CN103615357A - Cyclic wind, solar and wave power generation and sea water desalination system - Google Patents

Cyclic wind, solar and wave power generation and sea water desalination system Download PDF

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CN103615357A
CN103615357A CN201310566844.8A CN201310566844A CN103615357A CN 103615357 A CN103615357 A CN 103615357A CN 201310566844 A CN201310566844 A CN 201310566844A CN 103615357 A CN103615357 A CN 103615357A
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water
seawater
pipeline
outlet
pond
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CN103615357B (en
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韩树君
刘建军
范景泽
曾鹏飞
王一名
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    • YGENERAL 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
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02ATECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
    • Y02A20/00Water conservation; Efficient water supply; Efficient water use
    • Y02A20/124Water desalination
    • YGENERAL 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
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02ATECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
    • Y02A20/00Water conservation; Efficient water supply; Efficient water use
    • Y02A20/124Water desalination
    • Y02A20/138Water desalination using renewable energy
    • Y02A20/141Wind power
    • YGENERAL 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
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02ATECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
    • Y02A20/00Water conservation; Efficient water supply; Efficient water use
    • Y02A20/124Water desalination
    • Y02A20/138Water desalination using renewable energy
    • Y02A20/142Solar thermal; Photovoltaics
    • YGENERAL 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
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02ATECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
    • Y02A20/00Water conservation; Efficient water supply; Efficient water use
    • Y02A20/124Water desalination
    • Y02A20/138Water desalination using renewable energy
    • Y02A20/144Wave energy
    • YGENERAL 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
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02ATECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
    • Y02A20/00Water conservation; Efficient water supply; Efficient water use
    • Y02A20/20Controlling water pollution; Waste water treatment
    • Y02A20/208Off-grid powered water treatment
    • Y02A20/212Solar-powered wastewater sewage treatment, e.g. spray evaporation
    • YGENERAL 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
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/30Energy from the sea, e.g. using wave energy or salinity gradient
    • YGENERAL 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
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/40Solar thermal energy, e.g. solar towers
    • Y02E10/46Conversion of thermal power into mechanical power, e.g. Rankine, Stirling or solar thermal engines
    • YGENERAL 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
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/70Wind energy
    • Y02E10/72Wind turbines with rotation axis in wind direction

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Abstract

A cyclic wind, solar and wave power generation and sea water desalination system comprises a wave power subsystem, a wind power subsystem, a solar power subsystem and a sea water desalination subsystem. The wave power subsystem comprises a first generator, a high-pressure oil chamber and a plurality of reciprocating oil pumps, wherein the oil pumps are powered by sea wave. The sea water desalination subsystem comprises a sea water extraction pump, a plastic tunnel sea water heater pond, a solar heater, a vacuum tank, a transition tank, a vacuum pump and a desalination pond. The solar power subsystem comprises a plastic tunnel sea water heater pond, a sea water heater pond, a turbocharger, a first heat exchanger, a second generator, a second heat exchanger, a compressor, a condenser, and a sea water extraction pump. The wind power subsystem comprises at least one wind generator. The cyclic wind, solar and wave power generation and sea water desalination system is capable of cyclically utilizing wind power, solar power and wave power and using the powers together for power generation and sea water desalination, and is worthy of application and use in costal and island areas.

Description

A kind of wind energy, solar energy, sea wave energy circulation complemental power-generation and seawater desalination system
Technical field
The present invention relates to wind energy, solar energy and sea wave energy comprehensive utilization technique field, specifically a kind of system of utilizing wind energy, solar energy and sea energy generation and desalination of sea water.
Background technique
, there is the seriously short of electricity of many places coastal and Island in the world and China and lacks fresh water, and the living standard that has seriously affected local economic development and the people improves.And these areas are wind energy, solar energy and the very abundant area of sea wave energy resource.If can effectively these utilizations of resources be got up, just can solve well the difficulty in these areas, change inferior position is advantage.No matter be some area of the world and China at present, people also development and utilization wind energy, solar energy and sea wave energy, to solving local productive life difficulty, brought into play certain effect, but because being separately utilizes, this has just brought two problems, the one, narrow limitation is large, and such as only utilizing wind energy and solar energy, solving power supply so calm and night is exactly a large problem; The 2nd, cost is also higher.If these three kinds of energy recyclings, just can realize mutual supplement with each other's advantages, reduced widely again cost simultaneously.
