CN204329402U - A kind of multi-energy complementation combined production device of applicable rural households - Google Patents

A kind of multi-energy complementation combined production device of applicable rural households Download PDF

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Publication number
CN204329402U
CN204329402U CN201420772026.3U CN201420772026U CN204329402U CN 204329402 U CN204329402 U CN 204329402U CN 201420772026 U CN201420772026 U CN 201420772026U CN 204329402 U CN204329402 U CN 204329402U
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China
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water
valve
heat
pump
solar
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CN201420772026.3U
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Chinese (zh)
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郭晨星
郝小礼
王海桥
刘何清
刘仙萍
代圣军
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Hunan University of Science and Technology
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Hunan University of Science and Technology
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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
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B10/00Integration of renewable energy sources in buildings
    • Y02B10/10Photovoltaic [PV]
    • 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
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B10/00Integration of renewable energy sources in buildings
    • Y02B10/20Solar thermal
    • 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
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B10/00Integration of renewable energy sources in buildings
    • Y02B10/70Hybrid systems, e.g. uninterruptible or back-up power supplies integrating renewable energies
    • 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
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B30/00Energy efficient heating, ventilation or air conditioning [HVAC]
    • Y02B30/52Heat recovery pumps, i.e. heat pump based systems or units able to transfer the thermal energy from one area of the premises or part of the facilities to a different one, improving the overall efficiency
    • 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
    • Y02E10/50Photovoltaic [PV] 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
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/60Thermal-PV hybrids
    • 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
    • Y02E50/00Technologies for the production of fuel of non-fossil origin
    • Y02E50/30Fuel from waste, e.g. synthetic alcohol or diesel

Abstract

The utility model discloses a kind of multi-energy complementation combined production device of applicable rural households, comprise solar energy power generating loop, solar water produces loop, household electricity controller, refrigerant circulation loop, heat-pump hot-water closed circuit, underground water extracts and stores path, controller, household electricity controller and solar energy power generating loop, controller is connected, household electricity controller, controller produces loop with solar water respectively, heat-pump hot-water closed circuit, refrigerant circulation loop, underground water extracts and is connected with storage path, solar water produces loop and heat-pump hot-water closed circuit, underground water extracts and is connected with storage path, refrigerant circulation loop and heat-pump hot-water closed circuit, underground water extracts and is connected with storage path.Multiple renewable energy sources and conventional energy resource organically combine by the utility model, solve the gas processed of rural households, system electricity, water processed simultaneously, freeze, heat problem.

Description

A kind of multi-energy complementation combined production device of applicable rural households
Technical field
The utility model relates to energy-saving building technology field, particularly a kind of multi-energy complementation combined production device of applicable rural households.
Background technology
Although China is energy big country, owning amount is little per capita.Along with China's expanding economy, for the demand of the energy also in continuous increase.But energy resources are limited after all, when Ecological Civilization Construction includes five in one in, stand in the height of Chinese nation's Sustainable Development, necessary energy-saving and emission-reduction, realize resources circulation comprehensive utilization, realize reducing the wasting of resources, reduce the effects of energy conservation and environmental protection of energy consumption, and the utilization of new and renewable sources of energy, be conducive to the adjustment promoting China's energy resource structure.In China, rural area energy consumption occupies very large ratio in social total energy consumption, and rural households have various energy resources demand, solves the energy consumption problem of rural households, significant to the energy-saving and emission-reduction of promotion China.
At present, a lot of discarded biomass energy is had to utilize in China rural area, the ight soil, stalk etc. of such as livestock.Not only can utilize these biomass energies by methane-generating pit, but also can rural environment be improved.In the summer that temperature is higher, the air-conditioning of rural households but usually can not start because of brownout, and summer high temperature season, is just in time again solar energy the abundantest season, utilizes solar electrical energy generation effectively can evade peak of power consumption.Meanwhile, when summer temperature is higher, be also biogas output maximum time, except meeting family life needs, also have biogas superfluous, unnecessary marsh gas power generation can be utilized, for family provides electric energy.The domestic water of rural households is generally that and underground water has feature cool in summer and warm in winter by well-digging groundwater abstraction, utilize underground water as air-conditioning low-temperature receiver in summer and winter thermal source, the geothermal energy that can effectively utilize underground water to have, reduces air conditioning energy consumption.
Summary of the invention
In order to solve the problems of the technologies described above, the utility model provides one multiple renewable energy sources and conventional energy resource can be organically combined, and solves the multi-energy complementation being suitable for rural households hot and cold, electric, water, the gas combined production device of gas processed, system electricity, water processed, various problems of freezing, to heat etc.
The technical scheme that the utility model solves the problem is: a kind of multi-energy complementation combined production device of applicable rural households, comprises solar energy power generating loop, solar water produces loop, household electricity controller, refrigerant circulation loop, heat-pump hot-water closed circuit, underground water extracts and stores path, controller, household electricity controller respectively with solar energy power generating loop, solar water produces loop, heat-pump hot-water closed circuit, refrigerant circulation loop, underground water extracts and is connected with storage path, and solar energy power generating loop and solar water are produced loop and be connected, and solar water produces loop and heat-pump hot-water closed circuit, underground water extract with storage path be connected, refrigerant circulation loop respectively with heat-pump hot-water closed circuit, underground water extracts and is connected with storage path, and described controller produces loop with solar water respectively, household electricity controller, refrigerant circulation loop, heat-pump hot-water closed circuit, underground water extracts and is connected with storage path.
In the multi-energy complementation combined production device of above-mentioned applicable rural households, described solar energy power generating loop comprises photovoltaic and photothermal integral type solar panel, anti-reverse charging diode, DC/AC inverter, described photovoltaic and photothermal integral type solar panel, anti-reverse charging diode, DC/AC inverter is connected in series successively, DC/AC inverter is connected with household electricity controller, described household electricity controller is connected with electrical network through electric energy meter, household electricity controller is connected with other household electricity utensils by power cable, tapping pipe is also equipped with in the bottom of photovoltaic and photothermal integral type solar panel, tapping pipe is equipped with discharging valve.
