CN214664722U - Electric heating film top heating, wall heating and floor heating installation structure - Google Patents

Abstract

The utility model provides a warm, the warm and warm up mounting structure of wall of electric heat membrane top, wherein the warm mounting structure of electric heat membrane top includes floor and sets gradually heat preservation, gypsum board layer, electric heat membrane and the dope layer on the floor from inside to outside, wherein: the gypsum board layer is fixedly connected to the floor slab through a fastener, an installation gap is reserved between the gypsum board layer and the floor slab, the heat insulation layer is filled in the installation gap, the electrothermal film is bonded to the gypsum board layer through adhesive glue, and the coating layer is coated on the electrothermal film; the electrothermal film is electrically connected with an external distribution box through a lead. The utility model provides an electric heat membrane mounting structure can paste the dress with the electric heat membrane respectively on floor, wall body and terrace, has realized the hidden setting of electric heat membrane to the normal work of electric heat membrane has been guaranteed.

Description

Electric heating film top heating, wall heating and floor heating installation structure

Technical Field

The utility model belongs to the technical field of the heating and specifically relates to electric heat membrane top is warm, the wall is warm and warm up mounting structure.

Background

Heating system on the current market generally is total minute structure, and the warm braw of central air conditioning all comes from outer machine, and the heat source of water ground heating, radiator comes from hanging stove. That is, in the current heating system, heat is all from the same heat source. The heating system at least has the following defects: when the heat source is invalid, the whole heating system is in failure.

In view of this, heating systems based on electrothermal film technology have been proposed and gradually popularized. The heating system based on the electrothermal film has a main structure comprising a power supply mechanism and the electrothermal film, wherein the electrothermal film is directly attached in a room, and the power supply mechanism is used for realizing the electrification of the electrothermal film to trigger the electrothermal film to radiate far infrared rays, thereby realizing the heating of the space in the room. That is, the electrothermal film as a heat source is separately attached to a room to be heated, thereby realizing independent heating of an indoor space of the corresponding room.

The utility model aims at providing a specific mounting structure that electric heat membrane top is warm, the wall is warm and warm up promptly to realize pasting the electric heat membrane to floor, wall body and terrace on.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model discloses the first aspect provides a warm mounting structure in electric heat membrane top, and its concrete technical scheme is:

the utility model provides a warm mounting structure in electric heat membrane top, its includes the floor and sets gradually heat preservation, gypsum board layer, electric heat membrane and the dope layer on the floor from inside to outside, wherein:

the gypsum board layer is fixedly connected to the floor slab through a fastener, an installation gap is reserved between the gypsum board layer and the floor slab, the heat insulation layer is filled in the installation gap, the electrothermal film is bonded to the gypsum board layer through adhesive glue, and the coating layer is coated on the electrothermal film;

the electrothermal film is electrically connected with an external distribution box through a lead.

In some embodiments, the fastener comprises a U-shaped hanger, a light gauge steel, an expansion screw, a first screw, and a second screw, wherein: the U-shaped hanging piece is fixedly connected to the floor through the expansion screws, the light steel keel is fixedly connected to the U-shaped hanging piece through the first screws, and the gypsum board layer is fixedly connected to the light steel keel through the second screws.

In some embodiments, the electric heating film top heating installation structure further comprises a PVC wire pipe, and the conducting wire is installed in the PVC wire pipe.

The utility model discloses the second aspect provides a warm mounting structure of electric heat membrane wall, its technical scheme as follows:

the utility model provides a warm mounting structure of electric heat membrane wall, includes the wall body and sets gradually heat preservation, gypsum board layer, electric heat membrane and the dope layer on the wall body from inside to outside, wherein:

the gypsum board layer is fixedly connected to the wall body through a fastener, an installation gap is reserved between the gypsum board layer and the wall body, the heat insulation layer is filled in the installation gap, the electrothermal film is bonded to the gypsum board layer through adhesive glue, and the coating layer is coated on the electrothermal film;

the electrothermal film is electrically connected with an external distribution box through a lead.

