DE20319024U1 - Flat heating element made up of multiple layers for converting electric energy into heat energy formed by screen printing - Google Patents

Abstract

The heater element is a resistive heater with a multiple layer construction. It converts electric energy into heat energy and provides this to the substrate material of the heater element. The substrate material has a flat, curved or multi-dimensional surface. The heat generating conductor is formed on the substrate material to be heated, by means of a screen printing process. A plastic based insulating layer is formed over the electric conductor by a screen printing process or by spraying or rolling. The insulating layer is dried at temperatures of no more than 300[deg]C and hardened.

Description

The present invention relates to a surface heating element, for use in the production of low process temperatures come, as well as the surface heating elements produced by this method.

Several surface heating elements are known from the literature. So describes the US 4,203,198 a surface heating element in which a thin metal foil is embedded between two layers of glass fiber mats and the entire sandwich arrangement is fixed with a temperature-resistant binder. The binder contains colloidally bound silicon particles. The glass fiber layers serve as a base, as a cover and as an insulation layer, the metal foil forms the resistance heating element.

The DE 21 51 626 calls a rigid, heatable surface heating element, which consists of a thin, heat-resistant, rigid, heat-emitting layer, which has an electrically conductive film with corresponding electrical connections and is connected to a thicker, electrically insulating, rigid layer. To form the electrically conductive film, an aqueous plastic dispersion which contains electrically conductive particles such as noble metals, carbon, carbon black or graphite and additionally potassium or sodium silicate is applied to the thin, heat-emitting layer. After the aqueous dispersion has dried at temperatures of approximately 90 ° C., a thicker, heat-insulating layer of rigid polyurethane foam is applied by the foam-forming reaction mixture coming into direct contact with the electrically conductive film.

From the DE 196 38 640 is a surface heating element for ceramic hobs. The heating conductor is separated from a metal foil, for example by punching out or etching out. This film is suspended in the distance between the insulation base plate and the ceramic hob, whereby the effects of thermal expansion, which occur at temperatures of up to 1200 C, can be compensated for by sagging in the air space.

A heating foil with a heating conductor pattern is also used DE 100 25 539 , Here, however, a ceramic-filled polymer layer is arranged between the heating foil and the surface to be heated. The polymer layer connected to the heating foil is pressed with an insulating molded body against the surface to be heated or glued to this surface. The ceramic-filled polymer layer has a very low heat transfer resistance combined with a high electrical insulation capacity. The polymer layer is stable up to about 150 ° C. This heating surface is preferably attached to the outside of a water-filled container. Due to the good heat-conducting connection with the surface to be heated, the heating device remains at comparatively low temperatures.

In the DE 27 19 174 describes a heatable exterior mirror for motor vehicles, in which a resistance layer made of carbon synthetic resin is printed on an insulating layer and covered with a further insulating layer made of epoxy resin or silicone rubber. The layers are printed, sprayed or spread using the screen printing process. The power supply electrodes consist of a solderable conductive paste.

The use of carbon conductive varnishes and the printing with the help of the screen printing process is in "PCB 86, Volume 1, PCB production today ", Karlsruhe 5/6 May 1986, VDI / VDE Gesellschaft Feinwerktechnik, Düsseldorf, Pages 97 to 102. In this publication, leaders described from carbon-conductive varnish, which on plastic films, for example Polyimide films are applied. Such trace foils can by Glue to be connected to the component to be heated.

Furthermore describes the DE 35 25 488 a heating device for keeping the surface reflector of an antenna free of ice, the use of graphite varnish as a heating conductor, which is applied using a printing process or by spraying on using a template, being described. The heating power is around 200 to 400 W / m ² . However, this area performance is not sufficient for applications as a warming area or for tempering or heating a container, since heating powers of 0.1 to 30 W / cm ^{2 are} required here.

From the publication collection of the Patent offices numerous publications on heating devices are still known, which are operated with electric current. You ever let yourself according to temperature level in the application area in high temperature and differentiated in low temperature applications. For high temperature applications, which Temperatures above 300 ° C, are very temperature resistant Materials required. These devices can be used for air heating, for steam generation, for toaster, Soldering equipment, ironing machines and the like can be used. With the low temperature heating elements there are applications in the area of surface temperature control, such as hot plates, Defrosting devices, aquarium heaters, mirror and glass heaters, Warming devices for gaseous and fluid Media and the like.

If the surface to be heated is metallic, is between this surface and the heating element usually an insulation layer is arranged. This can be from email, from a Plasma layer, of metal oxide, of metal nitrite, of insulating adhesive or consist of a plastic layer, such as a plastic film.

