CN214675732U - Better electric heat membrane of reliability - Google Patents

Abstract

The utility model discloses a better electric heat membrane of reliability, its main points are: according to electric heat membrane service environment and by the heating surface (floor) heat transfer and the heat dissipation condition, adjustment electric heat membrane power density distribution (through the electrically conductive sectional area of adjustment interval and/or the portion that generates heat), when the occasion that heat transfer and heat dissipation are faster, heated surface temperature presents great gradient, electric heat membrane central temperature is high, the ambient temperature is low, through improving electric heat membrane peripheral power density, reduce the power density in the middle of the electric heat membrane, guarantee that electric heat membrane bulk temperature distributes evenly, prevent local high temperature, increase of service life and safety in utilization, adopt two or three heating circuit, after the problem all the way, all the other can also continue work and give off the heat, can not cause the temperature to reduce by a wide margin, especially, be fit for running long-distance motor car, provide sufficient time for the later stage change.

Description

Better electric heat membrane of reliability

Technical Field

The utility model relates to an electric heat membrane technical field specifically is a use better electric heat membrane of reliability with add heating circuit.

Background

The electrothermal film in the electric heating system is a film product which can generate heat after being electrified, is made by processing and hot-pressing conductive paint and metal current-carrying bars among insulating polyester films and belongs to a low-temperature radiation electrothermal film. The electrothermal film is used as a heating body to send heat into a space in a radiation mode, so that a human body feels warm, and the comprehensive effect of the electrothermal film is superior to that of the traditional convection heating mode. The ground heating system is composed of power supply, temp controller, connecting part, insulating layer, electrothermal film and decorative layer. The power supply is communicated with the electrothermal film through a lead to convert electric energy into heat energy. The ground electric heating system is not only suitable for the north, but also suitable for areas without heating facilities in winter. The electrothermal film is not only widely applied to heating systems of civil buildings such as houses, schools, shops, hospitals and office buildings, but also widely applied to heating systems of industrial buildings such as factory buildings and warehouses. The electrothermal film is also applied to heating systems of rail vehicles, the fields of road snow melting and the like, and the electrothermal film has wide application prospect. Because the electric heating film is planar, the heat dissipation speed of each part of the electric heating film is different, the phenomena of overheating at the central part and lower temperature at the periphery generally exist, and the high-temperature service life of the middle part is reduced and even the electric heating film is burnt out easily. Secondly, current electric heat membrane only has a heating circuit usually, and the intensification is slower in the time of the beginning work, in case the short circuit appears in addition, whole electric heat membrane just can't heat, needs to change, and is comparatively troublesome.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a simple structure has many (the meaning of many in the utility model is two or three) heating circuit's the better electric heat membrane of use reliability.

Realize the utility model discloses the basic technical scheme of purpose is: an electric heating film with better reliability is characterized in that: the heat-generating chip component comprises an upper insulating layer, a heat-generating core layer, a lower insulating layer and an electric connecting chip component.

The heating core layer is formed by laying two conductive heating strips, and the two conductive heating strips are respectively called as a first conductive heating strip and a second conductive heating strip according to the difference of the front position and the rear position of the two conductive heating strips. The first conductive heating strip is provided with a first live wire connecting part and a zero line connecting part at the head and the tail, the second conductive heating strip is provided with a second live wire connecting part at one end, and the other end of the second live wire connecting part is electrically connected with the zero line connecting part of the first conductive heating strip. The part between the live wire connecting part and the zero line connecting part of the two conductive heating strips is a heating part. The first conductive heating strip and the second conductive heating strip are arranged in an S shape, and the heating parts of the first conductive heating strip and the second conductive heating strip are arranged in parallel. The heating core layer is wrapped between the upper insulating layer and the lower insulating layer.

The electric connection piece assembly comprises a first live wire electric connection piece, a second live wire electric connection piece and a zero wire electric connection piece. The first live wire electric connection piece is fixedly connected and electrically connected to the part of the first live wire connection part coated by the upper insulating layer and the lower insulating layer. The second live wire electric connection piece is fixedly connected and electrically connected to the part of the second live wire connection part coated by the upper insulating layer and the lower insulating layer. The zero line electric connection sheet is fixedly connected and electrically connected with the part of the zero line connection part coated by the upper insulating layer and the lower insulating layer.

