KR200331006Y1 - Aeration device using vacuum ferromagnetic pump - Google Patents

Abstract

The present invention relates to an aeration device using a vacuum ferromagnetic pump, in the present invention is a pumping unit provided with a pump for pumping water of the tank, the ejector and the discharge pipe of the pump is connected to the pipe and the external air is connected to the ejector The first air suction unit is provided with an air inlet for introducing the vacuum suction pump is composed of a vacuum suction pump connected to the pipe, the first air suction unit, and an ejector connected to the vacuum suction pump and the vacuum suction pump And an underwater aeration device including a second air suction unit connected to the ejector and having an air inlet for introducing external air therein, the noise being generated by operating the pumping unit and the underwater pumping unit in the water through the fixing unit. It can be used safely while minimizing, can supply air to a deep depth, and the first and second air intakes using the ejector Supplying a large amount of oxygen through the wealth at the same time to discharge the water in the form of fine droplets has the effect of improving the aeration efficiency.

Description

Aeration device using vacuum ferromagnetic pump

The present invention relates to an underwater aeration apparatus, and more particularly to an underwater aeration apparatus that can improve the aeration efficiency by supplying a large amount of oxygen in the water.

In general, in order to farm fish or plants in fish farms or farms, the amount of oxygen dissolved in water (hereinafter referred to as 'dissolved oxygen') must be a certain amount or more.

This is because a certain amount of oxygen is required for the organic matter in the water to be stabilized and naturally purified by the action of aerobic microorganisms.

Therefore, fish farms and farms are emerging as an urgent task to supply and maintain a certain amount of dissolved oxygen for the growth of fish and plants.

In addition to such fish farms and farms, the supply and maintenance of a certain amount or more of dissolved oxygen is essential to maintain proper water quality or to purify water to proper water quality.

Therefore, various methods have been sought to supply and maintain a certain amount or more of dissolved oxygen in fish farms, farms, and sewage treatment plants. For example, an underwater aeration apparatus using a pump may be mentioned. In this way, the aeration apparatus using the pump installs the pump outside the tank, and installs the suction pipe and the discharge pipe inside the hydrogen, and installs the air inlet pipe through which the outside air flows into the suction pipe of the pump. It pumps water from the tank and supplies air.

Alternatively, the underwater oxygen supply device, which is registered in advance through Patent Registration No. 363740, adopts an air supply method by an ejector, and has a configuration in which a pump for pumping water in a tank is installed on the surface by a support body.

However, the prior art underwater aeration apparatus, including the pre-registration draft is a problem that is accompanied by a very loud noise as the device is operated because it is installed outside the water.

In particular, in the case of the above-mentioned pre-registration draft, there is a risk that the pump may be in contact with water during operation or handling as it is installed in the water suspended state.

In addition, the conventional underwater aeration device forcibly pushes the outside air, there is a problem that can not supply oxygen to a depth of relatively high pressure depth.

Therefore, the present invention was devised to solve the general problems of the conventional underwater aeration apparatus,

The object of the present invention is to provide an underwater aeration device that can be safely used while minimizing noise during operation.

In addition, the present invention provides an underwater aeration apparatus that can improve aeration efficiency by supplying air to a deep depth and supplying a large amount of oxygen.

Figure 1a is an overall configuration for explaining the underwater aeration apparatus according to the present invention.

Figure 1b is an exploded perspective view for explaining the coupling state of the support plate and the fixed rod in the underwater aeration apparatus according to the present invention.

2 is a cross-sectional view schematically showing the fluid flow of the underwater aeration apparatus according to the present invention.

3 is a block diagram schematically illustrating a second embodiment of the underwater aeration apparatus according to the present invention.

Figure 4 is a block diagram for schematically explaining a third embodiment of the underwater aeration apparatus according to the present invention.

<Description of the code | symbol about the principal part of drawing>

1,1 ', 1 ": Submersible aeration device 2: Pumping part

3: first air suction unit 4: submersible pumping unit

5: second air suction unit 6: fixed unit

7: Blower unit 21: Pump

22: filter 31,51: ejector

32,52: air suction port 41: vacuum suction pump

61: base plate 62: ball

63: connecting member 64: fixed rod

71: air blower 72: float

411 impeller 412 suction stage

413 discharge stage 414 air inlet pipe

415: suction pipe 611: locking portion

612: second hook 621: first hook

641: rod portion 642: head portion

B: Bolt N: Nut

As a specific means of the present invention for achieving the above object;

A pumping unit having a pump for pumping water of the tank;

A first air suction unit having an ejector to which the discharge pipe of the pump is connected and an air suction port connected to the ejector to introduce external air;

An underwater pumping unit configured of a vacuum suction pump connected to the first air suctioning unit and installed inside the tank; And

It is achieved by having an underwater aeration apparatus including an ejector connected to the vacuum suction pump and a second air suction unit connected to the ejector and having an air suction port for introducing external air.

