WO2013021488A1 - 再生エネルギー型発電装置 - Google Patents
再生エネルギー型発電装置 Download PDFInfo
- Publication number
- WO2013021488A1 WO2013021488A1 PCT/JP2011/068284 JP2011068284W WO2013021488A1 WO 2013021488 A1 WO2013021488 A1 WO 2013021488A1 JP 2011068284 W JP2011068284 W JP 2011068284W WO 2013021488 A1 WO2013021488 A1 WO 2013021488A1
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- WIPO (PCT)
- Prior art keywords
- cooling medium
- oil
- line
- tower
- hydraulic
- Prior art date
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Classifications
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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
- F03D—WIND MOTORS
- F03D9/00—Adaptations of wind motors for special use; Combinations of wind motors with apparatus driven thereby; Wind motors specially adapted for installation in particular locations
- F03D9/20—Wind motors characterised by the driven apparatus
- F03D9/28—Wind motors characterised by the driven apparatus the apparatus being a pump or a compressor
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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
- F03D—WIND MOTORS
- F03D80/00—Details, components or accessories not provided for in groups F03D1/00 - F03D17/00
- F03D80/60—Cooling or heating of wind motors
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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
- F03D—WIND MOTORS
- F03D13/00—Assembly, mounting or commissioning of wind motors; Arrangements specially adapted for transporting wind motor components
- F03D13/20—Arrangements for mounting or supporting wind motors; Masts or towers for wind motors
- F03D13/25—Arrangements for mounting or supporting wind motors; Masts or towers for wind motors specially adapted for offshore installation
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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
- F03D—WIND MOTORS
- F03D15/00—Transmission of mechanical power
- F03D15/20—Gearless transmission, i.e. direct-drive
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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
- F03D—WIND MOTORS
- F03D80/00—Details, components or accessories not provided for in groups F03D1/00 - F03D17/00
- F03D80/70—Bearing or lubricating arrangements
-
- 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
- F03D—WIND MOTORS
- F03D9/00—Adaptations of wind motors for special use; Combinations of wind motors with apparatus driven thereby; Wind motors specially adapted for installation in particular locations
- F03D9/20—Wind motors characterised by the driven apparatus
- F03D9/25—Wind motors characterised by the driven apparatus the apparatus being an electrical generator
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F05—INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
- F05B—INDEXING SCHEME RELATING TO WIND, SPRING, WEIGHT, INERTIA OR LIKE MOTORS, TO MACHINES OR ENGINES FOR LIQUIDS COVERED BY SUBCLASSES F03B, F03D AND F03G
- F05B2260/00—Function
- F05B2260/20—Heat transfer, e.g. cooling
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F05—INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
- F05B—INDEXING SCHEME RELATING TO WIND, SPRING, WEIGHT, INERTIA OR LIKE MOTORS, TO MACHINES OR ENGINES FOR LIQUIDS COVERED BY SUBCLASSES F03B, F03D AND F03G
- F05B2260/00—Function
- F05B2260/40—Transmission of power
- F05B2260/406—Transmission of power through hydraulic systems
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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
- Y02E10/70—Wind energy
- Y02E10/72—Wind turbines with rotation axis in wind direction
-
- 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
- Y02E10/70—Wind energy
- Y02E10/727—Offshore wind turbines
-
- 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
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P80/00—Climate change mitigation technologies for sector-wide applications
- Y02P80/10—Efficient use of energy, e.g. using compressed air or pressurized fluid as energy carrier
Definitions
- the present invention relates to a regenerative energy power generator that transmits rotational energy of a rotor obtained from a renewable energy source to a generator via a hydraulic transmission, and more particularly to a regenerative energy power generator having a cooling function of a hydraulic transmission.
- Patent Document 1 describes a wind power generator provided with a cooling system for cooling a converter, a transformer, and a control device.
- This cooling system has a plurality of heat exchangers attached to the outer peripheral surface of the tower, in which heat is exchanged between the cooling medium after cooling the converter, the transformer, and the control device with the atmosphere. It has become.
- Patent Document 2 discloses a cooling device for a wind power generator for cooling a plurality of devices (converters, transformers, bearing boxes, generators, etc.). This cooling device cools the cooling water after cooling a plurality of devices by a heat exchanger attached to the outer wall of the tower or nacelle.
- renewable energy power generators use renewable energy such as wind, tidal currents, rivers, and ocean currents, so they are often installed in locations where the temperature of the surrounding environment, such as outside air temperature or water temperature, varies greatly.
- the hydraulic oil temperature of the hydraulic transmission also changes.
- the cooling device as described above the cooling function depends on the temperature change of the surrounding environment because the cold air such as the outside air or seawater around the device is often used.
- the present invention has been made in view of the above circumstances, and an object of the present invention is to provide a regenerative energy type power generator capable of keeping the oil temperature of a hydraulic transmission at an appropriate temperature.
- a regenerative energy type power generating device is a regenerative energy type power generating device that generates electric power from regenerative energy, a rotary shaft driven by the regenerative energy, a hydraulic pump driven by the rotary shaft, and the hydraulic pressure
- a hydraulic motor driven by hydraulic oil supplied from a pump; a generator coupled to the motor; and the hydraulic pump and the hydraulic motor connected to each other, and the hydraulic oil is passed between the hydraulic pump and the hydraulic motor.
- a circulating oil line ; an oil cooler connected to the oil line for cooling the hydraulic oil by exchanging heat with a cooling medium; a cooling medium line for supplying the cooling medium to the oil cooler; the oil line; Branching from at least one of the cooling medium lines to join the line, The bypass line for bypassing the oil cooler, and at least one of the hydraulic oil and the cooling medium provided in the at least one line located between the branch point and the junction of the bypass line and flowing into the oil cooler And a flow rate adjusting valve that adjusts the flow rate.
- a bypass line is provided so that at least one of the hydraulic oil and the cooling medium bypasses the oil cooler, and the amount of the fluid flowing into the bypass line is adjusted by a flow rate adjustment valve. Therefore, the amount of heat exchanged between the working oil and the cooling medium can be adjusted by the oil cooler. As a result, the temperature of the hydraulic oil cooled by the oil cooler can be freely adjusted, and the hydraulic oil can be maintained at an appropriate temperature even when the ambient temperature, the heat generation amount of the generator, or the like changes. At the same time, it is possible to prevent overcooling by limiting the amount of bypass in advance. In addition, since the flow rate of the fluid flowing into the oil cooler becomes 0 in this case, the flow rate adjusting valve can be completely closed, so that the oil cooler is not cooled.
- the regenerative energy type power generation device further includes a heat exchanger that is provided in the cooling medium line and cools the cooling medium with an atmospheric fluid existing around the regenerative energy type power generation device, and the cooling in the heat exchanger
- the amount of heat exchange between the medium and the atmospheric fluid is preferably adjusted by at least one of the flow rate of the cooling medium and the flow rate of the atmospheric fluid.