Summary of the invention
Object of the present invention, is to provide a kind of wind energy, solar energy, sea wave energy circulation complemental power-generation and seawater desalination system, can realize sea wave energy and solar energy, the comprehensive utilization of sea wave energy and wind energy power, and provide the energy for desalination of sea water.
The technological scheme adopting is:
Wind energy, solar energy, sea wave energy circulation complemental power-generation and a seawater desalination system, comprise seawave power generation subsystem, wind-power electricity generation subsystem, desalination of sea water subsystem, solar electrical energy generation subsystem and computer controlled system (being located in remote equipment room).
Seawave power generation subsystem, comprises the first generator, high pressure bunker, oil storage storehouse, a plurality of reciprocating oil pump, a plurality of floating drum, the first pipeline road and the second pipeline road.
Described oil well pump driving mechanism, comprises that a plurality of floating drums, first support buoyancy tank, second and support buoyancy tank and supporting steel frame.The quantity of a plurality of floating drums is identical with a plurality of reciprocating oil pump quantity.Each reciprocating oil-well pump connects with corresponding floating drum by a lever rocker arm body, and described lever rocker arm body comprises vertical connecting rod, the first vertical connecting rod and the second vertical connecting rod.The lower end of the first vertical connecting rod connects with corresponding floating drum, the upper end of the first vertical connecting rod is hinged with the front end of corresponding longitudinal rod, the rear end of longitudinal rod is hinged with the piston rod of corresponding reciprocating oil pump, the upper end of the second vertical connecting rod is hinged with corresponding longitudinal rod, and the lower end of the second vertical connecting rod is fixed on supporting steel frame.Supporting steel frame cross setting, supporting steel frame left end and first supports buoyancy tank and is fixedly connected with, and the right-hand member of supporting steel frame and second supports buoyancy tank and is fixedly connected with.The first support buoyancy tank and second supports buoyancy tank and is set on the steel column that is fixed on seabed.The filler opening of a plurality of reciprocating oil-well pumps is connected with the first pipeline road by pipeline respectively, and the oil outlet of a plurality of reciprocating oil-well pumps is connected with the second pipeline road by pipeline along separate routes.One end sealing of the first pipeline road, the other end is connected with the oil outlet in oil storage storehouse.One end sealing of the second pipeline road, the filler opening connection mouth of the other end and high pressure bunker, the oil outlet of high pressure bunker is connected with the filler opening of the first generator by the road, and the oil outlet of the first generator is connected with the filler opening in oil storage storehouse by the road.
Desalination of sea water subsystem, comprises that seawater extracts pump, cooling storehouse, solar heater, heating of seawater pond, vacuum tank, transition tank, vacuum pump and the first fresh-water pool.
The water outlet that seawater extracts pump is connected with the first conduit pipe, the first conduit pipe is connected with the water intake of solar heater after winding in cooling storehouse, the water outlet of solar heater is connected with the water intake in heating of seawater pond through the 3rd water transport pipeline, and the water outlet in heating of seawater pond is connected with the water intake of vacuum tank through the 4th water transport pipeline.The steam ouput of vacuum tank is connected with the suction port of transition tank by the road, the air outlet of transition tank is connected with the suction port of vacuum pump by the road, air outlet first air delivering pipeline of vacuum pump is connected with the suction port in cooling storehouse, and the water outlet in cooling storehouse is connected with fresh-water pool through the 5th water transport pipeline.Steam in cooling storehouse is cooled into fresh water, leaves cooling storehouse and flows into fresh-water pool.
Solar energy subsystem comprises that heating of seawater pond, turbosupercharger, the first cold and hot transducer, the second fresh-water pool, the second generator, the second cold and hot transducer, compressor, condenser and the second seawater extract pump.
Air outlet second air delivering pipeline in heating of seawater pond is connected with the suction port of turbosupercharger, and the air outlet of turbosupercharger the 3rd air delivering pipeline is connected with the suction port of cold and hot transducer, and the first cold and hot transducer is connected with the second fresh-water pool through fresh water delivery pipe.
The coolant media outlet of compressor is connected with condenser coolant media entrance through the first coolant media transport tube, the coolant media outlet of condenser is connected with the coolant media entrance of turbosupercharger through the second coolant media transfer conduit, the coolant media outlet of turbosupercharger is connected with the coolant media entrance of the second generator after the second cold and hot transducer by the 3rd coolant media transfer conduit, and the coolant media outlet of the second generator is connected with the coolant media entrance of the second cold and hot transducer through the 4th coolant media transfer conduit.Seawater extracts pump and provides cooling water through the 6th water transport pipeline for the second cold and hot transducer.
