KR200483313Y1 - hydraulic pressure detection system for power generation - Google Patents

Abstract

The present invention relates to a technology for detecting a water pressure of water stored for generating electricity in a pumped-storage power plant, and is a technology for detecting a water pressure of an external predetermined reservoir for storing water and generating electricity from water stored in a predetermined reservoir based on the detected water pressure And a hydraulic pressure detection system for determining whether or not the hydraulic pressure is detected. In particular, by improving the structure of the hydraulic pressure detection chamber connected to the predetermined reservoir portion and the structure of each pipe connected to the hydraulic pressure detection chamber, it is possible to precisely detect the hydraulic pressure of the pressure switch portion communicating with the hydraulic pressure detection chamber . According to the present invention, there is an advantage that the structure of the water pressure detection chamber can be improved, and filtering of water for detecting the water pressure through the power generation facility can be performed by user operation at any time.

Description

[0001] The present invention relates to a hydraulic pressure detection system for power generation,

The present invention relates to a technique for detecting the water pressure of water stored for generating electricity in a pumped-storage power plant. More particularly, the present invention relates to a technology for detecting a water pressure of an external predetermined reservoir portion for storing water and detecting whether or not the water is generated from water stored in a predetermined reservoir portion based on the detected water pressure.

In particular, by improving the structure of the hydraulic pressure detection chamber connected to the predetermined reservoir portion and the structure of each pipe connected to the hydraulic pressure detection chamber, it is possible to precisely detect the hydraulic pressure of the pressure switch portion communicating with the hydraulic pressure detection chamber .

Generally, a pumped-storage power plant has a low-water reservoir at low and high positions, and when the remaining power is abundant, the pump is operated to transfer the water contained in the low reservoir to the high reservoir at a low position, And when necessary, discharges water from a reservoir at a high position to a reservoir at a low position to generate electricity.

At this time, it is necessary to check in real time whether or not the water stored in the reservoir at the high position has enough water pressure to generate electricity. To this end, a power generation facility is constructed adjacent to the reservoir at a high position and hydroelectric power is generated through the power generation facility.

For example, the power generation facility can establish a piping communicating with a lower portion of the reservoir at a higher position and check the water pressure formed in the pipe, thereby knowing the water pressure of the water reservoir, , And it is possible to check in real time how long it can be developed through this.

Therefore, it is very important to accurately check the water pressure of the reservoir at the power generation facility.

However, when the water contained in the water reservoir is mixed with various foreign substances (for example, suspended matter and sediment), when the water pressure supplied through the pipe is checked, foreign matter accumulated in each constitution of the power generation facility So that the detection of the correct hydraulic pressure is hindered, leading to a malfunction of the power generation equipment.

At this time, if the malfunction of the power generation facilities is remodeled, it takes a lot of time and manpower, and there is a serious problem of incidental damage caused by failure to generate electricity in time.

Korean Patent Application No. 10-1996-007329 "Control Apparatus and Method of Pressurized Feed Pump System" Korean Patent Application No. 10-2009-7020507 "Apparatus and Method for Controlling Slit Door Sealing Pressure" Korean Patent Application No. 10-2000-0082482 "Power Generation System Using Liquid Pressure and Its Method" Korean Patent Application No. 10-2009-0078166 "Control rod drive device for reactor (CEDM) Sealing surface leakage detection device of pressure housing" Korea Utility Model Registration Application 20-2005-0024576 "Piping Sealing Device for Piping Pressure Tester"

The object of the present invention is to provide a water pressure detection system for power generation that can accurately detect the water pressure of the reservoir for power generation.

Further, the object of the present invention is to provide a water pressure detection system for power generation that can prevent frequent failure of power generation facilities.

Further, the object of the present invention is to provide a water pressure detection system for power generation that is simple in preventive maintenance.

Further, the object of the present invention is to provide a water pressure detection system for power generation that can easily filter water for detecting water pressure.

