CN203757928U - Evaporative cooling air conditioner with wind-solar complementary power generation being power source - Google Patents

Evaporative cooling air conditioner with wind-solar complementary power generation being power source Download PDF

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Publication number
CN203757928U
CN203757928U CN201420114004.8U CN201420114004U CN203757928U CN 203757928 U CN203757928 U CN 203757928U CN 201420114004 U CN201420114004 U CN 201420114004U CN 203757928 U CN203757928 U CN 203757928U
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China
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wind
evaporative cooling
cooling air
air conditioning
pipe
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Expired - Fee Related
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CN201420114004.8U
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Chinese (zh)
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黄翔
申长军
宋祥龙
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Xian Polytechnic University
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Xian Polytechnic University
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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
    • Y02B10/40Geothermal heat-pumps

Abstract

The utility model discloses an evaporative cooling air conditioner with wind-solar complementary power generation being a power source. The evaporative cooling air conditioner is formed by connecting a wind-solar complementary power generation system, a wind-solar complementary power generation control system and an evaporative cooling air conditioning unit in sequence through wires. The wind-solar complementary power generation system comprises a wind power generation device and a solar panel. The evaporative cooling air conditioning unit is connected with a buried pipe heat exchange system. According to the evaporative cooling air conditioner, the renewable resources of wind energy, solar energy, dry air energy and geothermal energy in the natural world are comprehensively utilized, and therefore the evaporative cooling air conditioner has the advantages of saving energy and being environmentally friendly and efficient. Accordingly, the cooling mode of the air conditioner has broad application prospects.

Description

A kind of wind light mutual complementing power generation is the Evaporative Cooling Air Conditioning of power source
Technical field
The utility model belongs to air conditioner technical field, relates to the Evaporative Cooling Air Conditioning that a kind of wind light mutual complementing power generation is power source.
Background technology
Wind energy, solar energy, dry air energy, geothermal energy, as the regenerative resource of occurring in nature affluence, in current energy crisis, under the social reality backgrounds such as environmental pollution, are more and more subject to people's favor.Wind light mutual complementing power generation technology is exactly the feature of comprehensive utilization solar energy and wind energy, learns from other's strong points to offset one's weaknesses and carrys out complemental power-generation; Evaporative Cooling Air Conditioning technology is to utilize dry, the wet-bulb depression of air, and dry air can be as the air-conditioning technical that drives gesture to lower the temperature; Geothermal energy is the energy being stored in thin solum certain depth thermostat layer, and the mode that adopts underground pipe recirculated water and thin solum to carry out heat exchange utilization, can be our productive life service.
Wind energy, solar energy, dry air energy and geothermal energy are combined, and integrated application, in conditioner, is compared and is only utilized wherein a kind of or two kinds of more energy-saving and environmental protection and efficient of resource mode, has certain application value.
Utility model content
It is the Evaporative Cooling Air Conditioning of power source that the purpose of this utility model is to provide a kind of wind light mutual complementing power generation, and the regenerative resource of occurring in nature is combined and is applied to Evaporative Cooling Air Conditioning unit with new material, has improved cooling effectiveness.
The technical scheme that the utility model adopts is, a kind of wind light mutual complementing power generation is the Evaporative Cooling Air Conditioning of power source, include the wind and solar hybrid generating system, wind-solar hybrid generation control system and the Evaporative Cooling Air Conditioning unit that by wire, connect successively, Evaporative Cooling Air Conditioning unit is connected with buried pipe heat exchange system; Wind and solar hybrid generating system, includes wind power generation plant and solar panel.
Feature of the present utility model is also,
Wind-solar hybrid generation control system, is comprised of the wind/light complementation controller, batteries and the inverter that are followed in series to form closed-loop path by wire, and wind/light complementation controller is connected with wind power generation plant, solar panel respectively by wire; Inverter is connected with Evaporative Cooling Air Conditioning unit by wire.
Wind power generation plant, includes wind-driven generator, and wind-driven generator is connected in vertical axis top by rotating disk, and one end of wind-driven generator is connected with blading, and the other end of wind-driven generator is connected with tail vane.
