EP2671424A1

EP2671424A1 - Heating element comprising films

Info

Publication number: EP2671424A1
Application number: EP12706643.9A
Authority: EP
Inventors: Stephane Laurent; Bruno Mauvernay; David LUXEMBOURG
Original assignee: Saint Gobain Glass France SAS; Compagnie de Saint Gobain SA
Current assignee: Saint Gobain Glass France SAS; Compagnie de Saint Gobain SA
Priority date: 2011-02-04
Filing date: 2012-01-30
Publication date: 2013-12-11
Also published as: MX341630B; US10029651B2; EA201391128A1; JP2014509047A; EA031947B1; WO2012104530A1; KR20140036142A; FR2971387B1; CA2823538A1; MX2013008866A; FR2971387A1; CN103329616A; US20130299479A1; BR112013014948A2; CN110099466A

Abstract

The invention relates to a heating element comprising a substrate (1) equipped with a thin-film multilayer, the thin-film multilayer comprising a heating film (3) that has an electrical sheet resistance lying between 20 and 200 Omega/&square;, and two nonmetallic dielectric films (4, 5) located on either side of the heating film (3), the heating element also comprising two conductive collectors designed to receive a voltage, the heating film (3) being unpatterned, made of metal and electrically connected to the two conductive collectors. The invention allows a heating element comprising a heating film, which film is simple to manufacture, to be easily installed in an electric vehicle or to be easily connected to the mains.

Description

COATING HEATING ELEMENT

The invention relates to a heating element comprising a substrate provided with a stack of thin layers, the thin film stack comprising a layer suitable for heating.

It is known to use such heating elements as heating windshields of motor vehicles in order to demist and / or defrost the windshield. When the glazing is mounted on a vehicle and is connected to an electrical installation, the layer adapted to heat becomes heated.

The power dissipated P by a heated windshield is equal to the voltage U feeding the windshield, squared, divided by the electrical resistance R of the heating layer (P = U ² / R). The effective dissipated power to demist and / or de-ice a windscreen shall be greater than 500 W / m ² . In vehicles with combustion engines, the voltage on board is of the order of 12 or 42 volts. The heating layers used are silver. They have a surface electrical resistance of the order of 1 or 4 ohms per square respectively.

There is a need to equip electric vehicles with heated glass. However, the voltage in an electric vehicle is much higher than on board a combustion engine vehicle: it is of the order of 100 volts or more, and can even go up to several hundred volts. Thus, if one tried to install a heated vehicle windshield combustion engine in an electric vehicle, the power dissipated by the windshield would be very high. However, conventional electrical installations, such as those present in vehicles with combustion engines, would not withstand the very high dissipated electric powers that could be generated by such a heated windshield installed on an electric vehicle. Specific electrical installations would, however, be very costly and complex to implement.

In addition, it is also known to use heating elements with a silver heating layer as an electric building radiator. The same problem of high electrical voltage arises since the voltage available in buildings is that of the national electricity grid, namely 220 or 230 volts in Europe or 120 volts in the United States, much higher than 12 or 42 volts. To reduce the dissipated power (to prevent the radiator from overheating), the electric resistance of the heating layer is increased by etching the heating layer so that the electrons travel a longer path. This process is however complex and expensive.

There is therefore a need for a heating element comprising a substrate provided with a stack of thin layers, the thin film stack comprising a layer suitable for heating, which can be easily installed on an electric vehicle or connected to the national power grid. and that is simple to manufacture.

For this, the invention proposes a heating element comprising a substrate provided with a stack of thin layers, the thin film stack comprising a layer adapted to heat, having an overcurrent electrical resistance of between 20 and 200 Ω per square. , and two non-metallic dielectric layers located on either side of the layer adapted to heat, the heating element also comprising two collector conductors adapted to be supplied with electrical voltage, the layer adapted to heat being not machined and being electrically connected to the two collector conductors.

According to another feature, the layer adapted to heat is metal, said metal belonging to the group comprising niobium, molybdenum, nickel, chromium, tin, zinc, tantalum, hafnium, titanium, tungsten , aluminum, copper and their alloys.

According to another feature, the non-metallic dielectric layers are, for example, Si ₃ N ₄ , SnZnO, SnO ₂ or ZnO.

According to another feature, the stack comprises at least one blocking layer located between the layer adapted to heat and at least one of the non-metallic dielectric layers.

According to another feature, the layer adapted to heat has a thickness of between 2 and 30 nm.

According to another feature, the layer adapted to heat has a thickness of between 2 and 8 nm so that the light transmission of the heating element is at least 70%, preferably at least 75%.

