Title of Invention	"A surface coated substrate article of insulating material and a method for the preparation of the substrate article."
Abstract	This invention relates to a surface coated substrate article of insulating material of the kind such as herein described, which is intended to afford protection from electromagnetic attacks in a corrosive environment, said substrate article comprising of a stack of two metal layers, characterized in that the first of the two said layers which is in contact with the substrate is a layer of nickel-base alloy containing 80 to 90% by weight of nickel and at least one metal of group VB of the periodic classification of elements in an amount of between 2 and 20% by weight and that the second of said two layers being a surface layer is a silver base layer or a layer based on one of its alloys.

Title of Invention

"A surface coated substrate article of insulating material and a method for the preparation of the substrate article."

Abstract

This invention relates to a surface coated substrate article of insulating material of the kind such as herein described, which is intended to afford protection from electromagnetic attacks in a corrosive environment, said substrate article comprising of a stack of two metal layers, characterized in that the first of the two said layers which is in contact with the substrate is a layer of nickel-base alloy containing 80 to 90% by weight of nickel and at least one metal of group VB of the periodic classification of elements in an amount of between 2 and 20% by weight and that the second of said two layers being a surface layer is a silver base layer or a layer based on one of its alloys.

Full Text	The present invention relates to a surface coated substrate article of insulating material and a method for the preparation of surface coated substrate article of insulating material. The present invention concerns an insulative material surface coating. To be more precise, the invention concerns a surface coating for insulative material parts designed to assure protection against electromagnetic interference in a corrosive environment. S a id i n s u 1 a t i ve ma t e r i a 1 s i n c 1 u d e p o 1 yme r rna t; e r i a 1 s and composite materials of the type including, for example, but not exclusively, a resin based on polymer material, with reinforcing fibers. One application of the present invention is the production of electromagnetic screening for electrical or electronic component cases made of polymer or composite materials. The invention is therefore equally concerned with such screened polymer or composite material vises for electrical or electronic components. Another application of the present invention is the production of a protective layer, for parts subjected to severe constraints such as corrosion, that necessitates the presence of a metal protective layer having high adhesion, regardless of the external constraints. Industrial processes for metalizing polymer material parts, in particular the so-called "wet" process and the so-called "vacuum evaporation" process, and the application of paint charged with metal particles are already known in themselves. The wet process generally consists in appropriately-preparing the surface, including steps of satin finishing and activation, followed by depositing a layer of copper-in two steps, the first using chemical conversion, the second using electrolysis. The vacuum evaporation process, very widely used in the decorative arts, consists in applying a very thin film of metal, generally aluminum, to the part to be coated by evaporation in a vacuum. Because it is thin, this film is very fragile. For this reason it is often protected by a varnish. In some cases, metalization is sometimes preceded by an activation treatment using an atmospheric plasma or in a vacuum. Finally, conductive paints, consisting of resins containing metal, for example copper, aluminum, silver, etc particles are sometimes used but have high resistivities and the thickness of the coating is not controlled with great accuracy. Technical advances and ever more demanding performance requirements means that the current solutions have reached their limits and cannot be used in many cases. In particular, new applications of electronics are leading to the use of portable equipment in more and more varied conditions, in particular outside buildings, introducing a new constraint, namely resistance to various forms of corrosion. This phenomenon can deteriorate or even destroy the metal layer, as in the case of aluminum and copper, and can also deteriorate the interface between the polymer substrate and the metal coating leading to partial or total detachment of the latter. In both cases, the electromagnetic protection of the components is no longer assured. An object of the present invention is to provide a surface coating which, whilst having excellent adhesion to plastics and composite materials, together with remarkable resistance to corrosion, especially saline corrosion, provides high quality protection against electromagnetic interference and the adhesion of which is not affected by exposure to a corrosive atmosphere. The Applicant has developed a surface coating composition for an insula Live material substrate satisfying the above object. by assuring durable electromagnetic protection, even in corrosive atmospheres. To conform to the invention, the coating must have the following features simultaneously: it is composed of two stacked layers, the more external, or surface, layer is based on metallic silver or one of its alloys, the deeper layer, between the latter and the insulative material substrate, is constituted of a nickel-based alloy containing between about 