KR20130063725A - Insulated housing of load break switch and circuit breaker - Google Patents

Abstract

PURPOSE: A complex insulating housing of a prefabricated type for a load break switch or a circuit breaker is provided to solve crack problems generated from a difference in a coefficient of thermal expansion between an epoxy housing and a vacuum valve and from a problem due to a molding failure of an existed epoxy housing by forming an insulation part by injecting an insulating oil into a gap between the epoxy housing and the vacuum valve. CONSTITUTION: A complex insulating housing of a prefabricated type for a load break switch/a circuit breaker comprises to form in order to assemble a vacuum valve(200) in an epoxy housing(100) in which a secondary side electrode(120) and a primary side electrode(130) are molded into one body without a separate molding process or a surface process. An insulation part(240) is formed by filling an insulating oil in a separate space between the vacuum valve and the epoxy housing.

Description

Prefabricated composite insulated housing for switchgear / breaker {Insulated Housing of Load break Switch and Circuit Breaker}

The present invention relates to an insulating housing used for switchgear and breaker of the distribution line system, and more particularly, two types of insulating oil is introduced into the gap between the insulating housing and the vacuum valve after assembling the epoxy housing. A prefabricated composite insulating housing for a switch / breaker using an insulating medium.

From the current SF6 gas insulated switchgear / breaker in which the market trend of domestic power equipment is insulated using SF6 gas from the early stage, the polymer (epoxy) insulated load breaker / breaker recently insulated using epoxy as SF6 gas is known as environmental pollutant. It is changing rapidly.

A polymer (epoxy) insulation housing is used to insulate with epoxy by inserting a breaker (vacuum valve) basically in such a switch or a breaker.

By the way, in recent years, accidents caused by cracks in epoxy housing are frequently occurring in solid insulated switchgear / breaker manufactured using vacuum valve-integrated epoxy housing, and the KEPCO increases insulation strength against these problems. New measures are being explored.

It is now only 5 years since the first switchgear or circuit breaker using epoxy insulation housing is used in Korea, and only two companies have experience in molding insulation housing.

Until now, all of the insulation housings developed in Korea are all-in-one structure in which epoxy insulation housing and vacuum valve are molded at the same time.Even if an insulation housing molding company with the above-mentioned integrated production experience has a high defective rate, it will give up production or demand a price increase. It is a reality.

The technology of domestic insulation housing structure is a problem due to the internal structure of insulation housing or the fact that it is developed only as a simple integral molding structure due to lack of technology, and the experience of epoxy molding companies' molding technology between epoxy and vacuum valve Know-how is also lacking, so molding companies also pursue separate contracts for quality concerns and defective products in the production of integrated insulation housings. Therefore, both the ordering side and the production side start with a burden.

Conventional epoxy insulation housing manufacturing method is a one-piece manufacturing method in which many companies are molding all parts such as epoxy resin insulator, vacuum valve, voltage sensor, conductor, etc. at once.

Such a conventional one-piece insulation housing generates a lot of electrical property (interfacial) defects between the vacuum valve and the epoxy to be bonded during the molding process, and after the epoxy molding is completed, it hardens and hardens many parts inside the epoxy housing. No reuse at all. Therefore, because the entire amount must be discarded, there is a problem that costs a lot, resulting in a decrease in productivity and a rise in manufacturing costs.

In addition, there was a problem that a lot of environmental pollutants are generated due to many industrial wastes generated when defective.

Such a conventional one-piece insulating housing is manufactured by heating a high temperature (about 200 ° C.) by mounting an expensive vacuum valve inside a mold and then injecting an epoxy resin insulator, and vacuuming the mold at a high temperature inside the mold. Failure to do so may result in valve failure or characteristics change.

Vacuum valve is a product that is combined with Cu electrode, ceramic and plastic to melt the metal in the vacuum furnace and it is not good to reheat it to high temperature in the mold again.

Since the insulating material that forms the vacuum valve is coated with a glaze on the surface of the ceramic material, it is very smooth, so it is not reliably adhered to the epoxy and the molding. If such poor interface products are used, insulation breakdown occurs on the surface of the vacuum valve, which can be extended to the crack of the epoxy housing, which may lead to an accident. Therefore, during vacuum valve molding, the glaze on the surface of the vacuum valve is completely removed and surface treatment is performed with special chemicals in order to adhere well with epoxy. This process must be very carefully and strictly managed, and it takes a lot of time for the vacuum valve pre-molding before molding. .

