JP2018017188A - Geothermal power plant - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a geothermal power plant capable of returning gas extracted from a condenser to an injection well with small power consumption.SOLUTION: According to one embodiment, a geothermal power plant comprises: a separator separating geothermal fluid into first steam and first water; and a first boiling evaporator boiling and evaporating the first water and discharging second steam and second water obtained from the first water. Further, the plant comprises: a steam turbine driven by the first and second steam; a condenser cooling and condensing exhaust steam from the steam turbine, and discharging condensate obtained from the exhaust steam; and an injection water flow passage transporting injection water including the second water to an injection well. Still further, the plant comprises: a gas extractor extracting gas from the condenser; and a gas flow passage supplying the gas extracted from the condenser to the injection water flow passage and mixing the gas into the injection water.SELECTED DRAWING: Figure 1

Description

  Embodiments of the present invention relate to a geothermal power plant.

  FIG. 14 is a schematic diagram showing a configuration of a conventional geothermal power plant.

  The geothermal power plant in FIG. 14 includes a separator 1, a dehumidifier 2, a steam turbine 3, a generator 4, a condenser 5, a condensate pump 6, a reduced water flow path 7, and a condensate flow path 8. The gas extraction device 9, the sealed water separator 10, the cooling tower 11, the fan stack 12, the cooling water pump 13, the first cooling water flow channel 14, the second cooling water flow channel 15, and the cooling water branch flow channel. 16, a sealed water channel 17, and a gas channel 18. In this plant, a geothermal fluid containing steam and hot water generated by heating groundwater with magma is used for power generation.

  The geothermal fluid from the geothermal well (production well) is separated into steam and hot water by the separator 1. The separated steam is dehumidified by the dehumidifying device 2 to remove water droplets and the like, and then flows into the steam turbine 3 from the steam inlet 3a of the steam turbine 3. When the steam expands in the steam turbine 3 and rotates the steam turbine 3, the generator 4 connected to the steam turbine 3 is rotationally driven to generate power. The exhaust from the steam turbine 3 is condensed in the condenser 5 to become geothermal water (condensate).

  As the exhaust pressure of the steam turbine 3 becomes lower, the heat of the exhaust can be used more effectively, and the efficiency of the plant is improved. Therefore, the exhaust gas from the steam turbine 3 is maintained at a pressure lower than the atmospheric pressure, specifically, maintained in a vacuum state. In the condenser 5, the exhaust of the steam turbine 3 is cooled and condensed by indirect contact with the cooling water, and the vacuum state is maintained. The condensed geothermal water is discharged from the condenser 5 to the condensate flow path 8, boosted by the condensate pump 6 on the condensate flow path 8, and sent to the reduced water flow path 7. The reducing water channel 7 and the condensate channel 8 are configured by piping or the like. The same applies to other flow paths described later.

  On the other hand, the hot water separated by the separator 1 is sent as reduced water to the reduced water channel 7 and merges with water droplets from the dehumidifier 2 and condensate from the condensate channel 8. The reduced water that has merged with the water droplets and condensate is sent to the reduction well through the reduced water flow path 7.

The geothermal fluid from the production well contains non-condensable gas in addition to steam, but the content of non-condensable gas is 0.1% to 10% by weight with respect to the steam and varies depending on the well (overseas 30 There is also an example of weight%). Since the non-condensable gas is not condensed in the condenser 5, it is necessary to discharge the non-condensable gas from the condenser 5 by the gas extraction device 9 to prevent the pressure in the condenser 5 from increasing. The components of the non-condensable gas are generally about 90% carbon dioxide gas (CO ₂ ), 5% to 9% hydrogen sulfide gas (H ₂ S), a small amount of ammonia gas, methane gas, and nitrogen gas. There are often.

  The gas extraction device 9 includes a steam ejector method, a liquid ring vacuum pump method, a gas compressor method, and the like. However, these types of gas extraction devices 9 have advantages and disadvantages, such as consuming steam, requiring low-temperature sealed water, consuming pump power, and having high initial costs. In many cases, a hybrid method is employed in which a plurality of methods are combined in the most economical manner.

  In FIG. 14, a liquid ring vacuum pump is used as the gas extraction device 9, and noncondensable gas accumulated in the condenser 5 is extracted by the gas extraction device 9 which is a vacuum pump. In the gas extraction device 9, the eccentric impeller rotates to form a liquid ring of the sealed water, and the gas is compressed by the eccentric liquid ring.

  The compressed gas is separated into gas and sealed water by a sealed separator 10 installed at the outlet of the gas extraction device 9. The separated sealed water is returned to the condenser 5 via the sealed water flow path 17, collected by the condenser 5, and sent to the reduction well via the condensate flow path 8. On the other hand, the separated gas is sent to the fan stack 12 of the cooling tower 11 through the gas flow path 18, discharged to the vicinity or inside of the fan stack 12, and to the high sky using the wind speed of the fan of the fan stack 12. Carried and diffused.

  The cooling water pump 13 is provided in the first cooling water channel 14 and supplies the cooling water discharged from the cooling tower 11 to the condenser 5 through the first cooling water channel 14. The condenser 5 cools the steam exhausted from the steam turbine 3 by indirect contact with the cooling water. Thereby, since the temperature of the cooling water rises, the cooling water is sent to the cooling tower 11 via the second cooling water flow path 15 and cooled. The cooling water cooled in the cooling tower 11 is supplied to the condenser 5 from the first cooling water flow path 14 again. In this way, the cooling water circulates between the condenser 5 and the cooling tower 11 via the first and second cooling water flow paths 14 and 15. A part of the cooling water flowing through the first cooling water channel 14 is supplied to the gas extraction device 9 via the cooling water branch channel 16.

