JP6809698B2 - Brackish water separator, geothermal power generation device and geothermal power generation method - Google Patents

Description

The present invention is an air-water separator used in a geothermal exchanger that exchanges heat using the geotropical heat source, and a geothermal power generation device and geothermal heat that generate power using a geothermal exchanger that exchanges heat using the geotropic as a heat source. Regarding the power generation method.

Conventionally, in geothermal power generation equipment, natural steam existing in the geotropics is extracted using natural pressure and separated into steam and water for use. Therefore, the extracted steam includes sulfur and other substances peculiar to the geotropics. Contains a large amount of impurities. These impurities become scales and adhere to hot wells, pipes, turbine blades, and the like. If the scale adheres, the amount of power generation decreases over time, making it difficult to use for a long period of time.

In Patent Document 1, in a binary power generation system, a closed-loop circulation flow path in which a heat source fluid absorbs heat by heat exchange with a geothermal fluid or geothermal heat, dissipates heat with an evaporator, and recirculates for heat exchange with the geothermal fluid or geothermal heat. As for the cooling fluid that cools the low boiling point medium, a closed loop flow path that performs heat dissipation cooling in the ground is configured, or a refrigerator and heat exchanger that use the heat source fluid after passing through the evaporator as the driving heat source. A geothermal power generation system has been proposed that comprises a closed loop flow path that controls the temperature of the cooling fluid to supply the cooling fluid to the condenser so that the liquefaction of the low boiling medium in the condenser can be optimized.

Japanese Unexamined Patent Publication No. 2014-84857

As described above, in the power generation method in which hot spring water is pumped up and used, scale adheres to equipment such as piping equipment and turbines, and the amount of power generation decreases over time or maintenance is required. In terms of the environment, hot spring water is pumped up and used, which may affect the amount of hot spring water discharged. In addition, the water that has been pumped up and used for power generation is returned to the ground from the reduction well, but it contains chemical substances for removing scale and has a considerable impact on the environment.
Further, as seen in Patent Document 1, the method of generating electricity by using only underground heat is effective because it is environmentally friendly and it is not necessary to consider the amount of hot water in hot spring water and concerns about chemical substances.

However, the hot water heated underground may not always be hot, depending on the temperature of the tropics. Therefore, when high temperature is required, it is necessary to excavate deeply, but there is a problem that it is costly.
Therefore, in order to effectively utilize the steam and hot water obtained from the ground without requiring an excessive depth, the steam generated from the steam separator is effectively utilized, and the amount of steam from the hot water is increased. There is a need for technology that meets any of the issues of making hot water and effectively transferring hot water to a brackish water separator.

The present invention has been made in view of such problems, and is an air-water separation device, a geothermal power generation device, and a geothermal power generation method capable of effectively utilizing the amount of heat obtained from the geotropical zone on the ground to improve power generation efficiency. The purpose is to provide.

The present invention has adopted the following means in order to achieve the above-mentioned object.

A steam-water separation device that generates steam by boiling a high-temperature and high-pressure medium under reduced pressure to separate the steam and the medium. It receives the ejected medium and gradually expands its diameter in the ejection direction. It is characterized in that it is provided with a conical housing portion and a swivel guiding portion that is provided so as to project from the surface of the housing portion and swivels the medium.

With the above configuration, the hot water can be dispersed and the time for vaporization can be secured, so that the amount of steam can be increased.

FIG. 1 is a schematic view showing the configuration of the geothermal power generation device of the present invention according to the first embodiment. FIG. 2 is a perspective view showing a ground connection portion of the geothermal power generation device of the present invention according to the first embodiment. FIG. 3 is a perspective view showing the inside of the brackish water separator of the geothermal power generation device of the present invention according to the first embodiment. FIG. 4 is an explanatory view showing a state in which the brackish water separator of the geothermal power generation device of the present invention according to the first embodiment is cut and the brackish water is separated by a side view showing the inside. FIG. 5 is a perspective view of a separation device built in the brackish water separator of the present invention according to the first embodiment. FIG. 6 is a perspective view of a separation device showing a state of being mounted on a nozzle built in the brackish water separator of the present invention according to the first embodiment. FIG. 7 is a perspective view showing a hidden line of a separation device mounted on a nozzle built in the brackish water separator of the present invention according to the first embodiment. FIG. 8 is an explanatory view showing how the brackish water is separated by the separation device of the present invention according to the first embodiment. FIG. 9 is an explanatory view showing a modification of the separation device of the present invention according to the first embodiment by a perspective view and showing a state of separating air and water. FIG. 10 is an explanatory diagram showing the flow of steam in the hot water service tank of the present invention according to the first embodiment. FIG. 11 is an explanatory diagram showing the flow of steam in the hot water service tank in the modified example of the hot water service tank of the present invention according to the first embodiment. FIG. 12 is an explanatory diagram showing the flow of air and water in the hot water service tank in the modified example of the hot water service tank of the present invention according to the first embodiment. FIG. 13 is a schematic view of a change of state of water of the present invention according to the first embodiment. FIG. 14 is a relationship diagram showing the relationship between the depth of the medium transfer pipe of the geothermal power generation device of the present invention and the temperature distribution of hot water according to the first embodiment. FIG. 15 is a schematic view showing the configuration of the geothermal power generation device of the present invention according to the second embodiment. FIG. 16 is a schematic view showing the configuration of the geothermal power generation device of the present invention according to the third embodiment. FIG. 17 is a schematic view showing the configuration of the geothermal power generation device of the present invention according to the fourth embodiment.

The embodiments of the geothermal power generation devices 1, 100, and 200 according to the present invention will be described in detail with reference to the drawings. It should be noted that the embodiments and drawings described below exemplify a part of the embodiments of the present invention, are not used for the purpose of limiting to these configurations, and do not deviate from the gist of the present invention. Can be changed as appropriate in. The corresponding components in each figure are designated by the same or similar reference numerals.

(First Embodiment)
The geothermal power generation device 1 according to the first embodiment will be described with reference to FIGS. 1 to 14. FIG. 1 is a schematic view showing the configuration of the geothermal power generation device 1 of the present invention according to the first embodiment. FIG. 2 is a perspective view showing the ground connection portion 30 of the geothermal power generation device 1 of the present invention according to the first embodiment. FIG. 3 is a perspective view showing the inside of the gas-water separator F of the geothermal power generation device 1 of the present invention according to the first embodiment by cutting it. FIG. 4 is an explanatory view showing a state in which the steam separator F of the geothermal power generation device 1 of the present invention according to the first embodiment is cut and the steam is separated according to the side view showing the inside. FIG. 5 is a perspective view of a separation device 60 built in the steam separator F of the present invention according to the first embodiment. FIG. 6 is a perspective view of a separation device 60 showing a state of being mounted on a nozzle 51 built in the steam separator F of the present invention according to the first embodiment. FIG. 7 is a perspective view showing a hidden line of the separation device 60 mounted on the nozzle 51 built in the steam separator F of the present invention according to the first embodiment. FIG. 8 is an explanatory diagram showing a state in which air and water are separated by the separation device 60 of the present invention according to the first embodiment. FIG. 9 is an explanatory view showing a modification of the separation device 60 of the present invention according to the first embodiment by a perspective view and showing a state of separating air and water. FIG. 10 is an explanatory diagram showing the flow of air and water in the hot water service tank 4 of the present invention according to the first embodiment. FIG. 11 is an explanatory diagram showing the flow of air and water in the hot water service tank 4a in the modified example of the hot water service tank 4 of the present invention according to the first embodiment. FIG. 12 is an explanatory diagram showing the flow of air and water in the hot water service tank 4b in the modified example of the hot water service tank 4 of the present invention according to the first embodiment. FIG. 13 is a schematic view of a change of state of water of the present invention according to the first embodiment. FIG. 14 is a relationship diagram showing the relationship between the depth of the medium transfer pipe 10 of the geothermal power generation device 1 of the present invention and the temperature distribution of hot water according to the first embodiment.

