TWM648474U - High-efficiency microbubble-based oxygen dissolution apparatus - Google Patents

Abstract

The utility model is a high-efficiency microbubble-based oxygen dissolution apparatus that includes: a motor, a pipe frame, and at least one high-efficiency dissolved oxygen generation mechanism. The motor is provided in a fish pond. Ambient air is pressurized by the motor in order for oxygen-containing air to enter the space in the high-efficiency dissolved oxygen generation mechanism through the pipe frame. The high-efficiency dissolved oxygen generation mechanism has a double pressurization design based on the Venturi effect and spiral pressurization, allowing ambient air to be drawn into the mechanism by a negative pressure, and air bubbles broken into microbubbles. The microbubbles are dissolved in flowing water guided into the fish pond to enable an efficient increase in oxygen and water quality over a large area of the fish pond.

Description

High efficiency microbubble dissolved oxygen equipment

This creation is about high-efficiency micro-bubble oxygen-dissolving equipment, especially a high-efficiency micro-bubble oxygen-dissolving equipment developed mainly by using a fish pump to improve the amount of dissolved oxygen in deep water areas.

According to reports, Taiwan has an island-type terrain, and the special environment surrounded by the sea has created Taiwan's economically significant aquaculture industry. In the land-based aquaculture industry, the oxygen content of fish ponds in the aquaculture pond water has a significant impact on the health, survival rate and feed conversion rate of the fish in the pond. The impact is huge; when the oxygen content of the pond water is higher, the fish are healthier and have higher disease resistance, which can greatly increase the profits of breeding.

The methods currently used to provide dissolved oxygen in fish pond water are as follows:

1. Water tanker: Among them, some industry players have developed a new patent of the Republic of China No. M279182, which is that when the starter motor is running, the driving helical gear is rotated synchronously to drive the engaged driven helical gear and the gear shaft to rotate, which can drive the water tanker. The water pumping blade performs the water pumping action, and a small horsepower motor can drive the two meshing driving helical gears and the driven helical gear to run the water wheel. However, the above structure can only improve the dissolved oxygen content on the surface of the pool water, and the dissolved oxygen in the deep pool water can be improved. The amount of oxygen has not increased, and the blade-type flapping not only causes noise that affects the growth environment of aquatic organisms, but also easily harms aquatic organisms when the flapping speed is too high, causing unnecessary losses. In addition, this method requires a large voltage to be provided by the shore, which is not only dangerous. And are prone to power outages.

2. Windmill device: Another industry has developed a high-efficiency air-inflating windmill device according to the new patent number 141439 of the Republic of China. It is mainly composed of a fan blade wind receiving unit, an air compression unit, and a tail fin directional unit. This technology uses blades with a simple structure to fully incorporate the wind force to achieve operational functions and drive the rear compressor to compress and store the air to provide cylinder pressure to compress the air and pump it into the water to increase the oxygen density in the fish ponds. The energy generated by the above-mentioned wind power generation is unstable due to seasonality or wind strength, and it is easy to cause intermittent oxygen supply, resulting in uneven oxygen density.

3. Submersible type: Another industry developer has developed a submersible type pressurized oxygen feeder for water quality treatment, as shown in the new patent number 194375 of the Republic of China. It uses a hollow inverted cone-shaped pressurized suction pipe with a large top and a small bottom, and cooperates with a rotating machine. The linked supercharged air suction mechanism generates strong air suction force to achieve sufficient mixing of air and water and injects it into the water. However, in this method, the blades beating the fish pond will still produce a huge sound and affect the living space of the fish.

4. Submersible motor: A submersible motor pressurized dissolved oxygen pump has been developed by the industry under the new patent number M313423 of the Republic of China. It is an improvement of the submersible motor pump structure. The main structure includes a submersible motor, a shaft seal seat, and an air suction pipe. It consists of a base, a cylindrical squirrel-cage axial flow fan blade attached to the hollow inner shaft, a spiral exhaust fan blade, and a shaft propeller impeller attached to the outer shaft. It is characterized by the strong suction of the air on the water surface through the creation. The air motor is directly poured into the water, and the external blades disturb the water in the fish pond to generate water flow, which mixes the air and water and increases the oxygen content. However, this method still requires a large voltage to drive the motor and causes power consumption problems.

