CN202692537U - Residential energy-storage self-circulation constant temperature system - Google Patents
Residential energy-storage self-circulation constant temperature system Download PDFInfo
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- CN202692537U CN202692537U CN 201220378635 CN201220378635U CN202692537U CN 202692537 U CN202692537 U CN 202692537U CN 201220378635 CN201220378635 CN 201220378635 CN 201220378635 U CN201220378635 U CN 201220378635U CN 202692537 U CN202692537 U CN 202692537U
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Abstract
The utility model discloses a residential energy-storage self-circulation constant temperature system, which comprises a temperature regulation system and a self-circulation driving system. The temperature regulation system comprises an energy storage tank (4), a heat supply regulation system and a cold supply regulation system. The energy storage tank (4) comprises facade walls (41) of a house. The self-circulation driving system comprises a heating driving vertical pipe (8) and a cooling driving vertical pipe (5), which are vertically arranged indoors. The residential energy-storage self-circulation constant temperature system can be used for heating and cooling, and also can uniformly supply cold and heat to a plurality of rooms of a plurality of floors at the same time. Water with a temperature difference and different densities is naturally circulated in a pipeline, and a pipe coil circulating water pump is not required to be arranged, so that energy resources are saved, and the system is low in application cost and favorable for popularization.
Description
[technical field]
The utility model relates to the heating of dwelling house room temperature and the constant temperature system of refrigeration, relates in particular to a kind of accumulation of energy dwelling house self-loopa constant temperature system.
[background technology]
At present, the air conditioning of dwelling house has begun applied solar energy and energy accumulation air conditioner is regulated the dwelling house room temperature, namely builds the accumulation of energy pond and utilize the solar-heating accumulation of energy below dwelling house, reaches the effect to the room heat supply.But there are so several problems not solve: 1, can not be to cooling between housing types; 2, be difficult to a plurality of rooms heat supply more than two-layer; 3, the accumulation of energy pond build in underground, the building difficulty large, cost is high.4, the hot water in the accumulation of energy pond need use water pump to carry out the heat release circulation, and water pump expends certain electric energy.
[utility model content]
For the shortcoming of prior art, the purpose of this utility model is to provide a kind of accumulation of energy dwelling house self-loopa constant temperature system, and the adjustment pattern that exists with the solution prior art is single, needs use power-equipment and construction and the higher problem of operating cost.
The technical scheme that its technical problem that solves the utility model adopts is: a kind of accumulation of energy dwelling house self-loopa constant temperature system is provided, includes humidity control system and self-loopa drive system, it is characterized in that:
Described humidity control system comprises the accumulation of energy groove, supplies heat regulating system and cooling regulating system;
Described accumulation of energy groove comprises the vertical plane wall in house, and upper water-distributing device, lower water-distributing device are loaded on respectively top and the bottom of accumulation of energy groove;
Describedly be connected with heat power supply device, the first accumulation of heat valve, accumulation of energy groove bottom, lower water-distributing device in turn, heat coil pipe, heat and drive standpipe, heat supply valve, accumulation of energy groove top, upper water-distributing device, the second accumulation of heat valve and the company's of returning heat power supply device for heat regulating system;
Described cooling regulating system is connected with cold source device, the first cold-storage valve, accumulation of energy groove top, upper water-distributing device, refrigeration coil, refrigeration driving standpipe, cooling valve, accumulation of energy groove bottom, lower water-distributing device, the second cold-storage valve and the company's of returning cold source device in turn;
Described self-loopa drive system comprises that setting is installed on indoor heating and drives standpipe and refrigeration driving standpipe.
The described driving standpipe that heats can be straight tube or coil pipe with refrigeration driving standpipe.
During the winter accumulation of heat, open the first and second accumulation of heat valves, close the first and second cold-storage valves and cooling valve, hold over system is devoted oneself to work, the hot water that heat power supply device provides is transported to the accumulation of energy groove by upper water-distributing device, cold water in the accumulation of energy groove is recycled to heat power supply device by lower water-distributing device and heats, and closes the first and second accumulation of heat valves after the hot water in the accumulation of energy groove holds completely, and accumulation of energy groove accumulation of heat operating mode finishes.
During the winter heat supply, open the heat supply valve, close the first and second cold-storage valves and cooling valve, devote oneself to work for heat regulating system, the accumulation of energy groove enters by lower water-distributing device and heats the driving standpipe, erect the indoor effect that the driving standpipe is subjected to outdoor low temperature that heats that is installed on this moment, water temperature in the standpipe descends, and the density of water increases, sedimentation downwards under Action of Gravity Field, what enter the below, room heats coil pipe to the room heat supply, makes for the water in the heat regulating system and enters the self-loopa state.
