KR101040590B1 - Device to control the pressure in thermal chamber of gas circuit braker - Google Patents

Abstract

The present invention relates to a pressure expansion device for the thermal expansion chamber of the gas circuit breaker, to control the pressure of the thermal expansion chamber of the gas circuit breaker, to reduce the stress applied to the manipulator and the breaker and to cool the gas expanded to high temperature to prevent damage to the breaker. And it relates to a thermal expansion chamber pressure regulator that can increase the blocking performance.

To this end, in the present invention, the first pressure reducing valve 50 is installed on the separation wall 60 between the thermal expansion chamber 80 and the compression chamber 90, and when the gas pressure of the thermal expansion chamber 80 becomes greater than or equal to a threshold value, Provided is a thermal expansion chamber pressure regulating device for a gas circuit breaker in which one pressure reducing valve 50 is opened.

Circuit breaker, thermal expansion chamber, pressure, gas pressure, pressure regulation, breaking performance, pressure reducing valve

Description

Device to control the pressure in thermal chamber of gas circuit braker

The present invention relates to a pressure expansion device for the thermal expansion chamber of the gas circuit breaker, and more particularly, to adjust the pressure of the thermal expansion chamber of the gas circuit breaker, to reduce the stress applied to the manipulator and the blocking unit and to cool off the gas expanded to high temperature It relates to a thermal expansion chamber pressure regulating device that can prevent damage to the parts and increase the blocking performance.

In general, when a breakdown occurs in the power system, a circuit breaker is used to cut off the fault current and protect the power equipment. Such a breaker usually comprises two chambers, a compression chamber and a thermal chamber.

The breaker delivers electricity while supplying rated current under normal conditions, and breaks down the fault current using a compression chamber and a thermal expansion chamber when a fault or accident occurs in the power system and flows up to about 10 times the normal current. Done.

Usually, the compression chamber of a breaker is used for breaking a small current, and a thermal expansion chamber is used for breaking a large current.

1 is a schematic block diagram showing a conventional circuit breaker structure.

As shown in FIG. 1, a conventional circuit breaker includes a fixed arc contact 1, a movable arc contact 2, a first nozzle 4, a second nozzle 5, a cylinder rod 3, and a piston 7. And a check valve 6a mounted on the separating wall 6 separating the thermal expansion chamber 8 and the compression chamber 9 and a pressure reducing valve 7a provided on the piston 7.

When a breaker in the power system occurs, all of the remaining parts (hereinafter, referred to as movable parts) except for the fixed arc contact point 1 and the piston 7 move from left to right with reference to FIG. 1, and the movable part moves. Gas in the compression chamber 9 is automatically compressed by the piston 7.

In addition, as the movable portion moves, the movable arc contact 2 and the fixed arc contact 1 are separated, and an arc is generated between the two arc contacts 1 and 2.

When the gas pressure of the compression chamber 9 is higher than the gas pressure of the thermal expansion chamber 8, the check valve 6a of the separation wall 6 is opened, and the gas compressed in the compression chamber 9 is the thermal expansion chamber 8. And sprayed between the fixed arc contact 1 and the movable arc contact 2 through the first nozzle 4.

Accordingly, the arc generated between the two arc contacts (1, 2) is extinguished by the compressed gas in the compression chamber (9) to block the fault current.

The interruption of the fault current is possible only when the fault current generated in the power system is small, and the injected gas is expanded by an arc generated between the fixed arc contact point 1 and the movable arc contact point 2 so that the thermal expansion chamber ( 8) This is only possible if not backflowed.

When the fault current to be interrupted is large, the arc energy generated between the fixed arc contact 1 and the movable arc contact 2 becomes large so that the surrounding gas is expanded so that the gas flows back into the thermal expansion chamber 8.

The pressure of the thermal expansion chamber 8 is higher than that of the compression chamber 9 by the backflow gas, and the check valve 6a is closed by this.