5. Mobile green energy: The mobile green energy fish pond aerator of the new patent number M461318 of the Republic of China uses a pumping motor to pump the fish pond water out of the water and spray it into the air. The design of the atomizing nozzle makes the sprayed pond water The atomization method is sprayed into the air to increase the contact area between water and air and increase the oxygen content of the water. At the same time, the falling water mist can land on the solar panel to reduce the surface temperature of the solar panel and improve the conversion efficiency of the solar panel. A power motor is designed to allow users to control the creation via radio to move to a designated location for oxygenation. However, the above structure can only improve the dissolved oxygen level on the surface of the pool water. The amount of dissolved oxygen in the deep pool has not increased, and the solar panel For example, when the weather is bad, the mobile green energy fish aerator cannot increase the oxygen content and there are problems with mobile behavior.

In response to the above-mentioned new improved structures, other industries have also developed many types of water bath oxygen equipment used in water quality treatment (such as sewage treatment, aquaculture, etc.), such as in the known technical documents: Announcement Announcement No. 056594 "Floating circulation wide-angle gas transmission water truck", Announcement No. 066928 "Gush type water pump", Announcement No. 163849 "Improved structure of water truck pump for breeding farms", Announcement No. 177992 "New structure of water pump for breeding ", Announcement No. 189930 "New Structure of Oxygen Supply and Water Truck for Breeding", Announcement No. 228051 "Structure of Oxygen Supply and Water Truck for Breeding with Drainage Function", Announcement No. 342599 "Structure of Water Truck for Breeding"...etc. , but it is also unable to achieve the main effect of improving the efficiency of the fish farm, increasing the oxygen in the fish farm and purifying the water quality in a large area, which is what this invention aims to achieve.

In view of the above-mentioned shortcomings of conventional water-fetching motors, the creator of the invention thought about the idea of creation. After many discussions and prototype tests, as well as many revisions and improvements, he came up with this creation. This creation provides a high-efficiency microbubble dissolved oxygen equipment, which includes: a motor; A pipe frame body, the pipe frame system is assembled on the motor; and At least one high-efficiency dissolved oxygen generation mechanism. The high-efficiency dissolved oxygen generation mechanism has a structure that can produce a venturi effect and a spiral boosting action. The motor is installed in a fish tank, and the motor is used to guide the inside of the fish tank. The water then cooperates to drive the flowing water through the pipe frame body in sequence, and then enters the space of the high-efficiency dissolved oxygen generation mechanism, and cooperates with the dual pressurization method of the Venturi effect and spiral boosting in the high-efficiency dissolved oxygen generation mechanism. The outside air is sucked in and broken by negative pressure to form smaller micro-bubbles, which are dissolved in the flowing water and then introduced into the water inside the fish pond.

The main purpose of this high-efficiency microbubble dissolved oxygen equipment is to achieve the main effects of increasing oxygen in the fish pond and purifying the water quality in a large area with high efficiency.

The following is a further description of the preferred embodiments of the invention in conjunction with the drawings, in order to enable those who are familiar with the technology related to the invention to implement the invention in accordance with the statements in this specification.