  Since the wet cooling tower using the latent heat of vaporization is economical, the cooling tower 11 is often wet. When the cooling water evaporates in the cooling tower 11, water (river water or the like) corresponding to the evaporated amount of the cooling water is supplied to the cooling tower 11. However, if only water corresponding to the amount of evaporation is kept replenished, minerals such as calcium and salt contained in river water will be concentrated to become salt water, so a small amount of blowdown is performed.

In this plant, hot water generated from the geothermal fluid is collected in the reducing well by the reducing water flow path 7, but non-condensable gas is diffused from the fan stack 12 in the high sky. The non-condensable gas is released into the atmosphere at a reduced concentration, but if the non-condensable gas contains high-concentration hydrogen sulfide gas, there is a risk of odor of sulfur near the plant. Further, about 90% of the components of the non-condensable gas is carbon dioxide. Therefore, the geothermal power plant emits some CO ₂ even though the amount of CO ₂ emission is much smaller than that of the thermal power plant. Since geothermal power generation is highly expected as renewable energy power generation using natural energy, a cleaner geothermal power plant is desired for the global environment.

Japanese Patent No. 3166033 JP-A-4-321775

  Therefore, it is conceivable that non-condensable gas generated in the geothermal power plant is mixed with hot water (reduced water) from the separator 1 in the reduced water flow path 7 and returned to the reducing well. However, since the reducing water flowing through the reducing water flow path 7 is at a high pressure, it is necessary to raise the non-condensable gas to a pressure equal to or higher than the reducing water pressure in order to mix the non-condensable gas into the reducing water.

  Here, the reduced water from the separator 1 is generally high-temperature and high-pressure saturated water. If the reducing well inlet pressure of the reducing water channel 7 is reduced, a vaporization phenomenon in the piping of the high-temperature reducing water may occur, and the piping of the reducing water channel 7 may be blocked. Therefore, the reduced water from the separator 1 is returned to the reduction well with a high pressure. This is the reason why the reduced water flowing through the reduced water flow path 7 has a high pressure as described above.

  For this reason, when the non-condensable gas is mixed with the reduced water, the non-condensable gas is boosted. Therefore, the power generated in the plant is consumed before being transmitted, which is economically disadvantageous, and the problem is that the economic efficiency of the plant is deteriorated.

  Then, embodiment of this invention makes it a subject to provide the geothermal power plant which can return the gas extracted from the condenser to a reduction well with little power consumption.

  According to one embodiment, the geothermal power plant is obtained from the first water by separating the geothermal fluid into first steam and first water, evaporating the first water to boiling. And a first boiling vaporizer for discharging the second steam and the second water. The plant further includes: a steam turbine driven by the first and second steam; a condenser that cools and condenses exhaust from the steam turbine and discharges condensate obtained from the exhaust; And a reduced water flow path for conveying reduced water containing the second water to the reduction well. Further, the plant includes a gas extraction device that extracts gas from the condenser, and a gas flow path that supplies the gas extracted from the condenser to the reduced water flow path and mixes it with the reduced water. Prepare.

It is a schematic diagram which shows the structure of the geothermal power plant of 1st Embodiment. It is a schematic diagram which shows the structure of the geothermal power plant of 2nd Embodiment. It is a schematic diagram which shows the structure of the geothermal power plant of 3rd Embodiment. It is a schematic diagram which shows the structure of the geothermal power plant of 4th Embodiment. It is a schematic diagram which shows the structure of the geothermal power plant of 5th Embodiment. It is a schematic diagram which shows the structure of the geothermal power plant of 6th Embodiment. It is a schematic diagram which shows the structure of the geothermal power plant of 7th Embodiment. It is a schematic diagram which shows the structure of the geothermal power plant of 8th Embodiment. It is a schematic diagram which shows the structure of the geothermal power plant of 9th Embodiment. It is a schematic diagram which shows the structure of the geothermal power plant of 10th Embodiment. It is a schematic diagram which shows the structure of the geothermal power plant of 11th Embodiment. It is a schematic diagram which shows the structure of the geothermal power plant of 12th Embodiment. It is a schematic diagram which shows the structure of the geothermal power plant of 13th Embodiment. It is a schematic diagram which shows the structure of the conventional geothermal power plant.

  Embodiments of the present invention will be described below with reference to the drawings. 1 to 14, the same or similar components are denoted by the same reference numerals, and redundant description is omitted.

(First embodiment)
Drawing 1 is a mimetic diagram showing composition of a geothermal power plant of a 1st embodiment.

  The geothermal power plant of FIG. 1 includes a boiling vaporizer 21 and a dehumidifier 22 in addition to the components shown in FIG. The boiling vaporizer 21 is an example of a first boiling vaporizer.

  The geothermal fluid from the production well is separated into primary steam and primary hot water by the separator 1. Primary steam is an example of first steam, and primary hot water is an example of first water. The primary steam is dehumidified by the dehumidifying device 2 to remove water droplets and the like, and then flows into the steam turbine 3 from the first steam inlet 3 a of the steam turbine 3. On the other hand, the primary hot water flows into the boiling vaporizer 21 together with water droplets from the dehumidifier 2. The boiling vaporizer 21 evaporates the primary hot water at a low pressure, and generates low-pressure / low-temperature secondary steam and low-pressure / low-temperature secondary hot water from the primary hot water. Secondary steam is an example of the second steam, and secondary hot water is an example of the second water.

