KR101618331B1 - Flushing system of hydraulic actuator for turbine of power plant - Google Patents

Abstract

The present invention discloses a flushing system of hydraulic actuators for power plant turbines. A flushing system of a hydraulic actuator for a turbine of a plant is detachably provided outside a hydraulic actuator of a turbine of a power plant and includes a plurality of flushing blocks communicating with a first hydraulic line and a second hydraulic line through which fluid is injected and discharged, And a switching unit that operates between a first flushing position for flushing the second hydraulic line and a second flushing position for flushing the first hydraulic line, and a switching unit operable between the first flushing position and the second flushing position And a communication device which is provided between the flushing device and the control device and transmits and receives a control signal of the flushing device and the control device.

Description

TECHNICAL FIELD [0001] The present invention relates to a flushing system for a hydraulic actuator for a power plant turbine,

The present invention relates to a flushing system for a hydraulic actuator for a power plant turbine, and more particularly to a flushing system for a hydraulic actuator for a power plant turbine that flushes a hydraulic actuator for opening and closing a turbine valve of a power plant.

The output of the turbine that produces electricity in the power plant is controlled by controlling the amount of steam flowing into the turbine as the turbine valve that supplies and blocks the steam is opened and closed. At this time, the opening and closing of the turbine valve is controlled by the hydraulic actuator, and the hydraulic actuator is installed on one side of the turbine valve.

Here, the hydraulic actuator opens and closes the turbine valve as the piston reciprocates by the force of the hydraulic pressure. Further, in the process of continuously supplying and blocking the fluid, the hydraulic actuator floats the foreign object in the flow path through which the fluid moves, or the foreign substance adheres to the inner surface of the flow path.

As described above, when the foreign matter floats or adheres to the flow path through which the fluid moves, the operation of the hydraulic actuator is not smoothly performed, and the operation of the turbine valve is adversely affected. Therefore, it is necessary to prevent the deterioration of the performance of the hydraulic actuator by removing foreign matter or floating matters adhering to the inner surface of the flow path through a flushing process for cleaning the flow path through which the fluid moves.

Then, the foreign substances or floating matters adhered to the inside of the flow path are removed by using a flushing apparatus.

However, since the conventional flushing apparatus needs to replace one of the plurality of flushing blocks in accordance with the object to be flushed, there arises a problem that the flushing operation time due to replacement of the flushing block is increased, There is a problem that the work is inconvenient as well as the maintenance cost is increased.

Therefore, there is a need to improve this.

Korean Registered Patent No. 10-1184266 (Registered: 2012.09.13, Name: Inspection Device and Inspection Method of Hydraulic Actuator for Power Plant Turbine)

It is an object of the present invention to provide a flushing system for a hydraulic actuator for a power plant turbine which is capable of flushing hydraulic lines of a hydraulic actuator without replacement of a flushing block.

It is another object of the present invention to provide a flushing system of a hydraulic actuator for a power plant turbine that can automatically perform a flushing operation of a hydraulic actuator.

According to an aspect of the present invention, there is provided a flushing system for a hydraulic actuator for a turbine of a power plant, comprising: a first hydraulic line and a second hydraulic line removably installed outside a hydraulic actuator of a power plant turbine, And a switching unit that operates between a first flushing position for flushing the first hydraulic line and the second hydraulic line and a second flushing position for flushing the first hydraulic line, ; A control device for applying a control signal to the flushing device such that the switching unit moves between the first flushing position and the second flushing position; And a communication device provided between the flushing device and the control device and transmitting and receiving a control signal of the flushing device and the control device.

The first hydraulic line may include an actuating portion that reciprocates the piston of the hydraulic actuator through the reception and discharge of the first fluid; And a transfer path portion that forms a flow path through which the first fluid is injected and discharged with the actuating portion interposed therebetween.

Further, the hydraulic actuator further includes a disc dump valve arranged to form a space of the actuating portion.

Further, the second hydraulic line forms an injection and discharge passage of the second fluid for supplying the hydraulic pressure to the disk dump valve.

