CN108954479A - A kind of thermally conductive mortar energy-saving ground heating laying method of no aluminium film - Google Patents

Abstract

The invention discloses a kind of no thermally conductive mortar energy-saving ground heating laying method of aluminium film, the first step is laid with insulation board；Second step wraps up coil pipe with the thermally conductive mortar of cracking resistance, coil pipe is fixed on above insulation board；Third step, with the thermally conductive mortar levelling of cracking resistance, to final set；4th step, whole face pour the thermally conductive mortar of lightweight with self-leveling, after solidification, are conserved.The thermally conductive mortar of cracking resistance has superpower bonding force in the present invention, can have good cementability with plastics, metal etc., and water flow is avoided to resonate abnormal sound；The thermally conductive screed of lightweight is also as heat dissipation media, due to being cement-based material, the service life even can with build the same service life, can guarantee the long-term efficient operation of ground heating system；Opposite conventional wet is constructed in the present invention, due to largely using the thermally conductive mortar of lightweight (density about 800-900kg/m³), and concrete cover density used in traditional method is about 2000kg/m³, thus substantially reduce the weight of ground heating system.

Description

A kind of thermally conductive mortar energy-saving ground heating laying method of no aluminium film

Technical field

The present invention relates to low temperature field of heating more particularly to a kind of thermally conductive mortar energy-saving ground heating laying methods of no aluminium film.

Background technique

There are two types of existing conventional wet laying methods, the first is, the insulation board of not trough of belt is first laid with, without groove Insulation board on be laid with reflectance coating or aluminium film (total 3-3.5cm is thick), then in fixation coil pipe (2cm high), then cover coagulation again Soil layer (5cm is thick), about 8-8.5cm is thick in total.Second is the insulation board (3-3.5cm is thick) for being first laid with trough of belt, in insulation board It is placed in slotCoil pipe, upper berth aluminium film, then oversite concrete layer (3cm thick), about 6-6.5cm is thick in total.

The shortcomings that above-mentioned laying method, is as follows:

Although 1, temperature uniformity is better than traditional heat sinks, the cold and hot temperature difference generally also at 3 DEG C or more, frequently even reaches To 10 DEG C, however it remains drawback uneven in temperature largely effects on people's lives comfort level.

2, hot-water heating operation in usually due to concrete shrinkage is larger and with coil pipe bonding force it is weaker so that coil pipe and concrete Interlayer is not combined closely, cause to occur unfixed point not timing " drone " etc. water flows resonance abnormal sound, especially night make us it is bitter not It may say.

3, aluminium film initial stage used can also basic guarantee flooring the relatively uniform and upward heat dissipation capacity of temperature, and at present The problem of warm boundary dare not all face directly is that aluminium film is corroded completely for basic 3-6 months under the erosion of concrete and moisture, long 2-3 can be maintained, so that it is not too hot many household ground heating later periods occur, the bad problem of effect.

4, after conventional wet construction, place is due to temperature unevenness, contracting where concrete is very easy to cracking, especially coil pipe Swollen inconsistent, brittleness is larger again for concrete itself, cause usually not go out Heating Season will serious cracking, seriously affect use Effect.

5, conventional wet is constructed, and since concrete cover density is very big, every square meter is to building weight gain on the left side 60-100kg The right side greatly reduces building life, or increases building structure cost.

To solve the above problems, being now badly in need of a kind of thermally conductive mortar energy-saving ground heating laying method of no aluminium film, it to be used for ground heater laying.

Summary of the invention

The object of the present invention is to provide a kind of no thermally conductive mortar energy-saving ground heating laying methods of aluminium film, keep floor heating more comfortable, Using effect is good, long service life.

In order to solve the above technical problems, the present invention adopts the following technical scheme:

A kind of no thermally conductive mortar energy-saving ground heating laying method of aluminium film of the present invention,

The first step is laid with insulation board；

Second step wraps up coil pipe with the thermally conductive mortar of cracking resistance, coil pipe is fixed on above insulation board；

Third step, with the thermally conductive mortar levelling of cracking resistance, to final set；

4th step, whole face pour the thermally conductive mortar of lightweight with self-leveling, after solidification, are conserved.

Further, in the first step, the insulation board of laying is trough of belt insulation board；

In second step, by the slot of coil pipe indentation insulation board, the thermally conductive mortar of cracking resistance is poured into coil pipe and slot using tool Gap in, make to flush above the thermally conductive mortar of cracking resistance and insulation board, coil pipe covered；

In third step, using the thermally conductive mortar of cracking resistance with self-leveling, progress is levelling, to final set.

Further, in second step, the tool used is water clock or beaker.

Further, in third step, the thermally conductive mortar thickness of cracking resistance with self-leveling is 2-3mm.

Further, in the 4th step, the thermally conductive mortar thickness of lightweight with self-leveling is 2-4cm.

