KR200469241Y1 - Emergency drainage pump system of pumping-up electric power station - Google Patents

Abstract

The present invention is a drainage pump system 100 for discharging the discharged water collected in the bottom of the pumping station, the suction pipe 110 for sucking the discharged water from the drain pit; A high pressure water supply pipe 120 for supplying high pressure water; A discharge pipe 130 for discharging the discharge water; It includes an ejector pump 140 to suck the discharge water from the drain pit through the suction pipe 110 to the vacuum formed by the high pressure water supplied from the high pressure water supply pipe 120 to discharge through the discharge pipe 130. The high pressure water supply pipe 120 is provided with a suction valve 121, the discharge pipe 130 is provided with a check valve 131 and a discharge valve 132, the suction valve 121 Is an air driven self-holding suction valve, and the ejector pump 140 includes: a high pressure water inlet 141 through which high pressure water is introduced; A discharge water suction unit 145 through which discharge water is sucked; A chamber 146 through which the discharge water is sucked and mixed through the discharge water suction unit 145 by a vacuum formed by the high pressure water passing through the high pressure water inlet unit 141; A diffuser 147 converts velocity energy into pressure energy for the mixed water mixed in the chamber 146, and the high pressure water inlet 141 is detachably mounted to the chamber 146. A funnel inlet liner 142, a nozzle block 143 coupled to one side of the funnel inlet liner 142, and a nozzle 144 inserted into the nozzle block 143 is provided.

Description

EMERGENCY DRAINAGE PUMP SYSTEM OF PUMPING-UP ELECTRIC POWER STATION}

The present invention relates to a drainage pump system, and more particularly, to an emergency non-powered drainage pump system for a pumping station that can drain out effluent, such as leachate or effluent, accumulated in a drainage pit of a pumping station without power.

Pumped-up power plant utilizes the surplus power of low-cost generators (nuclear power, coal) to store and store water from the lower reservoir to the upper reservoir, and generates electricity during peak periods when electricity demand is high, replacing LNG and oil power generation. It contributes to the economical power generation through power distribution and efficiently load-sharing.

Since the pumping station pumps the high head from the lower dam to the upper dam, the probability of cavitation occurring in the pump suction is very high, and the pump installation position is located about 100 m below the lower dam to solve this problem.

As a result, a lot of underground discharges are generated, and if the drainage system is defective, the power plant may be flooded. It is very important, and in case of a power system failure, three power supplies (primary-on-site power, secondary-emergency generator, Tertiary-wiring line), but all drain pumps rely on electric motors, so there is no drainage method if the pump layer is flooded due to uninterruptible power failure and power plant failure.

1 is a conceptual diagram of a conventional drainage system, in which the pumping power plant drainage system 10 is provided with four pumps 11 and 12. During normal operation, the drainage pit is drained using a vertical drainage pump 912 for some reason. If the level continues to rise, the submersible drainage pump 11 is started and drained.

In addition, a predetermined valve (14, 15) is installed so that the water discharged through the drain pump can also be discharged by selecting the No. 1 or No. 2 draft tube (Draft Tube), if the discharge can not be discharged through the It is configured to be discharged out of the pumping power plant using a separate valve (13).

However, as mentioned above, in some cases there is a serious problem that the pumping power plant is flooded because there is no discharge method in the case of power supply failure, pump failure and insufficient pumping amount.

On the other hand, as a conventional pump technique, as shown in Fig. 2, a pump 21 for operating to pull up a fluid; A discharge pipe (B) connected to the pump (21) in a state filled with fluid so that a constant residual pressure is maintained therein even during a power failure; And an inlet pipe C branched from the discharge pipe B, an inlet pipe E extending from the pump 11, and an outlet pipe F for ejecting air and water sucked from the pump 11 to the outside. And a jet nozzle 22 having a venturi tube therein, wherein the water filled in the discharge pipe B is filled with the inlet pipe C through the head pressure existing in the discharge pipe B. The air inside the pump 21 is introduced into the jet nozzle 22 through the pressure difference generated by the change in the cross-sectional area of the venturi pipe while passing through the venturi pipe provided in the jet nozzle 22. It is discharged to the discharge pipe (F) through the pipe (E), to make the inside of the pump 21 in a full state of vacuum for the initial start of the pump 21, even if leakage occurs the pump 21 The pump 21 enters the inlet pipe E of the pump 21 to act as a buffer so as to maintain a degree of vacuum above a reference value capable of starting. There is an initial activatable pump system 20 has been proposed as a non-motorized comprising the tank 23 (see Patent Document 1).

[Patent Document 1] Domestic Registered Patent No. 10-1042676

In order to solve the above problems, the present invention provides a non-powered drainage pump system for a pumping station that can discharge effluent or effluent such as leachate or effluent out of the pumping station even when power supply is impossible. The purpose is to provide.