In some embodiments, the fastener includes a wood keel, a first side surface of the wood keel is attached to the wall, a second side surface of the wood keel is attached to the gypsum board layer, and an expansion end of the expansion screw penetrates through the gypsum board layer and the wood keel and then is fixed in the wall.

In some embodiments, the electric hot wall installation structure further comprises a PVC conduit, and the lead is installed in the PVC conduit.

In some embodiments, the electric heating film 100 includes a far infrared heating film, the far infrared heating film has a first surface and a second surface corresponding to the first surface, the first surface is sequentially laminated with a first hot melt adhesive layer, a first PET film layer and a first fiber cloth layer, the second surface is sequentially laminated with a second hot melt adhesive layer, a second PET film layer and a second fiber cloth layer, and a first copper foil strip and a second copper foil strip are pairwise laminated between two side edges of the first hot melt adhesive layer and two side edges of the first PET film layer.

The utility model discloses the third aspect provides a warm up mounting structure of electric heat membrane, its technical scheme as follows:

an electric heating film floor heating installation structure is characterized by comprising a floor, and a heat preservation layer, an electric heating film, a moisture-proof layer and a floor which are sequentially arranged on the floor from inside to outside, wherein the heat preservation layer is bonded on the floor through adhesive glue;

the electrothermal film is electrically connected with an external distribution box through a lead.

In some embodiments, the electric heating film comprises a far infrared heating film, the far infrared heating film has a first surface and a second surface corresponding to the first surface, a first hot melt adhesive layer, a first PET film layer and a first fiber cloth layer are sequentially laminated on the first surface, a second hot melt adhesive layer, a second PET film layer and a second fiber cloth layer are sequentially laminated on the second surface, and a first copper foil strip and a second copper foil strip which are laminated in pairs between two side edges of the first hot melt adhesive layer and two side edges of the first PET film layer.

The utility model provides a three kinds of electric heat membrane mounting structure can paste the dress with the electric heat membrane respectively on floor, wall body and terrace, has realized hidden laying of electric heat membrane to the normal work of electric heat membrane has been guaranteed.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings which are needed in the embodiments and are practical will be briefly described below and will be obvious, the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts. Wherein the content of the first and second substances,

fig. 1 is a schematic structural diagram of a distributed electrothermal film heating system according to a first embodiment of the present invention;

fig. 2 is a schematic plan view of an electric heating film according to a second embodiment of the present invention;

fig. 3 is a schematic cross-sectional view of an electrothermal film according to a second embodiment of the present invention;

fig. 4 is a schematic structural diagram of a distribution box according to a third embodiment of the present invention;

fig. 5 is a schematic view of an electric heating film top heating installation structure according to a fourth embodiment of the present invention;

fig. 6 is a schematic partial structural view of an electric heating film top heating installation structure according to a fourth embodiment of the present invention;

fig. 7 is a schematic structural view of a fastening mechanism in a top heating installation structure of an electric heating film according to a fourth embodiment of the present invention;

fig. 8 is a schematic partial structural view of an electric heating film wall heater mounting structure according to a fifth embodiment of the present invention;

fig. 9 is a schematic partial structural view of an electric heating film wall heater mounting structure according to a fifth embodiment of the present invention;

fig. 10 is a schematic view of a partial structure of a floor heating installation structure with an electric heating film according to a sixth embodiment of the present invention;

fig. 11 is a schematic view of a local structure in the electric heating film floor heating installation structure provided by the sixth embodiment of the present invention.

Detailed Description

In order to make the above objects, features and advantages of the present invention more comprehensible, the present invention is described in detail with reference to the accompanying drawings and the detailed description.

