CN204987306U - Use multipurposely solar energy light and heat and photoelectrical technique's domestic dc -inverter air conditioning system - Google Patents

Abstract

The utility model discloses an use multipurposely solar energy light and heat and photoelectrical technique's domestic dc -inverter air conditioning system, including solar energy optoelectronic system, solar energy light and heat system, dehumidification system, dc -inverter air conditioner and control system, solar energy optoelectronic system includes solar photovoltaic board, control module, battery and boost circuit, solar energy light and heat system includes solar vacuum heat collection tube, holding water box, dehumidification heat exchanger, changes white heat exchanger, circulating water pump, dehumidification system includes dehumidifier, dehumidification liquid storage pot, dehumidification system heat exchanger, solution circuit pump, regenerator and regeneration liquid storage pot, the dc -inverter air conditioner includes indoor set and off -premises station, control system includes temperature controller, humidity controller and electrical source controller. The utility model discloses an use multipurposely solar energy light and heat and photoelectrical technique's domestic dc -inverter air conditioning system can be air conditioning system heat supply and power supply, reduce advantages such as the demand of commercial power, energy savings for heat energy and electric energy solar energy conversion.

Description

The household DC frequency-conversion air-conditioning system of comprehensive utilization solar energy optical-thermal and photoelectric technology

Technical field

The utility model relates to a kind of air-conditioning system, and especially a kind of comprehensive utilization solar energy optical-thermal of independent temperature-humidity control and the household DC frequency-conversion air-conditioning system of photoelectric technology, for family's air conditioning, belong to domestic air conditioner.

Background technology

At present, air-conditioning has become people's requisite part in summer living, shows according to investigations, although China had postponed at family expenses air conditioner industry the step grown at top speed over the past two years.But see with regard to overall market situation, the recoverable amount of China's room air conditioner has exceeded 2.7 hundred million, become genuine air-conditioning and produced and occupy big country.These domestic air conditionings, while being convenient for people to life, also consuming huge electric energy every day, bring day by day serious problem of environmental pollution.

As everyone knows, coal, oil and natural gas are the topmost three large energy that present stage human lives and production rely on, but continue every day to consume a large amount of energy, also make three move towards exhausted gradually.According to estimates, the remaining natural gas in the world today also can for the mankind about 200 years, and coal and oil can only for the mankind about 100 years.In such a situa-tion, increasing people transfers eye to invest the regenerative resources such as wind energy, water energy, biomass energy and solar energy.Wherein, solar energy is natural energy source the most widely, has all started progressively to carry out solar energy household electrical appliances in many developed countries.Meanwhile, for the countries and regions of some shorts of electricity, develop the matter of great urgency that solar energy household electrical appliances more can solve them, and often the solar energy resources in these areas is all than more rich, therefore this also lays a good foundation for greatly developing solar energy household electrical appliances.

Utility model content

The utility model is for avoiding the weak point that exists in above-mentioned prior art, providing a kind of household DC frequency-conversion air-conditioning system fully utilizing solar energy optical-thermal and photoelectric technology, can use solar powered, economize energy to make domestic air-conditioning system.

The utility model be technical solution problem by the following technical solutions.

The household DC frequency-conversion air-conditioning system of comprehensive utilization solar energy optical-thermal and photoelectric technology, its design feature is, comprises solar photovoltaic system, solar energy hot systems, dehumidification system, direct current varied-frequency air conditioner and control system; Solar photovoltaic system, solar energy hot systems, dehumidification system are all connected with described control system with direct current varied-frequency air conditioner, control solar photovoltaic system, solar energy hot systems, dehumidification system and direct current varied-frequency air conditioner by described control system; Solar energy hot systems is connected with dehumidification system;

Described solar photovoltaic system comprises solar energy photovoltaic panel, control module, battery and booster circuit; Described solar energy photovoltaic panel connects battery and booster circuit by control module, for providing power supply for charge in batteries with for booster circuit; Described booster circuit will be supplied to described control system after boost in voltage;