- the cooling medium line is provided with a heat exchanger that cools the cooling medium with the atmospheric fluid existing around the regenerative energy generator, and at least one of the flow rate of the cooling medium and the atmospheric fluid in the heat exchanger is provided. Since the amount of heat held by the cooling medium can be freely adjusted. This makes it possible to adjust the amount of heat retained in the cooling medium, that is, the cooling capacity of the cooling medium itself, in addition to adjusting the amount of cooling of the hydraulic oil in the oil cooler using the bypass line and the flow rate adjustment valve. Function can be greatly improved. In the regenerative energy type power generation device, since the heat loss of the oil cooler varies particularly depending on the load of the generator, by providing the above configuration, the hydraulic oil can be cooled according to the load of the generator.
- the regenerative energy type power generator further includes a generator cooler connected to the cooling medium line and cooling the generator, and the cooling medium is used for cooling the oil cooler and the generator cooler. Also good.
- the generator cooler that is connected to the cooling medium line and cools the generator is provided, and the generator cooler is also cooled by the cooling medium used in the oil cooler.
- the heat generation source can be cooled in an integrated manner, and the cooling efficiency can be improved.
- the regenerative energy power generator includes a hydraulic oil extraction line that extracts a part of the hydraulic oil from the oil line and supplies the hydraulic oil as a lubricating oil to at least one sliding portion of the hydraulic pump and the hydraulic motor; and the hydraulic oil A lubricating oil cooling means provided on the drawing line for cooling the hydraulic oil, wherein the lubricating oil supplied to the sliding portion by the lubricating oil cooling means is lower in temperature than the hydraulic oil at the inlet of the hydraulic pump. Preferably it is maintained. In this way, by cooling a part of the hydraulic oil drawn from the oil line and using it as the lubricating oil, it is not necessary to newly provide a lubricating oil supply mechanism such as a lubricating oil storage tank, and the apparatus can be simplified.
- the lubricating oil supplied to the sliding part requires a higher viscosity than the hydraulic transmission hydraulic oil, but since it is cooled by the lubricating oil cooling means to increase the viscosity, it functions as a lubricating oil. Can be fulfilled sufficiently.
- the regenerative energy type power generator adjusts the opening of the flow rate adjusting valve so that the operating oil temperature at a predetermined position of the oil line becomes a set temperature, and the operating oil flow rate and cooling medium flowing into the oil cooler It is preferable to further include a controller that adjusts at least one of the flow rates. Accordingly, the temperature of the hydraulic oil flowing on the oil line can be accurately maintained at the set temperature, and the hydraulic transmission can be smoothly operated.
- the set temperature may be set based on the viscosity of the hydraulic oil.
- the upper limit value of the set temperature is a temperature corresponding to the lower limit value of the viscosity that is set so as to suppress the deterioration rate of the hydraulic oil, the leakage amount, etc.
- the lower limit value of the set temperature is the viscosity of the hydraulic oil in the hydraulic transmission.
- the temperature is set to a viscosity upper limit set so that energy loss due to resistance can be suppressed.
- the set temperature is set to a temperature corresponding to the position of the oil line.
- the regenerative energy type power generator further includes a tower / nacelle cooler that is provided inside a tower or nacelle that houses at least the hydraulic pump and the hydraulic motor, and cools the air in the tower or nacelle,
- the cooling medium may be supplied to the nacelle cooler.
- the tower / nacelle cooler for cooling the air in the tower or nacelle is provided, and the tower / nacelle cooler is also cooled by the cooling medium used in the oil cooler.
- a plurality of heat generation sources can be cooled in an integrated manner, and cooling efficiency can be improved.
- the cooling medium line includes a generator cooler that cools the generator, and a tower / nacelle cooler that cools at least the tower or nacelle that houses the hydraulic pump and the hydraulic motor. At least one of them is connected in series or in parallel, and the cooling medium is water to which an antifreeze is added.
- the cooling medium in addition to the oil cooler, at least one of the generator cooler and the tower / nacelle cooler Is preferably cooled. In this way, at least one of the generator cooler and the tower / nacelle cooler is connected to the cooling medium line, and at least one of the generator cooler and the tower / nacelle cooler is cooled by the cooling medium used in the oil cooler.
- the plurality of heat generation sources included in the renewable energy power generation apparatus can be cooled in an integrated manner, and the cooling efficiency can be improved. Further, by using water to which an antifreeze is added as a cooling medium, it is possible to prevent a failure of the cooling system due to freezing of the cooling medium even when the outside air temperature becomes below freezing point.
- the cooling medium may be air
- a cooling unit line may be provided with a blowing unit, and the cooling medium may be guided to the oil cooler by the blowing unit.
- the regenerative energy type power generation device is a wind power generation device having a tower and a nacelle supported by the tower and accommodating at least the hydraulic pump, wherein a transformer is provided in the tower or on the outer periphery of the tower. And a cooling medium connected in series or parallel to the cooling medium line and cooled by the heat exchanger is supplied to the transformer room through the cooling medium line, and And a transformer cooler that cools the air in the transformer room by cold heat, and the cooling medium is preferably water to which an antifreeze is added.
- the cooling medium used in the oil cooler is also used to cool the transformer room provided in the tower or the outer periphery of the tower, so the cooling of the plurality of heat generation sources of the regenerative energy generator is integrated.
- the cooling efficiency can be improved. Further, by using water to which an antifreeze is added as a cooling medium, it is possible to prevent a failure of the cooling system due to freezing of the cooling medium even when the outside air temperature becomes below freezing point.
- the regenerative energy type power generation device is a wind power generation device having a tower and a nacelle supported by the tower and accommodating at least the hydraulic pump, wherein the atmospheric fluid is preferably air.
- the atmospheric fluid is preferably air.
- a wind power generator is often installed in a place where the wind speed is obtained above a certain level. Therefore, in the wind power generator, it is possible to easily take in the atmospheric fluid into the heat exchanger by using air as the atmospheric fluid for cooling the cooling medium.
- the heat exchanger may be arranged in the upper part of the tower or in the nacelle. In this way, by arranging the heat exchanger in the upper part of the tower or the nacelle at a high place where the wind speed is high, it is possible to further promote the intake of the atmospheric fluid into the heat exchanger.
- the regenerative energy power generator is an offshore wind power generator installed on the ocean having a tower and a nacelle supported by the tower and containing at least the hydraulic pump, wherein the atmospheric fluid is Sea water is preferred.
- Sea water is sufficiently present in the surrounding area, and therefore seawater can be sufficiently secured as an atmospheric fluid for cooling the cooling medium.
- the heat exchanger and a transformer room in which a transformer is disposed may be provided in the lower part of the tower, and the cooling medium line may be extended to the lower part of the tower.
- part and an atmospheric fluid source becomes near, and the piping structure of a refrigerant
- At least one of the inside of the tower and the inside of the nacelle is preferably sealed with respect to the outside air.
- the corrosive substance contained in the outside air, particularly in the offshore wind power generator, the corrosion of the internal equipment due to the salt. Can be prevented.