  The boiling vaporizer 21 of this embodiment evaporates the primary hot water at a pressure of 0.1 to 0.2 MPa. In the present embodiment, it is possible to suppress the precipitation of silica in the primary hot water by boiling and evaporating the primary hot water at an absolute pressure of 0.1 MPa or more. Moreover, it becomes easy to realize the maximization of the power transmission output as a heat cycle by evaporating the primary hot water at a pressure of 0.2 MPa or less in absolute pressure. An example of primary hot water pressure is about 5 bara, and an example of secondary hot water pressure is about 1.5 bara. The boiling vaporizer 21 discharges secondary steam and secondary hot water obtained from the primary hot water.

  The secondary steam is dehumidified by the dehumidifier 22 to remove water droplets and the like, and then flows into the steam turbine 3 from the second steam inlet 3 b of the steam turbine 3. The second steam inlet 3b is provided downstream from the first steam inlet 3a. The primary steam and the secondary steam join in the steam turbine 3.

  When primary and secondary steam expand in the steam turbine 3 to rotate the steam turbine 3, the generator 4 connected to the steam turbine 3 is rotationally driven to generate power. Since the steam turbine 3 of this embodiment is driven using not only primary steam but also secondary steam, the power generation output of the generator 4 can be increased as compared with the case where the steam turbine 3 is driven only by primary steam. That is, according to the present embodiment, it is possible to effectively use the energy of the geothermal fluid as compared with the case where the steam turbine 3 is driven only by the primary steam.

  The exhaust from the steam turbine 3 is condensed in the condenser 5 to become geothermal water (condensate). In the condenser 5, the exhaust of the steam turbine 3 is cooled and condensed by indirect contact with the cooling water. The condensed geothermal water is discharged from the condenser 5 to the condensate flow path 8, boosted by the condensate pump 6 on the condensate flow path 8, and sent to the reduced water flow path 7.

  On the other hand, the secondary hot water is sent as reducing water to the reducing water channel 7 and merges with water droplets from the dehumidifier 22 and condensate from the condensate channel 8. The reduced water that has merged with the water droplets and condensate is sent to the reduction well through the reduced water flow path 7.

  The geothermal steam from the production well contains noncondensable gas in addition to the steam, but the noncondensable gas is not condensed in the condenser 5. Therefore, the gas extraction device 9 extracts non-condensable gas from the condenser 5 in order to prevent an increase in pressure in the condenser 5. In the gas extraction device 9, the eccentric impeller rotates to form a liquid ring of sealed water, and the gas is compressed by the eccentric liquid ring.

  The compressed gas is separated into gas and sealed water by a sealed separator 10 installed at the outlet of the gas extraction device 9. The separated sealed water is returned to the condenser 5 via the sealed water flow path 17, collected by the condenser 5, and sent to the reduction well via the condensate flow path 8. On the other hand, the separated gas is boosted to a pressure equal to or higher than the reducing water pressure by the gas extraction device 9 and sent to the reducing water channel 7 via the gas channel 18.

  In this way, the non-condensable gas discharged from the gas extraction device 9 is sent to the reducing water flow path 7 instead of the fan stack 12 of the cooling tower 11. Since the reducing water pressure (secondary hot water pressure) of this embodiment is about 1.5 bara, the non-condensable gas is also boosted to about 1.5 bara. Therefore, according to the present embodiment, it is possible to mix non-condensable gas into the reduced water flowing through the reduced water flow path 7. As a result, the non-condensable gas is returned to the reducing well together with the reduced water.

  The cooling water pump 13 supplies the cooling water discharged from the cooling tower 11 to the condenser 5 via the first cooling water channel 14. The condenser 5 cools the exhaust from the steam turbine 3 with cooling water through indirect contact. Thereby, since the temperature of the cooling water rises, the cooling water is sent to the cooling tower 11 via the second cooling water flow path 15 and cooled. In this way, the cooling water circulates between the condenser 5 and the cooling tower 11 via the first and second cooling water flow paths 14 and 15. A part of the cooling water flowing through the first cooling water channel 14 is supplied to the gas extraction device 9 via the cooling water branch channel 16.

  The cooling tower 11 of this embodiment is a wet cooling tower. When the cooling water evaporates in the cooling tower 11, water (river water or the like) corresponding to the evaporated amount of the cooling water is supplied to the cooling tower 11. This water is called make-up water.

  As described above, the geothermal power plant of the present embodiment boiles and vaporizes primary hot water, and generates a low-pressure / low-temperature secondary steam and low-pressure / low-temperature secondary hot water from the primary hot water. The steam turbine 3 is driven by primary steam and secondary steam. Therefore, according to this embodiment, compared with the case where the steam turbine 3 is driven only by the primary steam, the energy of the geothermal fluid can be effectively used.

  As a result, the reduced water of the present embodiment is not primary hot water but secondary hot water having a lower pressure and lower temperature than the primary hot water. If the reduced water is primary hot water, it is necessary to raise the pressure of the non-condensable gas to about 5 bara in order to mix the non-condensable gas into the reduced water. However, since the reduced water of this embodiment is secondary hot water, it is sufficient to raise the non-condensable gas to about 1.5 bara in order to mix the non-condensable gas into the reduced water. Therefore, it is possible to reduce the power consumption for mixing the non-condensable gas into the reduced water and increase the transmission power of the geothermal power plant.

  Therefore, according to the present embodiment, the reduced water is replaced from the primary hot water to the secondary hot water, and the secondary steam is used for power generation, so that the non-condensable gas extracted from the condenser 5 is reduced. It is possible to return to the reduction well with electric power. According to the present embodiment, it is possible to realize a zero emission geothermal power plant that does not release non-condensable gas including hydrogen sulfide gas and carbon dioxide gas from the fan stack 12.

(Second Embodiment)
Drawing 2 is a mimetic diagram showing the composition of the geothermal power plant of a 2nd embodiment.

  The geothermal power plant of FIG. 2 includes a cooling water branch passage 23 in addition to the components shown in FIG.