The top of solar panel is arranged with glass cover-plate in parallel, between solar panel and glass cover-plate, forms microchannel, and microchannel is communicated with the efflux nozzle on secondary air channel, and secondary air channel is connected with Evaporative Cooling Air Conditioning unit; Solar panel is multiple lines and multiple rows by polylith solar cell and rearranges.
Evaporative Cooling Air Conditioning unit, includes machine unit shell, and machine unit shell is respectively arranged with air inlet, air outlet on relative two side;
In machine unit shell, by new wind approach axis, be disposed with air cleaner, surface-type heat exchanger, porous ceramic vertical tube indirect evaporation cooler, foam metal filler direct evaporative cooler, water fender a, heater and axial flow blower; On machine unit shell roof corresponding to the top of porous ceramic vertical tube indirect evaporation cooler, be provided with Secondary Air exhaust outlet, in Secondary Air exhaust outlet, be provided with overfire air fan;
Secondary Air exhaust outlet is connected with one end of secondary air channel, and efflux nozzle is connected with the other end of secondary air channel.
In air inlet, be provided with air inlet valve, in air outlet, be provided with outlet valve.
Surface-type heat exchanger is the heat exchange coil vertically arranging, and one end of heat exchange coil is stretched in the diversion box of buried pipe heat exchange system, and the other end of heat exchange coil is connected with the 3rd feed pipe;
Porous ceramic vertical tube indirect evaporation cooler, include porous ceramics vertical heat exchanging pipe group, the top of porous ceramics vertical heat exchanging pipe group is disposed with water-locator a, water fender b, the bottom of porous ceramics vertical heat exchanging pipe group is provided with header tank a, between porous ceramics vertical heat exchanging Guan Zuyu header tank a, form air channel, on unit shell side wall corresponding to air channel, be provided with secondary air inlet, header tank a is connected with water-locator a by the first feed pipe, on the first feed pipe, be provided with water circulating pump a, header tank a is connected with the 3rd feed pipe by the first filling pipe, on the first filling pipe, be provided with water compensating valve a,
Foam metal filler direct evaporative cooler, include foam metal filler, the top of foam metal filler is provided with water-locator b, the bottom of foam metal filler is provided with header tank b, header tank b is connected with water-locator b by the second feed pipe, on the second feed pipe, be provided with water circulating pump b, header tank b is connected with the 3rd feed pipe by the second filling pipe, is provided with water compensating valve b on the second filling pipe.
Porous ceramics vertical heat exchanging pipe group is comprised of the many porous ceramics heat exchanger tubes that vertically arrange; Foam metal filler is the vertical side, foam metal filler edge of W type accordion or is formed along airflow direction successively parallel stack by polylith.
The 3rd feed pipe is connected with buried pipe heat exchange system.
Buried pipe heat exchange system, include and be arranged at underground flatly pipe laying, flatly one end of pipe laying is connected with header tank c, flatly the other end of pipe laying is connected with diversion box, and junction is provided with water circulating pump c, and header tank c, diversion box are connected with attemperater by tube connector respectively, attemperater is connected with the 3rd feed pipe, on the 3rd feed pipe, be provided with water circulating pump d, on diversion box, be also connected with the 3rd filling pipe, on the 3rd filling pipe, be provided with water compensating valve c.
The beneficial effects of the utility model are:
(1) energy source that Evaporative Cooling Air Conditioning of the present utility model adopts, in wind energy and solar energy complementary power generation system, has energy-saving and environmental protection and reproducible feature.
(2) in Evaporative Cooling Air Conditioning of the present utility model, be provided with indirect evaporation cooler, adopt porous ceramic vertical tube formula structure, make full use of the porous of ceramic material and the feature of water-wet behavior; The filler that adopts metal foaming material to make in direct evaporative cooler, utilizes the porosity of metal foam material high, shock proof feature, and air is fully contacted with water.
(3) after Evaporative Cooling Air Conditioning employing underground pipe of the present utility model and soil heat exchange, the water of lower temperature, as indirect section, the directly moisturizing of section recirculated water, can significantly improve evaporative cooling efficiency.
(4) in Evaporative Cooling Air Conditioning of the present utility model, be provided with surface-type heat exchanger, its inner loop medium be in underground pipe with soil to execute heat exchange (or changing cold) after water, be used for summer the air entering from the external world to carry out precooling; Be used for the primary air that preheating enters from the external world winter.