First of all, please refer to Figures 1 to 8, the high-efficiency microbubble dissolved oxygen equipment of this invention includes: First, as shown in Figures 1 to 14, this invention is a high-efficiency microbubble Dissolved oxygen equipment, which includes: a motor 10, the motor 10 is a high-pressure gas supply waterproof motor 10, the motor 10 is provided with a motor body 11 for assembly on a circular frame chassis 12, and the motor body 11 is It is also provided with a circular interface portion 111; a pipe frame body 20, which is provided with a cylindrical vertical main pipe 21, a cylindrical transverse main pipe 22, four L-shaped elbows 23 and two Cover body 24, one end of the vertical main pipe 21 is connected and fixed to the interface portion 111 of the motor body 11 of the motor 10, and the other end is connected to one end of the horizontal main pipe 22. The elbows 23 are spaced apart from the pipe frame body 20. The horizontal main pipe 22, and the two free ends of the horizontal main pipe 22 are sealed by the two covers 24, so that a sealed space is formed in the horizontal main pipe 22; four high-efficiency dissolved oxygen generating mechanisms 30, each of which has high efficiency The dissolved oxygen generating mechanism 30 is arranged on the bend 23 of the transverse main pipeline 22 of the pipe frame 20. The high-efficiency dissolved oxygen generating mechanism 30 is provided with an integrally formed high-efficiency dissolved oxygen injection pipe body 31 and a flexible arc. The high-efficiency dissolved oxygen injection pipe body 31 is provided with a first joint end 311, a second joint end 312 and a first air inlet elbow 32. The first joint end 311 of the spray water end 313 is provided in the elbow 23 of the transverse main pipeline 22 of the pipe frame body 20, and the first joint end 311 is internally configured as a cross-section changing aperture of a Venturi structure. , the first joint end 311 is provided with a first aperture 3111, a second aperture 3112 and a third aperture 3113 in sequence, wherein the first aperture 3111 and a third aperture 3113 are larger in diameter than the second aperture 3112, and the first aperture 3111 and a third aperture 3113 are larger in diameter. The second joint end 312 is located close to the third aperture 3113 of the first joint end 311. The second joint end 312 is provided for the first air intake elbow 32 to be combined. There is a second joint end 312 inside. The air column plate 3121 is provided with an air collection groove 3122 near the third aperture 3113. In addition, the jet water end 313 is provided with a plurality of staggered left and right spiral grooves 3131, and the spiral grooves 3131 Extending to the third aperture 3113 position of the first joint end 311, the first air inlet elbow 32 is provided with a first end 321 and a second end 322. The first end 321 is provided at the second end. The joint end 312 and the second end 322 are connected to the outside world to provide air to enter inside.

Please also refer to Figures 6 to 8, which are schematic diagrams of the use of high-efficiency microbubble oxygen-dissolving equipment in fish ponds. The sequential procedures are as follows: The first is the water pumping procedure: the motor body 11 of the motor 10 is set. In the water area at the bottom of the fish tank, the water in the fish tank is extracted from the bottom frame 12 by pressurizing the motor body 11 of the motor 10; the second is the guidance process: guided by the interface portion 111 of the motor 10 The water flow sequentially flows to the vertical main pipeline 21 and the horizontal main pipeline 22 of the pipe frame body 20 and the two covers 24. Since each cover 24 makes the internal flow pipeline a closed space, the water flow in the fish tank is extracted to make the direction Each elbow 23 enters the high-efficiency dissolved oxygen injection pipe body 31 respectively; the third step is the first pressurization process: the second end 322 of the first air intake elbow 32 is connected to the outside world to provide air. After sequentially entering the first end 321 of the first air inlet elbow 32 and reaching the 36 fine apertures of the air column plate 3121 of the second joint end 312, the air is divided, pressurized and broken to form microbubbles, And the first pressurization is conducted into microbubbles and guided into the gas collecting tank 3122; the fourth is the second pressurization process: the water flow will sequentially pass through the first joint end 311 of the high-efficiency dissolved oxygen injection pipe body 31 There are first aperture 3111, second aperture 3112 and a third aperture 3113 in the aperture. Since the diameter of the first aperture 3111 and the third aperture 3113 is larger than that of the second aperture 3112, different cross-sectional area designs produce a venturi effect, thereby causing the flow to After the water is pressurized and the second pressurization speed changes, the microbubbles in the air collecting tank 3122 are guided by the pressurization speed and are sucked in and broken by the negative pressure to form smaller microbubbles toward the ejection water end 313. There are a plurality of staggered left and right bubbles inside. The spiral groove 3131 produces a spiral pressurizing action; the fifth is the efficient oxygenation process in the fish tank: the microbubbles in the air collecting groove 3122 guide the pressurization speed and are suctioned and broken by the negative pressure to form smaller microbubbles towards the jet water end. 313 is equipped with a plurality of staggered left and right spiral grooves 3131 inside to generate spiral supercharging, which is sucked in by negative pressure and broken up to form smaller micro-bubbles that are dissolved in the flowing water and then introduced into the fish bowl at high pressure, thereby reaching the height inside the fish bowl. It has the main effects of increasing oxygen in fish ponds and purifying water quality in a large area.