- the regenerative energy type power generation device has an air inlet and an air outlet that cool the air inside the tower or the nacelle even by air cooling, and the air inlet and the air outlet are mixed with outside air. It is preferable that a filter for shielding the corrosive substance is provided.
- a filter for shielding the corrosive substance is provided.
- At least one fan is provided inside the tower or the nacelle, and openable and closable shutters are provided at the air inlet and the air outlet, respectively.
- the shutter is opened to enter a ventilation mode for ventilating the air inside the tower or the nacelle, and when the temperature inside the tower or the nacelle is equal to or lower than the predetermined temperature, It is preferable to set a circulation mode in which the shutter is closed and the air in the nacelle is circulated in the nacelle.
- the shutter is opened to enter the ventilation mode, and the air inside the tower or the nacelle is exchanged by the fan through the air inlet and the air outlet.
- the temperature inside the tower or the nacelle can be lowered.
- the shutter is closed to enter the circulation mode, and the air inside the tower or nacelle is internally circulated by a fan, so that a local high-temperature part (around the generator) Etc.) can be eliminated.
- the fan can be used in two applications including a ventilation mode and a circulation mode.
- a bypass line is provided so that at least one fluid of the hydraulic oil and the cooling medium bypasses the oil cooler, and the inflow amount of the fluid into the bypass line is adjusted by the flow rate adjustment valve.
- the amount of heat exchanged between the hydraulic oil and the cooling medium can be adjusted by the oil cooler.
- the temperature of the hydraulic oil cooled by the oil cooler can be freely adjusted, and the hydraulic oil can be kept at an appropriate temperature even when the temperature of the surrounding environment, the amount of heat generated by the generator, etc. change. Become.
- FIG. 1 It is a figure showing the whole wind power generator composition concerning a 1st embodiment of the present invention. It is a figure which shows the structural example of an oil line and a cooling medium line. It is a figure which shows the air-cooling mechanism in a nacelle, (a) is a figure which shows circulation mode, (b) is a figure which shows ventilation mode. It is a whole block diagram of the wind power generator provided with the cooling mechanism of the transformer chamber. It is a whole block diagram of the wind power generator provided with the other cooling mechanism of a transformer chamber. It is a whole block diagram of the wind power generator provided with the other cooling mechanism of a transformer chamber. It is a figure which shows the whole structure of the wind power generator which concerns on 2nd Embodiment of this invention. It is a figure which shows the whole structure of the wind power generator which concerns on the modification of 2nd Embodiment of this invention.
- FIG. 1 is a diagram illustrating an overall configuration of the wind turbine generator according to the first embodiment
- FIG. 2 is a diagram illustrating a configuration example of an oil line and a cooling medium line.
- the wind power generator 1 mainly includes a tower 2, a nacelle 4 supported by the tower 2, and a rotor 6 that rotates by wind energy.
- FIG. 1 illustrates an offshore wind power generator installed on the sea surface SL as the wind power generator 1, the wind power generator 1 may be installed on land.
- the rotor 6 includes at least one (for example, three) blades 6A and a hub 6B that supports the blades 6A.
- the hub 6B is connected to a main shaft 5 housed in the nacelle 4. As a result, when the blade 6A receives wind and the rotor 6 rotates, the main shaft 5 connected to the hub 6B also rotates.
- a hydraulic transmission 10 and a generator 20 are housed in the nacelle 4.
- the hydraulic transmission 10 includes a hydraulic pump 12 connected to the main shaft 5, a hydraulic motor 14 connected to the generator 20, and an oil line 18 provided between the hydraulic pump 12 and the hydraulic motor 14.
- the oil line 18 includes a high-pressure oil line 16 that connects the discharge side of the hydraulic pump 12 and the suction side of the hydraulic motor 14, and a low-pressure oil line 17 that connects the suction side of the hydraulic pump 12 and the discharge side of the hydraulic motor 14. It is comprised by.
- the hydraulic pump 12 is driven by the main shaft 5 to generate high-pressure hydraulic oil.
- the high-pressure hydraulic oil is supplied to the hydraulic motor 14 via the high-pressure oil line 16, and the hydraulic motor 14 is driven by the high-pressure hydraulic oil.
- the generator 20 connected to the hydraulic motor 14 is driven, and electric power is generated in the generator 20.
- the hydraulic oil discharged from the hydraulic motor 14 is supplied to the hydraulic pump 12 through the low-pressure oil line 17, and is boosted again by the hydraulic pump 12 and sent to the hydraulic motor 14.
- An oil cooler 36 for cooling the hydraulic oil is connected to the low-pressure oil line 17 by exchanging heat between the cooling medium and the hydraulic oil.
- the cooling medium is introduced into the oil cooler 36 via the cooling medium line 30.
- the cooling medium line 30 is a flow path for circulating a cooling medium for cooling the heat generation source (hydraulic transmission in FIG. 2) of the wind power generator 1, and is configured as a closed loop refrigerant circuit.
- a refrigerant made of any liquid or gas can be used.
- air is guided to the oil cooler 36 by the fan 39 provided in the cooling medium line 30. Thereby, the structure of the cooling medium line 30 can be simplified, and maintenance can be easily performed.
- water to which an antifreeze is added as a cooling medium.
- the required circulation amount of the cooling medium can be reduced by using water having a larger specific heat than a general gas (such as air) as the cooling medium.
- the addition of the antifreeze liquid can prevent a failure of the cooling system due to freezing of the cooling medium (water) even when the outside air temperature becomes below freezing point.
- a heat exchanger 35 including a heat transfer tube group is provided on the downstream side of the oil cooler 36 of the cooling medium line 30.
- the heat exchanger 35 is configured to cool the cooling medium flowing in the heat transfer tube by the atmospheric fluid flowing around the heat transfer tube.
- the atmospheric fluid is a fluid existing around the wind power generator 1 and is, for example, air, seawater, or the like.
- the cooling medium after passing through the oil cooler 36 flows in the heat transfer tube, and this cooling medium is cooled by the atmospheric fluid flowing on the outer periphery of the heat transfer tube. At this time, it is preferable to use air as the atmospheric fluid.
- the wind power generator 1 is often installed in a place where the wind speed is obtained above a certain level.
- seawater is preferably used as the atmospheric fluid.
- seawater is sufficiently present in the surrounding area, and therefore seawater can be sufficiently secured as an atmospheric fluid for cooling the cooling medium.
- the heat exchanger 35 is disposed in the upper part of the tower 2 or the nacelle 4. As described above, by arranging the heat exchanger 35 in the upper part of the tower 2 or the nacelle 4 at a high wind speed, it is possible to further promote the intake of the atmospheric fluid into the heat exchanger 35.
- the heat exchange amount between the cooling medium and the atmospheric fluid in the heat exchanger 35 may be adjusted by at least one of the flow rate of the cooling medium and the flow rate of the atmospheric fluid.
