KR101698139B1 - Power generation apparatus using a barge - Google Patents

Abstract

The present invention relates to a coolant power generation device using a barge. In order to generate power with a coolant, discharged from a discharge pipe to a reservoir, when the coolant, supplied to a cooling system of a thermoelectric power plant, is pumped through an intake and then stored in the reservoir, the prevention invention is capable of generating power by installing a turbine, rotated by the coolant discharged from the discharge pipe, on a barge floating on the reservoir. The present invention comprises: a reservoir including a discharge pipe discharging a coolant pumped from a thermoelectric power plant to an intake; a barge floating on the coolant in the reservoir, having a predetermined width, and fixed to a wall surface of the reservoir; a turbine installed in a turbine placement hole formed in the upper part of the barge with a predetermined width; a coolant inducing pipe combined with the discharge pipe to supply the coolant to the turbine; a hydraulic cylinder installed on the front side of the turbine placement hole to move the turbine forward or backward; and a power generator combined with the turbine to generate power.

Description

Technical Field [0001] The present invention relates to a power generation apparatus using a barge,

In the present invention, when cooling water to be supplied to a cooling system of a thermal power plant is pumped by a water intake port and stored in a water storage tank, the turbine rotated by the cooling water discharged from the discharge pipe is floated on the water storage tank The present invention relates to a cooling water generator using a barge that is installed on a true barge to generate electric power.

Since thermal power generation uses steam turbines to generate power, it requires cooling water using seawater or river water. Such cooling water is pumped to fill a certain amount in a water tank, and is used for cooling water 10-005843, and 10-1393854 have been proposed for the small-scale hydroelectric power generation using the conventional discharge water, and a genera- tion device using general discharge water has been proposed in the patent publication 10-2003-0046282.

In the water tank used for supplying the cooling water of the thermal power generation, the cooling water is pumped to the intake port and then filled through the discharge pipe. However, since the cooling water discharged from the discharge pipe is not high, Is disclosed in Patent Registration No. 10-1189213.

1, the discharge port 20 is formed on the upper side of the water storage tank 10 installed in the thermal power plant and the cooling water pumped in the water intake pipe is discharged from the discharge port 20 and collected in the water storage tank 10 A turbine 30 is installed to fix the frame 40 to the lower side of the discharge port 20 for supplying the cooling water to the water storage tank 10 and to convert the falling water of the cooling water and the energy of water into rotational energy, 30 is provided with a generator 50 for converting rotational energy into electric energy and the rotational force of the turbine 30 is transmitted through a power transmission shaft 41 coupled to the shaft coupling 42 The power generating apparatus can withstand the weight of the turbine 30 and the generator 50 even when the turbine 30 is installed by fixing the frame 40 to the water storage tank 10 because the amount of the cooling water discharged to the discharge port 20 is large. Can not expose the problem In addition, in the case where a large amount of water is discharged to the discharge port 20 at the same time in the stopped state, there is a problem that the impact applied to the turbine 30 is large and the turbine 30 is damaged. There is a problem in that the turbine 30 can not be approached around the turbine 30.

In the present invention, when a frame is fixed to a water tank to generate cooling water discharged from a discharge pipe for discharging cooling water to a water tank installed in a thermal power plant, when the turbine is installed, the weight of the turbine, In order to solve the problem that the turbine is suddenly exposed to a large amount of cooling water to be deformed or broken when the supply of the cooling water is resumed, The turbine generator is installed in the barge after the barge line is installed in the water tank. The turbine generator is installed to allow the turbine to withstand a heavy load while the barge is used to move the turbine back and forth. To make progress without giving Will.

The present invention relates to a water supply system comprising a water storage tank having a discharge pipe for discharging cooling water pumped from a thermal power plant to a water intake port, a barge floated on the cooling water filled in the water storage tank and fixed to a wall surface of the water storage tank, A cooling water guide pipe connected to the discharge pipe to supply cooling water to the turbine, a hydraulic cylinder installed on the front of the turbine parking hole to move the turbine back and forth, a generator When the cooling water pumped by the intake port is discharged through the cooling water induction pipe, the turbine is rotated to generate electricity in the generator. The turbine is moved to the hydraulic cylinder, and the rotation by the cooling water is gradually performed. .

