CN208620656U - Thermoelectricity air cooling tubes condenser safe production in summer device based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN - Google Patents
Thermoelectricity air cooling tubes condenser safe production in summer device based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN Download PDFInfo
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- CN208620656U CN208620656U CN201821126469.XU CN201821126469U CN208620656U CN 208620656 U CN208620656 U CN 208620656U CN 201821126469 U CN201821126469 U CN 201821126469U CN 208620656 U CN208620656 U CN 208620656U
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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
- Y02A—TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
- Y02A30/00—Adapting or protecting infrastructure or their operation
- Y02A30/27—Relating to heating, ventilation or air conditioning [HVAC] technologies
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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
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B30/00—Energy efficient heating, ventilation or air conditioning [HVAC]
- Y02B30/62—Absorption based 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
- Y02E10/50—Photovoltaic [PV] energy
Abstract
The utility model relates to a kind of thermoelectricity air cooling tubes condenser safe production in summer device based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN, including concentrating photovoltaic power generation and afterheat utilizing system, absorption system, thermoelectricity air cooling tubes condenser component, by the way that light gathering photovoltaic power generating system is combined with coal electric system, for solving the problems, such as thermoelectricity air cooling unit safe production in summer, the absorption type refrigerating unit of Winter heat supply is enabled in summer, using the waste heat driving absorption refrigeration unit of concentration photovoltaic system to produce chilled water, the high ambient temperature air of Electric Factory Air-Cooling unit is pre-chilled in chilled water, to promote the heat exchange property of condenser, achieving the purpose that, which reduces turbine discharge back pressure, improves generating efficiency;At the same time, the photoelectric conversion generated energy in Condensation photovoltaic battery can further increase power supply.It works along both lines, the electricity consumption excessive pressure caused by fired power generating unit when successfully managing summer high temperature.
Description
Technical field
The utility model belongs to the UTILIZATION OF VESIDUAL HEAT IN of condensation photovoltaic and the air cooling field of coal-fired thermal power generation unit, relates to
And a kind of light coal complementary system that concentrating photovoltaic power generation is combined with coal electricity, it is specifically a kind of based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN
Thermoelectricity air cooling tubes condenser safe production in summer device, for solving the problems, such as thermoelectricity air cooling unit safe production in summer.
Background technique
Coal-fired thermal power generation unit accounts for the 73% of all power supplies, is the basic guarantee of China's power supply.Due to sky
Cooling system has apparent water saving advantage, has become the first choice that China's richness coal lacks water area.The heat transfer property of air cooling tubes condenser
It is highly prone to the influence of meteorological condition, can greatly deteriorate the heat exchange property of condenser if ambient air temperature increases, make steamer
Machine exhaust pressure increases, and then is degrading the efficiency of generating set.Research shows that: environment temperature increases 1 DEG C, and steam-turbine unit is true
Reciprocal of duty cycle declines about 2kPa, and generated energy declines about 4MW;In addition to this, surrounding air high temperature is possible to the safe operation of threat system.
When environment temperature is excessively high, and turbine discharge back pressure is caused to increase, boiler must coal to maintain main vapour pressure, but work as condenser
When back-pressure surges decline, due to subtracting the hysteresis quality of coal adjusting, main vapour pressure can be caused excessively high, boiler is in turn resulted in and steam turbine is jumped
Lock.Therefore develop that a kind of to be able to suppress air cooling unit performance with the device of variation of ambient temperature be very necessary.
For air cooling unit safe production in summer problem, currently used solution is that load down operation or dry and wet are combined and changed
Make measure.Load down operation, although can guarantee the safety of unit, this big status back road with high-temperature condition electricity consumption and
It speeds;The measure for carrying out dry and wet joint transformation, as patent of invention " is combined using the dry and wet of gravity-flow ventilation and combined running mode and cooled down
(application number: 201510810682.7), which is based on cooling stack, proposes a kind of dry and wet connection for tower and its application "
Close the method for operation, it is indicated that recirculated water can be reduced using the combined running mode of series, parallel or mixture length by doing section and wet section
The cooling tower of temperature.Dry and wet combines the type of cooling, and a clammy effect also has the limit, and effect is not especially desirable, furthermore is violated
Build the water-saving original intention of air cooling unit.