  In the present embodiment, the condensate discharged from the condenser 5 is sent to the second cooling water channel 15 via the condensate channel 8 and mixed into the cooling water. Therefore, the condensate is sent to the cooling tower 11 together with the cooling water.

  Usually, the amount of condensate generated in the condenser 5 is larger than the amount of cooling water evaporated in the cooling tower 11. Therefore, according to this embodiment, it is possible to continue the operation of the cooling tower 11 without using makeup water. This is effective for geothermal power plants where it is difficult to secure makeup water. Excess condensate exceeding the amount of evaporation of the cooling water is sent from the cooling water branch channel 23 to the reducing water channel 7 using the outlet pressure of the cooling water pump 13.

  On the other hand, the non-condensable gas component is slightly dissolved in the condensate generated in the condenser 5. Therefore, in this embodiment, the component of noncondensable gas mixes in cooling water. However, water generally has a property of releasing a contained gas to the outside when heated and taking in the gas from the outside when cooled. Therefore, when the cooling water is cooled in the cooling tower 11, the amount of non-condensable gas components released from the cooling water is small, and most of the non-condensable gas components are supplied from the cooling water branch channel 23 to the reducing water channel. 7 will be sent.

  In the first embodiment, the condensate is sent to the reduced water flow path 7, so that the components of the noncondensable gas contained in the condensate are prevented from being mixed into the cooling water.

(Third embodiment)
Drawing 3 is a mimetic diagram showing composition of a geothermal power plant of a 3rd embodiment.

  In the geothermal power plant of FIG. 3, the cooling tower 11 of FIG. 1 is replaced with a dry cooling tower 31, and the cooling water branch flow path 16 of FIG. 1 has an indirect contact cooler 32, a sealed water circulation pump 33, and a sealed water branch. The flow path 34 is replaced.

  In the dry cooling tower 31, heat exchange between the cooling water and air is performed by indirect contact between the cooling water and air. Therefore, it can be avoided that the cooling water is lost by evaporation in the dry cooling tower 31. Therefore, according to the present embodiment, it is possible to continue the operation of the dry cooling tower 31 without using makeup water. This is effective for geothermal power plants where it is difficult to secure makeup water.

  Therefore, it is desirable that the gas extraction device 9 operates without consuming cooling water. Therefore, the indirect contact cooler 32 takes in the cooling water from the first cooling water passage 14, cools the sealing water flowing through the sealing water passage 17 by indirect contact with the cooling water, and supplies the cooling water to the second cooling water passage 15. To return. A part of the cooled sealed water is supplied to the gas extraction device 9 by the sealed water circulation pump 33 via the sealed water branch channel 34. Thus, the gas extraction device 9 of this embodiment operates using sealed water instead of cooling water.

  Here, the first embodiment and the third embodiment are compared. Although the geothermal power plant of the first embodiment does not release non-condensable gas from the fan stack 12, it discharges water vapor from the wet cooling tower 11. On the other hand, the geothermal power plant of the present embodiment does not discharge non-condensable gas from the fan stack 12 but also does not discharge water vapor from the dry cooling tower 31. Therefore, according to this embodiment, it is possible to realize a completely zero emission geothermal power plant that does not release water vapor.

  In general, wet cooling towers are installed on the rooftops of urban high-rise buildings to discharge water vapor, whereas outdoor units of home air conditioners are dry and do not discharge water vapor. According to this embodiment, the same effect as in the latter case can be obtained.

(Fourth embodiment)
Drawing 4 is a mimetic diagram showing the composition of the geothermal power plant of a 4th embodiment.

  In the geothermal power plant of FIG. 4, the indirect contact cooler 32 of FIG. 3 is replaced with a radiator 35, and the condenser 5 of FIG. 3 is replaced with an air-cooled condenser 36 and an electric fan 37. 4, the dry cooling tower 31, the fan stack 12, the cooling water pump 13, the first cooling water flow path 14, the second cooling water flow path 15, and the cooling water branch flow path 16 shown in FIG. 3 are removed. Has been.

  The exhaust gas from the steam turbine 3 is cooled by the air-cooled condenser 36 to become condensed water, and is sent to the reduced water channel 7 through the condensed water channel 8. The cooling air of the air-cooled condenser 36 is ventilated by the electric fan 37. Further, the sealed water flowing through the sealed water channel 17 is cooled by the radiator 35.

  According to the present embodiment, as in the third embodiment, it is possible to realize a completely zero emission geothermal power plant that does not release non-condensable gas or water vapor.

(Fifth embodiment)
Drawing 5 is a mimetic diagram showing the composition of the geothermal power plant of a 5th embodiment.

  In the geothermal power plant of FIG. 5, the condenser 5, the condensate pump 6, and the cooling water pump 13 of FIG. 1 are replaced with a direct contact condenser 38, a hot well pump 39, and a cooling water pump 40. It has been.

  The exhaust from the steam turbine 3 is cooled by direct contact with the cooling water in the direct contact condenser 38. As a result, the exhaust of the steam turbine 3 is changed to condensate, and the condensate is mixed with cooling water in the condenser 38. The cooling water mixed with the condensate is sent to the cooling tower 11 via the second cooling water channel 15 by the hot well pump 39. In the wet cooling tower 11, the cooling water is cooled by the effect of evaporating a part of the cooling water and taking away latent heat. The cooling water cooled in the cooling tower 11 is drawn into the vacuum of the condenser 38 and sent from the first cooling water flow path 14 to the condenser 38 without using a pump, and is reused as cooling water. .