Epoxy insulation housing consists of epoxy resin insulators for insulation and body support, vacuum valves to cut off electricity, and several components to improve the conducting conductors and electrical properties.

Among them, epoxy main insulation and vacuum valves are parts that are a big part of product cost because of their high price.

Until now, the conventional method has been developed considering the technical problem of coupling a vacuum valve inside an epoxy insulating housing only as a method of hard molding with a simple epoxy resin.

At present, many companies are producing enormous defects (about 30%) in the production of integrated insulation housings as described above, and therefore, material costs (epoxy raw materials, vacuum valves, electrodes, voltage sensors, etc.) and work costs in molding (parts in molds) There are many losses of granulation, epoxy resin injection, temperature heating, curing time, mold release, inspection, etc.).

Production of a conventional one-piece epoxy insulating housing takes much more than about two hours, so productivity is low and manufacturing cost of one insulating housing is about 600,000 won or more.

In addition, since the failure rate is high in the case of the conventional integrated insulating housing, the manufacturing cost is higher because the defect rate is considered in the manufacturing cost portion, thereby lowering the competitiveness in the market.

In addition, in case of integrated insulation housing, the condition after manufacture is good, and it is attached to the product and insulation breakdown occurs immediately when abnormality occurs at the interface of the vacuum valve surface while repeating the expansion and contraction of the temperature difference between summer and winter during use on the real line. This can lead to cracks in the insulation housing, which can cause massive power outages and casualties.

Recently, products using solid insulation at high speed are being applied to both load switch / breaker for overhead line and load switch / breaker for underground line, which is the time to fundamentally eliminate the problems caused by epoxy insulation housing itself. .

The object of the present invention devised to solve the problems of the prior art is to freely inside the insulating housing without any processing of the vacuum valve having the purpose of electrical shutdown after molding the epoxy housing having the purpose of insulation and support. In manufacturing the prefabricated insulating housing which is to be assembled, the insulating part is formed by injecting insulating oil into the gap between the vacuum valve and the epoxy housing, thereby causing problems due to poor molding of the existing epoxy housing and thermal expansion between the epoxy housing and the vacuum valve. An object of the present invention is to provide a prefabricated composite insulating housing for a switchgear / breaker that can solve the crack problem caused by the coefficient difference.

Another object of the present invention is to provide a prefabricated composite insulating housing, to improve the productivity by simplifying the manufacturing process of the housing and the vacuum valve assembly method, and to replace the defective parts only by easily separating the epoxy housing and the vacuum valve in the event of component failure. After that, by reassembling and reusing, it is possible to reduce component costs.

Another object of the present invention is to minimize the number of parts to be mounted in the mold during the mold operation to shorten the mold process time to reduce the manufacturing cost.

Another object of the present invention is to use an insulating oil (Oil) as the insulating medium of the interface between the insulating housing and the vacuum valve, the insulating oil is to use the vegetable insulating oil that is environmentally friendly.

The object of the present invention described above is assembled after fixing the vacuum valve itself is freely inserted into the insulating housing only in the state without any treatment after the completion of forming the insulating epoxy housing with a built-in conductor in the vacuum valve having the purpose of blocking the electric As a prefabricated insulating housing for a switch / breaker, it can be achieved by a prefabricated composite insulating housing for a switch / breaker, characterized in that to form an insulating part by filling the insulating oil in the space provided between the vacuum valve and the epoxy housing.

And, the object of the present invention is an epoxy housing; A vacuum valve inserted into and coupled to the hollow part of the epoxy housing; An insulation part formed by filling insulating oil in a space provided between the vacuum valve and the epoxy housing; A fixing bolt having one end screwed to a fixed electrode of the vacuum valve through the secondary electrode of the epoxy housing; A fixing plate coupled to the epoxy housing side to prevent the vacuum valve from being separated; A ring contactor configured to connect electricity between the fixed plate and the movable electrode of the vacuum valve; An electrode plate coupled to the fixing plate under the ring contactor to prevent the ring contactor from being separated; And an insulating rod coupled to operate the movable electrode of the vacuum valve in the lower portion of the electrode plate. It may be achieved by a prefabricated insulating housing for a switch / breaker.