Summer is during cold-storage, open the first and second cold-storage valves, close the first and second accumulation of heat valves and heat supply valve, cold accumulation system is devoted oneself to work, the cold water that cool source apparatus provides is transported to the accumulation of energy groove by lower water-distributing device, hot water in the accumulation of energy groove is recycled to cold source device by upper water-distributing device lowers the temperature, and closes the first and second cold-storage valves after the cold water in the accumulation of energy groove holds completely, and accumulation of energy groove charging finishes.
Summer is during cooling, open the cooling valve, close the first and second accumulation of heat valves and heat supply valve, the cooling regulating system is devoted oneself to work, and the accumulation of energy groove enters refrigeration by lower water-distributing device and drives standpipe, erect the effect that indoor refrigeration driving standpipe is subjected to outdoor high temperature that is installed on this moment, water temperature in the standpipe rises, and the density of water reduces, and moves upward under buoyancy, enter the refrigeration coil of top, room to the room cooling, make the water in the cooling regulating system enter the self-loopa state.
The beneficial effects of the utility model are: accumulation of energy dwelling house self-loopa constant temperature system not only can heat, and can freeze, and the energy while is to the even cold and heat supply in a plurality of rooms of a plurality of floors.The temperature difference of utilizing water is different from density, and Natural Circulation in pipeline does not need to install the coil pipe water circulating pump, energy savings, and application cost is low, and in addition, construction of the present utility model is easily, cost is lower, is beneficial to penetration and promotion.
[description of drawings]
The utility model will be further described below in conjunction with accompanying drawing.
Fig. 1 is structural representation of the present utility model.
Among the figure: 1 for heat power supply device, 3 for heat coil pipe, 4 for the accumulation of energy groove, 41 for the vertical plane wall in house, 5 for refrigeration drive standpipe, 6 for cold source device, 7 for refrigeration coil, 8 for heat drive standpipe, 21,22,23 for the room, 51 for upper water-distributing device, 52 for lower water-distributing device, 11 be that the first accumulation of heat valve, 12 is that the second accumulation of heat valve, 13 is that heat supply valve, 61 is that the first cold-storage valve, 62 is that the second cold-storage valve, 63 is that cooling valve, 71 is the second cooling valve.
[specific embodiment]
Referring to accompanying drawing, a kind of accumulation of energy dwelling house of the utility model self-loopa constant temperature system includes humidity control system and self-loopa drive system, it is characterized in that:
Described humidity control system comprises accumulation of energy groove 4, supplies heat regulating system and cooling regulating system;
Described accumulation of energy groove 4 comprises the vertical plane wall 41 in house;
Upper water-distributing device 51, lower water-distributing device 52 are loaded on respectively top and the bottom of accumulation of energy groove 4;
Describedly be connected with heat power supply device 1, the first accumulation of heat valve 11, accumulation of energy groove 4 bottoms, lower water-distributing device 52 in turn, heat coil pipe 3, heat and drive standpipe 8, heat supply valve 13, accumulation of energy groove 4 tops, upper water-distributing device 51, the second accumulation of heat valve 12 and the company's of returning heat power supply device 1 for heat regulating system;
Described cooling regulating system is connected with cold source device 6, the first cold-storage valve 61, accumulation of energy groove 4 tops, upper water-distributing device 51, refrigeration coil 7, refrigeration driving standpipe 5, cooling valve 63, accumulation of energy groove 4 bottoms, lower water-distributing device 52, the second cold-storage valve 62 and the company's of returning cold source device 6 in turn;
Described self-loopa drive system comprises that setting is installed on indoor heating and drives standpipe 8 and refrigeration driving standpipe 5.
The described driving standpipe 8 that heats can be straight tube or coil pipe with refrigeration driving standpipe 5.
During the winter accumulation of heat, open the first and second accumulation of heat valves 11,12, close the first and second cold- storage valves 61,62 and cooling valve 63, hold over system is devoted oneself to work, the hot water that heat power supply device 1 provides is transported to accumulation of energy groove 4 by upper water-distributing device 51, cold water in the accumulation of energy groove 4 are recycled to heat power supply device 1 by lower water-distributing device 52 and heat, and close the first and second accumulation of heat valves 11,12 after the hot water in the accumulation of energy groove 4 holds completely, and accumulation of energy groove 4 accumulation of heat operating modes finish.
During the winter heat supply, open heat supply valve 13, close the first and second cold- storage valves 61,62 and cooling valve 63, devote oneself to work for heat regulating system, accumulation of energy groove 4 enters to heat by lower water-distributing device 52 and drives standpipe 8, erect the indoor effect that driving standpipe 8 is subjected to outdoor low temperature that heats that is installed on this moment, water temperature in the standpipe descends, the density of water increases, sedimentation downwards under Action of Gravity Field, what enter room 21,22,23 belows heats coil pipe 3 to the room heat supply, makes for the water in the heat regulating system and enters the self-loopa state.
