DE4128735A1 - HEATABLE MIRROR - Google Patents

Description

The invention relates to a heatable Multilayer mirror assembly that has a mirror coating comprises, which is deposited on a first glass sheet, the due to its coated surface on a second glass sheet due to the intervening adhesive polymeric material is laminated.

Known heatable mirrors contain a heatable grid, that is over the main part of the surface of the mirror extends in which the circulation of the electrical Stroms heat generated by the Joule effect. These Heat is spread over the entire surface of the mirror distributed so that every point of the surface that touches can have a temperature that is not too hot, so that any risk of burns is avoided. Heatable Mirrors perform two different functions. In addition to their main function of reflection of rays of light in the same way as everyone other mirrors, they also give off heat. A conventional example is that of heated mirrors for Bathrooms that give off a little heat to the fitting to eliminate that located on the front of the mirror forms.

When using this mirror through an electrical power source very low voltage, e.g. B. 24 volts can be fed in practice not any risk to users and especially any risk of electric shock be avoided. However, it makes the feed very low voltage is required in residential buildings that Transform mains voltage, what the presence of expensive and bulky auxiliary equipment required. in addition, if the  heating current must be comparatively high, needs the Very low current supply the circulation of a electric current at high intensity, resulting in Electrical connection and connection problems adequate size of the collectors.

The energy supply of heated mirrors at the normal mains voltage, e.g. B. 220 volts, reduces Electrical supply voltage intensity, but required monitoring electrical safety for the User. This can cause problems if the heatable Mirror should give off enough heat to a room on one bring comfortable temperature and around in a damp Surroundings, e.g. B. to work in a bathroom.

Known heatable mirrors are not strict Safety standards satisfied, the constant use of electricity in a humid environment.

It is an object of the invention to provide a heatable mirror to provide a high level of protection against electrical shocks.

This task is characterized by the characteristics of the Claim 1 solved.

The subclaims further develop the invention.

According to the invention is a heatable Multi-layer mirror assembly provided that comprises a mirror coating on a first Glass sheet is deposited by its coated Surface on a second glass sheet by intervening adhesive polymeric material laminated  which is characterized in that this second Glass sheet is laminated to the first sheet by a surface the at least one electrically conductive coating layer carries, where there are current collectors provided with this or these conductive layer (s) are connected and each connected to a conductive lead to a heating circuit for connection to an electrical Form power supply, at least one of these feeders (hereinafter referred to as "first feeders" from their contact region with their respective Collector to the immediate neighborhood of one end of the other this feeder in a common Connection zone that runs along the edge of the array is arranged along a path which is within the polymeric material lies and is surrounded by it, and wherein the polymeric material and the heating circuit by electrical insulating material are surrounded.

The heatable mirror of the invention facilitates this electrical connection to the voltage network under good safe conditions, provided that the two Lead wires are connected in the same zone can, since the connecting ends of the two leads in the immediate vicinity of each other, what the Connection via a single power cable with double electrical insulation facilitated. The electrical Switching arrangement is inside the laminated disc isolated. Furthermore, the presence of an electric carries insulating material that the polymer material section covers and extends along the outside of the laminate extends to provide an auxiliary insulation. It is thus possible to form an electrical heating circuit that has a heating surface that is as large as possible under Terms of the surface of the laminate and the one double  has electrical insulation. Furthermore, since the senior Layer and the electrical circuit arrangement separated from the connecting ends of the two leads Sandwich way within the multilayer arrangement are arranged, which is formed by the two layers, which is connected by the polymeric material can electrical safety can be obtained even if the Paths are broken as the pieces are polymerized Material can be kept in place.

The term "double insulation" is used in the present description used the presence of an independent auxiliary insulation, in addition to the Operational or primary isolation to indicate ongoing protection against electrical shocks in the To ensure in case of loss of operational insulation. The operational or main isolation is that required insulation to ensure the correct functioning of the To ensure device and to provide users with a basic protection against electrical shocks equip.

It is surprising that it is possible to use a laminated one Arrangement using conventional techniques the heating circuit and the electrical voltage circuit, the sealed within the laminate, while a multi-layer mirror is provided will, the optical and mechanical properties with high Level.

