WO2013002054A1 - 太陽熱ボイラおよびそれを用いた太陽熱発電プラント - Google Patents
太陽熱ボイラおよびそれを用いた太陽熱発電プラント Download PDFInfo
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- WO2013002054A1 WO2013002054A1 PCT/JP2012/065497 JP2012065497W WO2013002054A1 WO 2013002054 A1 WO2013002054 A1 WO 2013002054A1 JP 2012065497 W JP2012065497 W JP 2012065497W WO 2013002054 A1 WO2013002054 A1 WO 2013002054A1
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- heating device
- heat
- temperature heating
- water
- low
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F03—MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
- F03G—SPRING, WEIGHT, INERTIA OR LIKE MOTORS; MECHANICAL-POWER PRODUCING DEVICES OR MECHANISMS, NOT OTHERWISE PROVIDED FOR OR USING ENERGY SOURCES NOT OTHERWISE PROVIDED FOR
- F03G6/00—Devices for producing mechanical power from solar energy
- F03G6/06—Devices for producing mechanical power from solar energy with solar energy concentrating means
- F03G6/065—Devices for producing mechanical power from solar energy with solar energy concentrating means having a Rankine cycle
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F03—MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
- F03G—SPRING, WEIGHT, INERTIA OR LIKE MOTORS; MECHANICAL-POWER PRODUCING DEVICES OR MECHANISMS, NOT OTHERWISE PROVIDED FOR OR USING ENERGY SOURCES NOT OTHERWISE PROVIDED FOR
- F03G6/00—Devices for producing mechanical power from solar energy
- F03G6/06—Devices for producing mechanical power from solar energy with solar energy concentrating means
- F03G6/065—Devices for producing mechanical power from solar energy with solar energy concentrating means having a Rankine cycle
- F03G6/067—Binary cycle plants where the fluid from the solar collector heats the working fluid via a heat exchanger
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F22—STEAM GENERATION
- F22B—METHODS OF STEAM GENERATION; STEAM BOILERS
- F22B1/00—Methods of steam generation characterised by form of heating method
- F22B1/006—Methods of steam generation characterised by form of heating method using solar heat
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24S—SOLAR HEAT COLLECTORS; SOLAR HEAT SYSTEMS
- F24S10/00—Solar heat collectors using working fluids
- F24S10/25—Solar heat collectors using working fluids having two or more passages for the same working fluid layered in direction of solar-rays, e.g. having upper circulation channels connected with lower circulation channels
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24S—SOLAR HEAT COLLECTORS; SOLAR HEAT SYSTEMS
- F24S20/00—Solar heat collectors specially adapted for particular uses or environments
- F24S20/20—Solar heat collectors for receiving concentrated solar energy, e.g. receivers for solar power plants
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24S—SOLAR HEAT COLLECTORS; SOLAR HEAT SYSTEMS
- F24S23/00—Arrangements for concentrating solar-rays for solar heat collectors
- F24S23/70—Arrangements for concentrating solar-rays for solar heat collectors with reflectors
- F24S23/74—Arrangements for concentrating solar-rays for solar heat collectors with reflectors with trough-shaped or cylindro-parabolic reflective surfaces
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24S—SOLAR HEAT COLLECTORS; SOLAR HEAT SYSTEMS
- F24S23/00—Arrangements for concentrating solar-rays for solar heat collectors
- F24S23/70—Arrangements for concentrating solar-rays for solar heat collectors with reflectors
- F24S23/80—Arrangements for concentrating solar-rays for solar heat collectors with reflectors having discontinuous faces
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K7/00—Arrangements for handling mechanical energy structurally associated with dynamo-electric machines, e.g. structural association with mechanical driving motors or auxiliary dynamo-electric machines
- H02K7/18—Structural association of electric generators with mechanical driving motors, e.g. with turbines
- H02K7/1807—Rotary generators
- H02K7/1823—Rotary generators structurally associated with turbines or similar engines
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24S—SOLAR HEAT COLLECTORS; SOLAR HEAT SYSTEMS
- F24S23/00—Arrangements for concentrating solar-rays for solar heat collectors
- F24S23/70—Arrangements for concentrating solar-rays for solar heat collectors with reflectors
- F24S2023/83—Other shapes
- F24S2023/834—Other shapes trough-shaped
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/40—Solar thermal energy, e.g. solar towers
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/40—Solar thermal energy, e.g. solar towers
- Y02E10/44—Heat exchange systems
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/40—Solar thermal energy, e.g. solar towers
- Y02E10/46—Conversion of thermal power into mechanical power, e.g. Rankine, Stirling or solar thermal engines
Definitions
- the present invention relates to a solar boiler that collects heat from the sun and generates steam by the heat, and a solar power plant using the solar boiler, and is particularly inexpensive and can prevent thermal damage to a heat transfer tube and the solar boiler
- the present invention relates to a solar thermal power plant using
- the amount of heat collected in a solar boiler is unavoidably repeated as the amount of sunshine changes rapidly in a short period of time, such as the sun being blocked by clouds depending on the location.
- solar boilers are often introduced in a region called a sun belt region, that is, a region where the amount of direct sunshine per year exceeds 2000 kWh / m 2 .
- Concentrating / collecting solar thermal power plants can be broadly divided into single power plants and combined power plants.
- most of the heat is not covered by solar heat, and some is backed up by fossil fuels.
- most of the heat is supplied by fossil fuels and nuclear fuel, and part of it is backed up by solar heat.
- a heat transfer tube is disposed above the inner peripheral curved surface of a condensing mirror extending in a bowl shape, and sunlight is condensed on the heat transfer tube by the light collecting mirror.
- the heat transfer tube panel is installed on a tower with a predetermined height, while a heat transfer tube panel is installed on the ground surface.
- the tower type etc. which arrange
- the trough type and the Fresnel type have a short focal length, and the solar condensing degree (heat density at the heat collecting part) is low.
- the tower type since the tower type has a long focal length, it has a feature that the degree of solar condensing (heat density at the heat collecting portion) is high.
- the heat density in the heat collecting part is high, the amount of heat collected per unit heat transfer area is high, and higher temperature steam can be obtained.
- the heat density is simply increased and the phase is changed from the water state to the superheated steam, there is a problem that a high temperature region is locally formed and the heat transfer tube is damaged.
- Patent Document 1 and Patent Document 2 propose solar solar boilers configured as shown in FIGS. 17 and 18 in order to solve such a problem in the tower type having a high heat density.
- FIG. 17 is a schematic configuration diagram of a solar heat boiler
- FIG. 18 is an enlarged schematic configuration diagram of a heat collecting device used for the solar heat boiler.
- reference numeral 1 is a heat collecting device
- 2 is an evaporator
- 3 is a superheater
- 4 is a brackish water separator
- 5 is a tower
- 6 is a heliostat
- 7 is the sun
- 8 is a steam turbine
- 9 is a generator.
- 11 is a water supply pump.
- the heat collecting device 1 is functionally separated into an evaporator 2 and a superheater 3, and a brackish water separation device 4 is installed between the evaporator 2 and the superheater 3.
- the heat collecting apparatus 1 is installed on a tower 5 having a height of about 30 to 100 m.
- the heliostat 6 installed on the ground reflects light from the sun 7 and collects it on the heat collecting apparatus 1.
- the evaporator 2 and the superheater 3 are heated by light.
- the superheated steam generated by the heat collecting apparatus 1 is sent to the steam turbine 8 to rotate the generator 9 to generate electricity.
- FIG. 19 is a schematic configuration diagram of a solar thermal power generation system described in US Pat. No. 7,296,380 (Patent Document 3).
- reference numeral 200 is a solar thermal power generation system
- 201 is a fluid path
- 202 is a valve
- 203 is a pump
- 204 is a trough device
- 205 is a heat collecting pipe
- 206 is a solar collector
- 207 is a tower
- 208 is a low-temperature heat storage tank
- Reference numeral 209 denotes an intermediate heat storage tank
- 210 denotes a high temperature heat storage tank
- 211 denotes a high output generator
- 212 denotes a turbine
- 213 denotes a generator.
