KR101940999B1 - Insulation oil filtering apparatus of power transformer - Google Patents

Abstract

The present invention relates to an insulation oil filtering apparatus of a power transformer. More specifically, the present invention relates to an insulation oil filtering apparatus of a power transformer which improves the structure of an insulation oil filter to automatically circulate an insulation oil used in the power transformer and filter the same to remove impurities, and blocks air bubble formation and moisture infiltration in re-supplying the filtered oil to reduce a processing time while enhancing filtering process efficiency, to prevent an accident by preventing a dielectric breakdown phenomenon in advance, and to improve management convenience in maintenance by facilitating replacement of the filter.

Description

TECHNICAL FIELD [0001] The present invention relates to an insulation oil filtering apparatus for a power transformer,

The present invention relates to an insulating oil filtering apparatus for a power transformer, and more particularly, to an insulating oil filter apparatus for filtering impurities by automatically circulating insulating oil used in a power transformer, By preventing the generation and inflow of water, it is possible to shorten the processing time while improving the efficiency of filtering the insulating oil, prevent the safety breakdown by preventing the destruction of insulation, and furthermore, it is possible to perform the replacement of the filter easily and quickly. To an apparatus for filtering an insulating oil of a power transformer.

Generally, a power transformer (MTR) used in a substation field is a device for increasing or decreasing the voltage of an alternating current by using electromagnetic induction in an electric facility, for example, a primary winding connected to a power transmission line and connected to a load And the secondary winding performs the function of changing a certain voltage to a higher or lower voltage while keeping the power as it is.

The power transformer installed to increase or decrease the voltage of the transmission and distribution line is an important component of the power system, and plays a large role in stabilizing the power supply.

Such a power transformer is filled with insulating oil to prevent the dielectric strength of the winding in the transformer from being lowered due to moisture or dust, and to heat the heat generated by the winding by convection or radiation of oil.

Especially, the transformer generates high pressure and high heat during operation. It keeps the proper load ratio at all times considering the stable operating environment and keeps the insulation oil in the transformer in the optimum state by filtering and replacing the insulating oil at the proper time to maximize the cooling effect through the insulating oil If a large amount of impurities is mixed in insulating oil due to long-term use of transformer, it will cause the circulation of insulation oil to be obstructed and the radiator will not be able to heat up sufficiently, and transformer can not be operated at rated capacity. do.

In addition, the insulating oil inside the transformer has a great influence on the insulation and heat dissipation, but impurities are generated in the insulating oil due to long-term use, which hinders the effect of the insulating oil.

These impurities are examples of external influx, but they are naturally produced inside the transformer by virtue of the carbon constituent of the core.

Therefore, the transformer is provided with an insulating oil filter body which is an apparatus for filtering the insulating oil, and many prior art related thereto are disclosed.

For example, the transformer is provided with a discharge chamber 12 at one side of the upper portion of the transformer 10 as shown in FIG. 1, and a suction pipe 14 and a discharge pipe 16 are connected to the discharge chamber 12, Is connected to the insulating oil filter body (20) and is configured to filter while circulating the oil inside the transformer (10), that is, the insulating oil.

The insulating oil filter 20 includes a pump motor 22 for oil circulation and a filter 24 for oil filtration and is installed outside the transformer 10 to periodically replace the filter 24 .

The pump motor 22 is electrically connected to the control box 30 and is activated when power is supplied thereto.

A converter 40 is installed at the upper part of the transformer 10 so that when the transformer 10 is overloaded and the temperature rises and the oil expands and the load is reduced The temperature is lowered to shrink the oil, thereby preventing contact with the air, thereby preventing deterioration of the oil, that is, the insulating oil.

The oil reservoir 40 is connected to the oil compartment 12 through a pipe and a relay (Pitot Relay: 96T) 42 is installed on the pipe. When the transformer 10 is rapidly expanded, And to prevent the safety accident by sounding an alarm.

In this case, the insulating oil should be periodically replaced when used for a long period of time. However, due to various reasons, it is difficult to replace the insulating oil within a predetermined period, which has shortened the life span of the transformer and increased the incidence of accidents.

In order to solve this problem, there have been proposed techniques relating to filtration of insulating oil of transformers. However, since the supply efficiency is reduced due to the bubble phenomenon occurring after re-feeding after filtration, the working time due to filtration and re-supply is excessively consumed, , A disadvantage that cost wastage is increased is derived.