It is also surprising that one Multilayer arrangement is not obtained during the Operational and accelerated aging tests delaminated even if it contains elements made from materials with different  thermal expansion coefficients are shaped and one Heating surface that is as large as possible.

The arrangement of the conduction path within the polymer Material and that is surrounded by it, makes it easier electrical insulation, especially reflective Coating of the mirror, which is also electrically conductive is. This arrangement of the Feed path the lamination of the webs to form the Mirror.

The one designed for electrical connection Connection zone can e.g. B. in the center of one of the sides of the mirror if it has a polygonal appearance having. The mirror can also be circular, with in this case the connection zone at a point of the Circumference sits. However, the mirror is preferred rectangular, with the collectors along two extend opposite sides of the rectangle and the Connection zone sits in a corner of the mirror. Means of a simple electrical circuit only the first Pass the feed line through the polymeric material and must travel a comparatively long way within the Laminates follow so as to keep the electrical current between the corresponding collector and connection zone transfer because one end of the other collector is directly in stops near the corner so that its corresponding Line can be very short.

In this embodiment, the corner becomes one of the glass sheets preferably cut at the location of the connection zone, to allow the passage of the power wires, and the connection of these wires to the leads is in an insulation material included. The electrical Connection is thus facilitated and a double  electrical insulation of the connection ends can be easier with an acceptable appearance. A piece of the glass that covers the insulation material can e.g. B. bound by glue to double to complete electrical insulation.

At least the first line preferably contains one flat metal strip, which is advantageously a strip is made of Cu, which is the passage of a current with high electrical energy allowed without being so thick or strong to interfere with the connection of the glass sheets. The collectors can by means of a conductive paint, e.g. B. a silver varnish, the screen printing process is separated, shaped, and by the Copper strips formed in electrical lines Be brought into contact with this conductive lacquer. A Slit can be provided in the film of the polymeric material be so that the copper strip in front of the Lamination process can be performed through it.

The conductive layer can be uniform across the entire Surface of a glass sheet to be deposited and to the to facilitate electrical insulation of the laminate sections, can an incision or a recess along the entire periphery of the conductive layer, e.g. B. 5 mm from the edge of be provided so as to the edge portion of the Insulate the rest of the layer electrically. However, it will preferred that the surface of the web that the conductive Bears layer, an edge zone of more than 5 mm without has conductive material that is substantially along their entire outer surface extends. A very good one electrical insulation of the laminate section is therefore reached faster and maintained over time especially in a humid environment. An outskirts of  up to z. B. 2 cm, which has no material, the Electricity conducts, preferably all over the place Periphery of the web are left behind. At this end the conductive layer can be uniform over the entire Surface of the web can be deposited and then the Edge section are removed, e.g. B. by means of a Grinding wheel. A mask can then be placed on the edge section the web before deposition on the layer, e.g. B. by Atomization. This mask protects the Layer before molding on the glass in a place where it is placed: B. by means of an adhesive tape or color formed during exposure to heat peels off.

However, it is preferred that the conductive layer be essentially within 2 cm of the edge of the mirror extends along its entire periphery. This is especially so in the case of heatable mirrors fairly high heat emission as this helps to avoid the edges of the mirror from thermal Shock subjected to high temperature gradients is due.

The conductive layer may e.g. B. from one layer doped tin oxide are formed. The doped tin oxide can form a very solid heating layer on a glass sheet, which very quickly by pyrolysis in a known manner and Way is obtained. This layer is very resistant towards handling and therefore opposite Lamination process. However, pyrolytic Coating reactions under certain circumstances opposite effect on the flatness of the coated Orbits and this in turn could be optical Affect the properties of the mirror. Such a  conductive layer could alternatively by means of a metal, that by chemical or electrochemical methods has been deposited. However it is preferred that the conductive layer by means of cathodic Sputtering of a metal can be shaped. Such a Layer can e.g. B. molded from gold, silver or copper will. Such a technique allows the flatness the web is preserved after coating. Such a Technology also allows the formation of highly adhesive Coatings and these coatings can easily be found in the Thickness can be regulated so that the resistance of the Coating is easily checked. To achieve the best corrosion resistance, it becomes special preferred to use a gold plating that is up to 30 nm can be thick. Indeed, the thickness is about 15 nm very effective. Such a gold coating can be a or several other coatings for transferring special optical or other properties if this is desired to be connected, e.g. B. can such Gold coating between two layers of bismuth oxide in Be sandwiched.