- the heat fluid medium stored in the low-temperature heat storage tank 208 is supplied to the trough device 204 by the pump 203, heated by the heat collected from the light of the sun 106, and further heated by the tower 207. It is sent to the high temperature heat storage tank 210.
- the heat fluid medium sent to the high-temperature heat storage tank 210 is sent to the high-power generator 211 by the pump 203, and returned to the low-temperature heat storage tank 208 in a state where the temperature is lowered by heat exchange.
- the steam generated by the high output generator 211 is sent to the turbine 212 and is generated by the generator 213.
- FIG. 20 is a schematic configuration diagram of a solar heat concentrating plant described in US Pat. No. 8,087,245 (Patent Document 4).
- 301 is a trough collector
- 302 is a heliostat and tower
- 303 is a low temperature regenerator
- 304 is a high temperature regenerator
- 305 is a fossil fuel auxiliary device
- 306 is a turbine
- 307 is a generator
- 308 is condensate.
- 309 is a pump.
- This solar thermal concentrating plant sends water to the trough collector 301 with a pump 309 and heats it with solar heat to generate saturated steam, sends the generated saturated steam to the heliostat and tower 302, and superheated steam.
- the turbine 306 is driven and the generator 307 generates power.
- a high-power generator 211 is required for heat exchange between the heat fluid medium and water-steam, and further, a generator 307 is controlled by suppressing temperature changes due to variations in solar radiation.
- a low-temperature heat storage tank 208, an intermediate heat storage tank 209, a high-temperature heat storage tank 210, and the like are also required. Therefore, there is a problem that the equipment cost is increased and the installation space is enlarged.
- the object of the present invention is to eliminate such drawbacks of the prior art, avoid thermal damage to the heat transfer tubes without increasing equipment costs and construction costs, and suppress fluctuations in the amount of power generation in the steam turbine.
- An object of the present invention is to provide a solar boiler capable of supplying high-quality electricity, and a single type or a composite type solar power plant using the solar boiler.
- the first means of the present invention is a solar boiler, A low-temperature heating device that heats water supplied from a water supply pump by the heat of sunlight; A brackish water separator for separating the water-steam two-phase fluid generated by the low-temperature heating device into water and steam; A high-temperature heating device that heats the steam separated by the brackish water separation device with the heat of sunlight, A circulation pump for supplying water separated by the brackish water separator to the low-temperature heating device is provided.
- the low temperature heating device and the brackish water separation device are installed on the ground surface or near the ground surface, and the high temperature heating device is installed at a higher position than the low temperature heating device and the brackish water separation device.
- a third means of the present invention is the first or second means,
- the low temperature heating device is:
- a heat transfer tube is arranged above the inner peripheral curved surface of the condensing mirror extending in a bowl shape, and sunlight is condensed on the heat transfer tube by the condensing mirror, thereby heating the water circulating in the heat transfer tube to generate steam.
- a heat transfer tube panel is installed on a tower having a predetermined height, a large number of condenser mirrors are arranged on the ground surface, and sunlight is condensed on the heat transfer tube panel by the condenser mirror group. It consists of a tower-type light collecting / collecting device that heats the water flowing through the heat tube panel to generate steam.
- a fourth means of the present invention is the first to third means,
- the outlet fluid temperature of the low-temperature heating device is regulated to 300 ° C. or lower.
- a fifth means of the present invention is the first to fourth means, A configuration in which a thermometer and a flow meter are installed at the outlet of the low-temperature heating device, and the feed water flow rate to the low-temperature heating device is adjusted so that the temperature and flow rate measured by the thermometer and the flow meter become predetermined values. It is characterized by being.
- a sixth means of the present invention is the first to fourth means, A thermometer and a flow meter are installed at the outlet of the low-temperature heating device, and the amount of heat collected by the low-temperature heating device is adjusted so that the temperature and flow rate measured by the thermometer and the flow meter become predetermined values. It is characterized by becoming.
- a seventh means of the present invention is the first to fourth means, A thermometer and a flow meter are installed at the outlet of the low-temperature heating device, and the amount of heat collected by the high-temperature heating device is adjusted according to the temperature and flow rate values measured by the thermometer and the flow meter. It is characterized by this.
- the eighth means of the present invention is the first to third means, A water level meter for measuring the water level of the brackish water separator, A water supply valve for adjusting a water supply flow rate to the low-temperature heating device; A circulation flow rate control valve for adjusting the circulation amount of water between the low temperature heating device and the brackish water separator is provided, The water supply flow rate or the circulation rate is adjusted by the water supply valve or the circulation flow rate control valve so that the water level of the brackish water separator becomes a predetermined value.
- the ninth means of the present invention is the first or second means,
- the low temperature heating device is: For example, a heat medium flow path through which a heat medium such as diphenyl oxide, biphenyl, 1,1 diphenylethane circulates, A heat medium circulation pump provided in the middle of the heat medium flow path; A light collecting / collecting device that is provided in the middle of the heat medium flow path and transmits heat generated by collecting sunlight to the heat medium circulating in the heat medium flow path; A part of the heat medium flow path includes a low-temperature heating device with a heat exchanger installed inside as a heat exchanger, The heat collected by the condensing / heat collecting device is transmitted to the water in the low-temperature heating device with the heat exchanger via the heat medium.
- a heat medium flow path through which a heat medium such as diphenyl oxide, biphenyl, 1,1 diphenylethane circulates,
- a heat medium circulation pump provided in the middle of the heat medium flow path
- a light collecting / collecting device that is provided
- the tenth means of the present invention is a solar thermal power plant,
- a generator driven by the steam turbine is provided.
- the eleventh means of the present invention is a solar thermal power plant, A boiler that generates steam by burning or generating heat; A water supply pump for supplying water to the boiler, A steam turbine driven by steam generated in the boiler; A generator driven by the steam turbine; A feed water heater for heating water supplied from the feed pump; A low-temperature heating device that heats a part of the water supplied from the feed water pump with the heat of sunlight using the extracted steam from the steam turbine; A brackish water separator that separates the water-steam two-phase fluid generated by the low-temperature heating device into water and steam; A high-temperature heating device that heats the steam separated by the brackish water separation device with the heat of sunlight, A circulation pump is provided for supplying water separated by the brackish water separation device to a low-temperature heating device.
- the twelfth means of the present invention is the eleventh means,
- the low temperature heating device, the brackish water separation device and the circulation pump are installed on the ground surface or near the ground surface, and the high temperature heating device is installed at a higher position than the low temperature heating device and the brackish water separation device. .
- the thirteenth means of the present invention is the eleventh or twelfth means
- the low temperature heating device is:
- a heat transfer tube is arranged above the inner peripheral curved surface of the condensing mirror extending in a bowl shape, and the sunlight is condensed on the heat transfer tube by the condensing mirror, thereby heating the water circulating in the heat transfer tube to steam.
- a large number of trough-type condensing / heat collecting devices or substantially planar collecting mirrors are arranged, a heat transfer tube is arranged above the collecting mirror group, and the sunlight is transmitted through the collecting mirror group.
- the high temperature heating device is: A heat transfer tube panel is installed on a tower having a predetermined height, a large number of condensing mirrors are arranged, and sunlight is condensed on the heat transfer tube panel by the condensing mirror group. It is characterized by comprising a tower-type light collecting / collecting device that generates steam by heating water flowing through the water.
- the fourteenth means of the present invention is the eleventh to thirteenth means,
- the outlet fluid temperature of the low-temperature heating device is regulated to 300 ° C. or lower.
- a fifteenth means of the present invention is the eleventh to thirteenth means, A configuration in which a thermometer and a flow meter are installed at the outlet of the low-temperature heating device, and the feed water flow rate to the low-temperature heating device is adjusted so that the temperature and flow rate measured by the thermometer and the flow meter become predetermined values. It is characterized by being.
- the sixteenth means of the present invention is the eleventh to thirteenth means, A thermometer and a flow meter are installed at the outlet of the low-temperature heating device, and the amount of heat collected by the low-temperature heating device is adjusted so that the temperature and flow rate measured by the thermometer and the flow meter become predetermined values. It is characterized by becoming.