In the multi-energy complementation combined production device of above-mentioned applicable rural households, described solar water is produced loop and is comprised heat preservation hot water tank, solar heat water-circulating pump, solar water supply pipe, solar energy return pipe, solar panel water supply shut-off valve and solar panel backwater shut-off valve, the two ends of described solar water supply pipe connect heat preservation hot water tank and photovoltaic and photothermal integral type solar panel respectively, solar heat water-circulating pump is arranged on solar water supply pipe, solar heat water-circulating pump respectively with household electricity controller, controller is connected, solar water supply pipe between heat preservation hot water tank and solar heat water-circulating pump is provided with solar panel water supply shut-off valve, the two ends of described solar energy return pipe connect heat preservation hot water tank and photovoltaic and photothermal integral type solar panel respectively, solar energy return pipe is provided with solar panel backwater shut-off valve, described heat preservation hot water tank is connected with family life water heater by domestic hot-water's feed pipe, described domestic hot-water's feed pipe is equipped with hot-water switch valve.
In the multi-energy complementation combined production device of above-mentioned applicable rural households, high water level meter, low water level meter described heat preservation hot water tank be equipped with, high water level meter, low water level meter are connected with controller, heat preservation hot water tank has passage, be provided with electric heating device in heat preservation hot water tank, electric heating device is connected with household electricity controller, controller respectively.
In the multi-energy complementation combined production device of above-mentioned applicable rural households, described underground water extracts and stores path and comprises underground water well, well water pump, well water plate type heat exchanger, electric T-shaped valve, non-tower water feeder, storage cistern, described electric T-shaped valve contains e, f, g tri-interfaces, described underground water well, well water pump, well water plate type heat exchanger is connected successively by pipeline, well water pump respectively with household electricity controller, controller is connected, and the outlet pipe of well water plate type heat exchanger is connected to the e interface of electric T-shaped valve again by pipeline, described non-tower water feeder and storage cistern by pipeline respectively with the f of electric T-shaped valve, g interface is connected, described non-tower water feeder is connected with heat preservation hot water tank by heat preservation hot water tank filling pipe, heat preservation hot water tank filling pipe is provided with boiler moisturizing magnetic valve, non-tower water feeder is connected with family life cold water apparatus by life cold water supplying pipe, cold water switch valve life cold water supplying pipe is equipped with, described electric T-shaped valve, boiler moisturizing magnetic valve is connected with controller respectively, described non-tower water feeder is also equipped with high pressure sensor and low pressure sensor, high pressure sensor, low pressure sensor is connected with controller respectively, and miscellaneous water feed pipe is equipped with in the bottom of storage cistern, miscellaneous water feed pipe is equipped with miscellaneous water switch valve.
In the multi-energy complementation combined production device of above-mentioned applicable rural households, described refrigerant circulation loop comprises compressor of air conditioner, four-way change-over valve, first expansion valve, first check valve, second expansion valve, second check valve, air-conditioning indoor heat exchanger, hot water plate type heat exchanger, hot water circuit magnetic valve, Air-conditioning Cycle magnetic valve, described four-way change-over valve comprises a, b, c, d tetra-interfaces, one end of described Air-conditioning Cycle magnetic valve is connected with the b interface of four-way change-over valve by refrigerant tubing, the other end of Air-conditioning Cycle magnetic valve, air-conditioning indoor heat exchanger, second expansion valve, first expansion valve, be connected with the c interface of four-way change-over valve after well water plate type heat exchanger is connected in series successively, described hot water plate type heat exchanger, the first branch road that hot water circuit magnetic valve serial connection is formed and Air-conditioning Cycle magnetic valve, the second branch road that air-conditioning indoor heat exchanger serial connection is formed also connects, and air-conditioning indoor heat exchanger is equipped with air-conditioning draught fan, and described first check valve is attempted by the first expansion valve two ends, and the second check valve is attempted by the second expansion valve two ends, the air entry of described compressor of air conditioner, exhaust outlet by refrigerant tubing respectively with four-way change-over valve d, a two interface be connected, described compressor of air conditioner, four-way change-over valve, air-conditioning draught fan, hot water circuit magnetic valve, Air-conditioning Cycle magnetic valve are connected with controller respectively, and described compressor of air conditioner, air-conditioning draught fan are connected with household electricity controller respectively.
In the multi-energy complementation combined production device of above-mentioned applicable rural households, described first check valve is contrary with the flow direction of the second check valve, and wherein the refrigerant flow direction of the first check valve is for flow to air-conditioning indoor heat exchanger or hot water plate type heat exchanger by well water plate type heat exchanger.
In the multi-energy complementation combined production device of above-mentioned applicable rural households, described heat-pump hot-water closed circuit comprises heat-pump hot-water circulating pump, heat pump feed pipe, heat pump return pipe, heat pump water supply shut-off valve, heat pump backwater shut-off valve, the two ends of described heat pump feed pipe connect the water inlet of heat preservation hot water tank and hot water plate type heat exchanger respectively, heat-pump hot-water circulating pump is arranged on heat pump feed pipe, heat pump feed pipe between heat-pump hot-water circulating pump and heat preservation hot water tank is provided with heat pump water supply shut-off valve, the two ends of described heat pump return pipe connect the delivery port of heat preservation hot water tank and hot water plate type heat exchanger respectively, heat pump return pipe is provided with heat pump backwater shut-off valve, described heat-pump hot-water circulating pump respectively with household electricity controller, controller is connected.
The multi-energy complementation combined production device of above-mentioned applicable rural households also comprises biogas utilization loop, described biogas utilization loop comprises methane-generating pit, biogas fairlead and biogas generator, biogas fairlead is equipped with on the top of described methane-generating pit, and biogas fairlead is divided into cooking biogas pipe and generating biogas pipe in methane-generating pit outside; Described cooking biogas pipe is directly connected with family cooking utensils, cooking methane pipeline is equipped with cooking biogas switch valve; Described generating biogas pipe is connected with biogas generator, and biogas generator is connected with household electricity controller by power cable, and described generating biogas pipe is equipped with generating biogas switch valve.
The multi-energy complementation combined production device of above-mentioned applicable rural households also comprises battery and AC/DC inverter, and described battery is connected with the input of AC/DC inverter, and the output of AC/DC inverter is connected with household electricity controller.