The geothermal power generation device 1 mainly includes a pressurized water supply pump 3, a medium transfer pipe 10, a hot water service tank 4, a condensate unit 17, a water supply unit 18, a gas / water separator F, a steam turbine T, a generator G, and a power receiving facility TF. It is composed of and.
The geothermal power generation device 1 supplies steam V1 to the steam turbine T to rotate the generator G to generate electricity, supply electricity to the power receiving equipment TF, and supply electricity to an electric power company or the like via a power transmission network. ing.
The steam turbine T may be of a screw type or the like as well as a turbine type, and may be of a type capable of generating electricity by steam. The steam V1 supplied to the steam turbine T is generated by the steam separator F by boiling the hot water L3 under reduced pressure.

Since the total amount of hot water L3 supplied to the steam separator F is not the steam V1, a large amount of hot water L4, so-called drain, is sent from the steam separator F to the hot water service tank 4. Further, the steam V3 exhausted by the steam turbine T is sent to the condensate unit 17, and the steam V4 sent to the condensate unit 17 is sent to the cooling tower 15 connected to the condenser 6. The sent steam V4 is condensed and returned to water, passes through the condenser 6, is temporarily stored in the condenser tank 14, and then is sent to the hot water service tank 4 by the condenser pump 5.

The hot water L8 of the hot water service tank 4 is transferred to the medium transfer pipe 10 as hot water L1 by the pressurized water supply pump 3. The hot water L1 transferred by the pressurized water supply pump 3 absorbs heat from the geothermal heat again in a deep part of the geotropic U and exchanges heat. The heat-exchanged hot water L2 is transferred by the pressurized water supply pump 3 by the medium transfer pipe 10 described later.

(Media transfer pipe)
Next, the medium transfer pipe 10 will be described. The medium transfer pipe 10 is buried from the surface S to the tropics U, which is a heat source in the deep underground. In the medium transfer pipe 10, a cylindrical medium injection pipe 11 is embedded on the outside, and the temperature around the medium injection pipe 11 is lower than the temperature required for power generation, that is, in front of the region from the ground surface S to the geothermal U. The underground area of the building is hardened with geothermal cement, etc., so that there is no danger of collapse. The medium transfer pipe 10 absorbs heat from the fluid or bedrock of the geotropic U located at the deepest part of the medium injection pipe 11 of the medium transfer pipe 10. The total length of the medium transfer pipe 10 changes depending on the temperature of the geotropic U, and extends to the geotropic where about 200 ° C. can be absorbed as heat.

The medium injection tube 11 is made of a material such as steel or stainless steel. In the region of the tropical U where the temperature is high, the medium injection pipe 11 is welded with cylindrical fins having a circular cross section in order to increase the surface area of the outer circumference and facilitate the heat transfer of the tropical U. The medium injection pipe 11 has a heat insulating structure provided with a heat insulating material or an air layer so that the heat of the hot water L1 pressurized and injected from the hot water service tank 4 is not taken away in a low temperature region close to the ground surface S. Has been done.

The medium transfer pipe 10 is provided with a cylindrical medium take-out pipe 12 for transferring water heated in the tropics U inside the medium injection pipe 11. The medium take-out pipe 12 is formed inside the medium injection pipe 11 in a cylindrical shape coaxially. The medium take-out pipe 12 has a cylindrical shape through which hot water L3 can pass through the inside of the pipe, and has a structure in which a vacuum heat insulating structure or a heat insulating material is attached along the outside in the vertical direction.

The hot water L3 heated in the tropics U is boiled under reduced pressure in the steam separator F to generate steam. Here, the steam separator F may use a nozzle capable of generating microbubbles or nanobubbles which become microbubbles by self-absorption as the nozzle for generating steam. Since the steam generation efficiency can be improved by this configuration, a sufficient amount of steam can be secured even if the speed of transferring water is reduced, so that it is possible to take a long time for water to stay in the heat absorption region of the tropical U. It can be made into hot water with a high temperature because it takes time for the water to absorb heat.

In this embodiment, water is used as a medium for heat exchange in the tropical U, but the medium has a boiling point higher than that of oil, gas (inert gas (nitrogen, carbon dioxide, etc.)) or water used in binary power generation. A medium with a low carbon dioxide (such as a mixture of water and ammonia) is conceivable. Further, when water or an inert gas is used as the medium, even if the medium transfer pipe 10 is damaged and flows out to the outside, the water or the inert gas does not harm the environment and the work surface. It is also possible to handle it safely.

(Ground connection)
Next, the ground connection portion 30 connected to the medium transfer pipe 10 and projecting to the ground side will be described with reference to FIG.
The ground connection portion 30 is a portion that connects the medium transfer pipe 10 buried underground with the equipment of the steam separator F and the pressurized water supply pump 3 on the ground side. The insulated upper connecting pipe 35 provided above the ground connecting portion 30 is a connecting portion for transferring the hot water L3 to the brackish water separator F. The upper connecting pipe 35 communicates with the medium take-out pipe 12 via the flanges 36 and 37.
Further, the air pipe 34 penetrating the flanges 36 and 37 is provided with a valve (not shown) in order to evacuate the air in the medium injection pipe 11. In the work of operating the valve of the air pipe 34 to remove the air, the pressurized water supply pump 3 causes air biting due to the air accumulated in the upper part of the medium injection pipe 11, and the pressurized water supply pump 3 sends the hot water L1. It prevents it from becoming impossible.

The medium injection pipe 11 includes an injection pipe portion 41 connected to the pressurized water supply pump 3 and drain discharge pipes 42 and 43 for discharging the drain in the intermediate pipe portion 33. The drain discharge pipes 42 and 43 are pipes for draining water in the intermediate pipe portion 33 in an emergency or when the medium take-out pipe 12 is replaced, and a valve (not shown) is closed during normal operation. ..

The ground connection portion 30 is a portion that connects the medium transfer pipe 10 buried underground, the steam separator F on the ground side, and the pressurized water supply pump 3. The ground connection portion 30 is connected to the medium injection pipe 11 inside the underground connection pipe 32 at the lower end and is solidified with concrete 31. The concrete 31 prevents groundwater from being blown up from the outside of the medium injection pipe 11 and maintains the strength for supporting the medium transfer pipe 10.