- the controller 50 sets the operating oil temperature or the outside air temperature on the oil line 18 to the controller 50. Based on this temperature, the rotational speed of the fan is controlled based on this temperature, and the flow rate of the outside air introduced into the heat exchanger 35 is adjusted.
- the amount of heat retained by the cooling medium can be freely adjusted.
- the amount of heat retained by the cooling medium that is, the cooling capacity of the cooling medium itself can be adjusted, so that the hydraulic oil cooling function can be greatly improved.
- the operation oil according to the load of the generator 20 can be cooled by providing the above configuration.
- a plurality of heat exchangers 35 may be provided according to the amount of heat generated from the heat generation source of the assumed wind power generator 1. In this case, the plurality of heat exchangers 35 may be connected to the cooling medium line 30 in parallel or in series.
- the oil line 18 is connected to a bypass line 19 that branches from the low-pressure oil line 17 at a branch point A and joins the low-pressure oil line 17 at a junction B.
- the hydraulic oil branched at the branch point A flows through the bypass line 19, and this hydraulic oil is joined again to the low-pressure oil line 17 at the junction B.
- the low-pressure oil line 17 a located between the branch point A and the junction B of the bypass line 19 is provided with a flow rate adjustment valve 51 that adjusts the flow rate of the hydraulic oil flowing into the oil cooler 36.
- the amount of heat exchanged between the hydraulic oil and the cooling medium by the oil cooler 36 can be adjusted by adjusting the flow rate of the hydraulic oil flowing into the bypass line 19 by the flow rate adjusting valve 51.
- the flow rate adjusting valve 51 may be provided at the branch point A. In this case, a three-way valve may be used.
- the opening of the flow rate adjusting valve 51 is controlled by the controller 50.
- the operating oil temperature at a predetermined position of the oil line 18 is detected by the temperature sensor T1 or T2, and the opening degree of the flow rate adjustment valve 51 is controlled by the controller 50 so that the detected temperature becomes a preset temperature.
- the set temperature may be set based on the viscosity of the hydraulic oil.
- the upper limit value of the set temperature is a temperature corresponding to the lower limit value of the viscosity that is set so as to suppress the deterioration rate of the hydraulic oil, the leakage amount, etc.
- the lower limit value of the set temperature is the viscosity of the hydraulic oil in the hydraulic transmission.
- the temperature is set to a viscosity upper limit set so that energy loss due to resistance can be suppressed.
- the set temperature is set to a temperature corresponding to the position of the oil line 18.
- the plurality of set temperatures respectively correspond to positions on the oil line. That is, there are set temperatures corresponding to the temperature sensors T1 and T2 provided at different positions on the oil line 18, respectively.
- the positions of the temperature sensors T1 and T2 on the oil line 18 are preferably on the low-pressure oil line 17, but may be on the high-pressure oil line 16.
- the flow rate adjusting valve 51 can be completely closed. In this case, the flow rate of the working oil flowing into the oil cooler 36 becomes 0, so that the oil cooler 36 is not cooled.
- the refrigerant line 30 that supplies the cooling medium to the oil cooler 36 extends to the vicinity of a heat generation source different from the hydraulic transmission 10, and a plurality of heat generation sources are generated by the cooling medium flowing through the refrigerant line 30. You may make it cool. Examples of other heat generation sources include a generator cooler 37, a nacelle cooler 38, a tower cooler, and the like. In this case, the heat exchanger 35 is shared, and the refrigerant line 30 is shown as a series pipe for each heat generation source. However, depending on the required temperature and flow rate of each heat generation source, a parallel pipe may be used. May be preferred.
- the generator cooler 37 is configured as a cooling jacket provided around the generator 20, for example.
- the generator 20 is cooled by heat exchange with the cooling medium supplied from the cooling medium line 30. Thereby, the generator 20 can be cooled effectively.
- the nacelle cooler 38 is configured as a heat exchanger with a fan including a fan and a heat transfer tube group.
- the air in the nacelle 4 sucked (or pushed in) by the fan is cooled by heat exchange with the cooling medium supplied from the cooling medium line 30 to the heat transfer tube group.
- the tower cooler has substantially the same configuration as the nacelle cooler 38.
- the cooling means of other heat generation sources such as the generator cooler 37 and the nacelle cooler 38 are connected to the cooling medium line 30 so that the other heat generation sources are also cooled by the cooling medium used in the oil cooler 36. Therefore, the cooling of the plurality of heat generation sources of the wind power generator 1 can be performed in an integrated manner, and the cooling efficiency can be improved.
- the generator cooler 37 and the nacelle cooler 38 are illustrated in FIG. 1, the heat generation source is not limited to these, and the above cooling mechanism can be applied to other heat generation sources. It is.
- the wind turbine generator 1 extracts a part of the hydraulic oil from the low-pressure oil line 17 and supplies the hydraulic oil to the sliding portion of at least one of the hydraulic pump 12 and the hydraulic motor 14 as a lubricating oil.
- a drawing line 40 may be provided on the hydraulic oil extraction line 40.
- a lubricating oil cooler 41 for further cooling the extracted hydraulic oil is provided on the hydraulic oil extraction line 40.
- the sliding portion is a portion between a rotating member such as a main shaft 5 connected to the rotor or a rotating shaft connected to the generator 20 and a bearing that slides and supports the rotating member.
- the apparatus can be simplified. Further, the lubricating oil supplied to the sliding portion is required to be higher in viscosity than the hydraulic oil of the hydraulic transmission 10. However, since the viscosity is increased by cooling with the lubricating oil cooler 41, The function of can be sufficiently fulfilled.
- At least one of the inside of the tower 2 and the inside of the nacelle 4 is in a sealed state with respect to the outside air.
- the corrosive substance contained in the outside air, particularly in the offshore wind power generation apparatus the internal equipment caused by salt Corrosion can be prevented.
- an air inlet 44 and an air outlet 45 may be provided on the outer wall of the nacelle 4.
- the air inlet 44 and the air outlet 45 may be configured to be openable and closable. When they are open, air (outside air) passes through the nacelle 4 and ventilation is performed. Thereby, the air in the nacelle heated by the heat generation source accommodated in the nacelle 4 can be air-cooled.
- the air suction port 44 and the air discharge port 45 are respectively provided with filters 44a and 45a that shield corrosive substances mixed in outside air.
- FIG. 3 is a figure which shows the air-cooling mechanism in a nacelle, (a) is a figure which shows circulation mode, (b) is a figure which shows ventilation mode.
- the controller 60 controls the opening and closing of the shutters 46 and 47.
- the controller 60 receives the temperature in the nacelle 4 detected by the temperature sensor T3, and when this temperature is higher than a predetermined temperature, the shutters 46 and 47 are opened as shown in FIG.
- the ventilation mode for ventilating the air is set, and as shown in FIG. 3A, the shutters 46 and 47 are closed and the circulation mode in which the air in the nacelle 4 is circulated internally is set. .
