WO2017148914A1 - Method for the treatment of a transparent lens for a motor vehicle lighting and/or signalling device - Google Patents

Abstract

The invention relates to a method (MTH) for the treatment of a transparent lens (G) for a lighting and/or signalling device (P) for a motor vehicle (V), in order to perform a de-icing function (Ft1) and/or an anti-condensation function (Ft2) on the lens (G). The treatment method (MTH) comprises: the deposition of an electrically conductive coating (R) on at least one internal face (s1) of the lens (G), said coating comprising an electrically conductive organic material; and the polymerisation of the coating (R). The invention also relates to a lighting and/or signalling device (P) for a motor vehicle (V), comprising a lens treated using the method of the invention.

Description

 PROCESS FOR TREATING A TRANSPARENT ICE FOR A LIGHTING AND / OR SIGNALING DEVICE FOR

 MOTOR VEHICLE

DOMAI N E TECH N I A L OF THE I NVE NTI ON

The present invention relates to a method of processing a transparent ice for a lighting and / or signaling device for a motor vehicle. It also relates to a lighting and / or signaling device for an associated motor vehicle.

It finds a particular but non-limiting application for motor vehicle headlamps.

BACKGROUND A process for treating a transparent glass for a motor vehicle comprises, in a manner known to those skilled in the art, the application of a resistive element composed of wires metal on transparent ice. When powered by a current, the resistive element dissipates a power that heats said transparent ice. This makes it possible to defrost the ice. This method of treatment is used in particular for a rear windshield glass motor vehicle.

A disadvantage of this state of the art is that such a resistive element can not be used for a lighting and / or signaling device. Indeed, the metallic son of the resistive element that are visible to the naked eye can not be applied to a lighting and / or signaling device such as a projector for example because they may significantly change the properties optics of the transparent glass of the projector. In this context, the present invention aims to solve the aforementioned drawback.

I NV E NTI ON G ENERAL C OMMITTEE

To this end, the invention proposes a method of treating a transparent ice for a lighting and / or signaling device for a motor vehicle to perform a de-icing function and / or an anti-condensation function on said ice, according to which the treatment method comprises:

 depositing an electrically conductive coating on at least one inner face of said ice, said coating being based on electrically conductive organic material; and

 the polymerization of said coating.

Thus, as will be seen in detail below, by applying an electrical voltage to the coating, the latter will emit thermal energy that will heat the transparent ice and thus prevent air from condensing and also defrost said ice.

According to non-limiting embodiments, the method for treating a transparent glass of a lighting and / or signaling device for a motor vehicle may also comprise one or more additional characteristics taken alone or in combination from the following :

 the transparent ice is made of synthetic polymer;

 the method further comprises the application of a surfactant to said ice prior to depositing said coating;

 the coating further comprises an alcoholic solvent;

the polymerization of said coating is carried out by thermal baking. depositing said coating on the ice is by watering or spraying;

 the organic material is composed of transparent electrically conductive polymers;

 said transparent electrically conductive polymers are:

 - phenylene polysulfide (PPS); or

 - Pedot-Pss.

 the deposition of the coating on the ice is carried out so as to obtain a coating thickness e of between 0.3 μηι and Ι Ο μΓΤΙ.

It is also proposed a lighting and / or signaling device for a motor vehicle comprising a housing and a transparent glass assembly said housing, wherein said ice comprises an electrically conductive coating on at least one inner face of said ice, said coating being based on electrically conductive organic material.

 According to non-limiting embodiments, the lighting and / or signaling device for a motor vehicle may also include one or more additional characteristics taken alone or in combination from the following:

 the organic material is composed of transparent electrically conductive polymers;

 the transparent electrically conductive polymers are: phenylene polysulfide (PPS); or Pedot-Pss.

