KR101195935B1 - Apparatus of Electrical trip solenoid valve isolation block - Google Patents

Abstract

The present invention relates to a blocking block device and method for an electric trip solenoid valve (ETSV) of a turbine emergency stop system that provides a quick closing function of a turbine valve in the event of an abnormal occurrence of a secondary turbine protection facility of a nuclear power plant.
The present invention provides a blocking block device for an electrical trip solenoid valve (ETSV) of a turbine emergency stop system of a power plant using a GE type turbine, wherein the control oil provided to the turbine emergency stop system is received from a turbine control oil pump. A P port for supplying an electrical trip solenoid valve (ETSV); A T port receiving the control oil through the P port and supplying the control oil to an electric trip valve (ETV) to operate the ETV; A B port for draining control oil supplied to the electric trip valve (ETV); And a control bolt provided at one side of the control oil flow path of the P port to open and close the control oil flow path of the P port. It includes, and to block the control oil pressure provided from the turbine control oil pump during replacement due to the ETSV failure.

Description

Electrical trip solenoid valve isolation block

The present invention relates to a blocking block device for an electric trip solenoid valve (ETSV) of a turbine emergency stop system that provides a quick closing function of a turbine valve in the event of an abnormal occurrence of a secondary turbine protection facility of a nuclear power plant.

Conventionally, an electric trip solenoid valve (hereinafter referred to as ETSV) serves as a pilot valve for controlling an electric trip valve (hereinafter referred to as an ETV). Since there is no separation means between the ETV during normal operation, the ETV is abnormally operated when an ETSV malfunction occurs. It is designed to make emergency stop.

However, according to the prior art, it is reasonable to operate the ETV by generating a turbine protection signal when symptoms such as low pressure of Lube Oil, which may affect the turbine operation, but there is no need for maintenance of individual equipment such as internal leakage of the ETSV during normal operation. Therefore, there is a problem that the power plant is stopped and becomes a factor that hinders power generation efficiency.

In order to solve this problem, an object of the present invention is to prevent unnecessary power plant shutdown due to simple failure of single equipment (ETSV), not normal turbine emergency stop condition, high pressure (about 1600psi) to ETV and ETSV during normal operation. Since the control valve of the turbine valve is always pressurized, in order to separate the ETSV from the ETV, the control oil flow path from the ETV to the ETSV is blocked so that the high pressure control oil is not drained.

In addition, the opening degree of the shutoff valve of the ETSV shutoff block must be identifiable from the outside, and the control oil is not leaked to the outside by the internal leakage.

The present invention provides a blocking block device for an electrical trip solenoid valve (ETSV) of a turbine emergency stop system of a power plant using a GE type turbine, wherein the control oil provided to the turbine emergency stop system is received from a turbine control oil pump. A P port for supplying an electrical trip solenoid valve (ETSV); A T port receiving the control oil through the P port and supplying the control oil to an electric trip valve (ETV) to operate the ETV; A B port for draining control oil supplied to the electric trip valve (ETV); And a control bolt provided at one side of the control oil flow path of the P port to open and close the control oil flow path of the P port. It includes, and to block the control oil pressure provided from the turbine control oil pump during replacement due to the ETSV failure.

According to the present invention, when the ETSV single device failure during operation of the power plant inevitably had to perform maintenance after power generation stop, there is an effect that can increase the efficiency of the power plant by providing a replacement means during normal operation.

1 is a flow chart of the turbine valve control oil of the turbine emergency stop system including the present invention.
Figure 2 is a side view of the electrical trip solenoid valve blocking block device according to a preferred embodiment of the present invention.
Figure 3 is an internal view of the electrical trip solenoid valve blocking block device according to an embodiment of the present invention.
Figure 4 is a perspective view of the electrical trip solenoid valve blocking block device according to an embodiment of the present invention.
Figure 5 is a control oil flow diagram showing the opening and closing of the shut-off valve of the blocking block device of the electrical trip solenoid valve blocking block device according to an embodiment of the present invention.
Figure 6 is a view of the blocking block utilization procedure of the electrical trip solenoid valve blocking block device according to an embodiment of the present invention.

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

And the following will be described a preferred embodiment of the present invention, but the technical idea of the present invention is not limited to this, but can be variously modified and implemented by those skilled in the art.