(Brackish water separator)
Next, with reference to FIGS. 3 to 8, a steam separator F for generating steam by boiling hot water L3 from the upper connecting pipe 30 under reduced pressure will be described. The steam separator F is a cylindrical pressure vessel, and a nozzle 51, which is a circular pipe, is provided at a position slightly below the middle. The nozzle 51 ejects hot water L3 from its tip and boils it under reduced pressure in the container to generate steam. Further, a control valve (not shown) for adjusting the pressure (steam generation amount) is provided either inside or outside the steam separator F.
The nozzle 51 is provided with a separation device 60 fixed to the inside of the tip by three support shafts 65. Further, below the separating device 60, a plate-shaped receiving plate 54 is provided, and a part of the receiving plate 54 is cut out to provide a discharge port 55. The receiving plate 54 is provided so as to be gently inclined toward the discharge port 55, and guides the hot water L3.
Below the receiving plate 54, a hot water service tank pipe 52 for transferring so-called drain that did not become steam to the hot water service tank 4 is provided.

The separation device 60 is provided to increase the amount of steam, and particularly when the amount of steam from the nozzle 51 can be sufficiently secured, the separation device 60 may not be attached, but it is the best method for increasing the amount of steam. ..
The separation device 60 has a horn portion 61 formed in a conical shape extending from the nozzle 51 in the blowing direction. Further, four continuous guide pieces 62a, 62b, 62c, 62d are provided evenly in the circumferential direction along the circumference of the horn portion 61. As shown in FIG. 8, the guide piece 62 has a continuous piece having a certain length with an inclination of about 30 to 60 degrees when viewed from the side surface, and surrounds the circumference of the horn portion 61. The guide piece 62 mainly spirals hot water L3 along the guide piece 62.

The tip 66 of the horn portion 61 is provided with a plurality of vapor intake holes 68 that serve as through holes. Since the steam intake hole 68 allows only a small amount of hot water L3 to pass through, the hot water L3 passes through the outer periphery of the horn portion 61 with little penetration into the inside of the horn portion 61.
The horn-shaped diameter of the separator 60 is preferably about 1.5 to 3 times the outer diameter of the nozzle 51, and the total length of the separator 60 may be provided according to the inner diameter of the brackish water separator F. ..

Further, the horn portion 61 between the guide piece 62 and the guide piece 62 is provided with a plurality of guide holes 63 serving as through holes along the guide piece 62. The guide hole 63 is a hole for guiding the steam V1 from the outside to the inside of the separation device 60. Therefore, by providing the guide hole 63, the steam V1 having a low density passes through the guide hole 63, but it becomes difficult for the hot water L3 having a high density to pass through, and the steam V1 is guided by the guide piece 62 and scatters radially. Even if the hot water L3 passes through the guide hole 63, it is expected that the flow velocity will be reduced and it will become droplets, and there is a possibility of further vaporization.

Next, the action of separating air and water will be described with reference to FIGS. 4 and 8. The hot water L3 ejected from the nozzle 51 into the steam separator F is boiled under reduced pressure to generate steam V1. The ejected hot water L3 is scattered around while spirally swirling along the induction piece 62 described above. Further, the steam V1 also swirls in the same manner as the hot water L3, but a part of the steam V1 is guided inside from the above-mentioned guide hole 63 to the horn portion 61 and blown forward. Since the steam V1 blown out and the steam V1 swirled have a low density, they are transferred to the upper steam take-out pipe 53.
However, the hot water L3 that did not become steam V1 falls on the receiving plate 54 due to gravity. Here, even while flowing to the receiving plate 54, if the hot water L3 becomes steam V1, the steam V1 rises and is transferred to the steam take-out pipe 53.
The hot water L4 that did not become steam is transferred to the hot water service tank 4 from the discharge port 55 in which the notch of the receiving plate 54 is formed.

Then, the induction piece 62 of the separation device 60 disperses the hot water by swirling the hot water L3, and gains time for the hot water L3 to stay in the steam separator F, thereby changing to steam V1. Can be sufficiently obtained. By making the structure in which the hot water L3 stays as easily as possible in this way, a large amount of steam can be taken out.
As described above, the separation device 60 of the present invention has a structure for increasing the amount of steam and increasing the power generation capacity by improving the so-called flash rate.

<Modification example 1 of the separator in the brackish water separator F>
Next, another example of the steam separator Fa will be described with reference to FIG. The same parts as those of the above-mentioned structure or function are designated by the same reference numerals, and the description thereof will be omitted, and different parts will be described.
The main difference from the above is that the ejection direction of the separating device 60 is upward and the top plate 86 is provided.

The separation device 60 itself has the same structure as described above, but the suction amount of the steam V1 is increased by pointing upward, and the total capacity of the steam is increased.
Further, the top plate 86 provided above the steam separator Fa is suspended from the ceiling of the steam separator Fa by a support rod 83.
The top plate 86 is located above the separation device 60, and is formed of a conical stainless steel material or the like covering the entire upper region so as to cover the steam take-out pipe 53. A plurality of steam passage holes 87, which are through holes formed by patching, are provided throughout the top plate 86 to increase the contact area in contact with the hot water L3.

The separation device 60 itself has the same effect as described above. By increasing the contact area of the top plate 86, when the hot water L3 ejected from the separating device 60 comes into contact with the top plate 86, it comes into contact with the steam passage hole 87 and other sheet metal, and the steam V1 is dropped while falling. I'm earning time to change. Therefore, the amount of steam changes depending on whether a large amount of time can be gained until the hot water L3 falls on the hot water service tank pipe 52.
The separation device 60 and the top plate 86 can provide a time for changing to the steam V1 by gaining a time for the hot water L3 to stay. With the above structure, the hot water L3 can easily stay as much as possible, so that a large amount of steam can be taken out. The separation device 60 and the top plate 86 of the present invention have a structure for increasing the amount of steam and increasing the power generation capacity by improving the so-called flash rate.

(Hot water service tank)
Next, the hot water service tank 4 will be described with reference to FIGS. 1 and 10 to 12. The hot water service tank 4 is a cylindrical pressure vessel. The main pipes connected to the hot water service tank 4 are connected to a pipe that takes in the condensate water L6 sent from the condensate unit 17, a pipe that takes in the degassed water L7 replenished from the water supply unit, and a pressurized water supply pump 3. A pump pipe 76 that sends hot water L8 from the hot water service tank 4, a drain injection pipe 74 that takes in the drain L4 sent from the air-water separator F, and a steam discharge that discharges steam V2 generated by boiling the pool in the hot water service tank 4. A pipe 75 is provided.

As shown in FIG. 10, a partition plate 71 is provided between the drain injection pipe 74 and the steam discharge pipe 75. The upper end of the partition plate 71a close to the drain injection pipe 74 is fixed above the hot water service tank 4, and the lower end of the partition plate 71b close to the steam discharge pipe 75 is fixed to the bottom plate of the hot water service tank 4. .. Further, the partition plate 71 close to the steam discharge pipe 75 and close to the pump pipe 76 is also formed with a through groove 73 serving as a notch groove for guiding the hot water L8 on the pump pipe 76 side.

In the hot water service tank 4, the drain L4 sent from the gas-water separator F is sent in a gas-liquid two-phase flow. In the present invention, a partition plate 71 is provided in the hot water service tank 4, and the hot water L8 after passing the drain L4 once through the liquid interface is guided to the pump pipe 76, so that only the hot water L8 containing no bubbles is pumped. It has a structure that can lead to 76. With the above structure, air bubbles are not guided to the pump pipe 76, so that the pressurized water supply pump 3 is prevented from causing cavitation.