Described solar energy hot systems comprises solar vacuum heat-collecting pipe, attemperater, dehumidification heat exchange, defrost heat exchanger, water circulating pump; The delivery port of described solar vacuum heat-collecting pipe connects the water inlet of attemperater, the delivery port of attemperater is connected the water inlet of solar vacuum heat-collecting pipe with water pipe by described water circulating pump, form one is utilized solar energy heating cold water water circulation system by solar vacuum heat-collecting pipe; Dehumidification heat exchange and defrost heat exchanger is provided with in described attemperater;

Described dehumidification system comprises dehumidifier, dehumidifying fluid reservoir, dehumidification system heat exchanger, solution circulation pump, regenerator and regeneration fluid reservoir; The liquid outlet of described dehumidifier is connected with the inlet of described dehumidifying fluid reservoir, the liquid outlet of described dehumidifying fluid reservoir is connected with the dehumidifying inlet of described dehumidification system heat exchanger, and the dehumidifying liquid outlet of described dehumidification system heat exchanger connects the inlet of described dehumidifier by described solution circulation pump; The regeneration liquid outlet of described dehumidification system heat exchanger is connected with the inlet of described regenerator, the liquid outlet of described regenerator is connected with the inlet of described regeneration fluid reservoir, and the liquid outlet of described regeneration fluid reservoir regenerates inlet with described dehumidification system heat exchanger and is connected;

Described direct current varied-frequency air conditioner comprises indoor set and off-premises station; Indoor set is refrigeration system evaporator, provides cold wind in indoor; Described off-premises station is by DC powered;

Described control system comprises temperature controller, humidity controller and power-supply controller of electric; Described temperature controller is for controlling direct current varied-frequency air conditioner, and described humidity controller is for controlling dehumidification system, and described power-supply controller of electric is for controlling the switching of solar-electricity and civil power.

The design feature of the household DC frequency-conversion air-conditioning system of comprehensive utilization solar energy optical-thermal of the present utility model and photoelectric technology is also:

Also electric heater is provided with in the attemperater of described solar energy hot systems.

The dehumidification solution of described dehumidification system is the inorganic salts aqueous solution.

Compared with the prior art, the utility model beneficial effect is embodied in:

The household DC frequency-conversion air-conditioning system of comprehensive utilization solar energy optical-thermal of the present utility model and photoelectric technology, comprises solar photovoltaic system, solar energy hot systems, dehumidification system, direct current varied-frequency air conditioner and control system; Solar photovoltaic system comprises solar energy photovoltaic panel, control module, battery and booster circuit; Solar energy hot systems comprises solar vacuum heat-collecting pipe, attemperater, dehumidification heat exchange, defrost heat exchanger, water circulating pump; Dehumidification system comprises dehumidifier, dehumidifying fluid reservoir, dehumidification system heat exchanger, solution circulation pump, regenerator and regeneration fluid reservoir; Direct current varied-frequency air conditioner comprises indoor set and off-premises station; Control system comprises temperature controller, humidity controller and power-supply controller of electric.

The utility model system provides power supply mainly through solar photovoltaic system, is responsible for the operation of direct current varied-frequency air conditioner and each circulating pump; There is provided thermal source by solar energy hot systems, be responsible for the defrost pattern of dehumidification system and direct current varied-frequency air conditioner.

When solar energy abundance, solar photovoltaic system provides the electric power of system cloud gray model, and by unnecessary electrical power storage in battery, and solar energy hot systems provides the heat energy of system cloud gray model and by unnecessary thermal energy storage in attemperater.Direct current varied-frequency air conditioner utilizes the electric power of solar photovoltaic system, is controlled by control system, and regulate indoor air temperature, dehumidification system utilizes the heat energy of solar energy hot systems, is controlled by control system, regulates the humidity of room air.When solar energy is not enough, regulated by control system, the heat energy of the attemperater storage of the electric energy first utilizing the battery of solar photovoltaic system to store and solar energy hot systems, when the two energy storage is also not enough, call civil power and provide electric energy, maintenance system is normally run.