Introduction of distributed electrothermal film heating system

In the electric heating film heating system in the prior art, the power supply mechanism comprises an in-house electric box and a uniform total distribution box, the in-house electric box supplies 220V alternating current commercial power to the total distribution box, and the distribution box converts the 220V alternating current commercial power into direct current (generally 36V) and then distributes the direct current to the electric heating films distributed in each room through a direct current line. Technical problems of an electrothermal film heating system in the prior art at least comprise: 1. the direct current line's line distance of walking is longer (from total block terminal to the electric heat membrane in each room promptly), leads to the line loss of electric current great, increases heating system's energy consumption. 2. The general distribution box distributes power uniformly, and a transformer in the general distribution box is easy to trip and lose efficacy due to overlarge electric quantity, so that the heating system is caused to lose efficacy integrally.

In order to solve the technical problem that the electric heat membrane heating system among the prior art exists, the utility model discloses a first embodiment provides a distributing type electric heat membrane heating system, it realizes the heating through the electric heat membrane of laying on floor, wall body and the terrace in room.

As shown in fig. 1, the distributed electrothermal film heating system includes a household electric box 200 and an electrothermal film heating component disposed in at least two rooms, in the embodiment of fig. 1, the distributed electrothermal film heating system includes four rooms, which are a room a, a room B, a room C and a room D, respectively, and the four rooms are all provided with a group of electrothermal film heating components. Of course, in other embodiments, the corresponding number of the electric heating film heating components can be correspondingly arranged according to other numbers of the rooms.

Every electric heat membrane heating subassembly of group all includes a block terminal 300 and a plurality of electric heat membrane 100, wherein:

among each electric heat membrane heating element, the input of block terminal 300 is connected with the output electricity of electrical box 200 of registering one's residence through first circuit 500 (alternating current circuit), and the output of block terminal 300 is connected in order to realize the circular telegram to each electric heat membrane 100 through second circuit 600 (direct current circuit) and each electric heat membrane 100 electricity, and electric heat membrane 100 is laid at least on one of floor, wall body and the terrace in room, and electric heat membrane 100 converts the electric energy into far infrared radiation or convection heat energy in order to send the heat.

Optionally, the working principle of the distributed electrothermal film heating system in this embodiment is as follows:

the household electrical box 200 supplies 220V alternating current (commercial power) supplied by an external power grid to the distribution box 300 of each electric heating film heating assembly through the first line 500.

The distribution box 300 converts the 220V ac power into the 36V dc power, and transmits the 36V dc power to the corresponding electric heating films 100 through the corresponding second lines 600.

The electric heating film 100 radiates far infrared rays having a wavelength range of 8 to 15 μm after being electrified, thereby realizing heating.

Referring to fig. 1, optionally, in the distributed electrothermal film heating system of the embodiment, each heating component further includes a temperature controller 400 electrically connected to the distribution box 300. The heating power of the electric heating film 100 can be adjusted through the temperature controller 400, thereby realizing the temperature adjustment in the room.

It can be seen that the electric heat membrane heating system that this embodiment provided all sets up an independent block terminal in each room, and each block terminal provides the electric heat membrane in this room through arranging second circuit 600 (direct current circuit) in this room after will shunting to the alternating current conversion that corresponds the room to the direct current. Thus, at least the following technical effects can be produced: 1. the wiring distance of the direct current circuit is obviously shortened, the line loss of the current is small, and the energy consumption of the heating system is reduced. 2. Each distribution box only carries out voltage conversion to the alternating current shunted to the corresponding room, and tripping failure of a transformer in the distribution box due to overlarge electric quantity is avoided. 3. Even if a certain distribution box is invalid, heating in a corresponding room is only affected, and the failure of the whole heating system cannot be caused.

Introduction to electrothermal films

The second embodiment of the utility model provides a concrete electric heat membrane structure, this electric heat membrane can become far infrared radiation or convection current heat energy with electric energy conversion after the circular telegram to the realization is to the heating of surrounding environment, and this electric heat membrane is fit for very much using the utility model discloses distributed electric heat membrane heating system in the first embodiment.

