WO2022229584A1

WO2022229584A1 - Glazed assembly comprising a condensation detector

Info

Publication number: WO2022229584A1
Application number: PCT/FR2022/050838
Authority: WO
Inventors: David Chauvin; Emmanuel Mimoun
Original assignee: Saint-Gobain Glass France
Priority date: 2021-04-30
Filing date: 2022-04-29
Publication date: 2022-11-03
Also published as: CN115552222A; FR3122495A1

Abstract

The present invention relates to a glazed element for a vehicle, comprising laminated glazing, the laminated glazing comprising a first glass sheet, a second glass sheet, the first glass sheet having a first face and a second face and having a first edge and a second edge, the second face being suitable for being in contact with an ambient interior environment of the vehicle and withstanding the nucleation of a condensation droplet, the glazed element comprising a light source and a photodetector, the light source and the photodetector being arranged such that a light beam propagates in the first glass sheet from the first edge to the second edge by a plurality of total internal reflections on the first face and on the second face in the first glass sheet.

Description

DESCRIPTION

TITLE: GLASS ASSEMBLY INCLUDING A MIST DETECTOR

FIELD OF THE INVENTION

The present invention relates to a glazed assembly for a vehicle, comprising a mist detector, and a method for detecting mist on a window of the vehicle by this detector.

STATE OF THE ART

When drops of mist appear on the inside face of a window of a vehicle, it is known to manually activate an ambient temperature and/or ventilation regulator in the vehicle, so as to control evaporation mist drops.

However, this method can distract the driver of the vehicle. In addition, this method is only possible when the fog drops have already appeared and have already degraded the driver's visual perception through the glazing.

To this end, document EP 3 552 004 describes a capacitive mist sensor comprising interdigital electrodes inserted in a glazing. When fog forms on the inside face of the glazing, the capacitance measured by the sensor varies. Thus, it is possible to dispense with visual detection of mist, and thus reduce the driver's loss of concentration.

However, the sensor described in document EP 3 552 004 does not make it possible to detect the smallest drops of mist. Thus, it is possible that the mist will be perceptible by the driver before it is detected by the capacitive sensor.

In addition, the capacitive detection of the mist can present a latency of the order of about ten seconds. For example, it is known that the mist sensor comprises a material capable of absorbing water from a drop of mist. In this case, the electrical capacity of this material is measured by the sensor and the sensor latency may depend on the water absorption kinetics of the material. This latency may be sufficient for the density of the mist to increase and consequently degrade the driver's visual perception. DISCLOSURE OF THE INVENTION

An object of the invention is to propose a solution for detecting fogging on the surface of a window of a vehicle automatically, and preferably before it is perceptible by the driver.

This object is achieved in the context of the present invention thanks to a glazed element for a vehicle, comprising laminated glazing extending along a main surface, the laminated glazing comprising a first sheet of glass, a second sheet of glass, and a interlayer arranged between the first sheet of glass and the second sheet of glass, the first sheet of glass having a first face and a second face parallel to the main surface, and having a first edge and a second edge opposite the first edge, the first face being on the side of the interlayer with respect to the first glass sheet, and the second face being opposite the first face with respect to the first glass sheet and being capable of being in contact with an ambient environment inside the vehicle and to support the nucleation of a drop of mist, the first sheet of glass being formed by a first glass having a first refractive index ni, the vi laminated covering comprising a material covering the first face on the side of the intermediate layer with respect to the first face and having a second index of reflection ni, - the second refractive index ni being strictly lower than the first refractive index ni,

- the glazed element comprising a light source adapted to emit a light beam, and a photodetector adapted to detect the light beam emitted by the light source, the light source and the photodetector being arranged so that the light beam propagates in the first glass sheet from the first edge to the second edge by several total internal reflections on the first face and on the second face in the first glass sheet. The present invention is advantageously supplemented by the following characteristics, taken individually or in any of their technically possible combinations:

- the material covering the first face forms, at least in part, the intermediate layer,

- the light beam has one or more wavelengths chosen from a range of wavelengths between 800 nm and 2500 nm, in particular between 850 nm and 1500 nm, and preferably between 850 nm and 1100 nm.

