KR101239777B1 - Geothermal power generation system using heat exchange of exhaust gas and molten salt - Google Patents

Abstract

PURPOSE: A geothermal power-generation system using heat exchange between waste gas and molten salt is provided to generate mechanical energy using steam energy when a second turbine part is connected to a latent heat collection part and to generate electric power using mechanical energy when a second generating part is connected to the second turbine. CONSTITUTION: A geothermal power-generation system using heat exchange between waste gas and molten salt comprises a waste gas moving part(100), a plurality of molten salt accommodating parts(200), a plurality of working fluid accommodating parts(300), a turbine part(600), and a generating part(700). The working fluid accommodating parts accommodates the working fluid which is delivered by heat exchange with a heating source of the molten salt at the inner part and is separated at a constant interval while individually surrounding the molten salt accommodating part. The turbine part is connected to the working fluid accommodating parts and generates mechanical energy using steam which is generated in the working fluid accommodating parts. The generating part is connected to the turbine part and generates electric power using the mechanical energy. The working fluid accommodating part includes a U-shaped pipe which includes a spiral fin for increasing the heating surface area in the outer circumference.

Description

Geothermal power generation system using heat exchange of exhaust gas and molten salt}

The present invention relates to a geothermal power generation system using heat exchange of waste gas and molten salt, and more particularly, to a geothermal power generation system capable of generating electricity by heat exchanging waste gas and molten salt.

Geothermal power is generated by receiving heat in the form of steam or hot water in the underground hot layer. Geothermal heat is the energy of hot water and rocks that are several kilometers deep from the shallow surface of the earth.

When hot steam is obtained from underground, it is led to a steam turbine and the turbine is rotated at high speed to generate power by a generator connected directly thereto. If the steam spouted from the basement is low in moisture, it can be sent directly to the turbine. However, when spouted as hot water, the heat is sent to a heat exchanger and the water is evaporated and sent to the turbine. Alternatively, when the water temperature is low, the lower boiling liquid may be evaporated and sent to the turbine.

Since geothermal power generation does not require fuel in principle, it is clean energy without the environmental pollution caused by fuel combustion. However, a small amount of hydrogen sulfide is contained in the non-condensable gas emitted from geothermal wells. At present, the concentration is low and less than the environmental standard, so there is no problem, but if a large amount is to be ejected in the future, a desulfurization device will be required. In addition, trace amounts of arsenic are contained in the hot water, and all of them are reduced back to the basement after power generation. However, if economic dearsenic technology is established, this hydrothermal water can also be used as a valuable low temperature heat energy source.

Most of geothermal power costs come from the construction cost of geothermal power plants and the excavation cost of geothermal wells, which also depend on the quality of geothermal resources and the type of power generation. However, the power plant is small compared to the thermal power and nuclear power, but it is economical and has the characteristics of a small decentralized local energy resource.

1 is a schematic view showing the configuration of a geothermal power generation apparatus using a conventional high temperature and high pressure compressed air.

For example, Korean Patent Application No. 10-2010-0115466 introduces a geothermal power generation device using a high temperature and high pressure compressed air, the application is shown in Figure 1, the purpose of the temperature reduction at the rear end of the compressor (4) By removing the cooler to be installed, and by performing artificial geothermal power generation using the characteristics of the high temperature / high pressure compressed air generated by the compressor (4) it can improve the efficiency of the compressed air storage power generation.

2 is a schematic view showing the configuration of a conventional low temperature geothermal power generation device.

In addition, Korean Patent Application No. 10-2010-0063987 discloses a low-temperature geothermal power generation apparatus, the application is shown in Figure 2, the superheater (superheater) for geothermal power generation using geothermal water below 100 ℃ 20, a post pressure pump 40 and a preheater 60, by driving the preheater 60 using the residual heat of geothermal water from the vaporizer 4; By raising the temperature and enthalpy of the secondary fluid to some extent, the efficiency of the vaporizer 4 is increased, and the temperature of the secondary fluid vaporized by the superheater 20 is raised as a result of increasing the pressure, By increasing the pressure of the secondary fluid flowing into the turbine (6) by reducing the pressure of the vaporizer 4 and the superheater 20, the efficiency of the vaporizer 4 can be increased and the flow rate of the superheater 20 can be maintained. Therefore, even if you use relatively low-temperature geothermal water Excessive development can be undertaken.