The gas flowing back into the thermal expansion chamber 8 is cooled in the thermal expansion chamber 8 and injected into the arc again between the fixed arc contact 1 and the movable arc contact 2 to extinguish the arc.

In this process, if the pressure in the compression chamber 9 is high, stress is applied to the manipulator (not shown), and mechanical pressure may be applied to the blocking part 10 itself, so that the pressure in the compression chamber 9 is constant (for example, For example, the pressure of the compression chamber 9 is adjusted by opening the pressure reducing valve 7a of the piston 7 to the rear to eject the gas of the compression chamber 9 to 15 bar or more.

In other words, when the magnitude of the fault current is small, the arc current is blocked by the compressed gas in the compression chamber 9, and the fault current is interrupted. When the fault current is large, the fixed arc contact 1 and the movable arc contact 2 Using the arc energy generated between) expands the surrounding gas to flow back to the thermal expansion chamber (8), and then flow back to cool the compressed and compressed gas in the thermal expansion chamber (8) again to extinguish the arc and to cut off the fault current It is.

Such a conventional circuit breaker can be said that the volume of the thermal expansion chamber (8) determines the fault current blocking performance. That is, if the volume of the thermal expansion chamber 8 is too large, it is impossible to obtain a gas pressure capable of extinguishing the arc and blocking the fault current through the gas flowing back into the thermal expansion chamber 8. On the contrary, if the volume of the thermal expansion chamber 8 is too small, the pressure of the thermal expansion chamber 8 rises but cooling of the backflow gas is lowered, stressing the manipulator due to a higher pressure than necessary, and the blocking unit 10 itself. There is a problem that the mechanical pressure is applied to the.

However, the magnitude of the fault current that the breaker should cut off varies from several 100A to several 10kA. Even with the magnitude of the fault current specified in the international standard, a small current of several 100A, T10 of 10% of rated breaking current, T30 of 30%, T60 of 60%, SLF90 of 90%, T100s of 100% and 100% T100a and the like, and if any one of them fails, the function as a circuit breaker cannot be recognized.

Usually, small currents, T10 and T30 are blocked by the compressed gas in the compression chamber 9, and the rest are blocked by the expanded gas in the thermal expansion chamber 8 using arc energy.

However, in the event that the volume of the thermal expansion chamber 8 is set to T60, the arc energy at T100 cannot be accommodated. On the contrary, if the volume is determined at T100, the pressure increase effect required at T60 cannot be obtained. Above all, failure to properly handle the gas heated and expanded by excessive arc energy (up to 2.5 times the rated breaking current 100%) in the T100a loaded with DC powder will fail.

That is, when the conventional circuit breaker cuts off a large current due to a failure in the power system, the pressure of the thermal expansion chamber 8 rises more than necessary due to too large arc energy, and the cooling of the gas is not performed. There is a problem that can damage the (10) as well as fail to interrupt the fault current.

The present invention is invented to solve the above problems, the pressure reducing valve 50 is provided on the separation wall 60 between the thermal expansion chamber 80 and the compression chamber 90, the pressure reducing valve 50 The gas can be set to operate at a pressure higher than the threshold value, and when excess current flowed back into the thermal expansion chamber 80 is introduced into the compression chamber 90 when an electric current is generated due to a failure in the power system, an excessive pressure of the thermal expansion chamber 80 can be controlled. It is an object of the present invention to provide a thermal expansion chamber pressure regulator of a circuit breaker.

In order to achieve the above object, in the present invention, a first pressure reducing valve (50) is installed on the separation wall (60) between the thermal expansion chamber (80) and the compression chamber (90), and the gas pressure of the thermal expansion chamber (80) is increased. When the threshold value is greater than the first pressure reducing valve 50 is provided to provide a thermal expansion chamber pressure regulating device of the gas circuit breaker.