In addition, the disclosed filters are of a fiber type such as a mesh type or nonwoven fabric, and have a good effect of filtering out impurities, but they deteriorate the flowability of the dielectric oil, so that the filtering time is long and inefficient. It is difficult to block the influx of moisture. In some cases, even though insulation oil is filtered at the maximum, insulation breakdown may cause equipment accidents.

Korean Utility Registration No. 20-0324878 (Aug. 18, 2003), insulating oil filtration system of transformer Korean Patent Registration No. 10-1037473 (May 20, 2011), an oil refining system Korean Patent Registration No. 10-1562532 (Oct. 16, 2015), a device for preventing malfunction of a relay when driving a dielectric filter of a power transformer

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems in the prior art, and it is an object of the present invention to improve the structure of an insulating oil filter body that filters impurities by automatically circulating insulating oil used in a power transformer, In order to prevent bubbles and water inflow during re-supply, it is necessary to increase the efficiency of filtering the insulation oil and to shorten the treatment time and prevent the safety breakdown by preventing the breakdown phenomenon beforehand. The present invention has been made to solve the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide an insulation oil filtering apparatus for a power transformer.

The present invention provides, as means for attaining the above object, a filter device comprising a filter part for filtering insulating oil, a buffer for circulating and supplying only the insulating oil without bubbles by floating the bubbles generated by storing the filtered insulating oil to a certain level, An apparatus for filtering an insulating oil of a power transformer, comprising:

The filter unit 200 includes a cylindrical filter case 210 having an open upper part and a plurality of filter balls 220 filled in the filter case 210. The filter unit 200 is seated on the filter case 210, And a cover body (230)

A tubular fuel cell body 2110 having a predetermined height is fixed at the center of the bottom surface of the filter case 210 and a lower end of the fuel cell case 210 is formed at the lower end of the fuel cell channel 2112 formed in the fuel cell body 2110. A connecting pipe 400 is connected through a coupler 2114 which is pierced through a bottom surface of the filter case 210. A fuel supply passage 2116 forms a tunnel in a circumferential direction inside the upper end of the filter case 210, An oil supply socket 2118 is provided at one point of the filter case 2116 to connect the end of the suction pipe 14 passing through the suction pump 120 and the oil supply passage 2116 is provided with a wall surface of the filter case 210 At least two feed ports 2120 are formed in the circumferential direction of the filter case 210 so as to communicate with the lower side of the filter case 210. At the inner wall surface of the filter case 210, Lt; RTI ID = 0.0 > 2110 < / RTI > A plurality of through holes 2126 are formed in the filter ball pressing plate 2124 and a plurality of through holes 2126 are formed in the bottom plate 2110, A rotating truncated cone 2128 is fitted;

The buffer unit 300 includes a cylindrical buffer housing 310 having an open upper portion and a buffer cover 312 for sealing the open upper portion of the buffer housing 310 and passing through the center to pipe the connection pipe 400 And a bubble removing valve 320 installed on one side of the buffer cover 312,

The bubble eliminating valve 320 includes a valve body 3210 having an H-shaped cross section and formed with an exhaust hole HL which is fixed to the buffer cover 312 and communicates with the inside of the buffer cover 312, A spool fixture 3212 made of synthetic resin having a hole DR and screwed to the upper portion of the valve body 3210 and a spool fixing member 3212 engaged with a hemispherical sealing protrusion DT protruding from the upper surface of the valve body 3210, A spool fixing rod 3216 penetrating the center of the spool fixing body 3212 and the valve spool 3214 and screwed to the spool fixing body 3212; (Not shown in the drawings) that is screwed to the end of the spool fixing rod 3216 so as not to be separated from the spool fixing rod 3214; And a return spring 3220 fixed at the other end to the spool fixture 3212 And an insulating oil filtering device for a power transformer.