80% and 98% of nickel. According to the present invention there is provided a coated substrate article of insulating material of the kind such as herein described, which is intended to afford protection from electromagnetic attacks in a corrosive environment, said substrate article comprising of a stack of two metal layers, characterised in that the first of the two said layers which is in contact with the substrate is a layer of nickel-base alloy containing 80 to 98% by weight of nickel and at least one metal of group VB of the periodic classification of elements in an amount of between 2 and 20% by weight and that the second of said two layers being a surface layer is a silver base layer or a layer based on one of its alloys. According to the present invention there is also provided a method for the preparation of surface coated substrate article of insulating material, as claimed in claim 1 adapted to ensure protection against electromagnetic interference in corrosive environments comprising depositing in the manner such as herein described, two stacked metal layers, the first, in contact with the substrate, being a layer of nickel base alloy containing 80 to 98% by weight of nickel and at least one metal of group VB of the periodic classification of elements in an amount of between about 2 and 20% by weight, the second of said two layers being a surface layer is a layer based on metal silver or one of its alloys. The surface coating of the present invention is a coated substrate article of insulating material exhibiting improved and unexpected properties. In one preferred embodiment of the invention, the nickel-based alloy contains at least one metal from group V B in the Periodic Table of the Elements, the most usual being vanadium, in an amount between about 2% and 20% by weight. The amount of the metal from group V B from the Periodic Table of the Elements in the nickel-based alloy is advantageously between about 5% and 10% by weight. In a manner that has yet to be explained, the simultaneous properties of protection against electromagnetic interference, resistance to corrosion and adhesion are optimal when the nickel-based alloy layer and the metallic silver based layer have thicknesses between 0.02 µm and 1 µm and between 0.2 µm and 2 µm, respectively. These qualities can deteriorate if the thicknesses are greater than those indicated. For smaller thicknesses adhesion is excellent but resistance to corrosion and electromagnetic protection are insufficient. The skilled person is well aware that silver-based alloys have a higher resistivity that metallic silver. Consequently, in the case of a silver-based alloy, the thickness of the layer must be multiplied by the ratio between the resistivity of said silver-based alloy and the resistivity of metallic silver. The surface coating of the present invention is particularly advantageous and performs particularly well because, simultaneously: - it provides high quality protection against electromagnetic interference due to its excellent electrical conductivity, - it has excellent adhesion to plastics and composite materials, - it has excellent resistance to corrosion, especially saline corrosion, - its adhesion is not affected at all by exposure to the corrosive atmosphere. The two-layer surface coating of the invention can be applied by any appropriate surface treatment process or technology without its properties being affected thereby. However, in one preferred, but not exclusive, embodiment the coating of the invention is applied by a vacuum deposition technology, the best results being obtained with the cathode sputtering technique. The surface coatings of the present invention have one application in screening cases of electrical or electronic components, in particular cases of portable telephones. The non-limiting examples described hereinafter illustrate the invention. Examples In all the following examples, polymer test pieces were coated. The surface resistivity RD, also known as the resistance per unit area, and representative of the protection against electromagnetic interference, was measured first and the adhesion of the coating was assessed using the standard pull-off test involving application of an adhesive tape after criss-cross scoring. The test pieces were then subjected for 48 hours to the accelerated corrosion test known as the "salt spray" test, carried out in accordance with French standard NF C 20-711. After washing and drying them, the test pieces were again subjected to the surface resistivity and adhesion tests, using the pull-off test of French standard NF T 30-038; the final result indicated the level of protection assured by the coating and its durability. Example 1 (Comparative) A 3 µm thick layer of aluminum was deposited on a batch of five test pieces by oxygen plasma activation followed by vacuum evaporation deposition. Before the corrosion test, the mean resistivity RD was 60 mΩ⁭. The adhesion was excellent (no pull-off in the traction test). After exposure to the salt spray, the resistivity RD was 150 mΩ⁭ at the measurement points, confirmed by visual observation: the coating had been converted, at least on the surface, into insulative alumina, with a greater or lesser degree of hydration. At the same time, adhesion had become very weak, the coating pulling off easily on the adhesive tape. Example 2 (Comparative) A 5 µm thick deposit of copper was applied to a second batch of five test pieces by a conventional aqueous phase technique: satin finishing, activation, chemical copper plating, electrolytic copper plating. Before the corrosion test, the mean resistivity RD was 10 mΩ⁭ and the adhesion was excellent. After exposure to the salt spray, the appearance of the coating