- the seventeenth means of the present invention is the eleventh to thirteenth means, A thermometer and a flow meter are installed at the outlet of the low-temperature heating device, and the amount of heat collected by the high-temperature heating device is adjusted according to the temperature and flow rate values measured by the thermometer and the flow meter. It is characterized by this.
- the eighteenth means of the present invention is the eleventh to thirteenth means, A water level meter for measuring the water level of the brackish water separator, A water supply valve for adjusting a water supply flow rate to the low-temperature heating device; A circulation flow rate control valve for adjusting the circulation amount of water between the low temperature heating device and the brackish water separator is provided, The water supply flow rate or the circulation rate is adjusted by the water supply valve or the circulation flow rate control valve so that the water level of the brackish water separator becomes a predetermined value.
- the low temperature heating device is: A heat medium flow path through which the heat medium circulates; A heat medium circulation pump provided in the middle of the heat medium flow path; A light collecting / collecting device that is provided in the middle of the heat medium flow path and transmits heat generated by collecting sunlight to the heat medium circulating in the heat medium flow path; A part of the heat medium flow path includes a low-temperature heating device with a heat exchanger installed inside as a heat exchanger, The heat collected by the light collecting / heat collecting device is transmitted to the water in the low temperature heating device with the heat exchanger through the heat medium.
- the twentieth means of the present invention is the eleventh to thirteenth means, An extraction valve is provided on the outlet side of the steam turbine, The bleed valve is operated in accordance with the amount of steam supplied from the high temperature heating device to adjust the bleed amount of the steam turbine.
- the present invention is configured as described above, and can avoid thermal damage to the heat transfer tube without increasing the equipment cost and construction cost, and also suppresses fluctuations in the amount of power generation in the steam turbine. It is possible to provide a solar boiler capable of supplying a high amount of electricity and a single type or a composite type solar power plant using the solar boiler.
- FIG. 1 is a schematic configuration diagram of a solar thermal power plant according to a first embodiment of the present invention. It is a principle figure for demonstrating the structure of the tower type condensing and heat collecting apparatus which installed the high temperature heating apparatus. It is an expansion schematic block diagram of the heat exchanger tube panel used for the high temperature heating apparatus. It is a schematic block diagram of the solar thermal single power plant which concerns on 2nd Embodiment of this invention. It is a principle figure for demonstrating the structure of a trough-type condensing and heat collecting apparatus. It is a principle figure for demonstrating the structure of a Fresnel type condensing / heat collecting apparatus. It is a schematic block diagram of the solar thermal single power plant which concerns on 3rd Embodiment of this invention.
- (A) is a diagram showing the flow state of the water-steam two-phase flow in the horizontal heat transfer tube of the low-temperature heating apparatus, and (b) is the flow state of the water-steam two-phase flow in the horizontal heat transfer tube.
- FIG. 1 is a schematic configuration diagram of a solar thermal power plant according to the first embodiment of the present invention.
- the water supplied from the feed water pump 11 passes through the feed valve 19, is sent to the feed water heater 12, is heated, and is introduced into the low temperature heating device 13 through the brackish water separator 4.
- the In this low temperature heating device 13 the feed water is heated by the light 32 from the sun 7, and the water is circulated between the brackish water separator 4 and the low temperature heating device 13 by the circulation pump 15.
- the water-steam two-phase fluid generated by the low-temperature heating device 13 is separated into saturated water and saturated steam by the brackish water separation device 4, and the separated steam is sent to the high-temperature heating device 14 installed on the tower 16.
- the steam introduced into the high-temperature heating device 14 is further superheated by solar heat reflected by the riostat 6 and guided to the high-temperature heating device 14.
- the superheated steam generated by the high-temperature heating device 14 rotates the steam turbine 8 and generates electricity by the generator 9 by the rotation.
- a feed water valve 19 is installed between the feed water pump 11 and the feed water heater 12, and a steam valve 18 is installed between the high temperature heating device 14 and the steam turbine 8. Has been.
- FIG. 2 is a principle diagram for explaining the configuration of a tower-type light collecting / collecting device provided with the high-temperature heating device 14.
- the tower type light collecting and heat collecting apparatus is provided with a high temperature heating device 14 (heat transfer tube panel 27) on a tower 16 having a predetermined height (about 30 to 100 m).
- a large number of heliostats 6 are arranged in various directions on the ground surface, and the heliostats 6 are focused on the high-temperature heating device 14 (heat transfer tube panel 27) while tracking the movement of the sun 7, and overheated. It is a mechanism to generate steam.
- This tower-type concentrator / heat collector has the advantage that it can generate higher-temperature steam than the trough-type concentrator / collector, increasing the turbine efficiency and obtaining more power. is doing.
- FIG. 3 is an enlarged schematic configuration diagram of the heat transfer tube panel 27 used in the high-temperature heating device 14.
- the heat transfer tube panel 27 includes a superheater lower header 22 that evenly distributes the steam from the brackish water separator 4 and superheater transmissions arranged in parallel to distribute the steam distributed by the superheater lower header 22. It consists of a heat pipe 21 and a superheater upper header 23 that collects superheated steam flowing out from the superheater heat transfer pipe 21. The superheated steam output from the superheater upper header 23 is supplied to the steam turbine 8.
- the low-temperature heating device 13 and the brackish water separation device 4 have a large amount of water inside, and the entire device becomes heavy. Therefore, the ground surface or a lower foundation with a height of, for example, about 1 to 2 m is used near the ground surface. It is installed. Thus, since the low temperature heating device 13 and the brackish water separation device 4 are installed on the ground surface or in the vicinity thereof, it is not necessary to raise the water to a height of, for example, 30 to 100 m as in the prior art, and therefore the pumping capacity is low. An inexpensive feed water pump 11 can be used.
- the high-temperature heating device 14 is installed at a height of 10 m or more (for example, 30 to 100 m) from the ground surface in order to collect the light 32 from the heliostat 6 with high light density. Since the fluid flowing inside the high-temperature heating device 14 is only steam, it is much lighter and smaller than the conventional heat collecting device 1 (see FIG. 18) comprising the evaporator 2, the superheater 3, and the brackish water separator 4. It is.
- the heat collection ratio of the low temperature heating device 13 and the high temperature heating device 14 is approximately 9: 1 to 7: 3, and the heat collection amount of the high temperature heating device 14 is much smaller than that of the low temperature heating device 13.
- a circulation pump 15 is installed on a path from the brackish water separator 4 to the low temperature heater 13. Compared with the case where the circulation pump 15 is installed on the path from the low-temperature heating device 13 to the brackish water separation device 4, the operating temperature of the circulation pump 15 can be lowered, so there is no need to use an expensive pump with high heat resistance. Cost reduction and reliability improvement can be achieved. This effect is also obtained in the second and subsequent embodiments.
- FIG. 4 is a schematic configuration diagram of a solar thermal power plant according to the second embodiment of the present invention.
- a low-temperature heating device 24 including a trough-type light collecting / collecting device is used.
- Other configurations and power generation mechanisms are the same as those in the first embodiment, and a duplicate description is omitted.
- FIG. 5 is a principle diagram for explaining the configuration of a trough-type condensing / heat collecting device.
- this trough-type condensing / heat collecting device has a heat transfer tube 31 disposed horizontally at a focal position above the inner peripheral curved surface of a condensing mirror 30 extending in a bowl shape, and sunlight 32. Is condensed on the heat transfer tube 31 by the condenser mirror 30. Water 33 circulates in each heat transfer tube 31, and the water 33 is heated by the heat collected in the heat transfer tube 31, and a water-steam two-phase fluid 34 is obtained from the heat transfer tube 31. .
- This trough-type condensing / heat collecting apparatus has the advantages that it does not require advanced condensing technology and has a relatively simple structure.
- the low-temperature heating device 24 composed of a trough-type condensing / collecting device is used, but a low-temperature heating device composed of a Fresnel-type condensing / collecting device may be used.