The present invention provides a blocking block device for an electrical trip solenoid valve (ETSV) of a turbine emergency stop system of a power plant using a GE type turbine, wherein the control oil provided to the turbine emergency stop system is received from a turbine control oil pump. A P port for supplying an electrical trip solenoid valve (ETSV); A T port receiving the control oil through the P port and supplying the control oil to an electric trip valve (ETV) to operate the ETV; A B port for draining control oil supplied to the electric trip valve (ETV); And a control bolt provided at one side of the control oil flow path of the P port to open and close the control oil flow path of the P port. It includes, characterized in that to cut off the control oil pressure provided from the turbine control oil pump during replacement due to the ETSV failure.

Preferably the P port is characterized in that formed by a multi-joint pipe.

Also preferably, the position indicator for indicating the opening position of the cutoff valve in the blocking block device; characterized in that it further comprises.

In addition, preferably the control bolt protection cap for blocking external leakage when the leakage occurs in the control bolt portion; characterized in that it further comprises.

More preferably, the position indicator is configured such that the electrical trip solenoid valve (ETSV) is positioned at "OPEN" by an adjustment bolt of the electrical trip solenoid valve blocking block device during normal operation, and when the electrical trip solenoid valve (ETSV) is replaced. , Characterized in that to be positioned in the "CLOSE" by the adjustment bolt.

First, Figure 1 is a flow chart of the turbine valve control oil of the turbine emergency stop system including the present invention. Line 10 in which 1600 psi pressure of control oil is provided to the turbine emergency stop system in the turbine control oil pump, and MTV (Mechanical Trip Valve) which performs emergency turbine stop function by draining the turbine valve control oil when the mechanical turbine trip signal is input. ), The control oil flow path branched at the rear of the MTV, and the control oil supply line 10 and the other flow line are provided to the MLSV line 30, which supplies the control oil to the MLSV (Mechanical Lockout Solenoid Valve) and the ELSV (Electrical Lockout Solenoid Valve). The hydraulic supply line 40 to prevent the turbine control oil from being lost even when the control oil flow path is switched during the excitation of the MLSV, and the MLSV function of providing the control oil to the ETV regardless of the MTV operation caused by a mechanical trip signal during excitation. 50) When the ETSV (Electric Trip Solenoid Valve) breaks down during normal operation, the control oil shut-off function can be performed to replace the ETSV without affecting the supply of the turbine control oil. Electrical trip solenoid valve block (ETSV Isolation Block) (60), ETV control to perform the emergency turbine stop function by operating the electrical trip valve (ETV) to drain the turbine control oil when the electrical turbine trip signal input An electric trip solenoid valve (ETSV) 70 that is a valve, an ETV 80 that operates by a control oil signal provided during ETSV excitation to provide a turbine control oil to a turbine valve, and an ETV by an electrical trip signal during excitation. And an electric lockout solenoid valve (ELSV) 90 that performs a function of providing control oil to the turbine valve regardless of the ETSV operation, and a hydraulic line providing the turbine valve control oil provided from the turbine emergency stop system to the turbine valve 100. ), Mechanical turbine stop circuit and electrical turbine stop circuit.

Figure 2 is a side view of the electrical trip solenoid valve blocking block device according to an embodiment of the present invention.

Referring to FIG. 2, an electrical trip solenoid valve blocking block device according to a preferred embodiment of the present invention is installed between an ETV and an ETSV to separate and maintain the ETSV from the ETV without affecting the power plant output operation in the event of an ETSV failure or leakage. Make it possible.

At this time, the opening degree of the internal shutoff valve should be checkable from the outside of the blocking block, and the opening degree should be adjustable through the adjustment bolt.

Figure 3 is an internal view of the electrical trip solenoid valve blocking block device according to an embodiment of the present invention, it comprises a control bolt 310, adjustment bolt protection cap 320, the position indicator 330.

Figure 4 is a perspective view of the electrical trip solenoid valve blocking block device according to an embodiment of the present invention. In Figure 4, ① is a position indicator 330, ② is a direction indicator, ③ is an adjustment bolt protective cap 320, ④ represents an adjustment bolt 310.

The adjusting bolt 310 is configured to manipulate the opening degree of the shutoff valve inside the shutoff block.

This adjustment bolt rotates the position indicator 330 counterclockwise to position the "OPEN" during normal operation, and rotates the position indicator 330 clockwise to position the "CLOSE" during ETSV replacement.

The control bolt protection cap 320 serves to block external leakage when the adjustment bolt site leakage occurs.

Position indicator 330 is a configuration for indicating the opening position of the blocking valve inside the blocking block.

And the direction indicator shows the direction of movement of the shutoff valve when operating the adjusting bolt.

Referring to the operation of the electrical trip solenoid valve blocking block device according to an embodiment of the present invention.