The utility model system, in the sufficient area of illumination, can rely on solar energy normally to run by day completely, and store enough energy, maintain the operation at night.Even if on the insufficient area of illumination or date, the use amount of civil power also significantly can be reduced.

The comprehensive utilization solar energy optical-thermal of comprehensive utilization solar energy optical-thermal of the present utility model and photoelectric technology and the household DC frequency-conversion air-conditioning system of photoelectric technology combine solar energy power technology, photothermal technique, humiture independence regulation technology, the technology such as DC frequency-changeable compressor, greatly reduce the demand to civil power, the area not easily arrived for the sufficient area of solar energy and civil power is especially applicable.

The household DC frequency-conversion air-conditioning system of comprehensive utilization solar energy optical-thermal of the present utility model and photoelectric technology, can be converted to heat energy and electric energy and be air-conditioning system heat supply and power supply, decrease demand to civil power, make domestic air-conditioning system can use the advantages such as solar powered, economize energy by solar energy.

Accompanying drawing explanation

Fig. 1 is the schematic diagram of the solar photovoltaic system of the household DC frequency-conversion air-conditioning system of comprehensive utilization solar energy optical-thermal of the present utility model and photoelectric technology.

Fig. 2 is the schematic diagram of the solar energy hot systems of the household DC frequency-conversion air-conditioning system of comprehensive utilization solar energy optical-thermal of the present utility model and photoelectric technology.

Fig. 3 is the schematic diagram of the direct current varied-frequency air conditioner of the household DC frequency-conversion air-conditioning system of comprehensive utilization solar energy optical-thermal of the present utility model and photoelectric technology.

Fig. 4 is the schematic diagram of the dehumidification system of the household DC frequency-conversion air-conditioning system of comprehensive utilization solar energy optical-thermal of the present utility model and photoelectric technology.

Fig. 5 is the workflow diagram of the household DC frequency-conversion air-conditioning system of comprehensive utilization solar energy optical-thermal of the present utility model and photoelectric technology.

Label in accompanying drawing 1-5: 1, solar energy photovoltaic panel, 2, control module, 3, battery, 4, booster circuit, 5, solar vacuum heat-collecting pipe, 6, attemperater, 7a, dehumidification heat exchange, 7b, defrost heat exchanger, 8, water circulating pump, 9, electric heater, 10, indoor set, 11, off-premises station, 12, dehumidifier, 13a, dehumidifying fluid reservoir, 13b, regeneration fluid reservoir, 14, dehumidification system heat exchanger, 15, regenerator, 16, solution circulation pump, 17, solar photovoltaic system, 18, solar energy hot systems, 19, control system, 20, direct current varied-frequency air conditioner, 21, dehumidification system.

Below by way of detailed description of the invention, and the utility model is described in further detail by reference to the accompanying drawings.

Detailed description of the invention

See Fig. 1-5, the household DC frequency-conversion air-conditioning system of comprehensive utilization solar energy optical-thermal of the present utility model and photoelectric technology, comprises solar photovoltaic system, solar energy hot systems, dehumidification system, direct current varied-frequency air conditioner and control system; Solar photovoltaic system, solar energy hot systems, dehumidification system are all connected with described control system with direct current varied-frequency air conditioner, control solar photovoltaic system, solar energy hot systems, dehumidification system and direct current varied-frequency air conditioner by described control system; Solar energy hot systems is connected with dehumidification system;

Described solar photovoltaic system comprises solar energy photovoltaic panel, control module, battery and booster circuit; Described solar energy photovoltaic panel connects battery and booster circuit by control module, for providing power supply for charge in batteries with for booster circuit; Described booster circuit will be supplied to described control system after boost in voltage; Solar energy photovoltaic panel is positioned at sun-drenched outdoor, converts solar energy to direct current, the control module described in direct current is imported by electric wire.The direct current entering control module distributes through control module, flows into booster circuit or battery.The effect of control module regulates the galvanic power entering booster circuit and battery.Described booster circuit receives the DC low-voltage electricity of control module conveying, and is converted into high voltage direct current, and for the consuming parts of whole system, described consuming parts comprises compressor, water circulating pump, solution circulation pump etc.Described battery is connected with control module, for storing the unnecessary electric energy that solar energy photovoltaic panel sends.By solar energy photovoltaic panel, can convert solar energy into electrical energy as air-conditioning system of the present utility model is powered, make full use of solar energy when solar energy abundance, save home-use electricity, energy-conserving and environment-protective.

