Title of Invention

A TRANSPARENT SUBSTRATE PROVIDED WITH A THIN-FILM MULTILAYER

Abstract A transparent substrate provided with a thin-film multilayer comprising at least one functional metal layer, especially a silver-based layer, having reflection properties in the infrared and/or in the solar radiation range, at least one metal barrier layer in contact with the functional layer and at least one upper dielectric layer, characterized in that at least one barrier layer is based on zirconium and in that the upper dielectric layer comprises at least one ZnO-based layer in contact with the functional layer or with the barrier layer.
Full Text The present invention relates to a transparent substrate provided
with a thin-film multilayer comprising at least one functional metal layer,
especially a silver-based layer, having reflection properties in the infrared
and/or in the solar radiation range, at least one metal barrier layer in
contact with the functional layer and at least one upper dielectric layer.
Such substrates are already known in which the layers
constituting the multilayer create an optical interference system that
results in selective transmission of certain parts of the solar spectrum or
infrared radiation.
It is known that silver deposited as a functional layer on a
substrate is relatively sensitive to chemical stresses, especially to attack
by oxygen, and it is liable to be degraded during the subsequent
deposition of another layer, especially when this is oxide-based. To protect
the silver layers from being attacked by oxygen, they are therefore, as a
general rule, protected by a thin metal layer applied on top of them, this
layer being called a "barrier layer" that has a very high affinity for oxygen.
Similarly, it may be opportune to have beneath the silver layer a
metal barrier layer so as to protect the silver layer from an oxygen flux
coming from the lower part of the multilayer.
This type of multilayer is described for example in document
FR-A-2 641 271, which relates to a substrate intended to be incorporated
into a glazing unit, bearing a coating composed of a tin oxide, titanium
oxide, aluminum oxide and/or bismuth oxide sublayer, then a zinc oxide
layer with a thickness not greater than 15 nm, then a silver layer, a
transparent covering layer comprising a layer of an oxide of a sacrificial
metal, chosen from Ti, Al, stainless steel, Bi, Sn and mixtures thereof,
and at least one other Sn, Ti, Al and/or Bi oxide layer, the oxide of
sacrificial metal being formed by initial deposition of the sacrificial metal,
with a thickness of 2 to 15 nm, followed by its conversion into an oxide so
as to produce the barrier layer.
This structure helps to improve the corrosion resistance of the
silver layer, not only during manufacture of the coated substrate but also
during the lifetime of the product.
In practice, only titanium and stainless steel are given as
illustrations of sacrificial metal, with a thickness of at least 3.5 nm.
Nickel-chromium is also a metal quite often used to form a barrier
layer in a silver-based multilayer. However, the optical performance of
such multilayers is limited in terms of light transmission and their energy
performance which could be further improved.
In a multilayer known from document EP 104 870, which relates
to the production of a low-emissivity coating by sputtering, one or more of
an additional metal, other than silver, are sputtered onto a silver layer, in
an amount equivalent to a layer from 0.5 to 10 nm in thickness, before
carrying out reactive sputtering, in the presence of oxygen or of an
oxidizing gas, onto the silver and the additional metal, of one or more
antireflection metal oxide layers under conditions which, in the absence
of the additional metal or metals, would lead to substantial reductions in
the low-emissivity properties of the resulting product.
Copper is presented as an advantageous additional metal because
of its oxidation resistance and of its contribution to the low emissivity, but
other metals are also envisioned that oxidize following the reactive
sputtering process into a colorless oxide favorable to a high light
transmission. Among such metals, aluminum, titanium and zirconium
are mentioned. Other preferred metals are Bi, In, Pb, Mn, Fe, Cr, Ni, Co,
Mo, W, Pt, Au, Vd, Ta and alloys such as stainless steel and brass.
Various metal oxides are then combined to produce a superior
antireflection coating.
Example 19 reveals in particular the possibility of using zirconium
as additional metal, with a thickness of 2.7 nm, on a 10 nm thick silver
layer, in combination with two SnO2 oxide coatings with a thickness of 48
nm underneath and 43 nm on top, respectively.
Among the examples presented, this structure makes it possible to
achieve an advantageous light transmission of 84 %.
However, the Applicant has found that the mechanical integrity of
such a multilayer is mediocre and that it does not sufficiently withstand
the operations and handling that are needed for incorporating the
substrate into a glazing unit, so that its properties, especially its
emissivity and light transmission, are of course impaired thereby.
The object of the invention is to propose a substrate provided with
a thin-film multilayer of the aforementioned type that exhibits high
performance in terms of light transmission, external reflection color and
emissivity, while still exhibiting good mechanical resistance.
The substrate according to the invention is provided with a thin-
film multilayer comprising at least one functional layer, especially a silver-
based layer, having reflection properties in the infrared and/or in the
solar radiation range, at least one metal barrier layer in contact with the
functional layer and at least one upper dielectric layer, and is
characterized in that at least one barrier layer is based on Zr and in that
the upper dielectric layer comprises at least one ZnO-based layer in
contact with the functional layer or with the barrier layer.
Within the meaning of the present application, the terms "lower"
and "upper" define the relative position of a layer relative to the functional
layer, without there necessarily being any contact between said layer and
the functional layer.
Also within the meaning of the present application, the term "metal