The first fluid and the second fluid may be respectively flushed from the flow path of the transfer passage section and the flow passage of the second hydraulic line at the first flushing position of the switching unit.

Further, the first fluid is characterized by flushing the actuating portion at the second flushing position of the switching unit.

The flushing apparatus may further include an adjusting unit for adjusting a flow path of the first hydraulic line to flush the actuating unit when the switching unit is in the second flushing position.

The control device may further comprise: a signal applying unit for applying a control signal to the flushing device such that the switching unit is located at any one of the first flushing position and the second flushing position; And a monitoring unit for receiving a feedback signal from the flushing device and monitoring an operating state of the flushing device.

The monitoring unit monitors the hydraulic pressure and the flow rate of the first fluid and the second fluid transferred to the first hydraulic line and the second hydraulic line provided from the flushing apparatus.

The communication device may further include: a first communication module connected to the flushing device and transmitting / receiving signals to / from the control device; And a second communication module connected to the control device and transmitting / receiving signals to / from the flushing device.

As described above, the filter unit of the air cleaner for a vehicle according to the present invention is capable of flushing the fluid flow path and the region providing the hydraulic pressure of the piston in accordance with the selective movement of the switching unit, unlike the prior art, It is possible to reduce the maintenance cost and shorten the working time.

Further, according to the present invention, the flushing device and the control device are automatically connected to each other through the communication device, thereby reducing the time required for the flushing process of the hydraulic actuator and ensuring the safety of the operator.

1 is a configuration diagram of a flushing system of a hydraulic actuator for a power plant turbine according to an embodiment of the present invention.
2 is a block diagram of a flushing system of a hydraulic actuator for a power plant turbine according to one embodiment of the present invention.
3 is a cross-sectional view illustrating a first operational state of the flushing apparatus in the first flushing position and the hydraulic actuator for the power plant turbine according to the embodiment of the present invention.
4 is a cross-sectional view illustrating a second operational state of the flushing apparatus at the second flushing position and the hydraulic actuator for the power plant turbine according to the embodiment of the present invention.

Hereinafter, a preferred embodiment of a flushing system of a hydraulic actuator for a power plant turbine according to the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

Before describing, the flushing system of a hydraulic actuator for a power plant turbine according to the present invention is hereinafter referred to as a flushing system, and the first fluid, the second fluid, and the end oil are FAS, ETS and FCD, respectively.

FIG. 1 is a block diagram of a flushing system of a hydraulic actuator for a power plant turbine according to an embodiment of the present invention, and FIG. 2 is a block diagram of a flushing system of a hydraulic actuator for a power plant turbine according to an embodiment of the present invention.

3 is a cross-sectional view showing a first operating state of the flushing apparatus at the first flushing position and the hydraulic actuator for the power plant turbine according to the embodiment of the present invention, and Fig. 4 is a cross- And a second operating state of the flushing device in the second flushing position.

1 to 4, the hydraulic actuator 10 includes a piston 12 reciprocated by hydraulic pressure and a disk dump valve 12 supported by hydraulic pressure to form a space in which the piston 12 can reciprocate. (14).

The hydraulic actuator 10 includes a first hydraulic line 16 for supplying the hydraulic pressure to the piston 12 and a second hydraulic line 18 for supplying the hydraulic pressure to the disc dump valve 14. The first fluid F1 and the second fluid F2 are injected into the first hydraulic line 16 and the second hydraulic line 18 and the first fluid F1 and the second fluid F2 are injected into the first hydraulic line 16 and the second hydraulic line 18, The first fluid F1 and the second fluid F2 injected respectively are flushed from the first hydraulic line 16 and the second hydraulic line 18 and discharged to the oil discharge F3.

Specifically, the first hydraulic line 16 is connected to the first fluid F1 via the actuating portion 16a and the actuating portion 16a through which the piston 12 reciprocates by the reception and discharge of the first fluid F1. And a transfer passage portion 16b for forming a passage through which the fuel F1 is injected and discharged. That is, the transfer passage portion 16b forms the discharge passage through which the first fluid Fl is injected and the first fluid Fl is flushed and discharged to the discharge oil F3. The operation procedure of flushing by the first fluid Fl and the second fluid F2 will be described in detail in the following flushing system 100.

