KR20100081006A - Safety valve bypass element guard - Google Patents

Abstract

PURPOSE: A SBE(Safety valve Bypass Element) guard for a boiler safety valve is provided to carry out reliability inspection of an SBE during a normal operation of a generating station by selectively controlling high-pressure hydraulic fluid. CONSTITUTION: A SBE guard for a boiler safety valve comprises a path opening/closing unit, and a supply pipe line, and a housing. The path opening/closing unit supplies and blocks high pressure hydraulic fluid to an SBE(120). The supply pipe line is connected between the actuator and the SBE and supplies the hydraulic fluid from an actuator to the SBE. The housing is integrally formed with the path opening/closing unit.

Description

Safety guard of boiler safety valve {Safety Valve Bypass Element Guard}

The present invention relates to the guard (Guard) of the SBE of the boiler safety valve, and more specifically, when the failure of the SBE mounted to the safety valve to discharge the steam to the outside when the steam pressure of the boiler excessively, the boiler This is to replace the SBE during normal operation of the SBE, and to the SBE guard of the boiler safety valve to facilitate the replacement of the failed SBE.

Conventionally, it was not possible to check whether a failure of the SBE during operation, the SBE guard of the safety valve according to the present invention is characterized in that it is possible to determine whether the failure of the SBE during operation.

In general, a standard coal-fired power plant has a total of eight safety valves, four for main steam and four for reheat steam, for each generator.

Four main steams are installed at the outlet of the superheater and four reheat steams are installed at the two outlets at the inlet side of the reheater.

1 is a perspective view of a safety valve equipped with a SBE used in a typical power plant.

The safety valve 100 functions to discharge gas to the outside when the steam pressure in the boiler is excessively increased.

In the safety valve 100, one servo valve 110 and three safety valve bypass elements (SBE) 120 are positioned in a 90 ° direction, respectively, and include an operation cylinder (not shown).

Servo system refers to a control system that controls the displacement of the position, orientation, posture, etc. of the object to follow the change of the desired target value, and the servo valve controls the actuator by adjusting the hydraulic pressure to obtain the desired mechanical displacement in the servo system. Play a role.

Such servo valves are applied to various industrial fields such as power plants, shipbuilding, and aviation industries.

The safety valve of such a power plant is an essential device to prevent an accident when the steam pressure in the boiler is excessively increased, and three safety valves 120 are installed in each safety valve so that the safety valve is operated immediately when the steam pressure rises. In case of failure of SBE 120, it should be replaced immediately.

However, in order to replace the SBE (120) in the prior art, the output of the hydraulic oil is required to reduce the output, according to the type of safety valve for the SBE replacement work according to the type of safety valve 500MW minimum output from the minimum 420MW to 300MW However, in order to prevent power system instability and profit reduction, the SBE is being replaced while maintaining the rated output of 500MW after the stopper is installed.

In this case, the safety valve function does not operate during the replacement time of the SBE. In case of system frequency sudden change, there is a risk of a large-scale accident of the power plant due to the large loss of boiler tube.

The present invention has been made to solve the above-mentioned problems, and includes a device that can supply and cut off the high-pressure hydraulic fluid to replace the SBE in the normal operation of the power plant, it is possible to check the health of the SBE during the normal operation of the power plant It is an object of the present invention to provide a SBE guard of a boiler safety valve.

SBE guard of the safety valve of the boiler according to the present invention, to remove and attach during normal operation of the power plant of the safety valve bypass element (SBE) mounted on the safety valve to discharge the steam to the outside when the steam pressure of the boiler is excessively increased A SBE guard of a safety valve for a boiler, comprising: a flow path opening and closing device for supplying and blocking a high pressure hydraulic fluid to the SBE; It is connected between the actuator (Actuator) and the SBE, characterized in that it comprises a supply line for supplying the hydraulic fluid from the actuator (Actuator) to the SBE.

SBE guard of the boiler safety valve according to the invention is characterized in that it further comprises a housing formed integrally with the flow path opening and closing device for supplying and blocking the high-pressure hydraulic fluid.

According to the SBE guard of the boiler safety valve of the present invention as described above has the following effects.

SBE of the boiler safety valve, which maintains the function of the boiler safety valve even when the SBE of the boiler safety valve is replaced during normal operation of the power plant, and includes a flow path opening and closing device for detaching and attaching the SBE from the actuator. By providing a guard, it is possible to solve problems such as generator output reduction caused by replacing the SBE of the boiler safety valve during normal operation of a conventional power plant and providing economic risks such as suspension of function as a safety valve of the boiler safety valve and providing safety threats. There is an advantage that can be prevented.