The beneficial effects of the utility model are:
1) multiple renewable energy sources and conventional energy resource can organically combine by the utility model, provide multiple forms of energy to complement each other, and various problems such as solving gas processed, system electricity, water processed simultaneously, freeze, heat, has saved the energy, protected environment;
2) unnecessary biogas is used for generating and combines with solar electrical energy generation by biogas utilization loop of the present utility model, improves generating capacity and the power supply reliability of whole device;
3) the utility model will can combine with geothermal energy heat pump water heating by water heating very much, improves the reliability of hot water supply;
4) the utility model feature of utilizing underground water cool in summer and warm in winter, underground water is used as air-conditioning low-temperature receiver in summer and winter thermal source, realize the multi-functional utilization of groundwater resources, improve the service efficiency of resource, while improve air-conditioning effect, reduce air conditioning energy consumption;
5) the utility model is applicable to the rural households with power supply, water supply, air feed, cooling, heat demand, is particularly useful for the rural area that solar radiation is relatively abundanter, underground water is sufficient, penkeeping is many.
Accompanying drawing explanation
Fig. 1 is structural representation of the present utility model.
Fig. 2 is the structural representation that the utility model performs air conditioner refrigerating+solar energy hot water running pattern.
Fig. 3 is the structural representation that the utility model performs heat pump water heating operational mode.
Fig. 4 is the structural representation that the utility model performs air-conditioning heating+solar energy hot water running pattern.
Fig. 5 is the structural representation that the utility model performs solar energy hot water running pattern.
In figure: photovoltaic and photothermal integral type solar panel 1, anti-reverse charging diode 2, DC/AC inverter 3, battery 4, methane-generating pit 5, biogas generator 6, household electricity controller 7, electrical network 8, compressor of air conditioner 9, four-way change-over valve 10, well water plate type heat exchanger 11, first expansion valve 12, air-conditioning indoor heat exchanger 13, hot water plate type heat exchanger 14, well water pump 15, storage cistern 16, boiler moisturizing magnetic valve 17, non-tower water feeder 18, heat preservation hot water tank 19, heat-pump hot-water circulating pump 20, underground water well 21, AC/DC inverter 22, electric energy meter 23, controller 24, electric T-shaped valve 25, hot water circuit magnetic valve 26, Air-conditioning Cycle magnetic valve 27, air-conditioning draught fan 28, first check valve 29, second expansion valve 30, second check valve 31, solar heat water-circulating pump 32, cooking biogas switch valve 33, generating biogas switch valve 34, hot-water switch valve 35, cold water switch valve 36, miscellaneous water switch valve 37, high water level meter 38, low water level meter 39, high pressure sensor 40, low pressure sensor 41, solar panel water supply shut-off valve 42, solar panel backwater shut-off valve 43, heat pump water supply shut-off valve 44, heat pump backwater shut-off valve 45, discharging valve 46, tapping pipe 47, miscellaneous water feed pipe 48, heat pump feed pipe 49, heat pump return pipe 50, electric heating device 51, solar water supply pipe 52, solar energy return pipe 53, cooking biogas pipe 54, generating biogas pipe 55, domestic hot-water's feed pipe 56, life cold water supplying pipe 57, biogas fairlead 58, passage 59, control circuit 60, power cable 61, heat preservation hot water tank filling pipe 62.
Detailed description of the invention
Below in conjunction with drawings and Examples, the utility model is further described.
As shown in Figure 1, the utility model comprises solar energy power generating loop, solar water produces loop, household electricity controller 7, refrigerant circulation loop, heat-pump hot-water closed circuit, underground water extracts and stores path, biogas utilization loop, controller 24, battery 4 and AC/DC inverter 22, described battery 4 is connected with the input of AC/DC inverter 22, and the output of AC/DC inverter 22 is connected with household electricity controller 7, household electricity controller 7 respectively with solar energy power generating loop, solar water produces loop, heat-pump hot-water closed circuit, refrigerant circulation loop, underground water extracts and is connected with storage path, and solar energy power generating loop and solar water are produced loop and be connected, and solar water produces loop and heat-pump hot-water closed circuit, underground water extract with storage path be connected, refrigerant circulation loop respectively with heat-pump hot-water closed circuit, underground water extracts and is connected with storage path, and described controller 24 produces loop with solar water respectively, household electricity controller 7, refrigerant circulation loop, heat-pump hot-water closed circuit, underground water extracts and is connected with storage path.
Described solar energy power generating loop comprises photovoltaic and photothermal integral type solar panel 1, anti-reverse charging diode 2, DC/AC inverter 3, described photovoltaic and photothermal integral type solar panel 1, anti-reverse charging diode 2, DC/AC inverter 3 is connected in series successively, DC/AC inverter 3 is connected with household electricity controller 7, described household electricity controller 7 is connected with electrical network 8 through electric energy meter 23, tapping pipe 47 is also equipped with in the bottom of photovoltaic and photothermal integral type solar panel 1, tapping pipe 47 is equipped with discharging valve 46, for the winter in severe cold, water in emptying photovoltaic and photothermal integral type solar panel 1, play the effect of preventing freeze in winter.
Described solar water is produced loop and is comprised heat preservation hot water tank 19, solar heat water-circulating pump 32, solar water supply pipe 52, solar energy return pipe 53, solar panel water supply shut-off valve 42 and solar panel backwater shut-off valve 43, the two ends of described solar water supply pipe 52 connect heat preservation hot water tank 19 and photovoltaic and photothermal integral type solar panel 1 respectively, solar heat water-circulating pump 32 is arranged on solar water supply pipe 52, solar heat water-circulating pump 32 respectively with household electricity controller 7, controller 24 is connected, solar water supply pipe 52 between heat preservation hot water tank 19 and solar heat water-circulating pump 32 is provided with solar panel water supply shut-off valve 42, the two ends of described solar energy return pipe 53 connect heat preservation hot water tank 19 and photovoltaic and photothermal integral type solar panel 1 respectively, solar energy return pipe 53 is provided with solar panel backwater shut-off valve 43, for when the circulation of photovoltaic and photothermal integral type solar panel 1 water heating does not work, cut off the current between heat preservation hot water tank 19 and photovoltaic and photothermal integral type solar panel 1, described heat preservation hot water tank 19 is connected with family life water heater by domestic hot-water's feed pipe 56, realizes the supply of family life hot water, domestic hot-water's feed pipe 56 is equipped with hot-water switch valve 35.
