KR101196004B1 - Rupture disk and gas insulated switchgear having the same - Google Patents

Abstract

PURPOSE: A rupture disc and gas insulated switchgear having the same are provided to minimize damage to a device by discharging excessive pressure to a safe external place. CONSTITUTION: A thin dome plate(110) includes a first flange(111) and a first dome shaped upper part(112). The first dome shaped upper part is formed on the center of the first flange. A rupture inducing plate(120) is stacked on the inside of the first flange and the first dome shaped upper part. The rupture inducing plate has a second dome shaped upper part(122). The second dome shaped upper part includes a plurality of slots(125). The plurality of slots limits a rupture shape. A thin film protection plate(130) has an opened dome shaped protection surface.

Description

Safety bursting plate and gas insulated switchgear having the same {RUPTURE DISK AND GAS INSULATED SWITCHGEAR HAVING THE SAME}

The present invention relates to a safety rupture plate and a gas insulation switchgear having the same so that the insulation gas is discharged in advance when the internal pressure rises to minimize the damage and expansion loss of the device.

A gas insulated switchgear (GIS) is a circuit breaker that opens and closes an electric circuit, and gas is filled in the circuit breaker as an insulator. Sulfur hexafluoride (SF ₆ ), which is spotlighted as an insulating gas, has an insulation effect that is three times higher than that of air, and the effect increases when pressure is applied thereto. Due to the electrical characteristics of SF ₆ gas, the breaker can obtain an insulation effect even in a smaller space than before, and is widely used in gas insulation switchgear.

Gas insulation switchgear filled with SF ₆ gas does not cause any problem when a constant pressure is maintained.However, when a short circuit occurs due to an electrical accident, the energy increases rapidly and the temperature rises. The container leads to an explosion. In this case, it is important to prevent the explosion of the device in advance, since the time for recovery is extended, the economic loss is increased astronomically, and may lead to environmental or human injury.

Although spring-type safety valves have been proposed to relieve the rapidly increasing pressure of the gas insulated switchgear, there is a problem that it is often difficult to solve unexpected sudden pressure rises. In addition, to solve this problem has been proposed to solve by a rupture disk (rupture disk), but when the pieces are ruptured due to the blockage does not smoothly reduce the pressure or damage caused by the pieces.

In view of the above, the present invention, in order to cope with a sudden pressure increase due to an unexpected failure inside the gas insulated switchgear, by discharging the excess pressure to a safe outside place when the pressure is applied above the safety limit and the appropriate pressure, It is to minimize the damage of equipment and to prevent large accidents or human injury in advance.

Another object of the present invention, the gas insulated switchgear is formed to be integrally in close contact with the portion that requires a large amount of discharge or damage in the moment, and breaks the entire pressure vessel in advance when the pressure rises rapidly To prevent it.

In order to solve the above problems, the safety rupture plate for a gas insulated switchgear according to the present invention, a thin dome plate including a first flange portion, and a first dome shape formed in the center of the first flange portion in the form of a dome. ; The first flange portion and the first dome-shaped portion is stacked inside the second flange portion and the first dome-shaped portion laminated on the first flange portion when the internal pressure rises a portion of the first dome-shaped portion is constant A rupture induction plate having a second dome shape having a plurality of slots defining a rupture shape to be ruptured in a shape; And a stack formed to protect the thin plate dome plate on the outside of the first flange portion and the first dome shape portion, and to protect the third flange portion and the outer portion of the first dome shape portion stacked on the first flange portion. It includes a thin plate protective plate having an open dome-shaped protective surface.

As an example related to the present invention, an inner diameter of the open dome protective surface may be formed to be larger than a diameter defined by the plurality of slots.

As an example related to the present invention, the third flange portion may be formed in a shape corresponding to the first flange portion, and the open dome protective surface may be formed to have a curvature corresponding to the first dome portion.

As an example related to the present invention, disposed between the first flange portion and the third flange portion or between the first dome shape portion and the open dome protection surface, between the first flange portion and the third flange portion. It may include a flexible sealing layer formed to maintain the airtight or the airtight between the first dome-shaped portion and the open dome-shaped protective surface.

As an example related to the present invention, the flexible sealing layer may include silicone resin or silicone rubber.

As an example related to the present invention, the flexible sealing layer may be formed by being applied to a target region and cured.

As an example related to the present invention, the safety rupture plate for the gas insulated switchgear may be formed to block foreign matters penetrating into the slot, and may further include a foreign material blocking layer formed by silicone resin or silicone rubber.