Specifically, as shown in fig. 2 and fig. 3, the electric heating film 100 in this embodiment includes a far infrared heating film 101, the far infrared heating film 101 has a first surface and a second surface corresponding to the first surface, the first surface is sequentially bonded with a first hot melt adhesive layer 102, a first PET film layer 104 and a first fiber cloth layer 106, the second surface is sequentially bonded with a second hot melt adhesive layer 103, a second PET film layer 105 and a second fiber cloth layer 107, and a first copper foil strip 108 and a second copper foil strip 109 are bonded between two side edges of the first hot melt adhesive layer 102 and two side edges of the first PET film layer 104 in pairs.

The first copper foil strip 108 and the second copper foil strip 109 constitute the electrical contact electrodes of the electrical heating film 100. With reference to fig. 1, the first copper foil strip 108 and the second copper foil strip 109 of the electric heating film 100 are connected to the distribution box 300 through the second line 600, so that the electric heating film 100 can be electrified. After the far infrared heating film 101 is electrified, the electric energy can be converted into far infrared radiation or convection heat energy, so as to realize heating of the surrounding environment.

The first hot melt adhesive layer 102 and the second hot melt adhesive layer 103 are made of known hot melt adhesives, such as EVA, PUR, and the like.

The far infrared heating film 101 is made of various known types of far infrared heating films, such as a wet carbon fiber heating film, a short carbon fiber heating film, a graphene oxide heating film, and the like. In specific implementation, one of the above film materials may be used as the far infrared heating film 101, or two or more film materials may be laminated to be used as the far infrared heating film 101.

The far infrared heating film 101 radiates far infrared rays (called "life rays") having a wavelength range of 8 to 15 μm when energized. After being absorbed by human body, the far infrared ray with the wavelength can promote the metabolism of mitochondria in cytoplasm, improve the blood microcirculation, indirectly diminish inflammation, relieve pain and improve the regulation capability of a nerve and body fluid system. Therefore, the human body can feel warm and be healthier when bathing under the light. Because far infrared has the function of activating human cells, the far infrared can promote the metabolism of mitochondria in cytoplasm, improve the blood microcirculation, indirectly diminish inflammation, relieve pain and improve the regulation capability of a nerve-fluid system.

The whole thickness of the electric heating film 100 in this embodiment is only 0.4mm, and it is very suitable for being directly pasted on a wall, a floor slab and a terrace as a film material.

In some embodiments, the thickness of the heat generating functional film 101 is 1 to 3 μm, the thickness of the first hot melt adhesive layer 102 and the second hot melt adhesive layer 103 is 8 to 12 μm, the thickness of the first PET film layer 104 and the second PET film layer 105 is 85 to 90 μm, the thickness of the first fiber cloth layer 106 and the second fiber cloth layer 107 is 50 to 70 μm, and the thickness of the first copper foil strip 108 and the second copper foil strip 109 is 15 to 25 μm. The widths of the first copper foil strip 108 and the second copper foil strip 109 are 20mm, and the distance between the first copper foil strip 108 and the second copper foil strip 109 is 500 mm.

In some preferred embodiments, circular holes are densely distributed on the electrothermal film 100 to penetrate through the electrothermal film 100. The electric heating film 100 is densely provided with round holes. In some embodiments, the total area of the circular holes is up to about 80% of the total area of the electrothermal film 100.

The present embodiment further provides a method for preparing the above electric heating film 100, which includes the following steps:

(1) the first surface and the second surface of the heat generating functional film 101 are uniformly sized to form a first hot melt adhesive layer 102 and a second hot melt adhesive layer 103. Optionally, the sizing temperature is 130-160 ℃.

(2) The first copper foil strip 108 and the second copper foil strip 109 are respectively attached to the edges of the two sides of the first hot melt adhesive layer 102.