- the shutters 46 and 47 are opened to enter the ventilation mode, and the air inside the tower 2 or the nacelle 4 is changed by the fan 48 into the air inlet 44. And the temperature inside the tower 2 or the nacelle 4 can be lowered by switching through the air discharge port 45.
- the shutters 46 and 47 are closed to enter the circulation mode, and the air inside the tower 2 or the nacelle 4 is circulated by the fan 48 to locally High temperature parts (such as around the generator) can be eliminated.
- the fan 48 can be used in two applications including a ventilation mode and a circulation mode.
- the oil line 18 is provided with the bypass line 19 so that at least one of the hydraulic oil and the cooling medium bypasses the oil cooler 36, and the bypass line 19 is provided by the flow rate adjustment valve 51.
- the amount of heat exchanged between the working oil and the cooling medium can be adjusted by the oil cooler 36.
- the temperature of the hydraulic oil cooled by the oil cooler 36 can be freely adjusted, and the hydraulic oil can be kept at an appropriate temperature even when the temperature of the surrounding environment, the amount of heat generated by the generator, or the like changes.
- bypass line 19 is provided in the oil line 18
- the bypass line may be provided on the cooling medium line 30 side.
- a bypass line 31 that branches from the cooling medium line 30 at the branch point C and joins the cooling medium line 30 at the junction D is connected to the cooling medium line 30.
- a cooling medium branched at the branch point C flows through the bypass line 31, and this cooling medium is joined again to the cooling medium line 30 at the junction point D.
- a flow rate adjusting valve 56 that adjusts the flow rate of the hydraulic oil flowing into the oil cooler 36 is provided in the cooling medium line 30 a located between the branch point C and the junction point D of the bypass line 31.
- the flow rate adjustment valve 56 may be controlled in opening degree by the controller 55.
- the hydraulic oil temperature at a predetermined position of the cooling medium line 30 is detected by the temperature sensor T1 or T2, and the controller 55 opens the flow rate adjustment valve 56 so that the detected temperature becomes a preset temperature.
- the flow rate of the cooling medium flowing into the oil cooler 36 is adjusted by adjusting the degree. Further, the flow rate adjusting valve 56 can be completely closed. In this case, the flow rate of the cooling medium flowing into the oil cooler 36 becomes 0, so that the oil cooler 36 is not cooled. In this way, by adjusting the flow rate of the coolant flowing through the oil cooler 36 by the flow rate adjusting valve 56, the hydraulic oil can be maintained at an appropriate temperature. Furthermore, if the flow rate through the oil cooler 36 is limited, cooling beyond a certain level becomes impossible, and overcooling can be physically prevented.
- the wind turbine generator 1 may have the following configuration. As shown in FIG. 5, the wind turbine generator 1 includes a transformer room cooler 72 that cools the transformer room 72.
- the transformer room 72 is a space that houses a transformer 73 that transforms the electric power generated by the generator 20.
- the temperature in the transformer chamber 72 is increased by heat dissipation from the transformer 73. Therefore, a transformer room cooler 72 is provided in the transformer room 72.
- the transformer room cooler 72 is configured to exchange heat between the cooling medium flowing through the second cooling medium line 70 and the air in the transformer room 72.
- the transformer room cooler 72 and the heat exchanger 71 are connected to the second cooling medium line 71.
- the heat exchanger 71 is connected to a seawater supply line 78 for supplying seawater pumped by a pump 77, and is configured to cool the cooling medium by exchanging heat between the seawater and the cooling medium. Furthermore, a tower cooler 75 that cools the air in the tower 2 may be connected to the second cooling medium line 70.
- a fan 82 that supplies air into the tower 2 and an air discharge port 83 that discharges air from the tower 2 can be provided to ventilate the air in the tower 2.
- a heat exchanger 81 that exchanges heat between the air in the tower 2 and the air in the transformer chamber 72 may be provided.
- the cooling medium line 18 that mainly cools the hydraulic transmission and the second cooling medium line 70 or the heat exchanger 81 that mainly cools the inside of the transformer chamber 72 are provided independently, respectively. It is possible to select an optimal cooling means. In this way, it is possible to simplify the piping by providing them independently and setting the piping of the cooling medium to an optimum length for each.
- the wind turbine generator of this embodiment has the same configuration as the wind turbine generator 1 of the first embodiment described above, except for the cooling mechanism in the transformer chamber 72. Therefore, here, the same reference numerals are given to members common to the first embodiment, and the description thereof is omitted, and the description will focus on parts different from the first embodiment.
- the wind turbine generator 1 includes a transformer room cooler 91 that cools the transformer room 72.
- the transformer room cooler 91 is connected to a cooling medium line 30 that supplies a cooling medium to the oil cooler 36.
- a cooling medium line 30 on the oil cooler 36 side and a cooling medium line 30 ′ on the transformer chamber 72 side are connected in a heat exchanger 35 that exchanges heat between the atmospheric fluid and the cooling medium.
- the cooling medium line 30 and the cooling medium line 30 ′ are connected in series is shown here, for example, these two lines are connected in parallel via the cooling medium storage tank. Also good.
- the transformer room cooler 91 has a cooling pipe group through which a cooling medium flows and a fan that forms an air flow so that air in the transformer room 72 passes around the cooling pipe group. With this configuration, the air flow cooled by the cooling tube group circulates in the transformer chamber 72, and the interior of the transformer chamber 72 heated by heat radiation from the transformer 73 can be cooled.
- the transformer room 72 may be installed in the outer periphery of the tower 2.
- At least one of the nacelle side heat exchanger 35 and the tower side heat exchanger 95 connected to the cooling medium lines 30 and 30 ′ may be provided.
- the nacelle-side heat exchanger 35 is disposed around the nacelle 4 and cools the cooling medium with outside air.
- the tower-side heat exchanger 95 is disposed at the bottom of the tower 2 and cools the cooling medium with seawater.
- the tower-side heat exchanger 95 is connected to a seawater supply line 97 for supplying seawater pumped by a pump 96, and is configured to cool the cooling medium by exchanging heat between the seawater and the cooling medium.
- a tower cooler 99 that cools the air in the tower 2 may be connected to the cooling medium line 30 ′.
- the cooling medium used in the oil cooler 36 is used to cool the transformer chamber 72 provided in the tower 2 or the outer periphery of the tower 2. Can be integrated and the cooling efficiency can be improved. At this time, it is preferable to use water to which an antifreeze is added as a cooling medium, so that it is possible to prevent failure of the cooling system due to freezing of the cooling medium even when the outside air temperature is below freezing point.
- the heat exchanger 35 or 95 is common, and the refrigerant line 30 or 30 ′ is shown as a series pipe for each heat generation source. However, depending on the required temperature and flow rate of each heat generation source, It may be preferable to use parallel piping.
- the present invention may be applied to a tidal current power generator.
- the “tidal current power generation device” here is a device that is installed in the sea, river, lake or the like and generates power using the energy of the tidal current, except that the rotor 2 rotates by receiving a tidal current instead of wind.
- the basic configuration is the same as that of the wind power generator 1 described above. The same components as those of the wind power generator 1 will be described using the same reference numerals.
