KR101968265B1 - Turbine Trip Device that can be tested without generating stop - Google Patents

Abstract

The present invention relates to a turbine trip device which includes: a hydraulic manifold connected to a passage from a pump; an MTV installed on the hydraulic manifold and enabling a mechanical trip; a first lockout valve connected to the MTV and bypassing oil pressure when the MTV is tested; an MTSV installed on the hydraulic manifold, and including a solenoid valve (a) and a solenoid valve (b) to enable an electric trip solenoid valve (a) and the solenoid valve (b); an exchange block enabling the replacement of a solenoid valve of the MTSV during the operation of a turbine by stopping the oil pressure flowing to the solenoid valve when the solenoid valve malfunctions; and a second lockout valve connected to the MTSV, and bypassing the oil pressure when the MTSV is tested. Accordingly, the present invention eliminates the need to stop power generation during a test of the MTSV and safely and periodically test the turbine trip device.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a turbine trip device,

The present invention relates to a trip device for a turbine of a power plant, and more particularly, to a turbine with a lockout valve for bypassing the hydraulic oil of the MTSV in order to prevent generation stoppage when performing an MTSV test Trip device.

The power plant turbine trip device is a device for stopping the turbine by cutting off the steam supplied to the turbine when the turbine is overspeed, and consists of MTV and MTV.

Specifically, MTV (MECHANICAL TRIP VALVE) is a valve that enables mechanical tripping with the governor of the turbine. MTSV, MASTER TRIP SOLENOID VALVE, and electric trip solenoid valve are solenoids This valve enables electrically tripping by a valve, and such a MTIV and MTIV is attached to a hydraulic manifold.

1, the conventional turbine trip device includes an MTB vane 11, an MTB vane 12, a lockout valve 13, a hydraulic manifold 14, an M-V solenoid valve a 15, An air conditioner solenoid valve b 16, an air conditioner a spool limit switch 17, an air conditioner b spool limit switch 18 and a lockout valve solenoid 19.

During the normal operation of the power plant turbine, the conventional turbine trip device supplies the hydraulic oil, which has flowed into the turbine trip device, to the main valve side through the MTB 11 and the lock-out valve 13 via the MTB 12.

Such a conventional turbine trip device is provided so that the operation can be terminated by self-safety design even in the event of an emergency situation or uncontrollable situation, so it is necessary to check whether the system normally operates or not.

Therefore, MTV and MTV of the turbine trip device are each subjected to an operational test to check whether the turbine is operating normally.

When the test of the MTV 11 during the operation of the power plant turbine is performed, the solenoid 19 of the lock-out valve 13 is energized to allow the hydraulic oil to bypass without passing through the MTV 11, Is supplied to the main valve side via the M-V via (12).

On the other hand, the test of the electromagnetic vane 12 is performed by the respective tests for the solenoid valve a (15) and the solenoid valve b (16).

As a result, when the solenoid valve a (15) is tested (switched from the energized state to the elementary state), the solenoid valve b (16) is energized and the hydraulic pressure is shut off.

Further, the solenoid valve a (15) is shut off during the test (switching from the energized state to the element state) of the solenoid valve b (16), so that the hydraulic pressure does not flow to the solenoid valve b (16).

However, the M-VV 12 can not bypass the hydraulic pressure.

Accordingly, when the solenoid valve b (16) is not normally closed during the test of the solenoid valve a (15), the hydraulic pressure is drained via the solenoid b (16) Trips can cause power failure.

 In the test of the solenoid valve b 16, when the solenoid valve a 15 is not completely shut off, the hydraulic pressure is also drained to the solenoid valve b 16 and the pressure on the main valve side line lowers, The power generation stoppage occurs.

As described above, the conventional turbine trip device has a problem that power generation stop may occur during trip test during turbine operation.

In other words, in the conventional turbine trip device and test method, the turbine trip is generated due to the abnormal operation of the solenoid valve a (15), the solenoid valve b (16) there is a problem.

In addition, the conventional turbine trip test method has a problem that the valve can not be replaced during operation even if an abnormality occurs in the solenoid valve a (15) or the solenoid valve b (16) of the MIS-v.

The conventional turbine trip device has the solenoid valve a 15 of the electromagnetic brake 12 and the limit switches 17 and 18 for the displacement of each spool for checking the spool operation of the solenoid valve b 16 , The contact can be operated even though the spool of the valve is not completely blocked due to the clearance of the limit switch contact, so that the solenoid valve a (15) and the solenoid valve b (16) can not be precisely detected.

Accordingly, there is a need for a turbine trip device capable of testing without improved power stoppage to solve the above problems.