In another feature, the collector conductors are disposed near two opposite edges of the heating element. According to another feature, the substrate provided with a stack of thin layers is organic or inorganic glass.

According to another feature, the substrate provided with a stack of thin layers is transparent.

According to another feature, the heating element further comprises a spacer and a second substrate, the spacer being between the two substrates to form a laminate, the layer adapted to heat being opposite the spacer.

In another feature, the heating element further comprises a third substrate separated from the laminate by a gas blade.

According to another feature, the heating element further comprises at least one second substrate, the substrates being separated two by two by a gas strip to form a multiple insulating glazing unit, the layer adapted to be heated being opposite the the gas blade.

According to another particularity, the second substrate is made of organic or inorganic glass.

According to another feature, the second substrate is transparent.

The invention also relates to a building glazing comprising a heating element as described above.

The invention also relates to an electric motor vehicle glazing unit comprising a heating element as described above.

The invention also relates to an electric motor vehicle comprising a glazing as described above, including a windshield, a front side glazing, a rear side glazing, a rear window or a roof glazing.

The invention also relates to an electric building radiator consisting of a heating element as described above.

Other features and advantages of the invention will now be described with reference to the drawings in which:

• Figure 1 shows a cross sectional view of a heating element according to one embodiment of the invention.

The invention relates to a heating element comprising at least one substrate provided with a stack of thin layers, the stack of thin layers these comprising a layer adapted to heat. The layer suitable for heating has a surface electrical resistance of between 20 and 200 Ω per square. The layer adapted to heat demisting / defrosting a glazing or heating and a room. The stack also comprises two non-metallic dielectric layers located on either side of the layer adapted to heat. These non-metallic dielectric layers have an anti-reflective function. The heating element also comprises two collector conductors adapted to be supplied with electrical voltage, the layer adapted to heat being electrically connected to the two collector conductors so as to be able to heat. The layer adapted to heat is full, that is to say that it is not machined by etching. Thus, no zone is removed from the layer and no geometric path for increasing the effective resistance of the glazing is etched in the layer adapted to heat.

Thus, the surface electrical resistance of the layer adapted to heat is between 20 and 200 Ω per square without the need to machine it by engraving. This simplifies the manufacturing process of the heating element. In addition, it allows a dissipated power that is controlled and is compatible with conventional electrical installations. The invention therefore makes it easy to install on an electric vehicle or to easily connect to the national power grid a heating element according to the invention.

Figure 1 shows a cross-sectional view of a heating element according to one embodiment of the invention.

The heating element comprises a substrate 1 on which is deposited a stack of thin layers comprising a layer 3 adapted to heat. The thin layers of the stack are deposited for example by cathode sputtering, in particular assisted by magnetic field ("magnetron" deposit).

The substrate 1 is for example organic or inorganic glass. For example, it is transparent, especially when it is used in an application that needs to be viewed through, for example, a vehicle or building glazing. The substrate 1 is preferably, but not limited to, a glass sheet. The layer 3 suitable for heating is metal, for example niobium, molybdenum, nickel, chromium, tin, zinc, tantalum, hafnium, titanium, tungsten, aluminum or copper, or one of their alloys.

The stack of thin layers also comprises two non-metallic dielectric layers 4, 5. The layer 3 adapted to heat is between the two non-metallic dielectric layers 4, 5. These non-metallic dielectric layers 4, 5 for example Si ₃ N ₄ , SnZnO, SnO ₂ or ZnO. These layers 4, 5 have an antireflection function which improves the visibility through the heating element provided with the layer 3 adapted to heat, particularly when the substrate is glass. The non-metallic dielectric layers 4, 5 are deposited for example by cathode sputtering, in particular assisted by a magnetic field.

The thin film stack optionally comprises at least one blocking layer (not shown) located between the layer 3 adapted to heat and at least one of the non-metallic dielectric layers 4, 5. Thus, the blocking layer may be in the underlayer of the layer 3 adapted to heat, and therefore between the substrate and the layer 3 adapted to heat, and / or in overlay of the layer 3 adapted to heat. The blocking layer or layers are very thin. They protect, if necessary, the layer 3 adapted to heat a possible degradation during the deposition of the dielectric layer 5 dielectric layer overlay of the layer 3 adapted to heat. They also protect the layer 3 adapted to heat during a possible heat treatment at high temperature, of the bending and / or quenching type, for example to prevent the oxidation of said layer 3. The blocking layer or layers are, for example, NiCr, titanium or aluminum. The blocking layer or layers are deposited for example by sputtering, in particular assisted by magnetic field.

