KR101115433B1 - Dry type mold reactor serially connected to capacitor for high voltage power - Google Patents

Abstract

The present invention is connected to the high-voltage power capacitor in series to suppress the waveform distortion and inrush current of the circuit voltage and to insulate the surface of the winding coil with an insulating material, and then to the high-voltage power capacitor series dry mold reactor molded with epoxy resin. A first support member having a first through hole is formed; A second support member installed below the first support member and formed with a first through hole; A third support member arranged and arranged at a predetermined interval between the first support member and the second support member and having a first through hole formed therein; A first iron core member installed on the first support member and having a second through hole formed therein; A second iron core member installed on the second support member and having a second through hole formed therein; A third iron core member installed on the third support member and having a second through hole formed therein; A dry epoxy mold winding inserted into the third iron core member and having a second through hole formed therein and connected in series with a high-voltage power capacitor to prevent distortion of a waveform of a circuit voltage and to suppress inrush current; A fastening member inserted into the first through hole and the second through hole; It is installed on the second support member is composed of a position adjusting mechanism for adjusting the installation position of the dry epoxy mold winding to improve the insulation, heat resistance and fire safety, characterized in that to facilitate the position adjustment.

High pressure, power, condenser, mold, dry, series, reactor, epoxy resin, iron core

Description

Dry type mold reactor serially connected to capacitor for high voltage power}

The present invention relates to a high-voltage power condenser series dry mold reactor, and more particularly, it is connected to the high-voltage power capacitor in series to suppress the waveform distortion and inrush current of the circuit voltage and insulates the surface of the winding coil with an insulating material and then epoxy It relates to a high-voltage power capacitor series dry mold reactor molded of resin.

The series reactor is inserted in series to the high voltage power capacitor to reduce distortion of the circuit voltage waveform and to suppress the inrush current of the high voltage power capacitor.

Conventional series reactors used to suppress the distortion of the circuit voltage waveform or the inrush current are largely inflow type and consist of a plurality of support frames, an upper iron core member, a lower iron core member, an intermediate iron core member, a winding coil, an enclosure, and an insulating oil.

The winding coil is connected to the high voltage power capacitor used in the power transmission / distribution system in series to prevent distortion of the circuit voltage waveform and to prevent the inrush current from being injected into the high voltage power capacitor. Each of the plurality of support frames is provided with an upper iron core member, a lower iron core member and an intermediate iron core member.

Each of the plurality of support frames is formed with a through hole, and the upper iron core member, the lower iron core member and the middle iron core member which are installed in the support frame are also formed through holes. When fastening the iron core member to the support frame, insert the bolt into the through hole formed in each, and then fasten the nut to the bolt to install the upper iron core member, the lower iron core member or the middle iron core member on the support frame, and assemble the series reactor to fill it with insulating oil. It is loaded inside the case and completed.

Conventional high-pressure condenser series inflow reactor has a safety problem that the fire is enlarged due to insulation oil in case of fire of reactor and peripheral devices, and the winding of the conventional high-density condenser series dry mold reactor for high-voltage power is made of aluminum with high loss rate. There is a problem that miniaturization is difficult due to the generation problem. In addition, the conventional high pressure power condenser series dry mold reactor has a problem that it is difficult to move, install, and attach a dustproof device when installed in a narrow panel as a heavy material.

The present invention has been made to solve the above problems, and is connected in series to a high-voltage power capacitor to suppress the waveform distortion and inrush current of the circuit voltage, and insulates the surface of the winding coil with an insulating material and then mold with epoxy resin (mold) In order to improve insulation, heat resistance, and fire safety, a high voltage power capacitor series dry mold reactor is provided.

Another object of the present invention is to provide a high pressure power condenser series dry mold reactor capable of miniaturizing a dry epoxy mold winding by using a material having a low loss rate of a winding coil.

Still another object of the present invention is to provide a high-voltage power condenser series dry mold reactor having a position adjusting mechanism to improve mobility and to easily install a dustproof device under the high-voltage power condenser series dry mold reactor.