Utility model content
In view of the above drawbacks of the prior art and insufficient, the utility model is intended to provide a kind of based on condensation photovoltaic waste heat benefit
Thermoelectricity air cooling tubes condenser safe production in summer device, using concentrating photovoltaic power generation incident photon-to-electron conversion efficiency is high, occupied area is small, the sun
The advantages that incident photon-to-electron conversion efficiency of energy battery is little with the influence of battery surface temperature, under the premise of guaranteeing photovoltaic power generation quantity,
By the way that battery surface is maintained higher temperature, takes out partial heat and be used, thus by concentrating photovoltaic power generation and coal electricity phase
In conjunction with for solving the problems, such as thermoelectricity air cooling unit safe production in summer, in the absorption refrigeration (heat pump) of summer enabling Winter heat supply
Device, using the waste heat driving absorption refrigeration unit of concentration photovoltaic system to produce chilled water, chilled water is to Electric Factory Air-Cooling machine
The high ambient temperature air of group is pre-chilled, to promote the heat exchange property of condenser, reaching, which reduces turbine discharge back pressure, is improved
The purpose of generating efficiency;At the same time, the photoelectric conversion generated energy in Condensation photovoltaic battery can further increase power supply.
It works along both lines, the electricity consumption excessive pressure caused by fired power generating unit when successfully managing summer high temperature.
The technical scheme adopted by the utility model for solving the technical problem is:
A kind of thermoelectricity air cooling tubes condenser safe production in summer device based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN, including concentrating photovoltaic power generation
And afterheat utilizing system, absorption system, thermoelectricity air cooling tubes condenser component, which is characterized in that
-- the concentrating photovoltaic power generation and afterheat utilizing system, including collector lens, photovoltaic cell mould group, temperature control heat transfer heat
Pipe and heat-accumulator tank, wherein
The collector lens the luminous energy from solar radiation to be gathered in the photovoltaic cell mould group,
The photovoltaic cell mould group is converted into high-grade electric energy luminous energy is passed through photoelectric conversion,
The evaporation ends of the temperature control heat transfer heat pipe and photovoltaic cell mould group heat transfer connect, the temperature control heat transfer heat pipe
Condensation end and heat-accumulator tank heat transfer connect, the low grade heat energy on the photovoltaic cell mould group surface is transmitted to the storage
Hot tank;
-- the absorption system, using lithium bromide water solution as working media, including absorber, generator,
Condenser, evaporator, Intermediate Heat Exchanger, solution pump, throttle valve I, throttle valve II, wherein
The steam output end of the generator successively through the condenser, throttle valve I, evaporator cold side after with the suction
The low-pressure steam input terminal connection of device is received,
The low concentration lithium-bromide solution output end of the absorber successively through the solution pump, Intermediate Heat Exchanger cold side after
It is connected to the low concentration lithium-bromide solution input terminal of the generator,
Hot side of the high concentration lithium-bromide solution output end of the generator successively through the Intermediate Heat Exchanger, throttle valve II
After be passed through the absorber,
Heat-exchanging component, the hot water outlet company of the import of the heat-exchanging component and the heat-accumulator tank are provided in the generator
Logical, the outlet of the heat-exchanging component is connected to the water return outlet of the heat-accumulator tank;
-- the thermoelectricity air cooling tubes condenser component, including thermoelectricity air cooling tubes condenser, cold-storage tank and air precooler, wherein
The hot side import of the thermoelectricity air cooling tubes condenser is passed through exhaust steam in steam turbine, and hot side outlet is condensed water,
Closed by pipeline with the heat-exchanging component formation being arranged in the cold-storage tank cold in the cold side of the air precooler
Circulation,
The cold water output end of the cold-storage tank after the hot side of evaporator in the absorption system with the cold-storage
The cold water input terminal of tank is connected to,
The hot side import of the air precooler is communicated with the atmosphere, the cold side of hot side outlet and the thermoelectricity air cooling tubes condenser
The cold side outlet port of inlet communication, the thermoelectricity air cooling tubes condenser is communicated with the atmosphere.