barrier" is understood to mean a barrier that is deposited in metal form;
however, it is obvious that this layer can undergo partial oxidation during
deposition (during its own deposition, but above all during deposition of
the next layer) or during a heat treatment.
It has thus been demonstrated that zirconium metal exhibits a
kind of incompatibility with most dielectrics commonly used to form
multilayers that include functional metal layers. The nature of this
incompatibility has not been clearly identified, and could prejudice
interlaminar adhesion between the layers. The scratch resistance or
abrasion resistance of a multilayer combining zirconium with zinc oxide is
in fact satisfactory, whereas the other multilayers have unacceptable
drawbacks.
The invention applies to multilayers comprising at least one metal
functional layer, especially based on silver, gold or copper, optionally
doped with at least one additional metal, such as titanium or palladium
in the case of silver.
According to the invention, the zirconium-based barrier layer may
be placed beneath and/or on top of the functional metal layer. The ZnO-
based dielectric layer may be in direct contact with a Zr-based upper
barrier, or in direct contact with the functional layer or with any upper
barrier if a zirconium lower barrier layer is present.
The structure according to the invention may thus be based on
the sequence:
functional metal layer/Zr/ZnO etc.
where the ZnO layer is in direct contact with the zirconium.
In this case, the high mechanical stability of the multilayer is
attributed to the good adhesion of the zinc oxide deposited as a thin film
on the zirconium layer, whereas the other known oxides adhere poorly to
Zr, probably because of poor wetting of the oxide on the zirconium during
deposition of the thin film.
The multilayer may then comprise beneath the silver, a lower
barrier layer based on a metal chosen from titanium, nickel-chromium,
niobium, zirconium, etc.
The structure according to the invention may also be based on the
sequence:
Zr/functional metal layer/ZnO etc.
In this case, the high mechanical stability of the multilayer is due
to the fact that, since zirconium is used as under-barrier, it is not
exposed to an oxidizing plasma, since no oxide is deposited on top, and
consequently it is very little oxidized by the layer deposited beforehand.
An upper barrier may optionally be inserted between the
functional metal layer and the zinc oxide, and this may be chosen from
nickel-chromium, titanium, niobium and zirconium.
A structure according to the invention may be followed by another
structure according to the invention, this being identical or different in
one and the same multilayer.
Thanks to the structure according to the invention of the strictly
lower and/or upper layers deposited on the functional layer, not only is
a multilayer obtained that has very satisfactory light transmission,
external reflection color and emissivity values, but also a multilayer
exhibiting surprisingly good mechanical resistance and also, where
appropriate, chemical resistance.
The thickness of the barrier layer(s), especially that (those) based
on Zr, is advantageously chosen to be of sufficient value for the layer to
oxidize only partially or practically completely - without impairing the
silver layer - during the subsequent deposition of oxide or during a heat
treatment in an oxidizing atmosphere, such as a toughening treatment.
Preferably, this thickness is less than or equal to 6 nm, advantageously
at least 0.2 nm, especially between 0.4 and 6 nm, and in particular 0.6
to 2 nm.
According to the invention, a Zr-based barrier layer is preferably
deposited by magnetron sputtering using a zirconium metal target, which
may optionally contain an additional element such as Ca, Y, or Hf, in a
proportion of 1 to 10% by weight of the target.
The or each functional metal layer is typically a silver layer, but
the invention applies in the same way to other reflective metal layers,
such as silver alloys, especially containing titanium or palladium, or
layers based on gold or copper. The thickness of each functional layer is
especially from 5 to 18 nm, preferably around 6 to 15 nm.
The substrate according to the invention may comprise one or
more functional metal layers, especially two or three, each with a
thickness within the aforementioned ranges. At least one functional
layer is associated with a zirconium-based barrier layer and preferably
each functional metal layer is associated with a zirconium-based barrier
layer. The position of the zirconium-based layer with respect to a
functional metal layer is not necessarily the same as for the other
functional metal layer or layers within a multilayer.
The function of the zinc oxide upper dielectric layer is especially to
protect the subjacent functional metal layer, while contributing to the
optical properties of the substrate.
This layer may in general be deposited with a thickness of at least
5 nm, especially around 5 to 25 nm, and more particularly 5 to 10 nm.
The multilayer may also include a lower dielectric layer based on
an oxide or nitride, especially comprising the sequence SnO2/TiO2/ZnO
or the sequence Si3N4/ZnO.
The multilayer may also include an upper mechanical protection
layer whose function is to improve the mechanical resistance of the
multilayer, especially its resistance to scratching or abrasion.
This may be an optionally doped layer based on an oxide, nitride
and/or oxynitride, especially based on at least one oxide of titanium, zinc,
tin, antimony, silicon or mixtures thereof, optionally nitrided, or based on
a nitride, especially based on silicon nitride or aluminum nitride. Mention
may more particularly be made of TiO2, SnO2, and Si3N4, or mixed oxides
based on zinc and tin (ZnSnOx), optionally doped with another element
such as Sb, or based on zinc and titanium (ZnTiOx) or else based on zinc
and zirconium (ZnZrOx).
It may also be a combination of layers based on the
abovementioned materials, especially Si3N4 /SnZnOx or Si3N4 /TiO2 .
Among these compounds, silicon nitride has an additional
advantage when the substrate is intended to undergo an oxidizing heat
treatment. This is because it blocks the diffusion of oxygen into the
interior of the multilayer, including at high temperature. Since the nitride