(5) in Evaporative Cooling Air Conditioning of the present utility model, solar panel upper surface is provided with one deck glass cover-plate at a certain distance, form microchannel, the auxiliary air of discharge is passed into wherein, give outdoor solar panel surface cooling, can not only improve solar panel electricity conversion and improve the rate that makes full use of and the cooling effectiveness of auxiliary air.
Accompanying drawing explanation
Fig. 1 is the structural representation of the utility model Evaporative Cooling Air Conditioning;
Fig. 2 is the structural representation of Evaporative Cooling Air Conditioning unit and buried pipe heat exchange system in the utility model Evaporative Cooling Air Conditioning;
Fig. 3 is the fundamental diagram of the auxiliary air cools solar cell plate of the utility model Evaporative Cooling Air Conditioning discharge;
Fig. 4 is the fundamental diagram of porous ceramic vertical tube formula indirect evaporation cooler in the utility model Evaporative Cooling Air Conditioning;
Fig. 5 is the fundamental diagram of foam metal filler direct evaporative cooler in the utility model Evaporative Cooling Air Conditioning.
In figure, 1. wind-driven generator, 2. solar panel, 3. wind/light complementation controller, 4. batteries, 5. inverter, 6. Evaporative Cooling Air Conditioning unit, 7. fan blade device, 8. tail vane, 9. rotating disk, 10. surface-type heat exchanger, 11. air cleaners, 12. air inlet valves, 13. overfire air fans, 14. water-locator a, 15. water-locator b, 16. porous ceramics vertical heat exchanging pipe groups, 17. foam metal fillers, 18. water fender a, 19. axial flow blowers, 20. header tank c, 21. attemperaters, 22. water circulating pump d, 23. heaters, 24. diversion boxs, 25. water circulating pump c, 26. pipe layings flatly, 27. water compensating valve c, 28. water circulating pump a, 29. secondary air inlets, 30. water compensating valve a, 31. water circulating pump b, 32. water compensating valve b, 33. water fender b, 34. outlet valves, 35. header tank a, 36. header tank b, 37. secondary air channels, 38. efflux nozzles, 39. auxiliary airs, 40. glass cover-plates, 41. primary airs, 42. water droplets a, 43. water droplets b, 44. first filling pipes, 45. second filling pipes, 46. the 3rd filling pipes, 47. first feed pipes, 48. second feed pipes, 49. the 3rd feed pipes.
The specific embodiment
Below in conjunction with the drawings and specific embodiments, the utility model is elaborated.
The Evaporative Cooling Air Conditioning that a kind of wind light mutual complementing power generation of the utility model is power source, its structure as shown in Figure 1, include the wind and solar hybrid generating system, wind-solar hybrid generation control system and the Evaporative Cooling Air Conditioning unit 6 that by wire, connect successively, wind and solar hybrid generating system, include wind power generation plant and solar panel 2, Evaporative Cooling Air Conditioning unit 6 is connected with buried pipe heat exchange system.
Wind-solar hybrid generation control system, is followed in series to form closed-loop path by wind/light complementation controller 3, batteries 4 and inverter 5 by wire; Wherein, batteries 4 is composed in series successively by a plurality of batteries.Wind/light complementation controller 3 is connected with wind power generation plant 1, solar panel 2 in wind and solar hybrid generating system by wire respectively; Inverter 5 is connected with Evaporative Cooling Air Conditioning unit 6.
Wind power generation plant, include the wind-driven generator 1 that is arranged at vertical axis top, wind-driven generator 1 is connected with vertical axis by rotating disk 9, and one end of wind-driven generator 1 is connected with blading 7, blading 7 is towards direction setting windward, and the other end of wind-driven generator 1 is connected with tail vane 8.
As shown in Figure 3, the top of solar panel 2 is provided with glass cover-plate 40, glass cover-plate 40 is parallel with solar panel 2, between solar panel 2 and glass cover-plate 40, form microchannel, microchannel is communicated with the efflux nozzle 38 on secondary air channel 37, and secondary air channel 37 is connected with Evaporative Cooling Air Conditioning unit 6.Solar panel 2 is multiple lines and multiple rows arrangement by polylith solar cell and forms.