The technical scheme based on the basic technical scheme is as follows: still include the adhesive layer, the adhesive layer bonds fixedly to set up on the downside of insulating layer down, and the downside of adhesive layer is equipped with from type paper.

The technical scheme based on the corresponding technical schemes is as follows: the heating parts of the first conductive heating strip and the second conductive heating strip are parallel to each other in the front-rear direction, and the distance d between the adjacent heating parts is gradually reduced from inside to outside, namely the distance between the two adjacent heating parts in the middle in the front-rear direction of the first conductive heating strip is larger than the distance between the two heating parts and the heating parts of the second conductive heating strip adjacent to the outer side of the first conductive heating strip. The distance between the heating part in the middle of the first conductive heating bar and the heating part of the second conductive heating bar adjacent to the outer side is larger than the distance between the heating part of the second conductive heating bar and the heating part of the second conductive heating bar adjacent to the outer side.

The technical scheme based on the corresponding technical schemes is as follows: the distance between the mutually parallel parts of the heating parts of the first conductive heating strip and the second conductive heating strip is always kept consistent, and the distance d1 between the central lines of the mutually parallel parts of the adjacent two sections of the first conductive heating strip and the second conductive heating strip is gradually reduced from inside to outside.

The technical scheme based on the corresponding technical schemes is as follows: the conductive heating strip of the heating core layer is made of metal materials. The interval between the adjacent parts of the heating part which are parallel to each other is gradually reduced from inside to outside, or the conductive sectional area of the heating part is gradually reduced from inside to outside, or the interval between the adjacent parts of the heating part which are parallel to each other is gradually increased from inside to outside, and simultaneously the conductive sectional area of the heating part is gradually reduced from inside to outside.

Realize the utility model discloses the second basic technical scheme of purpose is: an electric heating film with better reliability is characterized in that: the heat-generating chip component comprises an upper insulating layer, a heat-generating core layer, a lower insulating layer, an electric connecting chip component and a third insulating layer.

The heating core layer is formed by laying two conductive heating strips, and the two conductive heating strips are respectively called as an upper conductive heating strip and a lower conductive heating strip according to the difference of the upper position and the lower position of the two conductive heating strips. The head and the tail of the upper conductive heating strip are respectively provided with a first live wire connecting part and a zero line connecting part. The part between the first live wire connecting part and the zero line connecting part of the upper conductive heating strip is a heating part. The heating part is arranged in an S shape, and the distance d2 between the adjacent parts of the heating part which are parallel to each other in the front-back direction is gradually reduced from inside to outside. The upper insulating layer is fixed on the lower insulating layer and the heating core layer through hot-melt adhesive hot-pressing adhesion, so that the upper heating core layer of the heating core layer is coated between the upper insulating layer and the lower insulating layer.

And the head and the tail of the lower conductive heating strip are respectively provided with a second live wire connecting part and a lower zero line connecting part. The part between the second live wire connecting part and the lower zero line connecting part of the lower conductive heating strip is a heating part. The heating part is arranged in an S shape, and the distance between the adjacent parts of the heating part which are parallel to each other in the front-back direction is gradually reduced from inside to outside. The positions of the lower zero line connecting part and the heating part of the lower conductive heating strip in the up-down direction correspond to the positions of the zero line connecting part and the heating part of the upper conductive heating strip. The third insulating layer is fixed on the lower side of the lower insulating layer and the lower heating core layer through hot-melt adhesive hot-pressing adhesion, so that the lower heating core layer of the heating core layer is coated between the third insulating layer and the lower insulating layer.

The electric connection piece assembly comprises a first live wire electric connection piece, a second live wire electric connection piece and a zero wire electric connection piece. The first live wire electric connection piece is fixed and electrically connected to the first live wire connection part coated by the upper insulating layer and the lower insulating layer. The second live wire electric connection piece is fixed and electrically connected to the part of the second live wire connection part coated by the lower insulating layer and the third insulating layer. The zero line electric connection sheet is fixed and electrically connected to the part of the zero line connection part coated by the upper insulating layer and the lower insulating layer and the part of the lower zero line connection part coated by the lower insulating layer and the third insulating layer.

The technical scheme based on the second basic technical scheme is as follows: still include the adhesive layer, the adhesive layer bonds fixedly to set up on the downside of third insulating layer, and the downside of adhesive layer is equipped with from type paper.