Preferably, the temperature of the low grade heat energy on the photovoltaic cell mould group surface is 80~105 DEG C.
Preferably, the collector lens is high power concentrator Fresnel Lenses.
Preferably, the photovoltaic cell mould group is gallium arsenide cells array.
Preferably, the condensation end of the temperature control heat transfer heat pipe is connected by heat collector and heat-accumulator tank heat transfer.It is connected with liquid
The heat collector of body medium exchanges heat with multiple heat pipes, so that the heat of multiple battery modules is collected, it is more with few collection, and be stored in
In heat-accumulator tank.
Preferably, throttle valve I is provided on the pipeline between the condenser and the hot side of evaporator.
Preferably, throttle valve II is provided on the pipeline between the hot side and absorber of the Intermediate Heat Exchanger.
Preferably, recirculated water is provided on the hydraulic pipeline between the cold water output end and cold water input terminal of the cold-storage tank
Pump.
Preferably, on the connecting pipeline between the heat-exchanging component in the heat-exchanging component and the heat-accumulator tank in the generator
It is provided with control valve.
In the absorption system of the utility model, the concentrating photovoltaic power generation waste heat exported in heat-accumulator tank drives generator
Steam is generated, steam is condensed into liquid water within the condenser, is liquid water decrease temperature and pressure by throttle valve I, then in evaporator
Heat is released in middle evaporation.Low-pressure steam is absorbed in absorber by high concentration lithium-bromide solution, and it is molten to form low concentration lithium bromide
Liquid after low concentration hypotonic solution is pressurizeed by solution pump, exchanges heat in Intermediate Heat Exchanger and high temperature and pressure highly concentrated solution, cocurrent
Enter generator, issued in the driving of photovoltaic power generation waste heat and bear high steam, form highly concentrated solution, completes entire absorption system
SAPMAC method.
In the thermoelectricity air cooling tubes condenser component of the utility model, inhaled when liquid evaporation in the evaporator of absorption system
The heat of receipts is stored in cold-storage tank after recirculated water is cooled at the same time from circulated refrigerated water.In the another of cold-storage tank
Side output cooling capacity carries out pre-cooling cooling to surrounding air.Surrounding air by pre-cooling flows into thermoelectricity air cooling tubes condenser to steam turbine
Steam exhaust is condensed.
The thermoelectricity air cooling tubes condenser safe production in summer device based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN of the utility model, due to final
Refrigerant (surrounding air) temperature for reducing air cooling tubes condenser, greatly improves the heat exchange property of condenser, to reduce vapour
Turbine discharge back pressure, improves generating efficiency, and it is excessive to thermoelectricity system to resist summer high temperature power load to increase generated energy
Caused by pressure.At the same time, concentrating photovoltaic power generation amount can also supplement electricity consumption problems of too on daytime, mitigate peak of power consumption pair
Pressure caused by fired power generating unit.Two aspect factors are worked along both lines, in the common thermoelectricity system for solving the driving of air cooling tubes condenser unit
Existing two intrinsic problems: 1, thermal power plant's air cooling unit safe production in summer problem;2, summer high temperature power load is excessive and power plant
The contradiction of undercapacity.
