Summary of the invention
The purpose of this utility model provides the complementary heating system in the electric natural pond of xenogenesis scene of a kind of solar energy, wind, electricity, gas combination.
The complementary heating system in the utility model electric natural pond of a kind of xenogenesis scene is achieved by following technical proposals: the complementary heating system in the utility model electric natural pond of a kind of xenogenesis scene comprises solar heater, the underground heat feed pipe, the ground heat control valve (HCV), underground heat, circulating pump, circulation pipe, attemperating unit, temperature sensor, the water consumption device feed pipe, heat exchanger output water pipe, the energy storage heat exchanger, the running water feed pipe, the solar heater feed pipe, solar heater output water pipe, the miniature gas boiler, miniature gas boiler output water pipe, the natural gas input pipe, non-return valve, the water load, the fast heat apparatus temperature sensor, a speed heat clamp, the hot copper post of speed, copper pipe, heated seats, solar energy vacuum tube, heating rod, lenticular lens, the heating diaphragm, hollow is cut off, sealing gasket, the energy storage sensor, standing power supply, battery, power transmission line, electric heater, the electric heater support, the bath water switch, light-operated air discharge cook, fast heat apparatus, wind-driven generator, controller, the underground heat by-pass valve control, miniature gas boiler feed water valve, the solar water heater inlet valve, the methane-generating pit water circulating pump, the methane-generating pit heater, methane-generating pit, external source of the gas, the lucite cover that adds lustre to, air accumulator, appendix, running water pipe is connected with the fast heat apparatus input by feed pipe, running water pipe is connected with energy storage heat exchanger input simultaneously, solar energy heating pipe output water pipe is connected with heat exchanger output water pipe with the underground heat feed pipe respectively by threeway, the underground heat feed pipe is connected with the underground heat input by the ground heat control valve (HCV), energy storage heat exchanger output is connected with the underground heat feed pipe by heat exchanger output water pipe respectively and is connected with the water load by the bathing feed pipe, between described underground heat feed pipe and the ground hot output terminal water circulating pump and circulating water pipe are set, described circulating water pipe is connected with the underground heat feed pipe of circulation valve front end respectively by threeway and is connected with the underground heat return pipe by threeway; The underground heat return pipe is connected with the solar heater water inlet pipe; Described underground heat is provided with temperature sensor, and temperature sensor output signal is connected with the temperature controller input by power transmission line, and the temperature controller output is connected with water circulating pump by power transmission line.
The complementary heating system in the utility model electric natural pond of a kind of xenogenesis scene has following beneficial effect compared with prior art: the light-wind electric heating system is to utilize the irradiation of the environmental protection energy sun, solar water heater is heated water, or utilize the electric energy of wind-driven generator output that water is heated, or utilize miniature methane boiler with the water heating service.Solar water heater is as the main thermal source of fine day, wind-force electrical machinery, and miniature methane boiler is to the water concurrent heating in the energy storage heat exchanger.System is by the solar water heater that double-heat exchanger is arranged, wind-force electrical machinery, and battery, controller, light-operated air discharge cook, miniature methane boiler, methane-generating pit, standing power supply and pipeline are formed.Hot water in the heat exchanger of solar water heater flows in the energy storage heat exchanger, through pipeline, circulating pump is delivered to heating installation bag heating, the electricity that wind-driven generator sends daytime stores in battery, after water in the energy storage heat exchanger being heated during no sunshine at night or cloudy day, be transported to the heat supply of heating installation bag through pipe circle pump, calm, the battery electric energy discharges totally, in the evening of no sunshine, can utilize miniature methane boiler that the water in the energy storage heat exchanger is heated, realize heat supply heating, the energy storage heat exchanger also is provided with the bath water switch, and for the summer, two seasons of autumn live with hot water and bathing hot water.
A kind of solar energy composite heating system of the utility model series of products have that integrated use is high in technological content, volume is little, cost is low, can reach zero fuel consumption, have obviously energy-conservation, subtract dirty characteristic.Therefore, the utilization of this product will promote the fast development of heating industry, thereby making over outmoded heating facility obtains update.Such as: burning coal boiler room, boiler, chimney, blower fan, coal, oil, electricity, natural gas etc.