The high-voltage power condenser series dry mold reactor of the present invention includes a first support member having a first through hole formed therein; A second support member installed below the first support member and formed with a first through hole; A third support member arranged and disposed at a predetermined interval between the first support member and the second support member, the first support member having a first through hole formed therein; A first iron core member installed on the first support member and having a second through hole formed therein; A second iron core member installed at the second support member and having a second through hole formed therein; A third iron core member installed at the third support member and having a second through hole formed therein; A dry epoxy mold winding inserted into the third iron member and having a second through hole formed therein and connected in series with a high-voltage power capacitor to prevent distortion of a waveform of a circuit voltage and to suppress inrush current; A fastening member inserted into the first through hole and the second through hole; It is installed on the second support member is composed of a position adjusting mechanism for adjusting the installation position of the dry epoxy mold winding, the fastening member is inserted into the second through hole is inserted into the plastic cylindrical member and the first through hole And coupled to the plastic cylindrical member to fasten the first iron core member, the second iron core member, and the third iron core member to the first support member, the second support member, and the third support member, respectively. It is characterized by consisting of a fixing member.

The high-voltage power capacitor series dry mold reactor of the present invention is connected in series to the high-voltage power capacitor to suppress the waveform distortion and inrush current of the circuit voltage, and insulates the surface of the winding coil with an insulating material and then is made of flame-retardant and self-extinguishing epoxy resin. The mold can improve heat resistance, insulation and fire safety, reduce the generation of heat by minimizing heat generation by using electric copper with low loss rate of winding coil, and improve mobility by equipping position control mechanism. The dustproof device can be easily installed to have an effect of improving durability.

Hereinafter, an embodiment of a high pressure power capacitor series dry mold reactor of the present invention will be described with reference to the accompanying drawings.

As shown in FIGS. 1 and 2, the high-voltage power capacitor series dry mold reactor 10 of the present invention includes a first support member 11, a second support member 12, a third support member 13, and a first iron core. The member 14, the 2nd iron core member 15, the 3rd iron core member 16, the dry epoxy mold winding 17, the fastening member 18, and the position adjustment mechanism 19 are comprised.

The first supporting member 11 is formed by arranging a plurality of first through holes 10a and is installed above the third supporting member 13 in the longitudinal direction. The second supporting member 12 is formed with a plurality of first through holes 10a and is installed below the first supporting member 11. That is, the second support member 12 is installed below the third support member 13 in the longitudinal direction. The third support member 13 is installed and arranged at regular intervals between the first support member 11 and the second support member 12, and a plurality of first through holes 10a are formed.

The first iron core member 14 is inserted into the first support member 11 and a plurality of second through holes 10b are formed. The second iron core member 15 is inserted into the second support member 12 and a plurality of second through holes 10b are formed. The third iron core member 16 is inserted into the third support member 13 and a plurality of second through holes 10b are formed.

The dry epoxy mold winding 17 is inserted into and installed in the third iron core member 16, and the second through hole 10b is formed and connected in series with the high-voltage power capacitor 20 (shown in FIG. 7) to form a waveform of the circuit voltage. Prevents distortion and suppresses inrush current. The fastening member 18 is inserted into the first through hole 10a and the second through hole 10b. The fastening member 18 is composed of a plastic cylindrical member 111 and the fixing member 112.

As shown in FIG. 3, the plastic cylindrical member 111 is inserted into the second through hole 10b and the fixing member 112 is shown in FIGS. 3 to 5. And the plastic cylindrical member 110 is inserted and installed to fasten the first to third iron core members 14, 15 and 16 to the first to third supporting members 11, 12 and 13, respectively. The plastic cylindrical member 111 is made of polyvinyl chloride or polyethylene.

The position adjusting mechanism 19 is installed on the second supporting member 12 to adjust the installation position of the dry epoxy mold winding 17. That is, the position adjusting mechanism 19 is made up of a plurality, it is installed to face each other on the lower side of the second support member 12 to adjust the horizontal position or vertical position of the condenser series dry mold reactor 10 for high voltage power of the present invention. Will be adjusted.

Each configuration of the high-voltage power capacitor series dry mold reactor 10 of the present invention having the above configuration will be described in more detail as follows.

As shown in FIGS. 2 to 4, the first support member 11 and the second support member 12 each have a pair of 'c' shaped frames 11a and 12a and bolt and nut members 11b, 11c and 12b, respectively. 12c). The pair of 'c'-shaped frames 11a and 12a are each provided with a plurality of first through holes 10a, and the surfaces on which the plurality of first through holes 10a are formed to face each other. The first iron core member 14 is arranged between the pair of 'c' shaped frames 11a and 12a such that the second through hole 10b formed in the first iron core member 14 is aligned with the first through hole 10a. Is installed.