Low-temperature elements, such as those used for warming plates, are preferably made of heatable ceramics made of Wi derstandsmaterial coated plastic films, or from thick-film elements with coatings that are applied by screen printing or by a spray process.

Heated ceramics have the disadvantage that the mechanical resilience is generally very low, but theirs Manufacturing is complex and therefore expensive. Resistance heating elements, which by etching from a metal foil and then glue it to a plastic foil or by printing a conductive material on a plastic film have the major disadvantage of being bubble-free Gluing of the heating element produced in this way with the carrier is required is. As soon as there are any glueing defects or there are old-age replacements or If blistering occurs, gas-filled areas with poorer quality arise heat transfer and lead subsequently to an overload of the heating element at adjacent locations. If a critical is exceeded There is an interruption in the current conductor and that Heating element falls entirely out.

Heating elements made in thick film technology and where the dielectric is sprayed or by a printing process manufactured have the advantage of being direct and permanent Connection to the support surface, she but usually require Firing temperatures above 300 ° C. As a result, in addition to the sintering process, the thick-film pastes also the surface of the support optically changed. With these elements there are therefore additional surface treatments, such as grinding and polishing. Another disadvantage lies in that on most plastics and in some cases also no printing on aluminum and other non-ferrous metals possible is.

The present invention provides therefore the task of a panel heater with printed or sprayed on To create dielectric with which a permanent, reliable heating element on a carrier can be manufactured in which there is no life span of the Heating element impairing overheating problems can come from blistering, in the manufacturing process only temperatures below 300 ° C are used. Furthermore, the surface heating element on any carrier be built up and no post-processing such as grinding or polishing require.

This task is due to the technical characteristics solved, which are reproduced in the characterizing part of claim 1. Advantageous refinements or developments are the subject the dependent Expectations.

Through the use proposed according to the invention an insulation varnish or one in the field of insulation of electrical Components such as windings, capacitors, electrical potting compounds, which by spray techniques or applied by printing techniques such as screen printing or pad printing used, the insulation layers required for a resistance layer can be used produce. Use has proven to be particularly advantageous here of curable solder resists with a temperature resistance of up to 300 ° C proved. Due to the bubble-free or low-bubble application the metallic support can the for the respective insulation voltages required by single or multiple printing or by application using spray technology achieve.

On this insulating layer is a conductive paste plotted with a defined resistance value. Particularly advantageous is the application of conductive carbon coatings, which have a specific resistance in the range of 1 to 1000 ohms / unit area have, as well as temperature resistant and stable in the required Temperature range.

According to the required heated areas and the resulting power and resistance value the printed area a full area Training or a sequence of individual conductor tracks, which for example meandering or spiral, but also consist of alternately thick and thin conductor tracks can. There are no limits to the specific design.

The curing of the individual pastes takes place here at temperatures of maximum 300 ° C. By limiting this Curing temperature comes there are no visible changes the metallic carrier substance.

For the final one Protective covering of the heating element can use the same insulating varnishes can be used, which means a complete enclosure of the electrically conductive structure is achieved.

Be in this protective cover keep clear those areas where the power connections will be made later should. The electrical connection can be made, for example, via plug-in flags take place directly on the electrically conductive heating element Conductive adhesive are glued on. Another option is, for example the application of conductive lacquers based on silver or copper or other solderable Metals in the area of the connection points. One more way consists of attaching flags or strands to the heating element suitable soldering or welding processes. An alternative way provides the use of specially trained surface pressure contacts with an electrically good conductive and thus a safe current transfer guaranteeing surface represents.

For the regulation of the heating power are known from the prior art NTC and PTC elements, paste prints or connecting cables, such as mechanical thermostats or electronic controls are also possible.

The direct application of the temperature-resistant insulation layer to the metallic carrier and the use of electrical resistance pastes such as carbon conductive varnishes allow short-term power densities of up to 30 W / cm ² with sufficient energy dissipation.

With the method according to the invention can but also electrically insulating materials, such as plastics, metal oxides and metal nitrites can be printed. This is not necessary due to the self-insulating Property of the carrier material the need to apply a basic insulation layer.

One for the method according to the invention preferred carbon conductive varnish consists of coal dust and graphite Grain sizes between 5 and 7 μm. The Solids is preferably 67% and the specific weight is 1.15. It is a one or two component, thermal curing Resin mixture.

That according to the inventive method manufactured surface heating element can for Voltages up to 400V AC or 600V DC can be used. However, the preferred area of application is 12 to 24 V DC or AC voltage, as well as 230 to 400 V AC voltage.

The particular advantages of the surface heating element according to the invention lie in that arbitrarily shaped geometric support materials can be used which in turn can consist of any material. So can both electrically conductive carrier materials, made of aluminum, copper or steel, for example also those made of non-conductive material, such as plastic, metal oxide, Metal nitrite or also electrically conductive supports on which in a previous one Manufacturing step an electrically insulating coating, for example from Enamel or glass was applied.

