Title of Invention

A METHOD OF PRODUCING A METAL COMPOSITE FOR AN ELECTROCHEMICAL DEVICE

Abstract A metal composite for use in electrochemical devices is disclosed. The metal composite comprises a stainless steel interior component and a nitrided metal exterior layer comprises nitrogen or deposited in a nitrogen atmosphere, wherein the nitrided exterior layer has lower electric contact resistance and greater corrosion resistance than the stainless steel interior component.
Full Text TECHNICAL FIELD
The disclosed embodiments generally relate to metal
composites having high corrosion resistance and low electric contact
resistance for use in electrochemical devices such as fuel cells and batteries.
BACKGROUND
Electrochemical devices such as fuel cells and batteries typically
involve corrosive electrochemical reactions and high electric current flow.
Some of the key components of such electrochemical devices require high
corrosion resistance and very low electric resistance for long product life and
minimal energy loss. Bipolar plates in a polymer electrolyte membrane
(PEM) fuel cell, for example, must be cost effective, electrochemically stable,
electrically conductive, hydrophilic, and stampable. Sophisticated designs
with flow channels on both sides of the plate can be formed by a metal
stamping process. Stainless steels posses some of those desirable
characteristics including low cost and stampability. The presence of the
passive oxide film on the surface of stainless steel, however, creates an
extensive contact resistance with the gas diffusion medium. In addition,
typical stainless steels do not have the corrosion resistance required for a
bipolar plate in a demanding fuel cell. Corrosion of a bipolar plate also results
in metal ion contamination that adversely affects the performance of a fuel
cell. A conductive coating of noble metals, such as gold, has been used to


minimize the electric contact resistance of the stainless steel. Noble metal
coating adds significantly to the cost of the bipolar plate. Thermal nitriding of
certain types of stainless steel has also been disclosed. Relatively expensive
types of stainless steel are required in order to achieve the desired corrosion
resistance and low electric contact resistance. The thermal nitriding process
inherently generates a non-uniform and heterogeneous surface layer.
Desired consistency and reliability may be difficult to achieve in large volume
production using a thermal nitriding process. There is thus a need for a low
cost, highly corrosion resistant, and highly conductive material for
electrochemical devices.
SUMMARY OF EXEMPLARY EMBODIMENTS OF THE INVENTION
One embodiment of the invention includes a metal composite
comprising a low cost stainless steel interior component and a deposited
nitrided metal exterior layer. The nitrided exterior layer has lower electric
contact resistance and greater corrosion resistance than the stainless steel
interior component. The nitrided exterior layer may be deposited on the
stainless steel interior component using various metal coating/surface
deposition methods including sputtering method to form a highly consistent,
conductive and corrosion resistant surface layer.
In another embodiment, a bipolar plate for use in an
electrochemical fuel cell comprises a stainless steel sheet material having a
plurality of channels on at least one side and a deposited nitrided metal layer
covering substantially the exterior surface of the stainless steel sheet. The
nitrided metal has greater corrosion resistance and lower electric contact

resistance than the stainless steel. The channels on the stainless steel sheet
may be created by a conventional stamping process.
Other exemplary embodiments of the present invention will
become apparent from the detailed description provided hereinafter. It should
be understood that the detailed description and specific examples, while
disclosing exemplary embodiments of the invention, are intended for purposes
of illustration only and are not intended to limit the scope of the invention.
BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS
Exemplary embodiments of the present invention will become
more fully understood from the detailed description and the accompanying
drawings, wherein:
Figure 1 is a graph showing potentiodynamic polarization curves
of Hastelloy G-35 alloy and the corresponding thermally nitrided G-35 alloy.
Figure 2 is a graph showing potentiodynamic polarization curves
of Hastelloy G-30 alloy and the corresponding thermally nitrided G-30 alloy.
Figure 3 is a graph showing potentiostatic current transients of
Hastelloy G-35 alloy and the corresponding thermally nitrided G-35 alloy.
Figure 4 is a graph showing potentiostatic current transients of
Hastelloy G-30 alloy and the corresponding thermally nitrided G-30 alloy.
Figure 5 is a graph showing the plot of a fuel cell's voltage and
current density versus operating time. The fuel cell is a single unit fuel cell
made of thermally nitrided Hastelloy G-35 alloy as the bipolar plate and a
Gore 5051 membrane electrode assembly operating at 80°C.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS
The following description of the embodiment(s) is merely
exemplary in nature and is in no way intended to limit the invention, its
application, or uses.
A metal composite with high corrosion resistance and low
electric contact resistance is provided. The metal composite comprises a
stainless steel interior component and a deposited nitrided metal exterior
layer. The stainless steel interior component is typically a low cost metal
alloy, and may not have the corrosion resistance or electric contact resistance
required for use in a demanding electrochemical device. The deposited
nitrided metal exterior layer strongly adheres to the stainless steel component,
and typically covers substantially the surface of the stainless steel. The
nitrided metal layer exhibits higher corrosion resistance and lower electric
contact resistance than the stainless steel component.
Many different types of stainless steels can be used according
to this invention. Typical stainless steels comprise at least 50% iron and at
least 10% chromium by weight. The stainless steels may also include ferrite
and austenite depending on their crystal structures and composition. It is
preferred to use low cost stainless steels that can be easily made into thin
sheets which can be stamped to form complicated channels. Stainless steels
having higher electric conductivity and corrosion resistance are also preferred.
In one embodiment, stainless steel having chromium content of at least 16%
by weight is used. The stainless steel may also contain at least 6% nickel.
Exemplary stainless steels may have nickel content of between 6-20% and
chromium content of about 16% to about 20%. The stainless steel