The turbine hall hole of the present invention prevents the generation of bubbles by covering the turbine, and the cooling water induction pipe and the barge are fixed to the wall surface of the water storage tank by using a shock absorber.

In the present invention, two cooling water induction pipes may be installed in one discharge pipe, and two turbines may be installed in a barge line to generate power.

The present invention is characterized in that a barge is installed on a barge and a turbine and a generator are installed on a barge so that power is generated by cooling water discharged from the discharge pipe after the barge line is floated on a water tank filled with cooling water for thermal power generation, The turbine generator can be made to bear the weight of the turbine generator which is to be generated by the cooling water discharged to the water tank by the barge while the barge line can be used to access the turbine generator under power generation, There is an effect that the turbine is gradually moved by the cooling water so that the turbine is not subjected to an impact load by the cooling water.

1 is a schematic diagram of a conventional power generation apparatus
Fig. 2 is a perspective view of the installation state of the present invention.
Fig. 3 is a side sectional view
Fig. 4 is a plan view
5 is a state sectional view in which power generation is performed in the present invention
6 is a cross-sectional view of a state where power generation is not performed in the present invention
FIG. 7 is a cross-sectional view of the cover in the present invention
8 is a state plan view
9 is a plan view showing a state in which power generation is not performed in the present invention

The present invention relates to a method of generating power by using a downfall and a quantity energy of cooling water discharged when cooling water is filled in a water storage tank for storing cooling water, which is essential for a thermal power plant, and a turbine and a generator are installed on the barge And a cooling water induction pipe is installed in the discharge pipe to allow the cooling water to rotate the turbine installed on the barge line. The turbine can be moved back and forth as needed. When the cooling water supply is resumed, So as not to be damaged by the shock load of the cooling water applied to the turbine.

The turbine of the present invention is installed in a turbine hall hole opened at the bottom of a water tank, and a turbine installed in the turbine hole is rotated by cooling water discharged through a cooling water induction pipe at a water intake port. The generator is axially coupled, and the turbine and generator are moved back and forth using a hydraulic cylinder, but pulling the bearing box.

When the turbine of the present invention moves forward and moves away from the bottom of the nozzle, the upper part of the turbine guard hole is covered with a cover to prevent the generation of bubbles and two cooling water induction pipes can be installed in one discharge pipe. A turbine and a generator must be installed, and the turbine must be installed to be movable back and forth by a hydraulic cylinder together with the generator.

The cooling water induction pipe and the barge wire of the present invention are installed on the wall surface of the water tank, and they are installed with the buffer device therebetween, so that shocks applied to the cooling water induction pipe and the barge wire can be buffered when power generation by the cooling water occurs, The cooling water induction pipe is supported on the bottom of the water storage tank using a pedestal, and a nozzle is provided at the tip of the cooling water induction pipe so that the cooling water is discharged to the turbine at an optimum angle.

According to the present invention, the cooling water is discharged to the cooling water induction pipe, and the turbine installed in the turbine seat hole and the generator installed on the barge are moved to the hydraulic cylinder so as to prevent the sudden start of the turbine, When doing so, retract the turbine and generator to keep it away from the nozzle and cover it.

In the present invention, two cooling water induction pipes are installed in one discharge pipe, and a turbine is installed by drilling two turbine holes in a barge, and a generator axially coupled with the turbine is driven forward and backward When the turbine and generator reach normal power generation position, they should be firmly fixed to the barge using fixing bolts or the like in order to prevent movement of the turbine and generator. If movement is necessary, loosen fixing bolts and use hydraulic cylinders .

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

In the present invention, the motor 110 is driven in the intake port 100 to cool the pumped cooling water through the discharge pipe 120 into the water storage tank 1000, The barge 200 is installed on the wall surface 1001 of the water storage tank 1000 through a shock absorber 230 so that the water is supplied to the water tank 1000, A turbine 300 is installed in the turbine hole 210 after the barge 200 is pierced through the turbine hole 210 and a turbine 300 installed in the turbine hole 210 The cooling water is supplied from the cooling water induction pipe 150 installed in the discharge pipe 120 and the cooling water is discharged through the nozzle 160 installed at the end of the cooling water induction pipe 150, Is coupled via a wall surface (1001) and a shock absorber (130) while the bottom surface is connected to the barge line 0 by a pedestal 140 on the upper side.