indicated the abundant presence of verdigris, the resistivity RD was between 20 mΩ⁭ and 80 mΩ⁭ and the adhesion could not be measured because of partial separation and flaking of the coating at many points on the test pieces. Example 3 (Comparative) A conductive paint sold by BECKER INDUSTRIE under reference 599-Y 2000 was applied to a third batch of test pieces and then polymerized in accordance with the recommendations of the manufacturer. The mean thickness of the film was 35 µm ± 10 µm. Before the corrosion test, the mean resistivity RD was 50 mΩ⁭ and adhesion was excellent as the traction test did not cause any pulling off. After corrosion, the appearance of the coating had changed little and the resistivity RD was between 320 mΩ⁭ and 450 mΩ⁭. Adhesion was partly degraded as the test showed pull-off at a few points. Example 4 A fourth batch of 15 test pieces was divided into three groups A, B and C each of five test pieces. Each batch then received a first layer of nickel alloy including 8% vanadium (layer in contact with the substrate) followed by a layer of metallic silver (surface layer), the two layers being deposited successively by cathode sputtering in a vacuum. The respective thicknesses of the layers deposited on the test pieces of the three groups were as listed in Table 1 below: Table 1 (Table Removed) The results of the surface resistivity and adhesion tests before and after corrosion are set out in Table 2 below: Table 2 (Table Removed) Note that none of the test pieces from the three groups had changed in appearance after corrosion. Adhesion was excellent as the test showed no pull-off points for groups A and B and only a few pull-off points for group C, where the thickness of the coating, probably too great, had not produced an interface of perfect quality. The resistivity RD was remarkably stable. The very low values of RD measured for groups B and C indicated an excellent level of protection; the values of RD measured for group A, although acceptable, represented a slightly lower level of performance, probably associated with the small thickness of the layers. The person skilled in the art will understand that although the invention has been described and shown by specific embodiment, many variants can be envisaged without departing from the scope of the invention as defined in the accompanying claims. We Claim:- 1. A surface coated substrate article of insulating material of the kind such as herein described, which is intended to afford protection from electromagnetic attacks in a corrosive environment, said substrate article comprising of a stack of two metal layers, characterised in that the first of the two said layers which is in contact with the substrate is a layer of nickel-base alloy containing 80 to 98% by weight of nickel and at least one metal of group VB of the periodic classification of elements in an amount of between 2 and 20% by weight and that the second of said two layers being a surface layer is a silver base layer or a layer based on one of its alloys. 2. An article as claimed in claim 1, wherein the amount of element of group VB of the periodic classification of elements in the nickel-base alloy is between 5 and 10% by weight. 3. An article as claimed in claims 1 and 2, wherein the element of group VB of the periodic classification of elements is vanadium. 4. An article as claimed in any one of claims 1 to 3, wherein the thickness of the layer of nickel-base alloy is between 0.02 and 1 micrometer. 5. An article as claimed in any one of claims 1 to 4, wherein the surface layer based on metal silver, and the thickness of the layer based on said metal silver is between 0.2 and 2 micrometers. 6. An article as claimed in any one of claims 1 to 4 wherein the surface layer is a silver-base alloy, and the thickness of the silver base-alloy layer is between n x (0.2 and 2 micrometers), 'n' being the value of the ratio between the resistivity of the silver-base alloy and the resistivity of the metal silver. 7. An article as claimed in any one of claims 1 to 6 wherein the insulating material is selected from polymer materials of the kind such as herein described and composite materials. 8. An article as claimed in claim 7 wherein the composite material is formed by a polymer and reinforcing fibres. 9. A method for the preparation of surface coated substrate article of insulating material, as claimed in claim 1 adapted to ensure protection against electromagnetic interference in corrosive environments comprising depositing in the manner such as herein described, two stacked metal layers, the first, in contact with the substrate, being a layer of nickel base alloy containing 80 to 98% by weight of nickel and at least one metal of group VB of the periodic classification of elements in an amount of between about 2 and 20% by weight, the second of said two layers being a surface layer is a layer based on metal silver or one of its alloys. 10. A method as claimed in claim 9 wherein the nickel-base alloy layer and the silver-base surface layer are produced by vacuum deposition technology. 11. A method as claimed in claim 9 wherein the vacuum deposition technology is cathode sputtering. 12. A method as claimed in claim 9 wherein first a layer based on nickel alloy is applied on said substrate followed by a second silver -base layer, two layers being deposited successively by cathode sputtering in vacuum. 13. A surface coated substrate article of insulating material substantially as herein described with reference to the foregoing examples. 14. A method for the preparation of surface coated substrate article of insulating material as claimed in claim 1 substantially as herein described with reference to the foregoing examples.