- the tidal power generator includes a rotor 2 that rotates in response to a tidal current, a hydraulic transmission 10 that accelerates the rotation of the rotor 2, and power.
- the generator 20 to generate, the nacelle 4 which accommodates the hydraulic pump 12 of the hydraulic transmission 10 at least, and the tower 2 which supports the nacelle 4 are provided.
- the tidal current power generation device includes an oil line 18 that circulates the hydraulic oil between the hydraulic pump and the hydraulic motor of the hydraulic transmission 10, an oil cooler 36 that is connected to the oil line 18 and cools the hydraulic oil, and an oil cooler 36.
- a cooling medium line 30 for supplying a cooling medium to the oil line 18 and a bypass line provided in the oil line 18 or the cooling medium line 30.
- the flow rate adjusting valve appropriately adjusts the flow rate of at least one of the hydraulic oil and the cooling medium flowing into the oil cooler 36. Thereby, also in a tidal current power generation device, it becomes possible to maintain the temperature of the hydraulic fluid of the hydraulic transmission 10 appropriately.
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Abstract
Description
このように、冷却媒体ラインに接続され、発電機を冷却する発電機クーラを設け、オイルクーラで用いられる冷却媒体によって発電機クーラも冷却するようにしたので、再生エネルギー型発電装置が有する複数の熱発生源の冷却を統合的に行うことができ、冷却の効率化が図れる。
このように、オイルラインから引き抜いた作動油の一部を冷却し、潤滑油として用いることにより、潤滑油貯留タンク等の潤滑油供給機構を新たに設ける必要がなくなり、装置の簡素化が図れる。また、摺動部位に供給される潤滑油は、油圧トランスミッションの作動油より高粘度の油が必要とされるが、潤滑油冷却手段で冷却して粘度を上げているため、潤滑油としての機能を十分に果たすことができる。
これにより、オイルライン上を流れる作動油温度を設定温度に精度よく維持することができ、油圧トランスミッションを円滑に運転可能となる。なお、設定温度は、作動油の粘度に基づいて設定してもよい。例えば、設定温度の上限値は、作動油の劣化速度や漏れ量等が抑えられるように設定された粘度下限値に対応した温度とし、設定温度の下限値は、油圧トランスミッション内における作動油の粘性抵抗によるエネルギーロスが抑えられるように設定された粘度上限値に対応した温度とする。なお、油圧トランスミッションにおいては、オイルライン上の位置によって作動油の適正温度が異なるため、設定温度はオイルラインの位置に対応した温度とする。また、設定温度は少なくとも一つ以上有するものとし、設定温度が複数存在する場合は、複数の設定温度がオイルライン上の位置にそれぞれ対応している。
このように、タワー又はナセル内の空気を冷却するタワー/ナセル冷却器を設け、オイルクーラで用いられる冷却媒体によって、タワー/ナセル冷却器も冷却するようにしたので、再生エネルギー型発電装置が有する複数の熱発生源の冷却を統合的に行うことができ、冷却の効率化が図れる。
このように、冷却媒体ラインに、発電機クーラ並びにタワー/ナセル冷却器の少なくとも一方を接続し、オイルクーラで用いられる冷却媒体によって、発電機クーラ並びにタワー/ナセル冷却器の少なくとも一方も冷却するようにしたので、再生エネルギー型発電装置が有する複数の熱発生源の冷却を統合的に行うことができ、冷却の効率化が図れる。また、冷却媒体として不凍液を添加した水を用いることにより、外気温が氷点下になっても、冷却媒体の凍結による冷却システムの故障を防止できる。
このように、冷却媒体として空気を用い、空気を送風手段によりオイルクーラに導く構成とすることで、冷却媒体ラインの構造を簡素化でき、且つメンテナンスを容易に行うことが可能となる。
このように、オイルクーラで用いられる冷却媒体によって、タワー内またはタワー外周に設けられる変圧器室の冷却も行うようにしたので、再生エネルギー型発電装置が有する複数の熱発生源の冷却を統合的に行うことができ、冷却の効率化が図れる。また、冷却媒体として不凍液を添加した水を用いることにより、外気温が氷点下になっても、冷却媒体の凍結による冷却システムの故障を防止できる。
通常、風力発電装置は、風速がある一定以上得られる場所に設置されることが多い。したがって、風力発電装置において、冷却媒体を冷却する雰囲気流体として空気を用いることにより、熱交換器への雰囲気流体の取り込みを容易に行うことが可能となる。
このように、風速が大きい高所のタワー上部またはナセルに熱交換器を配置することで、熱交換器への雰囲気流体の取り込みをより一層促進することが可能となる。
洋上風力発電装置においては、周囲に海水が十分に存在するため、冷却媒体を冷却する雰囲気流体として海水を十分に確保することができる。
これにより、被冷却部位と雰囲気流体源との距離が近くなり、冷媒循環ラインの配管構成を簡素化できる。
このように、タワー内部及びナセル内部の少なくとも一方が外気に対して密閉状態となるように構成することで、外気に含まれる腐食性物質、特に洋上風力発電装置においては塩による内部機器の腐食を防止できる。
このように、タワー内部又はナセル内部空気を空冷でも冷却する空気吸入口及び空気排出口を有することで、発電機や油圧トランスミッション等の熱発生源によるタワー内部又はナセル内部の温度上昇を抑制できる。また、空気吸入口及び空気排出口には、外気に混在する腐食性物質を遮蔽するフィルタを設ける構成としているので、外気に含まれる腐食性物質がタワー内部又はナセル内部に侵入することを防止できる。
このように、タワー内部又はナセル内部温度が所定温度より高い場合には、シャッタを開いて換気モードとし、ファンによってタワー内部又はナセル内部の空気を、空気吸入口及び空気排出口を介して入れ換えることでタワー内部又はナセル内部温度を低下させることができる。一方、タワー内部又はナセル内部温度が所定温度以下の場合には、シャッタを閉じて循環モードとし、ファンによってタワー内部又はナセル内部の空気を内部循環させることで、局所的な高温部位(発電機周囲など)を解消することができる。さらにまた、換気モードと循環モードとからなる2つの用途でファンを使用できる。