On the other hand, hot steam or water drawn from underground in geothermal power generation is not a renewable energy in the strict sense. Heat storage is now decreasing because the amount of geothermal heat dissipated for generation is greater than the recharge capacity of the reservoir. It will take a long time, but when hot water or steam is depleted in the ground and the hot rock layer cools, there is a problem that it can no longer raise heat. Therefore, it is necessary to develop another energy system and convert it into geothermal energy for geothermal power generation.

The present invention has been invented to solve the above problems, to provide a geothermal power generation system using heat exchange of waste gas and molten salt which can generate electricity by rotating the turbine by heat exchange of waste gas and molten salt. There is this.

Geothermal power generation system using the heat exchange of the waste gas and molten salt according to the present invention to achieve the object as described above is a waste gas moving unit to move the waste gas; A plurality of molten salt containing portions accommodating the molten salt, which receives the waste heat of the waste gas by heat exchange therein, and installed at a predetermined interval on the ground; A plurality of working fluid receiving parts accommodating the working fluids receiving the heat source of the molten salts by heat exchange therein and being spaced at regular intervals on the ground while surrounding the respective molten salt receiving parts; A turbine unit connected to the working fluid receiving unit to generate mechanical energy using steam generated from the working fluid receiving unit; And a power generation unit connected to the turbine unit to generate electrical energy by using the mechanical energy, wherein the working fluid receiving unit is formed of a U-shaped tube having a spiral fin to increase a heat transfer area on an outer circumferential surface thereof. The working fluid is received inside the working fluid receiving part through an inlet of the working fluid receiving part, is heated by heat exchange of the molten salt contained in the molten salt receiving part by heat exchange, and is generated by evaporation of the heated working fluid. Steam flows to the turbine portion through the outlet of the working fluid receiving portion.

In addition, the molten salt receiving portion is characterized in that the upper side is connected to the waste gas moving portion and the lower side is formed of a straight pipe inserted into the ground.

In addition, the working fluid receiving portion is characterized in that the inlet is exposed on the ground, the outlet is connected to the turbine portion, respectively.

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In addition, the working fluid receiving portion is characterized in that the adjacent U-shaped pipes are formed integrally with each other.

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In addition, the geothermal power generation system using the heat exchange of the waste gas and molten salt according to the present invention is a waste gas moving unit for moving the waste gas; A plurality of molten salt accommodating parts having an upper side connected to the waste gas moving part and having a lower side spaced apart from each other by a predetermined interval, and receiving molten salt which receives waste heat of the waste gas by heat exchange therein; A heat transfer part installed in the ground and into which the working gas which receives the heat source of the molten salt is transferred by heat exchange; A turbine unit connected to the heat transfer unit to generate mechanical energy using a heated working gas; And a power generation unit connected to the turbine unit to generate electrical energy using the mechanical energy, wherein the heat transfer unit includes at least one gas inlet hole through which the working gas is introduced; A crack part that is a movement path of the working gas; And at least one gas outlet hole through which the working gas flows out, wherein the working gas flows into the heat transfer part through the gas inlet hole and moves through the crack part and is accommodated in the molten salt receiving part. The heat source of the molten salt is received by heat exchange and heated, and the heated working gas flows out of the heat transfer unit through the gas outlet hole and flows to the turbine unit.

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In addition, the heat transfer unit is characterized in that it is configured to perform the grouting so that the working gas introduced into the upper and side so that the heat-exchanged working gas flows out through the gas outlet hole.

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As described above, the geothermal power generation system using heat exchange between waste gas and molten salt according to the present invention has the effect of generating electricity by rotating the turbine by heat exchange between waste gas and molten salt.