The utility model wind-driven generator institute generated energy except that being used for daily life, also can be stored in the battery, for because of overcast and rainy snow night sky gas heating system being provided safeguard.
Solar energy has improved firing rate, adopts and adds lustre to device under faint light wave, just can reach desired temperature.The utility model energy storage heat exchanger internal structure adopts multi-layer heat preserving, and the heat pipe extinction adopts special-shaped ripple wideband structural, cold water can be heated to the 57-70 degree in two hours under low light level situation.Heat-insulation system adopts unique design, in establish multi-layer heat preserving, vacuum is every cold device.
The utility model methane-generating pit is being used to warm oneself the above heat energy of waste heat 35 degree by specific anaerobic digestion device production biogas, and biogas reflects, helps the oxygen burning through heating boiler, improves 40% of fuel availability, and aerogenesis is used for daily life.The method can guarantee not have power consumption, zero-emission, heating, bathing automation, thereby save be used to warm oneself, all energy of bathing.
Description of drawings
The complementary heating system in the utility model electric natural pond of a kind of xenogenesis scene has following accompanying drawing:
Fig. 1 is a kind of electric natural pond of xenogenesis scene of the utility model complementary heating system embodiment 1 structural representation;
Fig. 2 is a kind of electric natural pond of xenogenesis scene of the utility model complementary heating system embodiment 2 structural representations;
Fig. 3 is a kind of electric natural pond of xenogenesis scene of the utility model complementary heating system embodiment 3 structural representations;
Fig. 4 installs main TV structure schematic diagram for the hot copper post of the complementary heating system speed in the electric natural pond of a kind of xenogenesis scene of the utility model;
Fig. 5 is a complementary heating system fast heat apparatus left side, the utility model electric natural pond of an a kind of xenogenesis scene TV structure schematic diagram;
Fig. 6 is a kind of electric natural pond of xenogenesis scene of the utility model complementary heating system fast heat apparatus plan structure schematic diagram;
Fig. 7 is a kind of electric natural pond of xenogenesis scene of the utility model complementary heating system solar energy vacuum tube structural representation;
Fig. 8 is a kind of electric natural pond of xenogenesis scene of the utility model complementary heating system A-A sectional structure schematic diagram;
Fig. 9 is a kind of complementary heating system energy storage in the electric natural pond of xenogenesis scene of the utility model heat converter structure schematic diagram;
Figure 10 is a kind of electric natural pond of xenogenesis scene of the utility model complementary heating system hot- water line 2,10,14,16 structural representations.
Wherein: 1, solar heater; 2, underground heat feed pipe; 3, heat control valve (HCV); 4, underground heat; 5, circulating pump; 6, circulation pipe; 7, attemperating unit; 8, temperature sensor; 9, water consumption device feed pipe; 10, heat exchanger output water pipe; 11, energy storage heat exchanger; 12, running water feed pipe; 13, solar heater feed pipe; 14, solar heater output water pipe; 15, miniature gas boiler; 16, miniature gas boiler output water pipe; 17, natural gas input pipe; 18, non-return valve; 19, water load; 20, fast heat apparatus temperature sensor; 21, a speed heat clamp; 22, fast hot copper post; 23, copper pipe; 24, heated seats; 25, solar energy vacuum tube; 26, heating rod; 27, lenticular lens; 28, heating diaphragm; 29, hollow is cut off; 30, sealing gasket; 31, energy storage sensor; 32, standing power supply; 33, battery; 34, power transmission line; 35, electric heater; 36, electric heater support; 37, bath water switch; 38, light-operated air discharge cook; 39, fast heat apparatus; 40, wind-driven generator; 41, controller; 42, underground heat by-pass valve control; 43, miniature gas boiler feed water valve; 44, solar water heater inlet valve; 45, methane-generating pit water circulating pump; 46, methane-generating pit heater; 47, methane-generating pit; 48, external source of the gas; 49, the lucite cover that adds lustre to; 50, air accumulator; 51, miniature gas boiler appendix; 52, blowoff valve; 53, pressure-reducing valve; 54, reversal valve; 55, blast pipe; 56, temperature detect switch (TDS).