  Usually, the amount of condensate generated in the condenser 38 is larger than the amount of cooling water evaporated in the cooling tower 11. Therefore, according to this embodiment, it is possible to continue the operation of the cooling tower 11 without using makeup water. This is effective for geothermal power plants where it is difficult to secure makeup water. Excess condensate that exceeds the evaporation amount of the cooling water is sent from the second cooling water channel 15 downstream of the hot well pump 39 to the reducing water channel 7 via the condensate channel 8. A part of the cooling water flowing through the first cooling water channel 14 is supplied to the gas extraction device 9 by the cooling water pump 40 via the cooling water branch channel 16.

(Sixth embodiment)
Drawing 6 is a mimetic diagram showing the composition of the geothermal power plant of a 6th embodiment.

  The geothermal power plant in FIG. 6 includes a boiling vaporizer 41 and a dehumidifier 42 in addition to the components shown in FIG. The boiling vaporizer 41 is an example of a second boiling vaporizer.

  The geothermal fluid from the production well is separated into primary steam and primary hot water by the separator 1. Primary steam is an example of first steam, and primary hot water is an example of first water. The primary steam is dehumidified by the dehumidifying device 2 to remove water droplets and the like, and then flows into the steam turbine 3 from the first steam inlet 3 a of the steam turbine 3. On the other hand, the primary hot water flows into the boiling vaporizer 41 together with water droplets from the dehumidifier 2 before flowing into the boiling vaporizer 21. The boiling vaporizer 41 boiles and vaporizes the primary hot water at a low pressure (but higher pressure than in the boiling vaporizer 41), and generates low-pressure / low-temperature intermediate steam and low-pressure / low-temperature intermediate hot water from the primary hot water. The intermediate steam is an example of the third steam, and the intermediate hot water is an example of the third water.

  The intermediate steam is dehumidified by the dehumidifying device 42 to remove water droplets and the like, and then flows into the steam turbine 3 from the third steam inlet 3 c of the steam turbine 3. The third steam inlet 3c is provided downstream from the first steam inlet 3a. On the other hand, the intermediate hot water flows into the boiling vaporizer 21 together with water droplets from the dehumidifier 42. The boiling vaporizer 21 evaporates the intermediate hot water at a low pressure, and generates low-pressure / low-temperature secondary steam and low-pressure / low-temperature secondary hot water from the intermediate hot water. Secondary steam is an example of the second steam, and secondary hot water is an example of the second water.

  The secondary steam is dehumidified by the dehumidifier 22 to remove water droplets and the like, and then flows into the steam turbine 3 from the second steam inlet 3 b of the steam turbine 3. The second steam inlet 3b is provided downstream from the third steam inlet 3c. The primary steam, the secondary steam, and the intermediate steam join in the steam turbine 3.

  The boiling vaporizers 41 and 21 of the present embodiment respectively vaporize primary hot water and intermediate hot water at a pressure of 0.1 to 0.2 MPa. In the present embodiment, it is possible to suppress the precipitation of silica in the hot water by boiling and evaporating these hot waters at an absolute pressure of 0.1 MPa or more. Moreover, it becomes easy to realize the maximization of power transmission output as a heat cycle by boiling and evaporating these hot waters at an absolute pressure of 0.2 MPa or less. An example of secondary hot water pressure is about 1.5 bara.

  When the primary, secondary, and intermediate steam expand in the steam turbine 3 to rotate the steam turbine 3, the generator 4 connected to the steam turbine 3 is rotationally driven to generate power. Since the steam turbine 3 of the present embodiment is driven using not only primary and secondary steam but also intermediate steam, the power generation output of the generator 4 is increased as compared with the case where the steam turbine 3 is driven only by the primary and secondary steam. be able to. That is, according to the present embodiment, it is possible to effectively use the energy of the geothermal fluid as compared with the case where the steam turbine 3 is driven only by the primary and secondary steam.

  When the pressure of the geothermal fluid flowing into the separator 1 is sufficiently high, N boiling vaporizers 41 and N dehumidifying devices 42 are provided between the separator 1 and the boiling vaporizer 21. (N is an integer of 2 or more). In this case, the steam turbine 3 is provided with N + 2 steam inlets.

(Seventh embodiment)
FIG. 7 is a schematic diagram illustrating a configuration of a geothermal power plant according to the seventh embodiment.

  In the geothermal power plant of FIG. 7, the reducing water passage 7 and the condensate passage 8 of FIG. 1 are replaced with a first reducing water passage 43 and a second reducing water passage 44. The first reducing water channel 43 is an example of a first channel, and the second reducing water channel 44 is an example of a second channel.

  The secondary hot water generated in the boiling vaporizer 21 is sent as reduced water to the first reduced water flow path 43 and merges with water droplets from the dehumidifier 22. Then, the reduced water that has joined the water droplets is sent to the condenser 5 via the first reduced water flow path 43 and is cooled by the cooling water in the condenser 5. As a result, the temperature and pressure of the reduced water are reduced.

  The reduced water cooled in the condenser 5 is mixed with the condensed water in the condenser 5 and discharged to the second reduced water flow path 44. The reduced water mixed with the condensate merges with the non-condensable gas from the gas flow path 18 in the second reduced water flow path 44 and then is sent to the reduction well along with the non-condensed gas via the second reduced water flow path 44. .

  According to the present embodiment, by further reducing the temperature and pressure of the reducing water, it is possible to reduce the power required for boosting the non-condensable gas, and to reduce the power consumption of the geothermal power plant. Become.

(Eighth embodiment)
FIG. 8 is a schematic diagram showing the configuration of the geothermal power plant of the eighth embodiment.