 - The coating comprises a thickness e between 0.3 μηι and 10 μΓΤΙ.

said lighting and / or signaling device is a projector. BRIEF DESCRIPTION OF THE FIGURES

The invention and its various applications will be better understood on reading the following description and examining the figures that accompany it, in which:

 FIG. 1 represents a flow diagram of the process for treating a transparent ice of a lighting and / or signaling device according to a non-limiting embodiment of the invention;

FIG. 2 is a schematic side view of the lighting and / or signaling device comprising a transparent crystal treated by the treatment method of FIG. 1;

 FIG. 3 is an enlarged schematic view of a transparent ice portion of FIG.

DESCRIPTION OF EMBODIMENTS OF THE INVENTION

Identical elements, structure or function, appearing in different figures retain, unless otherwise specified, the same references.

The method MTH for processing a transparent glass G for a lighting and / or signaling device P for a motor vehicle V is illustrated in FIG. 1 in a nonlimiting embodiment.

 As will be seen below, the MTH treatment method makes it possible to perform a defrosting function Ft1 and / or anti-condensation Ft2 (or demisting) on the transparent ice G.

It will be noted that the frost may form on the outer face s2 as well as on the inner face s1 of the transparent ice G when it is integrated in a lighting and / or signaling device P for a motor vehicle V. Moreover, condensation or fog is mainly formed on the inner face s1 of the transparent ice G. In a non-limiting example, the lighting and / or signaling device P is a projector.

 A vehicle projector P is an element that breathes during use, through ventilation arranged in its housing. There is thus a more or less humid air exchange between the outside environment and the interior of the projector P. In fact, condensation can occur due to a temperature difference between the inner face s1 of the ice G and the outer face s2 of the ice G which is colder. Depending on the temperature, this mist can even freeze and form a layer of frost.

 Moreover, a projector P more and more often incorporates light sources that are semiconductor emitter chips such as LED light emitting diodes. These LEDs emit less thermal energy than conventional light sources such as filament halogen lamps and therefore do not heat the inner side of the ice G. Also, with the use of said LEDs, there is more risk of condensation on the inner face s1 of said transparent glass G. This condensation phenomenon is all the more troublesome that it is visible by an observer because the ice-cream G is transparent, unlike rear lights of a motor vehicle whose ice is tinted. It will be noted that the rear lights are less exposed to this phenomenon of condensation or frost than the headlamps P because:

 - they are not confronted with the frontal air flow; and

 - the light sources of the taillights are significantly less powerful than those of the headlamps. There is therefore less thermal difference between the outside and inside of the transparent ice G.

A projector P is illustrated in FIG. 2. As can be seen, such a projector P comprises in a non-limiting embodiment:

a reflector 20;

an outer casing 21 in which the reflector 20 is placed, a guide light 22 and at least one light source 23;

 a protective screen 24;

 the transparent ice G for closing said outer casing 21. The MTH treatment process is implemented on the transparent ice G before placing said ice-cream G on the outer casing 21 to close it. The ice G is subsequently attached to the housing 21 and generally glued.

 This method of MTH processing thus easily integrates into an already existing manufacturing process of a projector P, as it is related to ice. It is thus possible to propose standard versions of the projector without the de-icing or defogging function and the special versions of these projectors with these functions, while having an ice-cream on which the coating R has been applied, as well as arrangements of the housing allowing the power supply of said coating.

 As will be seen hereinafter, the MTH method makes it possible to obtain an electrically conductive layer which is the coating R on the surface of the ice G and, by heating the transparent ice G, makes it possible to perform a defrosting function Ft1 on said transparent ice G and an anti-condensation function Ft2 on said ice cream G.

 The coating R is thus conductive to convey the current supplied by a power source, and is also resistive to release heat so as to heat the transparent ice. As illustrated in FIG. 1, the MTH method comprises:

 depositing a coating R on at least one inner face s1 of said ice-cream G (illustrated function APP (R, s1, G)), said coating R being based on electrically conductive organic material; and

 the polymerization of said coating R (illustrated function POLYM (R)).

In the rest of the description, the coating R is also called film or varnish.

 In a non-limiting embodiment, the transparent ice G is made of synthetic polymer. Indeed, the transparent lens of a projector P is conventionally made of plastic. In a non-limiting example, said transparent ice G is polycarbonate.