Further, the hot water service tank 4 has a structure in which the high-temperature drain L4 becomes steam and the steam V2 generated in the hot water service tank 4 can be effectively used, and the generated steam V2 is steam from the hot water service tank 4. It is recharged to the steam side of the steam separator F via the steam discharge pipe 75 as a bypass. As described above, the hot water service tank 4 also has a structure for effectively increasing the amount of steam and increasing the power generation capacity.

<Modification example 1 of hot water service tank>
Next, another hot water service tank 4 will be described with reference to FIG.
The same parts as those of the above-mentioned structure or function are designated by the same reference numerals, and the description thereof will be omitted, and different parts will be described.
The main difference from the above is that the drain receiving plate 79 is provided. The drain receiving plate 79 supports the flat metal drain receiving plate 79 by the metal supporting feet 81 fixed to the floor plate of the hot water service tank 4. The drain receiving plate 79 has a structure for temporarily receiving the drain L4 and separating the air bubbles and the liquid.

In the present invention, the drain L4 is once received by the drain receiving plate 79 provided in the hot water service tank 4, and the bubbles and the liquid are separated so that only the hot water L8 containing no bubbles can be guided to the pump pipe 76. It has become. With the above structure, air bubbles are not guided to the pump pipe 76, so that the pressurized water supply pump 3 is prevented from causing cavitation.

<Modification example 2 of hot water service tank>
Next, another hot water service tank 4 will be described with reference to FIG. The same parts as those of the above-mentioned structure or function are designated by the same reference numerals, and the description thereof will be omitted, and different parts will be described.
The main difference from the above is that the drain receiving plate 77 is provided. The drain receiving plate 77 supports the flat metal drain receiving plate 79 by the metal supporting feet 78 fixed to the ceiling of the hot water service tank 4. The drain receiving plate 77 has a structure for temporarily receiving the drain L4 and separating the air bubbles and the liquid.

In the present invention, the drain L4 is once received by the drain receiving plate 77 provided in the hot water service tank 4, and the air bubbles and the liquid are separated so that only the hot water L8 containing no air bubbles can be guided to the pump pipe 76. It has become. With the above structure, air bubbles are not guided to the pump pipe 76, so that the pressurized water supply pump 3 is prevented from causing cavitation.

(Water supply unit)
Next, the water supply unit 18 will be described with reference to FIG. The water supply unit 18 uses an industrial soft water generator 9 to generate soft water from raw water 16 such as river water or tap water. Then, the generated soft water is stored in the make-up water tank 8. Dissolved oxygen is removed from the stored soft water by using a deoxidizer or a deoxidizer.

The degassed water L7 from which oxygen has been removed is sent via the hot spring service tank when the medium transfer pipe 10 is washed during the initial operation of the geothermal power generation device 1 and then replaced with water for operation. Be done. Then, by removing oxygen, rust prevention and scale generation in the medium transfer pipe 10 can be suppressed. In particular, since the medium transfer pipe 10 has a long overall length, it is possible to reduce the pressure loss by suppressing the scale of the pressurized water supply pump 3, which can lead to energy saving of the internal power.

In addition, typical examples of antacids include hydrazine, tannin, and products derived from plant spots. There is also a deoxidizer that uses an inert gas, and an inert gas that does not easily cause a chemical reaction is used. As examples of the inert gas, nitrogen, argon, etc., which are less harmful, are adopted. In particular, as in the present invention, since it is necessary to control the pressure of the heat exchange medium at a high temperature, a deoxidizer or a deoxidizer that does not change the physical properties of the working fluid is preferable.
Nitrogen and the like are easily dissolved in water by using a micro-bubble generator, and then the dissolved water is injected to facilitate replacement with oxygen.

During normal operation, since the temperature of the degassed water L7 is low, the water supply unit 18 does not directly enter the hot water service tank 4 having a high temperature, but replenishes the insufficient water via the condensate unit 18. Further, it is also possible to cool the condensate unit 18 by using the raw water 16.

(Condensation unit)
Next, the condensate unit 17 will be described. The condensate unit 17 has a function of condensing steam V3 exhausted from the turbine T and returning it to water, and is mainly composed of a condenser 6, a condensate tank 14, and a cooling tower CT. The steam V3 received by the condenser 6 is cooled by the cooling tower CT, condensed, returned to the hot water L10, and stored in the condenser tank 14 via the condenser 6. The stored hot water L6 is sent to the hot water service tank 4 by the condensate pump 5 and stored in the hot water service tank 4.
The cooling method by the cooling tower CT includes an air-cooled type, a water-cooled type using river water, seawater, or the like, or a geothermal heat replacement type that exchanges heat in the ground.

(Power generation method using the above equipment)
Explaining the power generation method with reference to FIGS. 1 and 13 to 14, the depth of the hole drilled by boring to obtain heat of about 200 ° C. is a depth of about 700 m to 2000 m in the ground. Has reached. It is thought that the deeper this depth is, the higher the temperature can be obtained, but it is determined in consideration of the excavation cost, and the geotropical U is best if the temperature is 150 ° C to 300 ° C, and the deepest of the geotropic U. The following values also change as appropriate depending on the temperature obtained from the vicinity of the part.

First, the power generation method of the pressurized water power generation device 1 will be described. A medium transfer pipe 10 is buried in the ground, and the medium transfer pipe 10 is connected to the medium injection pipe 11 on the outside in contact with the ground. It has reached deep. Further, the medium injection pipe 11 has a medium extraction pipe 12 connected to the inside of the medium injection pipe 11 and reaches the bottom of the medium injection pipe 11. These medium transfer pipes 10 are used as heat exchange units for absorbing heat obtained from the geotropic U. This pressurized water power generation device A evaporates hot water to generate electricity via a steam turbine T. The power generation method by the pressurized water power generation device A will be described in detail below.

For example, the hot water (L1) in the hot water service tank 4 is pressurized to 5 MPa by the pressurized water supply pump 3 and sent to the medium injection pipe 11 of the medium transfer pipe 10 at a flow rate of 55 (ton (ton)) / h (hours). , Transferred to the tropics U deep underground. The hot water transferred to the geotropic U at 210 ° C. absorbs the heat from the geotropic U from the medium injection pipe 11 having high effective thermal conductivity, and finally becomes hot water (L2) at 200 ° C. Then, the hot water (L3) taken out from the medium take-out pipe 12 is transferred to the steam separator F at an outlet temperature of 200 ° C. and a pressure of 2.0 MPa.

The steam separator F releases hot water (L3) having a temperature of 200 ° C. to boil it under reduced pressure to about 0.6 MPa to generate steam having a flash rate of about 11% and a steam amount of 6 t / h. .. The steam separator F sends the generated steam (V1) to the steam turbine T. The generated steam (V1) merges with the steam (V2) generated in the hot water service tank 4 in the steam separator F. The merged steam (V1 + V2) drives the generator G by the rotation of the steam turbine T to generate electricity. As for the amount of power generated by this steam (V1 + V2), an output of about 112 kWh can be obtained when the efficiency is 80%.