The bolt and nut members 11b, 11c, 12b, and 12c are fastened to a pair of 'c' shaped frames 11a to fix the first iron core member 14 or the second iron core member 15. That is, the bolt and nut members 11b, 11c, 12b, and 12c are fixed to the first iron core member 14 or the second iron core member 15 in close contact between the pair of 'c' shaped frames 11a and 12a. Be sure to

The third support member 13 is composed of a pair of plates 13a as shown in FIGS. 2 and 5, and each plate 13a is formed with a plurality of first through holes 10a. The pair of plates 13a are provided to face each other in the longitudinal direction, and a third iron core member 16 is disposed therebetween. When the third iron core member 16 is installed, the pair of plates 13a are installed such that the first through hole 10a is aligned with the second through hole 10b formed in the third iron core member 16.

The first iron core member 14, the second iron core member 15, and the third iron core member 16 each have a plurality of silicon steel plates 14a to prevent eddy currents, as shown in FIGS. 2 and 5, respectively. And 15a and 16a are laminated. For example, the first iron core member 14, the second iron core member 15, and the third iron core member 16 may be formed by sequentially stacking a plurality of silicon steel sheets 14a, 15a, and 16a and then pressing each of them. By preventing eddy currents and having a high permeability, it is possible to reduce losses and prevent secular changes.

In addition, the surfaces of the first iron core member 14, the second iron core member 15, and the third iron core member 16 are subjected to anti-rust treatment to prevent surface corrosion. The first iron core member 14 and the second iron core member 15 are formed in the shape of removing the corner portion, the third iron core member 16 is formed in each wedge shape to prevent the magnetic flux is concentrated to the edge do.

The diameter R1 of the second through hole 10b formed in the first iron core member 14, the second iron core member 15, and the third iron core member 16, respectively, corresponds to the first support member 11 and the second support. It is smaller than the diameter R2 of the 1st through-hole 10a formed in the member 12 and the 3rd support member 13, respectively. The diameter R1 of the second through hole 10b is larger than the diameter R2 of the first through hole 10a in order to install the plastic cylindrical member 111 of the fastening member 18. The plastic cylindrical member 111 is a fastening member 18 to support the first iron core member 14, the second iron core member 15, and the third iron core member 16 with the first support member 11 and the second support, respectively. It is fastened to the member 12 and the 3rd support member 13, respectively.

The dry epoxy mold winding 17 is composed of a winding coil 121, an insulating material 122, an epoxy resin molding member 123, and a support block 124, as shown in FIGS. 2 and 6.

The winding coil 121 is a high-voltage power condenser 20 used in a transmission / distribution system of electric power by forming a first drawing terminal 121a at one end and a second drawing terminal 121b at the other end thereof, as shown in FIG. 7. Connected in series. Since the winding coil 121 uses copper having a low loss rate, heat generation can be reduced, thereby minimizing the dry epoxy mold winding 17 to improve mobility.

The insulating material 122 is installed on the surface of the winding coil 121 to insulate the winding coil 121. That is, by insulating the interlayer of the winding coil 121 wound in a plurality of layers to increase the heat resistance and insulation of the condenser series dry mold reactor 10 for high voltage power of the present invention. The insulating material 122 is made of enamel resin or nomex insulating paper.

The epoxy resin molding member 123 seals the winding coil 121 so that the first drawing terminal 121a and the second drawing terminal 121b of the winding coil 121 are exposed to the outside. The epoxy resin molding member 123 is integrally formed by protruding the terminal lead-out portion 123a in which the first lead terminal 121a and the second lead terminal 121b of the winding coil 121 are installed. The epoxy resin molding member 123 forms an epoxy resin by a casting method in a vacuum state. The epoxy resin molding member 123 may improve fire safety by using a material having flame retardancy and self-extinguishing.

The support block 124 is formed above and below the epoxy resin molding member 122 to support the epoxy resin molding member 123 to the first support member 11 and the second support member 12.

As such, the winding coil 121 is insulated with the insulating material 122 and then molded into the epoxy resin molding member 123 to sufficiently withstand shrinkage and expansion due to temperature change of the winding coil 121, and cracks. By minimizing the occurrence of cracks to prevent moisture penetration due to cracks, it is possible to improve insulation, heat resistance and fire safety.