In order to achieve the above object, the present invention provides a water pressure detection system for detecting a water pressure of an external predetermined reservoir for storing water and determining whether or not to generate electricity from water stored in a predetermined reservoir based on the detected water pressure, A water supply piping communicating with a lower portion of a predetermined water storage portion for extracting water from a predetermined water storage portion and providing the water to the outside to detect a lower water pressure of the water storage portion; A water pressure detection chamber which is made of a housing closed inside and outside and which communicates with the water supply pipe through the one side portion to store water flowing in the water supply pipe inside to maintain the same water pressure as the water supply pipe; A pressure sensing chamber for sensing a pressure of water in the chamber for sensing the pressure of water, sensing the pressure of water discharged from the pressure sensing chamber by the pressure of the pressure sensing chamber, Off control command to an external power generation device interlocked with the predetermined low-water level portion according to the power-on / off control command.

The pressure gauge unit may further include a pressure gauge unit that communicates with the water pressure detection chamber and displays the water pressure of the water pressure detection chamber numerically.

A switch unit pipe connecting the pressure switch unit and the water pressure detection chamber to maintain the water pressure equal to the water pressure in the water pressure detection chamber; And a gauge part pipe connected to the pressure gauge part and the water pressure detection chamber so as to maintain the same water pressure as the water pressure in the water pressure detection chamber, and the water supply pipe, the switch part pipe, and the gauge part pipe, And a steel pipe which maintains the current inner diameter from the internal pressure so that the water pressure can be maintained at the same level as the water pressure in the water pressure detection chamber.

And a drain pipe communicating with the water pressure detection chamber so as to drain water in the water pressure detection chamber to the outside by the user's operation.

In this case, the water pressure detecting chamber preferably includes a floating drain socket portion which is connected to one end of the drain pipe so as to discharge the floating matter contained in the inside, through the upper surface.

The water pressure detection chamber includes a first drain socket portion connected to one end portion of the switch portion pipe, And a second drain socket part connected to the one end of the gauge pipe and communicating with the first drain socket part and the second drain socket part, and the sediment of water contained in the inside of the water pressure detection chamber can be discharged through the first drain socket part and the second drain socket part The first drain socket portion and the second drain socket portion may be provided so as to penetrate the lower surface of the water pressure detection chamber.

Further, the chamber for detecting the pressure of water includes a chamber cover which is opened and closed at one side wall of the body so as to be watertightly retained on one opened side wall thereof; And a cover o-ring for assisting watertightness maintenance between the one side wall opened between the opened one side wall and the chamber cover and the chamber cover.

On the other hand, a fluid control valve mounted on a reservoir supply pipe for on-off controlling the flow of water from a reservoir supply pipe to a hydraulic pressure detection chamber; And a drain control valve mounted on the drain pipe for on / off control of the flow of water moving from the hydraulic pressure detection chamber to the drain pipe.

Preferably, the switch portion pipe and the first drain socket portion, the gauge portion pipe and the second drain socket portion are detachably connected to each other according to a user operation.

The present invention has an advantage that the structure of the hydraulic pressure detection chamber can be improved and the hydraulic pressure through the pressure switch unit can be accurately measured.

In addition, the present invention has an advantage in that the structure of the hydraulic pressure detection chamber is improved, and filtering of the water pressure detection water passing through the power generation facility can be performed by user operation at any time.

In addition, the present invention improves the structure of the pressure sensing chamber and eliminates the frequent malfunction of the existing pressure switch.

In addition, the present invention is advantageous in that preventive maintenance is easily performed by designing each pipe connected to the water pressure detection chamber to be easily detachable by user's operation.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a configuration diagram showing a power generation hydraulic pressure detection system according to the present invention;
Fig. 2 is a disassembled view showing a water pressure detection system for power generation according to the present invention; Fig.
3 is a side cross-sectional view showing a hydraulic pressure detection chamber according to the present invention,
4 is a plan view showing a chamber for detecting a hydraulic pressure according to the present invention,
5 is a side view showing a chamber for detecting a hydraulic pressure according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings.