is largely inert with respect to an oxidizing attack, it undergoes no
appreciable chemical (oxidative) or structural modification during a heat
treatment of the toughening type. It therefore causes practically no optical
modification of the multilayer in the case of heat treatment, especially in
terms of light transmission level. This layer may also act as barrier to the
diffusion of species migrating from the glass, especially alkaline metals.
Furthermore, thanks to its refractive index close to 2, it is readily received
in a multilayer of the low-emissivity type from the standpoint of adjusting
the optical properties.
This protection layer may generally be deposited with a thickness
of at least 10 nm, for example between 15 and 50 nm, especially around
25 to 45 nm.
Preferably, the multilayer according to the invention
substantially preserves its properties, especially optical properties, after
a heat treatment at a temperature of at least 500°C, whether this be for
example a toughening operation, annealing operating or bending
operation.
The present invention also relates to low-emissivity or solar-
protection glazing that incorporates at least one substrate as described
above and especially laminated glazing or double glazing.
This is because the coated substrate may be used as double
glazing, the multilayer being able to be affixed to the insert film within the
laminated assembly facing the outside (face 2) or facing the inside (face 3).
In such glazing, at least one substrate may be toughened or hardened,
especially that bearing the multilayer. The coated substrate may also be
joined to another glass, at least via a gas-filled cavity in order to form an
insulating multiple glazing unit (double glazing). In this case, the
multilayer preferably faces the intermediate gas-filled cavity (face 2
and/or face 3). A double glazing unit according to the invention may
incorporate at least one laminated glass.
When the glazing according to the invention is mounted as double
glazing with another substrate, the assembly advantageously has a light
transmission of between 40 and 90%.
Furthermore, the glazing according to the invention
advantageously has a selectivity defined by the ratio of the light
transmission to the solar factor, Tl/SF of between 1.1 and 2.1.
The present invention also relates to a method of improving the
mechanical strength of a transparent substrate, especially glass, provided
with a thin-film multilayer comprising at least one functional metal layer,
especially a silver-based layer, having reflection properties in the infrared
and/or in the solar radiation range, at least one metal barrier layer in
contact with the functional layer and at least one upper dielectric layer,
characterized in that at least one functional metal layer, a Zr-based lower
and/or upper barrier layer, respectively on and/or under said functional
metal layer, and a ZnO-based upper dielectric layer are deposited on the
substrate by sputtering.
The invention is illustrated hereinafter by comparative examples
and examples according to the invention, in which various barriers and
dielectric layers will be examined.
Unless otherwise indicated, the thicknesses of the substrates and
of the glazing of the comparative examples are identical to the thicknesses
of the substrates and of the glazing of the examples according to the
invention with which they are compared.
The following optical properties are evaluated: light transmission,
light reflection on the multilayer side and color in reflection in the L*a*b*
system.
The light transmission and light reflection were measured with
an integrating-sphere measurement apparatus that measured the light
flux in all directions on one side of the substrate or on the other.
The thermal properties were measured by means of the electrical
surface resistance and the emissivity.
The mechanical resistance properties were also evaluated:
- shear abrasion resistance of the multilayer, obtained in the
Erichsen scrubbing brush test. It will be recalled that in this test the
multilayer is scrubbed by a brush with bristles made of polymeric
material, the multilayer being covered with water;
- scratch resistance in the Erichsen stylus test. It will be recalled
that in the test a stylus loaded with a weight is moved over the substrate
at a given speed. The load (in newtons) needed to make the stylus visibly
scratch the multilayer is noted; and
- indentation resistance in the Taber test. It will be recalled in the
Taber test that the specimen is subjected to abrasive rollers for a given
time and the proportion (in %) of the surface of the multilayer system that
is not torn after 20 revolutions under a load of 250 g is measured.
Comparative Example 1
In this comparative example, a silver-based multilayer according
to the prior art, with a nickel-chromium barrier and a tin oxide upper
dielectric layer, was deposited on a glass substrate 4 mm in thickness.
A multilayer of the following type was obtained:
substrate /SnO2 /TiO2 /ZnO/Ag/NiCr/SnO2.
This substrate was produced by sputtering, by making the
substrate run through a chamber past metal targets in an argon
atmosphere, in order to deposit a metal layer, and in an argon/oxygen
atmosphere in order to deposit an oxide.
The results of the optical and energy measurements are given in
Table 1 below.
The substrate was mounted in a double glazing arrangement
having an intermediate cavity 15 mm in thickness filled with 90° argon,
with a second glazed element 4 mm in thickness, and the transmission,
the light reflection, the color in reflection, the solar factor and the
coefficient U were again measured.
The results are given in Table 2 below.
The results of the mechanical measurements are given in Table 3
below.
Comparative Example 2
In this comparative example, a multilayer substantially identical
to that of Comparative Example 1 was used. Comparative Example 2
differs solely by the fact that the nickel-chromium barrier is replaced
with zirconium. A stack of the following type was obtained:
substrate / SnO2 /TiO2 /ZnO/Ag/Zr/SnO2.
The results of the optical measurements are given in Table 1 in
monolithic format, in Table 2 in double glazing format, and results of the
mechanical measurements are given in Table 3 below.