If such a coating on a chemical tempered glass sheet is deposited as preferred then this web can be made thinner while a given mechanical strength is maintained, and this is beneficial in obtaining one Mirror arrangement that has a lighter weight.

The reflective coating is preferably on a first glass sheet deposited and by means of a silver and / or copper-based layer molded electrically is isolated from the conductive layer by a other layer using a heat resistant protective  Color and the polymeric material is worn. The heat-resistant paint improves the Resistance of the heatable mirror to Aging while protecting the reflective Coating despite the high temperature of the laminated Arrangement is ensured. The color and the Polymer material arrangement thus represent an adequate Isolation of the electrical heating circuit.

The two glass sheets are advantageously one treatment subjected to reinforcement of their mechanical strength been. This can e.g. B. be a heat curing treatment. These tracks very quickly withstand thermal shock, by spraying cold water drops on her Surface, when hot, causes what continue to ensure electrical safety by that the laminate remains intact is improved. However is the glass sheet that carries the reflective coating, a glass sheet that undergoes a chemical hardening treatment has undergone. The glass sheet that is the reflective Coating is the front window of the mirror, though it is installed as the main function of a mirror the reflection of light is to create a reflected image, e.g. B. to represent a face. A chemical hardening gives the glass sheet has a very high impact resistance, which it gives her enables any mechanical and thermal shocks or Resist vibrations. Furthermore, a chemical hardening can be carried out on a thin sheet which facilitates the construction of a lighter mirror, and it’s much less likely to get one opposite effect on the flatness of a glass sheet as has a thermal hardening or tempering treatment.

The glass sheet that carries the reflective coating has  preferably a thickness of less than 3 mm, e.g. B. 2 mm. This small thickness limits the thermal insulation through the front glass sheet is delivered.

The glass sheet that carries the conductive layer is preferably a chemically hardened or tempered Glass track. The hardening treatment has no opposite Effect on the flatness of the glass sheet and therefore no effect on the flatness of the laminate.

The mirror according to the invention preferably contains on it outer surface, on the side that is not the light in reflected in a mirror image, a layer with low emissivity. Because the back of the mirror has low emissivity, heat loss, which are due to radiation to the wall on which the mirror is secured, can be reduced. Alternatively or In addition, the mirror can be coated on the back be made of thermal insulation material. When a Foam material used should preferably be one closed cell foam can be used to make the Resist moisture ingress. Extruded Polyethylene foam with a thickness of about 1 cm is suitable.

The mirror section or the mirror section is preferably at least partially with electrical insulating and wet protection material covered to prevent moisture between layers penetrates. This seal improves the Resistance of electrical insulation between the conductive layer and the laminate section during time under moist conditions of use. A seal on Silicone base can advantageously be used.  

In a first embodiment, the invention Mirror through a metal frame, e.g. B. made of aluminum or Plastic, e.g. B. PVC, be surrounded. The presence of electrically insulating material along the outer surface of the Laminates ensure the double insulation that the use of a metal frame allowed, although special attention must be directed to a double, electrical Isolation of the connection zone with respect to the frame maintain. The space between the frame and the Laminate section can be used to make the Resistance to penetration by Moisture, as explained above Installation of a moisture-proof seal on this Job to improve.

In a second embodiment, the web is the reflective coating wears larger than another associated web, creating an edge around the entire Outer surface of the mirror is left behind. In this Embodiment, the mirror has no frame and can in consequently, much more economically. The edge can be characterized by a stiff self-adhesive foam Plastic material, e.g. B. polyurethane foam, and the space between this border and that Laminate section that with the seal made of electrical insulating material is filled, preferably with a water-repellent material, e.g. B. silicone filled be.