Full Text

The present invention relates to a surface coated substrate article of insulating material and a method for the preparation of surface coated substrate article of insulating material.
The present invention concerns an insulative material surface coating. To be more precise, the invention concerns a surface coating for insulative material parts designed to assure protection against electromagnetic interference in a corrosive environment.
S a id i n s u 1 a t i ve ma t e r i a 1 s i n c 1 u d e p o 1 yme r rna t; e r i a 1 s and composite materials of the type including, for example, but not exclusively, a resin based on polymer material, with reinforcing fibers.
One application of the present invention is the production of electromagnetic screening for electrical or electronic component cases made of polymer or composite materials. The invention is therefore equally concerned with such screened polymer or composite material vises for electrical or electronic components.
Another application of the present invention is the production of a protective layer, for parts subjected to severe constraints such as corrosion, that necessitates the presence of a metal protective layer having high adhesion, regardless of the external constraints.
Industrial processes for metalizing polymer material parts, in particular the so-called "wet" process and the so-called "vacuum evaporation" process, and the application of paint charged with metal particles are already known in themselves.
The wet process generally consists in appropriately-preparing the surface, including steps of satin finishing and activation, followed by depositing a layer of copper-in two steps, the first using chemical conversion, the second using electrolysis.
The vacuum evaporation process, very widely used in the decorative arts, consists in applying a very thin

film of metal, generally aluminum, to the part to be coated by evaporation in a vacuum. Because it is thin, this film is very fragile. For this reason it is often protected by a varnish.
In some cases, metalization is sometimes preceded by an activation treatment using an atmospheric plasma or in a vacuum.
Finally, conductive paints, consisting of resins containing metal, for example copper, aluminum, silver, etc particles are sometimes used but have high resistivities and the thickness of the coating is not controlled with great accuracy.
Technical advances and ever more demanding performance requirements means that the current solutions have reached their limits and cannot be used in many cases.
In particular, new applications of electronics are leading to the use of portable equipment in more and more varied conditions, in particular outside buildings, introducing a new constraint, namely resistance to various forms of corrosion. This phenomenon can deteriorate or even destroy the metal layer, as in the case of aluminum and copper, and can also deteriorate the interface between the polymer substrate and the metal coating leading to partial or total detachment of the latter. In both cases, the electromagnetic protection of the components is no longer assured.
An object of the present invention is to provide a surface coating which, whilst having excellent adhesion to plastics and composite materials, together with remarkable resistance to corrosion, especially saline corrosion, provides high quality protection against electromagnetic interference and the adhesion of which is not affected by exposure to a corrosive atmosphere.