The thickness of the layer 3 adapted to heat is between 2 and 30 nm. This thickness range is both easily achievable technically and provides a layer of controlled thickness over the entire surface of the glass sheet. When the heating element is used in a glazing application with light transmission constraints of at least 70%, or even at least 75%, that is to say in particular for windshields and front side windows, the thickness of the layer 3 adapted to heat is between 2 and 8 nm. To obtain a light transmission of at least 75%, niobium and molybdenum are entirely suitable as a material for the layer 3 adapted to heat so that the layer 3 with a thickness of between 2 and 8 nm has a surface electrical resistance of the layer adapted to heat of between 20 and 200 Ω per square.

All materials in the group including niobium, molybdenum, nickel, chromium, tin, zinc, tantalum, hafnium, titanium, tungsten, aluminum, copper and their alloys are suitable as a material for the layer 3 adapted to heat so that the layer 3 with a thickness of between 2 and 30 nm has a surface electrical resistance of the layer adapted to heat of between 20 and 200 Ω per square when the heating element is not used in an application with a light transmission constraint.

The heating element also comprises two collector conductors (not shown) disposed near two opposite edges of the heating element. The layer 3 adapted to heat is electrically connected to these collector conductors. The collector conductors are voltage supply terminals of the layer 3 adapted to heat. In the case of a heated windshield, the collecting conductors are arranged for example at the top and bottom of the windshield.

In a first variant, the heating element preferably comprises a second substrate 2 and a spacer 6, the spacer being between the two substrates 1, 2 so as to form a laminate. In this configuration, the face of the substrate 1 on which is deposited the layer 3 adapted to heat and the non-metallic dielectric layers 4, 5 is preferably vis-à-vis the interlayer 6 and not facing outward of the heating element, so as to protect the stack of thin layers against external aggression. The interlayer is for example standard PVB (polyvinyl butyral) or material adapted to acoustically dampen waves. The material adapted to acoustically dampen waves is then preferably between two layers of standard PVB.

In this first variant, the second substrate 2 is for example organic or inorganic glass. For example, it is transparent, especially when used in an application that needs to be seen through example a vehicle or building glazing. The substrate 2 is preferably, but not limited to, a glass sheet.

A heating element according to this first variant can be used as glazing of a motor vehicle, in particular an electric vehicle. When the glazing is a windshield or a front side glazing, it is subject to visibility constraints. Indeed, the light transmission must be at least 70%, or even at least 75%, to comply with the standards in force. This light transmission is achieved with a heated glazing as defined above. However, when the glazing is a rear side glazing, a rear window or a roof glazing, it is not subject to any light transmission constraint.

A heating element according to this first variant can also be used as building glazing, for example in a partition between two rooms or in an outer building wall in combination with a third substrate separated from the heating element by a gas strip. The third substrate is for example organic or inorganic glass. The third substrate is, for example, transparent.

A heating element according to this first variant can also be used as an electric building radiator.

In a second variant, the heating element comprises at least a second substrate 2. The substrates 1, 2 are separated in pairs by a gas strip so as to form an insulating multiple glazing unit. The layer 3 adapted to heat is preferably vis-à-vis the gas plate and not directed towards the outside of the heating element, so as to protect the stack of thin layers against external aggression.

A heating element according to this second variant can be used as building glazing.

The invention therefore also relates to a glazing of an electric motor vehicle, in particular a windshield or a front side glazing which are subjected to light transmission constraints of at least 70%, or even at least 75%, or a rear side glazing, a rear window or a roof glazing, which are not subject to any light transmission constraint. The invention also relates to an electric motor vehicle with such a glazing. The invention also relates to a building glazing or an electric building radiator.

In the case of a vehicle or building glazing or an electrical building radiator, the collector conductors are connected in known manner to an electrical installation and are supplied with voltage via this electrical installation. When energized, the layer adapted to heat becomes a heating layer. Thanks to the invention, conventional electrical installations can be used.

In the case of a vehicle or building glazing, the layer adapted to heat has a purpose of defogging and / or defrosting of the glazing.

In the case of a radiator, the layer adapted for heating has essentially a home heating purpose but may also have a purpose of defogging, especially when used in a bathroom.

A heating element according to the invention having the following stack:

Glass / Si ₃ N ₄ / Nb / Si ₃ N ₄ / PVBA / wand

with, in order, the following thicknesses:

has a surface resistance of 150 ohms per square. In this example, the niobium layer is the layer adapted to heat and there is no blocking layer. A 75 cm high heating element, powered by a 220 V voltage, dissipates a pfd of 575 W / m ² and has a light transmission of 70%. Such a heating element can be used as windshield or side glazing before electric vehicle.