Therefore, even when the SBE is replaced during normal operation of the power plant, there is an effect that can eliminate the power deterioration or safety threats.

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

For reference, among the configurations of the present invention to be described below, the same configuration as the prior art will be referred to the above-described prior art, and a detailed description thereof will be omitted.

1 is a perspective view of a safety valve equipped with a SBE used in a general power plant.

Figure 2 is a hydraulic circuit diagram of the thermal power plant boiler safety valve used in the present invention

Figure 3a is a hydraulic circuit diagram showing a state during normal operation of the thermal power plant boiler used in the present invention

Figure 3b is a hydraulic circuit diagram showing the state of operation of the thermal power plant boiler safety valve used in the present invention

Figure 3c is a hydraulic circuit diagram showing a state when the SBE of the thermal power plant boiler in which the present invention is used does not operate.

4A is a perspective view of a safety valve equipped with SBE of a boiler safety valve in a thermal power plant using the present invention,

Figure 4b is a cross-sectional view of the first connecting portion and the second connecting portion connecting the SBE guard and the SBE of the present invention,

4C is a hydraulic circuit diagram in which an SBE guard is mounted between an actuator and an SBE according to a preferred embodiment of the present invention.

The safety valve 100 of the boiler is configured to include a servo valve 110, a working cylinder 220 and a SBE 120.

The operation cylinder 220 serves to open and close the valve according to whether the pressure of the steam rises.

The working cylinder 220 is a double acting cylinder and includes a piston inside the cylinder, and the piston is connected to the disk 280 at the lower side.

Double-acting cylinders, unlike single-acting cylinders, contain ports for supplying and discharging to both sides of the piston inside the cylinder.

As shown in FIG. 2, the operation cylinder 220 includes a cylinder upper flow path 210 and a cylinder lower flow path 215 to which hydraulic pressure is supplied from the servo valve 110 to upper and lower cylinders.

The cylinder upper flow path 210 and the cylinder lower flow path 215 may be flow paths through which hydraulic oil is supplied, and also flow paths through which hydraulic fluid is discharged.

The operating cylinder 220 is a double-acting cylinder and when hydraulic oil is supplied to the upper cylinder flow passage 210 under the flow control of the servo valve 110, the piston in the cylinder is operated downward, and the operating oil under the cylinder is the lower cylinder flow passage 215. Is discharged through.

This operation process works in reverse when the piston must be operated upwards.

The servovalve 110 controls the hydraulic oil to operate the working cylinder 220.

The servo valve 110 shown in FIG. 2 is a four-port three-position servo valve 110. Therefore, there are four connection ports through which hydraulic oil is supplied and discharged, and the valve switching positions are three.

The servo valve 110 includes a hydraulic oil supply port for supplying hydraulic oil from a hydraulic pump and a return port for returning to an oil tank, and a cylinder upper flow path 210 and a cylinder for supplying or discharging hydraulic pressure for operation of the operation cylinder 220. There is one port coupled to the lower flow path 215.

In addition, the servo valve 110 supplies the operating oil to the upper cylinder flow path 210 to operate the operation cylinder 220 and returns to the oil tank through the lower cylinder flow path 215, the position to stop the supply of the hydraulic oil And a position of supplying hydraulic oil to the lower cylinder flow passage 215 to operate the operating cylinder 220 and returning it to the oil tank through the upper cylinder flow passage 210 to control the operating cylinder 220 by the selective supply of the hydraulic oil.

SBE 120 serves to allow the safety valve to operate quickly in case the steam pressure in the boiler rises excessively.

The SBE 120 includes an SBE upper flow path 230, a SBE lower flow path 235, a check valve 240, a solenoid valve 250, a flow control valve 260, and a bypass line 270. It is.

The SBE upper flow path 230 is a passage for rapidly discharging the hydraulic oil in the upper cylinder of the working cylinder 220, the SBE lower flow path 235 is a hydraulic cylinder flowed into the SBE upper flow path 230 operating cylinder 220 It is a passage to discharge to the lower cylinder of the).

Therefore, when the boiler is normally operated, the working oil is transmitted from the check valve 240 to the flow control valve 260 through the solenoid valve 250.

The solenoid valve 250 adjusts the hydraulic oil to operate the operating cylinder 220 rapidly when the steam pressure in the boiler rises above the reference value.

The solenoid valve 250 as described above forms a magnetic field when a current flows through the cylindrical coil, and controls the hydraulic oil by opening and closing the valve by the magnetic field formed at this time.