Further, in the first step, the insulation board of laying is not trough of belt insulation board；

When second step and third step, one layer of thermally conductive mortar of cracking resistance with self-leveling is first brushed above insulation board, to After final set, coil pipe is fixed on the thermally conductive screed of cracking resistance with bail；

In 4th step, whole face pours the thermally conductive mortar of lightweight with self-leveling, covers coil pipe, after solidification, is conserved.

Further, second step and when third step, the thermally conductive sand of the cracking resistance with self-leveling first applied on insulation board Slurry is with a thickness of 2-3mm.

Further, in the 4th step, it is 4-6cm that whole face, which pours the thermally conductive mortar thickness of lightweight with self-leveling,.

Compared with prior art, advantageous effects of the invention are as follows:

The thermally conductive mortar of cracking resistance has superpower bonding force in the present invention, can have good cementability with plastics, metal etc., And there is certain flexibility and cracking resistance, therefore coil pipe and insulation board and protective layer (the thermally conductive mortar of lightweight) can be made closely to tie It closes, avoids water flow resonance abnormal sound；The thermally conductive mortar of lightweight also has very high crack resistance, reduces unnecessary cracking phenomena, improves Floor heating safety；The thermally conductive screed of lightweight is also as heat dissipation media, and due to being cement-based material, the service life even can be same with building Service life can guarantee the long-term efficient operation of ground heating system, avoid the awkward condition using several Nian Bure；It is relatively traditional in the present invention Wet construction, due to largely using the thermally conductive mortar of lightweight (density about 800-900kg/m³), and concrete used in traditional method is protected Sheath density is about 2000kg/m³, thus the weight of ground heating system is substantially reduced, to build 50% or more loss of weight, for 3-5 public affairs It is floor loss of weight 30-60kg/m for the protective layer divided², so that building structure cost is substantially reduced, for existing building heating It increases burden and greatly reduces when being transformed into ground heating system, be more conducive to improving existing building service life, or even reduce or exempt from The design needed for the reinforcing of existing building, material and construction cost.

Detailed description of the invention

The invention will be further described for explanation with reference to the accompanying drawing.

Fig. 1 is the structural representation of the invention without thermally conductive the first specific embodiment of mortar energy-saving ground heating laying method of aluminium film Figure；

Fig. 2 is the structural representation of the invention without thermally conductive second of the specific embodiment of mortar energy-saving ground heating laying method of aluminium film Figure；

Description of symbols: 1, slot；2, insulation board；3, the thermally conductive mortar of cracking resistance；4, bail；5, coil pipe；6, the thermally conductive sand of lightweight Slurry；7, wall；8, floor；9, corner thermal insulation material.

Specific embodiment

As shown in Figure 1, a kind of the first specific embodiment of the thermally conductive mortar energy-saving ground heating laying method of no aluminium film,

The first step is laid with the insulation board 2 of trough of belt 1；

Coil pipe 5 is pressed into the slot 1 of insulation board 2 by second step, using specific purpose tools such as water clock or beakers by the thermally conductive sand of cracking resistance Slurry 3 pours in the gap of coil pipe and slot, flushes the thermally conductive mortar 3 of cracking resistance above with insulation board 2, covers to coil pipe；

Third step brushes the thermally conductive mortar 3 of cracking resistance that one layer of 2-3mm has self-leveling, and progress is levelling, to final set, to generation For aluminium film.

4th step, whole face pours 3cm with self-leveling on the thermally conductive mortar 3 of the cracking resistance with self-leveling after solidification The thermally conductive mortar 6 (replacing original concrete layer) of lightweight, after solidification, conserved, it is identical as conventional concrete carry out from So maintenance can hand over.

As shown in Fig. 2, a kind of second of specific embodiment of the thermally conductive mortar energy-saving ground heating laying method of no aluminium film,

In the first step, it is laid with the insulation board 2 of not trough of belt；

When second step and third step, the cracking resistance with self-leveling that one layer of 2-3mm thickness is first brushed above insulation board is led Hot mortar 3, to replace aluminium film that coil pipe 5 is fixed on the thermally conductive screed of cracking resistance with bail 4 after final set；

In 4th step, the thermally conductive mortar 6 of the lightweight with self-leveling that whole face pours one layer of 5cm (is replaced original mixed Solidifying soil layer), coil pipe 5 is covered, after solidification, is conserved, progress natural curing identical as conventional concrete can hand over.

In both the above embodiment, the edge that wall 7 is in contact with floor 8 is laid with corner thermal insulation material 9, and corner is protected Adiabator is concordant with the upper plane after the completion of ground heater laying.