In desalination of sea water subsystem, be provided with a hot house seawater intensification pond, above-mentioned the first conduit pipe is connected with the water intake in hot house seawater intensification pond, and the water outlet in hot house seawater intensification pond is connected with the water intake of solar heater through the second water transport pipeline.The air outlet in hot house seawater intensification pond is connected with the second air delivering pipeline in solar energy subsystem by pipeline.
On the first water transport pipeline, be equiped with filter.Wind-power electricity generation subtense angle, comprises a plurality of wind-driven generators, and the electricity sending provides power supply through cable transmission for heating of seawater pond.The electricity that wind-driven generator, the first generator, the second generator send is customer power supply through cable transmission.
Working principle of the present invention:
One, seawave power generation subsystem working principle:
Floating drum is connected on lever rocking arm, and by lever rocking arm, the power that power floating drum is produced is transported on oil pump.Oil pump is squeezed into high pressure bunker by the second pipeline road by oil by power oil, and high pressure bunker provides dynamic power for generator.
Desalination of sea water subsystem working principle:
Seawater extracts pump extraction seawater and enters cooling storehouse by filter screen, and by cooling storehouse, ocean temperature rises to 20 ℃ of left and right by 15 ℃ of left and right.The seawater of 20 ℃ of left and right enters hot house seawater intensification pond by cooling storehouse the 5th water transport pipeline, and 40-50 ℃, under the effect of solar energy, is brought up to by the seawater of 20 ℃ of left and right temperature in booth intensification pond.Through solar heater heating, the temperature of seawater just can reach 60-70 ℃ very soon again.When the seawater of solar heater enters into heating of seawater pond, the electric energy producing by wind-driven generator heats, and the temperature of seawater can rise to 80-90 ℃.The seawater of 80-90 ℃ enters vacuum tank through the 4th water transport pipeline, enters seawater atomization rapidly under the effect of vacuum pump of vacuum tank, and seawater becomes gaseous state from liquid state.Seawater steam enters cooling storehouse under the effect of vacuum pump, and in cooling storehouse, seawater steam is through 15 ℃ of cooled with seawater, and seawater steam can be converted into fresh water by gaseous state rapidly, through fresh water delivery pipe, enters fresh-water pool.
Solar electrical energy generation subsystem working principle:
In hot house seawater intensification pond, sunlight can produce a large amount of high-temperature vapors when heating for seawater, when heating of seawater pond utilizes wind energy power to be its heating, also can produce a large amount of high-temperature vapours.The seawater of heating is for the desalination of seawater vacuum, and unnecessary high-temperature vapor, under the effect of turbosupercharger, enters the first cold and warm exchanger through the 3rd air delivering pipeline.High-temperature vapor is the rapid cooling fresh water that becomes of quilt in for the heating of generating coolant media, then enter the second fresh-water pool via fresh water delivery pipe.The coolant media of being exported by condenser has very high pressure, can provide very large driving force for turbosupercharger, installs turbo charging installation additional, can cut can, reduce the impact failure that coolant media brings to equipment due to high pressure, can turn waste into wealth again, for moisture vapor transport provides power.Compressor is squeezed into cooling cylinder by the refrigerant gas in cold and warm exchanger and is compressed into liquid state, and when liquid refrigerants goes out cooling cylinder by turbosupercharger, the pressure in liquid refrigerants can promote turbosupercharger rotary work.From turbosupercharger, liquid refrigerants medium out enters the first cold and warm exchanger, in for water vapour cooling, absorbed again a large amount of heat energy, liquid refrigerants will transform a large amount of refrigerant gas, and these refrigerant gas pass pipeline through coolant media and promote the second generator generating.The gas of abandoning of generating enters the second cold and warm exchanger, after the low temperature seawater cooling of extracting pump extraction through seawater, for compressor operating.
Great advantage of the present invention:
Applicability is strong.The present invention can be according to geographical position and user's actual demand, both can integrated configuration, also can take sea wave energy and solar energy, and sea wave energy is combined with wind energy power.Equipment is changeable, and system is the amount doesn't matter.Can utilize to greatest extent finite energy.In the coastal and Island without electricity, such as wind-powered electricity generation is installed separately, if user does not need electricity consumption just can only abandon electricity while having wind.Just not there is not this problem in the present invention, because there is sea water desalinating unit, during not electricity consumption of user, wind-powered electricity generation can desalinize seawater, and by storing the form of fresh water, wind-powered electricity generation used.The electricity that sea wave energy and solar energy send is also like this.At solar heater front end, set up hot house heating seawater for another example and both reduced equipment investment, can obtain a large amount of water vapour again; What make full use of that desalination of sea water heats that seawater produces abandons gas generating; Utilize the pressure of refrigerant exit to install turbosupercharger additional for extraction water vapour provides power, all turn waste into wealth, comprehensive utilization.