Further, the steam separator F connected to the hot water service tank 4 by a pipe has a pressure of about 89% of hot water (L4) remaining without becoming steam while maintaining a temperature of about 160 ° C. It is sent to the hot water service tank 4 at a flow rate of 49 t / h at 6 MPa.
Further, the steam (V3) exhausted from the steam turbine T is sent to the condenser 6. The steam (V4) sent to the condenser 6 is sent to an air-cooled or water-cooled cooling tower 7, condensed by the cooling tower 7, and returned to hot water (L10) at 100 ° C. at a pressure of 0.101 MPa. The returned hot water (L10) is stored in the condensate tank 14 at a flow rate of 6 t / h. Further, the hot water (L6) of the condensate tank 14 is sent to the hot water service tank 4 by the condensate pump 5.
Then, the hot water (L1) of the hot water service tank 4 at around 130 ° C. is again pressurized to 6 MPa by the pressurized water supply pump 3 and sent to the medium injection pipe 11 of the medium transfer pipe 10 at a flow rate of 55 t / h, deep underground. Transferred to the tropical U of the region.

FIG. 14 is a relationship diagram 20 between the depth of the medium transfer pipe 10 of the pressurized water power generation device 1 and the temperature distribution of hot water. The broken line shows the temperature distribution 21 in the ground, and the solid line shows the temperature distribution of the hot water L1, L2, and L3 of the medium injection pipe 11 and the medium take-out pipe 12.
With the alternate long and short dash line as the boundary, the upper heat insulating region 22 uses a pipe having an excellent heat insulating effect, which is made of a material having an effective thermal conductivity of 0.1 W / m · K or less of the medium injection pipe 11. Further, with the alternate long and short dash line as the boundary, the lower absorption region 26 uses a pipe having excellent heat absorption, which is made of a material having an effective thermal conductivity of 50 W / m · K or more for the medium injection pipe 11.

Further, the medium take-out pipe 12 uses a pipe having an excellent heat insulating effect, which is made of a material having an effective thermal conductivity of 0.1 W / m · K or less regardless of the heat insulating region 22 and the endothermic region 26. Due to the heat insulating effect, hot water (L2) that has absorbed the heat of the deepest geotropic U can be transferred to the brackish water separator F without being affected by the temperature change in the middle of the medium injection pipe 11.

FIG. 13 is a schematic diagram of a change of state of water. FIG. 13 shows the temperature and pressure when water changes into a solid, a liquid, and a gas. The solid line from the triple point to the critical point shows the evaporation curve 26. The boiling point at atmospheric pressure is 100 ° C. and shows 0.101 MPa. At point C on the line, at a temperature of 200 ° C., when the pressure is less than the pressure of 1.554 MPa, it is a boundary line that changes from the state of water to gas, that is, steam.
At point D on the line, at a temperature of 210 ° C., when the pressure is less than 1.907 MPa, it becomes a boundary line that changes from the state of water to gas, that is, steam.
Further, the pressurized region 23 shown by the diagonal line indicates a region of the pressure at which the hot water L3 does not become steam, and the pressurized water supply pump 3 sets the pressure value in consideration of the pressure loss.

The temperature of the temperature distribution 21 rises to 220 ° C. as it approaches the deep part of the tropics U. Since the effective thermal conductivity of the medium injection pipe 11 and the medium take-out pipe 12 is 50 W / m · K, the hot water (L1) guided to the medium injection pipe 11 has a temperature distribution 21 in the ground. The temperature distribution 22 rises along the line.

Here, even if the effective thermal conductivity of the medium take-out pipe 12 is set as small as 0.1 W / m · K, if the pressure of the hot water L3 at the outlet of the medium take-out pipe 12 is lower than the point C, the temperature distribution Is lower than the evaporation curve 26, so steam is generated, and the temperature drops so as to approach the boiling point.
When water changes to steam in the medium take-out pipe 12, it becomes a so-called gas-liquid two-phase flow, and the heat transfer coefficient is several tens of times higher than in the case of the water single-phase flow. Therefore, the medium take-out pipe 12 or the medium injection pipe Heat is easily taken away by the low temperature descending flow L1 flowing through 11. In order to prevent the heat loss and transfer the energy while storing it, it is necessary to make the hot water difficult to cool.
Then, the hot water having a boiling point or higher heated in the geotropic U is carried to the steam separator F in a state where it does not contain steam so as not to cool down, so that the heat loss is reduced. In order to reduce the heat loss, it is necessary to keep the pressure higher than the evaporation curve 26 of FIG. 13 as described above.

In particular, a temperature difference occurs in the medium transfer pipe 10 serving as a heat exchanger, and buoyancy due to the difference in water density is generated accordingly. In the pressurized water supply pump 3, the pressure for transferring the required flow rate is insufficient only by the natural circulation of buoyancy alone, and the pressure loss of the medium injection pipe 11 and the medium take-out pipe 12 must be taken into consideration. Further, it is important that the pressurized water supply pump 3 keeps the pressure high by the pressurized water supply pump 3 in order to keep the pressure higher than the evaporation curve 26, and keeps the state of not boiling in the medium transfer pipe 10. It is an advantage of the present invention that underground heat can be effectively utilized by transferring it to the brackish water separator F in the state of hot water L3 holding the amount of heat absorbed in the geotropic U, that is, in the state of so-called single-phase flow. ..

From the above, in the present invention, as shown in the shading of FIG. 14, the heat insulating region of the medium injection pipe 11 and the medium take-out pipe 12 is formed of a material having a heat transfer coefficient of 0.1 W / m · K or less. The best one has a heat insulating performance of 0.05 W / m · K to 0.001 W / m · K. By maintaining the heat insulating performance, it is possible to prevent the temperature from dropping at the outlet, and as a result, it is not necessary to set the pressure of the pressurized water supply pump 3 high. In FIG. 14, the broken line shows the temperature distribution 21 in the ground including the tropics U, and the solid line shows the temperature distribution 25 of hot water.

Further, the outlet pressure of the hot water L3 is preferably a pressure range 23 larger than the evaporation curve 26 of FIG. 13 by the pressurized water supply pump 3 in consideration of the pressure loss of the medium injection pipe 11 and the medium take-out pipe 12, and the temperature. The pressure was set so that steam was not generated so that hot water with a temperature above the boiling point could be transferred.
Further, the medium injection pipe 11 is made of a material having a high effective thermal conductivity of 50 W / m · K in a region having a high temperature distribution in the ground, that is, an endothermic region required for power generation. If it is particularly high, it may have a high effective thermal conductivity, but considering the pressure and corrosion in the ground, it is desirable to form it with a metal material, and the effective thermal conductivity should be 20 W / m · K or more. Just do it.

(Second Embodiment)
The geothermal power generation device 100 according to the second embodiment will be described with reference to FIG. FIG. 15 is a schematic view showing the configuration of the geothermal power generation device 100 of the present invention according to the second embodiment. The same parts as those in the second embodiment are designated by the same reference numerals, and the above description will be omitted.
The binary power generation device B will be described with reference to FIG. 15. The binary power generation device B includes a heat exchange unit 150 mainly connected to a pressurized water heat exchanger 1a, a steam turbine T2, a generator G2, and a power receiving facility TF2. It is composed of a cooler 154 and a circulation pump 155.

In the present invention, the geothermal heat obtained from the medium transfer pipe 10 provided in the pressurized water heat exchanger 1a passes through the heat exchanger 151 as the hot water L3 without being converted into steam. Since the steam separator F is not provided in this way, the operation heated by the heat exchange unit 150 can recover the geothermal heat with less loss by directly using the geothermal heat and use it for power generation. The medium M1 evaporates to rotate the steam turbine T2, and the generator G2 generates electricity.
The power receiving facility TF supplies electricity and supplies electricity to an electric power company or the like via a power transmission network. Here, the working media M1, M2, M3 include HFC-245fa, R245fa, etc., which are non-flammable and non-toxic inert gases, and media having a low boiling point (mixture of water and ammonia, hydrocarbons (pentane), etc.). used.