component may also include molybdenum which can further increase the
corrosion resistance. In one embodiment, AISI type 304 and type 316 are
used. The chemical composition of type 304 and type 316 are provided in
Table 1 and Table 2 respectively:

Although the stainless steel may be used in various forms
including rod, wire, screw, slab, tube, ball, foam, and other complex shapes,
stainless steel sheets are typically used. The sheet may be further processed
into other shapes. In one embodiment, the stainless steel sheet is stamped to
form a plurality of channels on at least one side. The plurality of channels can
be used to direct gas or other fluids that flow through an electrochemical
device. The channels may also be formed by etching, or other methods
known to one of ordinary skill in the art.
A nitrided metal layer is deposited on the stainless steel
component described above. The term "metal" here includes single
component metal consisting of only one chemical element, metal alloys
comprising 2 or more different chemical elements, and metal mixtures thereof.
The nitrided metal is preferably deposited as substantially uniform layers with
a thickness range from about 1 nm to about 10 µm. The nitrided metal layer

has higher corrosion resistance and lower electric contact resistance than the
stainless steel component.
The nitrided metal may be selected from metals comprising 0 to
50% iron by weight. The nitrided metal may comprise at least one metal
element that favors the formation of a nitride. The nitride forming elements
according to the invention include, but are not limited to, aluminum, chromium,
tungsten, molybdenum, vanadium, titanium, niobium, tantalum, and zirconium.
The nitrided metal may further comprise manganese and/or cobalt for better
stabilization of the nitride. The nitrided metal preferably comprises greater
than about 20% chromium and less than about 20% iron. In one embodiment,
the nitrided metal is a nickel alloy comprising at least 40% nickel and at least
20% chromium. In another embodiment, the nitrided metal further comprises
molybdenum at 1% or greater. Examples of such nitrided metals include
nitrided products of Hastelloy G-30 and G-35 alloy. The chemical
compositions of Hastelloy G-30 and G-35 are provided in Table 3.

Any nitriding processes known to one of ordinary skill in the art
may be used according to this invention. Nitridation is generally conducted at
a temperature in the range of 800°C to 1200°C in pure nitrogen or 96%
nitrogen-4% hydrogen mixtures, although a temperature as low as 400°C in
ammonia environments is also suitable. There is no need to remove the
passive oxide layer of the stainless steel before nitridation. Nitridation
typically involves diffusion of nitrogen into metal and metal alloys at elevated