The present invention, because be to recycle, complements one another, and than independent use, has reduced some links, and manufacture cost reduces greatly.Wind-powered electricity generation, seawave power generation and solar electrical energy generation are all mature technologies, stable and reliable operation of the present invention.
Greening and environmental protection of the present invention, the energy is from nature, and power source is inexhaustible, nexhaustible, and is once to drop into, and is forever benefited.
There is great economic benefit and social benefit.Some coastal and Island, possess very large exploitation value and development prospect, but due to short of electricity lack of water, local economic development and the raising of living standards of the people have seriously been hindered, if the present invention is promotion and implementation promptly, just can bring glad tidings for the development in these areas and the people's the improvement of living.
Accompanying drawing explanation
Fig. 1 is a kind of example structure schematic diagram of the present invention.
Embodiment
Wind energy, solar energy, sea wave energy circulation complemental power-generation and a seawater desalination system, comprise seawave power generation subsystem 1, wind-power electricity generation subsystem 2, desalination of sea water subsystem 3, solar electrical energy generation subsystem 51 and computer controlled system (being located in remote equipment room).
Seawave power generation subsystem 1, comprises the first generator 4, high pressure bunker 5, oil storage storehouse 6, a plurality of reciprocating oil-well pump 7, oil well pump driving mechanism, the first pipeline road 8 and the second pipeline road 9.
Described oil well pump driving mechanism, comprises that a plurality of floating drums 10, first support buoyancy tank 11, second and support buoyancy tank 12 and supporting steel frame 13.The quantity of a plurality of floating drums 10 is identical with a plurality of reciprocating oil pump 7 quantity.Each reciprocating oil-well pump 7 connects with corresponding floating drum 10 by a lever rocker arm body, and described lever rocker arm body, comprises longitudinal rod the 14, first vertical connecting rod 15 and the second vertical connecting rod 16.The lower end of the first vertical connecting rod 15 connects with corresponding floating drum 10, the upper end of the first vertical connecting rod 15 is hinged with the front end of corresponding longitudinal rod 14, the rear end of longitudinal rod 14 is hinged with the piston rod 17 of corresponding reciprocating oil pump 7, the upper end of the second vertical connecting rod 16 is hinged with corresponding longitudinal rod 14, and the lower end of the second vertical connecting rod 16 is fixed on supporting steel frame 13.Supporting steel frame 13 cross settings, supporting steel frame 13 left ends and first support buoyancy tank 11 and are fixedly connected with, and the right-hand member of supporting steel frame 13 and second supports buoyancy tank 12 and is fixedly connected with.The first support buoyancy tank 11 and second supports buoyancy tank 12 and is set on the steel column 18 that is fixed on seabed.The filler opening of a plurality of reciprocating oil-well pumps 7 is connected with the first pipeline road 8 by pipeline respectively, and the oil outlet of a plurality of reciprocating oil-well pumps 7 is connected with the second pipeline road 9 by pipeline respectively.One end sealing of the first pipeline road 8, the other end is connected with the oil outlet in oil storage storehouse 6.One end sealing of the second pipeline road 9, the other end is connected with the filler opening of high pressure bunker 5, and the oil outlet of high pressure bunker 5 is connected with the filler opening of the first generator 4 by the road, and the oil outlet of the first generator 4 is connected with the filler opening in oil storage storehouse 6 by the road.
Desalination of sea water subsystem 3, comprises that seawater extracts pump 19, cooling storehouse 20, hot house seawater intensification pond 21, solar heater 22, heating of seawater pond 23, vacuum tank 24, transition tank 25, vacuum pump 26 and the first fresh-water pool 28.