The winding coil 121 of the mold winding 17 may be made of electrophoresis, thereby miniaturizing and improving mobility, and a position adjusting mechanism 19 is installed below the second support member 12 to further improve the mobility. .

Position adjusting mechanism 19 is installed to face each other on the lower side of the second support member 12 as shown in Figures 2 and 5, each positioning mechanism 19 is a positioning frame (19a), a rotating member ( 19b) and screw jack 19c.

The position adjusting frame 19a is installed at the second supporting member 12, and nut members 131 are provided at both ends thereof. Rotating member (19b) is made of a plurality, each is installed on the positioning frame (19a) to face each other to move the positioning frame (19a). That is, the rotating member 19b is rotated in the pushing or pulling direction when the operator pushes or pulls the high pressure power condenser series dry mold reactor 10 to move the condenser series dry mold reactor 10 for power.

The rotating member 19b is composed of a fixed shaft 132, inner ring 133, outer ring 134, a plurality of bearings 135 and the moving wheel (136).

The fixed shaft 132 is installed to be fixed to the position adjustment frame 19a, the inner ring 133 is installed to be fixed to the fixed shaft 132. The outer ring 134 is installed to rotate on the inner ring 133, and the plurality of bearings 135 allow rolling motion of the outer ring 134 installed between the inner ring 133 and the outer ring 134. Movement 횔 136 is installed in the outer ring 134 is rotated in conjunction with the rotation of the outer ring 134, the urethane material is used to absorb the shock is used to move the shock when moving the condenser series dry mold reactor 10 for high voltage To absorb.

The screw jack 19c is fastened to the nut member 133 of the positioning frame 19a so that the vertical height of the positioning frame 19a is adjusted. That is, when the screw jack 19c is rotated, the screw jack 19c is moved up and down in the vertical direction so that the condenser series dry mold reactor 10 for high voltage power can be easily adjusted. Thus, by adjusting the height of the high pressure power condenser series dry mold reactor 10 by the screw jack (19c) it is possible to install more easily when the anti-vibration pad (not shown).

Referring to the operation of the high-voltage power capacitor series dry mold reactor 10 of the present invention having the above configuration is as follows.

The high-voltage power condenser series dry mold reactor 10 of the present invention is connected in series to the high-voltage power condenser 20, as shown in FIG. 7, and consists of a plurality of dry epoxy mold windings 17, each of which transmits power. When the circuit voltage of the / distribution system is applied to prevent the distortion and inrush current of the voltage waveform of the high-voltage power capacitor 20. The high pressure power capacitor series dry mold reactor 10 of the present invention may generate vibration during operation.

When the vibration is generated, the high-voltage power capacitor series dry mold reactor 10 of the present invention has a plastic cylindrical member in a plurality of second through holes 10b formed in the first to third iron core members 14, 15, and 16. After the 111 is inserted and installed, the first and third supporting members 11 and 12. 13 may be fastened with bolts and nuts 112a and 112b to suppress vibration of the third iron core member 16, thereby reducing noise. .

In addition, by installing the position adjusting mechanism 19 below the second support member 12 to adjust the horizontal or vertical position of the condenser series dry mold reactor 10 for high voltage power without a crane or a lift (not shown). It is possible to easily install a dustproof pad (not shown) that can absorb the vibration in the lower side of the high-voltage power capacitor series dry mold reactor 10 to reduce the generation of noise.

The high voltage power condenser series dry mold reactor of the present invention can be applied to a field for preventing distortion or inrush current of a circuit voltage waveform of a high voltage power capacitor used in a power transmission / distribution system.

1 is an assembled perspective view of a high pressure power condenser series dry mold reactor of the present invention;

FIG. 2 is an exploded perspective view of the condenser series dry mold reactor for high voltage power shown in FIG. 1;

3 is an enlarged perspective view of the first iron core member shown in FIG. 2;

4 is an enlarged perspective view of the second core member shown in FIG. 2;

5 is an enlarged perspective view of the third iron core member shown in FIG. 2;

6 is an enlarged cross-sectional view of the epoxy resin molding member shown in FIG. 2;

FIG. 7 is an equivalent circuit diagram of the condenser series type mold reactor for high voltage power shown in FIG. 1. FIG.