Please also refer to Figure 9, which is a schematic diagram of the use of high-efficiency microbubble dissolved oxygen equipment in fish ponds. The chassis 12 of the motor 10 is set behind a square underwater frame A and placed in the deep water area at the bottom of the fish pond. The motor body 11 of the motor 10 is disposed in the bottom water area of the fish tank. The motor body 11 of the motor 10 is pressurized to extract the water in the fish tank from the bottom frame 12 and through the interface portion 111 of the motor 10 The water flow is driven to flow sequentially to the vertical main pipeline 21 and the horizontal main pipeline 22 of the pipe frame body 20 and the two covers 24. Since each cover 24 makes the internal flow pipeline a closed space, the water flow in the fish pond is extracted. After each of the elbows 23 enters the high-efficiency dissolved oxygen injection pipe body 31, the second end 322 of the first air inlet elbow 32 is connected to the outside to provide negative pressure air to be inhaled into the first inlet in sequence. 36 from the first end 321 of the air bend pipe 32 to the air column plate 3121 of the second joint end 312 After the air is divided and pressurized to form microbubbles, the first pressurized microbubbles are guided into the air collecting tank 3122, and the water flow will sequentially pass through the first part of the high-efficiency dissolved oxygen injection tube body 31. The first aperture 3111, the second aperture 3112 and a third aperture 3113 in the joint end 311 are designed to produce a Venturi effect due to the different cross-sectional area designs of the first aperture 3111 and the third aperture 3113 being larger than the second aperture 3112. After the flowing water is pressurized to form a second change in pressurization speed, the micro-bubbles in the air collecting tank 3122 are guided by the pressurization speed and driven by the negative pressure to be sucked and broken into smaller micro-bubbles toward the ejection water end 313. A plurality of staggered left and right spiral grooves 3131 produce a spiral pressurization action. The micro-bubbles in the air collecting groove 3122 guide the pressurization speed and are sucked in and broken by the negative pressure to form smaller micro-bubbles toward the ejection water end 313. There are a plurality of staggered left and right spiral grooves 3131 inside. After the spiral groove 3131 generates spiral pressurization, it is sucked in by negative pressure and broken to form smaller micro-bubbles that dissolve in the flowing water and are then led to the deep water area at the bottom of the fish tank under high pressure, thereby reaching the deep water area at the bottom of the fish tank to increase oxygen and The main effect is to purify water quality.

Please also refer to Figures 10 and 11, which are perspective views of another embodiment of a high-efficiency dissolved oxygen generation mechanism. The high-efficiency dissolved oxygen generation mechanism 30 is provided with a cylindrical joint 33, a cylindrical cylinder 34 and a The quick connector 35 is designed with cross-sectional areas of different inner diameters and has a first end 331 and a second end 332 of internal threads. The first end 331 is screwed on the pipe frame 20 At one end of the elbow 23, the other second end 332 is screwed to one end of the cylinder 34. The cylinder 34 is provided with a screw lock portion 341 with external threads, a through hole portion 342 with internal threads, and a jet. At the water outlet end 343, the screw lock portion 341 of the cylinder 34 is locked and fixed with the second end 332 of the joint 33. The perforated portion 342 is for the quick connector 35 to be screw-locked and fixed, and the jet water outlet end 343 has an internal system. It is equipped with a plurality of staggered left and right spiral grooves, and the above combination provides a high-efficiency dissolved oxygen generation mechanism that is easy to produce and combine for use.