In addition, it is possible to provide an expansion space in communication with the insulating portion on the axis of the primary side electrode, to accommodate the expansion and contraction deformation of the insulating oil according to the temperature change.

In addition, the separation distance of the vacuum valve and the epoxy housing may be formed to 3 ~ 7mm.

Then, screw tabs are formed on the outer surface of the fixing plate and the inner surface of the conduction guide, respectively, so that they can be mutually coupled to each other.

In addition, the ring contactor may be installed so that a plurality of contact pieces face each other so as to prevent shaking during the operation of the vacuum valve and allow a current to flow therebetween, and may have a contact pressure by inserting a spring between opposite contact pieces. .

In addition, the epoxy housing penetrates the inner center in a vertical direction and may install a vacuum valve.

In addition, since the insulating oil layer is present between the epoxy housing and the vacuum valve, the epoxy housing and the vacuum valve do not make direct contact, thereby preventing cracking of the housing due to thermal expansion coefficients of the two different materials.

In addition, the oil is injected through the center of the primary conductor without a separate injection port for oil injection, and the exterior is beautifully structured to secure a space inside the primary conductor where the oil can contract and expand according to temperature changes. The internal pressure rise can be prevented.

According to the present invention, the vacuum valve is assembled without any treatment to the inner hollow portion of the epoxy housing molded together with the conductor, thereby eliminating the need for attaching the elastic rubber to the surface of the vacuum valve. In addition, since defects are hardly generated during the epoxy housing molding operation, the defect rate is reduced, and it has the effect of improving the reliability of the product due to the decrease of the defective rate.

In addition, the present invention has the effect that parts management is convenient and productivity is improved since the product is completed by simply assembling the epoxy housing and the vacuum valve manufactured separately.

In addition, the present invention is economical because it is possible to minimize the material loss because it is possible to replace only the defective parts and to reuse the remaining parts as it is by removing the epoxy housing when a failure occurs, it is economical, reducing waste disposal costs and environmental pollution It has an effect that can be minimized.

In addition, the present invention is to provide a composite insulation assembly to the primary external insulation is to be made in the epoxy housing of the epoxy material, the secondary internal insulation is maintained by the insulating portion filled with insulating oil (Oil), It can lower the defective rate according to, and has an economic effect to prevent the loss due to the disposal of defective products.

In addition, the present invention is easy to assemble, excellent in insulation performance, and does not generate a crack of the epoxy housing due to the change of the external temperature has an excellent durability and service life of the product.

1 is an exploded view showing the overall structure of a prefabricated insulating housing according to the present invention.
Figure 2 is an assembled cross-sectional view and a main portion enlarged view showing the assembled state of the prefabricated insulating housing according to the present invention.
Figure 3 is a cross-sectional view showing the epoxy housing of the prefabricated insulating housing according to the present invention.
Figure 4 is a cross-sectional view showing a vacuum valve of the prefabricated insulating housing according to the present invention.
Figure 5 is a cross-sectional view showing an oil injection method of the prefabricated insulating housing according to the present invention.

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

Figure 1 is an exploded view showing the overall structure of the prefabricated insulating housing according to the present invention, Figure 2 is an assembled cross-sectional view and a main portion enlarged view showing the assembled state of the prefabricated insulating housing according to the present invention, Figure 3 is a present invention Figure 4 is a cross-sectional view showing the epoxy housing of the prefabricated insulating housing according to the present invention, Figure 4 is a cross-sectional view showing a vacuum valve of the prefabricated insulating housing according to the present invention, Figure 5 is an oil injection method and injection path of the prefabricated insulating housing according to the present invention. It is sectional drawing.

1 to 4, the prefabricated insulating housing according to the present invention is composed of a configuration including an epoxy housing 100 and a vacuum valve 200.

The epoxy housing 100 is molded using an epoxy resin insulator, and the epoxy housing 100 forms a hollow portion 111 penetrating the inner center in a vertical direction.

At this time, the hollow portion 111 provides a passage through which the vacuum valve 200 is inserted.

