CN204494562U - Ultra-thin capillary network grid heating structure - Google Patents
Ultra-thin capillary network grid heating structure Download PDFInfo
- Publication number
- CN204494562U CN204494562U CN201520136390.5U CN201520136390U CN204494562U CN 204494562 U CN204494562 U CN 204494562U CN 201520136390 U CN201520136390 U CN 201520136390U CN 204494562 U CN204494562 U CN 204494562U
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- China
- Prior art keywords
- heat conduction
- capillary network
- network grid
- heat
- backwater
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- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Fee Related
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F28—HEAT EXCHANGE IN GENERAL
- F28D—HEAT-EXCHANGE APPARATUS, NOT PROVIDED FOR IN ANOTHER SUBCLASS, IN WHICH THE HEAT-EXCHANGE MEDIA DO NOT COME INTO DIRECT CONTACT
- F28D15/00—Heat-exchange apparatus with the intermediate heat-transfer medium in closed tubes passing into or through the conduit walls ; Heat-exchange apparatus employing intermediate heat-transfer medium or bodies
- F28D15/02—Heat-exchange apparatus with the intermediate heat-transfer medium in closed tubes passing into or through the conduit walls ; Heat-exchange apparatus employing intermediate heat-transfer medium or bodies in which the medium condenses and evaporates, e.g. heat pipes
- F28D15/04—Heat-exchange apparatus with the intermediate heat-transfer medium in closed tubes passing into or through the conduit walls ; Heat-exchange apparatus employing intermediate heat-transfer medium or bodies in which the medium condenses and evaporates, e.g. heat pipes with tubes having a capillary structure
- F28D15/046—Heat-exchange apparatus with the intermediate heat-transfer medium in closed tubes passing into or through the conduit walls ; Heat-exchange apparatus employing intermediate heat-transfer medium or bodies in which the medium condenses and evaporates, e.g. heat pipes with tubes having a capillary structure characterised by the material or the construction of the capillary structure
Abstract
This practicality discloses a kind of ultra-thin capillary network grid heating structure, it comprises: the capillary network grid forming heat radiation pipe network, capillary network grid comprise the heat conduction water inlet supervisor connecting heating feed pipe and the heat conduction backwater supervisor connecting heating return pipe, be evenly equipped with and through heat conduction can intake and be responsible for and capillary thermal conductive water pipe that heat conduction backwater is responsible between heat conduction water inlet supervisor and heat conduction backwater be responsible fors; The heat insulation extruded sheet of pressure-bearing, the top side face in the heat insulation extruded sheet of pressure-bearing forms adaptive with capillary network grid and places for it cavity installed; Heat conducting floor, between heat conducting floor and the heat insulation extruded sheet of pressure-bearing, be provided with bonding gypsum layer, beneficial effect is: take hot water as heating medium, using capillary network grid as heat carrier, there is the advantages such as energy-efficient and high degree of comfort, simultaneously flexible for installation and can not original ground be destroyed.
Description
Technical field
This practicality relates to floor heating structure technical field, is specially a kind of ultra-thin capillary network grid heating structure.
Background technology
Floor heating is generally the first accumulation of heat in ground and dispels the heat, and drawback is: accurately and in time can not adjust indoor temperature, can not personalized and behavior energy saving; Be not suitable for the room that floor height is low, easily increase load to building; The ground many for toilet cleaners and polishes and placed the bedroom of furniture, cause area of dissipation limited owing to blocking, and the not thermic load requirement of general floorings heating general satisfaction, increases auxiliary heating facility and installation cost will be caused to increase; Adopt the room floors ornament materials of floor heating to be restricted, solid wooden floor board etc. should not be installed; Floor heating thermal inertia 4-6 hour, is difficult to realize personalized and fast temperature adjustment; Although dry floor heating reaction speed is fast, due to without any recuperation layer, cause fluctuations in indoor temperature large, weight capacity is poor, and service life is short.