Please also refer to Figures 12 to 13 for another example of high-efficiency micro-bubble oxygen-dissolving equipment being used on the surface of the fish pond. Please refer to Figure 12 for another example of high-efficiency micro-bubble oxygen-dissolved equipment installed on the water surface. The floating plate frame 40 is provided with two floating plates 41 and a frame 42. The motor 10 is a gear pump, and the motor body 11 of the motor 10 is arranged in the frame 42, and the motor 10 is a gear pump. The pipe frame body 20 is disposed at the bottom of the two floating plates 41 in the fish tank. The water in the fish tank is extracted from the pipeline at the bottom frame 12 through the pressurization of the motor body 11 of the motor 10, and is pumped through the interface of the motor 10. 111 to drive the water flow to the inside of the pipe frame body 20 in sequence, and then enter the high-efficiency dissolved oxygen injection pipe body 31 respectively. The second end 322 of the first air inlet elbow 32 is connected to the outside to provide negative pressure. The air is sequentially sucked into the first end 321 of the first air inlet elbow 32 and then reaches the 36 fine holes of the air column plate 3121 of the second joint end 312 where the air is divided, pressurized and broken to form microbubbles, and then the air is Once pressurized, microbubbles are guided into the gas collecting tank 3122, and the water flow will sequentially pass through the first aperture 3111, the second aperture 3112 and a first joint end 311 of the high-efficiency dissolved oxygen injection pipe body 31. Three apertures 3113, because the diameter of the first aperture 3111 and the third aperture 3113 is larger than that of the second aperture 3112, the different cross-sectional area designs produce a Venturi effect, which in turn causes the flowing water to be pressurized to form a second pressurization speed change. The micro-bubbles in the air collecting groove 3122 are guided by the pressurization speed and are sucked and broken by the negative pressure to form smaller micro-bubbles toward the ejection water end 313. A plurality of staggered left and right spiral grooves 3131 are provided in the air collecting groove 3122 to produce a spiral pressurization action. The micro-bubbles in the groove 3122 guide the pressurization speed and are sucked and broken by the negative pressure to form smaller micro-bubbles toward the ejection outlet 313. There are a plurality of staggered left and right spiral grooves 3131 in the groove 3122 to generate spiral supercharging, so that they are sucked in and broken by the negative pressure. It is broken into smaller micro-bubbles and dissolved in the flowing water, and then introduced into the fish tank under high pressure, thereby achieving a high efficiency and large-scale increase in oxygen in the fish tank and purifying the water quality in the fish tank, and through the floating plate frame 40, it can be achieved The main effect is to increase the efficiency of dissolved oxygen in a wide range by moving the fish; please refer to Figures 13 and 14, in which a high-efficiency dissolved oxygen generating mechanism 30 is directly installed The pipe frame body 20 on the interface portion 111 of the motor body 11 of the motor 10 is arranged on the floating plate frame body 40 by the motor body 11 of the motor 10 and is pressurized by the motor body 11 and is combined with the bottom frame 12 The water in the fish pond is extracted from the pipe body, and driven from the interface part 111 of the motor 10 to the pipe frame body 20 to flow to the high-efficiency dissolved oxygen spray pipe body 31, and enters the high-efficiency dissolved oxygen spray pipe body 31. The first inlet The second end 322 of the air bend 32 is connected to the outside world to provide negative pressure air, which is sequentially sucked into the first end 321 of the first air intake bend 32 and then reaches the 36 small diameters of the air column plate 3121 of the second joint end 312 After the air is divided, pressurized and crushed to form microbubbles, the first pressurized microbubbles are guided into the air collection tank 3122, and the water flow will sequentially pass through the first joint of the high-efficiency dissolved oxygen injection pipe body 31 The first aperture 3111, the second aperture 3112 and a third aperture 3113 in the end 311, because the diameter of the first aperture 3111 and the third aperture 3113 is larger than that of the second aperture 3112, different cross-sectional area designs produce a venturi effect, thereby making After the flowing water is pressurized to form a second change in pressurization speed, the micro-bubbles in the air collecting tank 3122 are guided by the pressurization speed and driven by the negative pressure to be sucked and broken into smaller micro-bubbles toward the ejection water end 313. The staggered left and right spiral grooves 3131 produce a spiral pressurization action. The micro-bubbles in the gas collection groove 3122 guide the pressurization speed and are sucked and broken by the negative pressure to form micro-bubbles toward the ejection outlet 313. There are a plurality of staggered left and right spiral grooves inside. After the groove 3131 generates spiral supercharging, it is suctioned and broken by negative pressure to form smaller micro-bubbles that are dissolved in the flowing water and then introduced into the fish tank at high pressure, thereby achieving the main effect of increasing the large-scale area of high efficiency in the fish tank.