During normal operation, the ETSV blocking block is open, and the control oil is input through the P port to operate the ETV through the T port.

When the ETSV is not excited, the control oil input to the P port is cut off, and the control oil supplied to the ETV is drained to the B port via the T port.

However, even when the ETSV is not excited, when the ETSV is separated from the ETV, the high pressure control oil is ejected to the outside through the P port, so that the E port is disconnected after the P port is blocked by manipulating the control bolt of the blocking block.

FIG. 5 is a control flow chart showing the opening and closing times of a shutoff valve of a shutoff block device of an electrical trip solenoid valve shutoff block device according to an exemplary embodiment of the present invention.

FIG. 6 is a diagram illustrating a blocking block utilization procedure of an electrical trip solenoid valve blocking block device according to an exemplary embodiment of the present invention.

When the oil low pressure alarm occurs in the turbine emergency stop system ETS (Emergensy Trip System) due to a pressure drop below 100 kg / cm2 of the ETS control oil, the ELSV is excited (S2).

Here, if the ETS pressure is normally restored after ELSV excitation, it is determined that the ETSV / ETV has failed.

If the ETS pressure is normally restored after ELSV excitation in step S2, the ETSV is replaced (S4).

After replacing the ETSV, when the control oil low pressure alarm is removed, the ELSV is de-energized and normal operation continues (S6).

If the control oil low pressure alarm is not removed in the step (S6), the output deceleration and power generation stop procedure are performed.

On the other hand, after exciting the ELSV in the step (S2), look at the case where the ETS pressure is not normal recovery, as follows.

After the ELSV is excited in the step (S2), if the ETS pressure is not normally restored, the ELSV is not excited and then the MLSV is excited (S12).

At this time, if the ETS pressure is normally restored after the MLSV excitation, it is determined that the MTSV / MTV has failed.

After exciting the MLSV in the step (S12), if the ETS pressure is normally restored, the output deceleration and power generation stop procedure are performed.

After the excitation of the MLSV in the step S12, if the ETS pressure is not normally restored, the failure factor other than the instrument for the electric / mechanical trip is checked.

ETSV replacement procedure according to the present embodiment is performed in the order of ETSV non-excited-> shut-off valve Close-> ETSV separation and replacement-> shut-off valve Open-> ETSV excitation-> ETSV non-excited-> ETS oil low pressure alarm confirmation.

And if the low pressure alarm occurs even after replacing the ETSV, it performs the output deceleration and power generation stop procedure due to ETV failure.

According to the present invention, when the ETSV single device failure during operation of the power plant inevitably had to perform maintenance after power generation stop, there is an effect that can increase the efficiency of the power plant by providing a replacement means during normal operation.

It will be apparent to those skilled in the art that various modifications, substitutions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. will be. Accordingly, the embodiments disclosed in the present invention and the accompanying drawings are not intended to limit the technical spirit 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 the embodiments and the accompanying drawings. . The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

310: adjusting bolt
320: Adjusting bolt protective cap
330: position indicator

Claims (5)

In the blocking block device for the electrical trip solenoid valve (ETSV) of the turbine emergency stop system of a power plant using a GE type turbine,
A P port for receiving control oil provided from the turbine control oil pump to the turbine emergency stop system and supplying the control oil to the electrical trip solenoid valve (ETSV);
A T port receiving the control oil through the P port and supplying the control oil to an electric trip valve (ETV) to operate the ETV;
A B port for draining control oil supplied to the electric trip valve (ETV); And
An adjustment bolt provided at one side of the control oil flow path of the P port to open and close the control oil flow path of the P port; Including;
And an electric trip solenoid valve shutoff block device to cut off the control oil pressure provided from the turbine control oil pump during the replacement due to the ETSV failure. The method of claim 1,
The P port is an electrical trip solenoid valve blocking block device, characterized in that formed by a multi-joint pipe. The method of claim 1,
An electric trip solenoid valve shutoff block device further comprising: a position indicator indicating the opening position of the shutoff valve inside the shutoff block device. The method of claim 1,
Electrical trip solenoid valve blocking block device further comprises; control bolt protection cap for blocking external leakage when leakage occurs in the control bolt portion. The method of claim 3, wherein
The position indicator,
The electrical trip solenoid valve (ETSV) is positioned at "OPEN" by the control bolt of the electrical trip solenoid valve shut-off block device during normal operation, and "CLOSE" by the control bolt when the electrical trip solenoid valve (ETSV) is replaced. Electrical trip solenoid valve blocking block device, characterized in that located on the ".

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