1 is a schematic view showing the configuration of a geothermal power generation apparatus using a conventional high temperature and high pressure compressed air.
2 is a schematic view showing the configuration of a conventional low temperature geothermal power generation device.
3 is a configuration diagram of a geothermal power generation system using heat exchange between waste gas and molten salt according to a first embodiment of the present invention.
Figure 4 is a block diagram of the working fluid receiving portion according to the present invention.
Figure 5 is a view showing a state in which a plurality of working fluid receiving unit is connected integrally according to the present invention.
6 is a configuration diagram of a geothermal power generation system using heat exchange between waste gas and molten salt according to a second embodiment of the present invention.
7 is a configuration diagram of a geothermal power generation system using heat exchange between waste gas and molten salt according to a third embodiment of the present invention.
8 is a configuration diagram of a heat transfer unit according to the present invention.
9 is a view showing a state in which the working gas according to the invention moves through the crack formed in the heat transfer unit.
10 is a configuration diagram of a geothermal power generation system using heat exchange between waste gas and molten salt according to a fourth embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, it should be noted that the same components or parts among the drawings denote the same reference numerals whenever possible. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as not to obscure the subject matter of the present invention.

3 is a configuration diagram of a geothermal power generation system using heat exchange between waste gas and molten salt according to a first embodiment of the present invention.

As shown in FIG. 3, the geothermal power generation system using heat exchange between waste gas and molten salt according to the first embodiment of the present invention includes a waste gas moving unit 100, a plurality of molten salt receiving units 200, and a plurality of working fluids. It includes a receiving unit 300, the turbine unit 600 and the power generation unit 700.

The waste gas moving unit 100 is a pipe through which waste gas discharged from a combustion device, a roaster, a melting furnace, a prime mover, etc. moves, and the waste gas includes waste heat that is a residual heat.

The molten salt receiving unit 200 may accommodate the molten salt that receives the waste heat of the waste gas by heat exchange therein, and may be installed spaced apart from the ground.

Specifically, the molten salt receiving unit 200 may be formed of a straight pipe, the molten salt receiving unit 200 is connected to the waste gas moving unit 100 on the upper side, the molten salt is the waste gas moving unit 100 The heat source can be received from, and the heat source of the molten salt can be transferred to the ground by being inserted into the ground.

The working fluid receiving unit 300 accommodates the working fluid that receives the heat source of the molten salt by heat exchange therein, and may be installed at a predetermined interval on the ground while wrapping the respective molten salt containing parts 200. .

Specifically, the working fluid receiving portion 300 may be formed of a U-shaped tube, the upper side is exposed on the ground and the lower side is inserted into the ground, the U-shaped tube is open inlet exposed on the ground The outlet may be configured to be connected to the turbine unit 600 to be described later.

Here, the working fluid accommodated in the working fluid receiving unit 300 may be made of water, the working fluid is accommodated in the tube through the inlet, and receives the molten salt receiving unit 200 or the heat source in the ground The heated and steam generated by the evaporation of the heated working fluid may flow to the turbine unit 600 through the outlet.

Figure 4 is a block diagram of the working fluid receiving portion according to the present invention.

On the other hand, the working fluid receiving unit 300, as shown in Figure 4, the spiral pin 310 may be provided on the outer peripheral surface of the U-shaped tube, the spiral pin 310 is the working fluid receiving unit ( By increasing the heat transfer area of 300) it is possible to increase the heating efficiency of the working fluid.

Figure 5 is a view showing a state in which a plurality of working fluid receiving unit is connected integrally according to the present invention.

In addition, the working fluid receiving unit 300 may be formed integrally with a plurality of adjacent U-shaped pipes connected to each other, specifically, the working fluid receiving unit 300, as shown in FIG. The inlet of the U-shaped tube is open, the outlet and the inlet of the adjacent U-shaped tube is connected to each other, the outlet of the final U-shaped tube may be configured to be connected to the turbine unit 600 to be described later.

