Stock material or miscellaneous articles – Web or sheet containing structurally defined element or... – Composite having voids in a component
Reexamination Certificate
2002-04-26
2003-12-02
Loney, Donald J. (Department: 1771)
Stock material or miscellaneous articles
Web or sheet containing structurally defined element or...
Composite having voids in a component
C428S166000, C428S188000, C428S306600, C428S317100, C428S318400, C264S045100, C264S048000, C156S295000
Reexamination Certificate
active
06656580
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates to a flexible graphite sheet impregnated with a sealant. More particularly, the present invention relates to the infusion of the sealant into the porosity of the graphite sheet prior to mechanical deformation of the sheet to form an article of manufacture.
BACKGROUND OF RELATED TECHNOLOGY
Natural graphites are made up of layered planes of hexagonal arrays of networks of carbon atoms and typically exist in the shape of flakes in nature. These layered planes of hexagonally arranged carbon atoms are substantially flat and are oriented so as to be substantially parallel and equidistant to one another. The substantially flat, parallel equidistant layers of carbon atoms are joined together by weak Van der Waals forces. These natural graphites are soft and brittle and are typically difficult to form into a shape due to cracking along these layered planes. Such characteristics of graphites are well known to those skilled in the art, see, e.g., U.S. Pat. No. 5,149,518.
Natural graphites, however, may be formed into flexible sheets by compressing exfoliated graphite particles. Exfoliated graphite particles are formed by expanding the natural graphite flakes. In this expansion process, natural graphite flakes are intercalated by dispersing the flakes in a solution containing an oxidizing agent, for instance, a mixture of nitric and sulfuric acid. After the flakes are intercalated excess solution is drained from the flakes and after washing with water, the intercalated graphite flakes are dried. Upon exposure to high temperature, for instance 1,090-1,370° C. (2,000-2,500° F.), the particles of intercalated graphite expand in dimension as much as 80 to 1000 or more times their original volume in an accordion-like fashion in the direction perpendicular to the layered planes of the hexagonally arranged carbon atoms of the constituent graphite particles.
The exfoliated graphite particles are then compressed or compacted together, in the absence of any binder, so as to form a flexible integrated graphite sheet of desired thickness and density. The compression or compaction is carried out by passing a thick bed of expanded particles between pressure rolls or a system of multiple pressure rolls to compress the material in several stages into sheet material of desired thickness.
The sheet material formed from the exfoliated graphite particles, unlike the original graphite flakes, can be formed and cut into various shapes. The compression operation flattens the expanded graphite particles causing them to somewhat engage and interlock. The compression reorientates many of the carbon atoms from the perpendicular, accordion-like arrangement back into layered, parallel planes. Nevertheless, some carbon atoms remain in substantially nonparallel planes. These carbon atoms in the nonparallel planes increase the porosity of the sheet as compared to natural graphite, having parallel planes of carbon atoms, provide engagement among parallel planes of carbon atoms to provide flexibility to the sheet, and allow mechanical shaping without substantial cracking. Furthermore, as the degree of compression increases, the degree of reorientation of carbon atoms from nonparallel planes into layered, parallel planes also increases, especially near the exterior surfaces of the sheet.
The density of the compressed exfoliated product is typically in the range of about 0.08 to 1.4 g/cc (5 to 90 lbs/ft
3
) which is lower than the density of natural graphite (or fully compressed graphite) having a bulk density of about 2.2 g/cc (140 lbs/ft
3
). As the density of a graphite product increases, the porosity of the graphite product typically decreases. Porosity, P, is defined as the fraction of the total volume of a porous substance that is occupied by the pores of the substance, as shown below in Formula I.
P=V
P
/V
T
, (I)
where V
P
is the pore volume and VT is the total volume.
The pore volume, V
P
, of a porous material is the total volume, V
T
, less the volume of 30 the fully compressed bulk material, V
0
, or
V
P
=V
T
/V
0
. (II)
The porosity of a porous substance may also be expressed in terms of densities, as shown below in Formula III.
P=
1−
D
P
/D
0
, (III)
where D
P
is the density of the porous material and D
0
is the density of the fully compressed material.
From Formula III, the porosity of the compressed product is about 0.96 and to about 0.36 for products having a density of about 0.08 and 1.4 g/cc, respectively. The porosity of a fully compressed material is zero because such a fully compressed material does not have pore volume. This above-calculated porosity is often referred to as true porosity because the volume of both open and sealed pore spaces are included. Apparent porosity is a measurement of just the open-pore space which is accessible to a fluid, such as nitrogen or mercury. The volume of such open pore space is then substituted for V
P
in Formula I.
A higher density or a lower porosity product is typically too stiff for use as flexible sheet graphite and is typically too mechanically weak to survive mechanical shaping processes. Some applications require higher impermeability or greater mechanical strength than is typical for compressed graphite sheets. For instance, anode and cathode fluid-flow plates used in a fuel cell should be substantially impermeable to gaseous reactants and products, such as hydrogen and oxygen, to avoid undesired leakage of the reactants and products. For these applications, the graphite sheet is mechanically processed into a graphite plate, and then a sealant is impregnated into the graphite plate sheet to seal the plate. Such a graphite plate without an impregnated-sealant is too mechanically weak and not sufficiently impermeable to gaseous reactants and products for use as a fuel cell plate because of its internal porosity. The impregnation of the sealant into the graphite plates for these applications, however, is often difficult to achieve because such mechanical processing alters the graphite sheets by reorienting the carbon atoms from nonparallel to layered, parallel planes thereby inhibiting sealant infusion.
These layered, parallel planes tend to block access of the internal porosity. Furthermore, as the density of the graphite sheet increases, e.g., greater than about 1.0 g/cc (62 lbs/ft
3
), impregnation of a sealant into internal porosity becomes more difficult because the outer surface of the plate is characterized by a greater number of layered, parallel planes of carbon atoms. Impregnation of these denser sheets is often quite time consuming, thus increasing the manufacturing costs associated with such plates.
One technique for impregnating a dense graphite sheet is disclosed in U.S. Pat. No. 4,729,910. The disclosed technique is to de-aerate the sheet and to apply a sealant under multiple steps of reduced pressure and ambient pressure to facilitate the movement of the sealant into the porosity of the sheet. The technique suffers the disadvantage of requiring multiple, expensive pressure reducing steps and using a sealant dissolved in organic solvents to reduce the viscosity of the sealant to permit entry of the less viscous sealant mixture into the porosity of the sheet. The organic solvent is removed under reduced pressure conditions before the sealant is heat cured. This technique not only requires multiple pressure reducing steps to infuse the sealant, but also results in no more than about 20% by weight take-up of sealant, leaving many of the internal pores unfilled with the sealant.
U.S. Pat. Nos. 5,885,728 and 5,902,762 disclose a technique where ceramic fibers are incorporated into dense graphite sheets to facilitate subsequent sealant infusion. This technique, however, suffers from the disadvantage of introducing impurities, such as the ceramic fibers themselves, which can be harmful to certain applications, such as fuel cells where the surfaces of the graphite sheets are coated or proximal to precious metals, such as platinum. Al
Bauman Steven C.
Henkel Loctite Corporation
Loney Donald J.
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