  In the geothermal power plant of FIG. 8, the boiling vaporizer 21 and the dehumidifier 22 are removed from the geothermal power plant of FIG. Therefore, the primary hot water separated by the separator 1 is sent as reduced water to the first reduced water flow path 43 and merges with water droplets from the dehumidifier 2. Then, the reduced water that has joined the water droplets is sent to the condenser 5 via the first reduced water flow path 43 and is cooled by the cooling water in the condenser 5. As a result, the temperature and pressure of the reduced water are reduced.

  In the geothermal power plants of the first to seventh embodiments, the boiling vaporizer 21 is used to reduce the pressure of the reduced water. However, depending on the geothermal fluid from the production well, the energy of the geothermal fluid may originally be low, so the pressure of the primary hot water separated by the separator 1 may be low. In such a case, the boiling water vaporizer 21 is not used, and the reduced water is simply cooled and depressurized in the condenser 5, so that the reduced water pressure can be mixed with the extracted non-condensable gas. be able to. Therefore, according to this embodiment, it becomes possible to mix non-condensable gas into reduced water without using the boiling vaporizer 21, and it becomes possible to reduce the power consumption of a geothermal power plant.

  In the seventh and eighth embodiments, the first and second reduced water flow paths 43 and 44 are applied to the configuration of the geothermal power plant of the first embodiment, but instead of the second to sixth embodiments. You may apply the 1st and 2nd reduced water flow paths 43 and 44 to the structure of a geothermal power plant.

(Ninth embodiment)
FIG. 9 is a schematic diagram illustrating a configuration of a geothermal power plant according to the ninth embodiment.

  In the geothermal power plant of FIG. 9, the reducing water passage 7 of FIG. 1 is replaced with a first reducing water passage 43, a second reducing water passage 44, and a flash tank 45. The flash tank 45 is an example of a sedimentation part.

  Depending on the production well, the silica-containing concentration of the geothermal fluid may be high. When the silica content concentration of the reducing water is high and the temperature is low, silica dissolved in the reducing water is likely to be precipitated. As a result, silica may adhere to the piping of the first and second reducing water flow paths 43 and 44 and the inner wall of the reducing well, and the piping and the reducing well may be blocked. Therefore, in this embodiment, the flash tank 45 is provided as a countermeasure against silica precipitation.

  The secondary hot water generated in the boiling vaporizer 21 is sent as reduced water to the first reduced water flow path 43 and merges with water droplets from the dehumidifier 22. The reduced water that has joined the water droplets flows into the flash tank 45 via the first reduced water flow path 43.

  The flash tank 45 evaporates the reduced water at a low pressure to cause the silica in the reduced water to precipitate. FIG. 9 shows a silica precipitate 45 a that has been deposited in layers at the bottom of the flash tank 45. The flash tank 45 of this embodiment actively precipitates silica in the reduced water by reducing the pressure of the reduced water to about atmospheric pressure and lowering the temperature of the reduced water to a saturation temperature of about 100 ° C. or lower. To precipitate.

  In the present embodiment, the supernatant of the reduced water accumulated in the flash tank 45 is discharged from the flash tank 45 by a hydrostatic head or pump-up and sent to the second reduced water flow path 44. By discharging the supernatant of the reduced water, it is possible to suppress the silica precipitate from being mixed into the reduced water. The intake position of the supernatant of the reduced water is preferably as close as possible to the water surface of the reduced water, but may be separated from the water surface of the reduced water as long as mixing of silica precipitates can be sufficiently suppressed.

  In the present embodiment, the condensate discharged from the condenser 5 flows into the flash tank 45 via the condensate flow path 8. Therefore, the reduced water including the condensate is discharged from the flash tank 45 to the second reduced water flow path 44. The reduced water discharged from the flash tank 45 merges with the non-condensable gas from the gas flow path 18 in the second reduced water flow path 44, and then is sent to the reducing well along with the non-condensed gas via the second reduced water flow path 44. It is done.

  According to the present embodiment, by further reducing the temperature and pressure of the reducing water, it is possible to reduce the power required for boosting the non-condensable gas, and to reduce the power consumption of the geothermal power plant. Become.

(10th Embodiment)
FIG. 10 is a schematic diagram illustrating a configuration of a geothermal power plant according to the tenth embodiment.

  In the geothermal power plant of FIG. 10, the boiling vaporizer 21 and the dehumidifier 22 are removed from the geothermal power plant of FIG. Therefore, the primary hot water separated by the separator 1 is sent as reduced water to the first reduced water flow path 43 and merges with water droplets from the dehumidifier 2. The reduced water that has merged with the water droplets is sent to the flash tank 45 via the first reduced water flow path 43 and is vaporized at a low pressure. As a result, silica in the reduced water precipitates and precipitates.

  In the geothermal power plants of the first to seventh and ninth embodiments, the boiling vaporizer 21 is used to reduce the pressure of the reduced water. However, in this embodiment, since the reduced water is cooled and decompressed in the flash tank 45 as in the ninth embodiment, a configuration in which the boiling vaporizer 21 is not used is adopted. Therefore, according to this embodiment, it becomes possible to mix non-condensable gas into reduced water without using the boiling vaporizer 21, and it becomes possible to reduce the power consumption of a geothermal power plant.

  In the ninth and tenth embodiments, the flash tank 45 is applied to the configuration of the geothermal power plant of the first embodiment. Instead, the flash tank is added to the configurations of the geothermal power plant of the second to sixth embodiments. 45 may be applied.

  Further, the flash tank 45 of the ninth and tenth embodiments may be replaced with a reduced water tank or a reduced water pond that deposits and precipitates silica in the reduced water. Reduced water tanks and reduced water ponds are examples of sedimentation sections.

(Eleventh embodiment)
FIG. 11 is a schematic diagram illustrating a configuration of a geothermal power plant according to the eleventh embodiment.