In this case, the epoxy housing 100 may form a plurality of inner wrinkle layers 115 on the inner surface of the hollow part 111, such an inner wrinkle layer 115 widens the surface area of the epoxy housing 100, an insulation distance It serves to increase.

In the epoxy housing 100, the secondary side electrode 120, the primary side electrode 130, and the conduction guide 170 are integrally formed. The secondary side electrode 120, the primary side electrode 130, and the conduction guide ( 170 may be positioned in the mold during the molding operation of the epoxy housing 100 to allow the insert injection.

The secondary side electrode 120 is installed at the longitudinal end of the epoxy housing 100, the primary side electrode 130 extends in the horizontal direction of the side of the epoxy housing 100.

In this case, the secondary side electrode 120 and the primary side electrode 130 may be manufactured using AL or Cu.

The conduction guide 170 is installed at an intermediate point of the hollow part 111 of the epoxy housing 100.

The conduction guide 170 as described above is integrally manufactured with the primary side electrode 130 and welded or cast, so that the electrical contact is made by surrounding the vacuum valve 200 and the fixed plate 320.

The vacuum valve 200 will be described as follows.

The vacuum valve 200 has a vacuum unit 250 formed in the ceramic insulator 210, the fixed electrode 220 is installed at one end in the longitudinal direction of the insulator 210, the insulated cylinder A movable electrode 230 which is grounded and short-circuited to the fixed electrode 220 is installed at the other end of the lengthwise direction 210.

The vacuum valve 200 is formed in a high vacuum state of the insulating tube 210 of a ceramic material, so that a large current can be blocked even at a short distance.

Such a vacuum valve 200 is coupled to the hollow portion 111 inside the epoxy housing 100.

In this case, the vacuum valve 200 and the epoxy housing 100 is installed so as to be spaced apart by a predetermined distance so as not to be in direct contact. To form.

In this case, an expansion space 125 communicating with the insulating part 240 may be provided on the axis of the secondary electrode 120 to accommodate expansion and contraction deformation of the insulating oil according to temperature change.

For example, as illustrated in FIG. 2, the P1 position of the expansion space 125 may be set to shrinkage (low temperature) of the insulating oil, the P2 position to a normal temperature, and P3 may be set to an expansion (high temperature) situation of the insulating oil.

At this time, the separation distance between the vacuum valve 200 and the epoxy housing 100 may be formed of 3 ~ 7mm.

In addition, the first packing 270 and the second packing 280 may be installed between the vacuum valve 200 and the epoxy housing 100 so as not to leak the insulating oil of the insulating part 240.

In this case, the first packing 270 and the second packing 280 may have different sizes or shapes.

For example, referring to FIGS. 1 and 2, the first packing 270 is manufactured to be in contact with the lower end of the fixing plate 320, the inner wall of the conduction guide 170, and the upper circumference of the vacuum valve 240 at the same time. The second packing 280 is manufactured in the form of contact between the inner end of the hollow 111 of the secondary electrode 120 and the vacuum valve 200.

The insulating part 240 buffers the gap between the epoxy housing 100 and the vacuum valve 200 to prevent the external shock from being transmitted to the vacuum valve 200, as well as the vacuum valve 200 and the epoxy housing 100. It serves as an insulation role that electrically disconnects between

As such, the insulating part 240 fills the insulating oil. Due to the characteristics of the insulating oil, the insulating part 240 is freely deformed according to the thermal expansion and contraction deformation of the epoxy housing 100, thereby preventing the insulating housing from being damaged.

Such insulating oils may use environmentally friendly vegetable insulating oils.

In addition, compared to the conventional method of manufacturing the vacuum valve 200 integrally molded with the epoxy housing 100, the mechanical generated during the heat (200 ℃) stress and surface processing (to improve adhesion) according to the molding operation It is possible to prevent the stress applied to the vacuum valve 200.

In addition, by injecting insulating oil (Oil) between the vacuum valve 200 and the epoxy housing 100 to form the insulating portion 240, there is an advantage in the convenience of assembly and disassembly operation, when this occurs, when the failure occurs, the epoxy housing and vacuum By disassembling the valve and replacing only defective parts, it is possible to reuse expensive vacuum valves and insulating housings.

