the aquatic product A1 are effectively isolated from the external climate temperature. Also, the temperature-regulating pipe 15 for adjusting the temperature of the water A is distributed in the culture pond 123, and the temperature-regulating liquid A2 is circulated and circulated inside the temperature-regulating pipe 124, and the temperature-raising liquid A2 is passed through the temperature-adjusting device 13. The cooling machine 132 and the cooling machine 133 firstly control the temperature of the temperature-regulating liquid A2 in the variable temperature chamber 1311, and then use the first pump C1 to circulate the temperature-regulating liquid A2 into the temperature-regulating tube 124, and the adjusted The temperature of the temperature-regulating liquid A2 is distributed through the temperature-regulating tube 124 to affect the temperature of the water A within the preset range set by the controller 18, and the temperature of the water A is adjusted to the preset range set by the controller 18 When it is inside, the temperature measuring element B senses the temperature of the water A through the controller 18 and sends a signal to the first pump C1 connected to the thermostat pipe 124 to shut down until the temperature of the water A exceeds the temperature set by the controller 18 In the preset range, the temperature measuring element B senses the temperature of the water A through the controller 18 and sends a signal to the first pump C1 connected to the temperature regulating pipe 124 to start circulating the temperature regulating liquid A2 into the temperature regulating pipe 124 Emitting affects the temperature of the water A to the preset range, so as to ensure that the aquatic product A1 can continue to be raised at the most suitable living temperature, and also make the temperature of the water A not affected by the external temperature and climate, and allow the aquatic product to circulate The aquaculture system 1 can perform cultivation or breeding of the aquatic product A1 without being limited to any climatic conditions and regardless of the supply conditions of the water A. In addition, the temperature-regulating liquid A2 is a mild liquid with better heat transfer efficiency, wherein the temperature-regulating liquid A2 can also choose the water A as the implementation target, and cooperate with the temperature insulation space 1222 to form the aquatic product A1 Perfect breeding temperature control facilities (such as: as shown in Figure 3).

Also, the chamber 141 of the filter recovery device 14 is divided into the filter chamber 1411 and the defloating chamber 1412 by the filter body 142, and the defloating chamber 1412 is connected to the defloating recovery container 1413. The defloated A11 produced by A1 is collected and recycled into fertilizer, so that the aquaculture circulation system 1 can expand the production value according to the defloated A11. And the filter chamber 1411 draws the water A to the aeration tank 151 above the step circulation device 15 according to the fifth pump C5, and the water A is circulated back after being stepwise aerated according to the aeration tank 151. The culture pond 123 and the aeration tank 151 are mainly consuming the organic particles contained in the water A, increasing the water A close to the natural Due to the activity of the environment, the oxygen content of the water A is adjusted by using the gas control proportional device 19 and the micro-bubble device 17. Wherein, the microbubble device 17 uses the Venturi hole 1711 of the high pressure element 171 to communicate with the gas pre-storage element 191 to produce ultrafine bubbles A12 with hydrogen and oxygen into the water A and then imported into the pressure vessel 172 The aeration tank 151 and the culture pond 123 are supplied by the pressure vessel 172 in advance. In particular, the ultra-fine bubbles A12 of hydrogen can be used for the ultra-micro-range detonation and sterilization of the water A, the elimination of organic particles, the elimination of inorganic particles, and the splitting of oily food waste and oily excrement of the aquatic products A1 to become soluble in the water A The de-floating A11 makes the de-floating A11 enter the filtration recovery device 14 with the water A to be filtered and discharged to the de-floating recovery container 1413 to collect and recycle into fertilizer, and reduce the filtration cost according to the ultra-micro bubbles A12 of hydrogen gas, effectively ensuring the The quality of water A1 becomes the most suitable clean condition for the growth of this aquatic product A1. And adjusting the content of ultrafine bubbles A12 with oxygen in the water A can just meet the most suitable oxygen content for the growth of the aquatic product A1, and effectively guarantee the survival conditions of the aquatic product A1 in the water A (as shown in Figure 3 ).

In addition, an overflow tank 153 for accommodating the water A is provided below the unpowered hydraulic pump 152, and the overflow tank 153 is provided with the overflow pump 154 to overflow the unpowered hydraulic pump 152 into the overflow tank 153 When the water A level is close to the full level, the water A is pumped intermittently and circulated upwards to the driving water tank 155 (as shown in Figure 3). In addition, the non-powered hydraulic pump 152 is a mature lifting and conveying technology of the water A that does not need electric drive. Its power system comes from the self-pressure of the water A, and the water A flows into the upper head air cavity of the hydraulic pump seat chamber 1521. After the valve 1523 on the 1522, the air pressure of the air chamber 1522 backs up the water A and presses down the upper valve 1523 to close the communication of the hydraulic pump seat chamber 1521, and force the water A to be driven by the hydraulic pipe 1524 Sink 155 conveys. When the upper valve 1523 is opened, that is, the pressure relief valve 1525 is pressed by the water A to close the hydraulic pump seat chamber 1521, and when the upper valve 1523 is closed, that is, the pressure relief valve 1525 is opened to overflow the water A. The overflow tank 153 . And when the pressure of the air chamber 1522 was less than the water A pressure, the water A would repeatedly push up the upper valve 1523 and flow into the air chamber 1522 (as shown in Figure 4).

