RU180942U1 - Composite Flexible Electric Heater - Google Patents

Abstract

The utility model relates to electrical engineering. A composite flexible electric heater contains a flexible sheet resistive heating element 1 connected through conductive busbars 2 and 3 to a power source and enclosed between insulating layers 6 and 7, as well as heat-insulating 9 and decorative layers 12. According to the utility model, the front side of the electric heater between the outer insulating layer 6 and the resistive heating element 1 is a reinforcing layer 11 of fiberglass impregnated with a thermosetting binder him, and the decorative layer 12 is located between the inner side of the outer insulating layer 6 and the reinforcing layer 11. The technical problem that the utility model addresses is the improvement of consumer properties by eliminating wrinkling when folding the heater into a “tube” during transportation and storage during its non-use. 10 s.p. f-ly, 2 ill.

Description

The utility model relates to electrical engineering, namely to household radiating-type heating devices with a high degree of moisture and electrical protection.

Known electric heater containing a thin-layer flexible non-metallic heating element connected to power. A flexible non-metallic heating element is a conductive layer based on a carbon composition, reliably sealed between two layers of a durable dacron film. When connected to an electrical network, a flexible non-metallic heating element is heated to a temperature of 70 ° C (RU, No. 130374, class F24C 7/00, published on July 20, 2013).

The disadvantage of this device is the limited range of electrical resistivity, as well as a low maximum operating temperature (70 ° C), which is not enough for domestic and industrial heaters due to the low conductivity of the resistive material used in heaters, as well as the low heat resistance of some structural materials, for example glues.

Known flexible heating resistive element containing a fabric substrate and a conductive resistive layer based on a carbon - polymer composition. The conductive resistive layer is formed on the basis of a resistive carbon composite material deposited in the form of a colloidal suspension on a heat-resistant fabric base; the resistive carbon composite material contains carbon black with a highly developed specific surface area of 300–600 m ² / g and higher, with a particle size of 10 to 50 nm in combination with colloidal graphite preparations with graphite particle sizes less than 4 μm, and as a binder - a solution of heat-resistant polymer binder. In addition, in a flexible heating resistive element, either polyethylene terephthalate or lavsan is used as a heat-resistant fabric base. In addition, OMCARB ™ CH210, and / or CH220, and / or CH230 and OMCARB ™ CH600 carbon black, as well as colloidal graphite preparations or C-0 or C-1, or ground to a particle size of less than 4 microns natural graphites. In a resistive carbon composite material, a heat-resistant polymer in the form of a polyester based on either terephthalic acid, or sebacic acid, or adipic acid, or ethylene glycol, or diethylene glycol, or part of these components, for example, TF-60 resin, is used as a binder. In the resistive carbon composite material, either chloroform, or methylene chloride, or dichloroethane, or others that efficiently dissolve the polymer binder, are used as solvents (RU, No. 151642, class H01C7 / 00, published April 10, 2015).

A disadvantage of the known heating element is the use of toxic materials in the manufacture of the device, as well as the high production costs.

The closest in technical essence to the claimed utility model includes a composite heating electric device containing a flexible sheet resistive heating element connected through conductive leads to a power source and enclosed in an insulating shell consisting of a woven or non-woven reinforcing material impregnated with a synthetic resin. A composite heating electric device includes a decorative layer located on one side of the insulating shell made of synthetic resin with the addition of a catalyst, as well as a thermal insulation layer in the form of fiberglass material, located on the other side of the sheet heating element in the insulating shell (RU, No. 147183, cl. H05B3 / 36, publ. 10/27/2014).

The disadvantages of the known device are the low mechanical characteristics due to the susceptibility of the flexible heater to wrinkling when folded, which is inconvenient during transportation and storage during non-use, and this affects the consumer properties of the product, because the decorative layer applied to the outer surface of the heater is damaged.

The technical problem to which the utility model is aimed is to increase consumer properties by eliminating wrinkling when folding the heater into a “tube” during transportation and during storage during its non-use.

This problem is solved due to the fact that the composite flexible electric heater contains a flexible sheet resistive heating element connected through conductive busbars to a power source and enclosed between insulating layers, as well as heat-insulating and decorative layers. According to a utility model, a reinforcing layer of fiberglass impregnated with a thermosetting binder is located between the outer insulating layer and the resistive heating element on the front side of the electric heater, and the decorative layer is located between the inner side of the outer insulating layer and the reinforcing layer.

On the back side between the insulating and insulating layers is a reflective layer made of aluminum foil.

The resistive heating element is made in the form of a film with an electrically conductive coating PEP-R-700 (± 500).

The insulating layer is made of polymeric material.

The reinforcing layer is made of fiberglass brand PS-IF / EP-0,110 or PS-FAF / EP, with a thickness of 30 to 200 microns.

The thermal insulation layer is made up to 2 mm thick from a material with a thermal conductivity of 0.0037 W / (m⋅K), withstanding temperatures up to 150 ° C, for example polyurethane foam or foamed polyethylene.