The thermal expansion chamber pressure regulating device of the gas circuit breaker according to the present invention is provided with a pressure reducing valve that opens when a pressure greater than a threshold is applied to the separation wall between the thermal expansion chamber and the compression chamber, whereby the thermal expansion chamber flows backward when the current is generated due to a failure in the power system. When the gas pressure is greater than or equal to the threshold value, opening the pressure reducing valve of the separation wall to flow backflow gas into the compression chamber to control the excessive pressure of the thermal expansion chamber and at the same time can be cooled in the compression chamber.

Accordingly, in the present invention, the compression chamber is used as an auxiliary chamber as the second thermal expansion chamber, thereby preventing the gas pressure of the thermal expansion chamber from becoming higher than necessary, and cooling the reversed gas to block fault currents of various sizes, particularly large currents. It is possible to increase the blocking performance of the blocking portion.

In addition, the thermal expansion chamber pressure regulating device according to the present invention can be configured by installing a pressure reducing valve on the separation wall of the existing circuit breaker, it can be applied immediately with a low cost and a simple process, it can be applied to all kinds of complex fire breaker There is an advantage.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention, as used in the singular and the plural unless the context clearly indicates otherwise.

There may be a plurality of embodiments of the present invention, and overlapping descriptions of the same parts as in the prior art may be omitted.

The present invention provides a pressure reducing valve (50) which is opened when a pressure greater than or equal to a threshold is applied to the separation wall (60) between the thermal expansion chamber (80) and the compression chamber (90) of the gas circuit breaker to adjust the pressure of the thermal expansion chamber (80). By doing so, it is possible to reduce the stress applied to the manipulator (not shown) and the blocking unit 100 and to cool the gas expanded to a high temperature to prevent damage to the blocking unit 100 and to increase the blocking performance.

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

Figure 2 is a block diagram showing an embodiment of the thermal expansion chamber pressure regulating device of the gas circuit breaker according to the present invention, Figure 3 is a partial perspective view showing the main portion of the present invention, Figure 4 is a 'A' region of FIG. It is an enlarged view shown.

The present invention is to block the fault current flowing when a failure occurs in the power system, by configuring a gas circuit breaker to adjust the pressure of the thermal expansion chamber 80, when a large arc energy due to the failure current occurs in the thermal expansion chamber (80) The pressure of the thermal expansion chamber 80 is prevented from increasing higher than necessary by the gas flowed back to the back side).

Accordingly, when the pressure of the gas flowing back to the thermal expansion chamber 80 of the gas circuit breaker is excessively high, the gas of the thermal expansion chamber 80 is ejected to the outside to properly adjust the pressure of the thermal expansion chamber 80, the gas circuit breaker tank Prevents ground faults (breakdown) to (not shown).

When the gas pressure is excessively high, the cooling of the gas flowed back into the thermal expansion chamber 80 may be lowered. Therefore, the present invention should also obtain a cooling effect of lowering the temperature of the gas flowed back into the thermal expansion chamber 80.

To this end, the present invention, as shown in Figures 2 and 3, the first pressure reducing valve (or pressure reducing valve of the separation wall 60) 50 configured to open when the pressure in the thermal expansion chamber 80 exceeds the threshold (50) Is installed on the separation wall between the thermal expansion chamber 80 and the compression chamber 90, so that the gas in the thermal expansion chamber 80 is ejected into the compression chamber 90 when the pressure of the thermal expansion chamber 80 becomes a predetermined value or more. .

As shown in FIGS. 3 and 4, the first pressure reducing valve 50 includes a spring 51 compressed by a predetermined pressure, a spring support 53 supporting the spring 51, and the spring ( It may be configured to include a valve opening and closing portion 55 is provided with a guide shaft 57 penetrating 51.

The guide shaft 57 may be integrally formed with the valve opening and closing portion 55.

The spring support 53 is disposed on the compression chamber 90 side to be fixed to the outer wall surface of the cylinder rod 30, and the valve opening and closing portion 55 is movable along the outer wall surface of the cylinder rod 30. Is installed.

To this end, the valve opening and closing portion 55 is formed in a ring shape is configured to be in close contact with the outer wall surface of the cylinder rod (30).