Summary of the invention
For the problems referred to above, this practicality provides a kind of ultra-thin capillary network grid heating structure, and its main technical scheme is as follows:
Ultra-thin capillary network grid heating structure, it comprises:
Connect the through rear capillary network grid (2) forming heat radiation pipe network successively, described capillary network grid (2) comprise heat conduction water inlet supervisor (21) connecting heating feed pipe (1) and the heat conduction backwater connecting heating return pipe (3) supervisor (22), are responsible for be evenly equipped with between (22) and through heat conduction can to intake and be responsible for the capillary thermal conductive water pipe (23) that (21) and heat conduction backwater are responsible for (22) in heat conduction water inlet supervisor (21) and heat conduction backwater;
For laying the heat insulation extruded sheet of pressure-bearing (8) of capillary network grid (2), the top side face in the heat insulation extruded sheet of pressure-bearing (8) forms suitable with capillary network grid (2) and supplies its cavity placed (81);
Post in the heat conducting floor (10) of the heat insulation extruded sheet of pressure-bearing (8) top side face as heat conduction carrier, between heat conducting floor (10) and the heat insulation extruded sheet of pressure-bearing (8), be provided with bonding gypsum layer (9).
Further, described capillary thermal conductive water pipe (23) is diameter 4.3mm, the PPR pipe of wall thickness 0.8mm, spacing between adjacent capillary thermal conductive water pipe (23) is 40mm, and in every square metre of capillary network grid (2), the length of capillary thermal conductive water pipe (23) is 25m.
Further, the lateral surface of described capillary network grid (2) is provided with grey mud layer, and the thickness of described grey mud layer is 5-10mm, and the lateral surface in grey mud layer is provided with furring tile.
Further, described heating feed pipe (1) and heat conduction are intake to be responsible between (21) and are connected with into water tube connector (4), described heating return pipe (22) and heat conduction backwater are responsible between (3) and are connected with backwater tube connector (5), the two ends of described water inlet tube connector (4) and heating feed pipe (1), overall structure is fixed as respectively by elbow (6) between heat conduction water inlet supervisor (21), the two ends of described backwater tube connector (5) and heating return pipe (3), overall structure is fixed as respectively by elbow (6) between heat conduction backwater supervisor (22).
Further, when laying side by side, between heat conduction water inlet supervisor (21) of capillary network grid (2) and after fixing respectively by straight-through head (7) between heat conduction backwater supervisor (22), form heat radiation pipe network.
Further, the thickness of described bonding gypsum layer (9) is 5-10mm.
The beneficial effect of this practicality is:
1, take hot water as heating medium, using capillary network grid as heat carrier, have the advantages such as energy-efficient and high degree of comfort, capillary network can be combined with decorative layer and be arranged on indoor canopy, ground or metope simultaneously, flexible for installation and can not destroy original ground;
2, capillary network internal diameter is tiny especially, reach automatic vent effect by water surface tension, the water of capillary network flowing is low-temp low-pressure water, the conduit failure that can effectively avoid HTHP to bring, capillary network uses closed cycle water purification, can effectively avoid producing incrustation scale in pipeline;
3, ultra-thin recuperation layer, thermoregulation is fast;
4, pipeline enclosure is every little, floor temperature evenly;
5, general 55 DEG C-45 DEG C of common floor heating supply and return water temperature, general 30 DEG C-35 DEG C of capillary supply and return water temperature, than common ground warming energy-saving more than 30%, obvious energy conservation, be particularly suitable for same heat pump with the use of, reach more energy-conservation effect;
6, pipeline water resistance is little, can meet burnt gas wall hanging furnace water pump lift.
Accompanying drawing explanation
Fig. 1 is the structural representation of ultra-thin capillary network grid heating structure in embodiment
Fig. 2 is the syndeton schematic diagram of adjacent capillaries net grid in embodiment
Fig. 3 be in embodiment capillary network grid lay in place after structural representation
Detailed description of the invention
In order to make the technological means of this practicality, creation characteristic, reach object and effect is easy to understand, below in conjunction with concrete diagram, set forth this practicality further.