The heating power of the mirror of the invention is preferably greater than 500 W / m ² and preferably greater than 700 W / m ² . The heating power makes it possible to use the mirror according to the invention for heating or alternatively heating a small room such as a bathroom. A power of 800 W / m ² advantageously secures this heater without the risk of forming a dangerously high surface temperature in the front of the mirror. Adapting the resistivity of the conductive layer to obtain the specific force desired can be done quickly by adjusting the thickness of this layer to a layer of a given composition, depending on the dimensions of the mirror. The specific conductivity can be modified just as quickly by modifying the doping when the layer is formed by a semiconductor such as tin oxide. A third possibility is to model the conductive layer in order to limit the width and to increase the length of the heating current path. By combining these three setting options, it is possible to vary the overall resistance of the heating element.

The collectors can be sputtered with Cu either directly onto the glass before depositing the layer or after the layer has been deposited. At least one of the collectors is advantageous formed by two upstream paint strips that the Conduct electricity, between which an edge of the conductive layer is arranged in a sandwich manner. These Arrangement makes it possible to have a high electrical line get that is maintained over time regardless of the circulation of a comparatively intense Current. Furthermore, the conductive paint can quickly get under Applied using predetermined screen printing techniques will.

The invention is now, exclusively, for example, under Described with reference to the accompanying drawings.  

Show it:

Figure 1 is a partial plan view of the back of an embodiment of the heatable mirror of the invention.

Figures 2 and 3 partial cross sections through the heatable mirror of Figure 1 along the line AA 'and BB' of Fig. 1.

Fig. 4 is a perspective view of a corner of the mirror of Figure 1 before it is framed and prior to the deposition of insulation material on the intermediate polymer material portion.

Fig. 5 is a partial cross section through a further embodiment of the invention.

The heated mirror which is shown in Figs. 1 to 4, includes a multilayer or composite assembly 1 is formed by a glass sheet 2 carrying an opaque metal coating 3 reflects light in mirror image form, on the one by lamination to Glass sheet 4 is connected to the insertion of polymer material which is formed by two films 5 and 6. It should be noted that the drawings are not to scale. It must also be noted that the two films 5 and 6 of interposed polymeric material are shown separately for clarity, whereas in practice in the finished laminate these films are sealed into a single layer of interposed polymeric material. The glass layer 4 carries a conductive layer 7 which extends between two collectors 8 and 9 . The collector 9 is formed by a strip of conductive lacquer 10 , which is deposited on the edge of the conductive layer 7 . In the embodiment shown, the first conductive feed or feed line is formed by a Cu strip, one end 11 of which extends over the entire length of the collector 8 and is kept there in electrical contact in order to increase the electrical conductivity of the collector and which extends in the form of the strip 12 to the connection zone 13 .

In this embodiment, the connection zone 13 is arranged in a corner of the mirror. The strip 12 on the first lead passes through the web 6 of polymer material at the location shown at 14 in FIG. 1 and follows a path that lies between films 5 and 6 of polymer material as shown in FIG Figure shown. 3, that is disposed within the laminate to the individual connection zone 13. The electrical connection of the collector 8 is thus provided via the strip 12 of the first feed in the same zone of the connection 13 as the electrical connection of the collector 9 .

The collector 9 is also formed by a strip of lacquer on which a strip of Cu, which extends over the entire length of the collector, has been brought into electrical contact in order to increase the electrical conductivity of the collector. This Cu strip extends in the form of the feed line 30 to the connection zone 13 . The electrical cable 15 with double insulation, which contains two conductor wires, is connected to the strip 12 of the first feed and the second feed 30 in this connection zone 13 .

Fig. 4 shows that the location of the connection zone 13 , the glass sheet 4 has a corner cut to allow electrical connection. The Cu strip brought into contact with the collector 9 extends outside the collector 9 over the cut in the corner of the web 4 in the form of the feed 30 to allow an electrical connection in the connection zone 13 . After connection, the recess is filled with an insulating material 16 such as "ARALDITE" (trademark) that also secures the ends of the Cu strip.

In order to achieve double electrical insulation, a thin glass sheet 17 with a thickness of 4 mm can be glued above this zone 13 .