It is DR-SJ001 that the model of the thermally conductive mortar of cracking resistance is used in both the above embodiment, and the model of the thermally conductive mortar of lightweight is DR180228, Hebei, which is combined, has production along Huajian material Co., Ltd.The thermally conductive mortar heat conductivity coefficient of cracking resistance in the present invention can reach 5-8w/ (m.K) contains special fibre instead of the thermally conductive mortar of the lightweight of concrete cover, and crack resistance is fine, thermal coefficient 3-5w/ (m.K) can be reached, be 3-8 times of normal concrete (its thermal coefficient is generally 0.8-1w/ (m.K)), greatly improved The heat dissipation uniformity of ground heating system (can make floor heating high-low temperature difference lower than 1 DEG C, lacking well below 3-10 DEG C of the traditional approach temperature difference Fall into), upward heat dissipation capacity is greatly improved, to improve the comfort of floor heating and energy saving.

The thermally conductive mortar of cracking resistance has superpower bonding force, can have good cementability with plastics, metal etc., and have one Fixed flexibility and cracking resistance, therefore coil pipe can be made to combine closely with insulating layer and protective layer avoid water flow from resonating abnormal sound.Lightweight Thermally conductive mortar also has very high crack resistance, reduces unnecessary cracking phenomena, improves floor heating safety.

The thermally conductive screed of lightweight is also as heat dissipation media, and due to being cement-based material, the service life even can be with the building same longevity Life, can guarantee the long-term efficient operation of ground heating system, avoid the awkward condition using several Nian Bure.

Opposite conventional wet is constructed in the present invention, due to largely using the thermally conductive mortar of lightweight (density about 800-900kg/ m³), and concrete cover density used in traditional method is about 2000kg/m³, thus the weight of ground heating system is substantially reduced, it is Build m³50% or more loss of weight is built, is floor loss of weight 30-60kg/m for 3-5 centimeters of protective layer², built to substantially reduce Building structure cost increases burden when being transformed into ground heating system for existing building heating and greatly reduces, and is more conducive to improving both Design, material and construction cost needed for having building service life, or even reduction or the reinforcing from existing building.

Thermally conductive mortar used in the present invention has gravity flow in parallel and good workability, can carry out mechanization slip casting behaviour Make, greatly improve construction efficiency, reduces cost of labor.It of courses, the present invention is used to advocate the electricity floor heating system of new energy at present Middle substitution aluminium film and concrete cover, are equally played the long-life, uniform heat distribution and energy-efficient effect.

Embodiment described above is only that preferred embodiment of the invention is described, and is not carried out to the scope of the present invention It limits, without departing from the spirit of the design of the present invention, those of ordinary skill in the art make technical solution of the present invention Various changes and improvements, should all fall into claims of the present invention determine protection scope in.

Claims (8)

1. a kind of thermally conductive mortar energy-saving ground heating laying method of no aluminium film, it is characterised in that:

The first step is laid with insulation board；

Second step wraps up coil pipe with the thermally conductive mortar of cracking resistance, coil pipe is fixed on above insulation board；

Third step, with the thermally conductive mortar levelling of cracking resistance, to final set；

4th step, whole face pour the thermally conductive mortar of lightweight with self-leveling, after solidification, are conserved.

2. the thermally conductive mortar energy-saving ground heating laying method of no aluminium film according to claim 1, it is characterised in that:

In the first step, the insulation board of laying is trough of belt insulation board；

In second step, by the slot of coil pipe indentation insulation board, the thermally conductive mortar of cracking resistance is poured to the seam into coil pipe and slot using tool In gap, makes to flush above the thermally conductive mortar of cracking resistance and insulation board, coil pipe is covered；

In third step, using the thermally conductive mortar of cracking resistance with self-leveling, progress is levelling, to final set.

3. the thermally conductive mortar energy-saving ground heating laying method of no aluminium film according to claim 2, it is characterised in that: in second step, The tool used is water clock or beaker.

4. the thermally conductive mortar energy-saving ground heating laying method of no aluminium film according to claim 2, it is characterised in that: in third step, The thermally conductive mortar thickness of cracking resistance with self-leveling is 2-3mm.

5. the thermally conductive mortar energy-saving ground heating laying method of no aluminium film according to claim 1, it is characterised in that: in the 4th step, The thermally conductive mortar thickness of lightweight with self-leveling is 2-4cm.

6. the thermally conductive mortar energy-saving ground heating laying method of no aluminium film according to claim 1, it is characterised in that:

In the first step, the insulation board of laying is not trough of belt insulation board；

When second step and third step, one layer of thermally conductive mortar of cracking resistance with self-leveling is first brushed above insulation board, to final set Afterwards, coil pipe is fixed on the thermally conductive screed of cracking resistance with bail；

In 4th step, whole face pours the thermally conductive mortar of lightweight with self-leveling, covers coil pipe, after solidification, is conserved.

7. the thermally conductive mortar energy-saving ground heating laying method of no aluminium film according to claim 6, it is characterised in that: second step and When three steps, the thermally conductive mortar thickness of the cracking resistance with self-leveling first applied on insulation board is 2-3mm.

8. the thermally conductive mortar energy-saving ground heating laying method of no aluminium film according to claim 6, it is characterised in that: in the 4th step, It is 4-6cm that whole face, which pours the thermally conductive mortar thickness of lightweight with self-leveling,.