Furthermore, the aeration tank 151 at the height is connected with three to eight unpowered hydraulic pumps 152 downwards, the unpowered hydraulic pump 152 is connected with the driving water tank 155 upwards, and the driving water tank 155 is connected with the driving water tank 155 below. The water A drives the hydroelectric generator 16 that generates electricity, and the hydroelectric generator 16 is connected to the storage battery 11 that stores the generated electricity. The electricity stored in the storage battery 11 can just supply all the operating power of the aquaculture system 1 (such as: Figure 3).

The heating element 1321 of the heating machine 132 of the present invention is provided with a warming room 13211 for containing the temperature-regulating liquid A2. The heating room 13211 is equipped with a heating tube 13212 for raising the temperature of the temperature-regulating liquid A2. The heating tube 13212 circulates There is a medium oil E, and the heating tube 13212 is connected with a heating medium heater 2 which circulates and heats the medium oil E outside the heating element 1321. The heating medium heater 2 is also provided with a solar heat collecting umbrella 21. A heat collector 211 is connected upwards in the center of the heat umbrella 21. The heat medium heater 2 is further distributed with a heat medium part 22 connected to the heat collector 211. An oil medium chamber 221 is arranged inside the heat medium part 22. The oil medium chamber 221 contains the medium oil E in addition, and the heat medium heater 2 is distributed with an oil medium pump 23 that draws the medium oil E in the oil medium chamber 221 to the heat collector 211, and the heat collector 211 is also connected with the oil medium conduit 24 that is connected in series with the heat collector 211 and circulates the medium oil E back to the oil medium chamber 221. The heat medium part 22 is provided with a temperature-regulating pump 25 for circulating the medium oil E to the temperature raising pipe 13212 in the oil medium chamber 221. Pipe 26, and the controller 18 controls and starts and closes the oil medium pump 23 and the temperature regulating pump 25 according to the temperature of the temperature regulating liquid A2 measured by the temperature measuring element B (as shown in Fig. 5 Show).

The temperature adjusting device 13 of the present invention is further distributed with a heat medium heater 2, and the heat medium heater 2 is provided with a solar heat collecting umbrella 21, and the center of the sun heat collecting umbrella 21 is connected with a heat collector 211 facing upwards. The heat medium heater 2 is also distributed with a heat medium part 22 connected to the heat collector 211, and an oil medium chamber 221 is arranged inside the heat medium part 22, and the oil medium chamber 221 contains medium oil E in addition, and the heat medium heats the Device 2 is distributed to extract the oil The medium oil E in the medium chamber 221 is sent to the oil medium pump 23 of the heat collector 211, and the heat collector 211 is connected with the heat collector 211 in series and circulates the medium oil E back to the oil medium chamber 221. Oil medium conduit 24. The heat medium part 22 is provided with a heated interface pipe 222 for circulating the temperature-regulating liquid A2 in the oil medium chamber 221. The temperature-regulating liquid pump 27 of the chamber 1311, and the controller 18 controls and starts and shuts down the oil medium pump 23 and the temperature-regulating liquid pump 27 according to the temperature measured by the temperature measuring element B. And this solar heat collecting umbrella 21 is a high-efficiency high-temperature heat collecting equipment, so it is very appropriate to circulate the temperature-regulating liquid A2 in the heat-receiving interface tube 222 after the medium oil E is heated and then continuously heated (as shown in Figure 6 Show). In addition, the cooling element 1331 of the cooling machine 133 is provided with a cooling room 13311 for containing the temperature-regulating liquid A2, and the cooling room 13311 is equipped with a cooling tube 13312 for cooling the temperature of the temperature-regulating liquid A2, and the cooling tube 13312 circulates There is a refrigerant liquid 13313, and the cooling pipe 13312 is connected with a refrigerant cooler 13314 (as shown in FIG. 7 ) which circulates and cools the refrigerant liquid 13313 outside the cooling element 1331 .