Compared with the existing technology, the thermoelectricity air cooling tubes condenser degree of safety based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN of the utility model
Summer clothing is set, by light coal complementation thought, often solar radiation when daylight environment air high temperature causes the Performance of Condensers to deteriorate
When intensity is larger, makes full use of condensation photovoltaic waste heat at this time to drive absorption system to produce cold water, compensate condenser
Performance degradation, guarantee air cooling unit safe production in summer;The utility model does not compensate summer merely with concentration photovoltaic system power generation
Thermal power output is insufficient when high temperature, and condensation photovoltaic waste heat is made full use of to produce cold water, and condenser air is pre-chilled, and improves
The heat exchange property of condenser, and then fired power generating unit generating efficiency and generated energy are improved, so that light coal complementary coupled is performed to pole
It causes;From the angle of UTILIZATION OF VESIDUAL HEAT IN, many thermal power plants all have been provided with absorption refrigeration unit, in case heat supply in winter.This reality
Needing additionally to increase a cold-storage tank and air precooler with novel can erect and be coagulated with photovoltaic generating waste-heat solution summer
The bridge of vapour device heat exchange property attenuation problem, without increasing significantly investment.It will be served only for the absorption refrigeration of heating originally simultaneously
Unit is fully utilized in summer, substantially reduces equipment cost return period.
Detailed description of the invention
Fig. 1 is showing for the thermoelectricity air cooling tubes condenser safe production in summer device based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN of the utility model
It is intended to.
Specific embodiment
For the purpose of this utility model, technical solution and advantage is more clearly understood, develop simultaneously implementation referring to the drawings
The utility model is further described in example.
As shown in Figure 1, the thermoelectricity air cooling tubes condenser degree of safety summer clothing based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN of the utility model
It sets, including concentrating photovoltaic power generation and afterheat utilizing system, absorption system, thermoelectricity air cooling tubes condenser component.
Concentrating photovoltaic power generation and afterheat utilizing system, including collector lens 101, photovoltaic cell mould group 102, temperature control heat transfer heat
Pipe 103, heat collector 104 and heat-accumulator tank 105, wherein collector lens 101, such as can be 1000 times of high power concentrator Fresnel
Lens, to gather the luminous energy from solar radiation in photovoltaic cell mould group 102, photovoltaic cell mould group 102 can have more
Group, each photovoltaic cell mould group 102 includes again N × M gallium arsenide cells array, and photovoltaic cell mould group 102 is to pass through luminous energy
It crosses photoelectric conversion and is converted into high-grade electric energy, solar cell surface can export 80~105 DEG C of low-grade heat at the same time
Can, evaporation ends and photovoltaic cell mould group 102 heat transfer of temperature control heat transfer heat pipe 103 connect, and the condensation end of temperature control heat transfer heat pipe passes through
Heat collector 104 and the heat transfer of heat-accumulator tank 105 connect, and the heat collector 104 and multiple heat pipes for being connected with liquid medium exchange heat, to receive
Collect low-grade thermal energy on multiple 102 surfaces of battery modules, it is more with few collection, and be stored in heat-accumulator tank 105.
Absorption system, using lithium bromide water solution as working media, including absorber 201, generator 202,
Condenser 203, evaporator 204, Intermediate Heat Exchanger 205, solution pump 206, throttle valve I 207, throttle valve II 208, wherein occur
The steam output end of device 202 successively through condenser 203, throttle valve I 207, evaporator 204 cold side after it is low with absorber 201
The connection of steam input terminal is pressed, the low concentration lithium-bromide solution output end of absorber 201 is successively through solution pump 206, Intermediate Heat Exchanger
It is connected to behind 205 cold side with the low concentration lithium-bromide solution input terminal of generator 202, the high concentration lithium bromide of generator 202 is molten
Liquid output end is passed through absorber 201 after the hot side of Intermediate Heat Exchanger 205, throttle valve II 208, is provided with and changes in generator 202
The import of hot component, heat-exchanging component is connected to the hot water outlet of heat-accumulator tank 105, the outlet of heat-exchanging component and returning for heat-accumulator tank 105
Mouth of a river connection, and control valve is provided on connecting pipeline between.
In the absorption system of the utility model, the concentrating photovoltaic power generation waste heat driving exported in heat-accumulator tank 105 is sent out
Raw device 202 generates steam, and steam is condensed into liquid water in condenser 203, is liquid water decrease temperature and pressure by throttle valve I 207,
It is then evaporated in evaporator 204, releases heat.Low-pressure steam is absorbed in absorber 201 by high concentration lithium-bromide solution, shape
At low concentration lithium-bromide solution, after low concentration hypotonic solution is pressurizeed by solution pump 206, in Intermediate Heat Exchanger 205 and high temperature and pressure
Highly concentrated solution exchanges heat, and flows into generator 202, issues in the driving of photovoltaic power generation waste heat and bears high steam, is formed
Highly concentrated solution completes entire Absorption Cooling System.