temperatures and in controlled atmosphere to form nitrides on the surface of
the metal and inside the metal. The controlled atmosphere for nitridation may
include one or more of nitrogen gas, ammonia, hydrogen gas, or inert gases.
A plasma assisted nitriding process can also be used at relatively low
temperatures. Non-limiting examples of nitriding processes include Floe
process, salt bath nitriding process, ion nitriding process, plasma assisted
nitriding process, oxynitride process, ferritic nitrocarburizing process, and
derivatized or combination processes thereof.
The nitrided metal can be deposited on the stainless steel
interior component by various metal surface deposition or coating methods
including, but not limited to, sputtering, ion plating, ion implanting, thermal
spray coating, or vacuum coating. Detailed descriptions of the above
methods and other similar methods can be found in Metals Handbook, 9th
Edition, volume 5, "Surface cleaning, Finishing, and Coating." In comparison
with thermal nitriding surface treatment, the deposition method affords a
broader selection of metal materials, a more uniform layer of nitrided layer,
and better consistency.
A sputtering method is preferably used to deposit the nitrided
metal layer. Sputtering is a process wherein material is ejected from the
surface of a solid or liquid because of the momentum exchange associated
with bombardment by energetic particles. The bombarding species are
generally ions of a heavy inert gas. Argon is commonly used as the inert gas.
The source of ions may be an ion beam or a plasma discharge into which the
material to be bombarded is immersed. In the plasma-discharging sputter
coating process, a source of coating materials called target (nitrided metal or

metal to be nitrided and coated) is placed into a vacuum chamber which is
evacuated and then backfilled with a working gas, such as argon or nitrogen
containing gas or gas mixture. The gas pressure is adjusted to a level to
sustain plasma discharge. A negative bias is then applied to the target so that
it is bombarded by positive ions from the plasma. The sputter coating
chamber is typically evacuated to pressures ranging from 10-3 to 10-5 Pascal
before backfilling with argon to a pressure of 0.1 to 10 Pascal. The intensity
of the plasma discharge, and thus the ion flux and sputtering rate that can be
achieved, depend on the shape of the cathode electrode, and on the effective
use of a magnetic field to confine the plasma electrons. Simple planar
electrode and other electrode configurations can be used in such sputtering
method. Compared with thermal nitriding and other surface processes,
sputtering can be consistently done at low temperatures, for example less
than 100°C.
In one embodiment, an un-nitrided metal is used as the coating
or surface deposition starting material (or target if sputtering method is used).
The un-nitrided metal has essentially the same composition as the deposited
nitrided metal layer described previously in this disclosure except that nitrogen
has not been incorporated into the metal. The surface coating/deposition is
conducted in a nitrogen containing gas atmosphere such that the un-nitrided
metal reacts with the nitrogen atmosphere to form the corresponding nitrided
metal before depositing on the stainless steel substrate. In other words,
nitriding and surface coating can be achieved in a single operation. In a non-
limiting example, an un-nitrided metal starting material is used as the target in
a sputtering process. Nitrogen, ammonia, or ammonia/hydrogen mixture is

used as the working gas. The stainless steel interior component is used as
the substrate. The un-nitrided metal target is then converted into nitrided
metal during a sputtering process by reacting with the nitrogen containing
working gas before depositing on the stainless steel substrate as a nitrided
metal layer.
In another embodiment, a nitrided metal is used as the target in
a sputtering process. The working gas is argon or another inert gas. The
nitrided metal is deposited on the stainless steel substrate with virtually no
chemical reaction with the working gas.
A post-treatment may be used after the deposition of the nitrided
metal layer on the stainless steel interior component. Exemplary post-
treatments include, but are not limited to, post-oxidation, additional thermal
nitriding treatment, thermal treatment, annealing, carbiding, polishing,
cleaning, polishing, etching and the like.
The metal composite according to this invention can be used as
various parts or components in electrochemical devices such as batteries and
fuel cells. The metal composite can be used as fitting materials, connecting
tubes, and wall materials for the electrochemical cell chamber. The metal
composite can be used as an electric coupling/connecting component that
may come in contact with corrosive gas or liquid. The metal composite is
particularly useful as the material for a bipolar plate in an electrochemical fuel
cell due to its high corrosion resistance, low cost, and low electric contact
resistance. To make a bipolar plate, a low cost stainless steel sheet interior
component is first selected as described previously in this disclosure. A
plurality of channels are created on such stainless steel sheet by stamping or