Described solar energy hot systems comprises solar vacuum heat-collecting pipe, attemperater, dehumidification heat exchange, defrost heat exchanger, water circulating pump; The delivery port of described solar vacuum heat-collecting pipe connects the water inlet of attemperater, the delivery port of attemperater is connected the water inlet of solar vacuum heat-collecting pipe with water pipe by described water circulating pump, form one is utilized solar energy heating cold water water circulation system by solar vacuum heat-collecting pipe; Dehumidification heat exchange and defrost heat exchanger is provided with in described attemperater;

Wherein, solar vacuum heat-collecting pipe, as heat-producing unit, is placed in the place of Yanguan Pass abundance.The high-temperature vapor that described solar vacuum heat-collecting pipe produces flows into attemperater by pipeline.Described attemperater skin has insulation material.Described dehumidification heat exchange, defrost heat exchanger are positioned at attemperater, are pipe heat exchanger, and exported to by the heat in attemperater with hot junction, described hot junction comprises the condenser defrosting device of air-conditioner outdoor unit and the regenerator of dehumidification system.Dehumidification heat exchange connects the regenerator of dehumidification system and provides hot water for it, and defrost heat exchanger connects the condenser defrosting device of air-conditioner outdoor unit and provides hot water for it.Water circulating pump is used for for the recirculated water of solar energy hot systems and steam provide circulation power.

Described dehumidification system comprises dehumidifier, dehumidifying fluid reservoir, dehumidification system heat exchanger, solution circulation pump, regenerator and regeneration fluid reservoir; The liquid outlet of described dehumidifier is connected with the inlet of described dehumidifying fluid reservoir, the liquid outlet of described dehumidifying fluid reservoir is connected with the dehumidifying inlet of described dehumidification system heat exchanger, and the dehumidifying liquid outlet of described dehumidification system heat exchanger connects the inlet of described dehumidifier by described solution circulation pump; The regeneration liquid outlet of described dehumidification system heat exchanger is connected with the inlet of described regenerator, the liquid outlet of described regenerator is connected with the inlet of described regeneration fluid reservoir, and the liquid outlet of described regeneration fluid reservoir regenerates inlet with described dehumidification system heat exchanger and is connected;

Described dehumidifier removes the steam in air by the mode of solution dehumidification, and is sent into by the air after dehumidifying indoor.Described dehumidifying fluid reservoir is connected with dehumidifier, stores the solution after moisture absorption.Described dehumidification system heat exchanger is connected, for exchanging the heat between hygroscopic solution and actified solution with dehumidifying fluid reservoir.Described regenerator is connected with dehumidification system heat exchanger, by the heat regeneration hygroscopic solution obtained from sun energy opto-thermal system, recovers the wettability power of solution.A described regeneration fluid reservoir is connected with regenerator, and store regenerated solution also provides the solution of wettability power of recovery solution for dehumidification system heat exchanger.

Described direct current varied-frequency air conditioner comprises indoor set and off-premises station; Indoor set is refrigeration system evaporator, provides cold wind in indoor; Described off-premises station is by DC powered;

Described control system comprises temperature controller, humidity controller and power-supply controller of electric; Described temperature controller is for controlling direct current varied-frequency air conditioner, and described humidity controller is for controlling dehumidification system, and described power-supply controller of electric is for controlling the switching of solar-electricity and civil power.