As the steam turbine T2, an expansion turbine or the like is used. The working medium M2 that has passed through the steam turbine T2 is cooled by the cooling water 157a and 158a of the cooler 156. Further, the working medium M3 is condensed from gas to liquid or the like and sent to the heat exchanger 152 again by the circulation pump 155.
By piping the cooling water 157a and 158a in the vicinity of the medium transfer pipe 10 of the pressurized water heat exchanger 1a in a shallow region, heat can be exchanged through the ground in the shallow portion of the medium transfer pipe 10. .. Therefore, the medium transfer pipe 10 can cool the cooling waters 157a and 158a without cooling. In this way, effective use of heat can be realized in the same system (geothermal power generation device 100).

By using such an operating medium (M1 to M3), even hot water at 70 ° C. to 95 ° C. can generate electricity if there is a flow rate of 9 (ton (ton)) / h (hours) to 24 t / h. Is possible. In this system, the working medium exchanges heat in a closed system.

Further, the service tank 4 provided in the pressurized water heat exchanger 1a stores the hot water cooled by the heat exchanger 152, but as an element for keeping the pressure of the entire system of the pressurized water heat exchanger 1a constant. It is required along with the pressurized water supply pump 3. In particular, when the pressurized water supply pump 3 is stopped due to maintenance or the like, the water capacity of about 2 tons of the total system capacity is increased or decreased, so that the water level is kept constant and the operation is restarted smoothly. Can control the pressure of the service tank 4 to keep the water level constant.

(Third Embodiment)
The geothermal power generation device 200 according to the third embodiment will be described with reference to FIG. FIG. 16 is a schematic view showing the configuration of the geothermal power generation device 200 of the present invention according to the third embodiment. The same parts as those in the first embodiment and the second embodiment are designated by the same reference numerals, and the above description will be omitted.
Explaining the binary power generation device B with reference to FIG. 16, the binary power generation device B includes a heat exchange unit 150 mainly connected to the pressurized water power generation device 1b, a steam turbine T2, a generator G2, and a power receiving facility TF2. It is composed of a cooler 154 and a circulation pump 155.

In the present invention, hot water L3 obtained from the medium transfer pipe 10 provided in the pressurized water power generation device 1b is used to generate steam in the steam separator F, and the drain L4 that does not become steam is passed through the heat exchanger 151. ..
The working medium M1 heated in the heat exchange section 150 evaporates to rotate the steam turbine T2, and the rotation causes the generator G2 to generate electricity.
The power receiving facility TF supplies electricity and supplies electricity to an electric power company or the like via a power transmission network. Here, as the working medium M, a non-flammable or non-toxic inert gas such as HFC-245fa or R245fa or a medium having a low boiling point (hydrocarbon (pentane) such as a mixture of water and ammonia) is used.

As the steam turbine T2, an expansion turbine or the like is used. The working medium M2 that has passed through the steam turbine T2 is cooled by the cooling water 157a and 158b of the cooler 156. Further, the working medium M3 is condensed from gas to liquid or the like and sent to the heat exchanger 152 again by the circulation pump 155.
By piping the cooling water 157b and 158b to the raw water 16 provided in the water supply unit 18 of the pressurized water power generation device 1b and exchanging heat, the raw water 16 is warmed and the cooling water 157b and 158b are cooled, so that the entire geothermal power generation device 200 is used. Effective replacement of heat is carried out in the system. By being warmed, the raw water 16 can be directly charged into the hot water service tank 4 without going through the condensate unit 17.

By using such an operating medium (M1 to M3), even hot water at 70 ° C. to 95 ° C. can generate electricity if there is a flow rate of 9 (ton (ton)) / h (hours) to 24 t / h. Is possible. In this system, heat exchange is performed in a system in which the medium is closed. Since the medium that can be used for the working medium (M1 to M3) is determined by the temperature at which heat is exchanged, the temperature may be limited by the binary power generation device B. The pressurized water power generation device 1b is provided with a temperature control system 161 using the air-cooled tower CT of the water recovery unit 17 so as to cope with such a case. In particular, when the temperature of the drain L4 that does not become steam is high, it is possible to lower the temperature to a region that matches the set temperature of the binary power generation device B.

(Fourth Embodiment)
The geothermal power generation device 300 according to the fourth embodiment will be described with reference to FIG. FIG. 17 is a schematic view showing the configuration of the geothermal power generation device 300 of the present invention according to the fourth embodiment. The same parts as those in the first to third embodiments are designated by the same reference numerals, and the above description will be omitted.
Explaining the binary power generation device C with reference to FIG. 17, the binary power generation device C includes a first heat exchange unit 150c, a second heat exchange unit 156c, a steam turbine T2, and a steam turbine T3 connected to the pressurized water power generation device 1b. It is composed of a generator G2, a generator G3, a power receiving facility TF2, a cooler 164c, a first circulation pump 155c, and a second circulation pump 165c.

In the present invention, steam is generated from the hot water L3 obtained from the medium transfer pipe 10 provided in the pressurized water power generation device 1c by the steam separator F, and the drain L4 that does not become steam is used in the first heat exchanger 151c. Let it pass.
The working medium M1 heated in the portion of the first heat exchange section 150c evaporates to rotate the steam turbine T2, and the generator G2 generates electricity.

The power receiving facility TF2 supplies electricity and supplies electricity to an electric power company or the like via a power transmission network. Here, the working medium M (M1 to M23) is a non-flammable or non-toxic inert gas such as HFC-245fa or R245fa or a medium having a low boiling point (mixture of water and ammonia, hydrocarbon (pentane)) or the like. Is used. Further, in this embodiment, the working medium (M1 to M3) used in the binary power generation device C is divided into a working medium having a high boiling point region and a working medium (M21 to M3) having a boiling point lower than that of the working medium (M1 to M3). By using the working medium having two types of boiling point regions of M23), heat can be utilized in multiple stages, and power can be generated efficiently.

As the steam turbines T2 and T3, expansion turbines and the like are used. The working medium M2 that has passed through the steam turbine T2 is heat-exchanged and cooled by the second heat exchanger 153c of the second heat exchange unit 154c. Further, the working medium M3 is condensed from gas to liquid or the like and sent to the heat exchanger 152c again by the circulation pump 155c.
Further, in the second heat exchanger 156c in which heat exchange was performed by the second heat exchanger 153c of the second heat exchange unit 154c, the operating medium M21 heated by the second heat exchange unit 164c evaporates and the steam turbine. T3 is rotated and power is generated by the generator G3.

The working medium M21 that has passed through the steam turbine T3 is cooled by the cooling water 157c and 158c of the cooler 164c. Further, the working medium M23 is condensed from gas to liquid or the like and sent to the second heat exchange unit 154c again by the circulation pump 165c.
By piping the cooling water 157c and 158c to the raw water 16 provided in the water supply unit 18 of the pressurized water power generation device 1c and exchanging heat, the raw water 16 is warmed and the cooling water 157c and 158c are cooled, so that the entire geothermal power generation device 300 is used. Effective replacement of heat is carried out in the system. By being warmed, the raw water 16 can be directly charged into the hot water service tank 4 without going through the condensate unit 17.