The steps of the MTH process are described below.

• Deposit

The coating R is deposited on the inner face s1 of the glass G. This makes it possible to perform the functions of defrost Ft1 and anti-condensation Ft2 sought. Indeed, condensation appears mainly on the inner face s1 of the transparent ice G. Moreover, the fact of applying a voltage on the glass G, the latter, thanks to the resistive coating R, will heat and melt the frost which covers the outer face s2 or the inner face s1 of the ice G. In addition, the thermal energy released by the resistive coating R will help prevent air from condensing on the inner face s1 of the ice G.

 It will be noted that the coating R is deposited preferably over the entire extent of the inner face of the transparent ice G.

 It can also be deposited on only part of this surface:

- if the shape of the ice prevents deposition in certain areas, depending on the deposition techniques used;

 if it is desired to restrict the deposition to the areas of the ice in which the phenomenon of condensation occurs in the actual operating situation of the lighting device and / or signaling for which said ice-cream is intended, zones that can be determined by thermal simulation or by observation during the development phases of the lighting device and the vehicle in which it is integrated.

In a first non-limiting embodiment, the deposition of the coating R on the transparent ice G is done by a watering (called in English "flow-coating").

 Watering allows to deposit the coating R by means of a jet which flows on the ice G. The surplus of coating is recovered in a collecting tank by gravity or by rotation of the ice G. It will be noted that the ice G can be placed in an inclined position so as to facilitate access to hard-to-reach areas on the inner side s1 by the watering machine. These hard-to-access areas are so-called off-area areas or masked areas that correspond to areas of the ice-cream G not illuminated by the light sources of the projector P when they are lit. These areas are those on which the condensation is the most important since they are the coldest areas of the ice G because unheated by the light sources. In a second non-limiting embodiment, the deposition of the coating R on the transparent ice G is by spray (called "spray-coating"). The coating is mixed with compressed air to produce a jet which is sprayed with a pistol on the inside face s1 of the ice-cream.

Note that these two embodiments allow a good application of the coating R on a curved surface, which is at least the inner face s1 of the ice G.

 It will be noted that when only a portion of the ice G is treated, masks will advantageously be used to mask the areas of the ice G not to be treated with the deposition methods described above.

It will be noted that the depositing of the dip coating R (dip-coating) is not used if it is desired to cover only the inside face s1 of the ice-cream G, since in this case all the ice-cream G is immersed in a coating bath R. The outer face s2 and the inner side s1 are covered with the coating R.

It will be noted that it is possible to reuse already existing lines for depositing automotive window glazing varnishes, for example for the deposition of hyd roph lacquer or anti-condensation on the inner face of the ice or the deposition of varnish outer protection such as anti-scratch varnishes. It is thus not necessary to manufacture a mechanical deposition line dedicated to the application of electrically conductive anti-condensation and anti-condensation lacquer R.

In a non-limiting embodiment, the deposition of the coating R on the ice-cream G is performed so as to obtain a coating thickness R included, inclusive, between 0.3μηι and 10μηι (after drying), preferably between 0, 5 and 1 μηπ, limits included. It will be noted that the parameterization of the conventionally used deposition lines makes it possible to obtain a determined thickness e.

 Thus, for example, for deposition by "flow-coating", the thickness e of the coating R is a function of the inclination of the ice G, the viscosity of the coating R, the amount of solvent So used (described more away) and its evapo- ration.

In a nonlimiting embodiment, the MTH treatment method comprises the deposition of one or more R coating layers on the transparent ice G. Thus, a small thickness e between 0.3 μηι ΘΠ Ο μηι.

 This small thickness e of coating R makes it possible to preserve the optical properties of the transparent ice G. It is thus unnecessary to add an additional refractive layer. The path of the light beam formed by the light rays of the light sources is thus not disturbed. In addition, it does not alter the transparency effect of the ice G.

Moreover, this thin thickness e allows almost instantaneous drying of the R coating on ice G.

