CN204574274U - The terminal radiation structure of capillary radiation air-conditioning - Google Patents

Abstract

The utility model discloses a kind of terminal radiation structure of capillary radiation air-conditioning, be arranged on the furred ceiling in room or/and wall is or/and on floor, comprise surface of wall by inner the plank layer, the rubber heat-insulation layer that set gradually outward, the outer surface of described rubber heat-insulation layer is provided with plasterboard heat-conducting layer, and described plasterboard heat-conducting layer outer surface arranges capillary network; Described capillary network surface is provided with gluing gypsic horizon; Described plank layer is fixed on surface of wall; Described rubber heat-insulation layer is bonded in plank layer surface.The terminal radiation structure of capillary radiation air-conditioning of the present utility model, solve the problem of capillary radiation air-conditioning body of wall condensation when not freezing in inner wall of building adjacent room, construction technology aspect is simple, convenient.

Description

The terminal radiation structure of capillary radiation air-conditioning

Technical field

The utility model relates to air conditioner technical field, particularly relates to a kind of terminal radiation structure of capillary radiation air-conditioning.

Background technology

Modern social development is rapid, people require more and more higher for healthy, comfortable work living environment, a series of air-conditioning disease problems that traditional air-conditioning system is brought due to its high energy consumption, noise is large, blowing feeling is uncomfortable etc., obviously be difficult to meet the high degree of comfort requirement of modern to life, capillary radiation air-conditioning system can solve this series of problems just, but capillary radiation air-conditioning system also exists certain problem.

The terminal radiation structure of capillary radiation air-conditioning is capillary room, and capillary room can realize branch control.When some room does not need can close temperature controller in room when freezing, temperature controller closes capillary water route by the two-way electronic valve connected, can not freeze in room, and other room needs refrigeration, then temperature controller is opened, open capillary water route by the two-way electronic valve connected, freeze in room.Capillary is arranged on wall-body energy saving, is freezed by cooling wall surface radiation, and surface of wall temperature is reduced to 19 DEG C.Because architecture indoor wall is not generally incubated, the temperature in non-brake method room is high, the temperature in refrigeration room is low, if these two rooms are adjacent, then two rooms can produce the temperature difference, and the body of wall separating two rooms can produce heat transfer, and cold is delivered to the inner wall surface of the body of wall of next room by the inner wall surface in the room that freezes, if next door body of wall temperature is lower than the dew-point temperature in room, then can condense by the surface of wall in non-brake method room.

Utility model content

For the defect of above-mentioned prior art, the utility model provides a kind of terminal radiation structure of capillary radiation air-conditioning, stops the heat transfer of body of wall between adjacent non-brake method room and refrigeration room, prevents the surface of wall dew condensation phenomenon in non-brake method room from occurring.

To achieve these goals, the technical solution of the utility model is:

A kind of terminal radiation structure of capillary radiation air-conditioning, be arranged on the furred ceiling in room or/and wall is or/and on floor, comprise surface of wall by inner the plank layer, the rubber heat-insulation layer that set gradually outward, the outer surface of described rubber heat-insulation layer is provided with plasterboard heat-conducting layer, and described plasterboard heat-conducting layer outer surface arranges capillary network; Described capillary network surface is provided with gluing gypsic horizon; Described plank layer is fixed on surface of wall; Described rubber heat-insulation layer is bonded in plank layer surface.

As the improvement to technique scheme, described capillary network is fixed on plasterboard heat-conducting layer by geometrical clamp.

As the improvement to technique scheme, the thickness of described plank layer is 18 ~ 20mm.

As the improvement to technique scheme, the thickness of described plasterboard heat-conducting layer is 10 ~ 12mm.

Suppose indoor design: T=25 DEG C; Φ=55%;

Air-conditioning supply and return water temperature: 17/20 DEG C;

Indoor design: T=29 DEG C; Φ=65%; T ₀=21.8 DEG C;

Look into " practical heat supplying air conditioning design manual " and have following form:

Structure title	Thickness m	Heat transfer coefficient W/ (m 2*℃)
			Fine gauze is laid bricks	0.12	0.76
Plasterboard	0.012	0.33
			Fibrous plaster	0.012	0.3

Calculation and check when body of wall adopts rubber and plastic to be incubated:

Wherein:

Tw1___ capillary lays wall-body energy saving temperature DEG C

T shows ' _ _ _ capillary laying exterior surface of wall temperature DEG C

The environment temperature DEG C of tf2___ adjacent room

1___ plasterboard thickness m

2___ insulating rubber plastic thickness m

3___ brick wall is built a wall thickness m

2___ lays capillary body of wall screed-coat coefficient of heat transfer w/m DEG C

1___ plasterboard thermal conductivity factor w/m DEG C

2___ insulating rubber plastic thermal conductivity factor w/m DEG C

3___ brick wall is built a wall thermal conductivity factor w/m DEG C

Bring above known conditions into above formula to draw:

Be not incubated

Obtain t table=18.54 DEG C of < 21.8 DEG C, condensation;

Insulation

2=0.018m, therefore thickness can be selected to be that the insulating rubber plastic of 20mm carries out being incubated with anti-condensation.