In addition, since the number of parts to be mounted in the mold during the mold operation is small, the process time is shortened, manufacturing cost can be reduced, and the market competitiveness is increased.

In addition, prior to installing the vacuum valve 200 in the epoxy housing 100, a conductor 127 radially formed with an injection groove for oil injection is provided between the secondary electrode 120 and the vacuum valve 200. Install it.

When the conductor 127 and the vacuum valve 200 are assembled in this order, the fixing plate 320 is assembled on the movable electrode 230 side of the vacuum valve 200.

At this time, the outer surface of the fixing plate 320 and the inner surface of the conduction guide 170 is formed with a screw tab (not shown), respectively, the mutual spiral coupling is made, the fixing plate 320 is movable of the vacuum valve 200 The electrode 230 is pressed to be fixed.

At this time, the fixing plate 320 is made of a material capable of conducting electricity, it may be made of aluminum (AL) or copper (CU).

And, after the assembly of the fixing plate 320 is completed, to prevent shaking during the operation of the vacuum valve 200, the ring contactor for connecting the electricity flows between the vacuum valve movable electrode 230 and the fixed plate 320 ( 330 is assembled.

The ring contact 330 is installed so that a plurality of contact pieces (not shown) to face each other around, it is possible to have a contact pressure by inserting a spring (not shown) between the contact pieces facing each other.

After the assembly of the ring contactor 330 is completed, the electrode plate 340 to prevent the ring contactor 320 from being separated is coupled using the fixing bolt 350.

In this case, the electrode plate 340 also serves to further help to flow the electricity flowing through the vacuum valve 200 to the primary electrode 130.

The electrode plate 340 is assembled as described above is in contact with the current conduction guide electrode 170 with a constant contact force so that the electricity can flow, such an electrode plate 340 has the elasticity to be opened to the outside during assembly. By manufacturing, the contact area can be increased.

In this case, the electrode plate 340 may not be used when the contact relationship between the fixed plate 320 and the conduction guide 170 is sufficient for the conduction capability of 630A.

After the assembly of the electrode plate 350 is completed, the insulating rod 360 for operating the movable electrode 230 of the vacuum valve 200 is assembled.

Thereafter, as shown in FIG. 5, insulating oil is injected through the through hole of the secondary electrode 120, and the injected insulating oil is filled in an insulating part provided between the epoxy housing 100 and the vacuum valve 200.

At this time, the insulating oil is freely deformed according to the thermal expansion and contraction deformation of the epoxy housing 100, by the expansion space 125 is formed so as to communicate with the insulating portion 240 on the axis of the secondary electrode 120. It can accommodate the expansion and contraction deformation of the insulating oil according to the temperature change.

Thereafter, the fixing bolt 310 penetrates through the secondary side electrode 120 to be screwed to the fixed electrode 220 of the vacuum valve 200.

At this time, the O-ring 311 and the spacer 312 may be further installed on the shaft of the fixing bolt 310.

The prefabricated composite insulating housing of the present invention having the structure as described above allows the vacuum valve 200 to be assembled together without any molding process or surface treatment after the molding of the epoxy housing 100 is completed. By working, the operation is convenient, and the defect rate is hardly generated during molding of the housing, thereby reducing the defective rate and contributing to the improvement of the reliability of the product due to the reduced defective rate.

In addition, the present invention is a simple assembly of the epoxy housing 100 and the vacuum valve 200 made in a single unit to complete the product is convenient parts management, productivity is improved.

In addition, the present invention is economical because it is possible to minimize the material loss because it is possible to replace only the defective parts and to reuse the remaining parts as it is by removing the epoxy housing 100 when a failure occurs, as well as reducing waste disposal costs Environmental pollution can be minimized.

The present invention for this purpose can use vegetable insulating oil as an environmentally friendly insulating oil.

In addition, the present invention is to provide a composite insulation assembly to the primary external insulation is to be made in the epoxy housing of the epoxy material, the secondary internal insulation is maintained by the insulating portion filled with insulating oil (Oil), According to the present invention, it is possible to lower the defective rate, to prevent loss due to scrapping of the defective product, and the present invention is easy to assemble, has excellent insulation performance, and does not generate cracks in the epoxy housing due to external temperature changes. It has an excellent service life.

