KR800001078B1 - Apparatus for electrostatically purifying non-conductive liquid - Google Patents

Abstract

An electrostatic liquid purification appts. comprises a tank(10) containing anode and cathode plates(20,25) in an interleaved opposed relationship. A conduit(53) has apertures(55) at its upper surface for dispersing liquid. Particle collector plates of porous dielectric fibers(40) are disposed between the electrode plates in parallel with the direction of the electrode field created by the plate and the flow of liquid spurted from the conduit & tank bottm. A liquid outlet pipe removes treated liquid form the top of the tank & a drainage pipe(60) discharges liquid remaining in the particle precipitation space.

Description

Liquid electrostatic purification device

1 is a layout view of a dust collector in the apparatus of the present invention.

2 is a diagram of a conventional dust collector.

3 is a dust collection characteristic diagram.

Figure 4 is an overall side view showing an embodiment of the present invention.

5 is a perspective view cut out to clarify the internal structure of the septic tank.

6 is a partially cut-out front view.

7 is a plan view of the cover removed.

FIG. 8 is a partially cutaway X-ray cross-sectional view of FIG. 6. FIG.

9 is a central longitudinal cross-sectional view.

Tenth is an enlarged cross-sectional view of the negative electrode connection.

11a and (b) are structural diagrams of the dust collector.

12 is an electrical circuit diagram

13A and 13B are explanatory diagrams of a liquid circulation type.

14 is a configuration diagram showing another embodiment of the liquid discharge pipe.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electrostatic precipitator which collects and removes foreign particulates contained by suspended dispersion in an electrically insulating liquid by applying an electrostatic field.

BACKGROUND ART Conventionally, a method of generating an electric field in an electrically insulating liquid containing fine particles and interposing a dust collector of a dielectric between the electrodes to apply a voltage to strengthen the electric field bias to electrostatically capture the fine particles is known.

However, as a conventional apparatus, an apparatus configured to dispose a wave-like dust collector 10 as shown in FIG. 2 between the counter electrodes 20 has been proposed, but this is caused by severe convection in the liquid due to the generation of an electric field, Particles trapped in the collecting plate are lost by this convection, or because the force greater than the electrostatic adsorption force between the particle and the collecting plate is applied to the particles by this convection, the particles are scattered and suspended without being trapped in the collecting plate, and remain for processing time. In FIG. 3 showing the amount of dust, the amount of dust capturing decreases with time as shown by the curve B. However, the dust capturing rate is small and has a disadvantage in that effective capturing is not possible.

The present inventors have found that by arranging fibrous dust collecting plates such as paper so as to be parallel to the direction of the electric field, the effect of convection can be minimized and the fine particles can be collected very efficiently. That is, by arranging the dust collecting plate 1 in parallel with the direction of the electric field between the counter electrodes 2 as shown in FIG. 1, the amount of remaining dust decreases rapidly in a relatively short time from the start of the treatment as indicated by the curve A of FIG. After that, it gradually decreases, and can rapidly improve the collection efficiency in a short time compared with the conventional apparatus.

In both cases, the spacing between the electrodes 2 and the pitch of the dust collecting plate are the same.

The present invention is based on the above findings, and an object of the present invention is to provide a purification device capable of efficiently purifying a large amount of liquid.

The present invention provides a conductive septic tank body and a septic tank body, each having a liquid pipe having a soil solution hole on its upper surface, with a liquid discharge pipe disposed at a lower portion thereof, and forming a dust settling complex and a cast pipe communicating therewith between the liquid pipe and the bottom surface. And a plurality of dielectric fiber porous dust collectors disposed in parallel with the positive and negative electrode plates disposed to face each other and parallel to the direction of the electric field and the flow direction of the liquid discharged from the liquid conduit between the positive and negative electrode plates. The positive electrode plate is characterized in that it is electrically connected to the septic tank body.

EMBODIMENT OF THE INVENTION Below, this invention is demonstrated based on the Example shown to drawing.

4 shows an example in which the septic tank 10 is installed on the support vehicle 11. A trochoid pump 13 and a flow regulating valve 14 are arranged in the supply pipe 12 of the processing target liquid, and the supply pipe communicates with the lower part of the septic tank 10. The purified liquid flows out from the top of the tank 10 by the liquid discharge pipe 15. In addition, on the support vehicle 11, a power feeding device 17 including a boosting transformer 16 is provided.

The internal structure of the septic tank 10 is shown in FIG. The tank 10 is made of a metal rectangular parallelepiped container, and the positive electrode plate is disposed to face the inner wall face thereof. 20 is a plurality of positive electrode plates, are arranged at equal intervals and connected to each other by the back plate 21, and both side and bottom sides of the back plate 21 are detachable materials by the frame 22 fixed to the inner wall of the tank. Supported. In addition, the support frame 22 is made of a conductor, and the positive electrode plate 20 and the jaw 10 have the same electric potential, and not only the pole plate 20 but also the entire inner wall of the bath has a function as the positive plate. In general, the anode side is electrically grounded.