In order to achieve the above object, the pumping station emergency non-powered drainage pump system according to the present invention, a drainage pump system for discharging the effluent (leachage or effluent) to the bottom of the pumping station, for sucking the discharged water from the drain pit Suction pipe; A high pressure water supply pipe for supplying high pressure water; A discharge pipe for discharging the discharged water; And an ejector pump for sucking the discharged water from the drain pit through the suction pipe to the vacuum formed by the high pressure water supplied from the high pressure water supply pipe and discharging it through the discharge pipe, wherein the high pressure water supply pipe includes a suction valve. Is installed, the discharge pipe is provided with a check valve and a discharge valve, the suction valve is an air-driven self-holding suction valve, the ejector pump, the high-pressure water inlet for high-pressure water flows; A discharge water suction unit through which discharge water is sucked; A chamber in which the discharge water is sucked and mixed through the discharge water suction unit by a vacuum formed by the high pressure water passing through the high pressure water inlet unit; And a diffuser for converting velocity energy into pressure energy for the mixed water mixed in the chamber, and the high-pressure water inlet is detachably mounted to the chamber. And a nozzle block coupled to one side of the funnel inlet liner, the nozzle block coupled to one side of the funnel inlet liner, and a nozzle inserted into the nozzle block.

Here, a pump foot having a screen may be installed at the front end of the suction pipe to block foreign material inflow.

In addition, an air tank for supplying air to the suction valve and the discharge valve may be further provided.

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In addition, the air tank is supplied with compressor air, but a shutoff valve and a check valve are installed to always store an amount of air capable of operating the suction valve and the discharge valve in the compressor air supply line, and prevents damage to the tank. Safety facilities may be installed.

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According to the present invention, when the pumping station (underground) power supply, drainage pump failure or drainage pump operation due to power loss is impossible, the electric drive is inundated by the discharged water such as leachate or effluent so as not to lead to enormous damage There is an effect to enable the drainage of the discharged water by providing a drain pump using the pressure of the high pressure water.

1 is a conceptual diagram of a conventional drainage system.
2 is a conceptual diagram of a conventional pump system.
3 is a conceptual diagram of an emergency power-free drainage pump system for a pumping plant according to the present invention;
4 is a cross-sectional view of a pump foot according to the present invention.
5 is a cross-sectional view of the ejector pump according to the present invention.
6 is a conceptual view of an air tank according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying 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. It will be appreciated that those skilled in the art can change or modify the embodiments without departing from the scope and spirit of the invention.

3 is a conceptual diagram of an emergency non-powered drainage pump system according to the present invention, FIG. 4 is a sectional view of a pump foot according to the present invention, FIG. 5 is a sectional view of an ejector pump according to the present invention, and FIG. 6 is an air tank according to the present invention. Is a conceptual diagram.

The pumping station emergency non-powered drainage pump system according to the present invention has a technical gist that is capable of discharging effluent, such as leachate or effluent, out of the pumping station by using high pressure water pressure even in a situation where power supply is impossible.

That is, in the case of the emergency power non-powered drainage pump system of the pumping station according to the present invention, the pumping station has most of the main power generation facilities installed underground to discharge the underground drainage to the outside for protection of the facility when the effluent or effluent overflows. It is a system for.

As shown in the drawings, the pumping station emergency non-powered drainage pump system 100 according to the present invention is a drainage pump system for discharging effluent (leachate or effluent) that accumulates in the bottom of the pumping station, and largely suction pipe 110, It comprises a high pressure water supply pipe 120, discharge pipe 130, ejector pump 140 and air tank 150.

Pumping power station emergency non-powered drainage pump system 100 according to the present invention configured as described above is capable of always operating regardless of the power supply using a mechanical or air.

The suction pipe 110 is installed to suck the discharged water from the drain pit. In this case, a pump foot 111 having a screen 111a may be installed at the front end of the suction pipe 110 to block foreign material from entering.

In general, the foot valve (Foot Valve) may be a situation in which the pump can not play a role due to the stick in the emergency situation is that the valve footless pump foot 111 is installed. This is because it is not necessary to fill the suction side with water due to the characteristics of the ejector pump 140, only to have the screen 111a in fear of deterioration of the pump performance due to excessive inflow of foreign matter into the ejector pump 140.

The high pressure water supply pipe 120 is installed to supply high pressure water, and a predetermined air driven self-holding suction valve 121 may be installed in the high pressure water supply pipe 120.

The discharge pipe 130 is installed to discharge the discharge water, the check pipe 131 and the discharge valve 132 may be installed in the discharge pipe 130.

The ejector pump 140 is a vacuum formed by the high pressure water supplied from the high pressure water supply pipe 120 to suck the discharged water from the drain pit through the suction pipe 110 to discharge through the discharge pipe 130. Play a role.

At this time, the ejector pump 140, the high-pressure water inlet 141 through which the high-pressure water is introduced, the high-pressure water passed through the high-pressure water inlet 141, the discharge water suction unit 145, the high-pressure water inlet 141, for example, about Rate energy is applied to the chamber 146 and the mixed water mixed in the chamber 146 in which the discharge water is sucked and mixed through the discharge water suction unit 145 by a vacuum formed by 50 to 60 kg / cm ² ). It may include a diffuser 147 to convert to.