Described underground water extracts and stores path and is used for realizing underground water extraction, utilize and memory function, it comprises underground water well 21, well water pump 15, well water plate type heat exchanger 11, electric T-shaped valve 25, non-tower water feeder 18, storage cistern 16, described electric T-shaped valve 25 is containing e, f, g tri-interfaces, described underground water well 21, well water pump 15, well water plate type heat exchanger 11 is connected successively by pipeline, well water pump 15 respectively with household electricity controller 7, controller 24 is connected, the outlet pipe of well water plate type heat exchanger 11 is connected to the e interface of electric T-shaped valve 25 again by pipeline, non-tower water feeder 18 is for having the closed container of bearing capacity, what can store some has pressure household water, described non-tower water feeder 18 and storage cistern 16 by pipeline respectively with the f of electric T-shaped valve 25, g interface is connected, described non-tower water feeder 18 is connected with heat preservation hot water tank 19 by heat preservation hot water tank filling pipe 62, realize heat preservation hot water tank 19 moisturizing, heat preservation hot water tank filling pipe 62 is provided with boiler moisturizing magnetic valve 17, non-tower water feeder 18 is connected with family life cold water apparatus by life cold water supplying pipe 57, for family provides life cold water, cold water switch valve 36 life cold water supplying pipe 57 is equipped with, described electric T-shaped valve 25, boiler moisturizing magnetic valve 17 is connected with controller 24 respectively, high pressure sensor 40 and low pressure sensor 41 described non-tower water feeder 18 be also equipped with, high pressure sensor 40, low pressure sensor 41 is connected with controller 24 respectively, high pressure sensor 40, low pressure sensor 41 is for detecting the height of hydraulic pressure in non-tower water feeder 18, hydraulic pressure in non-tower water feeder 18 can fluctuate between high pressure sensor 40 and the setting value of low pressure sensor 41, when the setting value of the hydraulic pressure in non-tower water feeder 18 lower than low pressure sensor 41, the e of electric T-shaped valve 25, UNICOM between f two-port, e, g two-port is separated, by well water pump 15 to non-tower water feeder 18 water storage, when the setting value of the hydraulic pressure in non-tower water feeder 18 higher than high pressure sensor 40, the e of electric T-shaped valve 25, f two-port is separated, e, UNICOM between g two-port, stop to non-tower water feeder 18 water storage, unnecessary well water is stored in storage cistern 16, storage cistern 16 is open type tank, and for storing unnecessary well water, miscellaneous water feed pipe 48 is equipped with in the bottom of storage cistern 16, can be family and provides the miscellaneous waters such as pouring, cleaning, animals drinking-water, miscellaneous water feed pipe 48 is equipped with miscellaneous water switch valve 37, high water level meter 38, low water level meter 39 described heat preservation hot water tank 19 be equipped with, high water level meter 38, low water level meter 39 are connected with controller 24, for detecting the height of water level in heat preservation hot water tank 19, when the water level of water level in heat preservation hot water tank 19 lower than low water level meter 39 place, boiler moisturizing magnetic valve 17 opened by controller 24, be heat preservation hot water tank 19 moisturizing by non-tower water feeder 18, when the water level of water level in heat preservation hot water tank 19 higher than high water level meter 38 place, controller 24 cuts out boiler moisturizing magnetic valve 17, stops moisturizing, heat preservation hot water tank 19 has passage 59, electric heating device 51 is provided with in heat preservation hot water tank 19, electric heating device 51 is connected with household electricity controller 7, controller 24 respectively, can not work in solar heat water circulation, heat-pump hot-water circulation, or when quantity of heat production is inadequate, hot water preparing can be carried out by electrical heating.
Described refrigerant circulation loop comprises compressor of air conditioner 9, four-way change-over valve 10, first expansion valve 12, first check valve 29, second expansion valve 30, second check valve 31, air-conditioning indoor heat exchanger 13, hot water plate type heat exchanger 14, hot water circuit magnetic valve 26, Air-conditioning Cycle magnetic valve 27, described four-way change-over valve 10 comprises a, b, c, d tetra-interfaces, one end of described Air-conditioning Cycle magnetic valve 27 is connected with the b interface of four-way change-over valve 10 by refrigerant tubing, the other end of Air-conditioning Cycle magnetic valve 27, air-conditioning indoor heat exchanger 13, second expansion valve 30, first expansion valve 12, be connected with the c interface of four-way change-over valve 10 after well water plate type heat exchanger 11 is connected in series successively, described hot water plate type heat exchanger 14, hot water circuit magnetic valve 26 is connected in series the first branch road and Air-conditioning Cycle magnetic valve 27 that form, air-conditioning indoor heat exchanger 13 is connected in series the second branch road of formation and connects, by hot water circuit magnetic valve 26, the open and close of these two magnetic valves of Air-conditioning Cycle magnetic valve 27, realize air conditioning operating mode and heat-pump hot-water operational mode respectively, air-conditioning indoor heat exchanger 13 is equipped with air-conditioning draught fan 28, drives room air to flow through heat exchanger 13 in air conditioning chamber by air-conditioning draught fan 28, (summer) or heating (winter) are cooled to room air, realizes the cooling in summer to building, winter heating, described first check valve 29 is attempted by the first expansion valve 12 two ends, second check valve 31 is attempted by the second expansion valve 30 two ends, described first check valve 29 is contrary with the flow direction of the second check valve 31, and wherein the refrigerant flow direction of the first check valve 29 is for flow to air-conditioning indoor heat exchanger 13 or hot water plate type heat exchanger 14 by well water plate type heat exchanger 11, the air entry of described compressor of air conditioner 9, exhaust outlet by refrigerant tubing respectively with four-way change-over valve 10 d, a two interface be connected, described compressor of air conditioner 9, four-way change-over valve 10, air-conditioning draught fan 28, hot water circuit magnetic valve 26, Air-conditioning Cycle magnetic valve 27 are connected with controller 24 respectively, and described compressor of air conditioner 9, air-conditioning draught fan 28 are connected with household electricity controller 7 respectively.