Numeral 25 is a plurality of negative electrode plates, which are arranged at equal intervals in the same manner as the positive electrode plate, and are supported by a pipe 26.

Thus, the positive electrode plate 20 and the negative electrode plate 25 face each other alternately and in parallel, as shown in FIG. 7, and the intervals are the same. An insulating plate 27 is fixed to the rough wall between the negative electrode plate 25 and the inner wall, and both sides and the lower side of the negative electrode pipe 26 are attached and detached by the frame 28 fixed to both sides and the bottom of the insulating plate 27. It is supported by materials.

The negative electrode plate 25 is electrically insulated from the bath 10 by the insulating plate 27.

A negative DC high voltage is applied to the negative electrode plate 25 from the power supply device 17. The seventh of the connecting means is shown in FIG. 30 is a cylindrical member made of an insulating material, and a screw is formed on the outer circumferential surface thereof, one end of which is closely adhered to the rear surface of the insulating plate 27 for supporting the negative electrode plate, and the other end of the hole is drilled in the rough wall 31. Penetrates) and protrudes outside. Reference numeral 32 is a fixing nut. Reference numeral 33 denotes a socket attached to the tip of the wire 34, 35 denotes a conductor pin sensitized to the socket 33, and a screw 36 is formed on the tip, and an inner surface of the cylinder 30 is formed. It is combined with the female screw formed on the Reference numeral 37 denotes a slide pin, which is in contact with the tip of the conductor pin 35, and the tip penetrates through the insulating plate 27 and is in contact with the back surface of the negative electrode plate 26. 38 is a bushing. Numeral 39 is a nut attached to the tip of the cylinder.

When a voltage is applied to each of the Yin-Yang electrodes, an electric field is formed between the electrode plates and between the outermost negative electrode plate and the inner wall of the tank, the electric field being perpendicular to the electrode plate. Thus, a plurality of dust collectors 40 are arranged at substantially equal intervals so as to be parallel to the direction of the electric field between each electrode plate and between the outermost negative plate and the inner wall.

The dust collecting body 40 is made of a porous plate-like body which is fibrous such as plant fiber, synthetic resin fiber or glass fiber, and has liquid permeability. Although the shape of the dust collector 40 may support many end plates with a predetermined width by a suitable supporting means, as shown in FIG. 11A, one flat plate is continuously refracted in a spherical shape to give a plain shape (蛇 服 狀) or in the form of a continuous box as shown in Figure 11b. The narrower the interval between the dust collectors 40 is, the higher the particulate collection efficiency is, but usually about 10 mm in advance. The dielectric constant of the dust collector is determined by the material or dielectric constant of the fine particles to be captured and the dielectric constant of the liquid.

Each dust collector 40 is supported by a ladder member 43 disposed below the electrode plate. The dust collecting body support member 43 is composed of a shelf 44 made of a plurality of insulating materials and a set of connecting rods 45 supporting it, and each shelf 44 is located almost at the center between each electrode plate and is a current collector. Support the lower side of the. It is supported by the bracket 46 fixed to the inner wall of the both ends of each connecting rod 45. As shown in FIG. The current collector is not limited to the shelf 44. The upper edge of the dust collector may be supported by a suitable member.

The T-shaped liquid-conducting pipe 50 is arrange | positioned below the dust collector support member 43. FIG. The liquid pipe 50 is made of an insulating material, the T-shaped vertical portion 51 communicates from the liquid intake pipe 52 to the supply pipe 12, and the T-shaped horizontal portion 53 is almost the center of the tank 10. It is located on a shipboard, and both ends are supported by the bracket 54 fixed to the inner star. In addition, a plurality of soil liquids 55 are laid on the upper surface of the liquid pipe 53. It is preferable that the liquid jet hole 55 is located substantially at the center between the respective electrode plates so that the liquid discharged from the hole 55 rises between the electrode plates.

A suitable space 59 is provided between the liquid pipe 50 and the bottom plate 58, the bottom plate 58 is inclined to one side, and the drainage pipe 60 is provided in the lowest end part. In this space 59, dust settles and collects. Since the dust settling space is hardly affected by liquid convection movement, the settled dust is not scattered in an emergency, and since the bottom surface 58 is made of a positive electrode plate, the floating of dust is prevented electrostatically. Thus, the settled dust can be efficiently discharged.

On the rough wall located above the upper side of the electrode plate, a discharge port 15 for taking out the liquid after the purification process is provided. Moreover, the cover 64 maintains intimacy and is firmly installed in the ancestor side. Reference numeral 65 denotes a fixture storage box attached to the outer wall of the tank as needed, and 66 is a reinforcement member. Reference numeral 67 denotes a level switch having a float, and detects that the amount of liquid fed into the tank reaches a predetermined level.