(3) The first PET film layer 104 and the second PET film layer 105 are respectively attached to the first hot melt adhesive layer 102 and the second hot melt adhesive layer 103.

(4) The first fiber cloth layer 106 and the second fiber cloth layer 107 are respectively hot-pressed on the first PET film layer 104 and the second PET film layer 105. Optionally, the hot pressing temperature is 200-270 ℃.

After the forming of the electric heating film 100 is completed, holes are densely punched on the electric heating film 100 to form round holes densely distributed on the electric heating film 100 and penetrating through the electric heating film 100.

Introduction to electric distribution boxes

As described in the first embodiment, in the distributed electrothermal film heating system provided, an independent distribution box is arranged in each room. The common distribution box on the market has larger volume, and the power of a transformer in the distribution box is higher, so that a high-power radiating fan needs to be assembled. Considering the factors of space and noise, the traditional distribution box is difficult to satisfy the practical requirement of the distributed electrothermal film heating system of the first embodiment.

In view of this, the third embodiment of the present invention provides a distribution box 300 with a compact structure and without using a fan for heat dissipation, which is very suitable for being applied to the distributed electrothermal film heating system in the first embodiment of the present invention.

Specifically, as shown in fig. 4, the distribution box 300 provided in this embodiment includes a box body and a transformer 307.

The box includes bottom plate (not shown), left side board 301, right side board 302, front end board 305 and back end board 306, wherein: the left side plate 301 and the right side plate 302 are symmetrically arranged at two side edges of the bottom plate, a plurality of left side radiating fins 303 perpendicular to the left side plate 301 are arranged on the outer wall of the left side plate 301, and a plurality of right side radiating fins 304 perpendicular to the right side plate 302 are arranged on the outer wall of the right side plate 302.

The front ends of the left side plate 301 and the right side plate 302 are both outwards vertically turned to form a front end connection lip plate, and the rear ends of the left side plate 301 and the right side plate 302 are both outwards vertically turned to form a rear end connection lip plate.

Two ends of the front end plate 305 are respectively attached to the front end connecting lip plates of the left side plate 301 and the right side plate 302, and the front end plate 305 is provided with a circuit through hole.

The two ends of the rear end plate 306 are respectively attached to the rear end connecting lip plates of the left side plate 301 and the right side plate 302.

The transformer 307 is accommodated in the box body, the input end of the transformer 307 is electrically connected with the output end of the external household electrical box through a first line penetrating through the line through hole, and the output end of the transformer 307 is electrically connected with the external electric heating film through a second line penetrating through the line through hole so as to realize the electrification of the electric heating film.

Referring to fig. 1, the household electrical box 200 supplies 220V alternating current (commercial power) supplied from an external power grid to the transformer 307 in the distribution box 300 through the first line 500, and the transformer 307 converts the 220V alternating current into 36V direct current and transmits the 36V direct current to the corresponding electric heating film 100 through the second line 600.

Because the outer walls of the left side plate 301 and the right side plate 302 of the distribution box 300 are respectively provided with the left side heat radiating fin 303 and the right side heat radiating fin 304, heat generated by the transformer 307 can be quickly radiated out of the box body, and the transformer 307 is prevented from being burnt.

Optionally, for convenience of manufacturing and reduction of production cost, the left heat dissipating fin 303 and the left side plate 301 are integrally formed, and the right heat dissipating fin 304 and the right side plate 302 are integrally formed.

Optionally, in order to protect components such as the transformer 307 in the box body, the distribution box 300 in this embodiment further includes a cover plate (not shown) covering the box body.

In order to facilitate the wire combination of the first wire and the second wire, optionally, the wire through hole includes a first wire through hole 3051 and a second wire through hole 3052, the output end of the transformer 307 is electrically connected to the output end of the household electrical box 200 through the first wire 500 penetrating through the first wire through hole 3051, and the output end of the transformer 307 is electrically connected to the electrothermal film 100 through the second wire 600 penetrating through the second wire through hole 3052 to energize the electrothermal film 100.