This shows that replacing the NiCr barrier with a Zr barrier
improves the color in reflection on the multilayer side (more neutral
color), increases the transmission and reduces the resistance per
square in monolithic format.
This results in double glazing that is also slightly more neutral in
external reflection, with a higher transmission and with better thermal
insulation characteristics in double glazing format (U = 1.19 W.m2.K1 in
the case of the NiCr barrier, compared with U = 1.15 W.m-2.K-1 in the case
of the Zr barrier).
By replacing the NiCr barrier with Zr in the multilayer, the
mechanical integrity of the multilayers in the Erichsen scrubbing brush
test with a Zr barrier was catastrophic - after the test severe delamination
of the multilayer was observed.
The scratch resistance was also reduced.
Only the resistance to the Taber test was improved, indicating
special behavior as regards indentation compared with abrasion.
Example 1
In this example, on a glass substrate of the same type as for
Comparative Example 1, a multilayer of the following type was
deposited:
substrate /SnO2 / TiO2 / ZnO / Ag / Zr / ZnO / SnO2
22 nm / 8 nm / 8 nm / 10 nm / 0.6 nm/ 21 nm / 22 nm
The results of the optical measurements are given in Table 4 in
monolithic format, in Table 5 in double glazing format, and the results of
the mechanical measurements are given in Table 6 below.
Example 2
This example differs from Example 1 only by the fact that the the
final layer of SnO2 is replaced with Si3N4. A stack of the following type
was obtained:
substrate / SnO2 / TiO2 / ZnO / Ag / Zr / ZnO / Si3N1
22 nm / 8 nm / 8 nm / 10 nm / 0.6 nm/ 21 nm / 22 nm
Comparative Examples la and 2a
These comparative examples are similar to Comparative
Examples 1 and 2 in which the thickness of the multilayers was
adapted so as to be identical to the thicknesses of the homologous
multilayers of Example 1.
In practice, the thicknesses were as follows:
Comp. Ex. la
substrate / SnO2 / TiO2 / ZnO / Ag / NiCr / SnO2
22 nm / 8 nm / 8 nm/ 10 nm/ 0.6 nm/ 43 nm.
Comp. Ex. 2a
substrate / SnO2 / TiO2 / ZnO / Ag / Zr / SnO2
22 nm / 8 nm / 8 nm / 10 nm / 0.6 nm/ 43 nm.
The results of the optical measurements are given in Table 4 in
monolithic format and in Table 5 in double glazing format, and the results
of the mechanical measurements are given in Table 6 below.
Comparative Examples la and 2a also show that replacing the
NiCr barrier with a Zr barrier results in an increase in the light
transmission and a reduction in the emissivity in monolithic format. In
double glazing format, the light transmission also increases and the
factor U is lower for the same silver thickness when the barrier is of
zirconium in preference to NiCr.
The levels achieved by Examples 1 and 2 demonstrate a better
light transmission than with an NiCr barrier and a more neutral color in
reflection.
Table 6
Example 1 shows that the insertion of a ZnO layer between the
Zr layer and the Sn02 layer very slightly improves the behavior in the
Taber test, but most particularly it makes the behavior in the Erichsen
test similar to that of a multilayer with an NiCr barrier.
This result is surprising since in the Erichsen brush test the
multilayer of Comparative Example 2 with a Zr/SnO2 sequence
exhibited very poor adhesion.
From Example 2, it should be noted that the behavior of the
multilayers with a final Si3N4 layer is even better than that of
multilayers with an SnO2 final layer, with a better resistance to the
Erichsen stylus test and to the Taber test.
The behavior of the multilayers according to the invention in the
HC1 and HH tests at high humidity (40°C, 90% humidity, for 5 days)
was quite similar, or even slightly better, than that already obtained
with the multilayers having an NiCr-based barrier.
Example 3
This example has a multilayer comprising two silver layers with
zirconium lower barrier layers, of the type:
Si3N4 / ZnO/ Zr / Ag/ ZnO/ Si3N4 / ZnO / Zr / Ag / ZnO / Si3N4
22 / 10 / 0.5/8.2/ 10 / 69 / 10 / 0.5 / 10/ 10 / 28 nm.
The multilayer was deposited on a substrate consisting of a glass
sheet 1.6 mm in thickness.
The mechanical properties of the multilayer were measured by
means of a Taber test and by a peel test in which an adhesive tape was
applied to the multilayer, the tape was pulled off and the integrity of the
multilayer was assessed. The results of the mechanical measurements
are given in Table 7 below.
This substrate was subjected to a heat treatment of the bending
type, at above 640°C for 6 minutes, followed by air cooling, and the
optical changes after the heat treatment were determined. The substrate
had the same optical quality after the heat treatment.
This substrate was joined to a glass sheet 2.1 mm in thickness in
a laminated glazing unit using a PVB insert film 0.76 mm in thickness,
the multilayer facing toward the inside of the laminate.
The optical properties of the multilayer were measured as
previously, and the results of the optical measurements are given in
Table 8 below.
Comparative Example 3a
This comparative example is similar to Example 3 in which the
zirconium barrier layers were replaced with nickel-chromium layers. A
multilayer of the following type was obtained:
Si3N4 / ZnO/ NiCr / Ag/ ZnO/ Si3N4/ ZnO / Zr / Ag / ZnO / Si3N4
22 / 10 / 0,7 / 8,2/ 10/69 / 10 / 0,7 / 10 / 10 / 28 nm.
This substrate was subjected to the same heat treatment as in
Example 3: after the heat treatment, the substrate became hazy and
pitting was observed.
The results of the optical and mechanical measurements are given
in Tables 7 and 8.