Evaporative Cooling Air Conditioning unit 6, as shown in Figure 2, include machine unit shell, machine unit shell is respectively arranged with air inlet on relative two side, air outlet, in machine unit shell, by new wind approach axis, be disposed with air cleaner 11, surface-type heat exchanger 10, porous ceramic vertical tube indirect evaporation cooler, foam metal filler direct evaporative cooler, water fender a18, heater 23 and axial flow blower 19, on machine unit shell roof corresponding to the top of porous ceramic vertical tube indirect evaporation cooler, be provided with Secondary Air exhaust outlet, in Secondary Air exhaust outlet, be provided with overfire air fan 13, as shown in Figure 3, Secondary Air exhaust outlet is connected with one end of secondary air channel 37, the other end of secondary air channel 37 is provided with efflux nozzle 38.
Wherein, in air inlet, be provided with air inlet valve 12, in air outlet, be provided with outlet valve 34.
Surface-type heat exchanger 10 is the heat exchange coil vertically arranging, and one end of heat exchange coil is stretched in diversion box 24, and the other end of heat exchange coil is connected with the 3rd feed pipe 49.
Porous ceramic vertical tube indirect evaporation cooler, include porous ceramics vertical heat exchanging pipe group 16, the top of porous ceramics vertical heat exchanging pipe group 16 is disposed with water-locator a14, water fender b33, the bottom of porous ceramics vertical heat exchanging pipe group 16 is provided with header tank a35, between porous ceramics vertical heat exchanging pipe group 16 and header tank a35, form air channel, header tank a35 is connected with water-locator a14 by the first feed pipe 47, on the first feed pipe 47, be provided with water circulating pump a28, header tank a35 is connected with the 3rd feed pipe 49 by the first filling pipe 44, on the first filling pipe 44, be provided with water compensating valve a30.
On unit shell side wall corresponding to air channel, be provided with secondary air inlet 29.
Foam metal filler direct evaporative cooler, include foam metal filler 17, the top of foam metal filler 17 is provided with water-locator b15, the bottom of foam metal filler 17 is provided with header tank b36, header tank b36 is connected with water-locator b15 by the second feed pipe 48, on the second feed pipe 48, be provided with water circulating pump b31, header tank b36 is connected with the 3rd feed pipe 49 by the second filling pipe 45, on the second filling pipe 45, is provided with water compensating valve b32.
Porous ceramics vertical heat exchanging pipe group 16 is comprised of the many porous ceramics heat exchanger tubes that vertically arrange;
Foam metal filler 17 is W type accordion filling block by polylith forms along vertical side or along the mobile direction of primary air successively parallel stack setting.
The 3rd feed pipe 49 is connected with buried pipe heat exchange system.
Buried pipe heat exchange system, include and be arranged at underground flatly pipe laying 26, flatly one end of pipe laying 26 is connected with header tank c20, flatly the other end of pipe laying 26 is connected with diversion box 24, on the pipeline that flatly pipe laying 26 is connected with diversion box 24, be provided with water circulating pump c25, header tank c20, diversion box 24 are connected with attemperater 21 by tube connector respectively, and attemperater 21 is connected with on the 3rd feed pipe 49, the three feed pipes 49 and is provided with water circulating pump d22; On diversion box 24, be also connected with on the 3rd filling pipe 46, the three filling pipes 46 and be provided with water compensating valve c27.
Evaporative Cooling Air Conditioning of the present utility model, by the fan blade in wind blows fan blade device 7, rotated, thereby drive wind-driven generator 1 running to produce electric energy, and the electric energy producing with solar panel 2 through wind/light complementation controller 3 maximum power outputs, after inverter 5 boosts, supply with the consumer of Evaporative Cooling Air Conditioning unit, inverter 5 has direct current and converts alternating current and boost function to; Batteries 4 is parallel between wind/light complementation controller 3 and inverter 4, is used for storing unnecessary electric energy; Tail vane 8 is used for controlling windmill direction and makes fan blade device 7 rotations all the time in state windward through rotating disk 9 rotation.
Surface-type heat exchanger 10 is arranged on after air cleaner, is used for precooling (heat) primary air; Heater 23 is arranged between water fender a18 and axial flow blower 19, and heater 23 is in the winter time for auxiliary heating.