The spring support 53 is provided with a through hole 53a through which the guide shaft 57, which linearly moves, can communicate with the valve opening and closing portion 55 which is moved under pressure of the thermal expansion chamber 80. .

The first pressure reducing valve 50 is arranged in the opening hole 63 formed by opening the lower end of the separation wall 60 in contact with the cylinder rod 30, the first pressure reducing valve 50 is not opened In the upper end of the valve opening and closing portion 55 is in close contact with the lower end of the separation wall 60 is maintained in a close state by the elastic force of the spring (51).

The opening hole 63 is formed so as to open in the shape of a tapered arch from the compression chamber 90 side to the thermal expansion chamber 80 side, so that the compressed gas flows out of the thermal expansion chamber 80 into the compression chamber 90. The cross-sectional area is maximized so that the gas in the thermal expansion chamber 80 is easily introduced into the compression chamber 90 side, and the check valve at the upper portion, that is, the cylinder rod 30, for cooling the gas in the compression chamber 90. It is advantageous to circulate to the (61) side.

In the embodiment of the present invention, the first pressure reducing valve 50 is formed by forming the opening hole 63 on the cylinder rod 30 side, but in another embodiment, the opening hole 63 is formed on the inner wall side of the cylinder 35. It is also possible to form and install.

In addition, the first pressure reducing valve 50 may be adjusted to adjust the elastic force of the spring 51 to operate at a constant pressure, thereby adjusting the pressure of the thermal expansion chamber 80.

That is, it is possible to set the threshold pressure at which the first pressure reducing valve 50 is opened by adjusting the elastic force of the spring 51 of the first pressure reducing valve 50.

For example, when the first pressure reducing valve 50 is configured by using a spring 51 having an elastic force of less than 20 bar, when a pressure of 20 bar or more is applied to the valve opening and closing part 55 of the first pressure reducing valve 50, As the spring 51 contracts without being able to withstand the pressure, the valve opening and closing portion 55 moves to the compression chamber 90 side, and eventually the opening hole 63 of the separation wall 60 is opened.

When the opening hole 63 is opened, the gas introduced into the compression chamber 90 is mixed with the gas of the compression chamber 90 and cooled. At this time, a large amount of gas is introduced from the thermal expansion chamber 80 so that the gas pressure of the compression chamber 90 is increased. Since this can be higher than necessary, a second pressure reducing valve (pressure reducing valve of the piston 70) 71 for adjusting the pressure of the compression chamber 90 is configured.

The second pressure reducing valve 71 is installed on the piston 70 disposed behind the blocking unit 100, that is, the rear of the compression chamber 90, in order to prevent the ground to the gas circuit breaker tank, the compression chamber 90 When the pressure of) rises above a certain value, it operates and opens.

For example, the second pressure reducing valve 71 may be set to operate at 15 bar or more, and when the pressure in the compression chamber 90 reaches 15 bar, the second pressure reducing valve 71 of the piston 70 opens and opens the piston. 70, the gas is discharged to the rear.

When the pressure of the thermal expansion chamber 80 becomes lower than the compression chamber as time passes, the check valve 61 is opened in the separation wall 60 and the cooled gas of the compression chamber 90 is again fixed arc contact 40 and the movable arc. Sprayed by the arc between the contacts 20.

Hereinafter, the operating state of the embodiment according to the present invention configured as described above are as follows.

5 is an operation diagram showing an operating state of an embodiment according to the present invention.

In general, when the fault current is large, the check valve 61 is closed while the gas pressure of the thermal expansion chamber 80 becomes greater than the gas pressure of the compression chamber 90 due to the gas flowed back by arc energy. The gas flowed back to 80 is cooled in the thermal expansion chamber 80 and injected again between the fixed arc contact 40 and the movable arc contact 20 to extinguish the arc and block the fault current.