The specific embodiment
Below in conjunction with drawings and Examples the complementary heating system technical scheme in the utility model electric natural pond of a kind of xenogenesis scene is further described.
As Fig. 1-shown in Figure 10, the complementary heating system in the utility model electric natural pond of a kind of xenogenesis scene comprises solar heater 1, underground heat feed pipe 2, ground heat control valve (HCV) 3, underground heat 4, circulating pump 5, circulation pipe 6, attemperating unit 7, temperature sensor 8, water consumption device feed pipe 9, heat exchanger output water pipe 10, energy storage heat exchanger 11, running water feed pipe 12, solar heater feed pipe 13, solar heater output water pipe 14, miniature gas boiler 15, miniature gas boiler output water pipe 16, natural gas input pipe 17, non-return valve 18, water load 19, fast heat apparatus temperature sensor 20, a speed heat clamp 21, the hot copper post 22 of speed, copper pipe 23, heated seats 24, solar energy vacuum tube 25, heating rod 26, lenticular lens 27, heating diaphragm 28, hollow cuts off 29, sealing gasket 30, energy storage sensor 31, standing power supply 32, battery 33, power transmission line 34, electric heater 35, electric heater support 36, bath water switch 37, light-operated air discharge cook 38, fast heat apparatus 39, wind-driven generator 40, controller 41, underground heat by-pass valve control 42, miniature gas boiler feed water valve 43, solar water heater inlet valve 44, methane-generating pit water circulating pump 45, methane-generating pit heater 46, methane-generating pit 47, external source of the gas 48, lucite adds lustre to and covers 49, air accumulator 50, miniature gas boiler appendix 51, blowoff valve 52, pressure-reducing valve 53, reversal valve 54, running water pipe 12 is connected with fast heat apparatus 39 inputs by feed pipe 13, running water pipe 12 is connected with energy storage heat exchanger 11 inputs simultaneously, solar energy heating pipe output water pipe 14 is connected with heat exchanger output water pipe 10 with underground heat feed pipe 2 respectively by threeway, underground heat feed pipe 2 is connected with underground heat 4 inputs by ground heat control valve (HCV) 3, energy storage heat exchanger 11 outputs are connected with underground heat feed pipe 2 by heat exchanger output water pipe 10 respectively and are connected with water load 19 by bathing feed pipe 9, between described underground heat feed pipe 2 and underground heat 4 outputs water circulating pump 5 and circulating water pipe 6 are set, described circulating water pipe 6 is connected with the underground heat feed pipe 2 of circulation valve 3 front ends respectively by threeway and is connected with underground heat 4 return pipes by threeway; Underground heat 4 return pipes are connected with solar heater water inlet pipe 13; Described underground heat 4 is provided with temperature sensor 8, and temperature sensor 8 output signals are connected with temperature controller 7 inputs by power transmission line 34, and temperature controller 7 outputs are connected with water circulating pump 5 by power transmission line 34.
Between described running water pipe 12 and the solar thermal collector water inlet pipe 13 non-return valve 18 is set.
Described solar heater output water pipe 14 is connected with miniature gas boiler 15 inputs, miniature gas boiler 15 outputs are connected with underground heat feed pipe 2 by miniature gas boiler output water pipe 16, and miniature gas boiler 15 is connected with gas source by natural gas line 17.
Described electric heater 35 is arranged on energy storage heat exchanger 11 bottoms by support 36, and electric heater 35 is connected with battery 33, and battery 33 is connected with wind-driven generator 40 by controller 41.
Described miniature gas boiler 15 inputs are connected with methane-generating pit 47 by miniature gas boiler appendix 51, and methane-generating pit 47 is connected with air accumulator 50 by gas pipeline; Described methane-generating pit 47 tops be provided with arc corrugated surface lucite add lustre to the cover 49.