The Applicant has developed a surface coating composition for an insula Live material substrate satisfying the above object. by assuring durable electromagnetic protection, even in corrosive atmospheres.
To conform to the invention, the coating must have the following features simultaneously: it is composed of two stacked layers, the more external, or surface, layer is based on metallic silver or one of its alloys, the deeper layer, between the latter and the insulative material substrate, is constituted of a nickel-based alloy containing between about 80% and 98% of nickel.
According to the present invention there is provided a coated substrate article of insulating material of the kind such as herein described, which is intended to afford protection from electromagnetic attacks in a corrosive environment, said substrate article comprising of a stack of two metal layers, characterised in that the first of the two said layers which is in contact with the substrate is a layer of nickel-base alloy containing 80 to 98% by weight of nickel and at least one metal of group VB of the periodic classification of elements in an amount of between 2 and 20% by weight and that the second of said two layers being a surface layer is a silver base layer or a layer based on one of its alloys.
According to the present invention there is also provided a method for the preparation of surface coated substrate article of insulating material, as claimed in claim 1 adapted to ensure protection against electromagnetic interference in corrosive environments comprising depositing in the manner such as herein described, two stacked metal layers, the first, in contact with the substrate, being a layer of nickel base alloy containing 80 to 98% by weight of nickel and at least one metal of group VB of the periodic classification of elements in an amount of between about 2 and 20% by weight, the second of said two layers being a surface layer is a layer based on metal silver or one of its alloys.
The surface coating of the present invention is a coated substrate article of insulating material exhibiting improved and unexpected properties.

In one preferred embodiment of the invention, the nickel-based alloy contains at least one metal from group V B in the Periodic Table of the Elements, the most usual being vanadium, in an amount between about 2% and 20% by weight. The amount of the metal from group V B from the Periodic Table of the Elements in the nickel-based alloy is advantageously between about 5% and 10% by weight.
In a manner that has yet to be explained, the simultaneous properties of protection against electromagnetic interference, resistance to corrosion and adhesion are optimal when the nickel-based alloy layer and the metallic silver based layer have thicknesses between 0.02 µm and 1 µm and between 0.2 µm and 2 µm, respectively. These qualities can deteriorate if the thicknesses are greater than those indicated. For smaller thicknesses adhesion is excellent but resistance to corrosion and electromagnetic protection are insufficient.
The skilled person is well aware that silver-based alloys have a higher resistivity that metallic silver. Consequently, in the case of a silver-based alloy, the thickness of the layer must be multiplied by the ratio

between the resistivity of said silver-based alloy and the resistivity of metallic silver.
The surface coating of the present invention is particularly advantageous and performs particularly well because, simultaneously:
- it provides high quality protection against electromagnetic interference due to its excellent electrical conductivity,
- it has excellent adhesion to plastics and composite materials,
- it has excellent resistance to corrosion, especially saline corrosion,
- its adhesion is not affected at all by exposure to the corrosive atmosphere.
The two-layer surface coating of the invention can be applied by any appropriate surface treatment process or technology without its properties being affected thereby. However, in one preferred, but not exclusive, embodiment the coating of the invention is applied by a vacuum deposition technology, the best results being obtained with the cathode sputtering technique.
The surface coatings of the present invention have one application in screening cases of electrical or electronic components, in particular cases of portable telephones.
The non-limiting examples described hereinafter illustrate the invention. Examples
In all the following examples, polymer test pieces were coated. The surface resistivity RD, also known as the resistance per unit area, and representative of the protection against electromagnetic interference, was measured first and the adhesion of the coating was assessed using the standard pull-off test involving application of an adhesive tape after criss-cross