  In the geothermal power plant of FIG. 11, the separator 1, the boiling vaporizer 21, and the dehumidifier 22 are removed from the geothermal power plant of FIG.

  Depending on the production well, the geothermal fluid may not contain much hot water, and the geothermal fluid may have a low hot water content and a high steam content. Such a geothermal fluid is called a steam-dominated type. In this case, the necessity for separating the geothermal fluid into steam and hot water by the separator 1 is low. Therefore, the geothermal fluid of this embodiment is introduced into the dehumidifying device 2 without the separator 1 interposed.

  The dehumidifying device 2 dehumidifies the geothermal fluid to remove water droplets from the geothermal fluid, and discharges steam from which the water droplets have been removed. This steam flows into the steam turbine 3 from the first steam inlet 3a of the steam turbine 3, and rotates the steam turbine 3. On the other hand, water droplets obtained by dehumidification are sent as reduced water to the reduced water channel 7 and merge with the condensate from the condensate channel 8. Then, the reduced water that has joined the condensate is sent to the reduction well through the reduced water flow path 7.

  Since this reduced water is mostly composed of condensate, it has a relatively low pressure. Therefore, in this embodiment, the non-condensable gas from the gas flow path 18 can be mixed in the reduced water flowing through the reduced water flow path 7 and returned to the reducing well together with the reduced water.

  According to this embodiment, when the geothermal fluid is a steam-dominated type, it is possible to realize a geothermal power plant that can return non-condensable gas to the reduction well with low power consumption with a simple configuration.

(Twelfth embodiment)
FIG. 12 is a schematic diagram illustrating a configuration of a geothermal power plant according to a twelfth embodiment.

  The geothermal power plant of FIG. 12 includes a valve 46 and a dump capacitor 47 in addition to the components shown in FIG.

  An example of the valve 46 is a spring-type safety valve or a spring-type relief valve provided at a branch portion of the main steam pipe between the dehumidifier 2 and the steam turbine 3. Normally, pressure pipes such as main steam pipes have spring-type safety valves that fully open to protect the pipe when the pressure in the pipe exceeds the maximum operating pressure, and a little when the pressure in the pipe exceeds the normal pressure. A spring-type relief valve is provided that opens and controls the pressure to normal pressure. Instead of providing both a spring-type safety valve and a spring-type relief valve in the pressure pipe, a relief safety valve that also functions as these valves may be provided in the pressure pipe. In the present embodiment, the valve 46 is assumed to be this relief safety valve.

  Normally, the vapor passing through the valve 46 is released into the atmosphere. On the other hand, the steam that has passed through the valve 46 of this embodiment is sent to the dump condenser 47. The dump condenser 47 takes in the cooling water from the first cooling water flow path 14, cools the steam from the valve 46 by indirect contact with the cooling water, and returns the cooling water to the second cooling water flow path 15. The dump condenser 47 condenses the steam by cooling, and collects water (condensate) generated by the condensation in the condenser 5. Water from the dump condenser 47 is mixed into the condensate in the condenser 5.

  On the other hand, in the dump condenser 47, non-condensable gas is generated from the steam in addition to water. In this embodiment, this non-condensable gas is sent to the gas extraction device 9 and merged with the non-condensable gas from the condenser 5, but is sent to another system of gas extraction devices installed in parallel with the gas extraction device 9. Also good. The non-condensable gas discharged from the gas extraction device 9 or the gas extraction device of another system is sent to the reducing water channel 7 via the gas channel 18 and mixed into the reducing water.

  According to this embodiment, it is possible to realize a cleaner geothermal power plant by collecting the steam from the valve 46 by the dump condenser 47 or the like without releasing it into the atmosphere.

(13th Embodiment)
FIG. 13 is a schematic diagram illustrating a configuration of a geothermal power plant according to a thirteenth embodiment.

  In the geothermal power plant of FIG. 13, the dump capacitor 47 is removed from the geothermal power plant of FIG. Then, the steam that has passed through the valve 46 is introduced into the condenser 5 and mixed into the exhaust of the steam turbine 3 in the condenser 5. As a result, this steam is condensed in the same manner as the exhaust of the steam turbine 3 to become geothermal water (condensate), and is discharged from the condenser 5 to the condensate flow path 8. On the other hand, the non-condensable gas generated from the steam and the exhaust of the steam turbine 3 is extracted from the condenser 5 by the gas extraction device 9.

  According to this embodiment, it is possible to realize a cleaner geothermal power plant by collecting the steam from the valve 46 by the condenser 5 without releasing it into the atmosphere.

  In addition, in 11th-13th Embodiment, although the separatorless structure is applied to the geothermal power plant of 1st Embodiment, the separatorless structure is used for the geothermal power plant of 2nd-6th Embodiment instead. You may apply.

  Although several embodiments have been described above, these embodiments are presented as examples only and are not intended to limit the scope of the invention. The novel plant described herein can be implemented in a variety of other forms. Moreover, various omissions, substitutions, and changes can be made to the form of the plant described in the present specification without departing from the scope of the invention. The appended claims and their equivalents are intended to include such forms and modifications as fall within the scope and spirit of the invention.