The thermal insulation layer is fixed on the back side by diffusion, or with double-sided tape, or with a textile fastener (Velcro tape), or with glue.

On the back side of the insulating layer is an absorbing layer in the form of a black paint coating.

The decorative layer is applied with quick-drying paint, such as nitro or alcohol-based, on the inside of the outer insulating layer.

The decorative layer is made in the form of a flexible sheet material with decor elements, for example paper, fabric, non-woven material, and is located between the reinforcing and external insulation layers with the decorative side facing the inner side of the external insulation layer.

The external insulating and decorative layers are interconnected by ethylene vinyl acetate - EVA glue, with a vinyl acetate content of 3 to 28% and a fluidity of 0.5 to 25 g / 10 min.

The location of the resistive heating element with conductive busbars between the insulating layers provides it with a high degree of protection against moisture, dust and mechanical damage, thereby increasing reliability and durability during operation.

The presence of a reinforcing layer of fiberglass brand PS-IF / EP also PS-FAF / EP increases the mechanical strength of the heater and provides its flexibility, allowing for transportation to twist it into a "tube" without creases with a small bending radius. In this case, the use of fiberglass with impregnation provides bonding of the resistive heating element with a decorative coating and an insulating layer, facilitating the heat treatment during lamination. Fiberglass provides increased adhesion due to the fleecy surface, as a result of which the area of contact with the joined layers increases, more than 1,000,000 times, as on an adhesive basis. The glass fabric of the PS-IF / EP brand is already saturated with epoxy-phenol-formaldehyde varnish, which is a binder, and the diffusion process increases with lamination. At the same time, the fiberglass itself also serves as a strong, flexible binding and reinforcing element, thereby increasing the strength and necessary flexibility, while preventing the formation of thermal deformation folds (wrinkling) of the heater at elevated temperatures, increasing the resistance to spontaneous combustion and other operational characteristics of the heater.

Applying a decorative layer on the inner surface of the insulating layer avoids the effects of mechanical damage, ultraviolet radiation, as well as reactions to an aggressive environment, creating ample opportunities for decorative design of a flexible heating device and a diverse range of applications of the finished product in the interior, thereby increasing the consumer properties of the product.

The connection of composite layers of the insulating layer by lamination is high-tech and simple.

The location of the reflecting and absorbing layers on the rear side of the heater allows the formation of directional radiation, thereby increasing the heat-carrying ability of a flexible heating device, which increases its energy performance.

The utility model is illustrated by drawings, where in FIG. 1 shows the appearance of a composite flexible electric heater; in FIG. 2 - sectional heater.

Composite flexible electric heater contains a flexible resistive heating element 1, made in the form of a film with an electrically conductive coating PEP-R-700 (± 50), with conductive buses 2 and 3, equal in length for uniform heating of the resistive heating element 1, located on both sides . Tires 2 and 3 are connected to the power supply through current-carrying copper leads 4 and 5 made of stranded copper wire without a sheath. The heating element 1 with conductive busbars 2 and 3 is enclosed between the insulating layers, one of which is located on the front side of the heater - the outer insulating layer 6 and the back insulating layer 7. The insulating layers 6 and 7 are made of polymer material, which, when they are heat treated with a temperature of 80 to 150 ° C, and when exposed to a pressure of 0.4 to 18 kg / cm form a monolithic product, durable and flexible, providing electrical safety and tightness of the heater during its operation. On the back of the heater behind the insulating layer 7 is a reflective layer 8 made of aluminum foil. Behind the reflective layer 8 there is a heat-insulating layer 9 made of polyurethane foam or foamed polyethylene, up to 2 mm thick. The heat-insulating layer 9 is attached on the back of the heater with double-sided tape, or with a textile fastener such as Velcro tape, or with glue (not shown in the figure). The heat-insulating layer 9 is coated with black paint in the form of an absorbing layer 10. On the front side of the heater, between the insulating layer 6 and the flexible resistive heating element 1, there is a reinforcing layer 11 made of PS-IF / EP fiberglass impregnated with epoxy-phenol-formaldehyde varnish. The decorative layer 12 can be applied using nitro-paint or alcohol-based paint to the inner face of the insulating layer 6. The decorative layer 12 can also be made on any flexible medium, for example, paper, fabric, non-woven material, etc. and facing the decor towards the inner side of the outer insulating layer 6.