From the structure of the above specific embodiment, the following benefits can be obtained: In this high-efficiency microbubble oxygen-dissolving equipment, the second end 322 of the first air inlet elbow 32 is connected to the outside world to provide negative pressure air for sequential inhalation. After the 36 fine holes of the air column plate 3121 from the first end 321 of the first air inlet elbow 32 to the second joint end 312 are divided and pressurized to form microbubbles, the air is then pressurized for the first time. The micro-bubbles are guided into the air collecting tank 3122, and the water flow It will pass through the first aperture 3111, the second aperture 3112 and a third aperture 3113 in the first joint end 311 of the high-efficiency dissolved oxygen injection pipe body 31 in sequence, because the diameters of the first aperture 3111 and the third aperture 3113 The design of different cross-sectional areas larger than the second aperture 3112 produces a Venturi effect, which in turn causes the flowing water to be pressurized. After the second pressurization speed changes, the microbubbles in the air collecting tank 3122 are guided by the pressurization speed and are sucked in by the negative pressure. The smaller micro-bubbles are broken and formed toward the ejection water end 313. There are a plurality of staggered left and right spiral grooves 3131 inside to produce a spiral pressurization action. The micro-bubbles in the air collection groove 3122 are guided by the pressurization speed and are sucked in by negative pressure and broken into pieces. Smaller micro-bubbles are directed toward the jet water outlet 313 and are equipped with a plurality of staggered left and right spiral grooves 3131 to generate spiral pressurization, forming a double pressurization method. They will be sucked in and broken by negative pressure to form smaller micro-bubbles that are dissolved in the flowing water. The high pressure is then introduced into the fish pond, thereby achieving the main effects of increasing the oxygen in the fish pond and purifying the water quality in a large area with high efficiency.

This invention creates a high-efficiency micro-bubble dissolved oxygen equipment, in which the chassis 12 of the motor 10 is set behind a square underwater frame A and is placed in the deep water area at the bottom of the fish pond, thereby increasing oxygen and purifying the deep water area at the bottom of the fish pond. Water quality is the main effect.

This invention creates a high-efficiency micro-bubble oxygen-dissolving equipment, in which the floating plate frame 40 is used to move in the fish pond and achieve the main effect of increasing the efficiency of dissolved oxygen in a wide range.

10: Motor

11:Motor body

111:Interface Department

12: Bottom frame

20: Pipe frame body

21:Vertical main pipeline

22: Lateral main pipeline

23:Bend pipe

24: Cover

30: High-efficiency dissolved oxygen generation mechanism

31: High efficiency dissolved oxygen injection pipe body

311: first joint end

312: Second joint end

3121:Air column plate

3122:Gas collecting tank

313: Jet water end

3131: Spiral groove

32:First air intake elbow

321: first end

322:Second end

33:Connector

331:First end

332:Second end

34: Cylinder

341:Screw lock part

342: Perforation part

343: Jet water end

35:Quick connector

40: Floating board frame

41:Floating board

42:Frame

A: Underwater frame

The first picture is a three-dimensional view of this creation. The second picture is a three-dimensional exploded view of this creation. The third picture is a schematic cross-sectional view of this creation. The fourth picture is a schematic cross-sectional view of the high-efficiency dissolved oxygen generating mechanism of this invention. The fifth figure is a schematic cross-sectional view of the high-efficiency dissolved oxygen generating mechanism of this invention. The sixth picture is a schematic diagram of the usage state of this creation in the fish farm. The seventh picture is a schematic cross-sectional view of this creation in use in deep water. The eighth picture is a schematic diagram of the three-dimensional action of this creation when it is used in deep water. The ninth picture is a schematic diagram of the use of high-efficiency microbubble dissolved oxygen created in the deep water of Yushan. The tenth figure is a perspective view of another embodiment of the high-efficiency dissolved oxygen generating mechanism of the present invention. Figure 11 is an exploded three-dimensional view of another embodiment of the high-efficiency dissolved oxygen generating mechanism of the present invention. The twelfth picture is a schematic diagram of another embodiment of the invention being used on the water surface of the fish pond. Figure 13 is a schematic diagram of another embodiment of the present invention being used on the surface of the fish pond.

Figure 14 is a schematic diagram of another embodiment of the present invention being used on the surface of the fish pond.