The method of cooling the working medium or the medium such as water connected to the heat exchanger or the condenser described above is not limited to these, and the method of cooling by the heat exchange method using the Peltier element, etc. Various methods can be considered.
In all the embodiments of the present invention, a control valve (not shown) for controlling the pressure of the hot water L or the steam V is provided before or after the pressure vessel for entering and discharging the hot water L or the steam V to control the pressure. ..

(Other technical features considered from the above embodiments)
An example of the technical features of the present embodiment is shown in parentheses below, but it is not particularly limited and is illustrated, and the effects that can be considered from these features are also described.
<First feature point>
A steam separator (eg, mainly steam separator F) that generates steam by boiling a medium of high temperature and high pressure (for example, mainly hot water (L3)) under reduced pressure to separate the steam and the medium. A conical housing portion (for example, mainly a horn portion 61) that receives the ejected medium and gradually expands in diameter in the ejection direction, and a housing portion that protrudes from the surface of the housing portion. The medium is provided with a swivel guiding portion (for example, mainly a guiding piece 62) for swirling the medium.

Due to the above characteristics, since the medium is spirally swirled and scattered and the medium is dropped, it is possible to secure a time for the medium to be dispersed and vaporized, and it is also possible to atomize the medium. It is possible to increase the amount of steam.

<Second feature>
The swivel guide portion includes a plurality of spiral swivel guide pieces (for example, mainly a guide piece 62a, a guide piece 62b, a guide piece 62c, and a guide piece 62d) that are continuous from the tip to the end of receiving the ejected medium. It is characterized by having.

Due to the above characteristics, since the medium is spirally swirled and scattered and the medium is dropped, it is possible to secure a time for the medium to be dispersed and vaporized, and it is also possible to atomize the medium. It is possible to increase the amount of steam.

<Third feature point>
The housing portion is characterized by being positioned between the swivel guide pieces and provided with guide holes (for example, mainly guide holes 63) for guiding a plurality of vapors forming through holes. ..
Due to the above characteristics, steam is taken in from the guide hole, and the steam and the medium can be further separated.

<Fourth feature>
A steam take-out pipe (for example, hot water service tank pipe 52) for taking out steam is provided in the air-water separation device, and a top plate (for example, main plate) having a size covering the entire surface of the steam take-out pipe and formed in a conical shape. The top plate 86) is provided on the top plate 86), and the top plate is provided with steam guide holes (for example, mainly steam passage holes 87) for guiding a plurality of steams having through holes.
With the above features, it is possible to secure the time for the medium to vaporize, so that the amount of vapor can be increased. Steam is taken in from the steam guide hole, and the steam and the medium can be further separated.

<Fifth feature point>
The steam separator is characterized by including a steam generating nozzle for boiling under reduced pressure and generating steam containing fine bubbles.
With the above features, it is possible to increase the amount of steam by vaporizing hot water containing microbubbles and nanobubbles with the steam separator, which can lead to an increase in the amount of power generation.

<Sixth feature point>
A geothermal power generation device (for example, mainly) that uses the air-water separator according to claims 1 to 5 (for example, mainly air-water separator F) to generate power using a medium heated by the heat of the geotropic as a heat source. Geothermal power generation device 100, geothermal power generation device 200, geothermal power generation device 300).
A medium injection pipe (for example, mainly a medium injection pipe 11) that transfers the medium to the geotropic to the outside, and a medium take-out pipe (for example, a medium take-out pipe that takes out the medium heated by the heat of the geotropic inside the medium injection pipe). For example, a medium transfer pipe (for example, mainly a medium transfer pipe 10) including a medium take-out pipe 12) and
The medium take-out pipe provided with a heat insulating structure having a low effective thermal conductivity in the low temperature region and the medium injection pipe provided with a heat absorbing structure having a high effective thermal conductivity in the high temperature region. And,
The high-temperature medium that has absorbed heat due to the geotropics is transferred to the air-water separator on the ground in a liquid state so as not to generate steam by applying a pressure higher than the evaporation curve, and the air-water separation is performed. It is characterized in that steam is generated by boiling under reduced pressure in a vessel, and power is generated by the steam.

Due to the above characteristics, since the heat obtained from the ground is converted to heat using water as a medium, it is not necessary to consider the effect on the equipment such as the temperature drop of heat due to the scale and the clogging of the pipe, and the scale is removed. We do not consider pollution or damage caused by harmful substances from the ground.
In addition, water droplets in steam collide with the turbine blades rotating at high speed or the inner wall of the pipe, which causes erosion, which not only further reduces efficiency but also causes equipment damage.
In the present invention, since steam is generated by a brackish water separator (brackish water separator) on the ground, hot water is transferred to the ground with higher thermal efficiency than when steam is generated in the ground, and then boiled under reduced pressure. Since steam is generated, problems such as erosion and reduced efficiency can be solved.

<7th feature>
It is a geothermal power generation method that uses a medium heated by the heat of the tropics as a heat source to generate electricity.
A medium injection pipe (for example, mainly a medium injection pipe 11) that transfers the medium to the geotropic to the outside, and a medium take-out pipe (for example, a medium take-out pipe that takes out the medium heated by the heat of the geotropic inside the medium injection pipe). For example, a medium transfer pipe (for example, mainly a medium transfer pipe 10) including a medium take-out pipe 12) and
The medium take-out pipe provided with a heat insulating structure having a low effective thermal conductivity in the low temperature region and the medium injection pipe provided with a heat absorbing structure having a high effective thermal conductivity in the high temperature region. And,
First of operating the geothermal power generation device, the medium transfer pipe is washed, and an oxygen removing means (for example, mainly a deoxidizing device 19 or a deoxidizing agent) for removing oxygen dissolved in the medium is operated.
After removing the oxygen
The high-temperature medium that has absorbed heat due to the geotropics is transferred to a gas-water separator on the ground in a liquid state so as not to generate steam by applying a pressure higher than the evaporation curve. It is characterized in that steam is generated by boiling under reduced pressure and power is generated by the steam.

With the above features, by removing oxygen, it is possible to prevent rust and scale generation in the medium transfer pipe. In particular, since the medium transfer pipe has a long overall length, it is possible to reduce the pressure loss by suppressing the scale of the pressurized water supply pump, which can lead to energy saving of the power in the facility.

<Eighth feature point>
A geothermal power generation device (for example, mainly a geothermal power generation device 100, a geothermal power generation device 200, a geothermal power generation device 300) that generates power using a medium heated by the heat of the geothermal heat as a heat source.
A medium injection pipe (for example, mainly a medium injection pipe 11) that transfers the medium to the geotropic to the outside, and a medium take-out pipe (for example, a medium take-out pipe that takes out the medium heated by the heat of the geotropic inside the medium injection pipe). For example, a medium transfer pipe (for example, mainly a medium transfer pipe 10) including a medium take-out pipe 12) and
The medium take-out pipe provided with a heat insulating structure having a low effective thermal conductivity in the low temperature region and the medium injection pipe provided with a heat absorbing structure having a high effective thermal conductivity in the high temperature region. When,
The high-temperature medium that has absorbed heat due to the geotropics is transferred to an air-water separator on the ground in a liquid state so as not to generate steam by applying a pressure higher than the evaporation curve, and steam is boiled under reduced pressure. With the steam separator (for example, mainly steam separator F)
A storage unit (for example, mainly a hot water service tank 4) for storing the medium that did not become steam in the steam separator, and
A pressure pump (for example, mainly a pressure water supply pump 3) for transporting and pressurizing the medium supplied from the storage unit to the tropics is provided.
A bubble separation unit (for example, mainly a partition plate 71, a drain) that separates bubbles contained in the medium supplied from the brackish water separator and supplies only the medium to the pressurizing pump inside the storage unit. It is characterized by having a receiving plate 77.79).