The bottom side of the culture pond 123 of the present invention is coiled with the temperature regulation pipe 124, and the temperature regulation pipe 124 is coiled in a circular spiral manner on the bottom side of the culture pond 123. The coiling of the temperature regulation pipe 124 can just speed up the cultivation The temperature adjustment speed of the water A contained in the pool 123 (as shown in Fig. 8). And this culture pool 123 is distributed with the planting support body 125 that lays and floats on this water A surface in addition, and this planting support body 125 top is distributed with planting container 1251 again, and this planting container 1251 is pierced with water-permeable hole 1252 in addition, the planting The container 1251 is embedded with a planting inlay 1253, and the planting inlay 1253 is also planted with the crop A3 cultivated by the water A (as shown in Figure 10). In addition, the aquaculture pond 123 is distributed with the spiral temperature-regulating pipe 124, and the temperature-regulating pipe 124 is hung around the aquaculture pond 123, hoping to meet the needs of different aquatic products in this way. The breeding type (such as: as shown in Figure 9).

This aquaculture circulation culture system 1 of the present invention is distributed with in addition: the solar energy that can generate electric power Board F1, wind power generator F2 capable of generating electricity, and solar heat collection sleeve group 3. The solar panel F1 and the wind power generator F2 are connected to the storage battery 11 (as shown in FIG. 11 ) which stores the generated electric power. A warming room 13211 for accommodating the temperature-regulating liquid A2 is added inside the heating element 1321, and a heating tube 13212 for raising the temperature of the temperature-regulating liquid A2 is erected in the heating room 13211, and a medium oil E is circulated in the heating tube 13212. The tube 13212 is connected with at least one solar heat collecting sleeve group 3 which circulates and heats the medium oil E outside the heating element 1321. The solar heat collecting sleeve group 3 is also distributed with solar heat collecting tubes 31. The solar heat collecting sleeve Group 3 is also distributed with a heat medium part 22 connected to the solar heat collecting tube 31, and an oil medium chamber 221 is arranged inside the heat medium part 22, and the oil medium chamber 221 also contains medium oil E, and the heat medium part 22 is distributed There is an oil medium pump 23 that pumps the medium oil E in the oil medium chamber 221 to the solar heat collecting tube 31, and the solar heat collecting tube 31 is connected with the solar heat collecting tube 31 in series and circulates the medium oil E back to the oil The heat collecting pipe oil medium conduit 4 of the medium chamber 221. The heat medium part 22 is provided with a temperature-regulating pump 25 for circulating the medium oil E to the temperature raising pipe 13212 in the oil medium chamber 221, and the temperature rising pipe 13212 is connected with a temperature raising system for circulating the medium oil E back to the oil medium chamber 221 return pipe 26, and the controller 18 controls and starts and closes the oil medium pump 23 and the temperature regulating pump 25 according to the temperature of the temperature regulating liquid A2 measured by the temperature measuring element B (such as: Fig. 12 shown).