See Fig. 1-3, ultra-thin capillary network grid heating structure, it comprises capillary network grid 2, the heat insulation extruded sheet 8 of pressure-bearing and heat conducting floor 10, example is set to ground paving, concrete structure is: as the hot water storage tank providing thermal source, on hot water storage tank, being provided with the efferent duct for connecting heating feed pipe 1 and connecting the input pipe of heating return pipe 3, between heating feed pipe 1 and efferent duct, be provided with heating hot water circulating pump; Connect the through rear capillary network grid 2 forming heat radiation pipe network successively, capillary network grid 2 comprise the heat conduction water inlet supervisor 21 connecting heating feed pipe 1 and the heat conduction backwater supervisor 22 connecting heating return pipe 3, in heat conduction water inlet supervisor 21 and heat conduction backwater be responsible for be evenly equipped with between 22 can through heat conduction intake supervisor 21 and heat conduction backwater be responsible for 22 capillary thermal conductive water pipe 23; The heat insulation extruded sheet 8 of pressure-bearing for laying capillary network grid 2, the top side face in the heat insulation extruded sheet of pressure-bearing 8 forms suitable with capillary network grid 2 and supplies its cavity 81 placed; Post in the heat conducting floor 10 of pressure-bearing heat insulation extruded sheet 8 top side face as heat conduction carrier, between heat conducting floor 10 and the heat insulation extruded sheet 8 of pressure-bearing, be provided with bonding gypsum layer 9.During heating, the hot water in hot water storage tank is raised and is entered heat conduction water inlet supervisor 21 to the greatest extent into after heating feed pipe 1 by heating hot water circulating pump, completes heating cycle successively through capillary thermal conductive water pipe 23, heat conduction backwater supervisor 22, heating return pipe 3 after entering hot water storage tank.Hot water in capillary network grid 2 is continuable carries out heat loss through radiation, and during heat supply, in system, water temperature only needs the low-temperature water heating of 28-32 DEG C, and the surface temperature of heat exchange is absolute uniform, and surface temperature allows less than 29 DEG C, ground in European standard.
In order to increase heating surface area, uniform heat distribution can be ensured again simultaneously, see 1, as preferably, capillary thermal conductive water pipe 23 is the PPR pipe of diameter 4.3mm, wall thickness 0.8mm, spacing between adjacent capillary thermal conductive water pipe 23 is 40mm, and in every square metre of capillary network grid, the length of capillary thermal conductive water pipe 23 is 25m.
The ground many for toilet cleaners and polishes and placed the bedroom of furniture, capillary network grid 2 can be laid along metope, lateral surface in capillary network grid 2 is provided with grey mud layer, and the thickness of grey mud layer is 5-10mm, and the lateral surface in grey mud layer is provided with furring tile.
In order to solve remote heating, further improvement is, see Fig. 1, heating feed pipe 1 and heat conduction are intake between supervisor 21 and are connected with into water tube connector 4, heating return pipe 22 and heat conduction backwater are connected with backwater tube connector 5 between being responsible for 3, the two ends of water inlet tube connector 4 and heating feed pipe 1, heat conduction are intake between supervisor 21 and are fixed as overall structure respectively by elbow 6, and the two ends of backwater tube connector 5 and heating return pipe 3, heat conduction backwater are fixed as overall structure respectively by elbow 6 between being responsible for 22.
See Fig. 2, when needing multiple capillary network grid 2 to be connected, its concrete structure is that the heat conduction of adjacent capillaries net grid 2 is intake between supervisor 21 and fixes rear formation heat radiation pipe networks respectively by straight-through 7 between heat conduction backwater supervisor 22.
See Fig. 3, as preferably, in the present embodiment, the thickness of bonding gypsum layer 9 is 5-10mm.
When packed layer is 10mm ash mud layer, thermal conductivity factor is 1.84W/ (m DEG C), and wall coverings is 10mm ceramic tile, and thermal conductivity factor is 2.91W/ (m DEG C), and the heat dissipation capacity of unit are metope can by following value:
When packed layer is 10mm bonding gypsum layer, thermal conductivity factor is 1.84W/ (m DEG C), and ground decoration layer is the special heat conducting floor of 10mm floor heating, and thermal conductivity factor is 0.17W/ (m DEG C), and the heat dissipation capacity on unit are ground can by following value:
The foregoing is only the preferred embodiment of this practicality; the protection domain of this practicality is not limited in above-mentioned embodiment; every technical scheme belonging to this practical principle all belongs to the protection domain of this practicality; for a person skilled in the art; the some improvement carried out under the prerequisite of principle not departing from this practicality, these improve the protection domain that also should be considered as this practicality.