The technical scheme based on the corresponding technical scheme is as follows: the conductive heating strip of the heating core layer is made of metal materials. The interval between the adjacent parts of the heating part which are parallel to each other is gradually reduced from inside to outside, or the conductive sectional area of the heating part is gradually reduced from inside to outside, or the interval between the adjacent parts of the heating part which are parallel to each other is gradually increased from inside to outside, and simultaneously the conductive sectional area of the heating part is gradually reduced from inside to outside.

The utility model discloses following beneficial effect has: (1) the utility model discloses an electric heat membrane simple structure has broken through the mode that traditional evenly distributed set up, has adopted brand-new design theory. According to electric heat membrane service environment and by the heating surface (floor) heat transfer and the heat dissipation condition, adjustment electric heat membrane power density distribution (through the electrically conductive sectional area of adjustment interval and/or the portion that generates heat), when the occasion that heat transfer and heat dissipation are faster, heated surface temperature presents great gradient, electric heat membrane central temperature is high, the ambient temperature is low, through improving electric heat membrane peripheral power density, reduce the power density in the middle of the electric heat membrane, guarantee that electric heat membrane bulk temperature distributes evenly, prevent local high temperature, increase of service life and safety in utilization, adopt two or three heating circuit, after the problem all the way, all the other can also continue work and give off the heat, can not cause the temperature to reduce by a wide margin, especially, be fit for running long-distance motor car, provide sufficient time for the later stage change.

(2) The electric heating film of the embodiment 1 of the utility model realizes the uniform distribution of temperature by changing the distance between the adjacent parts parallel to each other of the heating parts, the middle part is slow in heat dissipation, the distance between the heating parts is large, the heating amount is small, the outside heat can be radiated to the inner side, and the middle part is ensured to reach the set temperature; the periphery is fast in heat dissipation, the distance between heating portions is small, the heating amount is large, a part of heat is radiated to the inner side, the temperature of the inner side is guaranteed, and a part of heat is radiated to the periphery, so that the periphery is guaranteed to reach the set temperature.

(3) Embodiment 2 the electric heat membrane through the interval that the portion of generating heat that adopts first electrically conductive heating strip and the electrically conductive heating strip of second is parallel to each other between the part of unchangeable structure setting throughout, the during operation begins, can two tunnel open simultaneously for electric heat membrane rapid heating up to the temperature of settlement, then close all the way, remain continuation work all the way. The two paths of heating parts are treated as a whole, the distance between the adjacent parts which are parallel to each other realizes the uniform distribution of temperature, the heat dissipation of the middle part is slow, the distance between the heating parts is large, the heat productivity is small, the heat at the outer side can be radiated to the inner side, and the middle part is ensured to reach the set temperature; the periphery is fast in heat dissipation, the distance between heating portions is small, the heating amount is large, a part of heat is radiated to the inner side, the temperature of the inner side is guaranteed, and a part of heat is radiated to the periphery, so that the periphery is guaranteed to reach the set temperature.

(4) Embodiment 3 the electric heat membrane divide into two-layer setting with the sandwich layer that generates heat, two-layer structure is the same, can simultaneous working at the beginning, intensifies rapidly, and the electric heat membrane can close all the way to setting for after the temperature. The electric heating film of this embodiment 3 can regard as two electric heating films to use, damages the back all the way, and another way can also normally continue work, need not change, has prolonged life greatly.

(5) The electric heating film (such as a carbon crystal electric heating film) used in the traditional civil building generally has the power attenuation and the great attenuation within about 3 to 5 years, the service life is mostly about 10 to 15 years, and the general design life of the rail vehicle is 30 years, so that the electric heating film is not suitable for the rail vehicle. And the utility model discloses a sandwich layer that generates heat of electric heat membrane is made for metal material, and the metal resistance circular telegram generates heat, and each side electric properties is reliable and stable, and power decay is very little, and the design life can reach more than 30 years, is applicable to among the rail vehicle heating system.

(6) The utility model discloses an embodiment 4 and embodiment 5 electrothermal film's the sandwich layer that generates heat be metal material, lean on the metal resistance circular telegram to generate heat, are pure resistive, generate heat more than 99%. And metal resistivity is positive temperature coefficient, rises to certain extent when the electric heat membrane temperature, and resistance grow, and power reduces, and restriction electric heat membrane temperature further rises, reaches balanced state very fast, consequently the utility model discloses an electric heat membrane has certain self-limiting temperature characteristic, and the safety in utilization improves greatly.