Described solar photovoltaic system and solar energy hot systems are positioned over the position of illumination abundance, and described dehumidification system and the off-premises station of direct current varied-frequency air conditioner are positioned over well-ventilated place, and described control system and the indoor set of direct current varied-frequency air conditioner are positioned at indoor.Whole system of the present utility model by solar photovoltaic system for air-conditioner and each circulating pump provide power supply, by solar energy hot systems for dehumidification system provides regeneration thermal source, for air-conditioner provides defrost thermal source, by dehumidification system conditioning chamber humidity, regulate indoor temperature by air-conditioner, control whole system by control system.System can realize utilizing solar energy to run completely, greatly saves electric energy, is applicable to the area of solar energy abundance and the area of electric energy scarcity.

Also electric heater is provided with in the attemperater of described solar energy hot systems.

The water of electric heater 9 when solar energy is not enough in heating and thermal insulation water tank, ensures that heat is enough.Water circulating pump 8 provides the power of water circulation.

The dehumidification solution of described dehumidification system is the inorganic salts aqueous solution.The described inorganic salts aqueous solution is preferably lithium chloride solution, also can bromizate lithium solution.

As shown in Figure 1, air-conditioning system of the present utility model, carry out opto-electronic conversion by solar photovoltaic system 17 and produce direct current energy, carry out photothermal deformation by solar energy hot systems 18 and produce heat energy, control system 19 receives solar DC electricity and mains electricity, solar energy hot systems 18 is outputted to through conversion, dehumidification system 21 and direct current varied-frequency air conditioner 20, output to the electric energy of solar energy hot systems 18 for driving water circulating pump 8, output to the electric energy of dehumidification system 21 for driving solution circulation pump 16, output to the electric energy of direct current varied-frequency air conditioner for driving indoor set 10 and off-premises station 11.The heat energy that solar energy hot systems 18 produces, outputs to the regeneration thermal source of dehumidification system 21 as regenerator 15, outputs to the defrost thermal source of off-premises station 11 as Winter heat supply of direct current varied-frequency air conditioner 20.The temperature that direct current varied-frequency air conditioner 20 is responsible for room air regulates, and the temperature that dehumidification system 21 is responsible for room air regulates.

As Fig. 1, described solar photovoltaic system 17 comprises solar energy photovoltaic panel 1, control module 2, battery 3, booster circuit 4.Wherein, solar energy is converted to direct current by described solar energy photovoltaic panel 1, enters control module 2.Control module 2 outputs to the power of boost module 4 according to the size adjustment of electrical power, unnecessary electricity is imported battery 3 and stores.When solar energy photovoltaic panel 1 generated output is not enough, control module 2 controls battery 3 and powers to boost module.Control module 2 passes through the power output regulating solar energy photovoltaic panel 1 and battery 3, to ensure the power stability of boost module 4.Boost module 4 promotes the galvanic voltage that control module 2 transports, and is applicable to the use of other subsystem electrical equipments.Control system is transported to by the high voltage direct current after boost module 4 boosts.

As Fig. 2, described solar energy hot systems 18 comprises solar vacuum heat-collecting pipe 5, attemperater 6, dehumidification heat exchange 7a, defrost heat exchanger 7b, water circulating pump 8; Electric heater 9 and associated pipe.Wherein solar energy is converted to heat energy by solar vacuum heat-collecting pipe 5, and the high-temperature hot water and steam of generation enters attemperater 6.In attemperater 6, dehumidification heat exchange 7a by the dehumidifier 12 of heat heat conduction dehumidification system 21, for dehumidifying; Defrost heat exchanger 7b by the off-premises station 11 of heat heat conduction direct current varied-frequency air conditioner 20, off-premises station defrost process when running for winter condition.The water of electric heater 9 when solar energy is not enough in heating and thermal insulation water tank, ensures that heat is enough.Water circulating pump 8 provides the power of water circulation.