* Brief description of symbols for the main parts of the drawings *

10: High Voltage Power Condenser Series Dry Mold Reactor

10a: first through hole 10b: second through hole

11: first supporting member 12: second supporting member

13: third supporting member 14: first iron core member

15: second iron core member 16: third iron core member

17: dry epoxy mold winding 18: fastening member

19: position adjusting mechanism 20: high voltage power condenser

Claims (11)

A first support member having a first through hole formed therein; A second support member installed below the first support member and having a first through hole formed therein; A third support member arranged and disposed at regular intervals between the first support member and the second support member, the first support member having a first through hole formed therein; A first iron core member installed on the first support member and having a second through hole formed therein; A second iron core member installed on the second support member and having a second through hole formed therein; A third iron core member installed at the third support member and having a second through hole formed therein; A dry epoxy mold winding inserted into the third iron member and having a second through hole formed therein and connected in series with a high-voltage power capacitor to prevent distortion of a waveform of a circuit voltage and to suppress inrush current; A fastening member inserted into the first through hole and the second through hole; Is installed on the second support member is composed of a position adjusting mechanism for adjusting the installation position of the dry epoxy mold winding, The fastening member may include a plastic cylindrical member inserted into the second through hole, and inserted into the first through hole and the plastic cylindrical member to respectively connect the first core member to the third iron core member to the first support member. It is made of a fixing member for fastening by fastening to each of the third support member, The position adjusting mechanism is installed on the lower side of the second support member and a position adjusting frame each having a nut member at both ends, and a plurality of rotating members installed to face each other on the position adjusting frame to move the position adjusting frame; Capacitor series dry mold reactor for high-voltage power, characterized in that the screw jack is fastened to the nut member of the positioning frame to adjust the vertical height of the positioning frame. The method of claim 1, wherein the first support member and the second support member comprises a pair of 'c'-shaped frame each of which a plurality of first through holes are formed; Capacitor series dry mold reactor for high voltage power, characterized in that consisting of a bolt and nut member which is fastened to the pair of '' 'frame is fixed to the first iron core member or the second iron core member. The condenser series dry mold reactor of claim 1, wherein the third support member comprises a pair of plates, and each of the pair of plates has a plurality of first through holes. The method of claim 1, wherein the first iron core member, the second iron core member and the third iron core member are each formed by stacking a plurality of silicon steel sheets to prevent eddy current phenomenon. Condenser series dry mold reactor. The condenser series dry mold reactor of claim 1, wherein each of the third iron core members is formed in a wedge shape. The diameter of the second through hole formed in the first iron core member, the second iron core member and the third iron core member, respectively, the diameter of the first support member, the second support member and the third support member. A condenser series dry mold reactor for high voltage power, characterized in that smaller than the diameter of each formed first through hole. The coil of claim 1, wherein the dry epoxy mold winding comprises: a winding coil having a first drawing terminal formed at one end thereof and a second drawing terminal formed at the other end thereof; An insulating material installed on a surface of the winding coil to insulate the winding coil; An epoxy resin molding member sealing the winding coil such that the first drawing terminal and the second drawing terminal of the winding coil are exposed to the outside; It is formed on the upper side and the lower side of the epoxy resin molding member is composed of a support block for supporting the epoxy resin molding member to the first support member and the second support member, The winding coil is used for copper, and the epoxy resin molding member is a series of high-voltage power capacitors characterized in that the terminal lead-out portion protruding from the first drawing terminal and the second drawing terminal of the winding coil is formed integrally. Dry mold reactor. 8. The high pressure power capacitor series dry mold reactor of claim 7, wherein the insulating material is enamel resin or nomex insulating paper. The condenser series dry mold reactor of claim 1, wherein the plastic cylindrical member of the fastening member is made of polyvinylchloride or polyethylene. delete The rotating member of claim 1, further comprising: a fixed shaft installed to be fixed to the position adjusting frame; An inner ring installed to be fixed to the fixed shaft; An outer ring installed to rotate on the inner ring; A plurality of bearings installed between the inner ring and the outer ring to allow rolling motion of the outer ring; It is installed on the outer ring and consists of a moving wheel (rotating) in conjunction with the rotation of the outer ring, The moving wheel is a high pressure power capacitor series dry mold reactor, characterized in that the urethane material for absorbing the shock is used.

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