Described heat-pump hot-water closed circuit is used for can not working when solar heat water circulation, or when solar heat water circulation quantity of heat production is inadequate, domestic hot-water is produced by heat pump cycle, it comprises heat-pump hot-water circulating pump 20, heat pump feed pipe 49, heat pump return pipe 50, heat pump water supply shut-off valve 44, heat pump backwater shut-off valve 45, the two ends of described heat pump feed pipe 49 connect the water inlet of heat preservation hot water tank 19 and hot water plate type heat exchanger 14 respectively, heat-pump hot-water circulating pump 20 is arranged on heat pump feed pipe 49, heat pump feed pipe 49 between heat-pump hot-water circulating pump 20 and heat preservation hot water tank 19 is provided with heat pump water supply shut-off valve 44, the two ends of described heat pump return pipe 50 connect the delivery port of heat preservation hot water tank 19 and hot water plate type heat exchanger 14 respectively, heat pump return pipe 50 is provided with heat pump backwater shut-off valve 45, for when heat-pump hot-water circulation does not work, cut off current, described heat-pump hot-water circulating pump 20 is connected with household electricity controller 7, controller 24 respectively.
Described biogas utilization loop comprises methane-generating pit 5, biogas fairlead 58 and biogas generator 6, biogas fairlead 58 is equipped with on the top of described methane-generating pit 5, methane-generating pit 5 utilizes family's organic waste to produce biogas, the biogas storage produced is on the top of methane-generating pit 5, when using biogas, drawn from methane-generating pit 5 top by biogas fairlead 58, biogas fairlead 58 is divided into cooking biogas pipe 54 and generating biogas pipe 55 in methane-generating pit 5 outside; Described cooking biogas pipe 54 is directly connected with family cooking utensils, for family provides cooking gas, cooking biogas pipe 54 is equipped with cooking biogas switch valve 33, for controlling family's cooking gas; Described generating biogas pipe 55 is connected with biogas generator 6, unnecessary biogas is utilized to be generated electricity by biogas generator 6, biogas generator 6 is connected with household electricity controller 7 by power cable 61, household electricity controller 7 using according to household electricity demand modeling biogas generator 6 electricities and storing, described generating biogas pipe 55 is equipped with generating biogas switch valve 34, controls biogas generator 6 and to generate electricity use gas.
Described household electricity controller 7 realizes producing home electrical, use and the scheduling that stores and management, household electricity controller 7 is connected with solar energy power generating loop, biogas generator 6, electrical network 8, battery 4 by power cable 61, when solar energy power generating, marsh gas power generation, and battery electric power storage is when can not meet household electricity demand, household electricity controller 7 is input electric power from electrical network 8, on the circuit that family's dsm controller 7 is connected with electrical network 8, electric energy meter 23 is installed, to realize electric power input metering; When solar energy power generating, electric power that marsh gas power generation produces are greater than the instant need for electricity of family, unnecessary electric power is stored by battery 4, described battery 4, AC/DC inverter 22, household electricity controller 7 are connected successively by power cable 61, realize the storage to excrescent electric power, when generating capacity can not meet household electricity demand, the electric energy inversion stored in battery 4 can be returned again by household electricity controller 7, for household use.Household electricity controller 7 is connected with compressor of air conditioner 9, well water pump 15, heat-pump hot-water circulating pump 20, solar heat water-circulating pump 32, air-conditioning draught fan 28, electric heating device 51, controller 24 by power cable 61, meet the electricity needs of this device self, simultaneously, household electricity controller 7 is also connected with other household electricity equipment by power cable 61, meets other daily need for electricity of family.
Described controller 24 is connected with compressor of air conditioner 9, well water pump 15, heat-pump hot-water circulating pump 20, solar heat water-circulating pump 32, air-conditioning draught fan 28, electric heating device 51, four-way change-over valve 10, boiler moisturizing magnetic valve 17, electric T-shaped valve 25, hot water circuit magnetic valve 26, Air-conditioning Cycle magnetic valve 27, high water level meter 38, low water level meter 39, high pressure sensor 40, low pressure sensor 41 by control circuit 60, realizes the train operation control and management to these equipment.
The utility model according to home-use energy demand and meteorological condition, can run following four kinds of different operational modes:
Operational mode one: air conditioner refrigerating+solar energy hot water running pattern:
The embodiment of air conditioner refrigerating+solar energy hot water running pattern as shown in Figure 2.In this operating mode, first expansion valve 12, hot water circuit magnetic valve 26, second check valve 31, heat pump water supply shut-off valve 44, heat pump backwater shut-off valve 45 are all in closed condition, hot water plate type heat exchanger 14, heat-pump hot-water circulating pump 20 quit work, and remaining part normally runs.
In this operating mode, be connected by refrigerant tubing by compressor of air conditioner 9, four-way change-over valve 10, well water plate type heat exchanger 11, first check valve 29, second expansion valve 30, air-conditioning indoor heat exchanger 13, Air-conditioning Cycle magnetic valve 27, composition refrigerant circulation loop, realizes air conditioner refrigerating circulation.Wherein, air-conditioning indoor heat exchanger 13 serves as the effect of evaporimeter, and under air-conditioning draught fan 28 acts on, send cold wind, be cooling in air conditioning chamber, maintains the temperature that air-conditioned room is lower; Well water plate type heat exchanger 11 serves as the effect of condenser, and heat kind of refrigeration cycle produced by it is entered in the underground water flowing through well water plate type heat exchanger 11.In this operational mode, the a interface of four-way change-over valve 10 is connected with the exhaust outlet of compressor of air conditioner 9, the d interface of four-way change-over valve 10 is connected with the air entry of compressor of air conditioner 9, the c interface of four-way change-over valve 10 is connected with well water plate type heat exchanger 11, and the b interface of four-way change-over valve 10 is connected with air-conditioning indoor heat exchanger 13.From the low-temperature low-pressure refrigerant steam of air-conditioning indoor heat exchanger 13 through refrigerant tubing, flow through Air-conditioning Cycle magnetic valve 27, four-way change-over valve 10 is flowed into again afterwards by the d interface of four-way change-over valve 10, b interface again through four-way change-over valve 10 flows out, sucked by compressor of air conditioner 9 afterwards, heated up by compression in compressor of air conditioner 9, the refrigerant vapour of HTHP is discharged through the exhaust outlet of compressor of air conditioner 9, four-way change-over valve 10 is entered again by a interface of four-way change-over valve 10, thereafter flow out from the c interface of four-way change-over valve 10 again, enter well water plate type heat exchanger 11 again, highly pressurised liquid is condensed in well water plate type heat exchanger 11, after condensed high pressure liquid refrigerant flows through the first check valve 29, low temperature is become after the second expansion valve 30 reducing pressure by regulating flow, the cold-producing medium that the gas-liquid two-phase of low pressure coexists, the last air-conditioning of inflow again indoor heat exchanger 13, continue to absorb heat from room, complete kind of refrigeration cycle.