Described energy storage heat exchanger 11 is provided with three layers of vacuum heat-preserving tube, hollow is set between every two-layer pipe cuts off 29; Described underground heat feed pipe 2, solar heater output water pipe 14, miniature gas boiler output water pipe 16 and heat exchanger output water pipe 10 are three layers of vacuum heat-preserving tube, hollow is set between every two-layer pipe cuts off 29; The logical heat exchanger 11 of described storage is respectively arranged with blowoff valve 52 and pressure-reducing valve 53.
Be provided with reversal valve 54 between described heat exchanger output water pipe 10 and the miniature gas boiler 15 output water pipes 16.
Described fast heat apparatus 39 comprises copper pipe 23, fast hot copper post 22, a speed heat clamp 21, heated seats 24, solar energy vacuum tube 25, heating rod 26, lenticular lens 27, heating diaphragm 28, described heating rod 26 vertically is welded to connect with heating diaphragm 28, fixedly connected with fast hot copper post 22 in heating rod 26 ends, the hot copper post 22 of speed is fixed in the groove on plane on the heated seats 24 by a speed heat clamp 21, and the cavity that copper pipe 23 vertically passes heated seats 24 is fixed on fast heat apparatus 39 shell two ends.
Embodiment 1.
As Fig. 1, Fig. 4-shown in Figure 10, present embodiment is not provided with miniature gas boiler 15.Running water pipe 12 is connected with fast heat apparatus 39 inputs by feed pipe 13, running water pipe 12 is connected with energy storage heat exchanger 11 inputs simultaneously, solar energy heating pipe output water pipe 14 is connected with heat exchanger output water pipe 10 with underground heat feed pipe 2 respectively by threeway, underground heat feed pipe 2 is connected with underground heat 4 inputs by ground heat control valve (HCV) 3, energy storage heat exchanger 11 outputs are connected with underground heat feed pipe 2 by heat exchanger output water pipe 10 respectively and are connected with water load 19 by bathing feed pipe 9, between described underground heat feed pipe 2 and underground heat 4 outputs water circulating pump 5 and circulating water pipe 6 are set, described circulating water pipe 6 is connected with the underground heat feed pipe 2 of circulation valve 3 front ends respectively by threeway and is connected with underground heat 4 return pipes by threeway; Underground heat 4 return pipes are connected with solar heater water inlet pipe 13; Described underground heat 4 is provided with temperature sensor 8, and temperature sensor 8 output signals are connected with temperature controller 7 inputs by power transmission line 34, and temperature controller 7 outputs are connected with water circulating pump 5 by power transmission line 34.As shown in Figure 1.
Between described running water pipe 12 and the solar thermal collector water inlet pipe 13 non-return valve 18 is set.
Described electric heater 35 is arranged on energy storage heat exchanger 11 bottoms by support 36, and electric heater 35 is connected with battery 33 by power transmission line 34, and battery 33 is connected with standing power supply 32 by controller 41.
Described energy storage heat exchanger 11 is provided with three layers of vacuum heat-preserving tube, hollow is set between every two-layer pipe cuts off 29.With vacuumizing between every two-layer insulating tube, at the end welded seal, the energy storage heat exchanger cover can adopt rivet to be connected with tank body or adopt pressure container cover to be connected with end connected mode, and sealing gasket 30 is set between energy storage heat exchanger cover and the tank body during making; Described underground heat feed pipe 2, solar heater output water pipe 14, miniature gas boiler output water pipe 16 and heat exchanger output water pipe 10 are three layers of vacuum heat-preserving tube, hollow is set between every two-layer pipe cuts off 29.With vacuumizing between every two-layer insulating tube, at the end welded seal, socket connects between per two joint insulating tubes during making; The logical heat exchanger 11 of described storage is respectively arranged with blowoff valve 52 and pressure-reducing valve 53.
Described fast heat apparatus 39 comprises copper pipe 23, fast hot copper post 22, a speed heat clamp 21, heated seats 24, solar energy vacuum tube 25, heating rod 26, lenticular lens 27, heating diaphragm 28, described heating rod 26 vertically is welded to connect with heating diaphragm 28, fixedly connected with fast hot copper post 22 in heating rod 26 ends, the hot copper post 22 of speed is fixed in the groove on plane on the heated seats 24 by a speed heat clamp 21, and the cavity that copper pipe 23 vertically passes heated seats 24 is fixed on fast heat apparatus 39 shell two ends.