In space-saving, aesthetic considerations, it is generally desirable to mount the panelboard 300 concealed on the keel frame of the ceiling of a room. Therefore, in order to realize the fixed connection between the distribution box 300 and the keel frame, the bottom plate of the box body is provided with a mounting bracket 308 matched with the keel frame.

Optionally, in order to achieve assembly and maintenance of the distribution box 300, the box body of the distribution box 30 is configured as a detachable structure, specifically, the left side plate 301 and the right side plate 302 are detachably connected to the bottom plate through first screws, respectively. Both ends of the front end plate 305 are detachably attached to the front end connecting lip plates of the left side plate 301 and the right side plate 302 through second screws. Two ends of the rear end plate 306 are detachably attached to the rear end connecting lip plates of the left side plate 301 and the right side plate 302 through third screws respectively.

In addition, in order to further improve the heat dissipation performance of the box body, optionally, the box body and the cover plate of the distribution box 30 are both made of aluminum sheet metal.

Because the distribution box in the embodiment only performs voltage conversion on the alternating current shunted to the corresponding room, only a low-power transformer needs to be equipped. Therefore, the volume of the distribution box is small, and as in one embodiment, the length, width, height dimensions of the box body of the distribution box are only 300mm, 240mm and 120 mm.

Introduction about mounting mode of electrothermal film

As described in the first embodiment, there is provided the distributed electrothermal film heating system in which the electrothermal film 100 is laid on the wall, the floor or the terrace of the room.

In the following, we will describe the specific installation manner of the electrothermal film 100 on the floor, wall and floor separately by three embodiments.

Electric heating film top heating installation structure

As shown in fig. 5 to 7, the fourth embodiment of the present invention provides an electric heating film top heating installation structure 700, which comprises a floor 701 and a heat preservation layer 702, a gypsum board layer 703, an electric heating film 100 and a coating layer 705 which are sequentially arranged on the floor from inside to outside, wherein:

the gypsum board layer 703 is fixedly connected on the floor 701 through a fastener 706, an installation gap is reserved between the gypsum board layer 703 and the floor 701, the heat insulation layer 702 is filled in the installation gap, the electrothermal film 100 is adhered on the gypsum board layer 703 through adhesive glue, and the coating layer 705 is coated on the electrothermal film 100.

The heat insulation layer 702 is generally made of heat insulation cotton, which can realize the resistance and heat insulation of the heat radiation of the electrothermal film 100 and reduce the heat dissipated through the floor 701. The gypsum board layer 703 and the paint layer 705 can be made of various known suitable building materials, and the present invention is not limited thereto.

The electric heating film 100 is electrically connected to an external electric distribution box via a line 600 (i.e., a second line 600 in the first embodiment). The electric heating film 100 directly adopts the electric heating film 100 provided in the second embodiment of the present invention, and the above has described the specific structure and the preparation method of the electric heating film 100 in detail, so that the details are not repeated herein.

Optionally, as shown in fig. 7, the fastener 706 includes a U-shaped hanger 7061, a light gauge steel 7062, an expansion screw 7063, a first screw 7064, and a second screw 7065, wherein: the U-shaped hanging piece 7061 is fixedly connected to the floor 701 through an expansion screw 7063, the light steel keel 7062 is fixedly connected to the U-shaped hanging piece 7061 through a first screw 7064, and the gypsum board layer 703 is fixedly connected to the light steel keel 7062 through a second screw 7065.

Optionally, in order to facilitate routing of the circuit 600, as shown in fig. 6, the electric heating film top heating installation structure 70 in this embodiment further includes a PVC conduit 707, and the circuit 600 is installed in the PVC conduit 707.