In addition, the present invention is able to inject and seal the oil through the center of the primary conductor without a separate injection port for oil injection, and to secure a space in the primary conductor inside the contraction and expansion of the oil according to the temperature change It has the advantage of maintaining the insulation performance and preventing oil leakage by preventing the pressure rise inside.

In addition, the present invention by inserting and molding only a simple conductor without a vacuum valve during the mold operation of the epoxy housing, it is easy to assemble and work the mold, it is possible to reduce the product cost as a short working time.

In particular, as in the prior art, there is no hassle of having to specially surface-treat the vacuum valve surface before the mold operation, and it is possible to completely eliminate the defect problem that occurred at the vacuum valve interface.

In addition, the present invention improves reliability because there is no thermal effect applied to the vacuum valve due to the temperature of the inside of the mold (about 200 ° C) when molding the conventional vacuum valve at the same time.

In addition, the present invention, but the vacuum valve built-in manufacturing method in the prior art took a lot of time for the inspection of the defective portion due to the vacuum valve, the present invention has the advantage that such inspection parts are unnecessary, the inspection work after production is shortened, Since the electrical insulation caused by the conventional vacuum valve and epoxy interface defects to use the oil insulation has a merit that can completely solve the electrical characteristic problem occurring in the conventional integrated.

100: epoxy housing 111: hollow part
115: inner wrinkle layer 120: secondary electrode
130: primary electrode 170: electricity supply guide
200: vacuum valve 210: insulating cylinder
220: fixed electrode 230: movable electrode
240: insulation section 250: vacuum section
270: first packing 280: second packing
320: fixed plate 330: ring contactor
340: electrode plate 350: electrode plate fixing bolt
360: insulated rod

Claims (7)

It is a prefabricated composite insulating housing for switchgear / breaker which is to assemble the vacuum valve 200 to the epoxy housing 100 in which the secondary side electrode 120 and the primary side electrode 130 are integrally molded without any molding process or surface treatment. ,
Prefabricated composite insulating housing for the switchgear / circuit breaker, characterized in that to form an insulating portion 240 by filling the insulating oil in the space provided between the vacuum valve 200 and the epoxy housing 100. Epoxy housing 100;
Vacuum valve 200 is inserted through the hollow portion 111 of the epoxy housing 100;
An insulating part 240 formed by filling insulating oil in a space provided between the vacuum valve 200 and the epoxy housing 100;
A fixing bolt 310 having one end screwed through the secondary electrode 120 of the epoxy housing 100 and screwed to the fixed electrode 220 of the vacuum valve 200;
A fixing plate 320 coupled to the epoxy housing 100 to prevent the vacuum valve 200 from being separated;
A ring contactor 330 which connects electricity between the fixed plate 320 and the movable electrode 230 of the vacuum valve 200;
An electrode plate 340 coupled to the fixed plate 320 under the ring contact 330 to prevent the ring contact 330 from being separated; And
Prefabricated composite insulating housing for the switchgear / circuit breaker comprising a; insulating rod 360 is coupled to operate the movable electrode 230 of the vacuum valve 200 in the lower portion of the electrode plate (350).
The method of claim 2,
Prefabricated switchgear / circuit breaker for providing an expansion space 125 in communication with the insulating portion 240 on the axis of the secondary side electrode 120 to accommodate the expansion and contraction deformation of the insulating oil according to the temperature change Composite Insulation Housing.
3. The method according to claim 1 or 2,
The vacuum valve 200 and the epoxy housing 100, the separation distance of the prefabricated composite insulating housing for the switchgear / circuit breaker, characterized in that formed in 3 ~ 7mm.
The method of claim 2,
Prefabricated composite insulating housing for switchgear / circuit breaker, characterized in that the screw tab is formed on the outer surface and the inner surface of the conductive guide inner surface of the fixing plate 320 to be coupled to each other spirally.
The method of claim 2,
The ring contact 330 is installed so that several contact pieces face each other so as to prevent shaking during operation of the vacuum valve 200, the spring is inserted between the contact pieces facing each other to have a contact pressure Composite insulation housing for switchgear / breaker
3. The method according to claim 1 or 2,
The epoxy housing 100 penetrates the inner center in a vertical direction, and forms a hollow part (111) (111 ').

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