Porous ceramics vertical heat exchanging pipe group 16 takes full advantage of the characteristics such as the porous of porous ceramics and hydrophily, because of the lost shower water of evaporation, with the water source as a supplement of the water in pipe laying 26 flatly, what in porous ceramics heat exchanger tube, auxiliary air carried out is to subtract enthalpy temperature-fall period.
Air-flow passes through from the interlayer of foam metal filler 17; Take full advantage of the feature of the specific area that the porous, impact resistance, life-span of foam metal material is long and larger, the recirculated water of disappearance utilizes water in pipe laying 26 flatly water source as a supplement, and primary air subtracts enthalpy temperature-fall period.
Buried pipe heat exchange system, flatly in pipe laying 26 with the cooled water of thin solum heat exchange through header tank c20 converge be stored in attemperater 21 standby, wherein most water is used for and surface-type heat exchanger 10 cycle heat exchanges, another part is as the moisturizing of header tank b36 in header tank a35 in porous ceramic vertical tube indirect evaporation cooler and foam metal filler direct evaporative cooler, and the rate of water make-up of each several part is controlled by water compensating valve a30 and water compensating valve b32 respectively; In buried pipe heat exchange system and surface-type heat exchanger 10, the power of water is controlled by water circulating pump c25 and water circulating pump d22 respectively, and flatly the moisture of pipe laying 26 disappearances is supplemented by the 3rd feed pipe 49 and water compensating valve c27; In winter, utilize surface-type heat exchanger 10 preheatings and heater 23 auxiliary heatings, to meet different places requirement.
As shown in Figure 3, auxiliary air 39 after Secondary Air exhaust outlet is discharged, is sprayed by efflux nozzle 38 along secondary air channel 37 under the drive of overfire air fan 13, can be used for lowering the temperature to solar panel 2.For improving the utilization rate of auxiliary air 39, on solar panel 2 surfaces, be provided with at a certain distance one deck glass cover-plate 40 and form microchannel, the auxiliary air 39 of discharging is passed in microchannel.
The course of work of the utility model Evaporative Cooling Air Conditioning is as follows:
In summer:
As shown in Figure 2, primary air 41 enters in machine unit shell through the effect of air inlet and air inlet valve 12, through air cleaner 11, filter successively, after surface-type heat exchanger 10 precoolings, flow through in porous ceramic vertical tube indirect evaporation cooler, at wet temperature-fall periods such as the interior porous ceramics heat exchange tube wall outgoing lifes of porous ceramics vertical heat exchanging pipe group 16, then enter in foam metal filler direct evaporative cooler, as shown in Figure 5, in foam metal filler 17, water droplets b43 and the primary air 41 of water-locator b15 ejection subtract enthalpy temperature-fall period in foam metal filler 17, finally by axial flow blower 19, send into workplace, in addition, after flatly pipe laying 26 and soil to execute heat exchange under outdoor ground, through header tank c20, tube connector, be stored in insulation in attemperater 21, high temperature cold water is followed after precooling through water circulating pump d22 and surface-type heat exchanger 10, drains into be diverted to flatly pipe laying 26 after diversion box 24 to proceed heat exchange cooling, as shown in Figure 4, auxiliary air 39 is after secondary air inlet 29 enters in machine unit shell, and the water droplets a42 spraying with water-locator a14 on the heat exchanger tube inwall of porous ceramics vertical heat exchanging pipe group 16 carries out wet exchange of heat and subtracts enthalpy drop temperature, as shown in Figure 3, then after overfire air fan 13 is discharged, along secondary air channel 37, through efflux nozzle 38, send into microchannel, carry out temperature-fall period to outdoor solar panel 2, to improve photoelectric transformation efficiency.
There are in the winter time three kinds of working methods:
The first working method: primary air 41 carries out, after preheating, directly passing into workplace through axial flow blower 19 through surface-type heat exchanger 10, at this moment other section is not worked, and can be used on the place that need to supplement new wind;
The second working method: primary air 41, after preheating, then after foam metal filler 17 place's humidifications, is sent into workplace, can be used on the place that need to supplement new wind and need humidification;
The third working method: primary air 41 is after surface-type heat exchanger 10 preheatings, after porous ceramic vertical tube indirect evaporation cooler, foam metal filler direct evaporative cooler and heater 23 auxiliary heatings are processed, send into workplace again, can be used on and need new wind and the more accurate place of humidification state parameter request.