Electric heating film wall heater mounting structure

As shown in fig. 8 to 9, the fifth embodiment of the present invention provides an electric heating film wall heating installation structure 800, which comprises a wall 801, and a heat insulation layer 802, a gypsum board layer 803, an electric heating film 100 and a coating layer 805 which are sequentially arranged on the wall 801 from inside to outside, wherein:

the gypsum board layer 803 is fixedly connected to the wall body 801 through a fastener 806, an installation gap is kept between the gypsum board layer 803 and the wall body 801, the heat insulation layer 802 is filled in the installation gap, the electrothermal film 100 is adhered to the gypsum board layer 803 through adhesive glue, and the coating layer 805 is coated on the electrothermal film 100.

The thermal insulation layer 802 is generally made of thermal insulation cotton, which can block and insulate the thermal radiation of the electrothermal film 100, and reduce the heat dissipated to the outside through the wall 801. The gypsum board layer 803 and the paint layer 705 can be made of various known suitable building materials, and the present invention is not limited thereto.

The electric heating film 100 is electrically connected to an external electric distribution box via a line 600 (i.e., a second line 600 in the first embodiment). Similarly, the electric heating film 100 directly adopts the electric heating film 100 provided in the second embodiment of the present invention, and since the above has been described in detail for the specific structure and the preparation method of the electric heating film 100, it is not repeated herein.

Optionally, as shown in fig. 9, the fastening member 806 includes a wood keel 8061 and an expansion screw 8062, a first side surface of the wood keel 8061 is attached to the wall 801, a second side surface of the wood keel 801 is attached to the gypsum board layer 803, and an expansion end of the expansion screw 8062 penetrates through the gypsum board layer 803 and the wood keel 801 and then is fixed in the wall 801.

Similarly, optionally, in order to facilitate the routing of the circuit 600, the electric heating film wall heating installation structure 80 in this embodiment may also include a PVC conduit, and the circuit 600 is installed in the PVC conduit.

Electric heating film floor heating installation structure

As shown in fig. 10 to fig. 11, the sixth embodiment of the utility model provides a warm mounting structure 90 warms up electrothermal film, it includes terrace 901 and sets gradually heat preservation 902, electrothermal film 100, dampproof course 904 and the floor on terrace 901 from inside to outside, wherein, heat preservation 902 bonds on terrace 901 through the adhesive glue, electrothermal film 100 bonds on heat preservation 902 through the adhesive glue, dampproof course 904 bonds on electrothermal film 100 through the adhesive glue, the floor then lays on the dampproof course.

The heat preservation layer 902 generally adopts a heat preservation plate, which can realize the resistance and heat preservation of the heat radiation of the electrothermal film 100, and reduce the heat dissipated to the outdoor through the terrace 901. The moisture barrier 904 enables moisture protection of the electrothermal film 100.

The electric heating film 100 is electrically connected to an external electric distribution box via a line 600 (i.e., a second line 600 in the first embodiment). Similarly, the electric heating film 100 directly adopts the electric heating film 100 provided in the second embodiment of the present invention, and since the above has been described in detail for the specific structure and the preparation method of the electric heating film 100, it is not repeated herein.

In the same way, optionally, in order to conveniently realize the wiring to circuit 600, electric heat membrane floor heating installation structure 90 in this embodiment also can include the PVC spool, and circuit 600 is installed in the PVC spool.

The invention has been described above with a certain degree of particularity and detail. It will be understood by those of ordinary skill in the art that the description of the embodiments is merely exemplary and that all changes that may be made without departing from the true spirit and scope of the present invention are intended to be within the scope of the present invention. The scope of the invention is defined by the appended claims rather than by the foregoing description of the embodiments.

Claims (10)

1. The utility model provides a warm mounting structure in electric heat membrane top, a serial communication port, the warm mounting structure in electric heat membrane top includes the floor and from inside to outside sets gradually heat preservation, gypsum board layer, electric heat membrane and the dope layer on the floor, wherein:

the gypsum board layer is fixedly connected to the floor slab through a fastener, an installation gap is reserved between the gypsum board layer and the floor slab, the heat insulation layer is filled in the installation gap, the electrothermal film is bonded to the gypsum board layer through adhesive glue, and the coating layer is coated on the electrothermal film;

the electrothermal film is electrically connected with an external distribution box through a lead.