And, the high-pressure water inlet 141, as shown in Figure 5, may be detachably mounted to the chamber 146, such as bolt fastening, funnel-type inlet liner 142, the funnel It may include a nozzle block 143 coupled to one side of the inlet liner 142 and a detachable nozzle 144 inserted into the nozzle block 143. Therefore, the nozzle block 143, the nozzle 144 and the like can be easily disassembled and easily maintained.

For reference, the shape and size of the chamber 146, the angle of the nozzle block 143, the angle of the diffuser 147, the aperture of the nozzle 144, etc. should be designed in proportion to the amount of discharged water.

The air tank 150 is installed to supply air to the intake valve 121 and the discharge valve 132. In this case, the air tank 150 is supplied with compressor air located in the pumping power plant, and is cut off to always store an amount of air capable of operating the suction valve 121 and the discharge valve 132 in the compressor air supply line. The valve 151 and the check valve 152 may be installed. In addition, a safety facility 153 may be installed at an upper portion of the air tank 150 to prevent damage to the tank when the pressure is excessively increased.

Referring to the operation of the pumping station emergency non-powered drainage pump system 100 according to the present invention is as follows.

When the drainage pump operation is impossible due to the failure of the drainage pump or the power supply in the pumping station, the high pressure water supply pipe 120 is connected to the ejector pump 140 of the pumping station emergency non-powered drainage pump system 100 of the present invention. From the high pressure water is supplied. Then, the chamber 146 of the ejector pump 140 is in a vacuum state by the supplied high pressure water, and by the vacuum sucks the discharged water from the drain pit through the suction pipe 110 to discharge through the discharge pipe 130 Let's go.

As described above, in the conventional pumping station drain pump system, only a motor pump driven by a power source is installed, so that there is no provision for power loss, but the emergency drain pump system 100 according to the present invention is used in If the drainage pump is unable to operate due to a failure of the drainage pump or loss of power, the drainage of the discharged water is provided by providing a drainage pump using the pressure of high-pressure water rather than electric drive so that the pumping power plant by the effluent or the effluent is not flooded and connected to enormous damage. It is possible to further improve the reliability of the system.

On the other hand, although the emergency power non-powered drainage pump system according to the present invention has been described according to a limited embodiment, the scope of the present invention is not limited to a specific embodiment, it will be apparent to those skilled in the art related to the present invention. Various alternatives, modifications, and changes can be made within the scope.

Therefore, the embodiments disclosed in the present invention and the accompanying drawings are intended to illustrate and not to limit the technical idea of the present invention, and the scope of the technical idea of the present invention is not limited by these 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 which are within the scope of the same should be interpreted as being included in the scope of the present invention.

100: drain pump system 110: suction pipe
111: pump foot 120; Supply piping
121: suction valve 130: discharge piping
131: check valve 132: discharge valve
140: ejector pump 141: high pressure water inlet
142: inlet liner 143: nozzle block
144: nozzle 145: discharge water suction
146: chamber 147: diffuser
150: air tank 151: suction valve
152: check valve 153: safety equipment

Claims (8)

As a drainage pump system 100 for discharging effluent (leakage or effluent) accumulated in the bottom of the pumping power plant,
A suction pipe 110 for sucking discharge water from the drain pit;
A high pressure water supply pipe 120 for supplying high pressure water;
A discharge pipe 130 for discharging the discharge water;
It includes an ejector pump 140 to suck the discharge water from the drain pit through the suction pipe 110 to the vacuum formed by the high pressure water supplied from the high pressure water supply pipe 120 to discharge through the discharge pipe 130. Done by
The high pressure water supply pipe 120 is provided with a suction valve 121,
The discharge pipe 130 is provided with a check valve 131 and the discharge valve 132,
The suction valve 121 is an air driven self-holding suction valve,
The ejector pump 140,
A high pressure water inlet 141 through which high pressure water is introduced;
A discharge water suction unit 145 through which discharge water is sucked;
A chamber 146 through which the discharge water is sucked and mixed through the discharge water suction unit 145 by a vacuum formed by the high pressure water passing through the high pressure water inlet unit 141;
It is provided with a diffuser 147 for converting the velocity energy into pressure energy for the mixed water mixed in the chamber 146,
The high pressure water inlet 141 is detachably mounted to the chamber 146. Pumping inlet liner 142, a nozzle block 143 coupled to one side of the funnel inlet liner 142 and a nozzle 144 inserted into the nozzle block 143 for emergency Non-powered drain pump system. The method according to claim 1,
A pump foot 111 having a pump 111 having a screen 111a is installed at the front end of the suction pipe 110 to block foreign substances from entering. delete delete The method according to claim 1,
Emergency pumping power drainage system for pumping power station, characterized in that it further comprises an air tank (150) for supplying air to the intake valve (121) and the discharge valve (132). The method according to claim 5,
Compressor air is supplied to the air tank 150, and a shutoff valve 151 is configured to always store an amount of air capable of operating the intake valve 121 and the discharge valve 132 in the compressor air supply line. Check valve 152 is installed,
Emergency power non-powered drainage pump system for a pumping station, characterized in that a safety facility (153) is installed to prevent tank damage. delete delete

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