This drive water tank 155 of the present invention is connected at least one to three inches in addition and the water delivery pipe 1551 that exports this water A downwards, and this water delivery pipe 1551 is connected with the impeller 161 that this hydraulic generator 16 adds, and this impeller 161 inside is again There is a flat impeller chamber 1611 , and an outlet pipe 1612 for outputting the water A to the aeration tank 151 is added on the lower side of the impeller chamber 1611 . The impeller chamber 1611 is pivotally connected with an impeller 1613 driven to rotate by the water A. The center of the impeller 1613 also has an impeller mandrel 1614 protruding downwards from the impeller machine 161. The impeller mandrel 1614 is located below the impeller machine 161. At least one gravity maglev group 5 is connected, and the gravity maglev group 5 is distributed with a fixed homopolar magnetic part 51 and a rotating homopolar magnetic part 52. The fixed homopolar magnetic part 51 is additionally equipped with a concave magnetic chamber 511. The center of the chamber 511 is pierced with a magnetic shaft hole 512, and the nanomagnetic chamber 511 is also distributed with Homopolar magnet 513, the center of the rotating homopolar magnetic part 52 is fixedly connected with the impeller mandrel 1614, and the rotating homopolar magnetic part 52 is distributed with the impeller mandrel 1614 screwed and driven counterweight plate 53. Counterweights 531 are distributed around the weight plate 53, and the rotating homopolar magnetic part 53 has a homopolar rotating part 532 extending into the nanomagnetic chamber 511. The homopolar rotating part 532 is fixed with a The rotating part of the magnet 513 is in the same polarity as the magnet 533, and the rotating part 52 of the same polarity has a magnetic floating shaft 534 passing through the gravity magnetic floating group 5 through the magnetic floating shaft hole 512, and the magnetic floating shaft 534 is below the gravity magnetic floating group 5 Also be fixed with transmission rotary body 535, this transmission rotary body 535 is screwed in addition and drives this hydraulic generator 16 that has two to four that can produce electric energy, and this hydraulic generator 16 is additionally provided with the generator rotary that this transmission rotary body 535 is screwed on. Body 16A "The transmission rotating body 535 is about 2400 to 3000 revolutions/2400rpm to 3000rpm per hour; in addition, the rotation ratio of the transmission rotating body 535 and the generator rotating body 16A can be: (1 to 1) to ( 4 to 1), each of the hydroelectric generators 16 generates electricity and stores it in the storage battery 11 (1.5kw to 6kw/1.5kw to 6kw). The storage battery 11 drives three to six multiplier power generators 6 (as shown in the 13th, 14th, and 15th figures) with the stored power, and the multiplier power generator 6 is at least provided with: a motor 61, a counterweight Maglev 62 and rear generator 63. The electric power stored in the storage battery 11 drives at least the motor 61 in addition, and the motor 61 only needs (750 watts/750w) to drive (the motor 61 is about 1200 to 2000 revolutions per hour/1200rpm to 2000rpm), the motor 61 At least one counterweight magnetic levitation device 62 is driven, and the counterweight magnetic levitation device 62 is at least distributed with: a fixed magnetic levitation part 621 with the same polarity and a magnetic levitation part 622 with the same polarity rotated. The fixed homopolar magnetic levitation part 621 is additionally equipped with a magnetic receiving part 6211, and the center of the magnetic receiving part 6211 is pierced with a magnetic receiving part perforation 6212, and the magnetic receiving part 6211 is distributed with the same magnetic direction body 6213; The center of the part 622 is provided with a rotating mandrel 6221 which is screwed to the motor 61. The magnetic levitation part 622 with the same polarity is distributed with a rotating counterweight plate 6222 pierced by the rotating mandrel 6221. The rotating counterweight plate 6222 is at least distributed with rotating weights 6223 around the periphery. The rotating homopolar magnetic levitation part 622 has a rotating homopolar rotating part 6224 extending into the receiving magnetic part 6211. The rotating homopolar rotating part 622 is also Fixed with the rotation corresponding to the same magnetic body 6213 to the same polarity magnetic body 6225, and the rotating part 622 with the same polarity has a rotating mandrel 6221 passing through the counterweight magnetic levitation device 62 through the hole 6212 of the magnetic receiving part. In addition to 62, a rotating transmission rotating body 6226 is fixed, and the rotating transmission rotating body 6226 is screwed to drive a rear generator 63 capable of generating electric energy. The rear generator 63 is additionally provided with a rotating transmission rotating body The ratio of 6226 is the rear generator rotating body 631 of three to one to four to one revolution ratio (the rear generator rotating body 631 is about 3600 to 8000 revolutions/3600rpm to 8000rpm per hour), and each rear generator 63 generates Electricity (5 kilowatts to 7 kilowatts/5kw to 7kw) is stored in this accumulator 11 in addition, is to be between 15 kilowatts to 48 kilowatts/15kw to 48kw with the electric quantity that three to six this multiplication power generators 6 produce, make the The self-circulation mechanism of the aquaculture system 1 expands to the continuous power generation efficiency of power multiplication (as shown in Figure 16; wherein, for the label of the aquaculture system 1, please refer to Figures 4 and 13; in addition, the same The polar magnet 513 and the same polarity magnet 533 of the spin portion are magnets repelling each other with the same pole; again, the magnet 6213 with the same polarity and the magnet 6225 with the same polarity are magnets that repel each other with the same pole).

It can be seen from the above description that the aeration tank 151, the unpowered hydraulic pump 152 and the hydroelectric generator 16 can make full use of the circulating power generation of the water A to supply the power required by the aquaculture system 1, and the water A passes through the The filtration and recovery device 14 can be continuously recycled, purified and reused. This purification and reuse can prevent the waste of the water A, and effectively reduce the external proportion of the water A, which can also reduce the unnecessary risk of infection of the aquatic product A1 during the breeding period. , the ultrafine bubbles A12 of hydrogen are used for the ultrafine explosion and sterilization of the water A, the elimination of organic particles, the elimination of inorganic particles, and the splitting of oily food waste and oily excrement of the aquatic products A1 into the water A Defloating A11 enters the filtration recovery device 14 to filter and remove, effectively maintaining the quality of the water A in a clean condition that is most suitable for the growth of the aquatic product A1, and the ultra-fine air bubbles A12 of oxygen can be adjusted to the oxygen content that is most suitable for the growth of the aquatic product A1 quantity. Then use the warming machine 132 and the cooling machine 133 of the temperature adjusting device 13 to mix and match to adjust the temperature of the water A to maintain the aquatic product A1 in the range of living conditions suitable for breeding. Therefore, it is the primary excellent feature of the present invention to combine the aquaculture circulation system 1 that is not restricted by climate, region and city at all.