Another advantage is that there is no peeling of the heat generating electrical conductor and therefore none of the life of the heating element impairing overheating problems can come from blistering. Furthermore, due to the low Process temperatures in the manufacturing process no post-processing, such as grinding or polishing required.

In compliance with the electrical safety regulations in terms of touch voltage in certain circumstances also the outer insulation and cover layer are dispensed with, without thereby endangering durability the electrically conductive layer occurs.

The main area of application from today's perspective are applications in the range up to about 100 ° C and low wing loads.

The surface heating element according to the invention is shown by way of example in the figures. However, it is expressly not limited to these embodiments. It shows 1 a carrier material 1 on which an insulating layer 2 , two adjacent conductor tracks 3 and a covering insulating layer 4 are applied in successive process steps.

2 shows a carrier material 1 on which an insulating layer 2 , two adjacent conductor tracks 3 , another layer of insulation 5 , a full-surface conductor 6 and a covering insulating layer 4 are applied in successive process steps.

In 3 is a plan view of a surface heating element according to the invention, the through the insulating layer 4 hidden conductor tracks 3 are indicated with broken lines. Contact surfaces are used for the electrical connection 7 when applying the insulating layer 4 released.

4 shows the surface heating element 3 in an oblique view, with on the contact surfaces 7 power connectors 8th are recognizable.

Claims (15)

Surface heating element as a resistance heater with a multilayer structure, which converts supplied electrical energy into thermal energy and releases it to the carrier material of the surface heating element and wherein the carrier material has a flat, curved or a multi-dimensionally shaped surface, characterized in that the heat-generating electrical conductor is to be heated Carrier material is applied by means of a screen printing process, an insulating layer based on plastic is applied over the electrical conductor by means of a screen printing process or by spraying or by rolling, and the insulating layer is dried and cured at temperatures of up to 300 ° C. panel heating according to claim 1, characterized in that the carrier material made of an electrically insulating material, such as plastic, Consists of metal oxide, metal nitrite or an electrically conductive carrier, on which in an earlier manufacturing step an electric insulating coating, for example made of enamel or glass. panel heating according to claim 1, characterized in that the carrier material itself made of an electrically conductive material, such as aluminum, copper or steel and that between the carrier material and the heat-generating electrical conductor on an insulating layer based on plastic the carrier material is applied, which is dried at temperatures of maximum 300 ° C. and cured has been. Surface heating element according to one of claims 1 to 3, characterized in that the heat-generating electrical conductor is a conductive pas te is made of a carbon conductive varnish which has a solids content of more than 60% and contains not only coal dust but also graphite with a grain size of preferably 5 to 7 μm. panel heating according to one of the claims 1 to 4, characterized in that the insulating layer of solder resist or from electrical insulation lacquer or from impregnation lacquer for electrical and / or electronic Components exist. panel heating according to one of the claims 1 to 5, characterized in that the heat-generating electrical conductor entire area formed or formed as a conductor track structure of any geometry becomes. panel heating according to one of the claims 1 to 6, characterized in that several layers on the carrier material calorific electrical conductors are applied, which by insulating layers are separated from each other, in the manufacturing process after each Apply an insulating layer a drying step at temperatures of maximum 300 ° C followed. panel heating according to one of the claims 1 to 7, characterized in that the carbon conductive paint has a specific Surface resistance of 1 to 1000 ohms / unit area having. panel heating according to one of the claims 1 to 8, characterized in that the electrically conductive paste is applied by screen printing and has a thickness of about 10 up to 50 μm having. panel heating according to one of the claims 1 to 9, characterized in that the insulating layer in the screen printing process or by spraying or rolling is applied and a thickness of about 20 to 200 microns accordingly the required test voltage Has. panel heating according to one of the claims 1 to 10, characterized in that additional electrically conductive Layers with corresponding insulation layers are applied, the one with grounding or a screen in order to comply with the required Safety regulations, improving equipotential bonding or related to influencing electromagnetic behavior are. panel heating according to one of the claims 1 to 11, characterized in that for the electrical connection the intended contact points are kept clear when applying the insulating layer. panel heating according to one of the claims 1 to 12, characterized in that the electrical connection by sticking on flags or other suitable metal electrodes with an electrically conductive adhesive or in a known manner solder on or weld on is made of flags or strands. panel heating according to one of the claims 1 to 12, characterized in that the electrical connection through specially designed surface pressure contacts is produced with an electrically well-conductive surface. Surface heating element according to one of claims 1 to 14, characterized in that the maximum specific surface load is 30 W / cm ² .