The first hydraulic line 16 and the second hydraulic line 18 of the hydraulic actuator 10 include a plurality of flow sensors and a plurality of hydraulic pressure sensors not shown in the present invention. The information collected by the plurality of flow sensors and the hydraulic pressure sensor is transmitted to the control device 140 by the communication device 160 described later as a feedback signal.

The flushing system 100 according to the present embodiment includes a flushing device 120, a control device 140, and a communication device 160. Here, the flushing device 120 and the communication device 160 are provided so as to correspond to the number of the hydraulic actuators 10, and may correspond to the number of the hydraulic actuators 10 in the case of the control device 140 and may correspond to the number of the hydraulic actuators 10 ).

The flushing apparatus 120 includes a flushing block 122, a switching unit 124, a regulating unit 126 and a fluid circulating unit 128. The flushing device 120 is mounted or connected to the hydraulic actuator 10 to flush the first hydraulic line 16 and the second hydraulic line 18 inside the hydraulic actuator 10. [ In addition, the flushing apparatus 120 flushes the hydraulic actuator 10 through a circulation process in which the first fluid Fl and the second fluid F2 are injected and discharged to the discharge oil F3.

The flushing block 122 is coupled to the outside of the hydraulic actuator 10 and communicates with the first hydraulic line 16 and the second hydraulic line 18. The flushing block 122 includes a first flushing block 122a, a second flushing block 122b, and a third flushing block 122c.

The first flushing block 122a forms an injection path for the first fluid F1 to communicate with the first hydraulic line 16 of the hydraulic actuator 10 and the second flushing block 122b communicates with the second fluid The flow path of the first fluid F1 is formed together with the injection path of the second fluid line F2 and communicated with the first hydraulic line 16 and the second hydraulic line 18, respectively.

The second flushing block 122b is disposed on the first hydraulic line 16. The second flushing block 122b according to the present invention is communicated with at least one of the first hydraulic line 16 and the second hydraulic line 18 by the operation of the switching unit 124. [

Specifically, the second flushing block 122b communicates with the first hydraulic line 16 and the second hydraulic line 18 when the switching unit 124 reaches the first flushing position, 2 reaches the flushing position, it communicates with the actuating portion 16a of the first hydraulic line 16. As such, the second flushing block 122b is detachably disposed in the hydraulic actuator 10 so as to perform the two-mode flushing process in accordance with the operation of the switching unit 124. [

The switching unit 124 is configured to selectively operate between a first flushing position for flushing the first hydraulic line 16 and the second hydraulic line 18 and a second flushing position for flushing the first hydraulic line 16 do.

In addition, the switching unit 124 receives the control signal from the control device 140 and is selectively moved between the first flushing position and the second flushing position. In detail, the switching unit 124 according to the present invention is disposed inside the second flushing block 122b and is reciprocated between the first flushing position and the second flushing position in accordance with the operation signal.

A solenoid valve may be used as the switching unit 124 according to the present embodiment, and the solenoid valve selectively opens and closes the flow paths inside the second flushing block 122b depending on whether the solenoid valve is excited.

Although a solenoid valve is used as the switching unit 124 in this embodiment, other types of valves may be used depending on the needs of the user.

The regulating unit 126 regulates the flow path of the first hydraulic line 16 to flush the actuating portion 16a when the switching unit 124 is in the second flushing position. For example, the control unit 126 may control the flow of the first fluid F1 injected through the first hydraulic line 16 to the flow-in line F3 and the flow path to the actuating portion 16a So as to open the oil line.

As the control unit 126 according to the present embodiment, a servo valve may be used, and other valves may be used according to the needs of the user.