In this case, a fixing unit is further included to install the pumping unit, the first and second air suction units, and the submersible pumping unit in the water tank.

In addition, the fixing unit is a support tube positioned in the water, the support plate is connected to the support plate and the support plate is located in the water to support the support plate on the water surface, the connecting member connecting the support plate and the ball, and the support plate at a certain position in the water It consists of a fixed rod that is fixed to

In addition, the pump of the pumping unit is installed in the water tank by applying an underwater pump.

In addition, the vacuum suction pump of the submersible pumping unit may be directly connected to the pump of the pumping unit.

In addition, the vacuum suction pump of the submersible pump is connected to a suction pipe having an air inlet pipe to the vacuum suction pub of the submersible pump unit to exclude the configuration of the pumping unit and the first air suction unit water and the outside of the tank through the suction pipe You can also inhale air directly.

In addition, a blower unit for forcibly injecting air is connected to the air inlets of the first and second air suction units.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1a is an overall configuration diagram for explaining the underwater aeration apparatus according to the present invention, Figure 1b is an exploded perspective view for explaining the coupling state of the support plate and the fixed rod in the underwater aeration apparatus according to the present invention.

Referring to FIG. 1A, the underwater aeration apparatus 1 of the present invention includes a pumping unit 2, a first air suction unit 3, an underwater pumping unit 4, and a second air suction unit 5. The pumping part 2, the first and second air intake parts 3 and 5, and the submersible pumping part 4 are installed in the water tank through the fixing unit 6.

At this time, the pumping unit 2 is provided with a pump 21 for pumping the water of the tank. Such a pumping unit 2 is preferably installed inside the tank by applying an underwater pump, and may be installed outside the tank depending on the conditions of the installation place. In addition, the suction end of the pump 21 is provided with a fine filter 22 to prevent the inflow of impurities and fry in the water tank.

In addition, the first air suction unit 3 is typically composed of an ejector 31 widely used in the hydraulic and pneumatic fields, and an air suction port 32 connected to the ejector 31. The ejector 31 is composed of a Venturi tube type in which the flow path inside the pipe is narrowed and widened in the middle so that the flow velocity of the fluid can be changed along the way, and the discharge end of the pump 21 is It is connected to the inlet. And, the air inlet 32 is installed so that one side end is connected to one side of the ejector 31 and the lower end protrudes above the water surface, the portion where the air inlet 32 is connected to the ejector 31 is an ejector ( 31) It is preferable to connect to the site | part which narrows and then expands again.

Accordingly, the first air suction unit 3 generates negative pressure by discharging the water in the tank supplied by the pump 21 through the ejector 31, and the external air is sucked into the air inlet 32 by the negative pressure. It enters through and discharges with water.

On the other hand, the submersible pump 4 is applied to the vacuum suction pump 41, for example, "vacuum suction pump", which is registered in advance by the applicant in the domestic patent registration No. 175650. Such a vacuum suction pump 41 has a configuration in which a motor of a conventional submersible pump is applied to a power unit for installation in water, but an impeller 411 is installed in such a motor shaft. The vacuum suction pump 41 is connected to an outlet of the ejector 31 of the first air suction unit 3 to the suction end 412, and a second air suction unit (described later) to the discharge end 413. 5) is connected.

Accordingly, in the submersible pump 4, the impeller 411 installed inside the vacuum suction pump 41 rotates and sucks water and external air through the suction end 412, and the impeller 411 is sucked in. As it rotates as a form of striking water, the water is made into a micro bubble, and thus serves to easily mix external air.

At this time, the vacuum suction pump 41 of the submersible pump 4 may be applied to the vacuum magnetic induction pump, which was previously filed by the applicant in the Korean Patent Publication No. 2000-66454 in addition to the pre-registered vacuum suction pump, Alternatively, the same effect can be obtained by applying a vacuum ferromagnetic pump pre-registered by the applicant of the Korean Utility Model Registration No. 194139, or by applying a multi-stage ferro-suction pump that has been filed by the applicant as Korean Patent Publication No. 2003-30316. In addition, depending on the installation site, only the vacuum suction pump may be installed on the ground.

In addition, the second air suction unit 5 has the same configuration as the first air suction unit 3 described above, and the inlet of the ejector 51 is connected to the discharge end of the vacuum suction pump 41. The air suction port 52 connected to the ejector 51 protrudes above the water surface. In the second air suction unit 5, the water in the form of water droplets mixed with external air is supplied from the vacuum suction pump 41 to the inlet side, and is strongly discharged to the outlet side. As the external air is sucked in, mixed with water, and discharged, the bubble-type water having a high oxygen dissolution rate is discharged.