As an example related to the present invention, the first flange portion, the second flange portion, and the third flange portion may be coupled to each other in a plurality of positions along the circumferential direction.

The present invention also provides a gas insulated switchgear having the safety rupture plate as described above.

According to the safety rupture plate and the gas insulated switchgear having the same according to the present invention, when the internal pressure of the insulating gas filled in the device rapidly rises, the thin dome plate ruptures to release the insulating gas, thereby preventing damage to the pressure vessel. This can minimize magnification losses.

According to an example related to the present invention, it is accurately ruptured within an error range of the set pressure, thereby enabling the safe discharge of the SF ₆ gas.

1 is a perspective view showing a state in which the safety rupture plate 100 is assembled according to an embodiment related to the present invention
2 is an exploded perspective view for showing a laminated state of the safety rupture plate 100 of FIG.
Figure 3 is a side cross-sectional view for explaining the assembly state of the safety rupture plate 100 of Figure 1 on the object 101
4 is a side cross-sectional view schematically showing a state in which the safety bursting plate 100 of FIG. 3 is ruptured under internal pressure.
5 is an exploded perspective view of a safety rupture plate 100 'according to another embodiment related to the present invention.
Figure 6 is an exploded perspective view of a safety rupture plate 100 "according to another embodiment related to the present invention

Hereinafter, with reference to the accompanying drawings, a safety bursting plate and a gas insulated switchgear having the same according to the present invention will be described in detail.

1 is a perspective view showing an assembled state of the safety rupture plate 100 according to the first embodiment related to the present invention, Figure 2 is an exploded perspective view for showing a laminated state of the safety rupture plate 100 of FIG.

As shown in these figures, the safety rupture plate 100 has a plurality of stacked plates. Specifically, the safety bursting plate 100 includes a thin dome plate 110, a tear induction plate 120 and a thin plate protection plate 130. These plates are stacked and assembled together to form an assembly as shown in FIG. A tab for displaying various specifications of the safety rupture plate 100 may be attached to one side of the safety rupture plate 100. For attachment of the tab, a protrusion may be formed at one side of the safety rupture plate.

The thin dome plate 110 is configured to keep the gas inside the gas insulation switchgear filled with an insulation gas such as SF ₆ within a predetermined pressure range, and to burst at a predetermined pressure or more. According to FIG. 2, the thin dome plate 110 has a first flange portion 111 and a first dome portion 112 formed in a dome shape inside the first flange portion 111.

The first flange 111 is in close contact with the opening surface of the gas insulated switchgear, and may further include a plurality of fastening holes along the circumferential direction to allow the fastening bolt to pass therethrough. The first dome-shaped portion 112 is installed to be recessed in the inner direction of the gas insulated switchgear, and is deformed in the opposite direction when the internal pressure rises in a form recessed in the inner direction during normal operation so as to protrude outward. The thin dome plate 110 is formed in the form of a thin metal sheet, and may have various thicknesses according to the bursting capacity.

The burst induction plate 120 is stacked on the rear surface of the thin dome plate 110, that is, inside the first dome shape 112 in relation to the gas insulated switchgear, and has a shape corresponding to the thin dome plate 110 as a whole. It is formed. In detail, the rupture induction plate 120 also has a second flange portion 121 stacked on the first flange portion 111 and a second dome portion 122 formed in a dome shape corresponding to the first dome portion 112. Equipped with. The second dome portion 122 has a slot 125 which defines a tear shape so that the first dome portion 112 may rupture in a predetermined shape at a limit pressure when the internal pressure of the first dome portion 112 rises. Is formed. By the slot 125, the second dome shape portion 122 is divided into an inner dome and an outer dome. When internal pressure is applied to the thin dome plate 110, the inner dome is separated from the outer dome and is opened to provide a space for the thin dome plate 110 to burst and expand.

Like the first flange 111, a plurality of fastening holes through which the fastening bolt can pass may be further formed in the second flange 121, and a protrusion for attaching a tab for displaying a specification may be additionally formed. Can be.