In the case where the arc energy is excessively large, the gas pressure in the thermal expansion chamber 80 is excessively high due to the gas flowed back by the arc energy, so that the first pressure reducing valve 50 according to the present invention operates. The opening hole 63 of the dividing wall 60 between the thermal expansion chamber 80 and the compression chamber 90 is opened.

As the first pressure reducing valve 50 is opened, the gas introduced into the compression chamber 90 from the thermal expansion chamber 80 is mixed with the gas of the compression chamber 90 and cooled, and as time passes, the thermal expansion chamber 80 When the pressure is lower than the compression chamber 90, the check valve 61 of the separation wall 60 is opened, and the cooled gas of the compression chamber 90 is returned to the arc furnace between the fixed arc contact 40 and the movable arc contact 20. It is injected to extinguish the arc and cut off the fault current.

As described above, the present invention provides that the pressure in the thermal expansion chamber 80 is more than necessary due to excessively large arc energy (for example, the backflow gas is cooled in the thermal expansion chamber 80, and then the fixed arc contact point 40 and the movable arc are used again). When the pressure is greater than the pressure required to be injected between the contacts 20) the pressure reducing valve 50 installed in the separation wall 60 is operated to adjust the pressure of the thermal expansion chamber 80, accordingly the manipulator and the blocking unit 100 The stress is reduced and the thermal gas expanded to a high temperature can be cooled, thereby preventing the fault current.

Accordingly, the apparatus for regulating pressure in the thermal expansion chamber of the gas circuit breaker according to the present invention is capable of blocking fault currents of various sizes, particularly large currents, thereby increasing the breaking performance.

While the conventional circuit breaker obtains only the pressure necessary for arc extinguishing by simply mechanical compression in the compression chamber 9, the present invention provides not only the pressure required for arc extinguishing in the compression chamber 90, but also in case of an excessively large arc energy. The effect that a compression chamber acts as a 2nd thermal expansion chamber which assists the thermal expansion chamber 80 can be acquired.

Although the present invention has been illustrated and described with respect to specific preferred embodiments, the invention is not limited to these embodiments, and the invention is claimed in the claims by one of ordinary skill in the art to which the invention pertains. It includes all embodiments of the various forms that can be carried out without departing from the spirit of the invention.

1 is a schematic diagram showing a conventional circuit breaker structure

Figure 2 is a block diagram showing an embodiment of the thermal expansion chamber pressure regulating device of the gas circuit breaker according to the present invention

3 is a partial perspective view showing the main part of the present invention;

4 is an enlarged view illustrating region 'A' of FIG. 2.

5 is an operation diagram showing an operating state of an embodiment according to the present invention;

<Description of the symbols for the main parts of the drawings>

20: movable arc contact 30: cylinder rod

35: cylinder 40: fixed arc contact

50: first pressure reducing valve (pressure reducing valve of the separating wall)

51: spring 53: spring support

53a: through hole 55: valve opening and closing portion

57: guide shaft

60: separating wall 61: check valve

63: opening hole

70: piston 71: second pressure reducing valve

80: thermal expansion chamber

90: compression chamber

100: breaker

Claims (3)

The first pressure reducing valve 50 is installed in the separation wall 60 between the thermal expansion chamber 80 and the compression chamber 90, and when the gas pressure of the thermal expansion chamber 80 becomes greater than or equal to the threshold value, the first pressure reducing valve 50 is provided. The first pressure reducing valve 50 has a spring 51, a guide shaft 57 penetrating the spring 51, the valve opening and closing portion 55 is installed to be movable; Thermal expansion chamber pressure regulating device of the gas circuit breaker, characterized in that it comprises a spring support (53) is formed and fixed to the through-hole (53a) is communicated with the guide shaft (57). delete The method according to claim 1, The opening hole 63 of the dividing wall 60 opened and closed by the first pressure reducing valve 50 is formed in the shape of an arch tapered from the compression chamber 90 side to the thermal expansion chamber 80 side. Thermal expansion chamber pressure regulator.

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