another suitable method. The channels serve as the flow fields for the fuel
gas and oxidant gas used in the fuel cell. A nitrided metal layer is deposited
on the surface of the stainless steel sheet using sputtering or one of the other
methods described previously in this disclosure. A bipolar plate made
according to this invention can be used in a PEM fuel cell where a
perfluorinated polymer electrolyte is used. The perfluorinated polymer
electrolyte contains a significant amount of acid and a small amount of highly
corrosive fluoride ion. In addition, a PEM fuel cell generally operates at
elevated temperatures to provide high current density and efficiency. As a
result, the bipolar plate must be highly resistant to corrosion in high acid, high
temperature, and fluoride ion environment. The metal composite according to
this invention exhibits all the desired characteristics as a bipolar plate for PEM
fuel cells.
An electrochemical fuel cell can be manufactured using the
metal composite described above as the bipolar plate. An electrochemical
fuel cell, especially a PEM fuel cell, is typically produced by stacking a
plurality of electrode assemblies and bipolar plates in an alternating manner.
The electrode assembly may comprise an anode and a cathode that are
respectively disposed on opposing sides of a membrane electrolyte. Such an
electrode assembly is commonly referred to as membrane electrode
assembly (MEA) in the technical field. The electrode assembly and metal
composite bipolar plate are joined together in an alternating manner to form a
fuel cell stack. A method of joining electrode assemblies and bipolar plates to
form electrochemical fuel cells is further described in D. A. Landsman and F.
J. Luczak, "Handbook of Fuel cells", John Wiley and Sons (2003).

Example 1: Corrosion resistance and electric contact resistance
of nitrided and un-nitrided alloys.
Ex-situ corrosion experiments were conducted in a relatively
harsh environment typically encountered inside PEM fuel cells under cyclic
conditions of relative humidity, for example, between 40 to 100% RH. Both
thermally nitrided and un-nitrided Hastelloy G-30 and G-35 alloys were tested
in a de-aerated simulated fuel cell solution containing 10 ppm hydrogen
fluoride (HF) at pH of 3 at 80°C.
Potentiodynamic polarization curves of alloy G-35 and G-30
were obtained and are shown in FIG. 1 and FIG. 2 respectively. Both nitrided
G-35 and G-30 alloys have lower current density by one order of magnitude
than their corresponding un-nitrided coupons over the tested range of
electrode potential. Lower current density in the potentiodynamic polarization
test indicates lower rate of corrosion.
Potentiostatic current transients were also obtained on thermally
nitrided and un-nitrided G-35 and G-30 alloys at +0.6V (versus silver/silver
chloride, Ag/AgCI, standard reference electrode) in argon purged simulated
fuel cell solution containing 10 ppm HF at pH of 3 at 80°C, as shown in FIG. 3
and FIG. 4. The potentiostatic testing condition is similar to the corrosion
environment near a PEM fuel cell cathode. Both the nitrided G-35 and G-30
alloys exhibited significantly lower current densities than their corresponding
un-nitrided coupons. Again, lower current density indicates lower corrosion
rate.
Electric contact resistance (ECR) of the metal samples before
and after the potentiostatic test was also measured. The sample contact

resistances were measured before and after the corrosion experiments using
a four-probe technique. According to this method, the sample is sandwiched
between two pieces of diffusion medium (DM), which in turn are sandwiched
between two gold-plated copper electrodes. The sample is subjected to
various compression pressures using a hydraulic press. A 1 A/cm2 current
density is then applied and the voltage drop is measured across the diffusion
media or from DM-to-sample. Thus, the contact resistance at the stainless
steel/DM interface can be measured at "stack" compression pressures.
The results are summarized in Table 3. As shown in Table 3,
the nitrided G-30 and G-35 alloys have much lower electric contact resistance
than their corresponding un-nitrided alloys. Additionally, nitrided alloys
showed very little change in ECR after the corrosion test while ECR of un-
nitrided alloys increased significantly under the same condition.

The above experiments demonstrate that a nitrided alloy has
higher corrosion resistance and lower electric contact resistance than its
corresponding un-nitrided alloy. The nitrided alloys would be suitable as the
exterior layer of a polar plate in a fuel cell.
Example 2: Electrochemical fuel cell having a nitrided alloy
bipolar plate.