Running water supplies water with fast heat apparatus 39 and energy storage heat exchanger 11 respectively by running water pipe 12, running water in the copper pipe 23 of fast heat apparatus 39 through solar energy vacuum tube 25 with solar heat by heating rod 26 and a speed heat copper post 22 heating that are attached thereto after, hot water supplies water for underground heat 4 and supplies water for energy storage heat exchanger 11 through heat exchanger water-supply-pipe 10 by solar heater the outlet pipe 14 and three underground heat water-supply-pipe 2 that stimulates the menstrual flow.Energy storage heat exchanger 11 heated hot water also supply water to water load 19 through bathing feed pipe 9.
The temperature that the fast heat apparatus temperature sensor 20 that fast heat apparatus 39 ends are provided with is set according to attemperating unit 7 is controlled the starting of circulating pump 5 and is stopped, and when temperature surpassed design temperature, 5 startings of attemperating unit 7 start cycles pumps were accelerated the circulation of water, the reduction temperature.
The temperature that the temperature sensor 8 that underground heat 4 is provided with is set according to attemperating unit 7 is controlled the starting of circulating pump 5 and is stopped, and when temperature surpassed design temperature, attemperating unit 7 start cycles pumps 5 were accelerated the circulation of water, reduce temperature.
Embodiment 2.
Present embodiment is provided with miniature gas boiler 15.Running water pipe 12 is connected with fast heat apparatus 39 inputs by feed pipe 13, running water pipe 12 is connected with energy storage heat exchanger 11 inputs simultaneously, solar energy heating pipe output water pipe 14 is connected with heat exchanger output water pipe 10 with underground heat feed pipe 2 respectively by threeway, underground heat feed pipe 2 is connected with underground heat 4 inputs by ground heat control valve (HCV) 3, energy storage heat exchanger 11 outputs are connected with underground heat feed pipe 2 by heat exchanger output water pipe 10 respectively and are connected with water load 19 by bathing feed pipe 9, between described underground heat feed pipe 2 and underground heat 4 outputs water circulating pump 5 and circulating water pipe 6 are set, described circulating water pipe 6 is connected with the underground heat feed pipe 2 of circulation valve 3 front ends respectively by threeway and is connected with underground heat 4 return pipes by threeway; Underground heat 4 return pipes are connected with solar heater water inlet pipe 13; Described underground heat 4 is provided with temperature sensor 8, and temperature sensor 8 output signals are connected with temperature controller 7 inputs by power transmission line 34, and temperature controller 7 outputs are connected with water circulating pump 5 by power transmission line 34.
Between described running water pipe 12 and the solar thermal collector water inlet pipe 13 non-return valve 18 is set.
Described solar heater output water pipe 14 is connected with miniature gas boiler 15 inputs, miniature gas boiler 15 outputs are connected with underground heat feed pipe 2 by miniature gas boiler output water pipe 16, and miniature gas boiler 15 is connected with gas source by natural gas line 17.
Described electric heater 35 is provided with logical heat exchanger 11 bottoms of storage by support 36, and electric heater 35 is connected with battery 33 by power transmission line 34, and battery 33 is by controller 41 and standing power supply 32.
Described energy storage heat exchanger 11 is provided with three layers of vacuum heat-preserving tube, hollow is set between every two-layer pipe cuts off 29.With vacuumizing between every two-layer insulating tube, at the end welded seal, the energy storage heat exchanger cover can adopt rivet to be connected with tank body or adopt pressure container cover to be connected with end connected mode, and sealing gasket 30 is set between energy storage heat exchanger cover and the tank body during making; Described underground heat feed pipe 2, solar heater output water pipe 14, miniature gas boiler output water pipe 16 and heat exchanger output water pipe 10 are three layers of vacuum heat-preserving tube, hollow is set between every two-layer pipe cuts off 29.With vacuumizing between every two-layer insulating tube, at the end welded seal, socket connects between per two joint insulating tubes during making; The logical heat exchanger 11 of described storage is respectively arranged with blowoff valve 52 and pressure-reducing valve 53.