In this case, a blower unit 7 for forcibly supplying air may be installed in the air inlets 32 and 52 connected to the ejectors 31 and 51 of the first and second air suction units 3 and 5. Such a blower unit 7 is composed of an air blower 71 and a float 72, the air blower 71 is connected to the other end of each air inlet (31, 51) protruding a certain distance over the water surface to receive air It serves to force the injection, the buoy 72 is used when the air blower 71 is installed on the water surface.

On the other hand, in the present invention, the pumping unit 2, the first and second air intakes (3, 5) and the submersible pump (4) is provided with a fixing unit (6) to the inside of the tank. The fixing unit 6 is a support plate 61 which is located in the water, and the support plate 61 is connected to the support plate 61 to support the support plate 61 on the water surface, and the support plate 610 and the support 62 It is composed of a connecting member 63 for connecting and a fixing rod 64 for fixing the support plate 61 to a predetermined position in the water.

At this time, the buoy 62 is formed of a plastic and relatively light weight material so as to float on the surface in the shape of a sphere or a cube, such as a sphere or hexahedron, the lower end of the connection member 63 is easily fitted The first hook 621 is formed to be able to. In addition, the first catching ring 621 may be implemented in a form such as a carabiner for climbing, that is, a structure that is not easily released before the worker unwinds by hand, as shown in the drawing.

In addition, the backing plate 61 has a panel shape having a predetermined thickness, and a vacuum suction in which a pump 21 and ejectors 31 and 51 of the first and second air inlets 3 and 5 are connected to a central portion thereof. A predetermined coupling hole is formed to allow the pump 41 to be mounted by a coupling bolt, etc., and a second engaging portion 611 and a connecting member 63 to which the fixing rod 64 is fitted at one end and the other end thereof. Hanging rings 612 are formed respectively.

At this time, the second hook 612 is preferably configured in a similar form to the first hook 621, that is, the second hook 612 is a climbing carabiner that is not easily released before the worker unwinds by hand. It is implemented in the form

Accordingly, the supporting plate 61 is installed so that the second catching ring 612 is connected to the first catching ring 621 of the float 62 by the connecting member 63 so that it can float in the water.

Here, the engaging portion 611 of the support plate 61, the fixing rod 64 is fitted has a configuration bent in the shape of '∪' as shown in Figure 1b, these holes by forming a predetermined size of holes at both ends Through the bolt (B) and the nut (N) has a configuration that is fixed.

Accordingly, when the fixing rod 64 is inserted into the catching portion 611 or the fixing rod 64 is to be pulled out of the catching portion 611, the worker may use the bolt B and the nut ( After loosening N), the fixing rod 64 can be pinched or removed from the locking portion 611.

In addition, the connection member 63 is preferably implemented as a chain (Chain), etc. are connected to a plurality of oval-shaped ring so as to be easily caught in the first and second hooks (621, 612) described above. Thus, the operator can control the underwater position by reducing or increasing the chain connected between the two hooks (621, 612).

On the other hand, the fixing rod 64 for fixing the support plate 61 to the bottom surface is a rod portion 641 is fixed to the bottom surface of the underwater in the shape of a rod of a predetermined thickness, and is formed on the top of the rod portion 641 It consists of the head part 642. The fixing rod 64 sets the length of the rod portion 641 so that the head portion 642 can protrude above the surface of the water, and the head portion 642 separates the engaging portion 611 of the support plate 61. It is formed to a diameter larger than the diameter of the rod portion 641 to prevent.

Accordingly, the fixing rod 64 is fitted to the engaging portion 611 of the support plate 61 and is fixed to the bottom surface of the water. The ejector of the pump 21 and the first and second air intake units 3 and 5 is fixed. The support plate 61 on which the vacuum suction pump 41 connected with the 31 and 51 is connected may flow up and down a predetermined distance along the rod part 641 of the fixed rod 64.

2 is a cross-sectional view schematically showing the fluid flow of the underwater aeration apparatus 1 according to the present invention.

Referring to FIG. 2, the water in the tank is pumped by the pump 21 of the pumping unit 2 and supplied to the ejector 31 of the first air suction unit 3.

The first air suction unit 3 generates a negative pressure by discharging the water in the tank supplied by the pump 21 through the ejector 31, and the external air flows through the air suction port 32 by this negative pressure. To supply the vacuum suction pump 41 to the suction end 412 of the underwater pumping unit 4 with water.