Single fuel cell tests were carried out on machined and thermally
nitrided G-35 (anode and cathode) metallic plates. A Global Tech. test station
controlled by Scribner software was used to control the fuel cell potential
and/or the current. A Gore 5051 membrane electrode assembly (MEA) with a
25 µm thickness and a 0.4 mg cm-2 (each side) platinum loading was used.
The experiments were done using hydrogen and air at a pressure of 25 psig,
cyclic relative humidity and at a temperature of 80°C.
Nearly 900 durability hours were collected on the nitrided G-35
alloy with little change in cell voltage or current density as shown in FIG. 5.
The results indicate that such nitrided alloys as an exterior layer for a bipolar
plate would function very well in a fuel cell. Furthermore, ICP (Inductively
Coupled Plasma) metal analysis of the product water collected from the fuel
cell showed below detection limit values for the total metal ion contaminants.
The ICP result further confirmed the robustness of the nitrided alloy as an
exterior layer of a bipolar plate.
Example 3: Metal Composite Bipolar Plate.
An AISI type 304 stainless steel sheet of 100 µm thick is
stamped to create straight gas flow channels. A Hastelloy G-35 alloy plate is
thermally nitrided in nitrogen gas or in a nitrogen/hydrogen gas mixture at
about 1000 - 1200°C for about 2 - 8 hours. The stamped stainless steel as a
substrate and the nitrided G-35 alloy foil as a target are placed in a sputtering
chamber. The chamber is evacuated to about 10"5 Pascal pressure, and
backfilled with inert argon gas to about 0.1 to 10 Pascal pressure. Stable
plasma is generated in the chamber. A negative bias is then applied to the
nitrided G-35 alloy target to initiate the sputtering process. A relatively

uniform layer of nitrided G-35 alloy of about 1 nm to about 3 µm is deposited
on the outer surface of the stainless steel depending on the sputtering time.
Thus a metal composite bipolar plate comprising a low cost stainless steel
interior component and a nitrided alloy exterior layer is obtained. The bipolar
plate can be then integrated with MEAs to form a single fuel cell unit and
multiple fuel cell stack.
Hastelloy G-30 has a composition including 28-31.5% Cr, 43%
Ni, and 13-17% Fe by weight percent. Hastelloy G-35 has a composition
including 33.2% Cr, 58% Ni and stainless steel has a composition including 18-20% Cr, 8-10.5% Ni and 60%
Fe by weight percent. AISI type 316 stainless steel has a composition
including 16-18% Cr, 10-14% Ni and 60% Fe by weight percent.
The above description of embodiments of the invention is merely
exemplary in nature and, thus, variations thereof are not to be regarded as a
departure from the spirit and scope of the invention.

WE CLAIM
1. A method of producing a metal composite for an electrochemical device
comprising:
providing a stainless steel component wherein the stainless steel is type
304 or type 316;
forming a plurality of channels in said stainless steel component;
providing a metal alloy comprising 43 wt. percent Ni, less than 5 wt.
percent Co, 28-31.5 wt. percent Cr, 4-6, wt. percent Mo, 1.5-4.0 wt.
percent W, 13-17 wt. percent Fe.;
placing said stainless steel component and said metal alloy in an inert gas
or a nitrogen gas containing atmosphere; and
depositing said metal alloy on an exterior surface of said stainless steel
component to form a nitrided alloy exterior layer by sputtering, ion
plating, ion implanting, chemical vapor deposition, plasma assisted metal
deposition, or thermal spray coating, wherein the metal alloy comprises
nitrogen or the depositing is conducted in a nitrogen atmosphere, and
wherein the nitrided alloy exterior layer has a lower electrical contact
resistance and a greater corrosion resistance than the stainless steel
component.
2. A method of producing a metal composite for an electrochemical device
comprising:

providing a stainless steel component wherein the stainless steel is type
304 or type 316;
having a plurality of channels formed in said stainless steel component;
providing a metal alloy comprising 58 wt. percent NI, 33.2 wt. percent Cr,
8.1 wt. percent Mo.;
placing said stainless steel component and said metal alloy in an inert gas
or a nitrogen gas containing atmosphere; and
depositing said metal alloy on an exterior surface of said stainless steel
component to form a nitrided alloy exterior layer by sputtering, ion
plating, ion implanting, chemical vapor deposition, plasma assisted metal
deposition, or thermal spray coating, wherein the metal alloy comprises
nitrogen or the depositing is conducted in a nitrogen atmosphere, and
wherein the nitrided alloy exterior layer has a lower electrical contact
resistance and a greater corrosion resistance than the stainless steel
component.


ABSTRACT

TITLE : "A METHOD OF PRODUCING A METAL COMPOSITE FOR AN
ELECTROCHEMICAL DEVICE"
A metal composite for use in electrochemical devices is disclosed. The metal
composite comprises a stainless steel interior component and a nitrided metal
exterior layer comprises nitrogen or deposited in a nitrogen atmosphere, wherein
the nitrided exterior layer has lower electric contact resistance and greater
corrosion resistance than the stainless steel interior component.