Another excellent feature of the present invention is that: and the solar heat collecting umbrella 21 is a high-efficiency high-temperature heat collecting device, so it is very suitable for circulating the temperature-regulating liquid A2 in the heating chamber 13211 after heating the medium oil E and continuously heating it .

Another excellent feature of the present invention is that the cooling machine 133 lowers the temperature of the temperature-regulating liquid A2 by controlling it, and the cooling machine 133 cooperates with the temperature-raising machine 132 to effectively adjust the temperature-regulating liquid A2 to an appropriate temperature, thereby adjusting the temperature The tempering liquid A2 then adjusts the temperature of the water A contained in the culture pond 123 until the temperature of the water A is controlled within the most suitable temperature range for the growth of the aquatic product A1.

Another excellent feature of the present invention is that: the crop A3 is just one of the best ways to assist in absorbing the organic particles in the floating A11 and the water A, and the crop A3 can become the aquaculture circulation system 1 in the aquatic product. The benefit characteristics of another source of sales income besides A1.

Another excellent feature of the present invention is that: the aquaculture circulation system 1 uses the solar panel F1 and the wind generator F2 that can generate electricity as the benefit characteristics of auxiliary electricity generation.

Yet another excellent feature of the present invention is: the transmission rotating body 535 of the hydraulic generator 16 is about 2400 to 3000 revolutions/2400rpm to 3000rpm per hour; The ratio can be: ratio between (1 to 1) to (4 to 1), each hydroelectric generator 16 generates electricity and stores it into the storage battery 11 (1.5kw to 6kw/1.5kw to 6kw). The storage battery 11 drives three to six multiplier power generators 6 with the stored power, and the stored electric power of the storage battery 11 drives the motor 61 of the multiplier power generator 6, and the motor 61 only needs (750 watts/750w ) can be driven, the motor 61 is about 1200 to 2000 revolutions/1200rpm to 2000rpm per hour, and the motor 61 passes through the rotary Set the transmission rotating body 6226 to be screwed with the rear generator rotating body 631 of the rear generator 63, and the ratio of the rotating driving rotating body 6226 to the rear generator rotating body 631 is three to one to four to one revolution ratio , the rear generator rotating body 631 is about 3600 to 8000 revolutions/3600rpm to 8000rpm per hour, and each of the rear generators 63 generates electricity of 5kw to 7kw/5kw to 7kw, and stores it into the storage battery 11 accordingly, The power generated by the three to six power multiplier generators 6 is between 15kw and 48kw/15kw and 48kw, which expands the self-circulation mechanism of the aquaculture circulation system 1 to the characteristic of continuous power generation efficiency of power doubling.

Another excellent feature of the present invention is that: the homopolar magnet 513 of the hydraulic generator 16 and the rotor homopolar magnet 533 are magnets that repel each other with the same pole, and the gravity magnetic levitation group 5 is fixed according to the homopolar magnet. The homopolar magnet 513 of the part 51 magnetically suspends the homopolar magnet 533 of the rotating part and the rotating homopolar magnetic part 52, and is used for magnetic levitation to make the rotating homopolar magnetic part 52 operate almost without frictional hindrance . The same magnetic body 6213 and the rotating homopolar magnet 6225 of the multiplying power generator 6 are magnets with the same polarity repelling each other. The homopolar magnet 6225 and the rotating homopolar magnetic levitation part 622 are used for magnetic levitation to make the rotating homopolar magnetic levitation part 622 operate almost without frictional hindrance. In addition to the gravitational rotation inertia of the counterweight 531 and the rotating counterweight 6223, the power generation efficiency of the hydroelectric generator 16 and the power multiplier generator 6 has excellent characteristics.

The technical content and technical characteristics of the present invention have been disclosed above. Accordingly, it can be seen that the present invention does meet the invention patent requirements of novelty, advancement and industrial applicability. Various replacements and modifications are made without departing from the spirit of the invention. Therefore, the protection scope of the present invention should not be limited to those disclosed in the embodiments, but should include various replacements and modifications that do not deviate from the present invention, and are covered by the patent scope of the present invention.