In the embodiment of FIGS. 1 to 3, the composite or the laminate 1 by a frame 18 , for. B. surrounded by aluminum or PVC, and the space between the portion 19 of the laminate 1 and the frame 18 is covered with an electrically insulating and water-repellent adhesive material 20 , for. B. silicone filled. For the sake of clarity in the drawing, this insulation material is not shown in FIG. 4. The connections 21 that allow the mirror to be attached to the wall are shown in dashed lines in FIG. 1.

In a specific example, web 2 is a 2 mm thick glass web that has been subjected to a thermal curing treatment. The reflective coating 3 is formed by silvering in a known manner and contains a layer of silver, a layer of copper and a layer of protective paint. In this specific example of the invention, the protective paint is a heat resistant, heat setting paint sold under the trademark "TRIGANITE" and marketed by "Pearl Paint". The polymeric material is formed by films 5 and 6 , made of PVB, which have a thickness of 0.38 mm. The web 4 is a glass web with a thickness of 4 mm. The conductive layer 7 is a doped tin oxide layer with a thickness of approximately 70 nm, which is obtained by pyrolysis. The conductive lacquer 10 is a cold-hardening lacquer based on silver. In order to improve the electrical conductivity of the collectors, a strip 31 of oven-baked silver-based lacquer (shown in dashed lines in FIG. 2) can be deposited before the SnO ₂ layer is deposited. At the location of the collectors, the SnO ₂ layer is thus sandwiched between the two strips 10 and 31 made of conductive lacquer. In this case, e.g. B. two strips of conductive varnish are deposited by means of screen printing on the glass sheet 4 at the location of the collectors, and this glass sheet is heated in an oven. The conductive paint is burned in. The SnO ₂ layer is deposited and the glass sheet is rapidly cooled by cold air flowing through the furnace to give a heat-tempered glass.

The strips of cold-curing conductive lacquer are then deposited, and the Cu strip is in front of the Lamination process attached.

In this specific example, the laminate 1 is a rectangle of 1183 mm × 683 mm, the specific electrical resistance of the heating layer is 143 ohms per glass plate and its total resistance is 82 ohms. The specific heating power of the layer is 800 W / m and the energy loss through the laminate 1 is 600 W. The temperature of the front does not exceed 60 ^° C. In order to avoid that this temperature is accidentally exceeded, a temperature limiting device (not shown) can be provided be. This can be carried out in a small plastic housing of 50 × 50 × 15 mm with double electrical insulation, which contains a bimetallic strip that connects the electrical circuit, e.g. B. at 60 ^o C, and z. B. at 40 ^o C. This housing is glued to the outer surface of the glass sheet 4 in the vicinity of the connection zone 13 . The cord 15 is connected to this housing and this housing is connected to the mains power supply.

The glazing of this embodiment has successfully Safety tests for electrical heating systems that are in humid atmospheres work and especially the Insulation resistance and dielectric resistance tests happens at a voltage of 3750 V.

In a modification of this example, the glass sheet 4 is a sheet made of chemically toughened glass and has a thickness of 2 mm. The conductive layer 7 contains three intermediate layers: a base coating layer of bismuth oxide, which is 3 mm thick, a gold coating, and an intermediate coating layer of bismuth oxide, which has a thickness of 15 mm, and which covers the gold. The thickness of the gold layer is such that it gives a specific electrical resistance of approximately 12 ohms per glass plate, approximately 16 nm. Such a gold coating is deposited on a web measuring 1183 mm x 683 mm in two spatially separated strips, each having an effective area between the collectors of approximately 1150 mm x 330 mm. The strips are connected at one side edge edge of the glass sheet by a common collector and they are fed with heating current through two separate collectors, each running along about half of the opposite side edge of the sheet. The resulting radiator in turn has a total resistance of approximately 82 ohms. The collectors 8 , 9 in this case are composed of Cu strips glued to the conductive layers using a conductive adhesive and they extend as leads through the polymeric material to a common connection zone.

As a further departure from the specific example described above, the collectors 8 and 9 are formed by Cu strips obtained by flame spraying Cu. In this example, both the conductive silver-based varnish and the end 11 of the first feed are omitted. The latter is formed by the strip 12 , which is a copper strip soldered to the end of the collector 8 .