Therefore, the working fluid is accommodated inside the pipe through the inlet of the first U-shaped pipe, is heated by receiving the molten salt receiving portion 200 or the heat source in the ground, the steam generated by the evaporation of the heated working fluid May flow to the turbine portion 600 through the outlet of the final U-shaped tube.

The turbine unit 600 may be connected to the working fluid receiving unit 300 to generate mechanical energy using steam energy generated by the working fluid receiving unit 300.

The power generation unit 700 may be connected to the turbine unit 600 to generate electrical energy using the mechanical energy.

Hereinafter, a geothermal power generation system using heat exchange between waste gas and molten salt according to a second embodiment of the present invention will be described in detail.

6 is a configuration diagram of a geothermal power generation system using heat exchange between waste gas and molten salt according to a second embodiment of the present invention.

As shown in FIG. 6, a geothermal power generation system using heat exchange between waste gas and molten salt according to a second embodiment of the present invention includes a waste gas moving unit 100, a plurality of molten salt receiving units 200, and a plurality of working fluids. The accommodation unit 300 includes a latent heat recovery unit 500, a first turbine unit 610, a second turbine unit 620, a first power generation unit 710, and a second power generation unit 720.

The waste gas moving unit 100, the molten salt receiving unit 200, and the working fluid receiving unit 300 are waste gas moving units included in the geothermal power generation system using heat exchange between the waste gas and the molten salt according to the first embodiment of the present invention. The molten salt accommodating part and the working fluid accommodating part and their configuration and content are the same, and thus detailed descriptions thereof will be omitted.

The latent heat recovery part 500 may be installed in the ground while surrounding the molten salt receiving part 200 and the working fluid receiving part 300 to recover latent heat generated by the phase change of the molten salt by heat exchange. .

Specifically, the latent heat recovery unit 500 may be a Rankine cycle for circulating and exchanging heat by circulating water. In the latent heat recovery unit 500, the latent heat recovery unit 500 performs adiabatic compression, isothermal heating. In addition, latent heat can be recovered by heat exchange by circulating with adiabatic expansion and isothermal heat with a phase change of vapor and liquid.

In addition, in the second embodiment, the latent heat recovery unit 500 may include a Brayton cycle in which heat is exchanged by circulating gas, and the latent heat recovery unit 500 circulates compressed air to provide latent heat. After recovery by heat exchange, fuel may be injected to produce combustion gases.

The first turbine part 610 is connected to the working fluid receiving part 300 and may generate mechanical energy using steam energy generated by the working fluid receiving part 300.

The second turbine 620 is connected to the latent heat recovery unit 500 and may generate mechanical energy using steam energy generated by the latent heat recovery unit 500.

The first generator 710 may be connected to the first turbine 610 to generate electrical energy using the mechanical energy.

The second power generator 720 may be connected to the second turbine 620 to generate electrical energy using the mechanical energy.

Hereinafter, a geothermal power generation system using heat exchange between waste gas and molten salt according to a third embodiment of the present invention will be described in detail.

7 is a configuration diagram of a geothermal power generation system using heat exchange between waste gas and molten salt according to a third embodiment of the present invention.

As shown in FIG. 7, a geothermal power generation system using heat exchange between waste gas and molten salt according to a third embodiment of the present invention includes a waste gas moving unit 100, a plurality of molten salt receiving units 200, and a heat transfer unit ( 400, the turbine unit 600, and the power generation unit 700.

The waste gas moving unit 100 is the same as the waste gas moving unit included in the geothermal power generation system using heat exchange between the waste gas and the molten salt according to the first and second embodiments of the present invention, so the detailed description is omitted. do.

The molten salt accommodating part 200 may accommodate molten salt that receives waste heat of the waste gas by heat exchange therein and may be installed at a predetermined interval apart from the heat transfer part 400.