20: Pipe frame body

23:Bend pipe

30: High-efficiency dissolved oxygen generation mechanism

31: High efficiency dissolved oxygen injection pipe body

311: first joint end

3111: First aperture

3112: Second aperture

3113:Third aperture

312: Second joint end

3121:Air column plate

3122:Gas collecting tank

313: Jet water end

3131: Spiral groove

32:First air intake elbow

321: first end

Claims (11)

A high-efficiency microbubble dissolved oxygen equipment, which includes: a motor; a pipe rack body, the pipe rack system is assembled on the motor; and at least one high-efficiency dissolved oxygen generating mechanism, the high-efficiency dissolved oxygen generating mechanism has an internal system A structure that can produce a venturi effect and a spiral pressurization action. The motor is installed in a fish tank. The motor guides the water in the fish tank and then cooperates to drive the flowing water through the pipe frame in sequence and then enters the high In the space of the high-efficiency dissolved oxygen generation mechanism, and with the dual pressurization method of the Venturi effect and spiral boosting in the high-efficiency dissolved oxygen generation mechanism, the outside air is sucked in by negative pressure and broken to form smaller micro bubbles in the flowing water. Then it is guided into the water inside the fish pond. A high-efficiency microbubble oxygen-dissolving equipment, which includes: a motor, the motor is provided with an interface part; a pipe frame body, the pipe frame system is provided with a vertical main pipeline, a horizontal main pipeline, at least one elbow and two covers body, one end of the vertical main pipeline is connected and fixed to the interface of the motor, and the other end is connected to one end of the horizontal main pipeline. The elbow pipes are spaced apart from the transverse main pipelines of the pipe frame body, and the two free ends of the transverse main pipeline are It is for the two covers to be sealed to form a sealed space in the transverse main pipeline; at least one high-efficiency dissolved oxygen generating mechanism is arranged on the bend of the transverse main pipeline of the pipe frame body , its high-efficiency dissolved oxygen generation mechanism is equipped with a high-efficiency dissolved oxygen injection pipe body and a first air inlet elbow. The high-efficiency dissolved oxygen injection pipe system is provided with a first joint end, a second joint end and an injection The water outlet end, the first joint end is arranged at the bend of the transverse main pipeline of the pipe frame body tube, the first joint end of which is provided with a cross-section changing aperture of a Venturi structure, and the first joint end of which is provided with a first aperture, a second aperture and a third aperture in sequence, wherein the first The aperture and a third aperture have a diameter larger than the second aperture, and the second joint end is located at the third aperture close to the first joint end, and the second joint end is provided for the first air inlet elbow to be combined, and the second joint end is provided with the first air inlet elbow. The two joint ends are equipped with an air column plate, and the air column plate is provided with an air collection groove near the third aperture. In addition, the jet water end is provided with a plurality of staggered left and right spiral grooves, and the spiral grooves are Extending to the third aperture position of the first joint end, the first air inlet elbow is provided with a first end and a second end, the first end is provided at the second joint end, and the second The end is connected to the outside world to provide air entry into the inside. The high-efficiency micro-bubble oxygen dissolving equipment described in claim 2, wherein the motor is provided with a motor body for assembly on a circular frame chassis, and the upper interface of the motor body is connected to the vertical main pipeline. The high-efficiency microbubble dissolved oxygen equipment as described in claim 2, wherein the vertical main pipeline and the transverse main pipeline of the pipe frame are cylindrical, and the four bent pipes are L-shaped for locking the high-efficiency dissolved oxygen generation mechanism. On top. The high-efficiency microbubble oxygen-dissolving equipment as described in claim 2, wherein the high-efficiency dissolved oxygen injection pipe body is formed in one piece, and the first air inlet elbow has a flexible arc shape. As for the high-efficiency microbubble oxygen-dissolving equipment described in claim 2 or 3, the sequential procedures in use are as follows: the first is the water pumping procedure: the motor body of the motor is installed in the middle water area at the bottom of the fish pond, The water in the fish tank is extracted from the bottom frame by pressurizing the motor body. ; The second is the guidance process: the interface part of the motor drives and guides the water flow to flow sequentially to the vertical main pipeline and the horizontal main pipeline of the pipe frame body and the two covers, because each cover makes the internal flow pipeline sealed space, so the water flow in the fish pond is extracted and directed towards each elbow, and then enters the high-efficiency dissolved oxygen injection pipe body respectively; the third is the first pressurization process: the second step of the first air inlet elbow The end is connected to the outside world to provide negative pressure air, which is sequentially