FIG. 1 is a configuration diagram showing a power generation hydraulic pressure detection system according to the present invention, and FIG. 2 is a separation configuration diagram showing a power generation hydraulic pressure detection system according to the present invention.

Referring to FIGS. 1 and 2, the present invention detects a water pressure of an external predetermined reservoir (not shown) for storing water, and based on the detected water pressure, ) Of the water supply system.

To this end, the water pressure detection system according to the present invention includes a water supply pipe 100, a water pressure detection chamber 200, a pressure switch unit 300, a switch unit pipe 310, a pressure gage unit 400, A drain pipe 500, a fluid control valve 600, and a drain control valve 700. The drain pipe 500,

The water supply pipe 100 preferably communicates directly with the lower portion of the predetermined reservoir portion to detect the lower water pressure of the predetermined reservoir portion and extracts water from the predetermined reservoir portion and provides the water to the water pressure detection chamber 200.

Here, the lower portion of the predetermined reservoir portion, the reservoir supply pipe 100, and the hydraulic pressure detection chamber 200 are connected to each other to exhibit the same water pressure. As a result, when the water pressure in the water pressure detection chamber 200 is accurately detected, the bottom water pressure of the water level can be detected.

The water pressure detection chamber 200 is composed of a housing in which the inside and the outside are closed and communicates with the water supply piping 100 through the one side to maintain the same water pressure as the water supply piping 100, I put it inside.

The pressure switch unit 300 communicates with the water pressure detection chamber 200 to detect the water pressure in the water pressure detection chamber 200 and pours the water pressure from the water pressure detection chamber 200 by the water pressure of the water pressure detection chamber 200 Off control command to an external power generator (not shown) that interlocks with a predetermined reservoir according to a preset manual based on the sensed pressure of the water.

Here, the preset manual includes an automatic mode in which the power generation facility is automatically operated when the water pressure is detected to be equal to or higher than a predetermined pressure, and a user operation mode in which the user confirms the numerical value of the pressure gauge unit 400 with the naked eye, And a manual mode.

The switch part pipe 310 connects the pressure switch part 300 and the water pressure detection chamber 200 so that the water pressure in the switch part pipe 310 can maintain the same water pressure as the water pressure in the water pressure detection chamber 200 .

The pressure gauge unit 400 communicates with the water pressure detection chamber 200 to display the water pressure of the water pressure detection chamber 200 as a numerical value so that the manager can check the water pressure of the water storage unit currently in real time.

The gauge pipe 410 connects the pressure gauge unit 400 and the water pressure detection chamber 200 so that the water pressure in the gauge pipe 410 can maintain the same water pressure as the water pressure in the water pressure detection chamber 200 .

The water supply pipe 100, the switch part pipe 310 and the gauge part pipe 410 each have an inner diameter that is the same as the inner diameter of the pressure detection chamber 200, so that the inner water pressure can be maintained at the same level as the water pressure in the water pressure detection chamber 200 And a steel pipe to be maintained.

The drain pipe 500 communicates with the water pressure detection chamber 200 so as to drain the water in the water pressure detection chamber 200 to the outside by the user's operation. At this time, impurities (for example, floating matters) in the water pressure detection chamber 200 are discharged to the outside, so that the floating matters can be filtered from the water pressure detection chamber 200 at any time.

The fluid control valve 600 is configured to on-off control the flow of water that is mounted on the water supply pipe 100 and moves from the water supply pipe 100 to the water pressure detection chamber 200.

That is, normally, the fluid control valve 600 is kept open so that the water in the reservoir portion is drawn into the water pressure detection chamber 200 through the water supply piping 100 and the water pressure detection chamber 200 is maintained When a system failure occurs, the flow of water from the reservoir to the water pressure detection chamber 200 is blocked by switching to the closed state.