Drawings

Fig. 1 is a schematic structural view of an electrothermal film according to embodiment 1 of the present invention.

Fig. 2 is a schematic view of a layer structure of the electric heating film of embodiment 1.

Fig. 3 is a schematic structural view of an electrothermal film according to embodiment 2 of the present invention.

Fig. 4 is a schematic structural view of an electrothermal film according to embodiment 3 of the present invention.

Fig. 5 is a rear view of fig. 4.

Fig. 6 is a schematic view of a layer structure of the electric heating film of embodiment 3.

Fig. 7 is a schematic structural view of an electrothermal film according to embodiment 4 of the present invention.

Fig. 8 is a schematic structural view of an electrothermal film according to embodiment 5 of the present invention.

The reference numbers in the drawings are:

an upper insulating layer (1) is formed on the substrate,

a heating core layer 2, a first live wire connecting part 2-1, a zero line connecting part 2-2, a second live wire connecting part 2-3, a heating part 2-4, a lower zero line connecting part 2-5, an upper electric heating strip 2a, a lower conductive heating strip 2b,

the lower insulating layer 3, the adhesive layer 4,

the cable comprises an electric connection piece assembly 5, a first live wire electric connection piece 5-1, a second live wire electric connection piece 5-2, a zero wire electric connection piece 5-3 and a third insulating layer 6.

Detailed Description

In order that the present invention may be more readily and clearly understood, the following detailed description of the present invention is provided in connection with the accompanying drawings. The description of the position of the utility model is carried out according to the position shown in fig. 1, namely the left and right directions about the upper and lower that fig. 1 is shown is the back left and right direction of description, and the party that fig. 1 faced is the top, and the party that deviates from fig. 1 is the below.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures. Meanwhile, in the description of the present invention, the terms "first", "second", and the like are used only for distinguishing the description, and are not to be construed as indicating or implying relative importance.

It should be understood that the terms "upper", "lower", "inner", "outer", etc. indicate orientations or positional relationships based on the positional relationships illustrated in the drawings, and are used only for convenience in describing the present invention or simplifying the description, but do not indicate that a particular orientation must be provided.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted" and "connected" are to be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

(example 1)

Referring to fig. 1 and 2, the reliable electrothermal film of this embodiment 1 includes an upper insulating layer 1, a heating core layer 2, a lower insulating layer 3, an adhesive layer 4, and an electrical connection sheet assembly 5.

The upper insulating layer 1 and the lower insulating layer 3 are made of PET (PET is an abbreviation of Polyethylene terephthalate, abbreviated as PET or PETP) or PI (PI is an abbreviation of Polyimide, abbreviated as Polyimide in PI, and is an aromatic heterocyclic polymer compound having a molecular structure containing imide chain links) or an epoxy resin material. The upper insulating layer 1 and the lower insulating layer 5 have the same shape and size.

The heating core layer 2 is formed by laying two or three conductive heating strips, in this embodiment, two conductive heating strips are respectively called as a first conductive heating strip and a second conductive heating strip according to the difference of the front and back positions of the two conductive heating strips. Two conductive heating strips are printed on the upper side of the lower insulating layer 3 by a screen printing method through conductive heating paint (the conductive heating paint is the prior art) or the conductive heating strips are made of metal foil which is glued and compounded on the upper side of the lower insulating layer 3 through a printing and etching method, the conductive heating strips of the embodiment are made of aluminum foil which is glued and compounded on the upper side of the lower insulating layer 3 through a printing and etching method, a first live wire connecting part 2-1 and a zero wire connecting part 2-2 are respectively arranged at the head and the tail of the first conductive heating strip, a second live wire connecting part 2-3 is arranged at one end of the second conductive heating strip, and the other end of the second conductive heating strip is electrically connected with the zero wire connecting part 2-2 of the first conductive heating strip.

