CN204612035U - A kind of photovoltaic ice conserve cold integrated air conditioning system - Google Patents
A kind of photovoltaic ice conserve cold integrated air conditioning system Download PDFInfo
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- CN204612035U CN204612035U CN201520140717.6U CN201520140717U CN204612035U CN 204612035 U CN204612035 U CN 204612035U CN 201520140717 U CN201520140717 U CN 201520140717U CN 204612035 U CN204612035 U CN 204612035U
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- controller
- column
- photovoltaic
- heat exchange
- exchange box
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/50—Photovoltaic [PV] energy
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/14—Thermal energy storage
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- Photovoltaic Devices (AREA)
- Air Conditioning Control Device (AREA)
Abstract
The utility model discloses a kind of photovoltaic ice conserve cold integrated air conditioning system, comprise photovoltaic electroplax, controller, heat exchange box and compression refigerating machine, described photovoltaic electroplax is fixedly mounted on solar bracket, described solar bracket is adjustable solar support, comprise base, rotating handles, rack column, flexible bearing diagonal, column, cant beam, crossbeam, DC controller is connected with controller by inverter, gauge tap is connected with between controller and battery, gauge tap is connected to heater and timing starter, timing starter also connects timer, compression refigerating machine passes through water pump and is connected with heat exchange box, heat exchange box connects compression refigerating machine by backheat pump again, the delivery port of backheat pump is also connected with filling pipe, in heat exchange box, blower fan is installed.The utility model adopts solar energy to change into heat energy and cold energy, reduces the use of electric energy, alleviates the phenomenon of shortage of electric power in summer, effectively utilize regenerative resource, energy-conserving and environment-protective.
Description
Technical field
The utility model relates to a kind of air-conditioning system, specifically a kind of photovoltaic ice conserve cold integrated air conditioning system.
Background technology
Along with the fast development of global economy, science and technology, every country increases the demand of the energy is also or else disconnected, non-renewable resources colliery, oil equal energy source are day by day in short supply, the carbon dioxide constantly needing to produce in consumption process of the energy and toxic gas heavy damage environment, therefore the clean energy resource such as solar energy, geothermal energy more and more comes into one's own.The utilization of current geothermal energy mainly adopts the mode of water circulation, utilizes electric flux to carry out heating and dispels the heat, consume energy huge after being turned by geothermal energy, brings larger financial burden to life.Air-conditioning system generally adopts electric energy to be combined with solar energy in the market, makes full use of regenerative resource and heats, and reduces the use of electric energy.But the air-conditioning system device that existing solar energy and electric energy combine still uses a large amount of electric energy, and in peak times of power consumption, be easy to cause shortage of electric power, therefore to have to temporary close, not only easily damage air-conditioning system like this, and Energy harvesting is low, cause the waste of energy, do not reach the requirement of energy-conserving and environment-protective.And solar energy is as a kind of natural pollution-free clean resource, it can be combined with the motive power of air-conditioning system, this kind of technology has been applied very extensive, but along with the rotation of smooth machine, is difficult to ensure that solar panel is always towards the direction faced south.
Utility model content
The purpose of this utility model is to provide a kind of photovoltaic ice conserve cold integrated air conditioning system, to solve the problem proposed in above-mentioned background technology.