図1及び図2を参照して、本発明の第1実施形態に係る風力発電装置について説明する。ここで、図1は、第1実施形態に係る風力発電装置の全体構成を示す図であり、図2は、オイルラインと冷却媒体ラインの構成例を示す図である。
図1に示すように風力発電装置1は、主として、タワー2と、タワー2に支持されるナセル4と、風のエネルギーによって回転するロータ6とを備える。
なお、図1には、風力発電装置1として海面SL上に設置される洋上風力発電装置を例示しているが、風力発電装置1は陸上に設置されていてもよい。
図2に示すように、油圧トランスミッション10は、主軸5に連結された油圧ポンプ12と、発電機20に連結された油圧モータ14と、油圧ポンプ12及び油圧モータ14間に設けられるオイルライン18とを有する。オイルライン18は、油圧ポンプ12の吐出側と油圧モータ14の吸込側とを接続する高圧油ライン16、および、油圧ポンプ12の吸込側と油圧モータ14の吐出側とを接続する低圧油ライン17により構成されている。
ここで、冷却媒体は、冷却媒体ライン30を介してオイルクーラ36に導入される。
冷却媒体ライン30は、風力発電装置1の熱発生源(図2では油圧トランスミッション)の冷却を行うための冷却媒体を循環させる流路であり、閉ループの冷媒回路として構成される。冷却媒体ライン30を循環する冷却媒体には、任意の液体又は気体からなる冷媒を用いることができる。特に、冷却媒体として空気を用いることが好ましい。このとき、冷却媒体ライン30に設けたファン39によって、空気がオイルクーラ36に導かれるようにする。これにより、冷却媒体ライン30の構造を簡素化でき、且つメンテナンスを容易に行うことが可能となる。また、冷却媒体として、不凍液を添加した水を用いることも好ましい。このように、冷却媒体として一般的な気体(空気など)に比べて比熱の大きい水を用いることで、冷却媒体の必要循環量を少なくできる。さらに、不凍液の添加により、外気温が氷点下になっても、冷却媒体(水)の凍結による冷却システムの故障を防止できる。
さらに、バイパスライン19の分岐点Aと合流点Bとの間に位置する低圧油ライン17aには、オイルクーラ36に流入する作動油の流量を調整する流量調整バルブ51が設けられている。
また、流量調整バルブ51は完全に閉とすることもでき、この場合、オイルクーラ36に流入する作動油の流量が0となるため、オイルクーラ36での冷却が行われない状態となる。
他の熱発生源としては、例えば、発電機クーラ37、ナセル冷却器38、タワー冷却器等が挙げられる。この場合、熱交換器35は共通として、冷媒ライン30は各熱発生源に対して直列配管にした構成例を示しているが、各熱発生源の必要温度、流量によっては並列配管とする方が好ましい場合もある。
なお、図1には、発電機クーラ37及びナセル冷却器38を例示したが、熱発生源はこれらに限定されるものではなく、他の熱発生源に対しても上記の冷却機構は適用可能である。
なお、図1には、空気吸入口44及び空気排出口45をナセル4に設けた構成を示したが、タワー2側に設けてもよい。このように、タワー2の内部又はナセル4の内部を空冷する空気吸入口44及び空気排出口45を設けることで、発電機20や油圧トランスミッション10等の熱発生源によるタワー2内部又はナセル4内部の温度上昇を抑制できる。
この場合、図4に示すように、冷却媒体ライン30には、分岐点Cにて冷却媒体ライン30から分岐して、合流点Dにて該冷却媒体ライン30に合流するバイパスライン31が接続されている。このバイパスライン31には、分岐点Cで分岐した冷却媒体が流れ、この冷却媒体は合流点Dで再度、冷却媒体ライン30に合流するようになっている。
さらに、バイパスライン31の分岐点Cと合流点Dとの間に位置する冷却媒体ライン30aには、オイルクーラ36に流入する作動油の流量を調整する流量調整バルブ56が設けられている。
また、流量調整バルブ56は完全に閉とすることもでき、この場合、オイルクーラ36に流入する冷却媒体の流量が0となるため、オイルクーラ36での冷却が行われない状態となる。
このように、流量調整バルブ56によって、オイルクーラ36を流れる冷却媒体流量を調整することで、作動油を適切な温度に保つことが可能となる。さらに、オイルクーラ36を流れる流量に制限を設けておくと一定以上の冷却が不可能になり、過冷却を物理的に防止することも可能となる。
図5に示すように、風力発電装置1は、変圧器室72を冷却する変圧器室冷却器72を備える。変圧器室72は、発電機20で発電した電力を変圧する変圧器73を収納する空間である。変圧器室72内は、変圧器73の放熱によって昇温する。そこで、変圧器室72に変圧器室冷却器72を設けている。この変圧器室冷却器72は、第2の冷却媒体ライン70を流れる冷却媒体と、変圧器室72内の空気とを熱交換する構成となっている。第2の冷却媒体ライン71には、上記変圧器室冷却器72と、熱交換器71とが接続されている。この熱交換器71は、ポンプ77によって汲み上げた海水を供給する海水供給ライン78が接続されており、海水と冷却媒体とを熱交換することにより冷却媒体を冷却する構成となっている。さらに、第2の冷却媒体ライン70には、タワー2内の空気を冷却するタワー冷却器75が接続されていてもよい。
図5及び図6に示した構成のように、変圧器室72内を冷却する構成を備えることで、風力発電装置1の主要な熱発生源を冷却でき、風力発電装置1の円滑な運転が可能となる。また、主に油圧トランスミッションを冷却する冷却媒体ライン18と、主に変圧器室72内を冷却する第2の冷却媒体ライン70または熱交換器81とを、それぞれ独立して設けることにより、それぞれに最適な冷却手段を選択することが可能となる。このように、これらを独立して設けて、冷却媒体の配管を各々で最適な長さとすることで、配管の簡素化を図ることが可能となる。
次に、第2実施形態に係る風力発電装置について説明する。本実施形態の風力発電装置は、変圧器室72内の冷却機構を除けば、既に説明した第1実施形態の風力発電装置1と同様の構成である。したがって、ここでは、第1実施形態と共通する部材には同一の符号を付してその説明を省略し、第1実施形態と異なる部分を中心に説明する。
2 タワー
4 ナセル
5 主軸
6 ロータ
6A ブレード
6B ハブ
10 油圧トランスミッション
12 油圧ポンプ
14 油圧モータ
16 高圧油ライン
17、17a 低圧油ライン
18 オイルライン
19 バイパスライン
20 発電機
30 冷却媒体ライン
31 バイパスライン
35 熱交換器
36 オイルクーラ
37 発電機クーラ
38 ナセル冷却器
50、55 コントローラ
51、56 流量調整バルブ
Claims (16)
- 再生エネルギーから電力を生成する再生エネルギー型発電装置であって、
再生エネルギーによって駆動される回転シャフトと、
前記回転シャフトによって駆動される油圧ポンプと、
前記油圧ポンプから供給される作動油によって駆動される油圧モータと、
前記モータに連結された発電機と、
前記油圧ポンプ及び前記油圧モータに接続され、前記油圧ポンプ及び前記油圧モータの間で前記作動油を循環させるオイルラインと、
前記オイルラインに接続され、前記作動油を冷却媒体と熱交換することにより冷却するオイルクーラと、
前記オイルクーラに前記冷却媒体を供給する冷却媒体ラインと、
前記オイルライン及び前記冷却媒体ラインの少なくとも一方のラインから分岐して該ラインに合流し、前記オイルクーラをバイパスするバイパスラインと、