The first live wire connecting part 2-1, the second live wire connecting part 2-3 and the zero line connecting part 2-2 are sequentially arranged on the left part of the front part of the electric heating film from front to back. The parts between the live wire connecting part and the zero line connecting part of the two conductive heating strips are heating parts 2-4. The first conductive heating strip and the second conductive heating strip are arranged in an S shape, and the heating parts 2-4 of the first conductive heating strip and the second conductive heating strip are arranged in parallel.

The heating parts 2-4 of the first conductive heating strip and the second conductive heating strip are parallel to each other in the front-back direction and are integrally arranged in a way that the distance d between the adjacent heating parts is gradually reduced from inside to outside, namely the distance between the two adjacent heating parts 2-4 in the middle part of the first conductive heating strip in the front-back direction is larger than the distance between the two heating parts and the heating parts 2-4 of the second conductive heating strip adjacent to the outer side of each heating part; the distance between the heating part 2-4 in the middle of the first conductive heating strip and the heating part 2-4 of the second conductive heating strip adjacent to the outer side is larger than the distance between the heating part 2-4 of the second conductive heating strip and the heating part 2-4 adjacent to the outer side of the second conductive heating strip, and so on. The specific setting method comprises the following steps: according to the formula P = I R, the series state currents are the same, and the smaller the conductive sectional area of the metal strip is, the larger the resistance is, and the larger the power is;

the heat Q is proportional to the electric power P, to time, and inversely proportional to the square of the radius, the coefficient k of the formula being related to the heat dissipation condition, k ranging from 0 to 1. According to the electric heat membrane service environment and by the heat transfer and the heat dissipation condition of heating surface (floor or wallboard etc.), adjust electric heat membrane power density distribution (through the conductive sectional area of adjustment interval and/or the portion that generates heat, this embodiment is the adjustment interval), when the occasion that heat transfer and heat dissipation are faster, the surface temperature that is heated presents great gradient, electric heat membrane central temperature is high, and peripheral temperature is low, through improving electric heat membrane peripheral power density, reduces the power density in the middle of the electric heat membrane, makes the surface temperature that is heated more even.

The upper insulating layer 1 is fixed on the lower insulating layer 3 and the heating core layer 2 through hot-melt adhesive bonding, so that the heating core layer 2 is coated between the upper insulating layer 1 and the lower insulating layer 3.

The adhesive layer 4 is fixedly arranged on the lower side of the lower insulating layer 3 in a bonding mode, and release paper is arranged on the lower side of the adhesive layer 4.

The electrical connection pad assembly 5 comprises a first live electrical connection pad 5-1, a second live electrical connection pad 5-2 and a neutral electrical connection pad 5-3. The first live wire electric connection piece 5-1, the second live wire electric connection piece 5-2 and the zero wire electric connection piece 5-3 are all made of copper materials. The first live wire electric connection sheet 5-1 is fixedly connected by piercing and crimping and is electrically connected to the part of the first live wire connection part 2-1 coated by the upper insulation layer 1 and the lower insulation layer 3, and the lower insulation layer 3 is pierced downwards to form riveting and fixing connection. The second live wire electric connection sheet 5-2 is fixedly connected by piercing and crimping and is electrically connected to the part of the second live wire connection part 2-3 coated by the upper insulation layer 1 and the lower insulation layer 3, and the lower insulation layer 3 is pierced downwards to form riveting and fixing connection. The zero line electric connection sheet 5-3 is fixedly connected by puncture and compression joint and is electrically connected with the position of the zero line connection part 2-2 coated by the upper insulating layer 1 and the lower insulating layer 3.

The utility model discloses a can bond through the adhesive layer when electric heat membrane uses fixedly and set up in floor or wallboard, first live wire electricity connection piece 5-1, second live wire electricity connection piece 5-2 and zero line electricity connection piece 5-3 are connected through corresponding wire and the live wire and the zero line electricity of power, and the part that part and zero line electricity connection piece 5-3 and corresponding wire electricity that each live wire electricity connection piece and corresponding wire electricity are connected seal the processing through waterproof sealed glue

(example 2)

Referring to fig. 2 and 3, the rest of the present embodiment is the same as embodiment 1, except that: the distance between the mutually parallel parts of the heating parts 2-4 of the first conductive heating strip and the second conductive heating strip is always kept consistent, and the distance d1 between the central lines of the mutually parallel parts of the heating parts 2-4 of the two adjacent sections of the first conductive heating strip and the second conductive heating strip is integrally and gradually reduced from inside to outside.