 Finally, this small thickness e makes it possible to obtain a defrosting in 20 minutes maximum in static mode simulating a stationary vehicle and cold engine, when the ice G is powered with a voltage of 12V in a non-limiting example.

In order to improve the deposition of the coating R on the transparent ice G, in a non-limiting embodiment, the method of treatment MTH further comprises the application of a surfactant S on said ice-cream G prior to the deposition of said coating R ( function shown in dashed lines in Figure 1 APP (S, G)).

 The surfactant S is a primer that modifies the surface tension of the transparent ice G to obtain a wettability effect and thus create a superior adhesion on said ice G. This makes it possible to deposit the coating R in a homogeneous and continuous manner and thus better check the thickness e deposited on the entire surface of the ice G.

Without depositing surfactant S beforehand, the coating R may form droplets which cause a rupture of said coating. Due to this rupture, the electrical conductivity of the coating R can lose efficiency. In a non-limiting example, the surfactant S is soapy water.

• Drying and / or J.yménsation

The drying and / or the polymerization of the coating R makes it possible to modify the organic material of the coating R so that this organic material undergoes a transformation phenomenon (here thermal) and thus enters a rigid, solid, thermosetting and non-fusible phase.

Thus, the drying and / or the polymerization of the coating R causes an increase in the viscosity of the coating R and thus a solidification of said coating R.

In a non-limiting embodiment, drying and / or polymerization R coating is carried out by thermal baking (function shown in dashed lines in Figure 1 CK (R)).

 Thermal cooking makes it possible to desolvenate the varnish R, namely to remove the solvent So (described later) which is used if appropriate. The solvent So is not trapped in the layer of varnish R and does not risk creating bubbles that disrupt the effect of the varnish.

 On the other hand, the thermal cooking makes it possible to polymerize the varnish R so that it becomes solid. Thus a crosslinking of said varnish R is observed, namely during a subsequent heat input, the varnish R will not melt or deform.

 As the viscosity increases with heat, a hardened layer is obtained on the inside face s1 of the ice cream G.

The coating R is detailed below with reference to FIG.

In a non-limiting embodiment, the coating R further comprises an alcoholic solvent So. This makes it possible to obtain a surface tension effect. In a non-limiting example, the alcoholic solvent is water combined with alcohol. This makes it possible to solubilize the organic matter. An aqueous or hydro-alcoholic coating R with a fairly low viscosity, in particular less than 0.9 m ² s ^-1 at 25 ° C., is thus obtained to facilitate the application of the coating on ice-cream G.

In one nonlimiting embodiment, the organic material is composed of transparent electrically conductive polymers Po as shown in FIG. 3 which is an enlargement of a portion of the mirror G of the lighting and / or signaling device P.

In a non-limiting embodiment, the conductivity of the transparent electrically conductive polymers Po is at least 10 ³ Sm ^-1 (Siemens per meter), for example between 10 ³ and 10 ⁶ Sm ^-1 . Thus, in non-limiting embodiments, the transparent electrically conductive polymers Po are:

 phenylene polysulfide; or

 Pedot: Pss.

It is recalled that the Pedot: Pss is a mixture of two polymers which are:

poly (3,4-ethylenedioxythiophene) (PEDOT); and

 sodium poly (styrene sulfonate) (PSS).

It is recalled that the electrical conductivity is the ability to let the electric charges move freely, namely to allow the passage of electric current. The electrical conductivity thus depends on the density of the charge carriers in the organic material. The charge carriers are the electrons (negative charge carrier) but also the electron holes (positive charge carriers).

The conductivity of the polymers is explained according to the molecular orbital theory. According to this theory, the electrons of a molecular structure are treated as moving under the influence of the nuclei of the molecule as a whole. Electrons are not assigned to chemical bonds between atoms as in the case of atomic orbitals. Each molecule is thus endowed with a set of molecular orbitals (also called hybrid atomic orbitals), a molecular orbital being a linear combination of atomic orbitals belonging to the same electronic layer.