This operational mode is applicable to the weather having sunlight summer, and temperature higher, need to open the situation of air-conditioning, in this operational mode, utilize solar energy to produce domestic hot-water, the embodiment that solar energy produces domestic hot-water is identical with operational mode four.When solar energy is not enough, the water can opened in electric heating device 51 pairs of heat preservation hot water tanks 19 heats, or when air-conditioning does not need to open, operating heat pump water heating operational mode, the embodiment that domestic hot-water produced by heat pump is identical with operational mode two.
Operational mode two: heat pump water heating operational mode:
As shown in Figure 3, this operational mode is applicable to the weather not having sunlight to the embodiment of heat pump water heating operational mode, and air-conditioning does not need the situation of unlatching.In this operating mode, air-conditioning indoor heat exchanger 13, air-conditioning draught fan 28, solar heat water-circulating pump 32 are out of service, Air-conditioning Cycle magnetic valve 27, first check valve 29, second expansion valve 30, solar panel water supply shut-off valve 42, solar panel backwater shut-off valve 43 are in closed condition, and remaining part normally runs.
In this operating mode, be connected by refrigerant tubing by compressor of air conditioner 9, four-way change-over valve 10, well water plate type heat exchanger 11, first expansion valve 12, second check valve 31, hot water plate type heat exchanger 14, hot water circuit magnetic valve 26, composition refrigerant circulation loop, realizes heat pump and heats circulation.Wherein, well water plate type heat exchanger 11 serves as the effect of evaporimeter, absorbs heat from the underground water flowing through well water plate type heat exchanger 11; Hot water plate type heat exchanger 14 serves as the effect of condenser, and the heat produced by heat pump cycle by it puts into the recirculated water flowing through hot water plate type heat exchanger 14, heats recirculated water.In this operational mode, the a interface of four-way change-over valve 10 is connected with the exhaust outlet of compressor of air conditioner 9, the d interface of four-way change-over valve 10 is connected with the air entry of compressor of air conditioner 9, the c interface of four-way change-over valve 10 is connected with well water plate type heat exchanger 11, and the b interface of four-way change-over valve 10 is connected with hot water plate type heat exchanger 14.From the low-temperature low-pressure refrigerant steam of well water plate type heat exchanger 11 through refrigerant tubing, four-way change-over valve 10 is flowed into from the c interface of four-way change-over valve 10, d interface again through four-way change-over valve 10 flows out, sucked by compressor of air conditioner 9 afterwards, heated up by compression in compressor of air conditioner 9, the refrigerant vapour of HTHP is discharged through the exhaust outlet of compressor of air conditioner 9, four-way change-over valve 10 is entered again by a interface of four-way change-over valve 10, thereafter flow out from the b interface of four-way change-over valve 10 again, enter hot water plate type heat exchanger 14 again, heat is released in hot water plate type heat exchanger 14, cold-producing medium is condensed into highly pressurised liquid, after condensed high pressure liquid refrigerant flows through the second check valve 31, low temperature is become after the first expansion valve 12 reducing pressure by regulating flow, the cold-producing medium that the gas-liquid two-phase of low pressure coexists, the last well water of inflow again plate type heat exchanger 11, continue the underground water heat absorption from flowing through in well water plate type heat exchanger 11, complete heat pump and heat circulation.
In this operational mode, photovoltaic and photothermal integral type solar panel 1, solar heat water-circulating pump 32 quit work, solar panel water supply shut-off valve 42, solar panel backwater shut-off valve 43 are closed, and heat pump water supply shut-off valve 44, heat pump backwater shut-off valve 45 are opened, and heat-pump hot-water circulating pump 20 runs.The water drawn in heat preservation hot water tank 19 taken out by heat-pump hot-water circulating pump 20, hot water plate type heat exchanger 14 is sent into by heat pump feed pipe 49, the heat of high-temperature gas cold-producing medium is absorbed in hot water plate type heat exchanger 14, temperature raises, hot water after intensification flows back to heat preservation hot water tank 19 through heat pump return pipe 50, iterative cycles like this, until the water temperature in heat preservation hot water tank 19 reaches the water temperature of setting, heat pump is out of service.When heat pump heating capacity is inadequate, the water also can opened in electric heating device 51 pairs of heat preservation hot water tanks 19 heats.
Operational mode three: air-conditioning heating+solar energy hot water running pattern:
The embodiment of air-conditioning heating+solar energy hot water running pattern as shown in Figure 4.In this operating mode, second expansion valve 30, hot water circuit magnetic valve 26, first check valve 29, heat pump water supply shut-off valve 44, heat pump backwater shut-off valve 45 are all in closed condition, hot water plate type heat exchanger 14, heat-pump hot-water circulating pump 20 quit work, and remaining part normally runs.