2, the slot 125 of the tear induction plate 120 is in the form of a sawtooth line. This serrated line provides a sharp vertex to facilitate rupture of the pressured thin dome plate 110. In general, the slot 125 is configured to include a plurality of unit slots having an arc shape. One unit slot is connected by an adjacent unit slot and a rupture bridge (a narrow connection point separating the unit slot and the unit slot). The bursting bridge is one element (parameter) that determines the bursting pressure when the thin dome plate 110 is pressurized. Thus, the shape or size of the bursting bridge can also be designed to match the set bursting pressure. The unit slots constituting the slot 125 are arranged in a columnar shape at regular angular intervals, two unit slots of which are farther from the rupture bridge, so as to form a hinge portion of the second dome portion 122. A burst limit opening 126 is formed at the end of two adjacent unit slots defining the hinge portion. The burst limit opening 126 prevents damage to the hinge portion during the tear of the tear-inducing plate 120 and prevents the inner dome from being separated from the outer dome during the tear. The shape or size of the burst limit opening 126 is another factor that determines the burst pressure or the shape of the burst, and can be designed according to the set burst pressure. The burst induction plate 120 includes a connection slot so that the slot 125 and the burst limit opening 126 can be connected. The shape of the connection slot may also be a factor in determining the burst pressure, and may be variously designed according to the set burst pressure. Slots 125 or openings 126 shown in FIG. 1 or 2 are exemplary and other shapes are possible.

The thin plate protection plate 130 is laminated to protect the thin plate dome plate 110 on the outer side of the first flange portion 111 and the first dome shape portion 112. The thin plate protection plate 130 was used to prevent scratches on the surface of the thin plate dome plate 110 is made of thin or deformed by other factors (impact, physical, chemical external factors) during handling. In particular, the thin plate protection plate 130 is very useful to prevent surface damage due to the penetration of sand when the environment of use of the safety bursting plate 100 is desert.

The thin plate protection plate 130 includes a third flange portion 131 stacked on the first flange portion 111, and the third flange portion 131 may cover a portion of the first dome portion 112. A dome-shaped protection surface 132 is formed to protect the outer portion of the first dome-shaped portion 112. The open dome-shaped protective surface 132 has an open center, and the inner diameter thereof is larger than the diameter defined by the slot 125 described above, thereby causing the rupture action of the thin dome plate 110 and the tear induction plate 120. It may be configured not to disturb.

In general, the third flange portion 131 is formed in a shape corresponding to the first flange portion 111, the open dome-shaped protective surface 132 may also be formed to have a curvature corresponding to the first dome-shaped portion (112). have.

Like the first flange 111 and the second flange 121, a plurality of fastening holes through which the fastening bolt can be passed may be further formed in the third flange 131, and the tab for the specification display Protrusions may be further formed for.

2, the flexible sealing layer 140 is disposed between the first flange portion 111 and the third flange portion 131 or between the first dome portion 112 and the open dome protective surface 132. Can be. The flexible sealing layer 140 may maintain the airtightness between the first flange portion 111 and the third flange portion 131 or the airtightness between the first dome shape portion 112 and the open dome protection surface 132. As it is formed, to prevent the penetration of sand or foreign matter into the gap between the thin dome plate 110 and the thin plate protection plate 130. If sand or foreign matter is caught, it may cause an impact on the durability or burst pressure of the thin dome plate 110 to prevent this in advance.

The flexible sealing layer 140 may be formed of a silicone resin or silicone rubber, and may be obtained by being applied to a target area and cured. A masking member may be used in the manufacturing process to prevent leakage of the flexible sealing layer 140 and to be applied only in a predetermined area. The masking member may be applied a release film or a release agent.

3 is a side cross-sectional view for explaining the assembly state of the safety rupture plate 100 of FIG. 1 to the object 101, Figure 4 is a side schematically showing a state in which the safety rupture plate 100 of FIG. It is a cross section.

The first flange portion 111 of the thin dome plate 110 forming the safety bursting plate 100, the second flange portion 121 of the tear induction plate 120, and the third flange portion 131 of the thin plate protection plate 130. ) May be press-bonded at a plurality of positions along the circumferential direction. By such bonding, the thin dome plate 110, the tear induction plate 120, and the thin plate protection plate 130 are formed in an integral form, and the first dome shape 112 and the second dome shape are formed by the fastening bolts B. The convex portion of the upper portion 122 is fastened to the object 101 to face the inner direction of the gas insulated switchgear. According to FIGS. 3 and 4, the bolt B is formed of the first flange 111 of the thin dome plate 110, the second flange 121 of the rupture induction plate 120, and the thin plate protection plate 130. It is disposed outside the three flange portions 131. However, bolt fastening holes are respectively applied to the first flange portion 111 of the dome plate 110, the second flange portion 121 of the rupture induction plate 120, and the third flange portion 131 of the thin plate protective plate 130. If formed, the bolt (B) is the first flange portion 111 of the thin plate dome plate 110, the second flange portion 121 of the tear-inducing plate 120 and the third plan of the plate protection plate 130 It is also possible to fasten through the branch 131. Accordingly, the airtightness of the SF ₆ gas is maintained by the thin dome plate 110, and the internal pressure below the set value is maintained by the rupture induction plate 120 and the thin plate protection plate 130.