The drain control valve 700 is mounted on the drain pipe 500 and is configured to on-off control the flow of water moving from the water pressure detection chamber 200 to the drain pipe 500.

That is, normally, the drain control valve 700 is kept in the locked state to maintain the water pressure in the water pressure detection chamber 200 and to change the state of the water in the water pressure detection chamber 200 to the open state at any time according to the user's operation, (Not shown).

FIG. 3 is a side sectional view showing a chamber for detecting a hydraulic pressure according to the present invention, FIG. 4 is a plan view showing a chamber for detecting a hydraulic pressure according to the present invention, FIG. 5 is a side view showing a chamber for detecting a hydraulic pressure according to the present invention to be.

3 to 5, the water pressure detection chamber 200 includes a floating drain socket section 210, a first drain socket section 220, a second drain socket section 230, a chamber cover 240, And an O-ring 250.

The floating drainage socket unit 210 is formed to penetrate the upper surface of the water pressure detection chamber 200 so as to be connected to one end of the drain pipe 500. At this time, the suspend drainage socket unit 210 discharges the suspended body of water contained in the water pressure detection chamber 200.

The first drain socket unit 220 is connected to one end of the switch unit pipe 310. Here, the water in the water pressure sensing chamber 200 is connected to the water pressure sensing part of the pressure switch part 300 through the first drain socket part 220.

Since the switch part pipe 310 is connected to the first drain socket part 220 so that the water pressure in the water pressure detection chamber 200 coincides with the water pressure of the switch part pipe 310, It is possible to accurately detect the water pressure of the reservoir through the sensing unit.

The second drain sockets 230 are connected to one end of the gauge piping 410. Here, the water in the water pressure sensing chamber 200 reaches the pressure sensing portion of the pressure gauge unit 400 through the second drain socket unit 230.

Since the gauge part pipe 410 is connected to the second drainage socket part 230 so that the water pressure in the water pressure detection chamber 200 coincides with the water pressure of the gauge part pipe 410, And the water pressure of the storage portion can be accurately displayed through the sensing portion.

The chamber cover 240 may be connected to the one side wall of the water detection chamber 200 to be watertightly connected to the opened side wall thereof and to be detachably attached by a user's operation.

A plurality of bolt holes 242 are formed in the rim of the chamber cover 240 so that one end of the water supply pipe 100 is connected to the other end of the chamber cover 240. [ B1, B2, B3, and B4 when the chamber cover 240 is attached to one side wall of the chamber 200 for detecting a pressure of water.

Such a connection structure of the chamber cover 240 is very useful in preventing maintenance of the water pressure detection chamber 200. In addition, the cover O-ring 250 allows a tight seal between the chamber cover 240 and the one side wall that is sandwiched between the opened one side wall and the chamber cover 240.

On the other hand, since the water introduced into the water pressure detection chamber 200 from the water supply pipe 100 contains a large amount of impurities (e.g., precipitates), the impurities are supplied to the inner wall of the water pressure detection chamber 200, .

At this time, the fluid control valve 600 can be switched to a locked state according to a user's operation to shut off the movement of water through the water supply pipe 100 and to maintain the interior of the water pressure detection chamber 200 in advance.

To this end, a first drain socket unit 220 is provided to easily discharge the precipitate of water contained in the water pressure detection chamber 200 through the first drain socket unit 220 and the second drain socket unit 230, And the second drain socket part 230 may be provided through the lower surface of the water pressure detection chamber 200. [

It is preferable that the switch part pipe 310 and the first drain socket part 220, the gage part pipe 410 and the second drain socket part 230 are detachably connected to each other by user's operation. As a result, the maintenance of the water pressure detection chamber 200 can be performed easily.