In this operating mode, be connected by refrigerant tubing by compressor of air conditioner 9, four-way change-over valve 10, well water plate type heat exchanger 11, first expansion valve 12, second check valve 31, air-conditioning indoor heat exchanger 13, Air-conditioning Cycle magnetic valve 27, composition refrigerant circulation loop, realizes air-conditioning heating circulation.Wherein, well water plate type heat exchanger 11 serves as the effect of evaporimeter, absorbs heat from the underground water flowing through well water plate type heat exchanger 11; Air-conditioning indoor heat exchanger 13 serves as the effect of condenser, and under air-conditioning draught fan 28 acts on, send hot blast, be air-conditioning indoor heating, maintains the temperature that air-conditioned room is higher; In this operational mode, the a interface of four-way change-over valve 10 is connected with the exhaust outlet of compressor of air conditioner 9, the d interface of four-way change-over valve 10 is connected with the air entry of compressor of air conditioner 9, the c interface of four-way change-over valve 10 is connected with well water plate type heat exchanger 11, and the b interface of four-way change-over valve 10 is connected with air-conditioning indoor heat exchanger 13.From the low-temperature low-pressure refrigerant steam of well water plate type heat exchanger 11 through refrigerant tubing, four-way change-over valve 10 is flowed into from the c interface of four-way change-over valve 10, d interface again through four-way change-over valve 10 flows out, sucked by compressor of air conditioner 9 afterwards, heated up by compression in compressor of air conditioner 9, the refrigerant vapour of HTHP is discharged through the exhaust outlet of compressor of air conditioner 9, four-way change-over valve 10 is entered again by a interface of four-way change-over valve 10, thereafter flow out from the b interface of four-way change-over valve 10 again, enter air-conditioning indoor heat exchanger 13 again, heat is released in air-conditioning indoor heat exchanger 13, cold-producing medium is condensed into highly pressurised liquid, after condensed high pressure liquid refrigerant flows through the second check valve 31, low temperature is become after the first expansion valve 12 reducing pressure by regulating flow, the cold-producing medium that the gas-liquid two-phase of low pressure coexists, the last well water of inflow again plate type heat exchanger 11, continue the underground water heat absorption from flowing through in well water plate type heat exchanger 11, complete air-conditioning heating circulation.
This operational mode is applicable to the weather having sunlight winter, and temperature lower, need to open the situation of air-conditioning heating, in this operational mode, utilize solar energy to produce domestic hot-water, the embodiment that solar energy produces domestic hot-water is identical with operational mode four.When solar energy is not enough, the water can opened in electric heating device 51 pairs of heat preservation hot water tanks 19 heats, or when air-conditioning does not need to open, operating heat pump water heating operational mode, the embodiment that domestic hot-water produced by heat pump is identical with operational mode two.
Operational mode four: solar energy hot water running pattern:
Fig. 5 shows the embodiment of solar energy hot water running pattern, and this operational mode is applicable to the weather of sunlight, and air-conditioning does not need the situation of unlatching.In this mode, compressor of air conditioner 9, four-way change-over valve 10, first expansion valve 12, air-conditioning indoor heat exchanger 13, hot water plate type heat exchanger 14, heat-pump hot-water circulating pump 20, hot water circuit magnetic valve 26, Air-conditioning Cycle magnetic valve 27, air-conditioning draught fan 28, first check valve 29, second expansion valve 30, second check valve 31 all quit work, heat pump water supply shut-off valve 44, heat pump backwater shut-off valve 45 are in closed condition, and remaining part normally runs.
In this operational mode, solar energy is utilized to produce domestic hot-water.Solar heat water-circulating pump 32 takes out the water drawn in heat preservation hot water tank 19, send in photovoltaic and photothermal integral type solar panel 1 through solar water supply pipe 52, photovoltaic and photothermal integral type solar panel 1 receives sunlight, convert part solar energy to heat energy, the current flowing through photovoltaic and photothermal integral type solar panel 1 are heated, current after heating flow back to heat preservation hot water tank 19 through solar energy return pipe 53, so repeatedly, heat the water storage in heat preservation hot water tank 19.When solar energy is not enough, the water can opening electric heating device 51 pairs of heat preservation hot water tanks 19 heats, or when air-conditioning does not need to open, operating heat pump water heating operational mode, the embodiment that domestic hot-water produced by heat pump is identical with operational mode two.
Above content described in this description is only illustrating of doing the utility model structure.The various amendments that specific embodiments described by the utility model is made are supplemented; or adopt similar mode to replace; only otherwise depart from structure of the present utility model, or do not surmount this scope as defined in the claims, protection domain of the present utility model all should be belonged to.

Claims (10)

1. the multi-energy complementation combined production device of applicable rural households, it is characterized in that: comprise solar energy power generating loop, solar water produces loop, household electricity controller, refrigerant circulation loop, heat-pump hot-water closed circuit, underground water extracts and stores path, controller, household electricity controller respectively with solar energy power generating loop, solar water produces loop, heat-pump hot-water closed circuit, refrigerant circulation loop, underground water extracts and is connected with storage path, solar energy power generating loop and solar water are produced loop and are connected, solar water produces loop and heat-pump hot-water closed circuit, underground water extracts and is connected with storage path, refrigerant circulation loop respectively with heat-pump hot-water closed circuit, underground water extracts and is connected with storage path, described controller produces loop with solar water respectively, household electricity controller, refrigerant circulation loop, heat-pump hot-water closed circuit, underground water extracts and is connected with storage path.
2. the multi-energy complementation combined production device being applicable to rural households as claimed in claim 1, it is characterized in that: described solar energy power generating loop comprises photovoltaic and photothermal integral type solar panel, anti-reverse charging diode, DC/AC inverter, described photovoltaic and photothermal integral type solar panel, anti-reverse charging diode, DC/AC inverter is connected in series successively, DC/AC inverter is connected with household electricity controller, described household electricity controller is connected with electrical network through electric energy meter, household electricity controller is connected with other household electricity utensils by power cable, tapping pipe is also equipped with in the bottom of photovoltaic and photothermal integral type solar panel, tapping pipe is equipped with discharging valve.
3. the multi-energy complementation combined production device being applicable to rural households as claimed in claim 2, it is characterized in that: described solar water is produced loop and comprised heat preservation hot water tank, solar heat water-circulating pump, solar water supply pipe, solar energy return pipe, solar panel water supply shut-off valve and solar panel backwater shut-off valve, the two ends of described solar water supply pipe connect heat preservation hot water tank and photovoltaic and photothermal integral type solar panel respectively, solar heat water-circulating pump is arranged on solar water supply pipe, solar heat water-circulating pump respectively with household electricity controller, controller is connected, solar water supply pipe between heat preservation hot water tank and solar heat water-circulating pump is provided with solar panel water supply shut-off valve, the two ends of described solar energy return pipe connect heat preservation hot water tank and photovoltaic and photothermal integral type solar panel respectively, solar energy return pipe is provided with solar panel backwater shut-off valve, described heat preservation hot water tank is connected with family life water heater by domestic hot-water's feed pipe, described domestic hot-water's feed pipe is equipped with hot-water switch valve.