WE CLAIM;
1. A transparent substrate provided with a thin-film multilayer
comprising at least one functional metal layer, especially a silver-based layer,
having reflection properties in the infrared and/or in the solar radiation range,
at least one metal barrier layer in contact with the functional layer and at
least one upper dielectric layer, characterized in that at least one barrier layer
is based on zirconium and in that the upper dielectric layer comprises at least
one ZnO-based layer in contact with the functional layer or with the barrier
layer.
2. The substrate as claimed in claim 1 wherein it includes, beneath the
silver, a lower barrier layer based on a metal such as titanium, nickel-
chromium, niobium, zirconium, etc.
3. The substrate as claimed in one of the preceding claims, wherein it
includes an upper mechanical protection layer based on an oxide, nitride
and/or oxynitride, especially ~SnO2, T1O2, ZnSnOx, ZnTiOX, ZnZrOx and/or
Si3N4, this upper layer being optionally doped.
4. The substrate as claimed in one of the preceding claims, wherein the
thickness of a barrier layer is less than or equal to 6 nm,in particular between
0.2 and 6 nm.
5. The substrate as claimed in any one of the preceding claims, wherein
the thickness of said functional layer is from 5 to 18 nm.
6. The substrate as claimed in any one of the preceding claims, wherein the
thickness of said dielectric layer is at least 5 nm, especially between 5 and 25
nm.
7. The substrate as claimed in one of the preceding claims wherein said
multilayer substantially retains its properties, especially optical properties, after a
heat treatment at a temperature of at least 500°C,
8. The substrate as claimed in any one of the preceding claims, wherein at least
one Zr-based barrier layer is deposited by magnetron sputtering using a
zirconium metal target that may optionally contain from 1 to 10% by weight of
an additional element such as Ca, Y, or Hf.
9. The substrate as claimed in any one of he preceding claims wherein the
multilayer includes a lower dielectric layer based on an oxide or nitride.
10. The substrate as claimed in claim 9, wherein the lower dielectric layer
comprises the sequence SnO2/TiO2/ZnO.
11. The substrate as claimed in claim 9, wherein the lower dielectric layer
comprises the sequence Si3N4/ZnO.
12. Low-emissivity or solar-protection glazing and especially laminated glazing
or double glazing, incorporating at least one substrate as claimed in any one of
the preceding claims.
13. The glazing as claimed in claim 12, wherein it comprises at least one
substrate according to the invention mounted with another substrate as double
glazing and the assembly has a light transmission of between 40 and 90%.
14. The glazing as claimed in either of claims 12 and 13 wherein it has a
selectivity defined by the ratio of the light transmission to the solar factor, TL/SF
of between 1.1 and 2.1.