- FIG. 6 is a principle diagram for explaining the configuration of a Fresnel type light collecting / heat collecting device.
- this Fresnel type condenser / heat collector has a large number of planar or slightly curved condenser mirrors 35 arranged at slightly different angles and several meters above the condenser mirror 35 group.
- the heat exchanger tube 31 group which became the panel shape is arrange
- This Fresnel type condenser / heat collector is easier to manufacture than the trough-type curved condenser mirror 30, can be produced at a low cost, and has the advantage that the condenser mirror 35 is less susceptible to wind pressure. ing.
- FIG. 7 is a schematic configuration diagram of a solar thermal power plant according to the third embodiment of the present invention.
- a thermometer 25 and a flow meter 28 for measuring fluid temperature and flow rate are provided on the outlet side of the low-temperature heating device 24, and measurement signals of the thermometer 25 and the flow meter 28 are calculated.
- the arithmetic unit 26 outputs a control signal for controlling the opening of the water supply valve 19, that is, the water supply flow rate, to the water supply valve 19 so that the outlet fluid temperature of the low temperature heating device 24 is always 300 ° C. or lower. Yes.
- the structure of the low-temperature heating device 24 composed of a trough-type (or Fresnel-type) light collecting / collecting device can be simplified, and transmission can be performed.
- a decrease in thermal efficiency can be suppressed.
- the outer glass tube cracks due to the difference in thermal elongation between the heat transfer tube and the outer glass tube, which is a problem when using a trough-type (or Fresnel-type) light collecting / collecting device at a high temperature, and Radiation cooling due to an increase in the surface temperature of the heat transfer tube can be suppressed.
- FIG. 8 is a partially enlarged cross-sectional view of the vicinity of a heat transfer tube used in a trough-type (or Fresnel-type) light collecting / collecting device.
- an outer peripheral glass tube 42 is disposed on the outer periphery of the horizontal heat transfer tube 38 to form a double structure.
- the outer peripheral glass tube 42 is provided in order to suppress heat release from the horizontal heat transfer tube 38 to the outside air by making the space between the horizontal heat transfer tube 38 and the outer peripheral glass tube 42 airtight or vacuum.
- the heat transfer tubes 38 are joined together to form one long heat transfer tube 38. Since the heat transfer tube 38 is made of a metal such as carbon steel stainless steel, as shown in FIG.
- the heat transfer tubes 38 can be welded 43 to a predetermined length.
- metal bonding pipes 44 are respectively arranged on the inner side and the outer side of the joint portion of the outer glass tube 42.
- the outer peripheral glass tube 42 and the bonding tube 44 are welded to each other so that the outer peripheral glass tubes 42 are connected to each other with a predetermined length via the bonding tube 44.
- the heat transfer tube 38 connected to a predetermined length is inserted inside the outer peripheral glass tube 42 connected to the predetermined length, and attached to the condensing / heat collecting apparatus. Therefore, when the difference in thermal expansion between the heat transfer tube 38 and the outer peripheral glass tube 42 is increased, the vicinity of the connecting portion between the outer peripheral glass tube 42 and the bonding tube 44 may be broken.
- the temperature of the outlet fluid of the low-temperature heating device 24 is limited to 300 ° C. or less, specifically 250 to 300 ° C., and the peripheral glass due to the difference in thermal expansion between the heat transfer tube 38 and the peripheral glass tube 42. Radiation cooling due to cracking of the tube 42 and an increase in the surface temperature of the heat transfer tube 38 is suppressed.
- the heat collection amount of the high-temperature heating device 14 can be adjusted based on the measurement signals of the thermometer 25 and the flow meter 28 so that the outlet fluid temperature of the high-temperature heating device 14 is 300 ° C. or higher.
- the amount of heat collection is adjusted by adjusting the opening of the water supply valve 19 and changing the water supply flow rate.
- thermometer 25 and the flow meter 28 are installed on the outlet side of the low temperature heating device 24, and the feed water flow rate to the low temperature heating device 24 is adjusted so that the measured temperature and flow rate become predetermined values.
- a thermometer 25 and a flow meter 28 may be installed on the outlet side of the low-temperature heating device 24, and the amount of heat collected by the low-temperature heating device 24 may be adjusted so that the measured temperature and flow rate become predetermined values.
- FIG. 9 relates to a fourth embodiment of the present invention, and relates to a boiler plant and a solar thermal power plant in which fuel is burned or exothermic (for example, in the case of nuclear fuel) or exhaust gas is recovered to generate steam. It is a schematic block diagram of the combined solar thermal power plant.
- a boiler plant 10 that generates steam by burning or generating heat or recovering the heat of exhaust heat gas, and its boiler
- a water supply pump 11 that supplies water to the plant 10
- a steam turbine 8 that is driven by superheated steam generated in the boiler plant 10, and water supplied from the water supply pump 11 using the extracted steam from the steam turbine 8.
- a feed water heater 12 is provided.
- the water supply supplied to the boiler plant 10 is supplied to the low-temperature heating device 13 through the feedwater valve 20 and heated by the light 32 of the sun 7. A part of it becomes a water-steam two-phase fluid converted into steam and flows into the brackish water separator 4.
- the steam is separated into saturated steam and saturated water by the brackish water separator 4, and the saturated water is supplied again to the low-temperature heating device 13 by the circulation pump 15.
- the saturated steam separated by the brackish water separator 4 is heated by the high-temperature heating device 14 to become high-temperature steam and sent to the feed water heater 12 (from A to A in the figure).
- high-temperature steam heated by the high-temperature heating device 14 is supplied to the boiler plant 10 (from A to A ′ in the figure), or with superheated steam that has come out of the boiler plant 10. It can also be supplied to the steam turbine 8 (from A to A ′′ in the figure).
- FIG. 10 is provided on the outlet side of the steam turbine 8 in accordance with the change in the amount of steam passing through the steam valve 18 provided on the outlet side of the high-temperature heating device 14 as shown in FIG. 9 [see FIG. It is the figure which showed an example which adjusts the opening degree of the extraction valve 17 [refer FIG.10 (b)].
- FIG. 11 is a schematic configuration diagram of a solar thermal combined power plant according to the fifth embodiment of the present invention.
- This embodiment is different from the fourth embodiment in that a low-temperature heating device 24 composed of a trough-type or Fresnel-type condensing / heat collecting device is used.
- Other configurations and power generation mechanisms are the same as those in the fourth embodiment, and a duplicate description is omitted.
- FIG. 12 is a schematic configuration diagram of a solar thermal combined power plant according to the sixth embodiment of the present invention.
- a thermometer 25 and a flow meter 28 for measuring the fluid temperature are provided on the outlet side of the low-temperature heating device 24, and measurement signals from the thermometer 25 and the flow meter 28 are calculated.
- the arithmetic unit 26 outputs a control signal for controlling the opening of the water supply valve 20, that is, the water supply flow rate, to the water supply valve 20 so that the outlet fluid temperature of the low temperature heating device 24 is always 300 ° C. or lower. Yes.
- outlet fluid temperature of the low-temperature heating device 24 is limited to 300 ° C. or lower is the same as that in the third embodiment, and a duplicate description is omitted.
- the low-temperature heating device 13 (24) and the high-temperature heating device 14 ultimately use a fluid consisting of steam (water) that drives the steam turbine 8 as a heat medium, and directly use this as the sun 7.
- This is a light collecting / collecting device that heats with the light 32.
- the solar heat boiler does not use a heat exchanger other than the low-temperature heating device 13 (24) and the high-temperature heating device 14, the configuration of the entire boiler device is simple, and the size and cost can be reduced. have.
- a Fresnel-type or trough-type condensing / collecting device used in the low-temperature heating device 13 (24) particularly has its heat transfer. If a phase change occurs from water to steam in the tube, resulting in a two-phase flow, the heat transfer tube may be locally damaged thermally.
- the Fresnel type or trough type light collecting / collecting device receives heat in the concentrated range of the outer peripheral surface of the horizontally arranged heat transfer tubes, so that the heat flux distribution is uneven over the outer periphery of the heat transfer tubes. It is the structure which is easy to produce.
