US2002166658A1PendingUtilityA1
Graphite-based thermal dissipation component
Est. expiryApr 4, 2021(expired)· nominal 20-yr term from priority
H10W 40/257H10W 40/73H10W 40/25C04B 2235/5264B32B 2307/202C04B 2235/77C04B 2235/5228C04B 2235/524B32B 9/00C04B 2235/5236F28F 21/02C04B 2235/5248C01B 32/225C04B 2235/522C04B 2235/604C04B 35/82C04B 2235/9607C04B 2235/608C04B 2235/5244C04B 2235/526C04B 35/536B32B 2037/1215B32B 2313/04C04B 2235/5224C04B 2235/48B32B 37/156B32B 37/12C04B 2237/363C04B 2235/5232
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Claims
Abstract
A process is presented for forming an anisotropic heat spreader or heat pipe, comprising forming a laminate comprising a plurality of flexible graphite sheets which comprise graphene layers; and directionally aligning the graphene layers of the laminate.
Claims
exact text as granted — not AI-modifiedWhat is claimed is:
1 . A process for producing a heat spreader or heat pipe for an electronic component, comprising forming a laminate comprising a plurality of flexible graphite sheets which comprise graphene layers; and directionally aligning the graphene layers of the laminate.
2 . The process of claim 1 wherein directionally aligning the graphene layers of the laminate is effected by the application of pressure.
3 . The process of claim 2 wherein the application of pressure is effected after the formation of the laminate from the plurality of flexible graphite sheets.
4 . The process of claim 3 wherein the graphene layers of the flexible graphite sheets which make up the laminate are subjected to the application of pressure prior to the formation of the laminate, by increasing the pressure applied to the sheets during the calendering process.
5 . The process of claim 2 wherein the application of pressure to the laminate results in an increase in the density of the laminate.
6 . The process of claim 4 wherein the increase in the pressure during the calendering process results in the formation of flexible graphite sheets having a greater density.
7 . A laminate produced in accordance with the process of claim 1 .
8 . A laminate produced in accordance with the process of claim 3 .
9 . A laminate produced in accordance with the process of claim 4 .
10 . A heat spreader for an electronic component comprising a plurality of flexible graphite sheets laminated into a unitary article, wherein the thermal anisotropic ratio of the article is at least about 70.
11 . The heat spreader of claim 10 wherein the thermal anisotropic ratio of the article is at least about 90.
12 . The heat spreader of claim 10 wherein the laminate is formed by laminating flexible sheets of compressed particles of exfoliated graphite with a suitable adhesive.
13 . The heat spreader of claim 12 wherein the adhesive comprises a pressure sensitive or thermally activated adhesive.
14 . A heat pipe for an electronic component comprising a plurality of flexible graphite sheets laminated into a unitary article, wherein the thermal anisotropic ratio of the article is at least about 70.
15 . The heat pipe of claim 14 wherein the thermal anisotropic ratio of the article is at least about 90.
16 . The heat pipe of claim 14 wherein the laminate is formed by laminating flexible sheets of compressed particles of exfoliated graphite with a suitable adhesive.
17 . The heat pipe of claim 16 wherein the adhesive comprises a pressure sensitive or thermally activated adhesive.Cited by (0)
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