A transparent substrate provided with a thin-film multilayer comprising at
least one functional metal layer, especially a silver-based layer, having reflection
properties in the infrared and/or in the solar radiation range, at least one metal
barrier layer in contact with the functional layer and at least one upper dielectric
layer, characterized in that at least one barrier layer is based on zirconium and in
that the upper dielectric layer comprises at least one ZnO-based layer in contact
with the functional layer or with the barrier layer.

Documents:

334-KOLNP-2006-FORM 27-1.1.pdf

334-KOLNP-2006-FORM 27.pdf

334-KOLNP-2006-FORM-27.pdf

334-kolnp-2006-granted-abstract.pdf

334-kolnp-2006-granted-claims.pdf

334-kolnp-2006-granted-correspondence.pdf

334-kolnp-2006-granted-description (complete).pdf

334-kolnp-2006-granted-examination report.pdf

334-kolnp-2006-granted-form 1.pdf

334-kolnp-2006-granted-form 18.pdf

334-kolnp-2006-granted-form 2.pdf

334-kolnp-2006-granted-form 3.pdf

334-kolnp-2006-granted-form 5.pdf

334-kolnp-2006-granted-gpa.pdf

334-kolnp-2006-granted-reply to examination report.pdf

334-kolnp-2006-granted-specification.pdf

334-kolnp-2006-granted-translated copy of priority document.pdf


Patent Number 234244
Indian Patent Application Number 334/KOLNP/2006
PG Journal Number 20/2009
Publication Date 15-May-2009
Grant Date 12-May-2009
Date of Filing 15-Feb-2006
Name of Patentee SAINT-GOBAIN GLASS FRANCE
Applicant Address LES MIROIRS 18 AVENUE D'ALSACE F-92400 COURBEVOIE
Inventors:
# Inventor's Name Inventor's Address
1 NADAUD NICOLAS 63 AVENUE PASTEUR F-94250 GENTILLY
2 LABROUSSE LAURENT 29-31 RUE ANATOLE FRANCE F-93120 LA COURNEUVE
3 PETIT, JEAN ERIC 29 RUE SAINTE MARTHE F-75010 PARIS
4 NADAUD NICOLAS 63 AVENUE PASTEUR F-94250 GENTILLY
5 LABROUSSE LAURENT 29-31 RUE ANATOLE FRANCE F-93120 LA COURNEUVE
6 PETIT, JEAN ERIC 29 RUE SAINTE MARTHE F-75010 PARIS
PCT International Classification Number C03C 17/36
PCT International Application Number PCT/FR2004/0002164
PCT International Filing date 2004-08-19
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 0310045 2003-08-20 France