Claims (6)
1. ultra-thin capillary network grid heating structure, it is characterized in that, it comprises:
Connect the through rear capillary network grid (2) forming heat radiation pipe network successively, described capillary network grid (2) comprise heat conduction water inlet supervisor (21) connecting heating feed pipe (1) and the heat conduction backwater connecting heating return pipe (3) supervisor (22), are responsible for be evenly equipped with between (22) and through heat conduction can to intake and be responsible for the capillary thermal conductive water pipe (23) that (21) and heat conduction backwater are responsible for (22) in heat conduction water inlet supervisor (21) and heat conduction backwater;
For laying the heat insulation extruded sheet of pressure-bearing (8) of capillary network grid (2), the top side face in the heat insulation extruded sheet of pressure-bearing (8) forms suitable with capillary network grid (2) and supplies its cavity placed (81);
Post in the heat conducting floor (10) of the heat insulation extruded sheet of pressure-bearing (8) top side face as heat conduction carrier, between heat conducting floor (10) and the heat insulation extruded sheet of pressure-bearing (8), be provided with bonding gypsum layer (9).
2. ultra-thin capillary network grid heating structure according to claim 1, it is characterized in that, described capillary thermal conductive water pipe (23) is diameter 4.3mm, the PPR pipe of wall thickness 0.8mm, spacing between adjacent capillary thermal conductive water pipe (23) is 40mm, and in every square metre of capillary network grid (2), the length of capillary thermal conductive water pipe (23) is 25m.
3. ultra-thin capillary network grid heating structure according to claim 1 and 2, it is characterized in that, the lateral surface of described capillary network grid (2) is provided with grey mud layer, and the thickness of described grey mud layer is 5-10mm, and the lateral surface in grey mud layer is provided with furring tile.
4. ultra-thin capillary network grid heating structure according to claim 1, it is characterized in that, described heating feed pipe (1) and heat conduction are intake to be responsible between (21) and are connected with into water tube connector (4), described heating return pipe (22) and heat conduction backwater are responsible between (3) and are connected with backwater tube connector (5), the two ends of described water inlet tube connector (4) and heating feed pipe (1), overall structure is fixed as respectively by elbow (6) between heat conduction water inlet supervisor (21), the two ends of described backwater tube connector (5) and heating return pipe (3), overall structure is fixed as respectively by elbow (6) between heat conduction backwater supervisor (22).
5. ultra-thin capillary network grid heating structure according to claim 1, it is characterized in that, when laying side by side, between heat conduction water inlet supervisor (21) of capillary network grid (2) and after fixing respectively by straight-through head (7) between heat conduction backwater supervisor (22), form heat radiation pipe network.
6. ultra-thin capillary network grid heating structure according to claim 1, is characterized in that, the thickness of described bonding gypsum layer (9) is 5-10mm.
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CN201520136390.5U CN204494562U (en) | 2015-03-11 | 2015-03-11 | Ultra-thin capillary network grid heating structure |
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CN201520136390.5U CN204494562U (en) | 2015-03-11 | 2015-03-11 | Ultra-thin capillary network grid heating structure |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109506354A (en) * | 2017-09-14 | 2019-03-22 | 昆山开思拓空调技术有限公司 | A kind of radiation air-conditioner end equipment being integrated in ceiling board |
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2015
- 2015-03-11 CN CN201520136390.5U patent/CN204494562U/en not_active Expired - Fee Related
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109506354A (en) * | 2017-09-14 | 2019-03-22 | 昆山开思拓空调技术有限公司 | A kind of radiation air-conditioner end equipment being integrated in ceiling board |
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Granted publication date: 20150722 Termination date: 20200311 |
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