4. the multi-energy complementation combined production device being applicable to rural households as claimed in claim 3, it is characterized in that: described heat preservation hot water tank is equipped with high water level meter, low water level meter, high water level meter, low water level meter are connected with controller, heat preservation hot water tank has passage, be provided with electric heating device in heat preservation hot water tank, electric heating device is connected with household electricity controller, controller respectively.
5. the multi-energy complementation combined production device being applicable to rural households as claimed in claim 3, is characterized in that: described underground water extracts and stores path and comprises underground water well, well water pump, well water plate type heat exchanger, electric T-shaped valve, non-tower water feeder, storage cistern, described electric T-shaped valve contains e, f, g tri-interfaces, described underground water well, well water pump, well water plate type heat exchanger is connected successively by pipeline, well water pump respectively with household electricity controller, controller is connected, and the outlet pipe of well water plate type heat exchanger is connected to the e interface of electric T-shaped valve again by pipeline, described non-tower water feeder and storage cistern by pipeline respectively with the f of electric T-shaped valve, g interface is connected, described non-tower water feeder is connected with heat preservation hot water tank by heat preservation hot water tank filling pipe, heat preservation hot water tank filling pipe is provided with boiler moisturizing magnetic valve, non-tower water feeder is connected with family life cold water apparatus by life cold water supplying pipe, cold water switch valve life cold water supplying pipe is equipped with, described electric T-shaped valve, boiler moisturizing magnetic valve is connected with controller respectively, described non-tower water feeder is also equipped with high pressure sensor and low pressure sensor, high pressure sensor, low pressure sensor is connected with controller respectively, and miscellaneous water feed pipe is equipped with in the bottom of storage cistern, miscellaneous water feed pipe is equipped with miscellaneous water switch valve.
6. the multi-energy complementation combined production device being applicable to rural households as claimed in claim 5, is characterized in that: described refrigerant circulation loop comprises compressor of air conditioner, four-way change-over valve, first expansion valve, first check valve, second expansion valve, second check valve, air-conditioning indoor heat exchanger, hot water plate type heat exchanger, hot water circuit magnetic valve, Air-conditioning Cycle magnetic valve, described four-way change-over valve comprises a, b, c, d tetra-interfaces, one end of described Air-conditioning Cycle magnetic valve is connected with the b interface of four-way change-over valve by refrigerant tubing, the other end of Air-conditioning Cycle magnetic valve, air-conditioning indoor heat exchanger, second expansion valve, first expansion valve, be connected with the c interface of four-way change-over valve after well water plate type heat exchanger is connected in series successively, described hot water plate type heat exchanger, the first branch road that hot water circuit magnetic valve serial connection is formed and Air-conditioning Cycle magnetic valve, the second branch road that air-conditioning indoor heat exchanger serial connection is formed also connects, and air-conditioning indoor heat exchanger is equipped with air-conditioning draught fan, and described first check valve is attempted by the first expansion valve two ends, and the second check valve is attempted by the second expansion valve two ends, the air entry of described compressor of air conditioner, exhaust outlet by refrigerant tubing respectively with four-way change-over valve d, a two interface be connected, described compressor of air conditioner, four-way change-over valve, air-conditioning draught fan, hot water circuit magnetic valve, Air-conditioning Cycle magnetic valve are connected with controller respectively, and described compressor of air conditioner, air-conditioning draught fan are connected with household electricity controller respectively.
7. the multi-energy complementation combined production device being applicable to rural households as claimed in claim 6, it is characterized in that: described first check valve is contrary with the flow direction of the second check valve, and wherein the refrigerant flow direction of the first check valve is for flow to air-conditioning indoor heat exchanger or hot water plate type heat exchanger by well water plate type heat exchanger.
8. the multi-energy complementation combined production device being applicable to rural households as claimed in claim 7, it is characterized in that: described heat-pump hot-water closed circuit comprises heat-pump hot-water circulating pump, heat pump feed pipe, heat pump return pipe, heat pump water supply shut-off valve, heat pump backwater shut-off valve, the two ends of described heat pump feed pipe connect the water inlet of heat preservation hot water tank and hot water plate type heat exchanger respectively, heat-pump hot-water circulating pump is arranged on heat pump feed pipe, heat pump feed pipe between heat-pump hot-water circulating pump and heat preservation hot water tank is provided with heat pump water supply shut-off valve, the two ends of described heat pump return pipe connect the delivery port of heat preservation hot water tank and hot water plate type heat exchanger respectively, heat pump return pipe is provided with heat pump backwater shut-off valve, described heat-pump hot-water circulating pump respectively with household electricity controller, controller is connected.
9. the multi-energy complementation combined production device of the applicable rural households according to any one of claim 1-8, it is characterized in that: also comprise biogas utilization loop, described biogas utilization loop comprises methane-generating pit, biogas fairlead and biogas generator, biogas fairlead is equipped with on the top of described methane-generating pit, and biogas fairlead is divided into cooking biogas pipe and generating biogas pipe in methane-generating pit outside; Described cooking biogas pipe is directly connected with family cooking utensils, cooking methane pipeline is equipped with cooking biogas switch valve; Described generating biogas pipe is connected with biogas generator, and biogas generator is connected with household electricity controller by power cable, and described generating biogas pipe is equipped with generating biogas switch valve.
10. the multi-energy complementation combined production device being applicable to rural households as claimed in claim 9, it is characterized in that: also comprise battery and AC/DC inverter, described battery is connected with the input of AC/DC inverter, and the output of AC/DC inverter is connected with household electricity controller.
CN201420772026.3U 2014-12-10 2014-12-10 A kind of multi-energy complementation combined production device of applicable rural households Withdrawn - After Issue CN204329402U (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104457025A (en) * 2014-12-10 2015-03-25 湖南科技大学 Multi-energy complementary co-production device applicable to rural households

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104457025A (en) * 2014-12-10 2015-03-25 湖南科技大学 Multi-energy complementary co-production device applicable to rural households

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