Specifically, the molten salt receiving unit 200 may be formed of a straight pipe, the molten salt receiving unit 200 is connected to the waste gas moving unit 100 on the upper side, the molten salt is the waste gas moving unit 100 The heat source can be received from, and the lower side is inserted into the heat transfer part 400 to transfer the heat source of the molten salt to the heat transfer part 400.

The heat transfer part 400 is installed in the ground and the working gas that receives the heat source of the molten salt by heat exchange may flow in and out.

8 is a configuration diagram of a heat transfer unit according to the present invention.

Specifically, as illustrated in FIG. 8, the heat transfer part 400 includes at least one gas inlet 410 through which the working gas is introduced and at least one gas outlet 420 through which the working gas is discharged. It may include, wherein the gas inlet hole 410 is open, the gas outlet hole 420 may be configured to be connected to each of the turbine unit 600 to be described later.

On the other hand, when the working gas is introduced into the heat transfer unit 400 through the gas inlet 410, the gas inlet 410 may be closed to prevent the outflow of the working gas.

9 is a view showing a state in which the working gas according to the invention moves through the crack formed in the heat transfer unit.

Here, the working gas flowing in and out of the heat transfer part 400 may be made of carbon dioxide (CO ₂ ) having high heat collecting efficiency and not causing pollution problems, and the working gas is introduced into the gas as shown in FIG. 9. It is introduced into the heat transfer part 400 through the ball 410, and moves through the crack 430 formed in the heat transfer part 400 while receiving the heat source of the molten salt, the gas outlet hole ( The outflow of the heat transfer part 400 through the 420 may flow to the turbine unit 600.

Meanwhile, the heat transfer part 400 grouts the grouting material 810 so that the working gas introduced into the upper and side surfaces thereof does not flow out so that the heat-exchanged working gas flows out through the gas outlet hole 420. Can be configured.

The turbine unit 600 may be connected to the heat transfer unit 400 to generate mechanical energy using energy of the working gas flowing out of the heat transfer unit 400.

The power generation unit 700 may be connected to the turbine unit 600 to generate electrical energy using the mechanical energy.

Hereinafter, a geothermal power generation system using heat exchange between waste gas and molten salt according to a fourth embodiment of the present invention will be described in detail.

10 is a configuration diagram of a geothermal power generation system using heat exchange between waste gas and molten salt according to a fourth embodiment of the present invention.

As shown in FIG. 10, a geothermal power generation system using heat exchange between waste gas and molten salt according to a fourth embodiment of the present invention includes a waste gas moving unit 100, a plurality of molten salt receiving units 200, and a heat transfer unit ( 400, a latent heat recovery part 500, a first turbine part 610, a second turbine part 620, a first power generation part 710, and a second power generation part 720.

The waste gas moving unit 100, the molten salt receiving unit 200 and the heat transfer unit 400 is a waste gas moving unit included in the geothermal power generation system using heat exchange between the waste gas and the molten salt according to the third embodiment of the present invention, Since the configurations and contents of the molten salt containing portion and the heat transfer portion are the same, detailed description thereof will be omitted.

The latent heat recovery part 500 may be installed in the heat transfer part 400 while surrounding the molten salt accommodating part 200 to recover latent heat generated by phase change of the molten salt by heat exchange.

Specifically, the latent heat recovery unit 500 is a first embodiment, consisting of a Rankine cycle for circulating water and exchanging heat, or in a second embodiment, a Brayton cycle for heat exchange by circulating gas. (Brayton cycle).

The first turbine unit 610 may be connected to the heat transfer unit 400 to generate mechanical energy using energy of the working gas flowing out of the heat transfer unit 400, and the first power generation unit 710 may be connected to the first turbine 610 to generate electrical energy using the mechanical energy.

In addition, the second turbine unit 620 may be connected to the latent heat recovery unit 500 to generate mechanical energy using steam energy generated by the latent heat recovery unit 500. 720 may be connected to the second turbine 620 to generate electrical energy using the mechanical energy.

As described above with reference to the drawings illustrating a geothermal power generation system using the heat exchange of the waste gas and molten salt according to the present invention, the present invention is not limited by the embodiments and drawings disclosed herein, of the present invention Of course, various modifications may be made by those skilled in the art within the scope of the technical idea.