Summer is during cold-storage, open the first and second cold- storage valves 61,62, close the first and second accumulation of heat valves 11,12 and heat supply valve 13, cold accumulation system is devoted oneself to work, the cold water that cool source apparatus 6 provides is transported to accumulation of energy groove 4 by lower water-distributing device 52, hot water in the accumulation of energy groove 4 are recycled to cold source device 6 by upper water-distributing device 51 lowers the temperature, and closes the first and second cold- storage valves 61,62 after the cold water in the accumulation of energy groove 4 holds completely, and accumulation of energy groove 4 chargings finish.
Summer is during cooling, open cooling valve 63, close the first and second accumulation of heat valves 11,12 and heat supply valve 13, the cooling regulating system is devoted oneself to work, accumulation of energy groove 4 enters refrigeration by lower water-distributing device 52 and drives standpipe 5, erect the effect that indoor refrigeration driving standpipe 5 is subjected to outdoor high temperature that is installed on this moment, water temperature in the standpipe rises, the density of water reduces, under buoyancy, move upward, enter the refrigeration coil 7 of room 21,22,23 tops to the room cooling, make the water in the cooling regulating system enter the self-loopa state.
Claims (2)
1. an accumulation of energy dwelling house self-loopa constant temperature system includes humidity control system and self-loopa drive system, it is characterized in that:
Described humidity control system comprises accumulation of energy groove (4), supplies heat regulating system and cooling regulating system;
Described accumulation of energy groove (4) comprises the vertical plane wall (41) in house, and (52 are loaded on respectively top and the bottom of accumulation of energy groove (4) for upper water-distributing device (51), lower water-distributing device;
Describedly be connected with heat power supply device (1), the first accumulation of heat valve (11), accumulation of energy groove (4) bottom, lower water-distributing device (52) in turn, heat coil pipe (3), heat and drive standpipe (8), heat supply valve (13), accumulation of energy groove (4) top, upper water-distributing device (51), the second accumulation of heat valve (12) and the company's of returning heat power supply device (1) for heat regulating system;
Described cooling regulating system is connected with cold source device (6), the first cold-storage valve (61), accumulation of energy groove (4) top, upper water-distributing device (51), refrigeration coil (7), refrigeration driving standpipe (5), cooling valve (63), accumulation of energy groove (4) bottom, lower water-distributing device (52), the second cold-storage valve (62) and the company's of returning cold source device (6) in turn;
Described self-loopa drive system comprises that setting is installed on indoor heating and drives standpipe (8) and refrigeration driving standpipe (5).
2. accumulation of energy dwelling house self-loopa constant temperature system according to claim 1 is characterized in that: described heating drives standpipe (8) and refrigeration driving standpipe (5) can be straight tube or coil pipe.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN 201220378635 CN202692537U (en) | 2012-08-01 | 2012-08-01 | Residential energy-storage self-circulation constant temperature system |
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN 201220378635 CN202692537U (en) | 2012-08-01 | 2012-08-01 | Residential energy-storage self-circulation constant temperature system |
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| CN202692537U true CN202692537U (en) | 2013-01-23 |
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| CN 201220378635 Expired - Lifetime CN202692537U (en) | 2012-08-01 | 2012-08-01 | Residential energy-storage self-circulation constant temperature system |
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102759221A (en) * | 2012-08-01 | 2012-10-31 | 苏彬诚 | Energy-storage residence self-circulation constant temperature system |
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2012
- 2012-08-01 CN CN 201220378635 patent/CN202692537U/en not_active Expired - Lifetime
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102759221A (en) * | 2012-08-01 | 2012-10-31 | 苏彬诚 | Energy-storage residence self-circulation constant temperature system |
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| TR01 | Transfer of patent right |
Effective date of registration: 20131126 Address after: 516200, Huizhou District, Guangdong City, Huiyang province Surabaya freshwater lake commercial residential area Peninsula 1 Garden 3, 1, 26, 27 shops Patentee after: GUANGDONG HAIPENGRENJU SCIENCE & TECHNOLOGY CO., LTD. Address before: Room 2002-2003, Seven Star Commercial Plaza, Meilong Road, Baoan District, Shenzhen, Guangdong, 518000 Patentee before: Su Bincheng |
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| AV01 | Patent right actively abandoned |
Granted publication date: 20130123 Effective date of abandoning: 20141105 |
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| AV01 | Patent right actively abandoned |
Granted publication date: 20130123 Effective date of abandoning: 20141105 |
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| RGAV | Abandon patent right to avoid regrant |