For achieving the above object, the utility model provides following technical scheme:
A kind of photovoltaic ice conserve cold integrated air conditioning system, comprise photovoltaic electroplax, controller, heat exchange box and compression refigerating machine, described photovoltaic electroplax is fixedly mounted on solar bracket, described solar bracket is adjustable solar support, comprise base, rotating handles, rack column, flexible bearing diagonal, column, cant beam, crossbeam, described rack column is arranged in the inside groove of base, described rotating handles is located at chassis outer side, one end of described column is fixed on rack column by fastening bolt, and the other end of column is connected with the second hinge, one end of described flexible bearing diagonal connects the first hinge, the other end is connected with column by anchor ear connector, described crossbeam is connected with cant beam by bolt, one end of described cant beam is connected with flexible bearing diagonal by the first hinge, the second chain connection on the upper middle portion of described cant beam and column, one end of described rotating handles is provided with gear, and this gear is corresponding with described rack column, described flexible bearing diagonal is made up of the cylinder that two root radiuses are different, and has knob to control, described column and the second hinge connection can be rotated, and described flexible bearing diagonal and the first hinge connection also can be rotated, described compression refigerating machine is fixedly mounted on indoor, and battery and DC controller are connected photovoltaic electroplax respectively, and DC controller is also connected with battery, described DC controller is connected with controller by inverter, described controller connects humidification dehumidifying integrated machine, gauge tap is connected with between described controller and battery, described gauge tap is connected to heater and timing starter, described determine compression refigerating machine with time starter be connected, timing starter is also connected with timer, described compression refigerating machine passes through water pump and is connected with heat exchange box, described heat exchange box connects compression refigerating machine by backheat pump again, the delivery port of described backheat pump is also connected with filling pipe, filling pipe is provided with control valve, in described heat exchange box, blower fan is installed.
As further program of the utility model: described heat exchange box water inlet is provided with control valve, and delivery port is provided with control valve.
As the utility model further scheme: described control valve all connects on the controller.
As the utility model further scheme: described photovoltaic electric plate layer structure is from bottom to top back cover PTP hardboard successively, PVB doubling film, solar silicon wafers, PVB doubling film and glass plate formed.
As the utility model further scheme: the thickness of described photovoltaic electroplax PVB doubling film is 0.46mm, and the thickness of described glass plate is 6mm, and the thickness of described back cover PTP hardboard is 0.8mm.
Compared with prior art, the beneficial effects of the utility model are: the utility model adopts solar energy to change into the technology of heat energy and cold energy to reach the temperature in conditioning chamber, not only reduce the use of electric energy, but also alleviate the phenomenon of shortage of electric power in summer, further provided with humidification dehumidifying integrated machine simultaneously, can select under different ambient humidities and mass dryness fraction, convenient and swift; Increase adjustable solar support, select efficient photovoltaic electroplax, improve the generating efficiency of photovoltaic module; This heating installation can realize the cooling of different gradient, makes full use of the energy in water, improves the utilization rate of energy, energy-conserving and environment-protective.
Accompanying drawing explanation
Fig. 1 is the structural representation of photovoltaic ice conserve cold integrated air conditioning system;
Fig. 2 is the structural representation of solar panel in photovoltaic ice conserve cold integrated air conditioning system;
Fig. 3 is the structural representation of solar bracket in photovoltaic ice conserve cold integrated air conditioning system;
Fig. 4 is the gear assembly detail drawing of solar bracket in photovoltaic ice conserve cold integrated air conditioning system;
Fig. 5 is the flexible bearing diagonal enlarged drawing of solar bracket in photovoltaic ice conserve cold integrated air conditioning system;
In figure: 1-photovoltaic electroplax, 2-battery, 3-solar bracket, 4-inverter, 5-controller, 6-gauge tap, 7-air-heater, 8-heater, 9-humidification dehumidifying integrated machine, 10-heat exchange box, 11-blower fan, 12-control valve, 13-control valve, 14-goes out water pump, 15-meeting heat pump, 16-timing starter, 17-compression refigerating machine, 18-timer, 19-DC controller, 101-glass plate, 102-PVB doubling film, 103-solar silicon wafers, 104-back cover PTP hardboard, 301-base, 302-rotating handles, 303-rack column, 304-stretches bearing diagonal, 305-column, 306-cant beam, 307-crossbeam, 308-fastening bolt, 309-first hinge, 310-anchor ear connector, 311-second hinge, 312-gear, 313-knob.
Detailed description of the invention
Be described in more detail below in conjunction with the technical scheme of detailed description of the invention to this patent.