- the first glass has a first absorption coefficient ai of the light beam, the second sheet of glass is formed by a second glass, the second glass has a second absorption coefficient θ2 of the light beam, the first absorption coefficient ai being strictly less than the second absorption coefficient 02, the first absorption coefficient ai being preferably less than 0.5 cm ¹ , in particular less than 0.1 cm ¹ ,

- the glazed element comprises several light sources arranged along at least part of an edge chosen from among the first edge and the second edge,

- the glazed element comprises several photodetectors arranged along at least part of an edge chosen from among the first edge and the second edge,

- the light sources are arranged along at least part of the first edge and the photodetectors are arranged along at least part of the second edge,

- the glazed element comprises several light sources, at least one of the light sources being arranged on the first edge and at least one other of the light sources being arranged on the second edge,

- the glazed element comprises several photodetectors, at least one of the photodetectors being arranged on the first edge and at least one other of the photodetectors being arranged on the second edge,

- the light source(s) and the photodetector(s) are arranged only on the first edge, the glazed element comprising a mirror arranged on the second edge, - the glazed element comprises a light source extending along part of the first edge,

- the glazed element comprises a photodetector extending along part of the second edge,

- the light source is arranged so that the light beam propagates in the first sheet of glass, the direction of the light beam at a point defined by a reflection of the light beam on the first face forms an angle, with the first face, lower at 30°, preferably less than 15°,

- the glazed element comprises a control unit configured to control an emission of the light beam by the light source, to receive data representative of the light beam detected by the photodetector, to compare the data representative of the light beam detected with data representative of a reference light beam, and emitting a signal representative of the nucleation of a drop of mist from the comparison.

Another aspect of the invention is a method for detecting the nucleation of a drop of mist on a glazed element, comprising the steps of: a) supplying a glazed element according to one embodiment of the invention, b ) emission of a light beam by the light source, so that the light beam propagates in the first sheet of glass from the first edge to the second edge by several total internal reflections on the first face and on the second face in the first sheet of glass, c) detection of the light beam by the photodetector and emission of data representative of the detected light beam, d) comparison of the data representative of the detected light beam with data representative of a reference light beam, and detection of 'a drop of fog on the second side from the comparison.

Advantageously, the method comprises a step e), subsequent to step d), in which data representative of the nucleation of a drop of mist on the second face are transmitted to a temperature control system and/or vehicle ventilation. DESCRIPTION OF FIGURES

Other characteristics, objects and advantages of the invention will emerge from the description which follows, which is purely illustrative and not limiting, and which must be read in conjunction with the appended drawings in which:

[Fig. 1] - Figure 1 schematically illustrates a section of a glazed element according to one embodiment of the invention,

[Fig. 2] - Figure 2 schematically illustrates a glazed element according to one embodiment of the invention,

[Fig. 3] - Figure 3 schematically illustrates a glazed element according to one embodiment of the invention,

[Fig. 4] - Figure 4 schematically illustrates a method according to one embodiment of the invention,

[Fig. 5] - Figure 5 schematically illustrates a glazed element according to one embodiment of the invention.

In all the figures, similar elements bear identical references.

DEFINITIONS

“Glazing” means a structure comprising at least one sheet of organic or mineral glass, preferably adapted to be mounted in a vehicle. The term “laminated glazing” means a glazed assembly comprising at least two sheets of glass and an intermediate layer formed of plastic material, preferably viscoelastic, separating the two sheets of glass. The intermediate layer can comprise one or more layers of viscoelastic polymer, for example poly(vinyl butyral) (PVB) or an ethylene-vinyl acetate copolymer (EVA). The interlayer film is preferably standard PVB or acoustic PVB. Acoustic PVB can consist of three layers: two outer layers of standard PVB and one internal layer in PVB added with plasticizer so as to make the internal layer less rigid than the external layers.