2. The electric heating film ceiling heating installation structure of claim 1, wherein the fastening member comprises a U-shaped hanger, a light steel keel, an expansion screw, a first screw and a second screw, wherein: the U-shaped hanging piece is fixedly connected to the floor through the expansion screws, the light steel keel is fixedly connected to the U-shaped hanging piece through the first screws, and the gypsum board layer is fixedly connected to the light steel keel through the second screws.

3. The electric heating film top heater mounting structure as claimed in claim 1, wherein said electric heating film top heater mounting structure further comprises a PVC conduit, said lead wire being mounted in said PVC conduit.

4. The electric heating film top heating installation structure as claimed in claim 1, wherein the electric heating film comprises a far infrared heating film, the far infrared heating film has a first surface and a second surface corresponding to the first surface, a first hot melt adhesive layer, a first PET film layer and a first fiber cloth layer are sequentially attached to the first surface, a second hot melt adhesive layer, a second PET film layer and a second fiber cloth layer are sequentially attached to the second surface, and a first copper foil strip and a second copper foil strip are attached in pairs between two side edges of the first hot melt adhesive layer and two side edges of the first PET film layer.

5. The utility model provides a warm mounting structure of electric heat membrane wall, a serial communication port, the warm mounting structure of electric heat membrane wall includes the wall body and from inside to outside sets gradually heat preservation, gypsum board layer, electric heat membrane and the dope layer on the wall body, wherein:

the gypsum board layer is fixedly connected to the wall body through a fastener, an installation gap is reserved between the gypsum board layer and the wall body, the heat insulation layer is filled in the installation gap, the electrothermal film is bonded to the gypsum board layer through adhesive glue, and the coating layer is coated on the electrothermal film;

the electrothermal film is electrically connected with an external distribution box through a lead.

6. The electric heating film wall heating installation structure as claimed in claim 5, wherein the fastening member comprises a wood keel and an expansion screw, a first side surface of the wood keel is attached to the wall body, a second side surface of the wood keel is attached to the gypsum board layer, and an expansion end of the expansion screw penetrates through the gypsum board layer and the wood keel and then is fixed in the wall body.

7. The electrothermal film wall heater mounting structure of claim 5, further comprising a PVC conduit in which the lead wires are mounted.

8. An electric heating film wall heating installation structure as claimed in claim 5, wherein the electric heating film comprises a far infrared heating film, the far infrared heating film has a first surface and a second surface corresponding to the first surface, a first hot melt adhesive layer, a first PET film layer and a first fiber cloth layer are sequentially laminated on the first surface, a second hot melt adhesive layer, a second PET film layer and a second fiber cloth layer are sequentially laminated on the second surface, and a first copper foil strip and a second copper foil strip are pairwise laminated between two side edges of the first hot melt adhesive layer and two side edges of the first PET film layer.

9. An electric heating film floor heating installation structure is characterized by comprising a floor, and a heat preservation layer, an electric heating film, a moisture-proof layer and a floor which are sequentially arranged on the floor from inside to outside, wherein the heat preservation layer is bonded on the floor through adhesive glue;

the electrothermal film is electrically connected with an external distribution box through a lead.

10. The electric heating film floor heating installation structure of claim 9, wherein the electric heating film comprises a far infrared heating film, the far infrared heating film is provided with a first surface and a second surface corresponding to the first surface, a first hot melt adhesive layer, a first PET film layer and a first fiber cloth layer are sequentially attached to the first surface, a second hot melt adhesive layer, a second PET film layer and a second fiber cloth layer are sequentially attached to the second surface, and a first copper foil strip and a second copper foil strip are attached between two side edges of the first hot melt adhesive layer and two side edges of the first PET film layer in pairs.

Images