Some molecular orbitals are boundary orbitals The boundary orbitals are:

- the HOMO ("Highest Occupied Molecular Orbital") orbital, which is the highest energy molecular orbital occupied by at least one electron. This orbital is also called valence band; - the LUMO ("Lowest Unoccupied Molecular Orbital") orbital, which is the lowest molecular orbital in energy not occupied by an electron. This orbital is also called conduction band.

 The HOMO orbital comprises mobile electrons shared by the atoms of the molecule. They are called π electrons.

These electrons can go from the HOMO orbital to the LUMO orbital. This is called the π-π ^* transition. The energy required for this transition determines the maximum wavelength that can be converted into electrical energy by the polymer.

The electrical conductivity of the polymers results in particular from doping by the addition of a chemical reagent which oxidizes or reduces the polymer. Doping passes electrons from the HOMO orbital to the LUMO orbital, making the polymer electrically conductive.

In a non-limiting embodiment, the doping is chemical. It exposes the polymer to an oxidant (in a non-limiting example of iodine, bromine, halogens) or to a reducing agent (in a non-limiting example of the alkali metals). Oxidation doping is also called P-type doping, and reduction doping is called N-type doping. Thus, positive or negative charges are introduced on the polymer.

In a second non-limiting embodiment, the doping is electrochemical. Two electrodes are immersed in a solution. One of them is covered with the polymer that we want to dope. By applying a voltage between the electrodes, this causes a movement of the ions of the solution and the electrons which:

 - attach to the polymer. An excess of electrons is obtained at the conduction band of the polymer (N doping); or

- escape from it. An electron defect is obtained at the conduction band of the polymer (P doping). Thus, with the treatment of the transparent ice G with said conductive coating R, when a supply voltage is applied to said mirror G, as in a non-limiting example, a voltage of 12V delivered by the vehicle battery, thanks to to the corresponding current supplied, the resistive coating R emits a thermal energy that is propagated to the ice through a suitable thermal conductivity. The ice G thus heated no longer freezes and there is also more condensation on the inner face s1 of said ice G. It will be noted that thanks to this conductive coating R and resistive, the tests made it possible to show that defrosting Ice G is less than ten minutes.

 Note that in the context of the motor vehicle application, in a non-limiting embodiment, the power source is the battery of the vehicle that powers the onboard electrical network of said vehicle.

Thus, thanks to the MTH treatment method described above, a lighting and / or signaling device P for a motor vehicle V comprising a housing 21 and a transparent ice G assembled to said housing 21, according to which said ice-cream G comprises an electrically conductive coating R on at least one inner face s1, said coating being based on electrically conductive organic material. As indicated above, in a non-limiting embodiment, the lighting and / or signaling device is a projector P, as illustrated in FIG. 2 or FIG.

Of course, in a non-limiting embodiment, the lighting and / or signaling device P furthermore comprises a power source (not shown) for supplying voltage to the ice-cream G and thus supplying a supply current to the R. coating

In addition, the lighting and / or signaling device P will comprise electrical connection means for connecting the power source to the resistive coating R. These connection means will comprise in particular dedicated electrodes for connecting the housing to the glass G during or after the placing of said glass G on the housing of the lighting and / or signaling device P. Such electrodes may according to a first embodiment be electrodes flexible metal, preferably copper, preferably adhesive. According to a second embodiment, they may be transparent and made based Pedot: Pss.

Of course, the description of the invention is not limited to the embodiments described above.

Thus, in a non-limiting embodiment, the coating R is applied to the outer face s2 of the transparent ice G.

 Thus, the treatment method has been described in the context of a motor vehicle. However, the treatment method can be applied to any type of vehicle, whether it is terrestrial or aerial, motorized or not.