As Fig. 3, described direct current varied-frequency air conditioner 20 comprises indoor set 10 and off-premises station 11.Direct current varied-frequency air conditioner adopts vapor-compression cycle, and summer adopts kind of refrigeration cycle, and winter, employing heated circulation.Described direct current varied-frequency air conditioner 20 is run by the DC powered direct current compressor of control system 19.Under winter condition, the heat having described solar energy optical-thermal system 18 to provide carries out defrost process to the evaporimeter of off-premises station.

As Fig. 4, described dehumidification system 21 comprises dehumidifier 12, dehumidifying fluid reservoir 13a, regeneration fluid reservoir 13b, dehumidification system heat exchanger 14, regenerator 15 and associated pipe.Dehumidification system 21 adopts the method for solution dehumidification, is controlled by control system 19, regulates indoor air humidity.The dehumidification solution of dehumidification system 21 is the inorganic salts aqueous solution.Wherein, room air is by dehumidifier 12, and moisture is absorbed by concentrated solution wherein, and humidity reduces, and gets back to indoor, completes and show process.Concentrated solution absorbs the moisture in room air, becomes weak solution, flows into dehumidifying fluid reservoir 13a.Weak solution carries out exchange heat with concentrated solution in dehumidification system heat exchanger 14, by concentrated solution preheating, then enters regenerator 15.Weak solution after preheating is heated in regenerator 15, and moisture evaporates, and is regenerated as the concentrated solution of high temperature, flows into regeneration fluid reservoir 13b.The thermal source of regenerator 15 is provided by solar energy hot systems 18.High temperature concentrated solution first preheating weak solution in dehumidification system heat exchanger 14 in regeneration fluid reservoir 13b, then spills into outdoor air by unnecessary heat, becomes normal temperature concentrated solution, send into dehumidifier 12, complete circulation via solution circulation pump 16.

As Fig. 5, described control system 19 comprises temperature controller, humidity controller and power-supply controller of electric.Wherein, the direct current that power-supply controller of electric reception solar photovoltaic system 17 transports and mains electricity, after rectification, unification is converted into direct current, is transported to the water circulating pump 8 of solar energy hot systems 18 respectively, the solution circulation pump 16 of dehumidification system 21 and direct current varied-frequency air conditioner 20.Temperature controller controls the temperature that direct current varied-frequency air conditioner 20 regulates room air, and humidity controller controls the humidity that dehumidification system 21 regulates room air.

Air-conditioning system of the present utility model provides power supply mainly through solar photovoltaic system, is responsible for the operation of direct current varied-frequency air conditioner and each circulating pump; There is provided thermal source by solar energy hot systems, be responsible for the defrost pattern of dehumidification system and direct current varied-frequency air conditioner, for the area that solar illuminating is more sufficient, the domestic air conditioner of traditional consumption civil power can be replaced.

When solar energy abundance, solar photovoltaic system provides the electric power of system cloud gray model, and by unnecessary electrical power storage in battery, and solar energy hot systems provides the heat energy of system cloud gray model and by unnecessary thermal energy storage in attemperater.Direct current varied-frequency air conditioner utilizes the electric power of solar photovoltaic system, is controlled by control system, and regulate indoor air temperature, dehumidification system utilizes the heat energy of solar energy hot systems, is controlled by control system, regulates the humidity of room air.When solar energy is not enough, regulated by control system, the heat energy of the attemperater storage of the electric energy first utilizing the battery of solar photovoltaic system to store and solar energy hot systems, when the two energy storage is also not enough, call civil power and provide electric energy, maintenance system is normally run.

The utility model system, in the sufficient area of illumination, can rely on solar energy normally to run by day completely, and store enough energy, maintain the operation at night.Even if on the insufficient area of illumination or date, the use amount of civil power also significantly can be reduced.

The comprehensive utilization solar energy optical-thermal of comprehensive utilization solar energy optical-thermal of the present utility model and photoelectric technology and the household DC frequency-conversion air-conditioning system of photoelectric technology combine solar energy power technology, photothermal technique, humiture independence regulation technology, the technology such as DC frequency-changeable compressor, greatly reduce the demand to civil power, the area not easily arrived for the sufficient area of solar energy and civil power is especially applicable.