前記バイパスラインの分岐点と合流点との間に位置する前記少なくとも一方のラインに設けられ、前記オイルクーラに流入する前記作動油及び前記冷却媒体の少なくとも一方の流量を調整する流量調整バルブとを備えることを特徴とする再生エネルギー型発電装置。 - 前記冷却媒体ラインに設けられ、前記再生エネルギー型発電装置の周囲に存在する雰囲気流体によって前記冷却媒体を冷却する熱交換器をさらに備え、
前記熱交換器における前記冷却媒体と前記雰囲気流体との熱交換量は、前記冷却媒体の流量及び前記雰囲気流体の流量の少なくとも一方によって調整されることを特徴とする請求項1に記載の再生エネルギー型発電装置。 - 前記冷却媒体ラインに接続され、前記発電機を冷却する発電機クーラをさらに備え、
前記冷却媒体は、前記オイルクーラ及び前記発電機クーラの冷却に用いられることを特徴とする請求項1に記載の再生エネルギー型発電装置。 - 前記オイルラインから前記作動油の一部を引き抜き、前記油圧ポンプ及び前記油圧モータの少なくとも一方の摺動部位に潤滑油として供給する作動油引き抜きラインと、
前記作動油引き抜きライン上に設けられ、前記作動油を冷却する潤滑油冷却手段とをさらに備え、
前記潤滑油冷却手段によって、前記摺動部位に供給される潤滑油が前記油圧ポンプ入口の作動油より低温に維持されることを特徴とする請求項1に記載の再生エネルギー型発電装置。 - 前記オイルラインの所定位置における作動油温度が設定温度となるように、前記流量調整バルブの開度を調節して、前記オイルクーラに流入する作動油流量及び冷却媒体流量の少なくとも一方を調整するコントローラをさらに備えることを特徴とする請求項1に記載の再生エネルギー型発電装置。
- 少なくとも前記油圧ポンプ及び前記油圧モータを収容するタワー又はナセルの内部に設けられ、前記タワー又はナセル内部の空気を冷却するタワー/ナセル冷却器をさらに備え、
前記タワー/ナセル冷却器に、前記冷却媒体を供給するようにしたことを特徴とする請求項1に記載の再生エネルギー型発電装置。 - 前記冷却媒体ラインには、前記発電機を冷却する発電機クーラ、並びに、少なくとも前記油圧ポンプ及び前記油圧モータを収容するタワー又はナセルを冷却するタワー/ナセル冷却器の少なくとも一方が、直列または並列に接続され、
前記冷却媒体は不凍液が添加された水であり、該冷却媒体により、前記オイルクーラに加えて、前記発電機クーラ及び前記タワー/ナセル冷却器の少なくとも一方を冷却することを特徴とする請求項1に記載の再生エネルギー型発電装置。 - 前記冷却媒体が空気であり、前記冷却媒体ラインに送風手段が設けられ、
前記冷却媒体が前記送風手段により前記オイルクーラに導かれることを特徴とする請求項1に記載の再生エネルギー型発電装置 - 前記再生エネルギー型発電装置が、タワーと、前記タワーによって支持され、少なくとも前記油圧ポンプを収容するナセルとを有する風力発電装置であって、
前記タワー内または前記タワーの外周に設けられ変圧器が配置される変圧器室と、
前記冷却媒体ラインに直列または並列に接続され、前記熱交換器にて冷却された冷却媒体が前記冷却媒体ラインを介して前記変圧器室に供給され、前記冷却媒体の冷熱により前記変圧器室内の空気を冷却する変圧器冷却器とを備え、
前記冷却媒体は不凍液を添加された水であることを特徴とする請求項2に記載の再生エネルギー型発電装置。 - 前記再生エネルギー型発電装置が、タワーと、前記タワーによって支持され、少なくとも前記油圧ポンプを収容するナセルとを有する風力発電装置であって、
前記雰囲気流体が空気であることを特徴とする請求項2に記載の再生エネルギー型発電装置。 - 前記熱交換器が前記タワー上部または前記ナセルに配置されていることを特徴とする請求項10に記載の再生エネルギー型発電装置。
- 前記再生エネルギー型発電装置が、タワーと、前記タワーによって支持され、少なくとも前記油圧ポンプを収容するナセルとを有し、海洋上に立設される洋上風力発電装置であって、
前記雰囲気流体が海水であることを特徴とする請求項2に記載の再生エネルギー型発電装置。 - 前記熱交換器と、変圧器が配置される変圧器室とが前記タワー下部に設けられ、
前記冷却媒体ラインが前記タワー下部まで延設されていることを特徴とする請求項12に記載の再生エネルギー型発電装置。 - 前記タワー内部及び前記ナセル内部の少なくとも一方は、外気に対して密閉状態であることを特徴とする請求項1に記載の再生エネルギー型発電装置。
- 前記タワー内部又は前記ナセル内部空気を空冷でも冷却する空気吸入口及び空気排出口を有し、
前記空気吸入口及び前記空気排出口には、外気に混在する腐食性物質を遮蔽するフィルタがそれぞれ設けられていることを特徴とする請求項9に記載の再生エネルギー型発電装置。 - 前記タワー内部又は前記ナセル内部には、少なくとも一つのファンが設けられ、
前記空気吸入口及び前記空気排出口には、開閉自在なシャッタがそれぞれ設けられており、
前記タワー内部又は前記ナセル内部温度が所定温度より高い場合には、前記シャッタを開いて前記タワー内部又は前記ナセル内部の空気を換気する換気モードとし、
前記タワー内部又は前記ナセル内部温度が所定温度以下の場合には、前記シャッタを閉じて前記ナセル内部の空気を該ナセル内部で循環させる循環モードとすることを特徴とする請求項15に記載の再生エネルギー型発電装置。
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- 2011-08-10 AU AU2011338137A patent/AU2011338137A1/en not_active Abandoned
- 2011-08-10 WO PCT/JP2011/068284 patent/WO2013021488A1/ja active Application Filing
- 2011-08-10 EP EP11797294.3A patent/EP2570660B1/en not_active Not-in-force
- 2011-08-10 CN CN2011800057023A patent/CN102859188A/zh active Pending
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JP2018518631A (ja) * | 2015-07-01 | 2018-07-12 | ヴォッベン プロパティーズ ゲーエムベーハーWobben Properties Gmbh | 風力発電装置および風力発電装置用の冷却装置 |
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JP2018091246A (ja) * | 2016-12-05 | 2018-06-14 | 株式会社Skip | 風力発電機 |
Also Published As
Publication number | Publication date |
---|---|
JP4950367B1 (ja) | 2012-06-13 |
JPWO2013021488A1 (ja) | 2015-03-05 |
EP2570660A4 (en) | 2013-05-29 |
US20120124984A1 (en) | 2012-05-24 |
KR20130050274A (ko) | 2013-05-15 |
AU2011338137A1 (en) | 2013-02-28 |
EP2570660B1 (en) | 2014-01-08 |
EP2570660A1 (en) | 2013-03-20 |
CN102859188A (zh) | 2013-01-02 |
US8601804B2 (en) | 2013-12-10 |
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