According to the present invention, it is possible to improve the structure of the insulating oil filter body that filters impurities by automatically circulating the insulating oil used in the power transformer, thereby preventing the occurrence of bubbles and inflow of water during the re- It is possible not only to shorten the processing time but also to prevent the safety breakdown by preventing the breakdown phenomenon beforehand, and furthermore, it is possible to perform the replacement of the filter easily and quickly, thereby improving the maintenance convenience due to the maintenance.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a schematic diagram illustrating a driving relationship of an insulating oil filter of a power transformer according to the prior art; FIG.
2 is a schematic diagram showing an insulation oil filter device of a power transformer according to the present invention.
FIG. 3 is an exemplary cross-sectional view of the filter portion taken in FIG. 2; FIG.
FIG. 4 is an exemplary cross-sectional view of the buffer section taken in FIG. 2; FIG.
Fig. 5 is an exemplary view of a bubble removing valve installed in the buffer unit of Fig. 4;

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

Before describing the present invention, the following specific structural or functional descriptions are merely illustrative for the purpose of describing an embodiment according to the concept of the present invention, and embodiments according to the concept of the present invention may be embodied in various forms, And should not be construed as limited to the embodiments described herein.

In addition, since the embodiments according to the concept of the present invention can make various changes and have various forms, specific embodiments are illustrated in the drawings and described in detail herein. However, it should be understood that the embodiments according to the concept of the present invention are not intended to limit the present invention to specific modes of operation, but include all modifications, equivalents and alternatives falling within the spirit and scope of the present invention.

2, the apparatus for filtering an insulating oil of a power transformer according to the present invention includes a housing 110, a filter unit 200 built in the housing 110 to filter insulating oil, A buffer unit 300 connected to the connection pipe 400 for storing the filtered insulating oil up to a predetermined level and floating the generated bubbles and circulating and supplying only the insulating oil without bubbles, A suction pump 120 installed on a suction pipe 14 for sucking the insulating oil from the suction pipe 120 and supplying the oil to the filter unit 200, a suction opening / closing valve 122 provided on the suction front end of the suction pump 120, A discharge pump 130 installed on a discharge pipe 16 connecting the discharge end of the discharge pump 200 and the oil compartment 12, a discharge opening / closing valve 132 provided on the discharge end of the discharge pump 130, A connection pipe opening / closing valve 410 provided in the suction pipe 400, a suction pipe connecting the suction pump 120 and the suction opening / closing valve 122, And a control box 30 for controlling the driving of the discharge pump 130, the discharge opening / closing valve 132 and the connection pipe opening / closing valve 410.

At this time, the housing 110 is provided with a door (not shown) at one side thereof so that the operator can open the door and enter the inside of the door to be maintenance-serviceable.

In addition, the filter unit 200 is filled with a spherical filter ball, so that the filtering speed of the insulating oil can be increased by using a void filter instead of a conventional woven or nonwoven film filter, and a moisture absorption function And can be implemented through a filter ball, thereby completely preventing water from penetrating into the transformer 10, thereby preventing an insulation breakdown phenomenon.

Particularly, as described later, the filter unit 200 is constructed so as to be replaceable with the filter ball in a state of being filled with the filter balls, so that the convenience of the periodic replacement operation is secured.

Here, the filter balls are required to be capable of absorbing moisture due to their hygroscopic properties, and also have a water repellent property so that the filtering effect can be enhanced by suppressing the adsorption or fixing of the insulating oil and flowing naturally, It should be high.

For this, in the present invention, the filter balls are prepared by mixing 40 wt% of silica gel, 2.5 wt% of propylene dicarboxylic acid, 15 wt% of hydrogen silsesquioxane resin, 1.5 wt% of a gypsum powder having a particle size of 0.02 mm, , 1.5 wt% of triglyceride, 2.0 wt% of aluminum hydroxide, 1.5 wt% of diaryl phthalate, 1.5 wt% of polyethylene glycol phenyl ether, and the remaining SEP (Polystyrene-b-polyethylene).

At this time, the silica gel maintains the dehumidifying function, and the propylene dicarboxylic acid is added as a reactive monomer in order to maintain the strong bonding force between the filter ball structures by imparting negatively charged functional groups to the inside and the surface of the polymer, The oxazine resin is a polymer composed of trifunctional siloxane units whose main skeleton is substituted with a hydroxyl group, a triorganosiloxy group, or a dimethylhydrogensiloxy group at the terminal in terms of molecular structure, While retaining the oil repellency property while manifesting the properties.

In addition, the Guiyang stone powder has a three-dimensional network structure, which contributes to the formation of voids in the filter balls, thereby enhancing moisture absorption and enhancing the filtering effect as a pore membrane filter. Triglyceride is a coating agent mainly composed of ricinoleic acid It is added to enhance the durability of the filter balls by increasing the erosion resistance.