Reference numeral 70 denotes a switchboard, in which necessary electrical components such as a power switch or various instruments are disposed. Usually, the positive electrode plate is grounded, and a negative voltage is applied to the negative electrode plate. An example of the power supply device will be described based on the wiring diagram of FIG. 71 is a commercial AC power supply terminal. Reference numeral 72 denotes a power switch, and 73 denotes a power lamp. Denoted at 74 is a motor of the trocoid pump 13, at 75 is a reverse rotation switching switch of the motor 74, at 76 is an electrostatic display, and at 77 is a reversing display. Reference numeral 78 denotes a high-pressure injection switch and 79 a level switch described above. When a predetermined amount of liquid is supplied into the septic tank, the level switch 79 operates to excite the relay 80 to close its make contact 81. Power is supplied to the primary side of the boost transformer 16. Reference numeral 82 is a high pressure lamp. The secondary side of the transformer 16 is connected to the negative electrode plate via the rectifier 83. 84 is an overcurrent relay, which operates when an abnormal current flows between the positive and negative electrodes, closes the make contact 85 to excite the relay 86, and opens the brake contact 87 of the relay 86 to the transformer 16. Stop feeding. Numeral 88 indicates an alarm light. At this time, the relay 89 is not excited and the motor 74 stops. Reference numeral 90 denotes a make contact of the relay 89, and 91 denotes a brake contact of the relay 86.

In the apparatus as described above, when the liquid to be processed is supplied into the tank and a direct current high voltage is applied between the positive electrode plates, foreign matter particles in the liquid are electrostatically captured by the porous dust collector 40. Particles suspended in the vicinity of the dust collector are quickly captured, and the particles that are dropped off are also transported in the vicinity of the dust collector by the convection of the liquid generated by the electric field, and are captured in the entire plane of the dust collector. In this way, foreign matter particles suspended in the liquid are almost completely removed and the liquid is purified.

The applied voltage value is determined by the size of the fine particles or the water content of the liquid, and the smaller the particles, the higher the voltage. In liquid purification, there are two types of circulating liquid and one not circulating liquid. In the case where it is not circulated, the liquid is fed and purified from the supply pipe 12 into the tank, and then, after the pump 13 is rotated reversely, the finished liquid is taken out using the supply pipe 12. In this case, since the space 59 is formed between the pipe pipe 50 and the bottom surface, there is no such thing as taking out the dust collected at the bottom.

In the case of circulating the liquid, the liquid is fed into the tank from the bottom of the tank by the supply pipe 12, and the finished liquid is taken out from the outlet 15 of the tank in the tank.

The flow velocity in the tank of the circulating liquid is about 1 to 10 mm / second. In addition, since the dust collector and the electrode plate are disposed parallel to the flow direction of the liquid, the flow of the liquid is not prevented.

In the circulation type, there is a type depending on the position of the pump. Shown in FIG. 13A is a type in which the pump 13 is arranged on the supply side of the liquid, and it is necessary to attach a strainer to the tip of the supply line to prevent the pump from being damaged by the dust in the liquid. In addition to lowering the flow rate or dust remaining in the tank, the pressure in the septic tank becomes high, which requires consideration of sealing means and strength.

In FIG. 13B, the pump 13 is arranged on the discharge pipe 15 side of the liquid, and there is no need to attach a strainer at the tip of the supply pipe, and no dust is left in the supply tank. Does not become so high, and even if it ignites by discharge, for example, in a septic tank, the sparking to the supply tank 96 has the advantage of being prevented by the pump 13, etc.

As described above, the discharge pipe for taking out the liquid after treatment may be provided on the side wall, but since the air region 97 is formed in the ancestor portion, when the liquid to be treated is highly flammable, it is ignited by discharge and fired. It can not be said that there is no fear of causing it. In this case, as shown in FIG. 14, the liquid discharge pipe 15 may be provided on the upper portion of the lid 64 so as to fill the tank with liquid.

As described above, according to the apparatus of the present invention, a plurality of dielectric fiber porous dust collectors are disposed between the electrode plates in parallel with the direction of the electric field and the flow direction of the liquid discharged from the liquid conduit, respectively. This remarkably improves and the processing time can be shortened so that a large amount of liquid can be efficiently purified. In addition, since the coarse particles are also part of the electrode, the effective treatment volume is large, and a larger amount of liquid can be purified. In addition, since it is sealed, it is safe to handle, and since the dust collector and the electrode plate are detachable materials, there are many advantages such as extremely easy maintenance such as replacement and cleaning.

In addition, the use of outliers is mainly suitable for the clean treatment of fuel oils and mechanical lubricating oils, and is most suitable for the removal of minute metal particles such as aluminum, which cannot be removed by filter, but the treatment of all insulating liquids, for example, solvents. It can be used for high clean processing, and its use is extremely wide, and plays a big role in pollution prevention and resource saving.

Claims (1)

The direction of the electric field between the positive and negative electrode plates disposed in a septic tank main body having a liquid discharge pipe disposed at the upper side and having a dust settling space and a drainage pipe communicating therewith between the liquid pipe and the bottom having a liquid hole at the top thereof. An electro-insulating liquid electrostatic purifier, comprising a plurality of dielectric fiber porous dust collectors disposed in parallel with the flow direction of the liquid discharged from the liquid pipe, and electrically connecting the positive electrode plate to the septic tank body.

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