The fluid circulating unit 128 is provided such that the first fluid Fl, the second fluid F2, and the oil drain F3 are continuously circulated. A filter (not shown) is provided in the fluid circulating unit 128 to remove foreign matters contained in the oil F3 and re-supply the oil to the hydraulic actuator 10. [ The flushing operation process of the hydraulic actuator 10 is performed through the continuous circulation of the first fluid Fl, the second fluid F2 and the oil draining F3 using the fluid circulating unit 128. [

Next, the control device 140 applies a control signal to the flushing device 120 so that the switching unit 124 selectively moves between the first flushing position and the second flushing position. In this case, the switching unit 124 according to the present embodiment includes a signal applying unit 142 and a monitoring unit 144.

In addition, the control device 140 according to the present embodiment operates the flushing apparatus 120 automatically according to an operator's input signal.

The signal application unit 142 applies an operation signal to the flushing apparatus 120 so that the switching unit 124 is selectively moved between the first flushing position and the second flushing position as described above. The signal application unit 142 also applies the operation signals of the adjustment unit 126 and the fluid circulation unit 128 to the flushing apparatus 120 in addition to the switching unit 124. [

The monitoring unit 144 receives the feedback signal from the flushing apparatus 120 and monitors the operation state of the flushing apparatus 120. [ The monitoring unit 144 receives a feedback signal from the flow sensor and the hydraulic pressure sensor disposed on the first hydraulic line 16 and the second hydraulic line 18 of the hydraulic actuator 10 and outputs the signal to the hydraulic actuator 10 and the second fluid F2 flushing the first fluid F1 and the second fluid F2.

Here, the monitoring unit 144 may monitor various variables other than the flow rate and the flow rate according to the design change. The monitoring unit 144 monitors the feedback signal and notifies the operator of the feedback signal, and can automatically feed back the signal to the signal applying unit 142.

The communication device 160 is provided between the flushing device 120 and the control device 140 and transmits and receives signals of the flushing device 120 and the control device 140. The communication device 160 connects the flushing device 120 and the control device 140 via a wired or wireless system.

For example, the communication device 160 can transmit and receive signals by connecting the flushing device 120 and the control device 140 through a LAN cable, a wireless LAN (for example, WiFi), a ZigBee communication, or the like.

As described above, the communication device 160 is provided so that the flushing device 120 and the control device 140 can transmit and receive signals to each other. Thus, the time and cost and the like can be saved more efficiently than the manually operated flushing operation .

The communication device 160 according to the present embodiment includes a first communication module 162 and a second communication module 164.

The first communication module 162 is connected to the flushing device 120 and exchanges signals with the control device 140. That is, the first communication module 162 receives the operation signal of the flushing device 120 applied from the control device 140 and transmits the feedback signal generated from the flushing device 120 to the control device 140.

The second communication module 164 is connected to the control device 140 to mutually exchange signals with the flushing device 120. That is, the second communication module 164 transmits the operation signal to the flushing device 120 and receives the feedback signal generated from the flushing device 120.

As described above, the flushing apparatus 120 and the control apparatus 140 transmit / receive control signals through the first communication module 162 and the second communication module 164.

The operation and operation of the flushing system of the hydraulic actuator for a power plant turbine according to one embodiment of the present invention will be described.

First, the flushing block 122 is coupled to the outside of the hydraulic actuator 10. Then, the first fluid (Fl) and the second fluid (F2) for flushing the hydraulic actuator (10) are injected. When the first fluid F1 and the second fluid F2 are injected into the hydraulic actuator 10, the first fluid F1 and the second fluid F1 are communicated to the first hydraulic line 16 and the second hydraulic line 18, And the second fluid F2 flow. At this time, when the operation signal of the switching unit 124 is applied by the controller 140, the switching unit 124 is placed in the first flushing position.