Thermoelectricity air cooling tubes condenser component, including thermoelectricity air cooling tubes condenser 301, cold-storage tank 302, air precooler 303 and follow
Ring pump 304, wherein the hot side import of thermoelectricity air cooling tubes condenser 301 is passed through exhaust steam in steam turbine, and hot side outlet is condensed water, air
The cold side of forecooler 303 forms closing SAPMAC method, cold-storage tank 302 with the heat-exchanging component being arranged in cold-storage tank 302 by pipeline
Cold water output end be connected to after the hot side of evaporator 204 in absorption system with the cold water input terminal of cold-storage tank 302, and
Circulating pump 304 is provided on hydraulic pipeline;The hot side import of air precooler 303 is communicated with the atmosphere, hot side outlet and thermoelectricity
The cold side import of air cooling tubes condenser 301 is connected to, and the cold side outlet port of thermoelectricity air cooling tubes condenser 301 is communicated with the atmosphere.
In the thermoelectricity air cooling tubes condenser component of the utility model, inhaled when liquid evaporation in the evaporator of absorption system
The heat of receipts is stored in cold-storage tank after recirculated water is cooled at the same time from circulated refrigerated water.In the another of cold-storage tank
Side output cooling capacity carries out pre-cooling cooling to surrounding air.Surrounding air by pre-cooling flows into thermoelectricity air cooling tubes condenser to steam turbine
Steam exhaust is condensed.
The thermoelectricity air cooling tubes condenser safe production in summer device based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN of the utility model, due to final
Refrigerant (surrounding air) temperature for reducing air cooling tubes condenser, greatly improves the heat exchange property of condenser, to reduce vapour
Turbine discharge back pressure, improves generating efficiency, and power load is excessive to thermoelectricity system when increasing generated energy to resist summer high temperature
Pressure caused by system.At the same time, concentrating photovoltaic power generation amount can also supplement electricity consumption problems of too on daytime, mitigate peak of power consumption
The pressure caused by fired power generating unit.Two aspect factors are worked along both lines, the common thermoelectricity system for solving the driving of air cooling tubes condenser unit
Present in air cooling unit safe production in summer problem and the excessive contradiction with power plant's undercapacity of summer high temperature power load.
The above is only the preferred embodiment of the utility model only, is not intended to limit the utility model, all at this
Within the spirit and principle of utility model, any modification, equivalent substitution, improvement and etc. done should be included in the utility model
Within the scope of.
Claims (9)
1. a kind of thermoelectricity air cooling tubes condenser safe production in summer device based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN, including concentrating photovoltaic power generation and
Afterheat utilizing system, absorption system, thermoelectricity air cooling tubes condenser component, which is characterized in that
-- the concentrating photovoltaic power generation and afterheat utilizing system, including collector lens, photovoltaic cell mould group, temperature control heat transfer heat pipe and
Heat-accumulator tank, wherein
The collector lens the luminous energy from solar radiation to be gathered in the photovoltaic cell mould group,
The photovoltaic cell mould group is converted into high-grade electric energy luminous energy is passed through photoelectric conversion,
The evaporation ends of the temperature control heat transfer heat pipe and photovoltaic cell mould group heat transfer connect, the condensation of the temperature control heat transfer heat pipe
End is connected with heat-accumulator tank heat transfer, the low grade heat energy on the photovoltaic cell mould group surface is transmitted to the accumulation of heat
Tank;
-- the absorption system, using lithium bromide water solution as working media, including absorber, generator, condensation
Device, evaporator, Intermediate Heat Exchanger, solution pump, throttle valve I, throttle valve II, wherein
The steam output end of the generator successively through the condenser, throttle valve I, evaporator cold side after with the absorber
Low-pressure steam input terminal connection,
The low concentration lithium-bromide solution output end of the absorber successively through the solution pump, Intermediate Heat Exchanger cold side after with institute
The low concentration lithium-bromide solution input terminal connection of generator is stated,
The high concentration lithium-bromide solution output end of the generator successively leads to after the hot side of the Intermediate Heat Exchanger, throttle valve II