Refer to Fig. 1-3, a kind of photovoltaic ice conserve cold integrated air conditioning system, comprise photovoltaic electroplax 1, solar bracket 3, controller 5, heat exchange box 10 and compression refigerating machine 17, described photovoltaic electroplax 1 fixedly mounts on solar bracket 3, described solar bracket 3 is adjustable solar support, as Fig. 3-5, comprise base 301, rotating handles 302, rack column 303, flexible bearing diagonal 304, column 305, cant beam 306, crossbeam 307, described rack column 303 is arranged in the inside groove of base 301, described rotating handles 302 is located at outside base 301, one end of described column 305 is fixed on rack column 303 by fastening bolt 308, and the other end of column 305 is connected with the second hinge 311, one end of described flexible bearing diagonal 304 connects the first hinge 309, the other end is connected on column 305 by anchor ear connector 310, described crossbeam 307 is bolted on cant beam 306, one end of described cant beam 306 is connected with flexible bearing diagonal 304 by the first hinge 309, the upper middle portion of described cant beam 306 is connected with the second hinge 311 on column 305, one end of described rotating handles 302 is provided with gear 312, and this gear 312 is corresponding with described rack column 303, by regulating rotating handles 302 to rotate by driven gear 312, and then driving rack column 303 to move up and down, reaching the effect of adjustment height, described flexible bearing diagonal 304 is made up of the cylinder that two root radiuses are different, and has knob 313 to control, and arbitrarily can change the length of flexible bearing diagonal 304 in certain limit, described column 305 and the second hinge 311 junction can be rotated, and this external extension bearing diagonal 304 and the first hinge 309 junction also can be rotated.Described compression refigerating machine 17 is fixedly mounted on indoor, battery 2 is connected photovoltaic electroplax 1 respectively with DC controller 19, DC controller 19 is also connected with battery 2, photovoltaic electroplax 1 produce electric energy do not use or excessive time be stored in battery 2, can be controller 5 and heater 8 energy supply when power-off, DC controller 19 is connected with controller 5 by inverter 4, described controller 5 connects humidification dehumidifying integrated machine 9, can according to season, the different choice humidification in geographical position or dehumidifying, make indoor environment more comfortable, connection control switch 6 between controller 5 and battery 2, gauge tap 6 is connected to heater 8 and timing starter 16, the electric energy that photovoltaic electroplax 1 produces is by DC controller 3, the effect of inverter 4 and controller 5, control heater 8 works and produces heat energy, the heat of generation is blown into indoor by the air-heater 7 on heater 8, maintain indoor temperature.
Described determine compression refigerating machine 17 with time starter 16 be connected, timing starter 16 is also connected with timer 18, is set in the low ebb time of actual electricity consumption the time of timer 18, when the time enters the low ebb phase, timer 18 starts, and timing starter 16 is opened simultaneously, and control compression refigerating machine 17 and work, stored water is freezed, the water of storage is become ice, thus store certain cold energy; By day, the electric energy that photovoltaic electroplax 1 produces not only can store, and also controls compression refigerating machine 17 by controller 5 and works, solar energy is changed into the cold energy of water to store for future use; Compression refigerating machine 17 passes through water pump 14 and is connected with heat exchange box 10, described heat exchange box 10 is connected on compression refigerating machine 17 by backheat pump 15 again, the delivery port of described backheat pump 15 is also connected with filling pipe, filling pipe is provided with control valve 12, in described heat exchange box 10, blower fan 11 is installed, the water inlet of described heat exchange box 10 is provided with control valve 12, and delivery port is provided with control valve 13, and all control valves 12 are all connected on controller 5.By controller 5 regulable control control valve 12, heat exchanging case 10 carries out moisturizing, by the effect of blower fan 11, the heat energy in water and air is carried out quick heat exchange, to reduce the temperature in air, reaches the object of cooling.
Refer to Fig. 2, the layer structure of the photovoltaic electroplax 1 in this photovoltaic ice conserve cold integrated air conditioning system is as follows: be back cover PTP hardboard 104 from below to up successively, PVB doubling film 102, solar silicon wafers 103, PVB doubling film 102 and glass plate 101 formed, wherein the thickness of PVB doubling film 102 is 0.46mm, the thickness of described glass plate 101 is 6mm, and the thickness of described back cover PTP hardboard 104 is 0.8mm.Because PVB doubling film 102 has good light transmission, water white transparency, between glass, its light transmittance of sandwiched multilayer is also more than 98%, and has very strong caking ability (70kg/m with silicon chip
2), high temperature resistantly reach 200 DEG C, cold-resistantly can reach-60 DEG C, service life can reach 30 years, therefore power generation plate is transparency, high temperature resistant cold tolerance or all have service life significantly improves to adopt PVB doubling film 102 to make, and not only increases properties of product, and reduces cost.