Aluminum hydroxide is added as an amphiphilic hydrate of aluminum to prevent hydrophobization and to induce hydrophilization to enhance hygroscopicity. Diaryl phthalate is added to improve the binding, formability and toughness between the compositions, and polyethylene glycol phenyl The ether is added to prevent aggregation of particles and ensure uniform dispersion.

And, SEP (Polystyrene-b-polyethylene) is a thermoplastic elastomer, which becomes a base resin added to improve moldability while preventing shrinkage.

In addition, the suction opening / closing valve 122, the discharge opening / closing valve 132, and the connection pipe opening / closing valve 410 are both constituted by solenoid valves and are directly opened and closed through the control box 30, .

Hereinafter, the configuration of the filter unit 200 and the buffer unit 300 will be described in detail.

3, the filter unit 200 according to the present invention includes a cylindrical filter case 210 having an open top, a plurality of filter balls 220 filled in the filter case 210, And a lid 230 which is seated on the upper portion of the case 210 and hermetically closed.

At this time, a cylinder-shaped endoscope 2110 having a predetermined height is fixed at the center of the bottom surface of the filter case 210, and the filter case 210 The connecting pipe 400 is connected through a coupler 2114 which is piped through the bottom surface of the connecting pipe.

An oil supply passage 2116 forms a tunnel in a circumferential direction within the upper end of the filter case 210 and a refueling socket 2118 is installed at one point of the oil supply passage 2116, And an oil supply port 2120 is formed in the oil supply passage 2116 so as to be lowered along the wall surface of the filter case 210 to communicate with the lower side of the filter case 210 At least two or more filters are formed in the circumferential direction of the filter case 210.

Accordingly, the suction pump 120 can supply the insulated oil sucked in the oil compartment 12 into the filter case 210.

In addition, a seating surface 2122 protrudes from an inner wall surface of the filter case 210 at a position corresponding to the height of the upper end of the storage tube 2110, and a filter ball pressing plate 2124 is attached to the seating surface 2122 Lt; / RTI >

At this time, the filter ball presser plate 2124 has a plurality of through holes 2126 formed therein, so that when the discharged insulating oil reaches a predetermined level, the filter ball presser plate 2124 can pass through the through hole 2126 and move to the upper portion of the filter ball presser plate 2124 , The filter ball presser plate 2124 serves as a weight plate having a weight so that the filter ball 220 is positively positioned without being detached and separated.

Here, before the filter ball presser plate 2124 is seated, a rotary truncated cone 2128 is fitted to the oil supply tube body 2110.

The rotating truncated cone 2128 is a member for rotationally moving the filter ball 220 that is filled on the outer circumference of the rotating truncated cone 2128. The rotating truncated cone 2128 is configured to rotate around the rotating shaft 2110, So that it can rotate slowly. Of course, it is not necessary to specify as a design to rotate at a certain speed, but it can be adjusted to the situation in the field.

Particularly, a cylindrical spline assembly 2132 is formed at the upper end of the rotary truncated cone 2128 and extends vertically by a predetermined length and has an inner surface formed with a spline in the longitudinal direction. And an oil drain guide hole 2134 is formed through the hole.

Therefore, since the insulating oil filled from the lower end of the filter case 210 through the oil filler port 2120 goes up while passing through the plurality of filter balls 220, the filter ball 220 functions as a kind of air gap filter, The insulating oil having the water level increased by passing through the air hole 2126 of the filter ball presser plate 2124 is guided to the coupler 2114 through the air outlet passage 2112 in the air outlet tube 2110 through the air outlet guide hole 2134, And is discharged to the connection pipe 400 through the connecting pipe 400.

A hole is formed in the center of the filter ball presser plate 2124 to be fitted on the spline assembly 2132 of the rotary truncated cone 2128. The outer surface of the rotary truncated cone 2128 is symmetrical A pair of stirring protrusions 2130 are protruded so as to smoothly mix the filter balls 220 by rotating the filter balls 220, thereby enhancing the filtering effect as a pore membrane filter.

A drain pipe (DRP) for discharging the filtered residue is piped to one side of the bottom surface of the filter case 210. A drain valve (DRV) is installed on the drain pipe (DRP) .