sucked in from the first end of the first air inlet elbow to the fine aperture of the air column plate at the second joint end, where the air is divided, pressurized and broken to form microbubbles, and The first pressurization is conducted into microbubbles and guided into the gas collecting tank; the fourth is the second pressurization process: the water flow will sequentially pass through the first joint end of the high-efficiency dissolved oxygen injection pipe body. aperture, a second aperture and a third aperture. Because the diameter of the first aperture and the third aperture are larger than the second aperture, the different cross-sectional area designs produce a Venturi effect, thereby pressurizing the flowing water to form a second pressurization. After the speed changes, the micro-bubbles in the air collecting groove are guided by the pressurization speed and are sucked and broken by the negative pressure to form smaller micro-bubbles towards the ejection water end. There are a plurality of staggered left and right spiral grooves inside to produce a spiral pressurization action; fifth Efficient oxygenation program for the fish pond: The micro-bubbles in the air collecting tank guide the pressurization speed and are sucked and broken by the negative pressure to form smaller micro-bubbles towards the ejection water end. The internal system is equipped with a plurality of staggered left and right spiral grooves to produce spiral growth. After pressure, the above-mentioned double pressurization method is suctioned and broken by negative pressure to form smaller micro-bubbles, which are dissolved in the flowing water and then introduced into the fish tank under high pressure. The high-efficiency microbubble oxygen-dissolving equipment as described in claim 2, wherein the chassis of the motor is installed behind a square underwater frame and placed in the deep water area at the bottom of the fish farm. A high-efficiency microbubble oxygen dissolving equipment, which includes: a motor, the motor is provided with a motor body for assembly on the bottom frame of a circular frame, and the motor body is also provided with a circular interface portion connected to the motor body ; A pipe frame body is provided at the circular interface portion of the motor body; a high-efficiency dissolved oxygen generating mechanism is directly provided at the interface portion of the motor body of the motor, whereby the motor body of the motor is provided on a floating The plate frame body is pressurized by the motor body to extract the water in the fish pond from the bottom frame combined with a pipe body, and is driven by the interface part of the motor to flow to the high-efficiency dissolved oxygen injection pipe body. The high-efficiency dissolved oxygen spray pipe The system is provided with a first joint end, a second joint end and a water jet end. The first joint end is arranged on the pipe frame body, and the first joint end is set as a cross-sectional change of the venturi structure. Aperture, the first joint end is provided with a first aperture, a second aperture and a third aperture in sequence, wherein the first aperture and a third aperture are larger in diameter than the second aperture, and the second joint end is provided with Close to the third aperture of the first joint end, the second joint end is provided for the first intake elbow to be combined, and an air column plate is provided inside the second joint end, and the air column plate is close to the third aperture. The aperture system is provided with an air groove, and the jet water outlet end is provided with a plurality of staggered left and right spiral grooves, and the spiral grooves extend to the third aperture position of the first joint end. The first air inlet elbow system A first end part and a second end part are provided, the first end part is arranged at the second joint end, and the second end part is connected to the outside to provide air to enter inside. The high-efficiency microbubble oxygen-dissolving equipment described in claim 1, 2, or 8, wherein the motor is a high-pressure air supply waterproof motor or gear pump. The high-efficiency micro-bubble oxygen-dissolving equipment as described in claim 8, wherein the high-efficiency micro-bubble oxygen-dissolving equipment is installed on a floating plate frame, and the floating plate frame system is provided with two The floating plate and a frame, the motor system of the motor is arranged in the frame, and the pipe rack system is arranged at the bottom of the two floating plates and is located in the fish pond. The high-efficiency microbubble dissolved oxygen equipment as described in claim 1 or 2 or 8, wherein the high-efficiency dissolved oxygen generating mechanism is provided with a joint, a cylinder and a quick joint, and the joint has cross-sectional areas of different inner diameters It is designed and has a first end and a second end with internal threads. The first end is screwed at one end of the pipe frame body, and the other second end is screwed at one end of the column. The column system is provided with A screw lock part with external threads, a perforated part with internal screw threads and a water jet end. The screw lock part of the cylinder is locked and fixed with the second end of the joint. The perforated part is for quick connector screws. The lock is fixed on the top, and the jet water outlet end is provided with a plurality of staggered left and right spiral grooves.

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