By finding out that the room laying capillary radiation system before adding insulating rubber plastic faces room surface of wall when freezing and there will be dew condensation phenomenon above, and do not condense after adding plank layer, rubber heat-insulation layer after laying capillary radiation system, therefore the design's patent is body of wall condensation trouble when can solve the non-heating in capillary radiation system adjacent room.

Compared with prior art, the utility model has the following advantages:

The terminal radiation structure of capillary radiation air-conditioning of the present utility model, solve the problem of capillary radiation air-conditioning body of wall condensation when not freezing in inner wall of building adjacent room, construction technology aspect is simple, convenient.

Accompanying drawing explanation

Fig. 1 is structural representation of the present utility model;

In figure: 1-plank layer; 2-rubber heat-insulation layer; 3-plasterboard heat-conducting layer; 4-capillary network; 5-gluing gypsic horizon; 6-body of wall.

Detailed description of the invention

Below in conjunction with drawings and Examples, detailed description of the invention of the present utility model is described in further detail.Following instance for illustration of the utility model, but is not used for limiting scope of the present utility model.

As shown in Figure 1, the terminal radiation structure of capillary radiation air-conditioning of the present utility model, be arranged on the furred ceiling in room or/and wall is or/and on floor, comprise body of wall 6 surface by inner the plank layer 1, the rubber heat-insulation layer 2 that set gradually outward, the outer surface of described rubber heat-insulation layer 2 is provided with plasterboard heat-conducting layer 3, and described plasterboard heat-conducting layer 3 outer surface arranges capillary network 4; Described capillary network 4 surface is provided with gluing gypsic horizon 5; Described plank layer 1 is fixed on body of wall 6 on the surface; Described rubber heat-insulation layer 2 is bonded in plank layer surface.

Described capillary network 4 is fixed on plasterboard heat-conducting layer 3 by geometrical clamp.

The thickness of described plank layer 1 is 18 ~ 20mm.

The thickness of described plasterboard heat-conducting layer 3 is 10 ~ 12mm.

Concrete construction method first on the surface of body of wall or floor, follows closely the lumps of wood with bolt, and lumps of wood length is laid area with capillary and specifically determined, lumps of wood thickness 20mm; Then brush one deck glue on floor or metope, is pasted onto insulation material in slab surfaces; Next nail on the plasterboard of 10mm thickness at the flat bed of the lumps of wood and insulation material, at gypsum board surface brush coating, capillary is laid on gypsum surface and is then fixed with geometrical clamp, levelling with gypsum plastering capillary after the glue solidifies.

The foregoing is only preferred embodiment of the present utility model; not in order to limit the utility model; all within spirit of the present utility model and principle, any amendment done, equivalent replacement, improvement etc., all should be included within protection domain of the present utility model.

Claims (4)

1. the terminal radiation structure of a capillary radiation air-conditioning, it is characterized in that, be arranged on the furred ceiling in room or/and wall is or/and on floor, comprise surface of wall by inner the plank layer, the rubber heat-insulation layer that set gradually outward, the outer surface of described rubber heat-insulation layer is provided with plasterboard heat-conducting layer, and described plasterboard heat-conducting layer outer surface arranges capillary network; Described capillary network surface is provided with gluing gypsic horizon; Described plank layer is fixed on surface of wall; Described rubber heat-insulation layer is bonded in plank layer surface.

2. the terminal radiation structure of capillary radiation air-conditioning as claimed in claim 1, it is characterized in that, described capillary network is fixed on plasterboard heat-conducting layer by geometrical clamp.

3. the terminal radiation structure of capillary radiation air-conditioning as claimed in claim 2, it is characterized in that, the thickness of described plank layer is 18 ~ 20mm.

4. the terminal radiation structure of capillary radiation air-conditioning as claimed in claim 2, it is characterized in that, the thickness of described plasterboard heat-conducting layer is 10 ~ 12mm.