In the submersible pump 4, an impeller 411 installed inside the vacuum suction pump 41 rotates, sucks water and external air from the first air suction unit 3, and sucks the impeller 411. As it rotates as it hits the water, it makes water into small droplets and mixes it with outside air.

The second air intake unit 5 receives water in the form of water droplets mixed with external air at the inlet side and strongly discharges it to the outlet side, and again inhales the external air, mixes it with water, and discharges it in the form of a strong jet. .

Accordingly, the underwater aeration apparatus 1 of the present invention can minimize noise while operating in a state in which all the components are installed in the water through the fixing unit 6, and at the same time performing agitation and aeration in the water tank There is an advantage that the air can be introduced to the bottom of the deep tank, and the water is mixed with the air in the form of fine water droplets and discharged, which has the advantage of doubling the oxygen dissolution rate.

3 is a block diagram schematically illustrating a second embodiment of the underwater aeration apparatus according to the present invention.

Referring to FIG. 3, the underwater aeration apparatus 1 ′ according to the second embodiment of the present invention is a vacuum suction pump 41 of the above-described underwater pumping unit 4 in a state in which the configuration of the first air suctioning unit 3 is excluded. ) Directly connected to the pump 21 of the pumping unit (2). The underwater aeration device 1 ′ of the second embodiment makes the water of the tank supplied from the pumping unit 2 into a bubble form in the vacuum suction pump 41 of the underwater pumping unit 4, and then the second air suction unit. It is supplied to (5) and discharged in the state mixed with external air.

Figure 4 is a block diagram for schematically explaining a third embodiment of the underwater aeration apparatus according to the present invention.

Referring to FIG. 4, the underwater aeration apparatus 1 ″ according to the third embodiment of the present invention includes the underwater pumping unit 4 in a state in which the configuration of the pumping unit 2 and the first air suction unit 3 is excluded. A suction pipe 415 is connected to the suction end 412 of the vacuum suction pump 41, and an air inlet pipe 414 is formed in the suction pipe 415 to directly suck water from the tank through the suction pipe 415. The underwater aeration apparatus 1 "of the third embodiment of the present invention is configured to draw the water of the tank through the suction pipe 415 as the vacuum suction pump 41 applied to the underwater pumping unit 4 performs the suction operation in a vacuum state. Since a negative pressure is generated when directly inhaled, external air is introduced through the air inlet pipe 414 to mix water and air, and then supplied to the second air intake unit 5.

The above-described underwater aeration device (1 ', 1 ") of the second and third embodiments is a simplified component according to the size of the tank, it is possible to be modified according to the conditions of the installation site.

As described above, the underwater aeration apparatus according to the present invention has a merit that it can be safely used while minimizing noise while operating in a state where the pumping unit and the underwater pumping unit are installed in the water through a fixed unit.

In addition, the underwater aeration device installed in the water as well as supplying air to the depth of the deep, while supplying a large amount of oxygen through the first and second air intake unit applying the ejector and at the same time discharge the water in the form of fine droplets There is an effect that can improve the aeration efficiency.

Claims (7)

A pumping unit having a pump for pumping water of the tank; A first air suction unit having an ejector to which the discharge pipe of the pump is connected and an air suction port connected to the ejector to introduce external air; An underwater pumping unit configured of a vacuum suction pump connected to the first air suctioning unit and installed inside the tank; And An aerator using a vacuum ferromagnetic suction pump including an ejector connected to the vacuum suction pump and a second air suction unit connected to the ejector and having an air suction port for introducing external air. The aeration apparatus according to claim 1, further comprising a fixing unit for installing the pumping unit, the first and second air suction units, and the submersible pumping unit in the water tank. According to claim 2, wherein the fixing unit is a support plate positioned in the water, the support plate is connected to the support plate and the support plate on the water so that the support plate is located in the water, a connecting member for connecting the support plate and the ball, and the support plate underwater Aeration device using a vacuum ferromagnetic suction pump, characterized in that consisting of a fixed rod that is fixed to a predetermined position of the. The aeration apparatus according to claim 1, wherein the pump of the pumping part is installed in the water tank by applying an underwater pump. The aeration apparatus according to claim 1, wherein the vacuum suction pump of the submersible pump is directly connected to the pump of the pumping part. According to claim 1, wherein the vacuum suction pump of the submersible pumping unit is connected to the suction pipe having an air inlet pipe to directly suck the water and external air of the water tank through the suction pipe in the state of excluding the configuration of the pumping unit and the first air suction unit Aeration device using a vacuum ferromagnetic suction pump, characterized in that configured to. The aeration device according to claim 1, wherein a blower unit for forcibly injecting air is connected to the air inlets of the first and second air suction units.