It is understood that a refractive index is greater than another refractive index for a predetermined wavelength, preferably for the wavelength or wavelengths of the light beam emitted by the light source.

DETAILED DESCRIPTION OF THE INVENTION

General architecture of glazed element 1

Referring to Figure 1, a glazed element 1 for a vehicle comprises a laminated glazing 3. The laminated glazing 3 extends along a main surface 4. The laminated glazing 3 comprises a first sheet of glass 5, a second sheet of glass 6, and an interlayer 7 arranged between the first sheet of glass 5 and the second sheet of glass 6. The interlayer 7 can be formed from PVB, and preferably from acoustic PVB. The intermediate layer 7 may comprise a layer formed from a viscoelastic material, having acoustic insulation properties.

The first sheet of glass 5 has a first face F3 and a second face F4. The first face F3 and the second face F4 are parallel to the main surface 4. The first face F3 is on the side of the intermediate layer 7 with respect to the first sheet of glass 5. The second face F4 is opposite the first face F3 relative to the first sheet of glass 5. The second face F4 is an outer face of the laminated glazing 3, preferably configured to be inside the vehicle when the laminated glazing 3 is installed on the vehicle. The second face F4 is able to be in contact with an ambient environment 10 inside the vehicle 2 and to support the nucleation of a drop of mist 14.

The first sheet of glass 5 has a first edge 8 and a second edge 9 opposite the first edge 8. The first edge 8 and the second edge 9 may be side edges, which are capable of extending along a vertical component when the laminated glazing 3 is installed on the vehicle. The first sheet of glass 5 is formed by a first glass having a bare first refractive index The laminated glazing 3 comprises a material covering the first face F3 on the side of the interlayer 7 with respect to the first face F3 and having a second index of reflection nor. The second refractive index i is strictly lower than the first refractive index n

The material covering the first face F3 can form, at least in part, the intermediate layer 7. The material covering the first face F3 can be PVB. The laminated glazing 3 may comprise a thin layer, arranged between the intermediate layer 7 and the first sheet of glass 5. The thin layer may be a layer making it possible to reflect light radiation. The thin layer may be a metallic layer. The material covering the first face F3 on the side of the intermediate layer 7 can be the material of the thin layer.

The glazed element 1 comprises a light source 11 adapted to emit a light beam 12, and a photodetector 13 adapted to detect the light beam 12 emitted by the light source 11. The light source 11 and the photodetector 13 are arranged so that the light beam 12 propagates in the first glass sheet 5 from the first edge 8 to the second edge 9 by several total internal reflections on the first face F3 and on the second face F4 in the first glass sheet 5.

Thus, the first sheet of glass 5 forms a waveguide on which drops of mist can be formed. Indeed, due to the relationships between the refractive indices of the air and of the material in contact with the first sheet of glass 5, the light beam 12 can propagate from the light source 11 to the photodetector 13 by total reflections internal on the first face F3 and on the second face F4. During the nucleation of a drop of mist on the second face F4, part of the light beam 12 is transmitted to the interface formed between the glass and the liquid water of the drop of mist. This results in a decrease in the intensity of the light beam 12 which propagates as far as the photodetector in the first sheet of glass 5. In the case where the material covering the first face F3 is a PVB of the intermediate layer 7, the manufacture of the waveguide is simplified, since it is not necessary to modify the structure of the laminated glazing 3 to use the first sheet of glass 5 as a waveguide. Indeed, PVB has a refractive index lower than the refractive index of glass for wavelengths in the visible and infrared range.