The solenoid valve 250 used in the SBE 120 is a three-port two-position valve, and when the solenoid is excited, the hydraulic fluid flows from the SBE upper flow passage 230 through the check valve 240 and the solenoid valve 250 to the flow control valve. 260 is supplied.

The solenoid valve 250 is operated by the compression spring when the current is cut off to change the hydraulic oil movement path to discharge the hydraulic oil from the flow control valve 260.

The flow control valve 260 controls the hydraulic oil of the bypass line 270 to move through the SBE lower flow passage 235.

The flow control valve 260 prevents the hydraulic fluid from moving from the bypass line 270 by closing the valve by the hydraulic spring flowing through the compression spring and the solenoid valve 250 in the valve when the boiler is normally operated.

The flow regulating valve 260 is a poppet valve having a cylindrical shape, and the piston inside the valve has a cross-sectional area of the bypass line 270 side smaller than that of the solenoid valve 250 side, so that the solenoid may be added even if the pressure of the compression spring is added. In this state, the valve is always closed.

Therefore, when the current is cut off from the solenoid, the hydraulic oil of the flow control valve 260 is discharged to increase the pressure on the bypass line 270 side, so that the flow control valve 260 is opened, and the hydraulic oil flows from the bypass line 270. It flows into the SBE lower flow path 235.

The bypass line 270 flows the hydraulic oil supplied from the SBE upper flow path 230 to the SBE lower flow path 235 so that when the pressure in the boiler rises above the reference value, the working cylinder 220 is immediately moved upward to discharge steam. Allow for discharge.

The present invention is a device capable of replacing a safety valve bypass element (SBE) mounted on a safety valve for discharging steam to the outside when the steam pressure of the boiler is excessively increased, the supply of high-pressure hydraulic oil to the SBE Provides a SBE guard of the boiler safety valve, characterized in that the overhaul and shutdown and the integrity of the SBE can be checked during normal plant operation.

Hereinafter, a hydraulic circuit diagram of a thermal power plant boiler safety valve using the present invention will be described in detail with reference to the drawings.

First, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

3A is a hydraulic circuit diagram illustrating a state in normal operation of a boiler.

When the boiler is normally operated, the operation cylinder 220 of the safety valve 100 is controlled by the servovalve 110.

Since the servo valve 110 is capable of three-position control as described above, when the safety valve 100 does not operate, the servo valve 110 supplies hydraulic oil through the upper cylinder flow path 210 and discharges the hydraulic oil through the lower cylinder flow path 215. Return to the oil tank.

In addition, the hydraulic oil supplied through the SBE upper flow path 230 is supplied to the solenoid valve 250 through the flow path a through the check valve 240, the solenoid valve 250 is always excited in the case of normal operation of the boiler Therefore, the hydraulic oil is supplied to the flow rate control valve 260 through the flow path d.

At this time, the poppet valve of the flow control valve 260 blocks the bypass line 270 by the pressure of the hydraulic oil so that the hydraulic oil is not supplied from the bypass line 270 to the SBE lower passage 235.

Therefore, when the boiler is operating normally, the operating oil is supplied to the upper cylinder of the operating cylinder 220 and the operating cylinder 220 is discharged to the lower cylinder to apply pressure downward.

3B is a hydraulic circuit diagram showing a state in operation of a boiler safety valve.

When the steam pressure inside the boiler rises above the reference value, the safety valve 100 is operated. At this time, the servo valve 110 is controlled to a position at which the hydraulic oil is not supplied to the cylinder upper flow passage 210 and the cylinder lower flow passage 215. .

At this time, when the excessive pressure acting on the disk 280 is sensed by the controller (not shown) to cut off the current acting on the solenoid valve 250 while the solenoid valve 250 flows the hydraulic oil in the flow control valve 260 It is operated to a position to discharge the supplied hydraulic oil supplied through (d) to the SBE lower passage 235 through the line (b) and line (c).

When the pressure acting on the poppet valve of the flow control valve 260 is removed, the pressure of the bypass line 270 increases and the poppet valve opens.

Therefore, the hydraulic oil contained in the upper cylinder of the working cylinder 220 flows into the SBE 120 through the SBE upper flow path 230 and the working oil is operated through the bypass line 270 and the SBE lower flow path 235. The safety cylinder 100 is opened by being supplied to the lower cylinder of the cylinder 220 so that the working cylinder 220 is pressurized upward.

3C is a hydraulic circuit diagram showing a state when the SBE does not operate.

When the SBE 120 operates normally, as shown in FIGS. 3A and 3B, when the pressure in the boiler is lower than the reference value, the flow path of the flow control valve 260 is closed and only when the pressure in the boiler rises above the reference value. 120 operates so that the safety valve 100 is opened.