Be provided with reversal valve 54 between described heat exchanger output water pipe 10 and the miniature gas boiler 15 output water pipes 16.
Described fast heat apparatus 39 comprises copper pipe 23, fast hot copper post 22, a speed heat clamp 21, heated seats 24, solar energy vacuum tube 25, heating rod 26, lenticular lens 27, heating diaphragm 28, described heating rod 26 vertically is welded to connect with heating diaphragm 28, fixedly connected with fast hot copper post 22 in heating rod 26 ends, the hot copper post 22 of speed is fixed in the groove on plane on the heated seats 24 by a speed heat clamp 21, and the cavity that copper pipe 23 vertically passes heated seats 24 is fixed on fast heat apparatus 39 shell two ends.
Running water supplies water with fast heat apparatus 39 and energy storage heat exchanger 11 respectively through non-return valve 18 by running water pipe 12, running water in the copper pipe 23 of fast heat apparatus 39 through solar energy vacuum tube 25 with solar heat by heating rod 26 and a speed heat copper post 22 heating that are attached thereto after, hot water flows to miniature gas boiler 15 by solar heater outlet pipe 14, and miniature gas boiler 15 is connected with gas source or biogas source by natural gas line 17; The hot water of fast heat apparatus 39 output through miniature gas boiler 15 continue the heating back by miniature boiler output water pipe 16 is connected with underground heat water-supply-pipe 2 give underground heat 4 water supply and through heat exchanger water-supply-pipe 10 to 11 water supply of energy storage heat exchanger.Energy storage heat exchanger 11 heated hot water also supply water to water load 19 through bathing feed pipe 9.As shown in Figure 2.
The temperature that the fast heat apparatus temperature sensor 20 that fast heat apparatus 39 ends are provided with is set according to attemperating unit 7 is controlled the starting of circulating pump 5 and is stopped, and when temperature surpassed design temperature, 5 startings of attemperating unit 7 start cycles pumps were accelerated the circulation of water, the reduction temperature.
The temperature that the temperature sensor 8 that underground heat 4 is provided with is set according to attemperating unit 7 is controlled the starting of circulating pump 5 and is stopped, and when temperature surpassed design temperature, attemperating unit 7 start cycles pumps 5 were accelerated the circulation of water, reduce temperature.
Embodiment 3.
Present embodiment as shown in Figure 3, running water pipe 12 is connected with fast heat apparatus 39 inputs by feed pipe 13, running water pipe 12 is connected with energy storage heat exchanger 11 inputs simultaneously, solar energy heating pipe output water pipe 14 is connected with heat exchanger output water pipe 10 with underground heat feed pipe 2 respectively by threeway, underground heat feed pipe 2 is connected with underground heat 4 inputs by ground heat control valve (HCV) 3, energy storage heat exchanger 11 outputs are connected with underground heat feed pipe 2 by heat exchanger output water pipe 10 respectively and are connected with water load 19 by bathing feed pipe 9, between described underground heat feed pipe 2 and underground heat 4 outputs water circulating pump 5 and circulating water pipe 6 are set, described circulating water pipe 6 is connected with the underground heat feed pipe 2 of circulation valve 3 front ends respectively by threeway and is connected with underground heat 4 return pipes by threeway; Underground heat 4 return pipes are connected with solar heater water inlet pipe 13; Described underground heat 4 is provided with temperature sensor 8, and temperature sensor 8 output signals are connected with temperature controller 7 inputs by power transmission line 34, and temperature controller 7 outputs are connected with water circulating pump 5 by power transmission line 34.
Between described running water pipe 12 and the solar thermal collector water inlet pipe 13 non-return valve 18 is set.
Described solar heater output water pipe 14 is connected with miniature gas boiler 15 inputs, miniature gas boiler 15 outputs are connected with underground heat feed pipe 2 by miniature gas boiler output water pipe 16, and miniature gas boiler 15 is connected with gas source by natural gas line 17.
In the logical heat exchanger 11 of described storage electric heater 35 is set, electric heater 35 is connected with battery 33, and battery 33 is connected with wind-driven generator 40 by controller 41.