Light source 11

The light source 11 can be configured to emit a light beam 12 having one or more chosen wavelength(s) in a range of wavelengths comprised between 800 nm and 2500 nm. Thus, it is possible to increase the total internal reflection properties of the waveguide formed by the first sheet of glass 5 while using a light beam 12 which is not visible to the user of the vehicle. Indeed, the interlayer 7 generally has a refractive index which decreases when the wavelength increases, while the refractive index of the glass is substantially constant during the variation of the wavelength from the visible range to the infrared domain. Preferably, the light source 11 can be configured to emit a light beam 12 having one or more chosen wavelength(s) in a range of wavelengths comprised between 850 nm and 1500 nm, and preferably between 850 nm and 1100nm. Thus, due to the dependence of the refractive index of the first sheet of glass on the wavelength of the light beams, it is possible to maximize the difference in refractive index between the first sheet of glass and between the layer spacer and/or the exterior of the glazed element.

The light source 11 may be a light-emitting diode, for example a light-emitting diode emitting in the infrared range. The light source 11 can comprise a laser, such as a dye laser, a gas laser, a semiconductor laser, a laser diode, a fiber laser, a solid laser, and/or a laser comprising a lamp discharge lamp, such as a neon lamp, a mercury lamp, a sodium lamp and/or a xenon lamp. The light source 11 can also comprise a lamp incandescent, for example an incandescent lamp comprising a halogen gas.

The light source 11 can be arranged so that the direction of the light beam 12, at a point defined by a reflection of the light beam on the first face F3, forms an angle with the first face F3 of less than 30°, preferably less than 15 ° . The angle formed on the one hand by a direction normal to the first face F3, in the first sheet of glass 5 and passing through the point defined by the reflection of the light beam 12 on the first face F3, and on the other hand by the light beam 12 is greater than 60°. Similarly, the angle formed on the one hand by a direction normal to the second face F4, in the first sheet of glass 5 and passing through the point defined by the reflection of the light beam 12 on the second face F4, and on the other hand by the light beam 12, is greater than 60 °. Thus, the first sheet of glass 5 can form a waveguide of the light beam 12 when the first sheet of glass 5 is arranged between the air and the interlayer 7, without having to modify the structure of the laminated glazing 3, by example by adding a thin layer allowing the total internal reflection of the light beam in the first glass sheet 5. Light absorption of the glass sheets

The first glass has a first absorption coefficient α 1 of the light beam 12. The second sheet of glass 6 is formed by a second glass and the second glass has a second absorption coefficient θ 2 of the light beam 12. The first coefficient of absorption ai can be strictly less than the second absorption coefficient θ2. Thus, the laminated glazing 3 can have infrared radiation absorption properties in transmission of the laminated glazing 3, while allowing the detection of the nucleation of a drop of fog on the second face F4. The first absorption coefficient ai may be less than 0.5 cm ¹ , in particular less than 0.1 cm ¹ . Thus, it is possible to limit the absorption of the light beam 12 during its propagation in the first sheet of glass 5 to detect fogging, while allowing the laminated glazing 3 to absorb the infrared radiation. Preferably, the second absorption coefficient O2 may be greater than 2 cm ¹ and preferentially greater than 3 cm ¹ .

Lighting of the laminated glazing 3 and spatial detection of the mist The glazed element 1 can comprise a light source 11 extending along part of the first edge 8, and preferably along the whole of the first edge 8. Thus, it is possible to increase the part of the first sheet of glass 5 which is illuminated by the light beam or beams 12, which makes it possible to increase the precision of the detection of the nucleation of a drop of mist 14. glazed element 1 may comprise a photodetector 13 extending along part of the second edge, and preferably along the whole of the first edge 8.

Referring to Figure 2, the glazed element 1 may include several light sources 11 arranged along at least part of an edge selected from the first edge 8 and the second edge 9. Thus, it is possible to increase the part of the first sheet of glass that is illuminated.

The glazed element 1 can comprise several photodetectors 13 arranged along at least part of an edge chosen from among the first edge 8 and the second edge 9. Thus, it is possible to spatially discriminate one or more parts of the first sheet of glass 5 where the mist appears, and thus to determine an image of the nucleation of drops of mist 14 on the second face F4.

The light sources 11 can be arranged along at least a part of the first edge 8 and the photodetectors 13 can be arranged along at least a part of the second edge 9.