In the embodiment of Fig. 5, the heatable mirror has no frame. The reflective coating 21 is deposited on a chemically hardened glass sheet 22 . The conductive layer 23 is carried by the thermoset glass sheet 24 . The two glass sheets 22 and 24 are connected by lamination using a polymeric material in the form of two films 25 and 26 . The glass sheet 24 is narrower than the sheet 22 , so that an edge 27 is left behind. The edge 27 is bordered by a strip of self-adhesive polyurethane foam 28 and the space between the strip 28 and the portion of the web 24 is covered with an electrically insulating and water-repellent adhesive material 29 , e.g. B. silicone filled.

This embodiment successfully has the electrical Isolation tests for humid environments happen. Your Structure is easier and it satisfies the demands regarding the appearance for mirrors without a frame.  

The embodiments shown in FIGS. 1 to 5 show a preferred solution in which the conductive layer 7 , 23 has a smaller area than that of the tracks 4 , 24 which they carry. The conductive layer section is thus insulated both by the intervening polymeric material and by the completely sealing material 20 , 29 .

Claims (18)

1. A heatable multilayer mirror composition comprising a mirror coating deposited on a first glass sheet laminated by its coated surface on a second glass sheet by interposed adhesive polymeric material, characterized in that said second glass sheet is bonded to the first glass sheet by a Surface is laminated which carries at least one electrically conductive coating layer, there being current collectors connected to this (these) conductive layer (s) and each being connected to a conductive lead to a heating circuit for connection to an electrical power source, at least one of these leads, or the first lead, from its contact region with its respective collector to the immediate vicinity of one end of the other lead in a common connection zone that runs along the path of the assembly is arranged, which lies within and is surrounded by the polymeric material, and wherein the polymeric material and the heating circuit are surrounded by electrically insulating material. 2. Heated mirror according to claim 1, wherein the mirror is rectangular and the collector is along two opposite sides of the rectangle extends and where the connection zone sits in a corner of the mirror. 3. Heated mirror according to claim 2, in which at the point the corner of one of the glass sheets in the connecting zone is cut off to the passage of  To allow power supply wires and being their Connection to the leads in an insulation material is embedded. 4. Heated mirror according to any previous Claim in which at least the first feed one contains flat metal strips. 5. Heated mirror according to claim 4, in which at least the first feeder contains a flat copper strip. 6. Heated mirror according to any previous Claim where the surface of the web that the conductive layer, an edge zone of more than 5 mm without conductive material, which is essentially extends along their entire periphery. 7. Heated mirror according to any previous Claim in which the conductive layer is within 2 cm the corner of the mirror essentially along its entire outer surface. 8. Heated mirror according to any previous Claim, wherein the conductive layer is a layer Is gold. 9. Heated mirror according to any previous Claim, in which the reflective coating on a first glass sheet is deposited and through one layer Silver and / or copper base which is electrically formed by the conductive layer is insulated by another Glass sheet through a heat-resistant protective color and that polymeric material is worn.   10. Heated mirror according to any previous Claim in which two glass sheets of treatment for Reinforcing their mechanical strength are. 11. Heated mirror according to claim 10, wherein the Glass sheet that carries the reflective coating, one Glass sheet is that of a chemical hardening treatment has undergone. 12. Heated mirror according to claim 11, wherein the Glass sheet that carries the reflective coating, one Thickness less than 3 mm. 13. Heated mirror according to any previous Claim where the glass sheet which is the conductive layer is a chemically hardened or tempered glass sheet. 14. Heated mirror according to any previous Claim where the mirror is on its outer surface on the side that is not the light in mirror image form reflected, a layer with low emissivity contains. 15. Heated mirror according to any previous Claim in which its subsection is at least partially thanks to electrical insulation and water-repellent Material is covered. 16. Heated mirror according to any previous Claim where the web that is the reflective Coating is larger than another web that is connected to it so that an edge spans the entire  Outer surface of the mirror is left behind. 17. A heatable mirror according to any preceding claim, in which its heating power is greater than 500 W / m and preferably greater than 700 W / m ² . 18. Heated mirror according to any preceding Claim in which at least one of the collectors by two upstream strips made of conductive lacquer between which is a corner of the conductive layer is arranged in a sandwich manner.