Evaporative Cooling Air Conditioning of the present utility model is utilized wind energy, the solar energy renewable resource complemental power-generation of occurring in nature, for air-conditioning system provides electric power, utilize buried pipe heat exchange system and thin solum heat exchange, precooling (heat) as surface-type heat exchanger 10, and flatly the water in pipe laying 26, also as the moisturizing of indirect evaporation device and direct evaporator, makes air and water subtract enthalpy temperature-fall period, improve cooling effectiveness, summer primary air first through surface-type heat exchanger 10 precoolings, in wet cooling procedures such as porous ceramics heat exchange tube wall carry out outward, then enter foam metal filler direct evaporative cooler, in foam metal filler 17, subtract enthalpy temperature-fall period, final process axial flow blower 19 is sent into workplace, carry out preheating with surface-type heat exchanger 10 winter, and use foam metal filler direct evaporative cooler and porous ceramic vertical tube indirect evaporation cooler according to the requirement in actual place, finally utilize axial flow blower 19 heater 23 auxiliary heatings above to reach air-supply shape point and send into workplace, the secondary air inlet 29 of auxiliary air through porous ceramic vertical tube indirect evaporation cooler bottom enters porous ceramics vertical heat exchanging pipe group 16 inside, carry out with the water droplets of spray that heat is wet exchanges that to carry out dehumidification cooling, then through overfire air fan 13, drain into secondary air channel 37, finally by efflux nozzle 38, send into microchannel.

Claims (10)

1. the Evaporative Cooling Air Conditioning that wind light mutual complementing power generation is power source, it is characterized in that, include the wind and solar hybrid generating system, wind-solar hybrid generation control system and the Evaporative Cooling Air Conditioning unit (6) that by wire, connect successively, described Evaporative Cooling Air Conditioning unit (6) is connected with buried pipe heat exchange system; Described wind and solar hybrid generating system, includes wind power generation plant and solar panel (2).
2. Evaporative Cooling Air Conditioning according to claim 1, it is characterized in that, described wind-solar hybrid generation control system, the wind/light complementation controller (3), batteries (4) and the inverter (5) that are followed in series to form closed-loop path by wire, consist of, described wind/light complementation controller (3) is connected with described wind power generation plant, solar panel (2) respectively by wire; Described inverter (5) is connected with described Evaporative Cooling Air Conditioning unit (6) by wire.
3. Evaporative Cooling Air Conditioning according to claim 1 and 2, it is characterized in that, described wind power generation plant, include wind-driven generator (1), described wind-driven generator (1) is connected in vertical axis top by rotating disk (9), one end of described wind-driven generator (1) is connected with blading (7), and the other end of described wind-driven generator (1) is connected with tail vane (8).
4. Evaporative Cooling Air Conditioning according to claim 1 and 2, it is characterized in that, the top of described solar panel (2) is arranged with glass cover-plate (40) in parallel, between described solar panel (2) and glass cover-plate (40), form microchannel, described microchannel is communicated with the efflux nozzle (38) on secondary air channel (37), and described secondary air channel (37) is connected with described Evaporative Cooling Air Conditioning unit (6); Described solar panel (2) is multiple lines and multiple rows by polylith solar cell and rearranges.
5. Evaporative Cooling Air Conditioning according to claim 4, is characterized in that, described Evaporative Cooling Air Conditioning unit (6), includes machine unit shell, and described machine unit shell is respectively arranged with air inlet, air outlet on relative two side;
By new wind approach axis, is disposed with air cleaner (11), surface-type heat exchanger (10), porous ceramic vertical tube indirect evaporation cooler, foam metal filler direct evaporative cooler, water fender a(18 in described machine unit shell), heater (23) and axial flow blower (19); On machine unit shell roof corresponding to the top of described porous ceramic vertical tube indirect evaporation cooler, be provided with Secondary Air exhaust outlet, in described Secondary Air exhaust outlet, be provided with overfire air fan (13);
Described Secondary Air exhaust outlet is connected with one end of described secondary air channel (37), and described efflux nozzle (38) is connected with the other end of secondary air channel (37).