Referring to Figure 3, at least one of the light sources 11 can be arranged on the first edge 8 and at least another of the light sources 11 can be arranged on the second edge 9. At least one of the photodetectors 13 can be arranged on the first edge 8 and at least one other of the photodetectors 13 can be arranged on the second edge 9. Thus, it is possible to illuminate the first sheet of glass 5 in a homogeneous manner, while by spatially discriminating one or more parts of the first sheet of glass 5 where the mist appears.

Method for detecting the nucleation of a drop of mist 14 With reference to FIG. 4, one aspect of the invention is a method for detecting the nucleation of a drop of mist 14 on the glazed element 1, in particular on the second face F4 of the glazed element 1 .

The method includes a step 401 of supplying a glazed element 1 according to one embodiment of the invention. The method comprises a step 402 of emission of a light beam by the light source 11, so that the light beam 12 propagates in the first sheet of glass 5 from the first edge 8 to the second edge 9 by several reflections internal total on the first face F3 and on the second face F4 in the first sheet of glass 5. The method comprises a step 403 of detection of the light beam 12 by the photodetector 13 and of emission of data representative of the light beam 12 detected.

The method comprises a step 404 of comparing the data representative of the light beam 12 detected with data representative of a reference light beam, and of detecting a drop of mist 14 on the second face F4 based on the comparison.

The method may comprise a step subsequent to step 404, in which data representative of the nucleation of a drop of mist on the second face F4 are transmitted to a system for controlling the temperature and/or the ventilation of the vehicle 2. Thus, it is possible to remove the mist from the first sheet of glass 5 before a driver can be bothered by the appearance of this mist.

When the glazed element comprises several photodetectors 13, the method can also comprise a step in which an image is determined the nucleation of drops of mist on the second face F4 from the representative data emitted by at least some of the photodetectors.

Referring to Figure 2 and Figure 3, the glazed element 1 may include control unit 15 configured to implement a method according to one embodiment of the invention.

Additional waveguide

Referring to Figure 5, a laminated glazing can include a waveguide 16, arranged on a part of the second face F4, on the side of the ambient medium 10 with respect to the second face F4. The waveguide 16 can be formed by a wire and/or by a film covering at least part of the second face F4. The waveguide 16 is arranged on the second face F4 so as to allow the propagation of a light beam 11 from the first edge 8 to the second edge 9. The waveguide has a face which is not in contact with the first face F4 and which is capable of supporting the nucleation of drops of mist 14.

A light source can be arranged so as to be able to inject a light beam into the waveguide 16. A photodetector can be arranged so as to be able to detect the light beam which propagates in the waveguide. The waveguide 16 can be formed by a wire or a film of organic material, glued to the first sheet of glass 5 on the second face F4. The waveguide 16 can be formed by a resin, preferably by a photocrosslinked resin.

The laminated glazing may comprise a plurality of waveguides 16, so as to spatially discriminate the nucleation of drops of mist on all of the waveguides 16, and thus on the first sheet of glass 5.

The dimensions of the waveguide, in particular the height and the width of the waveguide, can be chosen so that the waveguide 16 is a single-mode waveguide.

Claims

1. Glazed element (1) for a vehicle, comprising laminated glazing (3) extending along a main surface (4), the laminated glazing (3) comprising a first sheet of glass (5), a second sheet of glass (6), and an interlayer (7) arranged between the first sheet of glass (5) and the second sheet of glass (6), the first sheet of glass (5) having a first face (F3) and a second face (F4) parallel to main surface

(4), and having a first edge (8) and a second edge (9) opposite the first edge (8), the first face (F3) being on the side of the intermediate layer (7) with respect to the first sheet of glass (5), and the second face (F4) being opposite the first face (F3) with respect to the first sheet of glass