For the manufacture of a composite flexible heater, a film with an electrically conductive coating PEP-R-700 (± 500) is used as a resistive heating element 1. To the element 1 on the sides is attached using lamellas (not shown in the figure) formed on a conductive bus bar that pierce the resistive layer and bend on the other hand, mechanically attracting the resistive layer to the busbars 2 and 3, thereby forming conditions for heating. On the front surface of the element 1 is a reinforcing layer 11 of their fiberglass brand PS-IF / EP. A heating element 1 with a reinforcing layer 11 is placed between the insulating layers 6 and 7. At the same time, decor, for example, with nitro-paint, is applied to the inner side of the layer 6, or a decorative layer 12 in the form of a flexible material with a pattern is placed between the reinforcing layer 11 and the inner side of the layer 6, while the side with the pattern facing the inner side of layer 6. Then, the heating element with reinforcing 11, decorative 12 and insulating layers 6 and 7 is subjected to lamination at a temperature of from 80 to 150 ° C and at a pressure of 0.4 to 18 kg / cm.

Then, on the back side, a reflective layer 8 of aluminum foil is attached using EVA glue. With the help of glue, or double-sided tape, or Velcro tape, a heat-insulating layer 9 of polyurethane foam or foamed polyethylene up to 2 mm thick is attached to the back of the device. At the back, the heat-insulating layer 9 is coated with black paint, thereby forming an absorbent layer 10.

Composite flexible heater is used as follows.

The electric heater is placed on the wall (or other surface) by attaching or hanging on the wall through an opening or loop in the upper decorative strip. The current-carrying leads 4 and 5 through the power cord 13 are plugged into a socket, after which the current is supplied to the current-carrying buses 2 and 3. Due to the rigid connection of the heating element 1 with copper current-carrying buses 2 and 3, it quickly and uniformly heats up and radiates thermal energy in infrared the range that passes through the insulating layer 6, partially heating it due to thermal conductivity, into the surrounding space. The reflective layer 8 prevents the spread of heat to the side adjacent to the wall, and redirects it towards the heated space. The heat-insulating layer 9 in the electric heater accumulates heat and prevents the passage of heat flow to the back of the heater and its dissipation by heat loss. If necessary, the heating temperature of a flexible electric heater can be adjusted by connecting it to a power source through a temperature regulator, this will save energy consumption by half.

Composite flexible electric heaters, depending on the purpose, can be made in different sizes, colors and configurations. Using a decorative layer 12 in the form of various panels, which is reliably protected by the fact that it is located on the inner side of the insulating layer 6, it improves the design characteristics, expands the range, increases the consumer properties of heaters.

The use of a composite flexible electric heater reduces the specific current load on the flexible heating element due to the current distribution over the entire carbon surface. Thus, the entire surface works, which practically corresponds to the area of the flexible heating device as a whole.

The claimed device is highly reliable in operation, technologically advanced, moisture resistant, heat resistant, electrically safe, does not require sophisticated equipment and finds a wide scope.

Claims (11)

1. Composite flexible electric heater containing a flexible sheet resistive heating element connected through conductive busbars to a power source and enclosed between the insulation layers, as well as heat-insulating and decorative layers, characterized in that on the front side of the electric heater between the outer insulation layer and the resistive heating element a reinforcing layer of fiberglass impregnated with a thermosetting binder, and a decorative layer is located between the inner sides the outer insulating layer and the reinforcing layer. 2. A composite flexible electric heater according to claim 1, characterized in that on the back side between the insulating and heat-insulating layers there is a reflective layer made of aluminum foil. 3. A composite flexible electric heater according to claim 1, characterized in that the resistive heating element is made in the form of a film with an electrically conductive coating PEP-R-700 (± 500). 4. A composite flexible electric heater according to claim 1, characterized in that the insulating layer is made of a polymeric material. 5. Composite flexible electric heater according to claim 1, characterized in that the reinforcing layer is made of fiberglass brand PS-IF / EP-0,110 or PS-FAF / EP, with a thickness of 30 to 200 microns. 6. A composite flexible electric heater according to claim 1, characterized in that the heat-insulating layer is made up to 2 mm thick from a material with a thermal conductivity of 0.0037 W / (m⋅K) that can withstand temperatures up to 150 ° C, for example, polyurethane foam or foamed polyethylene. 7. A composite flexible electric heater according to claim 1, characterized in that the heat-insulating layer is fixed on the rear side by diffusion, or with double-sided tape, or with a textile fastener (Velcro tape), or with glue. 8. A composite flexible electric heater according to claim 1, characterized in that on the back side of the insulating layer is an absorbing layer in the form of a black paint coating. 9. A composite flexible electric heater according to claim 1, characterized in that the decorative layer is applied with quick-drying paint, for example nitro or alcohol-based, on the inner side of the outer insulating layer. 10. A composite flexible electric heater according to claim 1, characterized in that the decorative layer is made in the form of a flexible sheet material with decor elements, for example paper, fabric, non-woven material, and is located between the reinforcing and external insulation layers with the decorative side facing the inner side of the outer insulating layer. 11. A composite flexible electric heater according to claim 10, characterized in that the outer insulating and decorative layers are interconnected by ethylene vinyl acetate - EVA glue, with a vinyl acetate content of 3 to 28% and a fluidity of 0.5 to 25 g / 10 min.

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