Above the better embodiment of this patent is explained in detail, but this patent is not limited to above-mentioned embodiment, in the ken that one skilled in the relevant art possesses, can also makes a variety of changes under the prerequisite not departing from this patent aim.
Claims (5)
1. a photovoltaic ice conserve cold integrated air conditioning system, comprise photovoltaic electroplax, controller, heat exchange box and compression refigerating machine, it is characterized in that, described photovoltaic electroplax is fixedly mounted on solar bracket, described solar bracket is adjustable solar support, comprise base, rotating handles, rack column, flexible bearing diagonal, column, cant beam, crossbeam, described rack column is arranged in the inside groove of base, described rotating handles is located at chassis outer side, one end of described column is fixed on rack column by fastening bolt, and the other end of column is connected with the second hinge, one end of described flexible bearing diagonal connects the first hinge, the other end is connected with column by anchor ear connector, described crossbeam is connected with cant beam by bolt, one end of described cant beam is connected with flexible bearing diagonal by the first hinge, the second chain connection on the upper middle portion of described cant beam and column, one end of described rotating handles is provided with gear, and this gear is corresponding with described rack column, described flexible bearing diagonal is made up of the cylinder that two root radiuses are different, and has knob to control, described column and the second hinge connection can be rotated, and described flexible bearing diagonal and the first hinge connection also can be rotated, described compression refigerating machine is fixedly mounted on indoor, and battery and DC controller are connected photovoltaic electroplax respectively, and DC controller is also connected with battery, described DC controller is connected with controller by inverter, described controller connects humidification dehumidifying integrated machine, gauge tap is connected with between described controller and battery, described gauge tap is connected to heater and timing starter, described determine compression refigerating machine with time starter be connected, timing starter is also connected with timer, described compression refigerating machine passes through water pump and is connected with heat exchange box, described heat exchange box connects compression refigerating machine by backheat pump again, the delivery port of described backheat pump is also connected with filling pipe, filling pipe is provided with control valve, in described heat exchange box, blower fan is installed.
2. photovoltaic ice conserve cold integrated air conditioning system according to claim 1, is characterized in that, described heat exchange box water inlet is provided with control valve, and delivery port is provided with control valve.
3. photovoltaic ice conserve cold integrated air conditioning system according to claim 1 and 2, it is characterized in that, described control valve all connects on the controller.
4. photovoltaic ice conserve cold integrated air conditioning system according to claim 3, is characterized in that, described photovoltaic electric plate layer structure is from bottom to top back cover PTP hardboard successively, PVB doubling film, solar silicon wafers, PVB doubling film and glass plate formed.
5. photovoltaic ice conserve cold integrated air conditioning system according to claim 4, is characterized in that, the thickness of described photovoltaic electroplax PVB doubling film is 0.46mm, and the thickness of described glass plate is 6mm, and the thickness of described back cover PTP hardboard is 0.8mm.
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CN201520140717.6U CN204612035U (en) | 2015-03-12 | 2015-03-12 | A kind of photovoltaic ice conserve cold integrated air conditioning system |
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CN201520140717.6U CN204612035U (en) | 2015-03-12 | 2015-03-12 | A kind of photovoltaic ice conserve cold integrated air conditioning system |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN105201777A (en) * | 2015-09-10 | 2015-12-30 | 张家政 | Photovoltaic air compressor system |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN105201777A (en) * | 2015-09-10 | 2015-12-30 | 张家政 | Photovoltaic air compressor system |
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C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
CF01 | Termination of patent right due to non-payment of annual fee | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20150902 Termination date: 20160312 |