The water outlet that seawater extracts pump 19 is connected with the first conduit pipe 29, and the first conduit pipe 29 is connected with the water intake in hot house seawater intensification pond 21 after the interior winding in cooling storehouse 20.The water outlet in hot house seawater intensification pond 21 is connected with the water intake of solar heater 22 through the second water transport pipeline 30, the water outlet of solar heater 22 is connected with the water intake in heating of seawater pond 23 through the 3rd water transport pipeline 31, and the water outlet in heating of seawater pond 23 is connected with the water intake of vacuum tank 24 through the 4th water transport pipeline 32.The steam ouput of vacuum tank 24 is connected with the suction port of transition tank 25 by the road, the air outlet of transition tank 25 is connected with the suction port of vacuum pump 26 by the road, air outlet first air delivering pipeline 33 of vacuum pump 26 is connected with the suction port in cooling storehouse 20, and the water outlet in cooling storehouse 20 is connected with fresh-water pool 28 through the 5th water transport pipeline 27.Steam in cooling storehouse is cooled into fresh water, leaves cooling storehouse and flows into the first fresh-water pool 28.
Solar electrical energy generation subsystem 51 comprises hot house seawater intensification pond 21, and heating of seawater pond 23, the cold and hot transducer 36 of turbosupercharger 35, first, the second fresh-water pool 37, the cold and hot transducer 38 of the second generator 42, second, compressor 39, condenser 40 and the second seawater extract pump 41.
Air outlet second air delivering pipeline 43 in heating of seawater pond 23 and hot house seawater intensification pond 21 is connected with the suction port of turbosupercharger 35, the air outlet of turbosupercharger 35 the 3rd air delivering pipeline 44 is connected with the suction port of the first cold and hot transducer 36, and the first cold and hot transducer 36 is connected with the second fresh-water pool 37 through fresh water delivery pipe 45.
The coolant media outlet of compressor 39 is connected with the coolant media entrance of condenser 40 through the first coolant media transport tube 46, the coolant media outlet of condenser 40 is connected with the coolant media entrance of turbosupercharger 35 through the second coolant media transfer conduit 47, the coolant media outlet of turbosupercharger 35 is connected with the coolant media entrance of the second generator 42 after the second cold and hot transducer 36 by the 3rd coolant media transfer conduit 48, and the coolant media outlet of the second generator 42 is connected with the coolant media entrance of the second cold and hot transducer 38 through the 4th coolant media transfer conduit 49.Seawater extracts pump 41 and provides cooling water through the 6th water transport pipeline 50 for the second cold and hot transducer 36.
On the first water transport pipeline 29, be equiped with filter 34.Wind-power electricity generation subsystem, comprises at least one wind-driven generator 51, and the electricity sending provides power supply through cable transmission for heating of seawater pond 23.The electricity that wind-driven generator, the first generator, the second generator send is customer power supply through cable transmission.
Computer control subsystem is known technology, is installed in remote equipment room.

Claims (3)

1. a wind energy, solar energy, sea wave energy circulation complemental power-generation and seawater desalination system, comprise seawave power generation subsystem (1), wind-power electricity generation subsystem (2), desalination of sea water subsystem (3), solar electrical energy generation subsystem (51) and computer controlled system, it is characterized in that:
Seawave power generation subsystem (1), comprises the first generator (4), high pressure bunker (5), oil storage storehouse (6), a plurality of reciprocating oil-well pump (7), oil well pump driving mechanism, the first pipeline road (8) and the second pipeline road (9);
Described oil well pump driving mechanism, comprises that a plurality of floating drums (10), first support buoyancy tank (11), second and support buoyancy tank (12) and supporting steel frame (13), the quantity of a plurality of floating drums (10) is identical with a plurality of reciprocating oil-well pumps (7) quantity, each reciprocating oil-well pump (7) connects with corresponding floating drum (10) by a lever rocker arm body, described lever rocker arm body, comprise longitudinal rod (14), the first vertical connecting rod (15) and the second vertical connecting rod (16), the lower end of the first vertical connecting rod (15) connects with corresponding floating drum (10), the upper end of the first vertical connecting rod (15) is hinged with the front end of corresponding longitudinal rod (14), the rear end of longitudinal rod (14) is hinged with the piston rod (17) of corresponding reciprocating oil-well pump (7), the upper end of the second vertical connecting rod (16) is hinged with corresponding longitudinal rod (14), the lower end of the second vertical connecting rod (16) is fixed on supporting steel frame (13), supporting steel frame (13) cross setting, supporting steel frame (13) left end and first supports buoyancy tank (11) and is fixedly connected with, the right-hand member of supporting steel frame (13) and second supports buoyancy tank (12) and is fixedly connected with, the first support buoyancy tank (11) and second supports buoyancy tank (12) and is set on the steel column (18) that is fixed on seabed, the filler opening of a plurality of reciprocating oil-well pumps (7) is connected with the first pipeline road (8) by pipeline respectively, the oil outlet of a plurality of reciprocating oil-well pumps (7) is connected with the second pipeline road (9) by pipeline respectively, one end sealing of the first pipeline road (8), the other end is connected with the oil outlet of oil storage storehouse (6), one end sealing of the second pipeline road (9), the other end is connected with the filler opening of high pressure bunker (5), the oil outlet of high pressure bunker (5) is connected with the filler opening of the first generator (4) by the road, the oil outlet of the first generator (4) is connected with the filler opening of oil storage storehouse (6) by the road,