- Fresnel-type and trough-type concentrators / heat collectors are installed in a vast area with long heat transfer tubes arranged almost horizontally, and the amount of heat collected by sunlight varies greatly throughout the day. Also, it changes rapidly depending on the weather, and it is difficult to specify the range in which the two-phase flow flows in advance.
- FIG. 13 is a schematic block diagram of the solar-heat-only power plant which concerns on this 7th Embodiment.
- a feed water circulation flow rate control valve 37 for adjusting the circulation flow rate and a flow meter 28 are provided on the inlet side of the low temperature heating device 13, and a water level meter for detecting the water level of the brackish water separator 4 29 is provided.
- the flow rate measurement signal of the flow meter 28 and the water level measurement signal of the water level meter 29 are input to the arithmetic device 26, and the arithmetic device 26 supplies water for adjusting the feed water flow rate so that the water level of the brackish water separator 4 becomes the target value.
- a control signal is output to the valve 19 or (and) the feed water circulation flow rate control valve 37 for adjusting the circulation flow rate.
- FIG. 14 is a characteristic diagram showing the relationship between the water level L (horizontal axis) of the brackish water separator 4 and the outlet quality (ratio of the steam flow rate in the total mass flow rate) X (vertical axis) of the low-temperature heating device 13.
- the relationship between the water level L and the outlet quality X is shown with the total mass flow rate G of the separator 4 as a parameter.
- the outlet quality X of the low-temperature heating device 13 is the ratio of the mass flow rate of steam to the total mass flow rate G. Further, the total mass flow rate G of the brackish water separator 4 is a flow rate of fluid circulating through the low temperature heating device 13 via the brackish water separator 4.
- FIG. 15A shows the outlet quality X of the low-temperature heating device 13 on the horizontal axis and the total mass flow rate G of the brackish water separator 4 on the vertical axis. It is the figure which divided
- FIG. 15 (b) is a schematic diagram showing each flow state of the water-steam two-phase flow in the horizontal heat transfer tube 38.
- the states of the spray flow, the annular flow, the bubble flow, the slag flow and the stratified flow are shown in FIG. It is shown.
- the water-steam two-phase flow is a spray flow, which means that most of the inside of the pipe is steam and minute water droplets flow along with the steam.
- An annular flow forms a very thin water film on the tube wall, and the inside thereof indicates a state of a spray flow mainly composed of steam.
- the bubble flow indicates a state where most of the inside of the pipe is filled with water and small bubbles are present therein.
- the slug flow is considerably larger than the bubble flow, and indicates an intermediate state between the bubble flow and the stratified flow.
- the stratified flow indicates a state where the gas phase and the liquid phase are separated from each other by the action of gravity. Therefore, a preferable flow state of the water-steam two-phase flow in the horizontal heat transfer tube 38 is a spray flow or an annular flow.
- the outlet quality X of the low-temperature heating device 13 and the total mass flow rate G of the brackish water separator 4 are known, the flow of the water-steam two-phase flow in the low-temperature heating device 13 You can know the state.
- the outlet quality is X 1.
- the flow state of the water-steam two-phase flow in the horizontal heat transfer tube 38 of the low-temperature heating device 13 is a spray flow. I understand.
- the flow state is a bubble flow, an annular flow, or a spray flow over all operating conditions.
- an annular flow or a spray flow is particularly desirable.
- the water level target value of the brackish water separator 4 corresponding to the value of the outlet quality X that achieves a desired flow state as described above is stored in the arithmetic unit 26 in advance. Then, the measurement signals of the flow rate of the flow meter 28 and the water level of the water level meter 29 are input to the calculation device 26, and the calculation device 26 adjusts the feed water flow rate so that the water level of the brackish water separator 4 becomes the target value.
- the control signal is output to the feed water circulation valve 19 or (and) the feed water circulation flow rate control valve 37 for adjusting the circulation flow rate, so that the power plant can be stably operated.
- the present invention can also be applied to a solar thermal power plant.
- FIG. 16 is a schematic configuration diagram of a solar thermal power generation plant according to the eighth embodiment.
- the low-temperature heating device 51 and the condensing / heat collecting device 52 are separated, and the condensing / heat collecting device 52 is provided with a heat medium flow channel 53, and in the middle of the heat medium flow channel 53.
- a heat medium circulation pump 55 is provided.
- a part of the heat medium flow path 53 is disposed in the low temperature heating device 51 as a heat exchanger to form a low temperature heating device with a heat exchanger, and the heat medium 54 flows from the condensing / heat collecting device 52 to the heat medium flow. It is configured to circulate in the passage 53.
- the heat collected by the condensing / heat collecting device 52 is transmitted to the low temperature heating device 51 through the heat medium 54 circulating in the heat medium flow path 53, and the water-vapor fluid in the low temperature heating device 51 is heated.
- the heat exchanger in the low-temperature heating device 51 (in this embodiment, a part of the heat medium flow channel 53) is a non-contact between the heat medium 54 and the fluid composed of water-vapor in the low-temperature heating device 51.
- the light collecting / heat collecting device 52 a light collecting device and a heat collecting device can be installed at a low position near the ground surface, such as a Fresnel type or trough type light collecting / heat collecting device. Is preferred.
- the heat medium 54 a heat medium that does not change phase in the operating temperature range is used, and the heat medium circulation pump 55 circulates the heat medium flow path 53 from the condensing / heat collecting device 52.
- the heat medium 54 for example, a simple substance such as diphenyl oxide, biphenyl, 1,1 diphenylethane, or a chemically synthesized oil blended can be used.
- the maximum operating temperature of the exemplified heat medium 54 is about 400 ° C., and if it exceeds this, the performance is significantly deteriorated and lost. For this reason, strict temperature control is required.
- a heat medium thermometer 56 is attached to the heat medium flow path 53 to monitor the temperature of the outlet heat medium of the light collecting / heat collecting device 52.
- the temperature of the heat medium 54 is lower than the maximum use temperature, for example, regulated to 300 ° C. or less, so that it is not necessary to take special measures within the operation range.
- the heat medium 54 does not change phase and does not become a two-phase flow. Therefore, thermal damage of the heat transfer tube is not caused even under uneven heat flux distribution conditions, and reliability can be improved and material cost can be reduced.
- a heat medium thermometer 56 and a heat medium flow meter 57 for measuring the temperature and flow rate of the heat medium 54 are provided on the outlet side of the light collecting / heat collecting device 52.
- Each measurement signal of the medium flow meter 57 is input to the arithmetic unit 26.
- a control signal for controlling the opening degree of the water supply valve 20, that is, the water supply flow rate, is supplied so that the outlet side heat medium temperature of the light collecting / heat collecting device 52 becomes 300 ° C. or less. To output.
- the reason for restricting the outlet fluid temperature of the light collecting / heat collecting device 52 to 300 ° C. or lower is the same as that in the third embodiment, and a duplicate description is omitted. Also, Other configurations are the same as those in the above-described embodiment, and thus, duplicate description is omitted.
- the low-temperature heating device 51 uses solar heat for steam generation / heating indirectly through a heat medium heated by a separate condensing / heat collecting device 52, and the high-temperature heating device 14 uses other heat.
- the steam is directly heated by the collected and collected solar heat, and so-called hybrid heating type.
- the configuration and scale of the parts related to the circulation system of the heat medium such as the heat exchanger and the heat medium circulation pump 55 that complicate the structure of the boiler device, are suppressed to the necessary minimum.
- the problem described at the beginning of the description of the seventh embodiment can be reliably suppressed, which is effective.
- the feed water heater 12 used in each of the above-described embodiments one having a configuration in which the feed water is heated by a heat medium such as steam is used, but the feed water heater 12 is also configured to heat the feed water using solar heat. Is also possible.
- the present invention eliminates the need for a structure (for example, a support base) that supports a heavy object that holds saturated water, A structure that is low and easy to install and maintain the low-temperature heating device and the brackish water separator is sufficient. Further, it is possible to simplify the structure for installing a relatively lightweight high-temperature heating apparatus that holds only steam at a high place.