(example 3)

Referring to fig. 3 to 5, the rest of the present embodiment is the same as embodiment 1, except that: the third insulating layer 6 is further included, and the third insulating layer 6 is made of PET (PET is an abbreviation of Polyethylene terephthalate, abbreviated as PET or PETP) or PI (PI is an abbreviation of Polyimide, abbreviated as Polyimide in PI, and is a heterocyclic aromatic polymer compound with a molecular structure containing imide chain links) or an epoxy resin material. The third insulating layer 6 and the lower insulating layer 5 have the same shape and size.

The heating core layer 2 is formed by laying two conductive heating strips, and the two conductive heating strips are respectively called an upper conductive heating strip 2a and a lower conductive heating strip 2b according to the difference of the upper and lower positions of the two conductive heating strips. The upper conductive heating strip 2a is formed by printing conductive heating paint (the conductive heating paint is the prior art) on the upper side of the lower insulating layer 3 through a screen printing method to form an upper heating core layer, and the head and the tail of the upper conductive heating strip 2a are respectively provided with a first live wire connecting part 2-1 and a zero wire connecting part 2-2. The part between the first live wire connection part 2-1 and the neutral wire connection part 2-2 of the upper conductive heating bar 2a is a heating part 2-3. The heating parts 2-3 are arranged in an S shape, and the distance d2 between the adjacent parts of the heating parts 2-3 parallel to each other in the front-back direction is gradually reduced from inside to outside.

The upper insulating layer 1 is fixed on the lower insulating layer 3 and the heating core layer 2 through hot-melt adhesive hot-pressing adhesion, so that the upper heating core layer of the heating core layer 2 is coated between the upper insulating layer 1 and the lower insulating layer 3.

The lower conductive heating strip 2b is formed by printing conductive heating paint (the conductive heating paint is the prior art) on the lower side of the lower insulating layer 3 through a screen printing method to form a lower heating core layer, and the head and the tail of the lower conductive heating strip 2b are respectively provided with a second live wire connecting part 2-3 and a lower zero line connecting part 2-5. The part between the second live wire connecting part 2-3 and the lower neutral wire connecting part 2-5 of the lower conductive heating bar 2b is a heating part 2-3. The heating parts 2-3 are arranged in an S shape, and the distance between the adjacent parts of the heating parts 2-3 which are parallel to each other in the front-back direction is gradually reduced from inside to outside. The positions of the lower neutral wire connecting part 2-5 and the heating part 2-3 of the lower conductive heating strip 2b in the vertical direction correspond to the positions of the neutral wire connecting part 2-2 and the heating part 2-3 of the upper conductive heating strip 2 a.

The third insulating layer 6 is fixed on the lower side of the lower insulating layer 3 and the lower heating core layer through hot-melt adhesive hot-pressing adhesion, so that the lower heating core layer of the heating core layer 2 is coated between the third insulating layer 6 and the lower insulating layer 3.

The adhesive layer 4 is fixedly arranged on the lower side of the third insulating layer 6 in a bonding mode, and release paper is arranged on the lower side of the adhesive layer 4.

The first live wire connecting piece 5-1 of the electric connecting piece assembly 5 is electrically connected to the first live wire connecting part 2-1 coated on the upper insulating layer 1 and the lower insulating layer 3 by piercing, and the third insulating layer 6 is pierced downwards to form riveting fixed connection. The second live wire electric connection sheet 5-2 is electrically connected to the part of the second live wire connection part 2-3 coated by the lower insulation layer 3 and the third insulation layer 6 by piercing, and the third insulation layer 6 is pierced downwards to form riveting fixed connection. The zero line electric connection piece 5-3 is electrically connected to the part of the zero line connection part 2-2 coated by the upper insulation layer 1 and the lower insulation layer 3 and the part of the lower zero line connection part 2-5 coated by the lower insulation layer 3 and the third insulation layer 6 by puncturing, and the third insulation layer 6 is punctured downwards to form riveting fixed connection.