A rotary motor 2310 is fixed to a center of a lower end surface of the cover 230 and a rotary drive body 2314 is fixed to a motor shaft 2312 of the rotary motor 2310. The rotary drive body 2314 are inserted into the spline assembly 2132 at a predetermined depth naturally when the lid 230 is engaged, and are splined to the circumferential surface so as to be splined to each other.

In this case, it is preferable to use a battery in that the lid 230 is separated from the power supply of the rotor of the rotation motor 2310, and in some cases, a commercial power supply may be used by using a flexible lead wire.

The filter ball 220 may be replaced periodically, and the filter 230 may be separated from the filter bowl 220 by removing the filter 230 and the filter ball pressing plate 2124 in this order. Replacement can be used to fill.

However, in the present invention, since the filter ball 220 is rotated, the service life of the filter ball 220 is longer than that of the conventional art, and the replacement period can be extended.

In order to maintain the heat resistance, water resistance and durability of the filter case 210 according to the present invention, 10.5 wt% of propylene dicarboxylic acid, 5.5 wt% of potassium silicate, 2.0 wt% of 3-chloropropylene oxide, 3.5 wt% of ceteth, 7.0 wt% of talc, 2.0 wt% of triglyceride, 5.0 wt% of polyethylene glycol phenyl ether, 1.5 wt% of buthylated hydroxy toluene and remaining polycarbonate resin.

At this time, the propylene dicarboxylic acid is added as a reactive monomer in order to maintain a strong bonding force by imparting negatively chargeable functional groups to the inside and the surface of the polymer.

In addition, the potassium silicate is added as an inorganic substance to contribute not only to the heat resistance but also to the dew condensation and consequently the inhibition of fungal growth.

And, the 3-chloropropylene oxide is added as a stabilizer of a reactive emulsion, to enhance the adhesion stability between the compositions.

In addition, the coal tar is added for crack suppression and waterproofing performance enhancement.

Furthermore, the above-mentioned cetostose is an extract extracted from palm oil, which is added to control emulsion stabilization as well as viscosity and prevent settling of the composition.

In addition, the nepheline ((Na ₂ O and Al ₂ O ₃ and 2SiO ₂₎ (K ₂ O and Al ₂ O ₃ and 2SiO ₂₎ is added to enhance the strength of the filter case 210, that the two compositions mix do.

The above-mentioned triglycerides are added as a coating agent comprising ricinoleic acid as a main component in order to increase the surface smoothness of each of the outer and inner surfaces, thereby enhancing the antifouling property and increasing the erosion resistance.

In addition, the polyethylene glycol phenyl ether is added to prevent aggregation of particles and ensure uniform dispersion so that waterproof components are evenly distributed.

In addition, the BHT (Butylated Hydroxy Toluene) is added to prevent deterioration by suppressing natural oxidation or aging by ultraviolet rays, heat or air.

The polycarbonate resin is a base resin which strengthens high strength and heat resistance and ensures strong toughness so that it is not easily broken or broken.

Meanwhile, the buffer unit 300 as shown in FIG. 4 is a kind of tank in which the filtered insulating oil is collected through the connection pipe 400. When a predetermined amount is filled and buffered, the bubbles generated inside are floated, It is a means for supplying only the insulating oil.

To this end, the buffer unit 300 includes a buffer housing 310.

The upper portion of the buffer housing 310 is cylindrical and the upper portion of the buffer housing 310 is closed by the buffer cover 312 and the connection pipe 400 is pierced through the center of the buffer cover 312.

Of course, since the buffer cover 312 is provided with the buffer socket 314 and the lower end of the connection pipe 400 is connected to the buffer socket 314, it is possible to disassemble it if necessary.

In addition, a drain 316 for discharging the oil-retained oil residues collected for cleaning is provided at the bottom of the buffer housing 310. The drain 316 is openable and closable.

In addition, a discharge pipe 16 is connected to a discharge pump 130 at a portion of the periphery of the buffer housing 310 at a predetermined height from the bottom.

Since the portion to which the discharge pipe 16 is connected is located at a portion of the buffer housing 310 that is spaced apart from the bottom surface of the buffer housing 310 by a predetermined height, the insulating oil residue remains on the bottom surface without being supplied again, Do not.

In addition, a bubble removing valve 320 may be further provided at one side of the buffer cover 312.

The bubble eliminating valve 320 is opened automatically when the internal pressure of the buffer housing 310 rises above a predetermined level to relieve the internal pressure to securely maintain the buffer housing 310.