100: waste gas moving unit 200: molten salt receiving unit
300: working fluid receiving portion 310: spiral pin
400: heat transfer unit 410: gas inlet hole
420: gas outflow hole 430: crack portion
500: latent heat recovery part 600: turbine part
610: first turbine section 620: second turbine section
700: power generation unit 710: first power generation unit
720: second power generation unit 810: grouting material

Claims (12)

Waste gas moving unit 100 to which the waste gas is moved;
A plurality of molten salt containing parts 200 receiving molten salts received from the waste heat of the waste gas by heat exchange and being spaced apart from each other by a predetermined interval on the ground;
A plurality of working fluid accommodating parts 300 accommodating the working fluid receiving the heat source of the molten salt by heat exchange therein and surrounding each of the molten salt accommodating parts 200 and installed at a predetermined interval on the ground;
A turbine unit 600 connected to the working fluid receiving unit 300 to generate mechanical energy using steam generated by the working fluid receiving unit 300; And
And a power generation unit 700 connected to the turbine unit 600 to generate electrical energy using the mechanical energy.
The working fluid receiving portion 300 is made of a U-shaped tube having a spiral fin 310 to increase the heat transfer area on the outer peripheral surface,
The working fluid is accommodated in the working fluid receiving part 300 through an inlet of the working fluid receiving part 300, and is heated by receiving a heat source of molten salt contained in the molten salt receiving part 200 by heat exchange. , Geothermal power generation system using the heat exchange of the waste gas and molten salt, characterized in that the steam generated by the evaporation of the heated working fluid flows to the turbine unit 600 through the outlet of the working fluid receiving unit (300).
The method of claim 1,
The molten salt receiving unit 200 is geothermal power generation system using heat exchange between the waste gas and molten salt, characterized in that the upper side is made of a straight pipe connected to the waste gas moving unit 100 and the lower side is inserted into the ground.
The method of claim 1,
The working fluid receiving portion 300 is geothermal power generation system using heat exchange of the waste gas and molten salt, characterized in that the inlet is exposed on the ground, the outlet is connected to the turbine unit 600, respectively.
delete The method of claim 1,
The working fluid receiving part 300 is a geothermal power generation system using heat exchange of waste gas and molten salt, characterized in that the adjacent U-shaped tube is connected to each other integrally formed.
delete delete delete Waste gas moving unit 100 to which the waste gas is moved;
The upper side is connected to the waste gas moving unit 100, the lower side is installed at a predetermined interval spaced apart in the heat transfer unit 400, a plurality of molten molten salt to receive the molten salt that receives the waste heat of the waste gas by heat exchange therein Salt receiving unit 200;
A heat transfer part 400 installed in the ground and into which the working gas which receives the heat source of the molten salt by heat exchange flows in and out;
A turbine unit 600 connected to the heat transfer unit 400 to generate mechanical energy using a heated working gas; And
And a power generation unit 700 connected to the turbine unit 600 to generate electrical energy using the mechanical energy.
The heat transfer part 400 includes at least one gas inlet hole 410 into which the working gas is introduced; A crack part 430 which is a moving passage of the working gas; And at least one gas outlet hole 420 through which the working gas is discharged.
The working gas is introduced into the heat transfer part 400 through the gas inlet hole 410, and moves through the crack part 430 to heat the heat source of the molten salt contained in the molten salt receiving part 200. Received and heated by the exchange, the heated working gas is discharged to the outside of the heat transfer unit 400 through the gas outlet hole 420 flows to the turbine unit 600, characterized in that Geothermal power generation system using heat exchange.
delete The method of claim 9,
The heat transfer part 400 is a waste gas, characterized in that the heat-exchanging working gas is discharged to the outside through the gas outlet hole 420 by performing a grouting so that the working gas introduced into the upper and side does not flow out; Geothermal power generation system using heat exchange of molten salt.
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