scoring. The test pieces were then subjected for 48 hours to the accelerated corrosion test known as the "salt spray" test, carried out in accordance with French standard NF C 20-711. After washing and drying them, the test pieces were again subjected to the surface resistivity and adhesion tests, using the pull-off test of French standard NF T 30-038; the final result indicated the level of protection assured by the coating and its durability.
Example 1 (Comparative)
A 3 µm thick layer of aluminum was deposited on a batch of five test pieces by oxygen plasma activation followed by vacuum evaporation deposition.
Before the corrosion test, the mean resistivity RD was 60 mΩ⁭. The adhesion was excellent (no pull-off in the traction test). After exposure to the salt spray, the resistivity RD was 150 mΩ⁭ at the measurement points, confirmed by visual observation: the coating had been converted, at least on the surface, into insulative alumina, with a greater or lesser degree of hydration. At the same time, adhesion had become very weak, the coating pulling off easily on the adhesive tape.
Example 2 (Comparative)
A 5 µm thick deposit of copper was applied to a second batch of five test pieces by a conventional aqueous phase technique: satin finishing, activation, chemical copper plating, electrolytic copper plating.
Before the corrosion test, the mean resistivity RD was 10 mΩ⁭ and the adhesion was excellent.
After exposure to the salt spray, the appearance of the coating indicated the abundant presence of verdigris, the resistivity RD was between 20 mΩ⁭ and 80 mΩ⁭ and the adhesion could not be measured because of partial separation and flaking of the coating at many points on the test pieces.

Example 3 (Comparative)
A conductive paint sold by BECKER INDUSTRIE under reference 599-Y 2000 was applied to a third batch of test pieces and then polymerized in accordance with the recommendations of the manufacturer. The mean thickness of the film was 35 µm ± 10 µm.
Before the corrosion test, the mean resistivity RD was 50 mΩ⁭ and adhesion was excellent as the traction test did not cause any pulling off. After corrosion, the appearance of the coating had changed little and the resistivity RD was between 320 mΩ⁭ and 450 mΩ⁭. Adhesion was partly degraded as the test showed pull-off at a few points.
Example 4
A fourth batch of 15 test pieces was divided into three groups A, B and C each of five test pieces. Each batch then received a first layer of nickel alloy including 8% vanadium (layer in contact with the substrate) followed by a layer of metallic silver (surface layer), the two layers being deposited successively by cathode sputtering in a vacuum.
The respective thicknesses of the layers deposited on the test pieces of the three groups were as listed in Table 1 below:
Table 1

(Table Removed)
The results of the surface resistivity and adhesion tests before and after corrosion are set out in Table 2 below:
Table 2

(Table Removed)
Note that none of the test pieces from the three groups had changed in appearance after corrosion. Adhesion was excellent as the test showed no pull-off points for groups A and B and only a few pull-off points for group C, where the thickness of the coating, probably too great, had not produced an interface of perfect quality. The resistivity RD was remarkably stable. The very low values of RD measured for groups B and C indicated an excellent level of protection; the values of RD measured for group A, although acceptable, represented a slightly lower level of performance, probably associated with the small thickness of the layers.
The person skilled in the art will understand that although the invention has been described and shown by specific embodiment, many variants can be envisaged without departing from the scope of the invention as defined in the accompanying claims.