However, when the SBE 120 is not normally operated as shown in FIG. 3C, even though the pressure inside the boiler is maintained below a reference value, the hydraulic fluid may be supplied from the servo valve 110 to the upper cylinder flow path 210 of the SBE 120. Flow control valve 260 is opened to the hydraulic fluid is discharged to the lower cylinder through the bypass line 270 and the SBE lower flow path 235, the safety valve 100 is opened by the steam pressure acting on the disk 280 do.

The reason why the flow path of the flow regulating valve 260 is opened may be caused by an abnormality of the flow regulating valve 260 itself or a malfunction of the solenoid valve 250.

4A and 4B are perspective and cross-sectional views of SEB 120 and SBE guard 300 in accordance with a preferred embodiment of the present invention.

As shown in FIGS. 4A and 4B, an SBE guard 300 is installed between the safety valve 100 and the safety valve bypass element (SBE) 120.

SBE guard 300 is composed of a rectangular cylindrical housing, including a first connection portion 10 in the form of a male coupling portion for opening and closing the supply line and the connection line 17 and the connection line 17 therein. It is composed.

The first connection portion 10 is composed of the pressing rod 12, the main body 11, the ball 15, the spring 16, the packing 13 and is connected to the connection pipe 17.

A contact portion 12a is formed at one end of the pressing rod 12, and a first flow passage 20 and a second flow passage 21 are formed in the pressing rod 12.

The first flow path 20 and the second flow path 21 communicate with each other.

The contact portion 12a is formed such that the cross-sectional area becomes narrower gradually toward the end of one end (X1 direction) of the pressing rod 12, and at the same time, the tapered portion 12b is formed.

 When the push rod 12 is accommodated in the push rod accommodating space 33 of the second connecting portion 30 described later, the male screw portion 14 and the female screw portion 32 of the connecting nut 35 are screwed together. The tapered portion 12b is in contact with the nut tapered portion 21 of the connecting nut 35.

The other end (X2 direction) of the pressing rod 12 is in contact with the ball 15.

The pressing rod 12 is pressed toward the one end side (X1 direction) of the pressing rod by the spring 16 with the ball 15.

That is, the push rod 12 is movable toward the connecting pipe 17 when an external force is applied from one end side of the push rod to the other end side of the push rod.

The main body 11 includes a pressing rod accommodation space 22, a male screw portion 14, and a first relay path 24.

The pressing rod receiving space 22 is accommodated in a state where the contact portion 12a of the pressing rod 12 protrudes to the outside, and the pressing rod receiving space 22 has a first flow path in a state where the pressing rod 12 is accommodated. 20 and the second flow path 21 are formed in communication.

The ball 15 is arranged in the first relay path 24, and closes the pressing rod accommodation space 22 and the first relay path 24 by the pressure of the spring 16.

The spring 16 is disposed in the first relay path 24 similarly to the ball 15 and presses the push rod 12 and the ball 15 as described above.

The connecting conduit 17 has a second relay path 23.

SBE 120 is formed with a second coupling portion 30 of the female coupling portion shape.

The connection nut 35 is rotatably installed in the second connection part 30.

An internal thread portion 32 and a nut taper portion 21 are formed inside the connection nut 35.

The ends of the SBE upper flow path 230 and the SBE lower flow path 235 protrude inside the connection nut 35.

 When the SBE guard and the SBE 120 are connected, the male threaded portion 14 of the first connecting portion 10 and the female threaded portion 32 of the connecting nut 35 are screwed together, first, the SBE upper flow path 230. And an end portion of the SBE lower channel 235 is inserted into the first channel 20.

Then, the contact taper portion 12b contacts the nut taper portion 21 of the second connecting portion 30, and the pressing rod 12 and the ball 15 react with the spring force of the spring 16 to connect the pressing rod. It begins to move towards the conduit 17.

As a result, the SBE upper flow path 230 and the SBE lower flow path 235 communicate with the first flow path 20 and the second flow path 21, and at the same time, the push rod accommodation space 22 and the first relay path 24. ) Is also communicated.

When the SBE guard and the SBE 120 are separated in order to replace the SBE, the reverse order of the above procedure is made, and the pressing rod receiving space 22 and the first relay path 24 are separated by the ball 15. It is closed.

The first connecting portion 10 and the second connecting portion 30 may be implemented by various configurations that can open and close the flow path.

Not limited to the above-described example, the first connection portion 10 may be made of a flow control valve of Korea Patent Publication No. 2008-0094339, or after closing the inside of the first connection portion 10 by a switch Of course, the SBE guard and the SBE 120 can be separated.