- the risk of damage to the heat transfer tube can be reduced by functionally separating the low temperature heating device and the high temperature heating device and installing a brackish water separation device between them. Furthermore, by installing a high-temperature heating device at a high place, heat exchange with high heat density is possible, and high-temperature steam can be efficiently obtained.
- the steam turbine output can be kept constant by adjusting the amount of extracted steam on the steam turbine side in accordance with the fluctuation of the steam temperature and the steam flow rate when the heat collection amount is controlled by the high-temperature heating device. .
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Abstract
Description
これらの図において、符号1は集熱装置、2は蒸発器、3は過熱器、4は汽水分離装置、5はタワー、6はへリオスタット、7は太陽、8は蒸気タービン、9は発電機、11は給水ポンプである。
給水ポンプから供給される水を太陽光の熱で加熱する低温加熱装置と、
その低温加熱装置によって生成した水-蒸気二相流体を水と蒸気とに分離する汽水分離装置と、
その汽水分離装置で分離された蒸気を太陽光の熱で加熱する高温加熱装置と、
前記汽水分離装置で分離した水を前記低温加熱装置に供給する循環ポンプを備えたことを特徴とするものである。
前記低温加熱装置と汽水分離装置を地上面または地上面付近に設置し、前記高温加熱装置を前記低温加熱装置ならびに汽水分離装置よりも高所に設置したことを特徴とするものである。
前記低温加熱装置は、
桶状に延びた集光ミラーの内周曲面の上方に伝熱管を配置し、太陽光を集光ミラーで伝熱管に集光することにより、伝熱管内を流通する水を加熱して蒸気を生成するトラフ式の集光・集熱装置、または略平面状(平面状または内側に向けて若干曲面状)の集光ミラーを多数並べて、その集光ミラー群の上方に伝熱管を配置し、太陽光を前記集光ミラー群で伝熱管に集光することにより、伝熱管内を流通する水を加熱して蒸気を生成するフレネル式の集光・集熱装置からなり、
前記高温加熱装置は、
所定の高さを有するタワーの上に伝熱管パネルを設置し、多数の集光ミラーを地上面に配置して、太陽光を前記集光ミラー群で伝熱管パネルに集光することにより、伝熱管パネル内を流通する水を加熱して蒸気を生成するタワー式の集光・集熱装置からなることを特徴とするものである。
前記低温加熱装置の出口流体温度を300℃以下に規制したことを特徴とするものである。
前記低温加熱装置の出口に温度計および流量計を設置して、その温度計および流量計で計測した温度および流量が所定の値になるように、前記低温加熱装置への給水流量を調整する構成になっていることを特徴とするものである。
前記低温加熱装置の出口に温度計および流量計を設置して、その温度計および流量計で計測した温度および流量が所定の値になるように、前記低温加熱装置の集熱量を調整する構成になっていることを特徴とするものである。
前記低温加熱装置の出口に温度計および流量計を設置して、その温度計および流量計で計測した温度および流量の値に応じて、前記高温加熱装置の集熱量を調整する構成になっていることを特徴とするものである。
前記汽水分離装置の水位を計測する水位計と、
前記低温加熱装置への給水流量を調整する給水弁と、
前記低温加熱装置と前記汽水分離装置の間の水の循環量を調整する循環流量制御弁を設け、
前記汽水分離装置の水位が所定の値になるように、前記給水弁あるいは循環流量制御弁によって給水流量あるいは循環量を調整する構成になっていることを特徴とするものである。
前記低温加熱装置は、
例えば酸化ジフェ二ル、ビフェ二ル、1,1ジフェ二ルエタンなどの熱媒体が循環する熱媒体流路と、
その熱媒体流路の途中に設けられた熱媒体循環ポンプと、
前記熱媒体流路の途中に設けられ、太陽光を集光して生じた熱を前記熱媒体流路を循環する熱媒体に伝達する集光・集熱装置と、
前記熱媒体流路の一部が熱交換器として内側に設置された熱交換器付き低温加熱装置を備えて、
前記集光・集熱装置で集熱した熱を前記熱媒体を介して前記熱交換器付き低温加熱装置内の水に伝達する構成になっていることを特徴とするものである。
前記第1ないし第9の手段の太陽熱ボイラと、
その太陽熱ボイラで生成した蒸気により駆動される蒸気タービンと、
その蒸気タービンで駆動される発電機を備えたことを特徴とするものである。
燃料を燃焼もしくは発熱させて蒸気を発生させるボイラと、
そのボイラへ水を供給する給水ポンプと、
前記ボイラで発生した蒸気で駆動される蒸気タービンと、
その蒸気タービンで駆動される発電機と、
前記給水ポンプから供給される水を加熱する給水加熱器と、
前記蒸気タービンからの抽気蒸気を用いて、前記給水ポンプから供給される水の一部を太陽光の熱で加熱する低温加熱装置と、
その低温加熱装置で生成した水-蒸気二相流体を水と蒸気とに分離する汽水分離装置と、
その汽水分離装置で分離された蒸気を太陽光の熱で加熱する高温加熱装置と、
前記汽水分離装置で分離した水を低温加熱装置に供給する循環ポンプを
備えたことを特徴とするものである。
前記低温加熱装置と汽水分離装置と循環ポンプを地上面または地上面付近に設置し、前記高温加熱装置を前記低温加熱装置ならびに汽水分離装置よりも高所に設置したことを特徴とするものである。
前記低温加熱装置は、
桶状に延びた集光ミラーの内周曲面の上方に伝熱管を配置し、前記太陽光を集光ミラーで伝熱管に集光することにより、伝熱管内を流通する水を加熱して蒸気を生成するトラフ式の集光・集熱装置、または略平面状の集光ミラーを多数並べて、その集光ミラー群の上方に伝熱管を配置し、前記太陽光を前記集光ミラー群で伝熱管に集光することにより、伝熱管内を流通する水を加熱して蒸気を生成するフレネル式の集光・集熱装置からなり、
前記高温加熱装置は、
所定の高さを有するタワーの上に伝熱管パネルを設置し、多数の集光ミラーを配置して、太陽光を前記集光ミラー群で伝熱管パネルに集光することにより、伝熱管パネル内を流通する水を加熱して蒸気を生成するタワー式の集光・集熱装置からなることを特徴とするものである。
前記低温加熱装置の出口流体温度を300℃以下に規制したことを特徴とするものである。
前記低温加熱装置の出口に温度計および流量計を設置して、その温度計および流量計で計測した温度および流量が所定の値になるように、前記低温加熱装置への給水流量を調整する構成になっていることを特徴とするものである。
前記低温加熱装置の出口に温度計および流量計を設置して、その温度計および流量計で計測した温度および流量が所定の値になるように、前記低温加熱装置の集熱量を調整する構成になっていることを特徴とするものである。
前記低温加熱装置の出口に温度計および流量計を設置して、その温度計および流量計で計測した温度および流量の値に応じて、前記高温加熱装置の集熱量を調整する構成になっていることを特徴とするものである。
前記汽水分離装置の水位を計測する水位計と、
前記低温加熱装置への給水流量を調整する給水弁と、
前記低温加熱装置と前記汽水分離装置の間の水の循環量を調整する循環流量制御弁を設け、