Desalination of sea water subsystem (3), comprises that seawater extracts pump (19), cooling storehouse (20), solar heater (22), heating of seawater pond (23), vacuum tank (24), transition tank (25), vacuum pump (26) and the first fresh-water pool (28);
The water outlet that seawater extracts pump (19) is connected with the first conduit pipe (29), the first conduit pipe (29) is connected with the water intake of solar heater (22) after winding in cooling storehouse (20), the water outlet of solar heater (22) is connected with the water intake of heating of seawater pond (23) through the 3rd water transport pipeline (31), the water outlet in heating of seawater pond (23) is connected with the water intake of vacuum tank (24) through the 4th water transport pipeline (32), the steam ouput of vacuum tank (24) is connected with the suction port of transition tank (25) by the road, the air outlet of transition tank (25) is connected with the suction port of vacuum pump (26) by the road, air outlet first air delivering pipeline (33) of vacuum pump (26) is connected with the suction port of cooling storehouse (20), the water outlet in cooling storehouse (20) is connected with the first fresh-water pool (28) through the 5th water transport pipeline (27), steam in cooling storehouse is cooled into fresh water, leave cooling storehouse and flow into the first fresh-water pool (28),
Solar electrical energy generation subsystem (51) comprises that heating of seawater pond (23), turbosupercharger (35), the first cold and hot transducer (36), the second fresh-water pool (37), the second generator (42), the second cold and hot transducer (38), compressor (39), condenser (40) and the second seawater extract pump (41);
Air outlet second air delivering pipeline (43) in heating of seawater pond (23) is connected with the suction port of turbosupercharger (35), air outlet the 3rd air delivering pipeline (44) of turbosupercharger (35) is connected with the suction port of the first cold and hot transducer (36), and the first cold and hot transducer (36) is connected with the second fresh-water pool (37) through fresh water delivery pipe (45);
The coolant media outlet of compressor (39) is connected with the coolant media entrance of condenser (40) through the first coolant media transport tube (46), the coolant media outlet of condenser (40) is connected with the coolant media entrance of turbosupercharger (35) through the second coolant media transfer conduit (47), the coolant media outlet of turbosupercharger (35) is connected with the coolant media entrance of the second generator (42) after the second cold and hot transducer (36) by the 3rd coolant media transfer conduit (48), the coolant media outlet of the second generator (42) is connected with the coolant media entrance of the second cold and hot transducer (38) through the 4th coolant media transfer conduit (49), seawater extracts pump (41) and provides cooling water through the 6th water transport pipeline (50) for the second cold and hot transducer 36,
On the first water transport pipeline (29), be equiped with filter (34), wind-power electricity generation subsystem, comprises at least one wind-driven generator (51), and the electricity sending is that heating of seawater pond (23) provides power supply through cable transmission; The electricity that wind-driven generator, the first generator, the second generator send is customer power supply through cable transmission;
Computer control subsystem, is installed in remote equipment room.
2. a kind of wind energy according to claim 1, solar energy, sea wave energy circulation complemental power-generation and seawater desalination system, it is characterized in that described desalination of sea water subsystem is provided with hot house seawater intensification pond (21), the first conduit pipe (29) is connected with the suction port in hot house seawater intensification pond (21), and the water outlet in hot house seawater intensification pond (21) is connected with the water intake of solar heater (22) through the second water transport pipeline (30).
3. a kind of wind energy according to claim 2, solar energy, sea wave energy circulation complemental power-generation and seawater desalination system, is characterized in that the air outlet in hot house seawater intensification pond (21) is connected with the second air delivering pipeline (43) by the road.
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CN105909321A (en) * 2016-04-29 2016-08-31 张启文 Wind-light-wave (three energy sources-one storage) complementary compressed air gravity voltage-stabilizing large-scale air turbine power generating unit
CN105936520A (en) * 2016-06-12 2016-09-14 河海大学常州校区 Electric heating piston reciprocating type seawater desalination system
CN105952586A (en) * 2016-06-12 2016-09-21 河海大学常州校区 Multi-energy assisted fresh water and sea salt co-production system
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