To those skilled in the art, obvious the utility model is not limited to the details of above-mentioned one exemplary embodiment, and when not deviating from spirit of the present utility model or essential characteristic, can realize the utility model in other specific forms.Therefore, no matter from which point, all should embodiment be regarded as exemplary, and be nonrestrictive, scope of the present utility model is limited by claims instead of above-mentioned explanation, and all changes be therefore intended in the implication of the equivalency by dropping on claim and scope are included in the utility model.Any Reference numeral in claim should be considered as the claim involved by limiting.

In addition, be to be understood that, although this description is described according to embodiment, but not each embodiment only comprises an independently technical scheme, this narrating mode of description is only for clarity sake, those skilled in the art should by description integrally, and the technical scheme in each embodiment also through appropriately combined, can form other embodiments that it will be appreciated by those skilled in the art that.

Claims (3)

1. fully utilize the household DC frequency-conversion air-conditioning system of solar energy optical-thermal and photoelectric technology, it is characterized in that, comprise solar photovoltaic system, solar energy hot systems, dehumidification system, direct current varied-frequency air conditioner and control system; Solar photovoltaic system, solar energy hot systems, dehumidification system are all connected with described control system with direct current varied-frequency air conditioner, control solar photovoltaic system, solar energy hot systems, dehumidification system and direct current varied-frequency air conditioner by described control system; Solar energy hot systems is connected with dehumidification system;

Described solar photovoltaic system comprises solar energy photovoltaic panel, control module, battery and booster circuit; Described solar energy photovoltaic panel connects battery and booster circuit by control module, for providing power supply for charge in batteries with for booster circuit; Described booster circuit will be supplied to described control system after boost in voltage;

Described solar energy hot systems comprises solar vacuum heat-collecting pipe, attemperater, dehumidification heat exchange, defrost heat exchanger, water circulating pump; The delivery port of described solar vacuum heat-collecting pipe connects the water inlet of attemperater, the delivery port of attemperater is connected the water inlet of solar vacuum heat-collecting pipe with water pipe by described water circulating pump, form one is utilized solar energy heating cold water water circulation system by solar vacuum heat-collecting pipe; Dehumidification heat exchange and defrost heat exchanger is provided with in described attemperater;

Described dehumidification system comprises dehumidifier, dehumidifying fluid reservoir, dehumidification system heat exchanger, solution circulation pump, regenerator and regeneration fluid reservoir; The liquid outlet of described dehumidifier is connected with the inlet of described dehumidifying fluid reservoir, the liquid outlet of described dehumidifying fluid reservoir is connected with the dehumidifying inlet of described dehumidification system heat exchanger, and the dehumidifying liquid outlet of described dehumidification system heat exchanger connects the inlet of described dehumidifier by described solution circulation pump; The regeneration liquid outlet of described dehumidification system heat exchanger is connected with the inlet of described regenerator, the liquid outlet of described regenerator is connected with the inlet of described regeneration fluid reservoir, and the liquid outlet of described regeneration fluid reservoir regenerates inlet with described dehumidification system heat exchanger and is connected;

Described direct current varied-frequency air conditioner comprises indoor set and off-premises station; Indoor set is refrigeration system evaporator, provides cold wind in indoor; Described off-premises station is by DC powered;

Described control system comprises temperature controller, humidity controller and power-supply controller of electric; Described temperature controller is for controlling direct current varied-frequency air conditioner, and described humidity controller is for controlling dehumidification system, and described power-supply controller of electric is for controlling the switching of solar-electricity and civil power.

2. the household DC frequency-conversion air-conditioning system of comprehensive utilization solar energy optical-thermal according to claim 1 and photoelectric technology, is characterized in that, is also provided with electric heater in the attemperater of described solar energy hot systems.

3. the household DC frequency-conversion air-conditioning system of comprehensive utilization solar energy optical-thermal according to claim 1 and photoelectric technology, is characterized in that, the dehumidification solution of described dehumidification system is the inorganic salts aqueous solution.