We Claim:-
1. A surface coated substrate article of insulating material of the kind such as herein described, which is intended to afford protection from electromagnetic attacks in a corrosive environment, said substrate article comprising of a stack of two metal layers, characterised in that the first of the two said layers which is in contact with the substrate is a layer of nickel-base alloy containing 80 to 98% by weight of nickel and at least one metal of group VB of the periodic classification of elements in an amount of between 2 and 20% by weight and that the second of said two layers being a surface layer is a silver base layer or a layer based on one of its alloys.
2. An article as claimed in claim 1, wherein the amount of element of group VB of the periodic classification of elements in the nickel-base alloy is between 5 and 10% by weight.
3. An article as claimed in claims 1 and 2, wherein the element of group VB of the periodic classification of elements is vanadium.
4. An article as claimed in any one of claims 1 to 3, wherein the thickness of the layer of nickel-base alloy is between 0.02 and 1 micrometer.
5. An article as claimed in any one of claims 1 to 4, wherein the surface layer based on metal silver, and the thickness of the layer based on said metal silver is between 0.2 and 2 micrometers.
6. An article as claimed in any one of claims 1 to 4 wherein the surface layer is a silver-base alloy, and the thickness of the silver base-alloy layer is between n x (0.2 and 2 micrometers), 'n' being

the value of the ratio between the resistivity of the silver-base alloy and the resistivity of the metal silver.
7. An article as claimed in any one of claims 1 to 6 wherein the insulating material is selected from polymer materials of the kind such as herein described and composite materials.
8. An article as claimed in claim 7 wherein the composite material is formed by a polymer and reinforcing fibres.
9. A method for the preparation of surface coated substrate article of insulating material, as claimed in claim 1 adapted to ensure protection against electromagnetic interference in corrosive environments comprising depositing in the manner such as herein described, two stacked metal layers, the first, in contact with the substrate, being a layer of nickel base alloy containing 80 to 98% by weight of nickel and at least one metal of group VB of the periodic classification of elements in an amount of between about 2 and 20% by weight, the second of said two layers being a surface layer is a layer based on metal silver or one of its alloys.
10. A method as claimed in claim 9 wherein the nickel-base alloy layer and the silver-base surface layer are produced by vacuum deposition technology.
11. A method as claimed in claim 9 wherein the vacuum deposition technology is cathode sputtering.
12. A method as claimed in claim 9 wherein first a layer based on nickel alloy is applied on said substrate followed by a second silver -base layer, two layers being deposited successively by cathode sputtering in vacuum.

13. A surface coated substrate article of insulating material substantially as herein described with reference to the foregoing examples.
14. A method for the preparation of surface coated substrate article of insulating material as claimed in claim 1 substantially as herein described with reference to the foregoing examples.

Documents:

2693-del-1997-abstract.pdf

2693-DEL-1997-Assignment-(08-08-2011).pdf

2693-del-1997-claims.pdf

2693-del-1997-complete specification (granted).pdf

2693-DEL-1997-Correspondence Others-(08-08-2011).pdf

2693-del-1997-correspondence-others.pdf

2693-del-1997-correspondence-po.pdf

2693-del-1997-description (complete).pdf

2693-del-1997-form-1.pdf

2693-del-1997-form-13.pdf

2693-DEL-1997-Form-16-(08-08-2011).pdf

2693-del-1997-form-19.pdf

2693-del-1997-form-2.pdf

2693-del-1997-form-3.pdf

2693-del-1997-form-4.pdf

2693-del-1997-form-6.pdf

2693-DEL-1997-GPA-(08-08-2011).pdf

2693-del-1997-gpa.pdf

2693-del-1997-petition-137.pdf

2693-del-1997-petition-138.pdf

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Patent Number

195243

Indian Patent Application Number

2693/DEL/1997

PG Journal Number

38/2008

Publication Date

19-Sep-2008

Grant Date

08-Dec-2006

Date of Filing

23-Sep-1997

Name of Patentee

Tecmachine

Applicant Address

Rue Benoit-Fourneyron, Zone Industrielle Sud, 42160 Andrezieux-Boutheon, France.

Inventors:

#	Inventor's Name	Inventor's Address
1	Chiristophe Heau	22 Rue Voltaire, 42100, Saint-Etienne,FRANCE.
2	Paul Berger	24, Rue Gabriel Peri, 42490 Fraisses.

PCT International Classification Number

C23C 28/02

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	96 11724	1996-09-26	France