6. Evaporative Cooling Air Conditioning according to claim 5, is characterized in that, is provided with air inlet valve (12) in described air inlet, is provided with outlet valve (34) in described air outlet.
7. Evaporative Cooling Air Conditioning according to claim 5, it is characterized in that, described surface-type heat exchanger (10) is the heat exchange coil vertically arranging, one end of described heat exchange coil is stretched in the diversion box (24) of buried pipe heat exchange system, and the other end of described heat exchange coil is connected with the 3rd feed pipe (49);
Described porous ceramic vertical tube indirect evaporation cooler, include porous ceramics vertical heat exchanging pipe group (16), the top of described porous ceramics vertical heat exchanging pipe group (16) is disposed with water-locator a(14), water fender b(33), the bottom of described porous ceramics vertical heat exchanging pipe group (16) is provided with header tank a(35), described porous ceramics vertical heat exchanging pipe group (16) and header tank a(35) between form air channel, on unit shell side wall corresponding to air channel, be provided with secondary air inlet (29), described header tank a(35) by the first feed pipe (47) and described water-locator a(14) be connected, on described the first feed pipe (47), be provided with water circulating pump a(28), described header tank a(35) by the first filling pipe (44), be connected with the 3rd feed pipe (49), on described the first filling pipe (44), be provided with water compensating valve a(30),
Described foam metal filler direct evaporative cooler, include foam metal filler (17), the top of described foam metal filler (17) is provided with water-locator b(15), the bottom of described foam metal filler (17) is provided with header tank b(36), described header tank b(36) by the second feed pipe (48) and described water-locator b(15) be connected, on described the second feed pipe (48), be provided with water circulating pump b(31), described header tank b(36) by the second filling pipe (45), be connected with described the 3rd feed pipe (49), on described the second filling pipe (45), be provided with water compensating valve b(32).
8. Evaporative Cooling Air Conditioning according to claim 7, is characterized in that, described porous ceramics vertical heat exchanging pipe group (16) is comprised of the many porous ceramics heat exchanger tubes that vertically arrange; Described foam metal filler (17) is the vertical side, foam metal filler edge of W type accordion or is formed along airflow direction successively parallel stack by polylith.
9. Evaporative Cooling Air Conditioning according to claim 7, is characterized in that, described the 3rd feed pipe (49) is connected with described buried pipe heat exchange system.
10. according to claim 1, Evaporative Cooling Air Conditioning described in 7 or 9, it is characterized in that, described buried pipe heat exchange system, include and be arranged at underground flatly pipe laying (26), one end of described flatly pipe laying (26) and header tank c(20) be connected, the other end of described flatly pipe laying (26) is connected with diversion box (24), and junction is provided with water circulating pump c(25), described header tank c(20), diversion box (24) is connected with attemperater (21) by tube connector respectively, described attemperater (21) is connected with described the 3rd feed pipe (49), on described the 3rd feed pipe (49), be provided with water circulating pump d(22), on described diversion box (24), be also connected with the 3rd filling pipe (46), on described the 3rd filling pipe (46), be provided with water compensating valve c(27).
CN201420114004.8U 2014-03-13 2014-03-13 Evaporative cooling air conditioner with wind-solar complementary power generation being power source Expired - Fee Related CN203757928U (en)

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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103900177A (en) * 2014-03-13 2014-07-02 西安工程大学 Evaporative cooling air-conditioning system with power provided based on wind-solar hybrid power generation
CN105091164A (en) * 2015-08-14 2015-11-25 西安工程大学 Integrated evaporative cooling air conditioner system applicable to single building

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103900177A (en) * 2014-03-13 2014-07-02 西安工程大学 Evaporative cooling air-conditioning system with power provided based on wind-solar hybrid power generation
CN103900177B (en) * 2014-03-13 2016-08-24 西安工程大学 The Evaporative Cooling Air-conditioning System of power is provided based on wind light mutual complementing power generation
CN105091164A (en) * 2015-08-14 2015-11-25 西安工程大学 Integrated evaporative cooling air conditioner system applicable to single building
CN105091164B (en) * 2015-08-14 2018-01-02 西安工程大学 Suitable for the integrated Evaporative Cooling Air-conditioning System of single building

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