(example 4)

Referring to fig. 7, the rest of the present embodiment is the same as embodiment 2, except that: the distance between the adjacent parallel parts of the heating parts 2-4 is gradually reduced from inside to outside. The specific method comprises the following steps: according to the formula P = I R, the series state currents are the same, and the smaller the conductive sectional area of the metal strip is, the larger the resistance is, and the larger the power is;

the heat Q is proportional to the electric power P, to time, and inversely proportional to the square of the radius, the coefficient k of the formula being related to the heat dissipation condition, k ranging from 0 to 1. According to electric heat membrane service environment and by the heating surface (floor) heat transfer and the heat dissipation condition, adjust electric heat membrane power density distribution (this embodiment is realized through adjusting the interval), when the occasion that heat transfer and heat dissipation are faster, heated surface temperature presents great gradient, electric heat membrane central temperature is high, peripheral temperature is low, through improving electric heat membrane peripheral power density, reduce the power density in the middle of the electric heat membrane, make by heating surface temperature more even, the difference in temperature is at 5 degrees centigrade

(example 5)

See FIG. 8, this embodimentThe rest of the example is the same as example 2, except that: the distance between the adjacent parallel parts of the heating parts 2-4 is gradually increased from inside to outside, and the conductive sectional area of the heating parts 2-4 is gradually reduced from inside to outside. The specific method comprises the following steps: according to the formula P = I R, the series state currents are the same, and the smaller the conductive sectional area of the metal strip is, the larger the resistance is, and the larger the power is;

the heat Q is proportional to the electric power P, to time, and inversely proportional to the square of the radius, the coefficient k of the formula being related to the heat dissipation condition, k ranging from 0 to 1. According to the electric heat membrane service environment and by the heating surface (floor) heat transfer and the heat dissipation condition, adjust electric heat membrane power density distribution (this embodiment adjusts the interval simultaneously and the portion that generates heat the electrically conductive sectional area that generates heat realizes), when the occasion that heat transfer and heat dissipation are faster, the surface temperature that is heated presents great gradient, electric heat membrane central temperature is high, and peripheral temperature is low, through improving electric heat membrane peripheral power density, reduces the power density in the middle of the electric heat membrane, makes by heating surface temperature more even, the difference in temperature 5 degrees centigrade.

The above-mentioned embodiments, further detailed description of the objects, technical solutions and advantages of the present invention, it should be understood that the above-mentioned embodiments are only specific embodiments of the present invention, and are not intended to limit the present invention, and any modifications, equivalent substitutions, improvements, etc. made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (8)

1. The utility model provides a better electric heat membrane of reliability which characterized in that: the heating chip comprises an upper insulating layer, a heating core layer, a lower insulating layer and an electric connecting chip assembly; the heating core layer is formed by laying two conductive heating strips, and the two conductive heating strips are respectively called as a first conductive heating strip and a second conductive heating strip according to the difference of the front position and the rear position of the two conductive heating strips; the head and the tail of the first conductive heating strip are respectively provided with a first live wire connecting part and a zero line connecting part, one end of the second conductive heating strip is provided with a second live wire connecting part, and the other end of the second conductive heating strip is electrically connected with the zero line connecting part of the first conductive heating strip; the parts between the live wire connecting part and the zero line connecting part of the two conductive heating strips are heating parts; the first conductive heating strip and the second conductive heating strip are arranged in an S shape, and the heating parts of the first conductive heating strip and the second conductive heating strip are arranged in parallel; the heating core layer is coated between the upper insulating layer and the lower insulating layer; the electric connection piece assembly comprises a first live wire electric connection piece, a second live wire electric connection piece and a zero wire electric connection piece; the first live wire electric connecting sheet is fixedly connected and electrically connected to the part of the first live wire connecting part coated by the upper insulating layer and the lower insulating layer; the second live wire electric connecting sheet is fixedly connected and electrically connected to the part of the second live wire connecting part coated by the upper insulating layer and the lower insulating layer; the zero line electric connection sheet is fixedly connected and electrically connected with the part of the zero line connection part coated by the upper insulating layer and the lower insulating layer.

2. The electrothermal film with better reliability as claimed in claim 1, wherein: still include the adhesive layer, the adhesive layer bonds fixedly to set up on the downside of insulating layer down, and the downside of adhesive layer is equipped with from type paper.