(5) and being capable of being in contact with an ambient medium (10) inside the vehicle (2) and of supporting the nucleation of a drop of mist (14), the first sheet of glass (5) being formed by a first glass having a first refractive index ni, the laminated glazing (3) comprising a material covering the first face (F3) on the side of the interlayer (7) with respect to the first face (F3) and having a second refractive index nor reflection, the glazed element (1) being characterized in that:

- the second refractive index ni is strictly lower than the first refractive index ni,

- the glazed element (1) comprises a light source (11) adapted to emit a light beam (12), and a photodetector (13) adapted to detect the light beam (12) emitted by the light source (11), the light source

(11) and the photodetector (13) being arranged so that the light beam

(12) propagates in the first glass sheet (5) from the first edge (8) to the second edge (9) by several total internal reflections on the first face (F3) and on the second face (F4) in the first glass sheet (5), the first glass having a first absorption coefficient ai of the light beam (12), the second glass sheet (6) being formed by a second glass, the second glass having a second coefficient d absorption O2 of the light beam (12), the first absorption coefficient d _f being strictly less than the second absorption coefficient Q _Î .

2. Glazed element (1) according to claim 1, wherein the material covering the first face (F3) forms, at least in part, the intermediate layer (7).

3. glazed element (1) according to claim 1 or 2, wherein the light beam (12) has one or more selected wavelength(s) in a range of wavelengths between 800 nm and 2500 nm, in particular between 850 nm and 1500 nm and preferably between 850 nm and 1100 nm.

4. glazed element (1) according to claim 3, wherein the first absorption coefficient ai is less than 0.5 cm ¹ , in particular less than 0.1 cnr ¹ .

5. Glazed element (1) according to one of the preceding claims, comprising several light sources (11) arranged along at least part of an edge selected from the first edge (8) and the second edge (9) .

6. Glazed element (1) according to one of the preceding claims, comprising several photodetectors (13) arranged along at least part of an edge selected from the first edge (8) and the second edge (9).

7. glazed element (1) according to claim 5 and according to claim 6, wherein the light sources (11) are arranged along at least a portion of the first edge (8) and wherein the photodetectors (13) are arranged along at least part of the second edge (9).

8. Glazed element (1) according to one of the preceding claims, comprising several light sources (11), at least one of the light sources (11) being arranged on the first edge (8) and at least one other of the sources lights (11) being arranged on the second edge (9).

9. Glazed element (1) according to one of the preceding claims, comprising several photodetectors (13), at least one of the photodetectors (13) being arranged on the first edge (8) and at least one other of the photodetectors (13 ) being arranged on the second edge (9).

10. glazed element (1) according to one of the preceding claims, wherein the light source (11) is arranged so that the light beam (12) propagates in the first glass sheet (5), the direction of the beam light (12) at a point defined by a reflection of the light beam on the first face (F3) forming an angle of less than 30° with the first face (F3).

11. Glazed element (1) according to one of the preceding claims, comprising a control unit (15) configured for:

- controlling an emission of the light beam (12) by the light source

(11 ),

- receiving data representative of the light beam (12) detected by the photodetector (13),

- comparing the data representative of the detected light beam with data representative of a reference light beam, and emitting a signal representative of the nucleation of a drop of mist (14) from the comparison.

12. Method for detecting the nucleation of a drop of mist (14) on a glazed element (1), comprising the steps of: a) supplying a glazed element (1) according to one of claims 1 to 11 , b) emission of a light beam by the light source (11), so that the light beam (12) propagates in the first sheet of glass (5) from the first edge (8) to the second edge ( 9) by several total internal reflections on the first face (F3) and on the second face (F4) in the first sheet of glass (5), c) detection of the light beam (12) by the photodetector (13) and emission of data representative of the light beam (12) detected, d) comparison of the data representative of the light beam (12) detected with data representative of a reference light beam, and detection of a drop of mist (14) on the second face (F4) from the comparison.

13. Method according to claim 12, comprising a step e), subsequent to step d), in which data representative of the nucleation of a drop of mist on the second face (F4) are transmitted to a control system temperature and/or ventilation of the vehicle (2).