Korean Patent No. 10-1495197 (Feb.

In order to solve the conventional problems as described above, the present invention aims at bypassing the hydraulic pressure through the lock-out valve during the MTV test to prevent power generation stoppage.

In addition, when the solenoid valve a and the solenoid valve b of the M-th V are tested, the spool of each solenoid valve monitors the displacement and additionally confirms the pressure, thereby confirming the abnormality.

It is also possible to replace the solenoid valve a and the solenoid valve b even during operation of the turbine trip device.

According to an aspect of the present invention, there is provided a hydraulic pump comprising: a hydraulic manifold connected to a pump through a pump; An MTIV that is installed in the hydraulic manifold and enables mechanical tripping; A first lock-out valve connected to the throttle and bypassing the hydraulic pressure during the test of the throttle; A solenoid valve a and a solenoid valve b installed in the hydraulic manifold for electrically tripping the solenoid valve a and the solenoid valve b; And a second lock-out valve connected to the MIS-V and bypassing the hydraulic pressure during the test of the MIS-V.

The solenoid valve a and the solenoid valve b are mounted on an exchange block.

In addition, the exchange block is further provided with a hydraulic shutoff manual valve for shutting off hydraulic pressure to the solenoid valve a and the solenoid valve b.

The first lock-out valve and the second lock-out valve each include a solenoid valve.

The solenoid valves a and b each include a displacement measuring sensor for measuring the spool displacement.

The displacement measuring sensor is connected to a monitor for displaying a measured value.

The turbine trip device of the present invention has an effect of preventing power generation stoppage by bypassing the hydraulic pressure through the lock-out valve during the MTV test.

The turbine trip device according to the present invention is advantageous in that when the solenoid valve a and the solenoid valve b of the MIS type V are tested, the spool of each solenoid valve monitors the displacement and additionally confirms the pressure to check the abnormality.

In addition, there is an advantage that the solenoid valve a and the solenoid valve b, which are inoperable even during operation of the turbine trip device, can be replaced.

In addition, the turbine trip device can be periodically and safely tested, which is advantageous in stabilizing the turbine facility.

1 is a hydraulic circuit diagram of a conventional turbine trip device.
2 is a hydraulic circuit diagram of a turbine trip device according to the present invention.
3 is a hydraulic circuit diagram of an exchange block applied to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. Further, if it is determined that the gist of the present invention may be blurred, detailed description thereof will be omitted. In addition, embodiments of the present invention will be described below, but it goes without saying that the technical idea of the present invention is not limited thereto and can be practiced by those skilled in the art.

FIG. 2 is a hydraulic circuit diagram of a turbine trip apparatus according to the present invention, and FIG. 3 is a hydraulic circuit diagram of an exchange block applied to the present invention.

Hereinafter, a turbine trip device according to the present invention will be described with reference to FIGS. 2 and 3. FIG.

The turbine trip device according to the present invention comprises a hydraulic manifold 14, a throttle 11, a first lock-out valve 13, a throttle V 12, and a second lock-out valve 20.

Specifically, MTV (MECHANICAL TRIP VALVE) and MTSV (MASTER TRIP SOLENOID VALVE, electric trip solenoid valve) are installed in the hydraulic manifold 14 connected to the flow path from the pump.

The MTV 11 is connected to the first lock-out valve 13 for bypassing the hydraulic oil flowing into the MTV 11 during the test of the MTV 11. [

The electromagnetic vane 12 is connected to the solenoid valve a 15 and the solenoid valve b 16 and the valves 15 and 16 enable the electromagnetic trip of the electromagnetic vane 12.

The second lock-out valve 20 connected to the M-VV 12 functions to bypass the hydraulic oil to the M-VV 12 during the test of the M-V-VV 12.

On the other hand, referring to FIG. 3, an exchange block portion 25 of the MT V (12) is shown. The exchange block 25 is constituted by solenoid valves a and b (15 and 16) and a hydraulic shutoff manual valve 26 in such a configuration that the solenoid valves a and b (15 and 16) can be replaced.

At this time, the hydraulic cut-off manual valve 26 is located between the solenoid valves a, b (15, 16) and the M-VV 12 to connect the respective components.

The hydraulic cut-off manual valve 26 is configured to shut off the hydraulic pressure to the solenoid valves a and b (15, 16). When the operation abnormality of the solenoid valves a, b (15, 16) is confirmed, The solenoid valves a, b (15, 16) can be replaced by closure.

Each of the solenoid valves a and b has displacement measuring sensors 27 and 28 for physically measuring the spool displacements and a monitor (not shown) for indicating the measured values of the displacement measuring sensors 27 and 28 29 are provided.