3. The electrothermal film with better reliability according to claim 1 or 2, characterized in that: the heating parts of the first conductive heating strip and the second conductive heating strip are parallel to each other in the front-rear direction, and the whole part is arranged in a way that the distance d between the adjacent heating parts is gradually reduced from inside to outside, namely the distance between the two adjacent heating parts in the middle in the front-rear direction of the first conductive heating strip is larger than the distance between the two heating parts and the heating parts of the second conductive heating strip adjacent to the outer side of the first conductive heating strip; the distance between the heating part in the middle of the first conductive heating bar and the heating part of the second conductive heating bar adjacent to the outer side is larger than the distance between the heating part of the second conductive heating bar and the heating part of the second conductive heating bar adjacent to the outer side.

4. The electrothermal film with better reliability according to claim 1 or 2, characterized in that: the distance between the mutually parallel parts of the heating parts of the first conductive heating strip and the second conductive heating strip is always kept consistent, and the distance d1 between the central lines of the mutually parallel parts of the adjacent two sections of the first conductive heating strip and the second conductive heating strip is gradually reduced from inside to outside.

5. The electrothermal film with better reliability according to claim 1 or 2, characterized in that: the conductive heating strip of the heating core layer is made of metal material; the interval between the adjacent parts of the heating part which are parallel to each other is gradually reduced from inside to outside, or the conductive sectional area of the heating part is gradually reduced from inside to outside, or the interval between the adjacent parts of the heating part which are parallel to each other is gradually increased from inside to outside, and simultaneously the conductive sectional area of the heating part is gradually reduced from inside to outside.

6. The utility model provides a better electric heat membrane of reliability which characterized in that: the heating core layer is arranged on the upper insulating layer; the heating core layer is formed by laying two conductive heating strips, and the two conductive heating strips are respectively called as an upper conductive heating strip and a lower conductive heating strip according to the difference of the upper position and the lower position of the two conductive heating strips; the head and the tail of the upper conductive heating strip are respectively provided with a first live wire connecting part and a zero line connecting part; the part between the first live wire connecting part and the zero line connecting part of the upper conductive heating strip is a heating part;

the heating part is arranged in an S shape, and the distance d2 between the adjacent parts of the heating part which are parallel to each other in the front-back direction is gradually reduced from inside to outside; the upper insulating layer is fixed on the lower insulating layer and the heating core layer through hot-melt adhesive bonding, so that the upper heating core layer of the heating core layer is coated between the upper insulating layer and the lower insulating layer;

the head and the tail of the lower conductive heating strip are respectively provided with a second live wire connecting part and a lower zero line connecting part; the part between the second live wire connecting part and the lower zero line connecting part of the lower conductive heating strip is a heating part; the heating part is arranged in an S shape, and the distance between the adjacent parts of the heating part which are parallel to each other in the front-back direction is gradually reduced from inside to outside; the positions of the lower zero line connecting part and the heating part of the lower conductive heating strip in the up-down direction correspond to the positions of the zero line connecting part and the heating part of the upper conductive heating strip; the third insulating layer is fixed on the lower side of the lower insulating layer and the lower heating core layer through hot-pressing adhesion of a hot melt adhesive, so that the lower heating core layer of the heating core layer is coated between the third insulating layer and the lower insulating layer;

the electric connection piece assembly comprises a first live wire electric connection piece, a second live wire electric connection piece and a zero wire electric connection piece; the first live wire electric connecting sheet is fixed and electrically connected to the first live wire connecting part coated by the upper insulating layer and the lower insulating layer; the second live wire electric connecting sheet is fixed and electrically connected to the position of the second live wire connecting part coated by the lower insulating layer and the third insulating layer; the zero line electric connection sheet is fixed and electrically connected to the part of the zero line connection part coated by the upper insulating layer and the lower insulating layer and the part of the lower zero line connection part coated by the lower insulating layer and the third insulating layer.

7. The electrothermal film with better reliability as claimed in claim 6, wherein: still include the adhesive layer, the adhesive layer bonds fixedly to set up on the downside of third insulating layer, and the downside of adhesive layer is equipped with from type paper.

8. The electrothermal film with better reliability as claimed in claim 7, wherein: the conductive heating strip of the heating core layer is made of metal material; the interval between the adjacent parts of the heating part which are parallel to each other is gradually reduced from inside to outside, or the conductive sectional area of the heating part is gradually reduced from inside to outside, or the interval between the adjacent parts of the heating part which are parallel to each other is gradually increased from inside to outside, and simultaneously the conductive sectional area of the heating part is gradually reduced from inside to outside.

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