When the proper pressure of the gas insulated switchgear is exceeded in the state where the safety rupture plate 100 is mounted, the first dome portion 112 of the thin plate dome plate 110 and the second dome portion of the rupture induction plate 120 are instantaneous. 122 is deformed in the reverse direction, and at the threshold pressure, the rupture bridge is first broken, causing the inner dome of the rupture induction plate 120 to suddenly drop (open). At this time, since the outer dome of the rupture induction plate 120 is fixed, the thin plate dome plate 120 is cut into a sawtooth-like slot by a punch action generated by the gas pressure.

5 is an exploded perspective view of the safety rupture plate 100 ′ according to another example related to the present invention.

The safety rupture plate 100 ′ of the present example may further include a foreign material blocking layer 150 in addition to the thin dome plate 110, the rupture induction plate 120, the thin plate protection plate 130, and the flexible sealing layer 140 described above. It is included. The foreign material blocking layer 150 blocks sand or foreign matter from infiltrating into the slot 125 and the burst limit opening 126 that are exposed to the outside during handling, and the silicone resin like the soft sealing layer 140. Or silicone rubber. FIG. 5 shows that the foreign material blocking layer 150 is formed outside of the tear induction plate 120, that is, inside the second dome portion 122 of the tear induction plate 120. The foreign material barrier layer 150 continuously maintains the reliability of the safety rupture plate 100 ′ in a desert or dusty environment.

6 is an exploded perspective view of a safety rupture plate 100 "according to another example related to the present invention.

The safety rupture plate 100 ″ of the present example shows that the foreign material blocking layer 150 ′ is disposed between the thin plate dome plate 110 and the tear induction plate 120 instead of the foreign material blocking layer 150 shown in FIG. 5. The foreign material barrier layer 150 'also continuously maintains the reliability of the safety rupture plate 100 "in a desert or dusty environment.

The safety bursting plate and the gas insulation switchgear having the same described above are not limited to the configuration and method of the embodiments described. The embodiments may be configured so that all or some of the embodiments may be selectively combined so that various modifications may be made.

100: safety rupture plate 101: gas insulated switchgear
110: thin plate dome plate 111: first flange portion
112: first dome shape 120: rupture induction plate
121: second flange portion 122: second dome shape portion
125: slot 126: burst limit opening
130: thin plate protective plate 131: third flange portion
132: open dome type protective surface 140: flexible sealing layer
150: foreign material blocking layer

Claims (9)

A thin dome plate including a first flange portion and a first dome shape portion formed in a dome shape at the center of the first flange portion;
The first flange portion and the first dome-shaped portion is stacked inside the second flange portion and the first dome-shaped portion laminated on the first flange portion when the internal pressure rises a portion of the first dome-shaped portion is constant A rupture induction plate having a second dome shape having a plurality of slots defining a rupture shape to be ruptured in a shape; And
The thin plate dome plate is laminated on the outer side of the first flange portion and the first dome shape portion to protect the third flange portion and the outer portion of the first dome shape portion laminated to the first flange portion. A safety rupture plate for a gas insulated switchgear comprising a thin plate protection plate having an open dome type protection surface.
The method of claim 1,
And an inner diameter of the open dome protective surface is larger than a diameter defined by the plurality of slots.
The method of claim 1,
The third flange portion is formed in a shape corresponding to the first flange portion,
The open dome protective surface is formed to have a curvature corresponding to the first dome shape, safety bursting plate for gas insulated switchgear.
The method of claim 1,
Between the first flange portion and the third flange portion or between the first dome shape portion and the open dome protection surface, and between the first flange portion and the third flange portion, And a flexible sealing layer formed to maintain the airtightness between the open dome type protective surfaces.
5. The method of claim 4,
The flexible sealing layer comprises a silicone resin (silicone resin) or silicone rubber (silicone rubber), safety bursting plate for gas insulation switchgear.
5. The method of claim 4,
The flexible sealing layer is a safety rupture plate for a gas insulated switchgear formed by applying to the target area and cured.
The method of claim 1,
It is formed to block the foreign matter penetrating into the slot, and further comprising a foreign material blocking layer, comprising a silicone resin or silicone rubber, safety bursting plate for gas insulation switchgear.
The method of claim 1,
And the first flange portion, the second flange portion, and the third flange portion are press-bonded and coupled at a plurality of positions along the circumferential direction.
A gas insulated switchgear having a safety rupture plate according to any one of claims 1 to 8.

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