100: Reservoir supply piping
200: chamber for water pressure detection
210: Float drainage socket part
220: first drain socket portion
230: second drain socket portion
240: chamber cover
241: Fasteners
242: Bolt hole
250: Cover O-ring
300: pressure switch section
310: Switch part piping
400: Pressure gauge section
410: Gauge piping
500: drain pipe
600: Fluid control valve
700: drain control valve
B, B1, B2, B3, B4: fastening bolt

Claims (10)

A water pressure detection system for detecting a water pressure of an external predetermined reservoir portion for storing water and determining whether or not the water is generated from water stored in the predetermined reservoir portion based on the detected water pressure,
A water supply piping (100) communicating with a lower portion of the predetermined reservoir portion for extracting water from the predetermined reservoir portion and providing the water to the outside to detect a lower water pressure of the predetermined reservoir portion;
A water pressure detection chamber (200) which is made of a housing closed inside and outside and communicates with the water supply pipe through a side portion to store water flowing in the water supply pipe inside to maintain the same water pressure as the water supply pipe;
Detecting a pressure of water blown out from the water pressure detection chamber by the water pressure of the water pressure detection chamber in communication with the water pressure detection chamber so as to detect the water pressure in the water pressure detection chamber, Off control command to an external power generator interlocked with the predetermined reservoir unit according to a manual set in advance by the user; And
A drain pipe (500) communicating with the water pressure detection chamber so as to drain water in the water pressure detection chamber to the outside by user's operation;
And a control unit for controlling the power generation system.
The method according to claim 1,
A pressure gauge unit (400) communicating with the hydraulic pressure detection chamber for numerically displaying the hydraulic pressure of the hydraulic pressure detection chamber;
And a pressure sensor for detecting the pressure of the hydraulic fluid.
The method of claim 2,
A switch part pipe (310) connecting the pressure switch part and the water pressure detection chamber to maintain the same water pressure as the water pressure in the water pressure detection chamber;
A gauge part pipe 410 connecting the pressure gauge part and the water pressure detection chamber to maintain the water pressure equal to the water pressure in the water pressure detection chamber;
Further comprising:
Wherein the water supply pipe, the switch portion pipe, and the gauge pipe are each composed of a steel pipe that maintains the current inner diameter from the inner pressure so that the inner water pressure can be maintained at the same level as the water pressure in the water pressure detection chamber Water pressure detection system for power generation.
delete The method of claim 3,
Characterized in that the water pressure detection chamber (200) is provided with a floating water drainage socket part (210) connected to one end of the drain pipe so as to discharge the suspended matter of water contained in the water pressure sensing chamber Hydraulic pressure detection system.
The method of claim 5,
The hydraulic pressure detection chamber 200
A first drain socket part 220 connected to one end of the switch part pipe;
A second drain socket part 230 connected to one end of the gauge part pipe;
Further comprising:
The first drain socket portion and the second drain socket portion are formed on the lower surface of the water pressure detection chamber so that the sediment of water contained in the water pressure detection chamber can be discharged through the first drain socket portion and the second drain socket portion, And a power supply for supplying power to the power generation unit.
The method of claim 6,
The hydraulic pressure detection chamber (200)
A chamber cover (240) having one side wall of the body opened and being detachably attached to an opened side wall thereof so as to be watertightly held;
A cover o-ring (250) sandwiched between the opened one side wall and the chamber cover to assist watertightness maintenance between the opened one side wall and the chamber cover;
Further comprising: a pressure sensor for detecting the pressure of the hydraulic fluid;
The method of claim 7,
A fluid control valve (600) mounted on the water supply pipe for on / off control of the flow of water moving from the water supply pipe to the water pressure detection chamber;
And a pressure sensor for detecting the pressure of the hydraulic fluid.
The method of claim 8,
A drain control valve 700 mounted on the drain pipe for on / off control of the flow of water moving from the hydraulic pressure detection chamber to the drain pipe;
And a pressure sensor for detecting the pressure of the hydraulic fluid.
The method of claim 9,
Wherein the switch portion pipe, the first drain socket portion, the gauge portion pipe, and the second drain socket portion are detachably connected in accordance with a user's operation, respectively.

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