DE9004145U1 - Electrically heated alarm glass pane - Google Patents

Description

Electrically heated alarm glass

The invention relates to a glass pane provided with a transparent, electrically conductive surface coating.

It is known to use heating panes with an electrically conductive transparent surface , the electrically conductive layer serving as a heating intermediate layer. Since the surface resistance of the transparent conductive layers is inevitably relatively high, a relatively high electrical voltage is required for effective heating.

It is also known to use glass panes provided with a transparent, electrically conductive surface layer as alarm glass panes by connecting the surface layer as a signal transmitter to an electrical alarm circuit (DE 37 16 766 AD). In this known alarm glass pane, the surface coating forms the signal transmitter in its entire extent, and the contact with the conductive layer is made at two diagonally opposite corners of the glass pane. In this case, the glass pane provided with the conductive surface layer consists of tempered glass and is connected to a second glass pane to form a laminate.

The invention is based on the object of providing a glass pane provided with an electrically conductive surface coating, which simultaneously

Function of a heating pane as well as the function of an alarm glass pane.

According to the invention, this object is achieved in that the glass pane provided with the surface coating consists of tempered glass, that by subsequently removing the surface coating along an inner line in an edge or corner area, a small partial area is electrically separated from the remaining large partial area, that the large partial area serves as a heating resistor and is provided with connection electrodes and connection lines for connection to a heating voltage and the small partial area serves as a break detector and has connection electrodes and connection lines for connection to an electrical alarm circuit.

The combination of the above-mentioned features means that the glass pane can be used simultaneously as a heating pane and as an alarm pane without affecting either of these two functions. Because a tempered glass pane is used as the glass pane, ^which , as is well known, breaks into small pieces when broken, it is sufficient if only a very small part of the surface layer is used as a break detector, which can be arranged anywhere in the edge area. For example, a narrow strip a few centimeters long is sufficient for this function. The total area of the surface layer is thus only reduced by a negligible amount, so that the heating function extends over the entire surface layer with the exception of this small area serving as a break detector.

At the same time, the ^complete separation of the layer serving as heating resistance from the layer serving as signal generator avoids controls of the alarm function which could otherwise be caused by resistance changes in this layer as a result of strong heating or by the heating voltage itself. In this way it is possible to produce glass panes which fulfil both of the above-mentioned functions at the same time with minimal effort.

An embodiment of the invention is described in more detail below with reference to the single drawing.

The embodiment shown in the drawing is a laminated glass pane made of a thermally tempered float glass pane 1, a non-tempered float glass pane 2 and a thermoplastic intermediate layer 3 made of polyvinyl butyral.

The tempered float glass pane 1 is provided with an electrically conductive transparent surface coating on the surface adjacent to the thermoplastic intermediate layer 3. Transparent surface coatings with sufficient electrical conductivity are known. They can consist of tin oxide, for example, and be formed by pyrolysis of suitable tin compounds. Multiple layers applied using the method of magnetic field-assisted cathode sputtering or magnetic field-assisted reactive cathode sputtering, whose electrically conductive layer consists of silver, have proven to be particularly suitable as electrically conductive transparent layers. Underneath the silver layer and above the silver layer, further layers, in particular metal oxide layers, are generally used as adhesives.

and/or protective layers and/or as

Anti-reflective coatings applied. Transparent Surface layers of this type have a Surface resistance from 2 to 12 ohms per square unit and

can, depending on the thickness of the silver layer and the

Surface dimensions of the layer, with electrical Voltages from 40 to 220 volts serve as heating resistors.

In the example shown, the surface coating is interrupted by a dividing line 5 using a suitable laser, which runs at a distance of about 1 to 5 cm from the upper edge 6 of the glass pane 1. The process of structuring surface layers using a laser beam is known as such. The dividing line 5 can be so narrow that it is difficult to see with the naked eye. The only important thing is that the surface layer is completely galvanically separated. The dividing line divides the surface layer into a large partial area 8 and a narrow partial area 9 running parallel to the edge 6. The large partial area 8 is used to heat the laminated glass pane, and the strip-shaped partial area 9 serves as a signal generator.

To contact the surface coating, soldering connection surfaces 10 made of a suitable stoving paint are provided on the two end sections of the strip-shaped partial surface 9. Metal strips or metallic flat strands 11 are attached to the soldering connection surfaces 10 by soldering and lead out of the side of the laminated glass pane. These metal strips or connection strands

serve as connection cables to the electrical evaluation circuit of the alarm system.

The large partial surface 8 is also contacted in a suitable manner. In the case shown, the contact is made by conductive silver strips 13 made of a baked-on paint containing metallic silver, onto which

Meta I Ifolienbaender 14 for example with an electric ?

conductive adhesive or a low-melting solder

L
The Meta I I foil tapes 14, where

!These can also be thin metallic flat strands are led out of the side of the laminated glass pane and are used to connect to the supply lines that supply the heating current.

In the described embodiment, the partial area of the surface coating that serves as a break detector is designed in the form of a straight strip along one edge of the tempered glass pane. However, it is of course also possible to design the partial area that serves as a break detector in any shape, for example in the form of a loop, and to arrange this loop in a corner area of the glass pane. Furthermore, it is also possible to structure the partial area that serves for electrical heating in any way using a laser in order to adapt the surface resistance of the conductive layer to the desired power on the one hand and to the available electrical voltage on the other.

If the electrically conductive surface layer is sufficiently weather-resistant, which is particularly the case with pyrolytically applied layers, the glass pane according to the invention can be designed as a monolithic glass pane. As a rule, however,

It is advisable to protect the surface coating with another pane of glass. While in the example described the pane of glass protecting the surface layer is connected to the pane of glass carrying the surface layer to form a laminated glass pane, this second pane of glass can instead be connected to the pane of glass carrying the surface layer via a spacer frame to form an insulating ^glass pane.

Claims (4)

Protection claims 1. Glass pane provided with a transparent electrically conductive surface coating, characterized in that the glass pane provided with the surface coating (1) consists of tempered glass, that a small partial area (9) is electrically separated from the remaining large partial area (8) by subsequent removal of the surface coating along a dividing line (5) in an edge or corner area, that the large partial area (8) serves as a heating resistor and is provided with connection electrodes (13) and connection lines (14) for connection to a heating voltage, and that the small partial area (9) serves as a break detector and has connection electrodes (10) and connection lines (11) for connection to an electrical alarm circuit. 2. Glass pane according to claim 1, characterized in that it is connected to another glass pane (2) via a thermoplastic intermediate layer (3) to form a laminated glass pane. 3. Glass pane according to claim 1, characterized in that it is connected to a second glass pane via a spacer frame and adhesive and sealing layers to form an insulating glass pane. 4. Glass pane according to one of claims 1 to 3, characterized in that the large partial area of the surface coating serving as a heating resistor is separated by dividing lines according to the desired heating power and and the available electrical voltage. Glass pane according to one of claims 1 to 4, characterized in that the small part of the surface coating serving as a sound detector has the shape of a loop.