A: water

A1: Aquatic products

A11: Defloating

A12: Micro bubbles

A2: Tempering liquid

B: temperature measuring element

C1: first pump

C2: Second pump

C3: The third pump

C4: Fourth pump

C5: fifth pump

C6: sixth pump

D: Solenoid valve

1: Aquaculture Recirculating Culture System

11: Battery

12: breeding tank

121: base

122: groove wall

1221: vertical wall

1222: Insulation space

123: Breeding pond

124: thermostat tube

1241: import connector

1242: lead out connector

13: Temperature adjustment device

131: variable temperature container

1311: variable temperature chamber

132: Heating machine

1321: heating element

1322: warming circulation tube

133: cooling machine

1331: cooling element

1332: cooling circulation tube

14: Filtration recovery device

141: Containment room

1411: clean room

1412: Defloating chamber

1413: Defloat recovery container

142: filter body

15: Class cycle device

151: Aeration tank

152: Unpowered hydraulic pump

153: overflow tank

154:Overflow pump

155: drive sink

16: Hydroelectric Generator

17: Ultramicro Bubble Device

171: High voltage components

1711: Venturi hole

1712: pressurized narrow section

1713: air intake

172: Pressure vessel

1721: outlet pipe

1722: Nozzle

18: Controller

19: Air control proportional device

191: Gas pre-storage element

Claims (7)