Enter the absorber,
Heat-exchanging component is provided in the generator, the import of the heat-exchanging component is connected to the hot water outlet of the heat-accumulator tank,
The outlet of the heat-exchanging component is connected to the water return outlet of the heat-accumulator tank;
-- the thermoelectricity air cooling tubes condenser component, including thermoelectricity air cooling tubes condenser, cold-storage tank, air precooler and circulating pump,
In,
The hot side import of the thermoelectricity air cooling tubes condenser is passed through exhaust steam in steam turbine, and hot side outlet is condensed water,
The cold side of the air precooler forms closing SAPMAC method with the heat-exchanging component being arranged in the cold-storage tank by pipeline,
The cold water output end of the cold-storage tank after the hot side of evaporator in the absorption system with the cold-storage tank
The connection of cold water input terminal,
The hot side import of the air precooler is communicated with the atmosphere, the cold side import of hot side outlet and the thermoelectricity air cooling tubes condenser
Connection, the cold side outlet port of the thermoelectricity air cooling tubes condenser are communicated with the atmosphere.
2. the thermoelectricity air cooling tubes condenser safe production in summer device according to claim 1 based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN,
It is characterized in that, the temperature of the low grade heat energy on the photovoltaic cell mould group surface is 80 ~ 105 DEG C.
3. the thermoelectricity air cooling tubes condenser safe production in summer device according to claim 1 based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN,
It is characterized in that, the collector lens is high power concentrator Fresnel Lenses.
4. the thermoelectricity air cooling tubes condenser safe production in summer device according to claim 1 based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN,
It is characterized in that, the photovoltaic cell mould group is gallium arsenide cells array.
5. the thermoelectricity air cooling tubes condenser safe production in summer device according to claim 1 based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN,
It is characterized in that, the condensation end of the temperature control heat transfer heat pipe is connected by heat collector and heat-accumulator tank heat transfer.
6. the thermoelectricity air cooling tubes condenser safe production in summer device according to claim 1 based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN,
It is characterized in that, throttle valve I is provided on the pipeline between the condenser and the hot side of evaporator.
7. the thermoelectricity air cooling tubes condenser safe production in summer device according to claim 1 based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN,
It is characterized in that, is provided with throttle valve II on the pipeline between the hot side and absorber of the Intermediate Heat Exchanger.
8. the thermoelectricity air cooling tubes condenser safe production in summer device according to claim 1 based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN,
It is characterized in that, is provided with water circulating pump on the hydraulic pipeline between the cold water output end and cold water input terminal of the cold-storage tank.
9. the thermoelectricity air cooling tubes condenser safe production in summer device according to claim 1 based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN,
It is characterized in that, is provided with control valve on the connecting pipeline between heat-exchanging component and the heat-accumulator tank in the generator.
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CN201821126469.XU CN208620656U (en) | 2018-07-16 | 2018-07-16 | Thermoelectricity air cooling tubes condenser safe production in summer device based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN |
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Cited By (1)
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CN108800652A (en) * | 2018-07-16 | 2018-11-13 | 中国科学院工程热物理研究所 | Thermoelectricity air cooling tubes condenser safe production in summer device based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN |
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2018
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Cited By (2)
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CN108800652A (en) * | 2018-07-16 | 2018-11-13 | 中国科学院工程热物理研究所 | Thermoelectricity air cooling tubes condenser safe production in summer device based on condensation photovoltaic UTILIZATION OF VESIDUAL HEAT IN |
CN108800652B (en) * | 2018-07-16 | 2024-01-23 | 中国科学院工程热物理研究所 | Thermal power air-cooling condenser safety summer device based on concentrating photovoltaic waste heat utilization |
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