The first fluid F1 and the second fluid F2 flowing respectively to the first hydraulic line 16 and the second hydraulic line 18 are supplied to the first hydraulic line 16 and the second hydraulic line 18, Respectively, and is discharged into the end oil F3 and is received in the fluid circulating unit 128. [ Here, the transfer passage portion 16b for guiding the first fluid F1 of the first hydraulic line 16 to the actuating portion 16a is flushed at the first flushing position. The oil F3 contained in the fluid circulating unit 128 is filtered and circulated to flush the hydraulic actuator 10. [

On the other hand, the switching unit 124 is moved to the second flushing position so as to flush the actuating portion 16a that directly provides the hydraulic pressure to the piston 12 of the first hydraulic line 16. [ Then, the second hydraulic line 18 for supplying the hydraulic pressure to the disc dump valve 14 is closed, whereby the space of the actuating portion 16a is opened by the disc dump valve 14, Is supplied to the actuating portion 16a and is discharged to the discharge oil F3. Thus, the first fluid Fl is supplied to the actuating portion 16a to flush the actuating portion 16a. Of course, even when the switching unit 124 is located at the second flushing position, the flushing operation is performed by circulating the first fluid Fl and the oil F3.

As a result, the hydraulic flow path and the area providing the hydraulic pressure of the piston can be flushed according to the selective movement of the switching unit, so that the operation cycle can be shortened together with the maintenance cost of the hydraulic actuator.

In addition, by automatically connecting the flushing device and the control device as a communication device, it is possible to reduce the time required for the flushing process of the hydraulic actuator and ensure the safety of the operator in comparison with the manual operation.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand.

Accordingly, the true scope of protection of the present invention should be defined by the claims.

10: Hydraulic actuator 12: Piston
14: disk dump valve 16: first hydraulic line
18: second hydraulic line 100: flushing system
120: Flushing device 122: Flushing block
124: switching unit 126: regulating unit
140: control device 142: signal application unit
144: monitoring unit 160: communication device
162: first communication module 164: second communication module

Claims (9)

A plurality of flushing blocks detachably provided outside the hydraulic actuator of the turbine of the power plant and communicating with a first hydraulic line and a second hydraulic line through which fluid is injected and discharged and a plurality of flushing blocks communicating with the first hydraulic line and the second hydraulic line, A flushing device having a switching unit operating between a first flushing position for flushing the first hydraulic line and a second flushing position for flushing the first hydraulic line; A control device for applying a control signal to the flushing device such that the switching unit moves between the first flushing position and the second flushing position; And a communication device provided between the flushing device and the control device for mutually transmitting and receiving control signals of the flushing device and the control device,
Wherein the first hydraulic line
An actuating portion for reciprocating the piston of the hydraulic actuator through the reception and discharge of the first fluid; And
A transfer path portion for forming a flow path through which the first fluid is injected and discharged with the actuating portion interposed therebetween;
Wherein the turbine is a turbine. delete The method according to claim 1,
Wherein the hydraulic actuator further comprises a disc dump valve arranged to define a space in the actuating portion,
Wherein the second hydraulic line forms an injection and discharge flow path of a second fluid to provide hydraulic pressure to the disk dump valve. The method of claim 3,
Wherein the first fluid and the second fluid respectively flush the flow path of the conveyance passage portion and the second hydraulic pressure line at the first flushing position of the switching unit. The method of claim 3,
Wherein the first fluid flushes the actuating portion at the second flushing position of the switching unit. The method according to claim 1,
Characterized in that the flushing device further comprises an adjusting unit for adjusting the flow path of the first hydraulic line to flush the actuating part when the switching unit is in the second flushing position Of flushing system. The control apparatus according to claim 1,
A signal applying unit for applying a control signal to the flushing apparatus such that the switching unit is located at one of the first flushing position and the second flushing position; And
A monitoring unit for receiving a feedback signal from the flushing device and monitoring an operating state of the flushing device;
Wherein the turbine is a turbine. 8. The method of claim 7,
Wherein the monitoring unit monitors the hydraulic pressure and the flow rate of the first fluid and the second fluid transferred to the first hydraulic line and the second hydraulic line provided from the flushing apparatus. The communication apparatus according to claim 1,
A first communication module connected to the flushing device and transmitting / receiving signals to / from the control device; And
A second communication module connected to the control device to transmit / receive a signal to / from the flushing device;
Wherein the flushing system of the hydraulic actuator for the power plant turbine comprises:

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