1: separator, 2: dehumidifier, 3: steam turbine,
3a: first steam inlet, 3b: second steam inlet, 3c: third steam inlet,
4: generator, 5: condenser, 6: condensate pump, 7: reduced water flow path, 8: condensate flow path,
9: Gas extraction device, 10: Sealed water separator, 11: Cooling tower, 12: Fan stack,
13: Cooling water pump, 14: 1st cooling water flow path, 15: 2nd cooling water flow path,
16: Cooling water branch channel, 17: Sealed water channel, 18: Gas channel,
21: Boiling vaporizer, 22: Dehumidifier, 23: Cooling water branch flow path,
31: Dry cooling tower, 32: Indirect contact cooler, 33: Sealed water circulation pump,
34: Sealed water branch flow path, 35: Radiator, 36: Air-cooled condenser,
37: Electric fan, 38: Direct contact condenser, 39: Hot well pump,
40: Cooling water pump, 41: Boiling vaporizer, 42: Dehumidifier,
43: first reduced water flow path, 44: second reduced water flow path, 45: flash tank,
45a: Silica precipitate, 46: Valve, 47: Dump condenser

Claims (15)

A separator that separates the geothermal fluid into first steam and first water;
A first boiling vaporizer configured to boil and vaporize the first water and to discharge the second steam and the second water obtained from the first water;
A steam turbine driven by the first and second steam;
A condenser for cooling and condensing the exhaust from the steam turbine, and discharging the condensate obtained from the exhaust;
A reduced water flow path for conveying reduced water containing the second water to the reduction well;
A gas extraction device for extracting gas from the condenser;
A gas flow path for supplying the gas extracted from the condenser to the reduced water flow path and mixing it in the reduced water;
A geothermal power plant. A cooling tower for supplying cooling water for cooling the exhaust,
A cooling water flow path for circulating the cooling water between the cooling tower and the condenser;
A condensate flow path for supplying the condensate discharged from the condenser to the reduced water flow path and mixing it into the reduced water;
The geothermal power plant according to claim 1, further comprising: A cooling tower for supplying cooling water for cooling the exhaust,
A cooling water flow path for circulating the cooling water between the cooling tower and the condenser;
A condensate flow path for supplying the condensate discharged from the condenser to the cooling water flow path and mixing it into the cooling water;
The geothermal power plant according to claim 1, further comprising: A dry cooling tower for supplying cooling water for cooling the exhaust;
A cooling water flow path for circulating the cooling water between the cooling tower and the condenser;
The geothermal power plant according to claim 1, further comprising:   The geothermal power plant according to claim 1, wherein the condenser is an air-cooled condenser that cools the exhaust air. A cooling tower for supplying cooling water for cooling the exhaust,
A cooling water flow path for circulating the cooling water between the cooling tower and the condenser;
The geothermal power plant according to claim 1, wherein the condenser cools the exhaust gas by direct contact between the exhaust gas and the cooling water, and discharges the cooling water and the condensate into the cooling water flow path. A second boiling vaporizer configured to boil and vaporize the first water and discharge third steam and third water obtained from the first water;
The first boiling vaporizer vaporizes the third water, discharges the second steam and the second water obtained from the third water,
The geothermal power plant of claim 1, wherein the steam turbine is driven by the first, second, and third steam.   The reduced water flow path includes a first flow path that supplies the reduced water to the condenser, and a second flow path that conveys the reduced water discharged from the condenser to the reducing well. Item 2. A geothermal power plant according to item 1. Further comprising a precipitation part for precipitating and precipitating silica in the reduced water,
The reduced water flow path includes a first flow path for supplying the reduced water to the settling portion, and a second flow path for discharging the reduced water supernatant accumulated in the settling portion and transporting the reduced water to the reducing well. The geothermal power plant according to claim 1. A separator that separates the geothermal fluid into first steam and first water;
A steam turbine driven by the first steam;
A condenser for cooling and condensing the exhaust from the steam turbine, and discharging the condensate obtained from the exhaust;
A reduced water channel for conveying reduced water containing the first water to a reduction well, a first channel for supplying the reduced water to the condenser, and the reduced water discharged from the condenser A reduced water channel comprising: a second channel that transports the reducing well to the reduction well;
A gas extraction device for extracting gas from the condenser;
A gas flow path for supplying the gas extracted from the condenser to the reduced water flow path and mixing it in the reduced water;
A geothermal power plant. A separator that separates the geothermal fluid into first steam and first water;
A steam turbine driven by the first steam;
A condenser for cooling and condensing the exhaust from the steam turbine, and discharging the condensate obtained from the exhaust;
A precipitation part for precipitating and precipitating silica in reduced water containing the first water;
A reducing water channel for conveying the reducing water to the reducing well, the first channel supplying the reducing water to the settling portion; and the reducing water supernatant accumulated in the settling portion is discharged to reduce the reducing well A reduced water flow path comprising a second flow path transported to
A gas extraction device for extracting gas from the condenser;
A gas flow path for supplying the gas extracted from the condenser to the reduced water flow path and mixing it in the reduced water;
A geothermal power plant. A dehumidifying device in which the geothermal fluid is introduced without a separator separating the geothermal fluid into steam and water, and dehumidifies the geothermal fluid;
A steam turbine driven by steam discharged from the dehumidifier;
A condenser for cooling and condensing the exhaust from the steam turbine, and discharging the condensate obtained from the exhaust;
A reduced water flow path for transporting reduced water containing water obtained by the dehumidification to the reduction well;
A gas extraction device for extracting gas from the condenser;
A gas flow path for supplying the gas extracted from the condenser to the reduced water flow path and mixing it in the reduced water;
A geothermal power plant. A dump condenser that cools and condenses the steam discharged from the dehumidifier;
A valve for supplying the steam discharged from the dehumidifying device to the dump condenser,
The geothermal power plant according to claim 12, wherein water obtained from the steam by the dump condenser is supplied to the condenser and mixed into the condensate.   The geothermal power plant according to claim 12, further comprising a valve for supplying the steam discharged from the dehumidifying device to the condenser and mixing the steam into the exhaust gas.   The geothermal power generation according to any one of claims 1 to 9, wherein the first or second boiling vaporizer vaporizes the first or third water at a pressure of 0.1 to 0.2 MPa. plant.