Here, the cooling water induction pipe 150 has a diameter gradually reduced toward the outlet rather than an inlet, and the height thereof is lowered so that the cooling water is pressurized.

A turbine 300 is installed in the turbine hall hole 210 formed in the barge 200 and a bearing box 310 supporting the turbine 300 is installed on the barge 200, The generator 400 can be moved back and forth by a sliding means 330 such as an LM guide or a roller and the generator 400 connected to the turbine 300 by coupling is installed on the barge 200, And the other end of the hydraulic cylinder 500 fixed to the barge 200 is coupled to the bearing box 310 so that the hydraulic cylinder 500 500 so that the turbine 300 and the generator 400 are moved back and forth by means of the sliding means 330. [

The turbine 300 installed in the turbine placement hole 210 of the present invention drills the turbine placement hole 210 so that the turbine 300 can be moved to a position not to be exposed to the cooling water discharged from the nozzle 160 by the hydraulic cylinder 500, When the turbine 300 and the generator 400 are retreated to the hydraulic cylinder 500 and the turbine 300 and the generator 400 are fixed to the barge 200 using the fixing bolts, The turbine 300 and the generator 400 are prevented from moving by hydraulic pressure during the process.

That is, if the turbine 300 and the generator 400 are advanced to the sliding means 330 by the hydraulic cylinder 500 after the fixing bolts are pulled, the cooling water discharged from the nozzle 160 installed in the cooling water induction pipe 150 The turbine 300 is not brought into contact with the turbine 300, and in this state, since the bubbles are generated, the cover 600 covering the turbine seat hole 210 is installed to reduce the generation of bubbles.

The present invention is characterized in that two cooling water induction pipes 150 are provided in one discharge pipe 120 and the nozzles 160 are connected to the respective cooling water induction pipes 150 so that cooling water discharged from the cooling water induction pipe 150 So that the turbine 300 is smoothly rotated. In this case, two turbine holes 210 are also formed in the barge 200 And two turbines 300 are installed.

In the present invention, the choice of installing only one turbine 300 or two turbines 300 is selected according to the quantity of cooling water discharged to the discharge tube 120, and the cooling water is supplied to the turbine 300 And then is filled in the water storage tank 1000 through the turbine hole 210. [

The present invention having such a structure is configured such that when the pump 110 of the intake port 100 is driven to fill the cooling water into the water storage tank 100 and the cooling water is discharged to the discharge pipe 120, The turbine 300 is rotated by using the position of the cooling water and the energy of the water to generate electricity in the generator 400 while the turbine 300 and the generator 400 are installed on the barge 200 floated on the water storage tank 1000 And the turbine 300 is rotated in the barge 200 to form a turbine hole 210 through which the cooling water moves to the water storage tank 1000.

Before the cooling water is discharged to the discharge pipe 120, the turbine 300 is mounted on the sliding means 330 by using the hydraulic cylinder 500, one side of which is fixed to the barge 200 and the other side is fixed to the bearing box 310, And the generator 400 is pulled forward so that the cooling water does not reach the turbine 300 even if the cooling water is discharged to the nozzle 160.

In this state, when the motor 110 is driven to pump the cooling water to the intake port 100 and the cooling water is discharged to the discharge pipe 120, the cooling water flows from the discharge pipe 120 through the cooling water induction pipe 150 to the rear nozzle 160 The turbine 300 is discharged to the turbine hole 210 of the barge 200. At this time, the turbine 300 does not contact the cooling water, so that the turbine 300 is not rotated.

In order to generate electricity, the pump 110 of the intake port 100 is driven to discharge the gas to the discharge pipe 120, and the cooling water discharged to the discharge pipe 120 is discharged from the cooling water induction pipe 150 to the nozzle 160 When the hydraulic cylinder 500 is operated at this time, the hydraulic cylinder 500 retracts the bearing box 310 by using the sliding means 330, so that the turbine 300 is rotated by the nozzle 160, .

The turbine 300 is slowly rotated backward by the hydraulic cylinder 500 and rotated by the cooling water discharged from the nozzle 160. The rotation of the turbine 300 is delayed when the cooling water touches a little, The reason why the cooling water is gradually applied to the turbine 300 is that when a large amount of cooling water is applied to the turbine 300, the turbine 300 is deformed or damaged due to the impact The turbine 300 is gradually moved so as to gradually reach the cooling water discharged from the nozzle 160 to increase the rotation speed.