An aquaculture circulation aquaculture system, wherein the aquaculture circulation aquaculture system at least includes: distribution of storage batteries, distribution of culture tanks, distribution of temperature adjustment devices, distribution of filtration and recovery devices, distribution of stage circulation devices, distribution of hydroelectric generators, Distributed with ultra-micro bubble devices and a controller; the aquaculture system is provided with the battery that supplies all the electricity used; Extended tank wall, the tank wall surrounds at least one culture pond, water and aquatic products are contained in the culture pond, a temperature-regulating pipe for adjusting the temperature of the water is distributed in the culture pond, and a regulating pipe is circulated inside the temperature-regulating pipe Warm liquid, the temperature regulating pipe is distributed with an inlet joint and an outlet joint protruding from the culture pond, a temperature measuring element for measuring the water temperature is distributed in the culture pond, and the tank wall is provided with at least three vertical walls. A hollow temperature insulation space is maintained between the walls; the aquaculture circulation system is distributed with the temperature adjustment device around the culture tank, and the temperature adjustment device is distributed with a temperature-changing container, and the temperature-changing container is provided with at least one chamber for containing the temperature-regulating liquid. Variable temperature chamber, the temperature variable container is assembled with the temperature measuring element placed in the variable temperature chamber to measure the temperature of the temperature-regulating liquid, and the temperature adjustment device is distributed to extract the temperature-regulating liquid in the variable temperature chamber and enter it by connecting the inlet joint The first pump in the temperature regulating pipe, and the temperature regulating pipe circulates the temperature regulating liquid through the outlet joint and flows back to the variable temperature chamber; The heating element for heating the temperature-regulating liquid, the temperature-adjusting device is distributed with the second pump that draws the temperature-regulating liquid in the variable-temperature chamber into the temperature-raising element, and the temperature-adjusting device is distributed with the temperature-adjusting device connected to the temperature-raising element The liquid enters the temperature-increasing circulation pipe of the variable temperature chamber; the cooling machine is equipped with at least one cooling element for cooling the temperature-adjusting liquid, and the temperature adjustment device is distributed with the first pump that draws the temperature-adjusting liquid in the variable temperature chamber into the cooling element. Three pumps, the temperature adjustment device is distributed with a cooling circulation pipe that communicates with the temperature-regulating liquid in the cooling element and enters the variable temperature chamber; the fourth pump for pumping the water is distributed around the culture tank, and the fourth pump At least the filter recovery device is connected with the filter recovery device. The filter recovery device is distributed with a chamber, and a filter body is embedded in the chamber. The room is connected with at least one defloatation recovery container, and the fifth pump for extracting the water is distributed around the filter room pump, the filter chamber is connected to at least one stage circulation device through the fifth pump, and the stage circulation device is distributed with at least five stages of aeration tanks from high to low, and the aeration tank at the top of the stage circulation device is connected to the The fifth pump distributed around the filter room, the aeration tank is connected to the lower aeration tank from the high, at least the lowest aeration tank is connected to the culture pond, and the high aeration tank is at least There are three to eight unpowered hydraulic pumps driven by the water downwards, and an overflow tank to accommodate the water is provided under the unpowered hydraulic pump, and the overflow tank indirectly draws the full overflow of the water pump, the overflow pump is upwardly connected to a driving water tank that accommodates the water, and the unpowered hydraulic pump is upwardly connected to the driving water tank, and the bottom of the driving water tank is connected to the hydraulic generator that is driven by the water to generate electricity. The motor, the hydroelectric generator is connected to the storage battery that stores the generated electricity, and the aeration tank is connected under the hydroelectric generator; the aquaculture circulation system is provided with at least one air control proportional device, and the air control proportional device is distributed with gas The pre-storage element, the gas pre-storage element at least stores: hydrogen and oxygen; the ultra-fine bubble device is distributed with a high-pressure element, and the high-voltage element is provided with a Venturi hole, and one end of the Venturi hole is connected to the sixth pump, The sixth pump is at least connected to the driving water tank; and a narrow pressurized section with a small diameter is provided in the middle of the Venturi hole, and an air inlet is provided on the side of the pressurized narrow section, and the air inlet is connected to a solenoid valve. The gas hole communicates with the gas pre-storage element through the electromagnetic valve; the other end of the Venturi hole communicates with the electromagnetic valve, and the Venturi hole communicates with a pressure vessel through the electromagnetic valve, and the pressure vessel is distributed with a water outlet pipe. The water pipe communicates with at least one solenoid valve, and the pressure vessel communicates with at least one nozzle through the solenoid valve, and the nozzle communicates with the aeration tank at least, and the nozzle communicates with the culture pond at least; the controller uses the temperature measuring element to detect And set the predetermined temperature of the water in the culture pond and the temperature-regulating liquid in the temperature-changing container, and the temperature of the water and the temperature-regulating liquid detected by the temperature measuring element makes the controller at least activate and deactivate the temperature raising machine with this cooling machine. The aquaculture circulation aquaculture system as described in Claim 1, wherein, the inside of the heating element is provided with a warming room for containing the temperature-regulating liquid, and the warming-up room is set up with a heating tube to increase the temperature of the temperature-regulating liquid, and the heating tube circulates again There is a medium oil, and the heating tube is connected with a heat medium heater which circulates and heats the medium oil outside the heating element. The heat medium heater is also provided with a solar thermal umbrella, and the center of the solar thermal umbrella is connected upward There is a heat collector, and the heat medium heater is distributed with heat medium connected to the heat collector There is an oil medium chamber inside the heat medium part, the oil medium chamber also contains the medium oil, and the heat medium heater distributes the oil medium that draws the medium oil in the oil medium chamber to the heat collector Pump, the heat collector is also connected with the oil medium pipe that is connected in series with the heat collector and circulates the medium oil back to the oil medium chamber; the heat medium part is provided with a circulation medium oil to the heating pipe The temperature-regulating pump, the temperature-raising pipe is connected with a temperature-raising return pipe that circulates the medium oil back to the oil medium chamber, and the controller controls and activates and shuts down the temperature-regulating liquid according to the temperature of the temperature-measured liquid The oil-medium pump and the temperature-regulated pump. The aquaculture circulation breeding system as described in Claim 1, wherein, the temperature adjustment device is further distributed with a heat medium heater, and the heat medium heater is also provided with a solar heat collecting umbrella, and the center of the solar heat collecting umbrella