Thus, the invention described has the following advantages:

- it is a simple solution to implement and inexpensive;

 - it solves at the same time the problem of defrosting and the problem of condensation;

 - It provides a simple solution of defrosting and anti-condensation on a concave ice-cream;

 - it provides a simple defrosting and anti-condensation solution on a plastic ice-cream;

 - It provides a solution that has good performance over time: the coating R degrades very little over time, especially when it is applied to the inner surface of the ice;

 - It answers a problem concerning the presence of frost on a projector at very low temperature, said projector comprising light emitting diodes;

it does not disturb the light beam emitted by the projector P, unlike the solution of the state of the prior art comprising a silkscreened resistance, said resistor being composed of visible metal wires;

it does not modify the optical properties of the ice-cream G unlike a solution which comprises a resistive element screen-printed on an ice such as a rear windshield;

it does not modify the aesthetics of the glass G since it does not use a resistor composed of visible metal son as in the prior art described;

it avoids adding additional parts in the projector as opposed to a solution that includes a heating resistor and a convection system inside the projector P;

it allows to quickly defrost ice G unlike a solution that includes a heating resistor and a convection system inside the projector P, this solution only to defrost the ice after about an hour;

it is not bulky in contrast to a solution that includes a heating resistor and a convection system inside the projector P, the convection system comprising a fan and a support and thus occupying an important place in the projector P; it is not energy consuming, unlike a solution that includes a heating resistor and a convection system inside the projector P, said heating resistor consuming a power greater than 40 Watts;

it avoids managing the arrangement between a resistor and a convection system as in a solution that includes a heating resistor and a convection system inside the projector P; it is much more effective than a solution which comprises the treatment of the inner surface of the ice with a hydrophilic varnish, said hydrophilic varnish avoiding only to see the condensation droplets on the ice but not preventing the formation of condensation and gel formation on an ice cream G. In this solution with the hydrophilic varnish, the water is not removed and once the varnish is saturated with water, it loses efficiency.

Claims

1. Method (MTH) for processing a transparent ice (G) for a lighting and / or signaling device (P) for a motor vehicle (V) for performing a defrosting function (Ft1) and / or a function of d anti-condensation (Ft2) on said ice (G), wherein the treatment method (MTH) comprises:

 depositing a coating (R) on at least one inner face (s1) of said ice (G), said coating being based on electrically conductive organic material; and

 the polymerization of said coating (R).

2. Method (MTH) according to claim 1, wherein the transparent ice (G) is synthetic polymer.

3. The method of claim 1 or claim 2, wherein the method further comprises the application of a surfactant (S) on said ice (G) prior to the deposition of said coating (R).

4. Method according to any one of claims 1 to 3, wherein the coating (R) further comprises an alcoholic solvent (So).

5. Method according to any one of claims 1 to 4, wherein the polymerization of said coating is carried out by thermal baking.

6. Method (MTH) according to any one of claims 1 to 5, wherein the deposition of said coating (R) on ice (G) is by sprinkling or spraying.

7. Method (MTH) according to any one of the preceding claims 1 to 6, wherein the organic material is composed of transparent electrically conductive polymers (Po).

8. Method (MTH) according to the preceding claim 7, wherein transparent electrically conductive polymers (Po) are:

- phenylene polysulfide (PPS); or

 - Pedot-Pss.

9. Method (MTH) according to any one of the preceding claims 1 to 8, wherein the deposition of the coating (R) on the ice (G) is performed so as to obtain a coating thickness (e) of between 0, 3 μηι and 10 μηι.

10. A lighting and / or signaling device (P) for a motor vehicle (V) comprising a housing (21) and a transparent ice (G) assembled to said housing (21), wherein said ice (G) comprises a coating (R) on at least one inner face (s1), said coating being based on electrically conductive organic material.

1 1. Lighting and / or signaling device (P) according to the preceding claim, according to which the organic material is composed of transparent electrically conductive polymers (Po).

12. A lighting and / or signaling device (P) according to the preceding claim, according to which the transparent electrically conductive polymers (Po) are:

 - phenylene polysulfide (PPS); or

- Pedot-Pss.

13. A lighting and / or signaling device (P) according to any one of the preceding claims 10 to 12, wherein the coating (R) comprises a thickness (e) between 0.3 μηι and 10 μΓΤΙ.

14. A lighting and / or signaling device (P) according to any one of the preceding claims 10 to 13, wherein said lighting and / or signaling device (P) is a projector.