4C is a hydraulic circuit diagram in which an SBE guard 300 is mounted between an actuator and an SBE 120 according to a preferred embodiment of the present invention.

SBE guard 300 is configured to include a flow path opening and closing device for opening and closing the supply line and the connecting line 17 therein.

A pressure indicator (PI) is installed between the downturn valve 320 and the connection pipe 17 installed inside the SBE guard 300.

In order for the SBE 120 to operate normally, the SBE guard 300 is mounted between the actuator and the SBE 120 as shown in FIG. 4C.

At this time, the supply line and the connection line 17 of the SBE guard is directly connected between the actuator (Actuator) and the SBE (120) to form a closed circuit.

In addition, the hydraulic oil supplied through the SBE upper flow path 230 is supplied to the solenoid valve 250 through the check valve 240, the solenoid is always excited in the case of normal operation of the boiler, so the hydraulic fluid is supplied to the flow control valve 260 To supply.

At this time, the poppet valve of the flow control valve 260 blocks the bypass line 270 by the pressure of the hydraulic oil so that the hydraulic oil is not supplied from the bypass line 270 to the SBE lower passage 235.

Therefore, when the boiler is operating normally, the operating oil is supplied to the upper cylinder of the operating cylinder 220 and the operating cylinder 220 is discharged to the lower cylinder to apply pressure downward.

The SBE guard maintains the function of the power plant safety valve during normal operation and can attach and remove the SBE 120 from the actuator.

First, in order to separate the SBE from the actuator (Actuator), as shown in FIG. 4C, the flow paths are blocked by changing the positions of the up and down direction switching valves 310 and 320 of the SBE guard, which are the channel opening and closing devices.

Thereafter, when the male thread portion 14 of the first connecting portion 10 and the female thread portion 32 of the connecting nut 35 are separated, the pressing rod accommodation space 22 and the first are formed by the ball 15 as shown above. One relay path 24 is closed.

Then, after the broken SBE 120 is separated from the SBE guard 300, the prepared new SBE is attached to the SBE guard 300.

In a state in which the SBE 120 is installed in the SBE guard 300, the protective case, which is a cylindrical cover, is exposed to prevent the first connection part 10 and the second connection part 30 from being exposed to the outside to be loosened. It may be installed outside the first connecting portion 10 and the second connecting portion 30.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention.

Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments.

The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

As described above, the SBE guard of the boiler safety valve includes a device capable of supplying and cutting off the high-pressure hydraulic fluid so that the SBE can be replaced even in the normal operation state of the power plant. Suitable for providing

1 is a perspective view of a safety valve equipped with a SBE used in a typical power plant

2 is a hydraulic circuit diagram of a thermal power plant boiler safety valve used in the present invention

Figure 3a is a hydraulic circuit diagram showing a state during normal operation of the thermal power plant boiler used in the present invention

Figure 3b is a hydraulic circuit diagram showing the state of operation of the thermal power plant boiler safety valve used in the present invention

Figure 3c is a hydraulic circuit diagram showing a state when the SBE of the thermal power plant boiler is not used in the present invention

Figure 4a is a perspective view of a safety valve equipped with the SBE of the boiler safety valve in the thermal power plant in which the present invention is used

Figure 4b is a cross-sectional view of the first connecting portion and the second connecting portion connecting the SBE guard and the SBE of the present invention

4C is a hydraulic circuit diagram in which an SBE guard is mounted between an actuator and an SBE according to a preferred embodiment of the present invention.

** Description of symbols for the main parts of the drawing **

10: first connection portion 11: main body

12: push rod 15: ball

16: spring 17: discharge line

20: first euro 21: second euro

30: second connection portion 36: connection nut

100: boiler safety valve 110: servo valve

120: SBE 210: cylinder upper flow path

215: cylinder lower flow path 220: working cylinder

230: SBE upper flow path 235: SBE lower flow path

240: check valve 250: solenoid valve

260: flow control valve 270: bypass line

280: Disc 300: SBE Guard

Claims (2)

In the SBE guard of the boiler safety valve for removing and attaching the safety valve bypass element (SBE) mounted on the safety valve to discharge steam to the outside when the steam pressure of the boiler is excessively increased, A channel opening / closing device for supplying and cutting off the high pressure hydraulic oil to the SBE; SBE guard of the boiler safety valve is connected between the actuator (Actuator) and the SBE and comprises a supply line for supplying the hydraulic fluid from the actuator (Actuator) to the SBE. The method of claim 1, SBE guard of the boiler safety valve SBE guard of the boiler safety valve further comprises a housing formed integrally with the flow opening and closing device for supplying and blocking the high-pressure hydraulic fluid.

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