2 and 3, the first and second and third pressure gauge sections 21, 22, and 23 are provided in the men's folding block 14 and the exchange block 15 to monitor the pressure have.

Accordingly, the displacement of the spool of the solenoid valves 15 and 16 is monitored during the testing of the solenoid valves a and b (15 and 16), and the pressure is further checked to check whether the solenoid valves 15 and 16 are abnormal.

Hereinafter, the operation of the turbine trip device according to the present invention will be described.

When the test of the turbine trip device of the present invention is carried out, first, the test of the MTV 11 is performed, and the solenoid 19 of the first lock-out valve 13 is switched from the device state to the energized state, Thereby allowing the MTIB 11 to bypass.

That is, the bypassed hydraulic oil passes through the M-V-VRT 12 without passing through the M-VR 11 and is directly supplied to the main valve side.

Thereafter, when the test of the throttle 11 is completed, the solenoid valve 19 of the first lock-out valve 13 is switched from the energized state to the element state, whereby the hydraulic oil is again supplied to the main And is normally supplied to the valve side.

Then, the solenoid valves a, b (15, 16) of the EMI V-12 are tested. Before that, the solenoid valve 24 of the second lock-out valve 20 is switched from the element state to the energized state .

Then, the hydraulic oil is supplied to the main valve side bypassing the bypass via the bypass valve (12).

In this state, first, the solenoid valve a (15) in an energized state is first energized to perform a test, then the energized state is switched to the energized state, and the energized solenoid valve b (16) Switch back to the energized state.

When the solenoid valves a, b (15, 16) of the MTV 12 are tested, the solenoid valve 24 of the second lock-out valve 20 is switched from the energized state to the elementary state.

As a result, the bypassed hydraulic oil is normally supplied to the main valve again via the MIS type V (12).

Further, when the solenoid valves a and b (15, 16) are tested, the spool displacements of the respective valves are physically measured through the displacement measurement sensors (27, 28) and the measured values are monitored through the monitor (29) .

At this time, if the operation abnormality of the solenoid valves a, b (15, 16) is confirmed, the hydraulic block manual valve (26) of the exchange block is closed and the abnormal solenoid valve is replaced.

The thus configured turbine trip device can prevent an undesired trip from occurring in the test of the M-VV 12.

It is also possible to check whether the solenoid valves a, b (15, 16) are in normal operation by measuring the accurate displacement.

It is also very useful because it is possible to replace the solenoid valves a, b (15, 16) that are faulty even during turbine 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. Therefore, the embodiments disclosed in the present invention and the accompanying drawings are intended to illustrate and not to limit the technical spirit of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments and accompanying drawings. The scope of protection of the present invention should be construed according to the claims, and all technical ideas within the scope of equivalents thereof should be construed as being included in the scope of the present invention.

11: MTV (MTV) 12: MTV (MTV)
13: First lock-out valve 14: Hydraulic manifold block
15: EMI V solenoid valve a
16: EMI V solenoid valve b
17: Solenoid valve a Spool limit switch
18: Solenoid valve b Spool limit switch
19: First lock-out valve solenoid valve
20: second lock-out valve 21: first pressure gauge
22: second pressure gauge 23: third pressure gauge
24: Second lockout solenoid valve
25: Exchange Block
26: Hydraulic shutoff manual valve
27: EMI V solenoid valve a Spool displacement measurement sensor
28: EMI V solenoid valve b Spool displacement measurement sensor
29: Spool monitor section

Claims (6)

A hydraulic manifold to which a flow path is connected from the pump;
An MTIV that is installed in the hydraulic manifold and enables mechanical tripping;
A first lock-out valve connected to the throttle and bypassing the hydraulic pressure during the test of the throttle;
A solenoid valve a and a solenoid valve b installed in the hydraulic manifold for electrically tripping the solenoid valve a and the solenoid valve b;
A second lock-out valve connected to the MIS-V and bypassing the hydraulic pressure during the test of the MIS-V; And
And an exchange block having the solenoid valve a and the solenoid valve b mounted thereon and a hydraulic shutoff manual valve for shutting off the hydraulic pressure to the solenoid valve a and the solenoid valve b,
The solenoid valve a and the solenoid valve b each include a displacement measurement sensor for measuring the spool displacement,
Wherein the hydraulic manifold and the exchange block are provided with first, second and third pressure gauges capable of confirming the pressure. delete delete The method according to claim 1,
Wherein the first lock-out valve and the second lock-out valve each include a solenoid valve. delete The method according to claim 1,
Wherein the displacement measuring sensor is connected to a monitor for displaying a measured value.

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