At this time, the internal pressure of the buffer housing 310 is generated for various reasons such as oil vapor generated from the insulating oil, pneumatic pressure caused by bursting of air bubbles, and the like.

5, the bubble eliminating valve 320 includes a valve body 3210 having an H-shaped cross section and formed with an exhaust hole HL which is fixed to the buffer cover 312 and communicates with the inside of the buffer cover 312, A spool fixing body 3212 made of a synthetic resin having a flow space SP and a discharge hole DR and screwed to the upper portion of the valve body 3210 and a hemispherical sealing ring 3210 protruding from the upper surface of the valve body 3210, A disk-shaped valve spool 3214 which seals the protrusion DT by engaging with the projection DT, a spool fixing rod 3214 passing through the center of the spool fixing body 3212 and the valve spool 3214 and screwed to the spool fixing body 3212 And a valve seat 3216 which is fixed to the end of the spool fixing rod 3216 such that the valve spool 3214 is not separated from the valve spool 3216. When the valve spool 3216 is fitted to the spool fixing rod 3216, (3214) and the other end is fixed to the spool fixture (3212) It is configured to include a spring 3220.

Therefore, when there is no internal pressure fluctuation, the valve spool 3214 closes the exhaust hole HL by the elastic force of the return spring 3220, and when the internal pressure fluctuates, the return spring 3220 is compressed by the pressure- (3214) rises and the exhaust hole (HL) is opened to enable bubble removal by exhaust.

Of course, in the opposite case, the valve spool 3214 closes the exhaust hole HL, which is due to the elastic force of the return spring 3220. [

200: filter unit 210: filter case
220: Filter Ball 230: Cap
300: buffer unit 400: connector

Claims (1)

And a buffer unit (300) for circulating and supplying only the insulating oil without bubbles by floating the bubbles generated by storing the filtered insulating oil to a predetermined level, and filtering the insulating oil of the power transformer An apparatus comprising:
The filter unit 200 includes a cylindrical filter case 210 having an open upper part and a plurality of filter balls 220 filled in the filter case 210. The filter unit 200 is seated on the filter case 210, And a cover body (230)
A tubular fuel cell body 2110 having a predetermined height is fixed at the center of the bottom surface of the filter case 210 and a lower end of the fuel cell case 210 is formed at the lower end of the fuel cell channel 2112 formed in the fuel cell body 2110. A connecting pipe 400 is connected through a coupler 2114 which is pierced through a bottom surface of the filter case 210. A fuel supply passage 2116 forms a tunnel in a circumferential direction inside the upper end of the filter case 210, An oil supply socket 2118 is provided at one point of the filter case 2116 to connect the end of the suction pipe 14 passing through the suction pump 120 and the oil supply passage 2116 is provided with a wall surface of the filter case 210 At least two feed ports 2120 are formed in the circumferential direction of the filter case 210 so as to communicate with the lower side of the filter case 210. At the inner wall surface of the filter case 210, Lt; RTI ID = 0.0 > 2110 < / RTI > A plurality of through holes 2126 are formed in the filter ball pressing plate 2124 and a plurality of through holes 2126 are formed in the bottom plate 2110, A rotating truncated cone 2128 is fitted;
The buffer unit 300 includes a cylindrical buffer housing 310 having an open upper portion and a buffer cover 312 for sealing the open upper portion of the buffer housing 310 and passing through the center to pipe the connection pipe 400 And a bubble removing valve 320 installed on one side of the buffer cover 312,
The bubble eliminating valve 320 includes a valve body 3210 having an H-shaped cross section and formed with an exhaust hole HL which is fixed to the buffer cover 312 and communicates with the inside of the buffer cover 312, A spool fixture 3212 made of synthetic resin having a hole DR and screwed to the upper portion of the valve body 3210 and a spool fixing member 3212 engaged with a hemispherical sealing protrusion DT protruding from the upper surface of the valve body 3210, A spool fixing rod 3216 penetrating the center of the spool fixing body 3212 and the valve spool 3214 and screwed to the spool fixing body 3212; (Not shown in the drawings) that is screwed to the end of the spool fixing rod 3216 so as not to be separated from the spool fixing rod 3214; And a return spring 3220 fixed at the other end to the spool fixture 3212 Wherein the transformer is a transformer.

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