Documents:

2214-KOL-2008-(09-05-2012)-ABSTRACT.pdf

2214-KOL-2008-(09-05-2012)-AMANDED CLAIMS.pdf

2214-KOL-2008-(09-05-2012)-DESCRIPTION (COMPLETE).pdf

2214-KOL-2008-(09-05-2012)-DRAWINGS.pdf

2214-KOL-2008-(09-05-2012)-EXAMINATION REPORT REPLY RECEIVED.pdf

2214-KOL-2008-(09-05-2012)-FORM-1.pdf

2214-KOL-2008-(09-05-2012)-FORM-2.pdf

2214-KOL-2008-(09-05-2012)-FORM-3.pdf

2214-KOL-2008-(09-05-2012)-OTHERS.pdf

2214-KOL-2008-(09-05-2012)-PETITION UNDER RULE 137.pdf

2214-kol-2008-abstract.pdf

2214-KOL-2008-ASSIGNMENT.pdf

2214-kol-2008-claims.pdf

2214-KOL-2008-CORRESPONDENCE 1.3.pdf

2214-KOL-2008-CORRESPONDENCE-1.1.pdf

2214-KOL-2008-CORRESPONDENCE-1.2.pdf

2214-kol-2008-correspondence.pdf

2214-kol-2008-description (complete).pdf

2214-kol-2008-drawings.pdf

2214-KOL-2008-EXAMINATION REPORT.pdf

2214-kol-2008-form 1.pdf

2214-KOL-2008-FORM 18 1.1.pdf

2214-kol-2008-form 18.pdf

2214-kol-2008-form 2.pdf

2214-KOL-2008-FORM 3 1.1.pdf

2214-kol-2008-form 3.pdf

2214-kol-2008-form 5.pdf

2214-kol-2008-gpa.pdf

2214-KOL-2008-GRANTED-ABSTRACT.pdf

2214-KOL-2008-GRANTED-CLAIMS.pdf

2214-KOL-2008-GRANTED-DESCRIPTION (COMPLETE).pdf

2214-KOL-2008-GRANTED-DRAWINGS.pdf

2214-KOL-2008-GRANTED-FORM 1.pdf

2214-KOL-2008-GRANTED-FORM 2.pdf

2214-KOL-2008-GRANTED-SPECIFICATION.pdf

2214-KOL-2008-OTHERS 1.1.pdf

2214-KOL-2008-OTHERS.pdf

2214-KOL-2008-REPLY TO EXAMINATION REPORT.pdf

2214-kol-2008-specification.pdf

2214-KOL-2008-TRANSLATED COPY OF PRIORITY DOCUMENT 1.1.pdf

2214-KOL-2008-TRANSLATED COPY OF PRIORITY DOCUMENT.pdf

abstract-2214-kol-2008.jpg


Patent Number 254021
Indian Patent Application Number 2214/KOL/2008
PG Journal Number 37/2012
Publication Date 14-Sep-2012
Grant Date 13-Sep-2012
Date of Filing 24-Dec-2008
Name of Patentee GM GLOBAL TECHNOLOGY OPERATIONS, INC.
Applicant Address 300 GM RENAISSANCE CENTER DETROIT, MICHIGAN
Inventors:
# Inventor's Name Inventor's Address
1 YOUSSEF M. MIKHAIL 12702 WINDSOR COURT STERLING HEIGHTS, MICHIGAN 48313
2 MAHMOUD H. ABD ELHAMID 1976 FLEETWOOD GROSSE POINTE WOODS MICHIGAN 48236
3 GAYATRI VYAS DADHEECH 398 DAYLILY DRIVE ROCHESTER HILLS, MICHIGAN 48307
4 FENG ZHONG 1900 STONEY CV TROY, MICHIGAN 48085
5 RICHARD H. BLUNK 15415 CRESTWOOD DRIVE, MACOMB TOWNSHIP, MICHIGAN 48044
6 DANIEL J. LISI 23009 HAYES EASTPOINTE, MICHIGAN 48021
PCT International Classification Number C01B21/06,B05D3/00
PCT International Application Number N/A
PCT International Filing date
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 11/968,890 2008-01-03 U.S.A.