Described miniature gas boiler 15 inputs are connected with methane-generating pit 47 by miniature gas boiler appendix 51, and methane-generating pit 47 is connected with air accumulator 50; Described methane-generating pit 47 tops be provided with arc corrugated surface lucite add lustre to the cover 49.
Described energy storage heat exchanger 11 is provided with three layers of vacuum heat-preserving tube, hollow is set between every two-layer pipe cuts off 29.With vacuumizing between every two-layer insulating tube, at the end welded seal, the energy storage heat exchanger cover can adopt rivet to be connected with tank body or adopt pressure container cover to be connected with end connected mode, and sealing gasket 30 is set between energy storage heat exchanger cover and the tank body during making; Described underground heat feed pipe 2, solar heater output water pipe 14, miniature gas boiler output water pipe 16 and heat exchanger output water pipe 10 are three layers of vacuum heat-preserving tube, hollow is set between every two-layer pipe cuts off 29.With vacuumizing between every two-layer insulating tube, at the end welded seal, socket connects between per two joint insulating tubes during making; The logical heat exchanger 11 of described storage is respectively arranged with blowoff valve 52 and pressure-reducing valve 53.
Be provided with reversal valve 54 between described heat exchanger output water pipe 10 and the miniature gas boiler 15 output water pipes 16.
Described fast heat apparatus 39 comprises copper pipe 23, fast hot copper post 22, a speed heat clamp 21, heated seats 24, solar energy vacuum tube 25, heating rod 26, lenticular lens 27, heating diaphragm 28, described heating rod 26 vertically is welded to connect with heating diaphragm 28, fixedly connected with fast hot copper post 22 in heating rod 26 ends, the hot copper post 22 of speed is fixed in the groove on plane on the heated seats 24 by a speed heat clamp 21, and the cavity that copper pipe 23 vertically passes heated seats 24 is fixed on fast heat apparatus 39 shell two ends.
Described methane-generating pit 47 is connected with air accumulator 50 by gas pipeline.
Running water supplies water for fast heat apparatus 39 through running water pipe 12 and non-return valve 18 and water inlet pipe 13, supplies water for miniature gas boiler 15 through water inlet pipe 13 and miniature gas boiler feed water valve 43 simultaneously; Fast heat apparatus 39 heated hot water supply water for behind temperature detect switch (TDS) 56 energy storage heat exchanger 11, further heating is after underground heat water-supply-pipe 2 supplies water for underground heat 4 to hot water through the electric heater 35 of energy storage heat exchanger 11, and underground heat 4 backwater return energy storage heat exchanger 11 through return pipe and circulating pump 5; The hot water of miniature gas boiler 15 supplies water for energy storage heat exchanger 11 through output water pipe and temperature detect switch (TDS) 56, gives for simultaneously methane-generating pit heater 46 and supplies water, and the backwater of methane-generating pit heater 46 returns miniature gas boiler 15 through return pipe and methane-generating pit water circulating pump 45; Methane-generating pit 47 is by methane-generating pit heater 46 heating fermentation gas, and sunshine is amplified light methane-generating pit 47 temperature are raise by the lucite cover 49 that adds lustre to, and the unnecessary biogas of methane-generating pit 47 outputs flows to air accumulator 50 through appendix and stores.
Wind-driven generator 40 generatings give the electric heater in the energy storage heat exchanger 11 35 power supplies by controller 41 and battery 33, further heat the hot water in the energy storage heat exchanger 11.
The temperature that the fast heat apparatus temperature sensor 20 that fast heat apparatus 39 ends are provided with is set according to attemperating unit 7 is controlled the starting of circulating pump 5 and is stopped, and when temperature surpassed design temperature, 5 startings of attemperating unit 7 start cycles pumps were accelerated the circulation of water, the reduction temperature.
The temperature that the temperature sensor 8 that underground heat 4 is provided with is set according to attemperating unit 7 is controlled the starting of circulating pump 5 and is stopped, and when temperature surpassed design temperature, attemperating unit 7 start cycles pumps 5 were accelerated the circulation of water, reduce temperature.