The turbine 300 and the generator 400 are retracted by the sliding means 330 with the hydraulic cylinder 500 as in the present invention and the turbine 300 and the turbine 400 are fixed to the bottom of the barge 200, 300 and the generator 400 are fixed to each other so that the movement is not caused by the impact generated when the cooling water touches the turbine 300 and the weight load can be handled by the barge line 200.

The turbine 300 moves back and forth in the turbine hole 210 and the generator 400 moves back and forth in the barge 200. The cooling water discharged from the nozzle 160 rotates the turbine 300, And is filled in the water storage tank 1000 through the hole 210.

If the operation of the pump 110 is stopped in order to stop the power generation in this state, the cooling water is not discharged, so that the rotation of the turbine 300 is gradually stopped and the rotation of the turbine 300 is stopped The turbine 300 and the generator 400 are advanced by using the hydraulic cylinder 500 after the fixing bolts fixing the turbine 300 and the generator 400 to the barge 200 are released and the turbine 300 210 are covered with a lid 600 to prevent foaming from occurring.

Although only one turbine 300 and the generator 400 are described in the present invention, the two cooling water induction pipes 150, the turbine 300 and the generator 400 can be installed and operated One or two turbine 300 may be selectively used depending on the amount of cooling water withdrawn from the intake port 100. The choice of utilizing one turbine 300 or utilizing the two turbines 300 may be performed by any one of ordinary skill in the art Can easily be changed and carried out by those having knowledge of the present invention.

100: intake port 110: motor
120: Discharge tube 130:
150: Cooling water induction pipe 160: Nozzle
200: Barge 210: Turbine Anchor Hole
230: Shock Absorber 300: Turbine
310: Bearing box 339: Sliding means
400: generator 500: hydraulic cylinder
600: cover 1000: water tank
1001: Wall

Claims (3)

A water storage tank (1000) having a discharge pipe (120) through which cooling water pumped to the water intake port (100) is discharged;
A nozzle 160 coupled to the tip of the cooling water induction pipe 150 coupled to the discharge pipe 120 to discharge the cooling water;
A barge 200 floated on the cooling water filled in the water storage tank 1000 and having a predetermined width and fixed to the wall surface 1001 of the water storage tank 1000 and formed with a turbine water hole 210 having a predetermined width;
A turbine 300 installed in the turbine hole 210 of the barge 200 and rotated by cooling water discharged through the nozzle 160;
A hydraulic cylinder 500 having one side fixed to the front barge 200 of the turbine seat hole 210 is installed and the other side of the hydraulic cylinder 500 is coupled to a bearing box 310 supporting the turbine 300 A hydraulic cylinder 500 for moving the turbine 300 back and forth;
And a generator 400 installed in an upper portion of the barge 200 and axially coupled with the turbine 300 while being moved back and forth along the sliding means 330 together with the turbine 300 by a hydraulic cylinder 500 In addition,
When the cooling water is discharged from the nozzle 160, the turbine 300 and the generator 400 are gradually advanced to the hydraulic cylinder 500 to increase the rotation speed of the turbine 300, And is fixed to the barge line (200) so that power generation is performed. delete And a water storage tank (1000) provided with a discharge pipe (120) for discharging cooling water pumped to the water intake (100)
A barge 200 floated on the cooling water filled in the water storage tank 1000 and fixed to the wall surface 1001 of the water storage tank 1000 with a predetermined width,
And a turbine (300) installed in a turbine hole (210) opened at an upper portion of the barge line (200)
Two cooling water induction pipes 150 for supplying cooling water to the turbine 300 are installed in the discharge pipe 120. The cooling water induction pipe 150 is formed such that the inlet is formed to have a larger sectional area than the outlet and the height is set higher ,
The turbine 300 is positioned below the nozzle 160 installed at the tip of the cooling water induction pipe 150 so as to be rotated by the cooling water,
And a hydraulic cylinder 500 installed on the barge 200 in front of the turbine position hole 210 to move the turbine 300 installed in the two turbine holes 210 forward and backward,
And a generator 400 that is shaft-coupled to the turbine 300 to generate electric power and the generator 400 is moved along with the turbine 300 by the hydraulic cylinder 500 in the forward and backward directions A cooling water generator using a barge.

Images