前記汽水分離装置の水位が所定の値になるように、前記給水弁あるいは循環流量制御弁によって給水流量あるいは循環量を調整する構成になっていることを特徴とするものである。
前記低温加熱装置は、
熱媒体が循環する熱媒体流路と、
その熱媒体流路の途中に設けられた熱媒体循環ポンプと、
前記熱媒体流路の途中に設けられ、太陽光を集光して生じた熱を前記熱媒体流路を循環する熱媒体に伝達する集光・集熱装置と、
前記熱媒体流路の一部が熱交換器として内側に設置された熱交換器付き低温加熱装置を備えて、
前記集光・集熱装置で集熱した熱を前記熱媒体を通じて前記熱交換器付き低温加熱装置内の水に伝達する構成になっていることを特徴とするものである。
前記蒸気タービンの出口側に抽気弁を設け、
前記高温加熱装置から供給される蒸気量に応じて前記抽気弁を操作して、前記蒸気タービンの抽気量を調整する構成になっていることを特徴とするものである。
次に本発明の実施形態を図面と共に説明する。図1は、本発明の第1実施形態に係る太陽熱単独型発電プラントの概略構成図である。
このタワー式集光・集熱装置は図2に示すように、所定の高さ(30~100m程度)を有するタワー16の上に高温加熱装置14(伝熱管パネル27)を設置する。一方、地上面に多数のヘリオスタット6を色々な向きに配置して、太陽7の動きを追尾しながら前記ヘリオスタット6群で高温加熱装置14(伝熱管パネル27)に集光して、過熱蒸気を生成する仕組みになっている。
図4は、本発明の第2実施形態に係る太陽熱単独型発電プラントの概略構成図である。
本実施形態では、トラフ式の集光・集熱装置からなる低温加熱装置24を用いている。他の構成や発電の仕組みなどは前記第1実施形態と同様であるので、重複する説明は省略する。
このトラフ式の集光・集熱装置は図5に示すように、桶状に延びた集光ミラー30の内周曲面上方の焦点位置に個別に伝熱管31を水平に配置し、太陽光32を前記集光ミラー30で伝熱管31に集光する。各伝熱管31内には水33が流通しており、伝熱管31に集められた熱によってその水33が加熱され、伝熱管31から水-蒸気二相流体34が得られる仕組みになっている。
このトラフ式の集光・集熱装置は、高度な集光技術は不要であり、構造が比較的単純であるという長所を有している。
このフレネル式の集光・集熱装置は図6に示すように、平面状あるいは若干曲面状の集光ミラー35を角度を少しずつ変えて多数枚並べて、その集光ミラー35群の上方数メートルの所にパネル状になった伝熱管31群を水平に配置する。
図7は、本発明の第3実施形態に係る太陽熱単独型発電プラントの概略構成図である。
本実施形態の場合図7に示すように、低温加熱装置24の出口側に流体温度と流量を測定する温度計25と流量計28を設け、その温度計25と流量計28の計測信号を演算装置26に入力する。そして演算装置26では、低温加熱装置24の出口流体温度が常に300℃以下になるように、給水弁19の開度、すなわち、給水流量を制御するための制御信号を給水弁19に出力している。
図9は、本発明の第4実施形態に係り、燃料を燃焼もしくは発熱(例えば核燃料の場合)させて、あるいは排気ガスの熱を回収して蒸気を発生させるなどのボイラプラントと太陽熱発電プラントを組み合わせた太陽熱複合型発電プラントの概略構成図である。
また、蒸気タービン8から一部の蒸気が抽気され、抽気弁17を通って給水加熱器12へ送られ、給水が加熱される。
図11は、本発明の第5実施形態に係る太陽熱複合型発電プラントの概略構成図である。
本実施形態で前記第4実施形態と相違する点は、トラフ式あるいはフレネル式の集光・集熱装置からなる低温加熱装置24を用いた点である。
他の構成や発電の仕組みなどは前記第4実施形態と同様であるので、重複する説明は省略する。
図12は、本発明の第6実施形態に係る太陽熱複合型発電プラントの概略構成図である。
本実施形態の場合図12に示すように、低温加熱装置24の出口側に流体温度を測定する温度計25と流量計28を設け、その温度計25と流量計28の計測信号を演算装置26に入力する。そして演算装置26では、低温加熱装置24の出口流体温度が常に300℃以下になるように、給水弁20の開度、すなわち、給水流量を制御するための制御信号を給水弁20に出力している。
前記何れの実施形態においても、低温加熱装置13(24)および高温加熱装置14は、最終的には蒸気タービン8を駆動する蒸気(水)からなる流体を熱媒体として、これを直接、太陽7の光32で加熱する集光・集熱装置となっている。
従って、水平伝熱管38内における水-蒸気二相流の好ましい流動状態は、噴霧流あるいは環状流である。
本発明の第8実施形態も前記第7実施形態と同様の問題点を解消するためのもので、図16はこの第8実施形態に係る太陽熱複合型発電プラントの概略構成図である。
本実施形態において、集光・集熱装置52としては、フレネル型またはトラフ型の集光・集熱装置のように、地表付近の低い位置に集光手段と集熱手段とが設置可能なものが好適である。
図16に示すように、集光・集熱装置52の出口側に熱媒体54の温度と流量を測定する熱媒体温度計56と熱媒体流量計57を設け、その熱媒体温度計56と熱媒体流量計57の計測信号をそれぞれ演算装置26に入力する。
他の構成は前述した実施形態と同じなので、同様に、重複する説明は省略する。
さらにまた、高温加熱装置を高所に設置することで、熱密度の高い熱交換が可能となり、高温の蒸気を効率的に得ることができる。
また、高温加熱装置で集熱量を制御した際の蒸気温度や蒸気流量の変動に応じて、蒸気タービン側の抽気蒸気量を調整することで、蒸気タービンの出力を一定に保つことが可能となる。
6:ヘリオスタット、
7:太陽、
8:蒸気タービン、
9:発電機、
10:ボイラプラント、
11:給水ポンプ、
12:給水加熱器、
13:低温加熱装置、
14:高温加熱装置、
15:循環ポンプ、
16:タワー、
17:抽気弁、
18:蒸気弁、
21:過熱器伝熱管、
24:トラフ式低温加熱装置、
25:温度計、
26:演算装置、
27:伝熱管パネル、
28:流量計、
30,35:集光ミラー、
31:伝熱管、
32:太陽の光、
33:水、
34:水-蒸気二相流、
37:循環流量制御弁、
38:水平伝熱管、
51:低温加熱装置、
52:集光・集熱装置、
53:熱媒体流路、
54:熱媒体、
55:熱媒体循環ポンプ、
56:熱媒体温度計、
57:熱媒体流量計。
Claims (20)
- 給水ポンプから供給される水を太陽光の熱で加熱する低温加熱装置と、
その低温加熱装置によって生成した水-蒸気二相流体を水と蒸気とに分離する汽水分離装置と、
その汽水分離装置で分離された蒸気を太陽光の熱で過熱する高温加熱装置と、
前記汽水分離装置で分離した水を前記低温加熱装置に供給する循環ポンプを備えたことを特徴とする太陽熱ボイラ。 - 請求項1に記載の太陽熱ボイラにおいて、
前記低温加熱装置と汽水分離装置と循環ポンプを地上面または地上面付近に設置し、前記高温加熱装置を前記低温加熱装置ならびに汽水分離装置よりも高所に設置したことを特徴とする太陽熱ボイラ。 - 請求項1または2に記載の太陽熱ボイラにおいて、
前記低温加熱装置は、
桶状に延びた集光ミラーの内周曲面の上方に伝熱管を配置し、前記太陽光を集光ミラーで伝熱管に集光することにより、伝熱管内を流通する水を加熱して蒸気を生成するトラフ式の集光・集熱装置、または略平面状の集光ミラーを多数並べて、その集光ミラー群の上方に伝熱管を配置し、前記太陽光を前記集光ミラー群で伝熱管に集光することにより、伝熱管内を流通する水を加熱して蒸気を生成するフレネル式の集光・集熱装置からなり、
前記高温加熱装置は、
所定の高さを有するタワーの上に伝熱管パネルを設置し、多数の集光ミラーを配置して、前記太陽光を前記集光ミラー群で伝熱管パネルに集光することにより、伝熱管パネル内を流通する水蒸気を過熱するタワー式の集光・集熱装置からなることを特徴とする太陽熱ボイラ。 - 請求項1ないし3のいずれか1項に記載の太陽熱ボイラにおいて、
前記低温加熱装置の出口流体温度を300℃以下に規制したことを特徴とする太陽熱ボイラ。 - 請求項1ないし4のいずれか1項に記載の太陽熱ボイラにおいて、