is connected upwards with a A heat collector, the heat medium heater is also distributed with a heat medium part connected to the heat collector, and an oil medium chamber is arranged inside the heat medium part, and the oil medium chamber also contains medium oil, and the heat medium heater is also An oil medium pump is distributed to draw the medium oil in the oil medium chamber to the heat collector, and the heat collector is also connected with an oil medium pipe connecting the heat collector in series and circulating the medium oil back to the oil medium chamber; The heat medium part is further provided with a heat interface pipe for circulating the temperature-regulating liquid in the oil medium chamber, and the heat-receiving interface pipe is connected with a temperature-regulating liquid pump for circulating the temperature-regulating liquid to the variable temperature chamber outside the heat medium part pump, and the controller controls and activates and shuts down the oil pump and the temperature-regulating liquid pump according to the temperature measured by the temperature-measuring element; a cooling chamber for containing the temperature-regulating liquid is added inside the cooling element, and the The cooling chamber is also equipped with a cooling pipe for cooling the temperature of the temperature-regulating liquid, and the cooling pipe circulates a refrigerant liquid, and the cooling pipe is connected with a refrigerant cooler for circulating and cooling the refrigerant liquid outside the cooling element. The aquaculture circulation system as described in Claim 1, wherein, the temperature regulating pipe is coiled on the bottom side of the culture pond, and the temperature regulating pipe is coiled in a circular spiral manner on the bottom side of the culture pond; and the culture pond is further distributed There is a planting support body floating on the water surface, and a planting container is distributed above the planting support body, and a water-permeable hole is pierced under the planting container body, and a planting inlay is embedded in the planting container, and the planting inlay In addition, the hydroponic crops are planted. The aquaculture circulation system as described in Claim 1, wherein the aquaculture pond is distributed with the spiral temperature-regulating pipe, and the aquaculture pond is additionally hung with the temperature-regulating pipe. The aquaculture circulation system as described in Claim 1, wherein, the aquaculture circulation system is further distributed with: a solar panel capable of generating electricity, a wind generator capable of generating electricity, and a solar heat collection sleeve group; the solar panel and the The wind power generator is connected with the accumulator which stores the generated electric power; the heating element is equipped with a warming room containing the temperature-regulating liquid, and the warming-up room is set up with a temperature-raising tube to raise the temperature of the temperature-regulating liquid, and the temperature-raising tube circulates again There is a medium oil, and the heating tube is connected with at least one solar heat collecting sleeve group for circulating heating the medium oil outside the heating element, and the solar heat collecting sleeve group is distributed with solar heat collecting tubes, and the solar heat collecting sleeve The group is also distributed with a heat medium part connected to the solar heat collecting tube, and an oil medium chamber is arranged inside the heat medium part, and the oil medium chamber also contains medium oil. The oil-medium pump from the medium oil to the solar heat collecting tube, and the solar heat collecting tube is also connected with the oil-medium conduit of the heat collecting tube which is connected in series with the solar heat collecting tube and circulates the medium oil back to the oil medium chamber; The medium chamber is also equipped with a temperature-regulating pump that circulates the medium oil to the temperature riser pipe, and the temperature riser pipe is connected with a temperature rise return pipe that circulates the medium oil back to the oil medium chamber, and the controller is based on the temperature measured by the temperature measuring element. The temperature of the temperature-regulating liquid is controlled and activated and shut down with the oil-medium pump and the temperature-regulating pump. The aquaculture circulation system as described in Claim 1, wherein, the driving water tank is connected with at least one to three inches and a water delivery pipe that outputs the water downwards, and the water delivery pipe is connected with the impeller added to the hydroelectric generator. The inside of the impeller machine also has a flat impeller chamber, and the lower side of the impeller chamber is provided with an outlet pipe for outputting the water to the aeration tank; the impeller chamber is pivotally connected with an impeller driven by the water, and the center of the impeller has a Protruding downwards is the impeller mandrel of the impeller. The impeller mandrel is connected with at least one gravity magnetic levitation group under the impeller machine. The gravity magnetic levitation group is distributed with fixed homopolar magnetic parts and rotating homopolar magnetic parts. The homopolar magnetic part is additionally equipped with a concave magnetic chamber, and the center of the nanomagnetic chamber is pierced with a magnetic floating shaft hole. The impeller shaft, the rotating homopolar magnetic part is distributed with a counterweight plate that is screwed and driven by the impeller shaft, and a counterweight is distributed around the counterweight disc, and the rotating homopolar magnetic part has a The same polarity rotating part of the magnetic chamber, the same polarity rotating part is fixed with the rotating part and the same polarity magnet corresponding to the same polarity magnet, and the same polarity rotating part has a gravity magnetic levitation group through the magnetic levitation axis hole The magnetic floating shaft, the magnetic floating shaft is fixed with a transmission rotating body under the gravity magnetic floating group, and the driving rotating body is screwed to drive two to four hydraulic generators that can generate electric energy. The generator swivel of the transmission swivel body, each of the hydroelectric generators generates electricity and stores it into the storage battery; the storage battery drives the stored power to have three to six multiplier power generators, and the multiplier power generators are at least equipped with: A motor, a counterweight magnetic levitation device and a rear generator; the electric power stored in the storage battery drives at least the motor, and the motor drives at least one counterweight magnetic levitation device, and the counterweight magnetic levitation device is distributed with at least: Homopolar magnetic levitation part and a rotating homopolar magnetic levitation part; the fixed homopolar magnetic levitation part is additionally equipped with a magnetic levitation part, and the center of the magnetic levitation part is pierced with a magnetic part perforation, and the magnetic part is distributed with magnetotropic bodies ; The center of the magnetic levitation part with the same polarity is provided with a rotating mandrel that is screwed to the motor, and the magnetic levitation part with the same polarity is distributed with a rotating counterweight plate pierced by the rotating mandrel. The disc is provided with rotating counterweights distributed at least around the periphery, and the rotating homopolar magnetic levitation part has a rotating homopolar rotating part extending into the receiving magnetic part, and the rotating homopolar rotating part is fixed with corresponding corresponding The magnetic body is rotated to the magnet of the same polarity, and the rotating part of the same polarity has a rotating mandrel that passes through the counterweight maglev through the hole of the magnetic receiving part. In addition to the heavy magnetic levitation device, there is a rotating transmission rotating body fixed, and the rotating driving rotating body is screwed to drive a rear generator capable of generating electric energy. It is a rear generator rotating body with a rotation ratio of 3 to 1 to 4 to 1, and the electricity generated by each rear generator is stored in the storage battery.

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