With the above features, the structure is such that only the medium containing no bubbles can be guided to the pressurized water supply pump. In this way, since the air bubbles are not guided to the pressurized water supply pump, the pressurized water supply pump can prevent cavitation.

<Ninth feature point>
A geothermal power generation device (for example, mainly a geothermal power generation device 100, a geothermal power generation device 200, a geothermal power generation device 300) that generates power using a medium heated by the heat of the geothermal heat as a heat source.
A medium injection pipe (for example, mainly a medium injection pipe 11) that transfers the medium to the geotropic to the outside, and a medium take-out pipe (for example, a medium take-out pipe that takes out the medium heated by the heat of the geotropic inside the medium injection pipe). For example, a medium transfer pipe (for example, mainly a medium transfer pipe 10) including a medium take-out pipe 12) and
The medium take-out pipe provided with a heat insulating structure having a low effective thermal conductivity in the low temperature region and the medium injection pipe provided with a heat absorbing structure having a high effective thermal conductivity in the high temperature region. When,
A water-water separator (for example, mainly a water-water separator) on the ground in a liquid state so as not to generate steam by applying a pressure higher than the evaporation curve to the high-temperature medium that has absorbed heat by the geotropa. The steam separator that generates steam by transferring to F) and boiling under reduced pressure.
A storage unit (for example, mainly a hot water service tank 4) for storing the medium that did not become steam in the steam separator, and
The storage unit includes a bypass path (for example, mainly a steam discharge pipe 75, a path of steam V2) for supplying steam generated from the medium supplied from the steam separator to the steam separator. It is characterized by that.

With the above features, the steam generated in the storage section can be effectively used, and the structure is designed to increase the power generation capacity.

<10th feature point>
A geothermal power generation device (for example, mainly a geothermal power generation device 200) that uses a medium heated by the heat of the geothermal heat as a heat source to generate power.
A medium injection pipe (for example, mainly a medium injection pipe 11) that transfers the medium to the geotropic to the outside, and a medium take-out pipe (for example, a medium take-out pipe that takes out the medium heated by the heat of the geotropic inside the medium injection pipe). For example, a medium transfer pipe (for example, mainly a medium transfer pipe 10) including a medium take-out pipe 12) and
The medium take-out pipe provided with a heat insulating structure having a low effective thermal conductivity in the low temperature region and the medium injection pipe provided with a heat absorbing structure having a high effective thermal conductivity in the high temperature region. When,
The high-temperature medium that has absorbed heat due to the geotropics is transferred to a heat exchanger on the ground in a liquid state so as not to generate vapor by applying a pressure higher than the evaporation curve, and the medium is used as a heat source. A binary power generation device (for example, mainly a binary power generation device B) used in a heat exchanger to vaporize an operating medium having a boiling point lower than that of the medium (for example, mainly operating media M1 to M3) to generate power.
It is characterized by including a storage unit (for example), mainly a hot water service tank 4) that keeps the water level of the medium cooled by heat exchange in the heat exchanger constant throughout the system.

Based on the above features, the load on the pressurized water supply pump can be reduced and the water level can be kept constant by effectively utilizing the storage unit as an element for keeping the pressure of the entire system constant.

<11th feature point>
It is a geothermal power generation device (for example, mainly geothermal power generation device 100, 200, 300) that generates power using a medium heated by the heat of the geothermal heat as a heat source.
A medium injection pipe (for example, mainly a medium injection pipe 11) that transfers the medium to the geotropic to the outside, and a medium take-out pipe (for example, a medium take-out pipe that takes out the medium heated by the heat of the geotropic inside the medium injection pipe). For example, a medium transfer pipe (for example, mainly a medium transfer pipe 10) including a medium take-out pipe 12) and
The medium take-out pipe provided with a heat insulating structure having a low effective thermal conductivity in the low temperature region and the medium injection pipe provided with a heat absorbing structure having a high effective thermal conductivity in the high temperature region. When,
The high-temperature medium that has absorbed heat due to the geotropics is transferred to a heat exchanger on the ground in a liquid state so as not to generate vapor by applying a pressure higher than the evaporation curve, and the medium is used as a heat source. It is equipped with a binary power generation device (for example, mainly a binary power generation device B) that is used in a heat exchanger and vaporizes an operating medium having a boiling point lower than that of the medium to generate power.
The working medium pipe for transferring the cooling medium for cooling the working medium is laid in the ground near the medium transfer pipe to exchange heat with the underground heat (for example, mainly cooling water 157a, It is characterized by being provided with a pipe for cooling 158a).
Regarding the above-mentioned features 1 to 11, the geothermal power generation method that is the invention of the method may be used. Further, the feature points 1 to 5 above may be the brackish water separation method which is the invention of the method.

With the above features, effective use of heat can be realized in the same system (for example, mainly the geothermal power generation device 100).

It goes without saying that the present invention is not limited to the above-described embodiments, and can be carried out in various embodiments as long as it belongs to the technical scope of the present invention.

As shown in the above-described embodiment, it can be used not only in the tropics where hot springs spring out, but also in volcanic areas and underwater volcanic areas.

1,100,200,300 ... Geothermal power generator,
3 ... Pressurized water pump, 4 ... Hot water service tank,
5 ... Condensation pump, 6 ... Condenser,
10 ... Media transfer pipe,
11 ... medium injection tube, 12 ... medium removal tube,
26 ... Evaporation curve, 60 ... Separator,
F ... steam separator, 150 ... heat exchanger, 151 ... heat exchanger,
155 ... Circulation pump,
T / T1, T2 / T3 ... steam turbine, G ... generator,
1a ... Pressurized water power generator, B ... Binary power generator, CT ... Cooling tower,
F ... steam separator, TF ... power receiving equipment,
S ... surface, U ... tropical.

Claims (2)

A steam-water separation device that generates steam by boiling a high-temperature and high-pressure medium under reduced pressure to separate the steam and the medium.
A conical housing portion that receives the ejected medium and gradually expands in diameter in the ejection direction, and a swivel guidance portion that projects from the surface of the housing portion and swivels the medium. ,
The swivel guide portion includes a plurality of spiral swivel guide pieces that are continuous from the tip to the end to receive the ejected medium.
The brackish water separation device is characterized in that the housing portion is located between the swivel guide pieces and includes guide holes for guiding a plurality of steams having formed through holes . A steam-water separation device that generates steam by boiling a medium at high temperature and high pressure under reduced pressure, and separates the steam and the medium after boiling under reduced pressure .
A conical housing portion that receives the ejected medium and gradually expands in diameter in the ejection direction, and a swivel guidance portion that projects from the surface of the housing portion and swivels the medium.
A steam intake hole provided at the tip of the housing and for taking in steam inside the housing,
With
The swirling guide portion guides the medium after boiling under reduced pressure, and the steam intake hole is characterized in that the steam and the medium are separated by inducing the steam inside the housing portion. Steam-water separator.

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