前記低温加熱装置の出口に温度計および流量計を設置して、その温度計および流量計で計測した温度および流量が所定の値になるように、前記低温加熱装置への給水流量を調整する構成になっていることを特徴とする太陽熱ボイラ。 - 請求項1ないし4のいずれか1項に記載の太陽熱ボイラにおいて、
前記低温加熱装置の出口に温度計および流量計を設置して、その温度計および流量計で計測した温度および流量が所定の値になるように、前記低温加熱装置の集熱量を調整する構成になっていることを特徴とする太陽熱ボイラ。 - 請求項1ないし4のいずれか1項に記載の太陽熱ボイラにおいて、
前記低温加熱装置の出口に温度計および流量計を設置して、その温度計および流量計で計測した温度および流量の値に応じて、前記高温加熱装置の集熱量を調整する構成になっていることを特徴とする太陽熱ボイラ。 - 請求項1ないし3のいずれか1項に記載の太陽熱ボイラにおいて、
前記汽水分離装置の水位を計測する水位計と、
前記低温加熱装置への給水流量を調整する給水弁と、
前記低温加熱装置と前記汽水分離装置の間の水の循環量を調整する循環流量制御弁を設け、
前記汽水分離装置の水位が所定の値になるように、前記給水弁あるいは循環流量制御弁によって給水流量あるいは循環量を調整する構成になっていることを特徴とする太陽熱ボイラ。 - 請求項1または2に記載の太陽熱ボイラにおいて、
前記低温加熱装置は、
熱媒体が循環する熱媒体流路と、
その熱媒体流路の途中に設けられた熱媒体循環ポンプと、
前記熱媒体流路の途中に設けられ、太陽光を集光して生じた熱を前記熱媒体流路を循環する熱媒体に伝達する集光・集熱装置と、
前記熱媒体流路の一部が熱交換器として内側に設置された熱交換器付き低温加熱装置を備えて、
前記集光・集熱装置で集熱した熱を前記熱媒体を介して前記熱交換器付き低温加熱装置内の水に伝達する構成になっていることを特徴とする太陽熱ボイラ。 - 請求項1ないし9のいずれか1項に記載の太陽熱ボイラと、
その太陽熱ボイラで生成した蒸気により駆動される蒸気タービンと、
その蒸気タービンで駆動される発電機を備えたことを特徴とする太陽熱発電プラント。 - 燃料を燃焼もしくは発熱させて蒸気を発生させるボイラと、
そのボイラへ水を供給する給水ポンプと、
前記ボイラで発生した蒸気で駆動される蒸気タービンと、
その蒸気タービンで駆動される発電機と、
前記給水ポンプから供給される水を加熱する給水加熱器と、
前記蒸気タービンからの抽気蒸気を用いて、前記給水ポンプから供給される水の一部を太陽光の熱で加熱する低温加熱装置と、
その低温加熱装置で生成した水-蒸気二相流体を水と蒸気とに分離する汽水分離装置と、
その汽水分離装置で分離された蒸気を太陽光の熱で加熱する高温加熱装置と、
前記汽水分離装置で分離した水を低温加熱装置に供給する循環ポンプを
備えたことを特徴とする太陽熱発電プラント。 - 請求項11に記載の太陽熱プラントにおいて、
前記低温加熱装置と汽水分離装置と循環ポンプを地上面または地上面付近に設置し、前記高温加熱装置を前記低温加熱装置ならびに汽水分離装置よりも高所に設置したことを特徴とする太陽熱発電プラント。 - 請求項11または12に記載の太陽熱発電プラントにおいて、
前記低温加熱装置は、
桶状に延びた集光ミラーの内周曲面の上方に伝熱管を配置し、前記太陽光を集光ミラーで伝熱管に集光することにより、伝熱管内を流通する水を加熱して蒸気を生成するトラフ式の集光・集熱装置、または略平面状の集光ミラーを多数並べて、その集光ミラー群の上方に伝熱管を配置し、前記太陽光を前記集光ミラー群で伝熱管に集光することにより、伝熱管内を流通する水を加熱して蒸気を生成するフレネル式の集光・集熱装置からなり、
前記高温加熱装置は、
所定の高さを有するタワーの上に伝熱管パネルを設置し、多数の集光ミラーを配置して、太陽光を前記集光ミラー群で伝熱管パネルに集光することにより、伝熱管パネル内を流通する水を加熱して蒸気を生成するタワー式の集光・集熱装置からなることを特徴とする太陽熱発電プラント。 - 請求項11ないし13のいずれか1項に記載の太陽熱発電プラントにおいて、
前記低温加熱装置の出口流体温度を300℃以下に規制したことを特徴とする太陽熱発電プラント。 - 請求項11ないし13のいずれか1項に記載の太陽熱発電プラントにおいて、
前記低温加熱装置の出口に温度計および流量計を設置して、その温度計および流量計で計測した温度および流量が所定の値になるように、前記低温加熱装置への給水流量を調整する構成になっていることを特徴とする太陽熱発電プラント。 - 請求項11ないし13のいずれか1項に記載の太陽熱発電プラントにおいて、
前記低温加熱装置の出口に温度計および流量計を設置して、その温度計および流量計で計測した温度および流量が所定の値になるように、前記低温加熱装置の集熱量を調整する構成になっていることを特徴とする太陽熱発電プラント。 - 請求項11ないし13のいずれか1項に記載の太陽熱発電プラントにおいて、
前記低温加熱装置の出口に温度計および流量計を設置して、その温度計および流量計で計測した温度および流量の値に応じて、前記高温加熱装置の集熱量を調整する構成になっていることを特徴とする太陽熱発電プラント。 - 請求項11ないし13のいずれか1項に記載の太陽熱発電プラントにおいて、
前記汽水分離装置の水位を計測する水位計と、
前記低温加熱装置への給水流量を調整する給水弁と、
前記低温加熱装置と前記汽水分離装置の間の水の循環量を調整する循環流量制御弁を設け、
前記汽水分離装置の水位が所定の値になるように、前記給水弁あるいは循環流量制御弁によって給水流量あるいは循環量を調整する構成になっていることを特徴とする太陽熱発電プラント。 - 請求項11または12に記載の太陽熱発電プラントにおいて、
前記低温加熱装置は、
熱媒体が循環する熱媒体流路と、
その熱媒体流路の途中に設けられた熱媒体循環ポンプと、
前記熱媒体流路の途中に設けられ、太陽光を集光して生じた熱を前記熱媒体流路を循環する熱媒体に伝達する集光・集熱装置と、
前記熱媒体流路の一部が熱交換器として内側に設置された熱交換器付き低温加熱装置を備えて、
前記集光・集熱装置で集熱した熱を前記熱媒体を介して前記熱交換器付き低温加熱装置内の水に伝達する構成になっていることを特徴とする太陽熱発電プラント。 - 請求項11ないし13のいずれか1項に記載の太陽熱発電プラントにおいて、
前記蒸気タービンの出口側に抽気弁を設け、
前記高温加熱装置から供給される蒸気量に応じて前記抽気弁を操作して、前記蒸気タービンの抽気量を調整する構成になっていることを特徴とする太陽熱発電プラント。
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WO2015086883A1 (es) * | 2013-12-13 | 2015-06-18 | Abengoa Solar New Technologies, S.A. | Planta de generación directa de vapor y procedimiento de operación de la planta |
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EP2728276A4 (en) | 2015-03-04 |
AU2012276966B2 (en) | 2015-08-06 |
JPWO2013002054A1 (ja) | 2015-02-23 |
AU2012276966A1 (en) | 2014-02-20 |
JP5602306B2 (ja) | 2014-10-08 |
EP2728276B1 (en) | 2017-10-25 |
ZA201400347B (en) | 2014-10-29 |
US9605662B2 (en) | 2017-03-28 |
ES2646761T3 (es) | 2017-12-15 |
CN103649648A (zh) | 2014-03-19 |
US20140138952A1 (en) | 2014-05-22 |
EP2728276A1 (en) | 2014-05-07 |
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