Similarly, a heating element according to the invention having the following stack:

Glass / Si ₃ N ₄ / Al / Cu / Al / Si ₃ N ₄ / PVBA / wand

with, in order, the following thicknesses:

has a surface resistance of 40 ohms per square. In this example, the copper layer is the heatable layer and the aluminum layers are the blocking layers. A heating element 75 cm high, powered by a voltage of 220 V then dissipates a pfd of 2150 W / m ² and has a light transmission of 70%. Such a heating element can be used as windshield or side glazing before electric vehicle.

Glass / Si ₃ N ₄ / Ti / Nb / Ti / Si ₃ N ₄ / PVBA / wand

with, in order, the following thicknesses:

has a surface resistance of 23 ohms per square. In this example, the niobium layer is the layer suitable for heating and the titanium layers are the blocking layers. A heating element 1 m high, powered by a voltage of 220 V then dissipates a pfd of 2100 W / m ² and has a light transmission of 27%. Such a heating element can be used as rear side glazing, roof glazing or electric vehicle rear window, or as building glazing or as an electric building radiator.

Glass / Si ₃ N ₄ / NiCr / Al / NiCr / Si ₃ N ₄ / PVBA / wand with, in order, the following thicknesses:

has a surface resistance of 80 ohms per square. In this example, the aluminum layer is the layer suitable for heating and the NiCr layers are the blocking layers. A heating element 1 m high, powered by a voltage of 220 V then dissipates a pfd of 605 W / m ² and has a light transmission of 50%. Such a heating element can be used as rear side glazing, roof glazing or electric vehicle rear window, or as building glazing or as an electric building radiator.

Claims

1. Heating element comprising a substrate (1) provided with a stack of thin layers, the thin film stack comprising a layer (3) adapted to heat, having a surface electrical resistance of between 20 and 200 Ω per square, and two layers (4, 5) dielectric non-metallic located on either side of the layer (3) adapted to heat, the heating element also comprising two collector conductors adapted to be supplied with voltage, the layer (3) adapted to heat being solid, metal and electrically connected to the two collector conductors.

2. A heating element according to claim 1, wherein the metal of the layer adapted to heat belongs to the group comprising niobium, molybdenum, nickel, chromium, tin, zinc, tantalum, hafnium, titanium. , tungsten, aluminum, copper and their alloys.

3. Heating element according to claim 1 or 2, wherein the non-metallic dielectric layers (4, 5) are, for example, Si ₃ N ₄ , SnZnO, SnO ₂ or ZnO.

4. heating element according to one of claims 1 to 3, wherein the stack comprises at least one blocking layer located between the layer (3) adapted to heat and at least one of dielectric layers (4, 5). non-metallic

5. Heating element according to one of claims 1 to 4, wherein the layer (3) adapted to heat has a thickness between 2 and 30 nm.

6. Heating element according to claim 5, wherein the layer (3) adapted to heat has a thickness of between 2 and 8 nm so that the light transmission of the heating element is at least 70%, preferably at least 75%.

7. Heating element according to one of claims 1 to 6, wherein the collector conductors are disposed near two opposite edges of the heating element.

8. Heating element according to one of claims 1 to 7, wherein the substrate (1) provided with a stack of thin layers is organic or inorganic glass.

9. heating element according to one of claims 1 to 8, wherein the substrate (1) provided with a stack of thin layers is transparent.

10. heating element according to one of claims 1 to 9, further comprising a spacer (6) and a second substrate (2), the spacer (6) being between the two substrates (1, 2) to form a laminated , the layer (3) adapted to heat being vis-à-vis the interlayer (6).

1 1. The heating element of claim 10, further comprising a third substrate separated from the laminate by a gas strip.

12. heating element according to one of claims 1 to 9, further comprising at least a second substrate (2), the substrates (1, 2) being separated in pairs by a gas strip to form an insulating multiple glazing, the layer (3) adapted to heat being vis-à-vis the gas blade.

13. Heating element according to one of claims 10 to 12, wherein the second substrate (2) is organic or inorganic glass.

14. Heating element according to one of claims 10 to 13, wherein the second substrate (2) is transparent.

15. Building glazing comprising a heating element according to any one of claims 1 to 14.

16. Glazing of an electric motor vehicle comprising a heating element according to any one of claims 1 to 10 and 13 or 14 when dependent on claim 10.

17. Electric motor vehicle comprising a glazing according to claim 16, including a windshield, a front side glazing, a rear side glazing, a rear window or a roof glazing.

18. Electric building radiator consisting of a heating element according to any one of claims 1 to 10 and 13 or 14 when dependent on claim 10.