Heater plate with embedded hyper-conductive thermal diffusion layer for increased temperature rating and uniformity
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| Název: | Heater plate with embedded hyper-conductive thermal diffusion layer for increased temperature rating and uniformity |
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| Patent Number: | 8,481,896 |
| Datum vydání: | July 09, 2013 |
| Appl. No: | 12/881790 |
| Application Filed: | September 14, 2010 |
| Abstrakt: | A heater plate is constructed with an embedded thermal diffusion layer of pyrolytic graphite to provide increased temperature uniformity in a critical heating surface. The heater has first and second metal plates with a heater element contained within the first plate and a core of the pyrolytic graphite diffusion layer sandwiched between the heater element and the second metal plate. The diffusion layer may be sputter metal coated to improve bonding of the layer to the plates. |
| Inventors: | Quinton, Jr., Phillip G. (Pleasanton, CA, US) |
| Claim: | 1. A uniform heater, comprising: first and second metal plates, one of the plates providing a critical heating surface; a heater element contained within the first metal plate; and a core formed of a thermally-annealed pyrolytic graphite diffuser sandwiched between the heater element and the second metal plate with the diffuser in direct contact with the heater element; braze alloy sheets between the thermal diffuser and the respective plates; wherein the diffuser and metal plates are vacuum thermal brazed together; and wherein the metal coating encapsulating the diffuser is a sputtered metal coating selected to aid in brazing the diffuser to the metal plates. |
| Claim: | 2. A heater as in claim 1 , wherein the sputtered metal coating is selected from any one or more of molybdenum, nickel alloys, titanium, copper, aluminum, and combinations and alloys thereof. |
| Claim: | 3. A heater as in claim 1 , wherein the metal plates are composed of any one or more of copper, aluminum, molybdenum, tungsten, nickel alloys, stainless steel, and titanium. |
| Claim: | 4. A heater as in claim 1 , wherein the heater element has an electrically insulating material with an insulation distance sufficient to ensure minimal leakage current at temperatures in excess of 450° C. |
| Claim: | 5. A heater as in claim 4 , wherein the insulation is composed of MgO with a heater diameter of at least 0.188″ (4.8mm). |
| Claim: | 6. A heater as in claim 4 , wherein the insulation is composed boron nitride. |
| Claim: | 7. A uniform heater, comprising: upper and lower metal plates, the upper one of the plates providing a critical heating surface; a heater element contained in a cavity within the lower metal plate, the heater element being electrically isolated from the lower metal plate by a thermally conducting electrically insulating material; and a heat spreader core formed of a thermally-annealed pyrolytic graphite (TPG) diffuser encapsulated with a metal coating and contained within a cavity of the upper metal plate and bonded with a braze material to the upper metal plate, the heat spreader core being in direct contact with the heater element. |
| Claim: | 8. A heater as in claim 7 , wherein the insulation is composed boron nitride. |
| Claim: | 9. A heater as in claim 7 , wherein the insulation is composed of MgO with a heater diameter of at least 0.188″ (4.8mm). |
| Claim: | 10. A heater as in claim 7 , wherein the metal plates are composed of any one or more of copper, aluminum, molybdenum, tungsten, nickel alloys, stainless steel, and titanium. |
| Claim: | 11. A heater as in claim 7 , wherein the diffuser is vacuum thermal brazed to the upper metal plate. |
| Claim: | 12. A heater as in claim 11 , wherein the metal coating encapsulating the diffuser is a molybdenum coating and a braze alloy sheet is present between the diffuser and the upper metal plate. |
| Claim: | 13. A method of making a uniform heater, comprising: sandwiching a first metal plate, a heater element; a thermally-annealed pyrolytic graphite diffuser encapsulated with a metal coating, a braze sheet, and a second metal plate; and vacuum thermally brazing sandwiched elements, with the diffuser in direct contact with the heater element. |
| Claim: | 14. The method as in claim 13 , wherein the sheath is a dielectric selected from either of magnesium oxide (MgO) or boron nitride. |
| Claim: | 15. The method as in claim 13 , wherein the heater element is provided with a thermally conducting electrically insulating material to a heater diameter of at least 0.188″ (4.8mm). |
| Claim: | 16. The method as in claim 13 , wherein the bonding is performed by thermal brazing the respective elements together using a braze material selected for the metal plate material. |
| Claim: | 17. The method as in claim 13 , wherein the metal plates are composed of any one or more of copper, aluminum, molybdenum, tungsten, nickel alloys, stainless steel, titanium. |
| Claim: | 18. The method as in claim 13 , wherein the first metal plate has a cavity to accept the heater element therein. |
| Claim: | 19. The method as in claim 18 , wherein the cavity in the first metal plate is a spiral cavity to accept spiral coils of the heater element. |
| Claim: | 20. The method as in claim 13 , wherein an interface is provided to fill spaces between coils of the heater element. |
| Claim: | 21. The method as in claim 13 , wherein the second metal plate has a cavity to accept the diffuser therein. |
| Claim: | 22. The method as in claim 13 , wherein the diffuser is sputter coated with a high-temperature sputter material. |
| Claim: | 23. The method as in claim 22 , wherein the sputter material is selected from any one or more of molybdenum, nickel alloys, titanium, copper, aluminum, and combinations and alloys thereof. |
| Claim: | 24. The method as in claim 16 , wherein braze material between the diffuser and the second metal plate comprises a nickel braze alloy sheet. |
| Current U.S. Class: | 219/532 |
| Patent References Cited: | 4481406 November 1984 Muka 4742324 May 1988 Shida et al. 5343022 August 1994 Gilbert, Sr. et al. 5348215 September 1994 Rafferty et al. 5863467 January 1999 Mariner et al. 6147334 November 2000 Hannigan 6534751 March 2003 Uchiyama et al. 6758263 July 2004 Krassowski et al. 7901509 March 2011 Mariner et al. 2009/0235866 September 2009 Kataigi et al. WO 9609738 March 1996 |
| Other References: | Accuratus Corporation, Boron Nitride, BN Material Properties, 2002. cited by examiner |
| Assistant Examiner: | Miller, Renee L |
| Primary Examiner: | Paik, Sang |
| Attorney, Agent or Firm: | Schneck & Schneck Schneck, Thomas Protsik, Mark |
| Přístupové číslo: | edspgr.08481896 |
| Databáze: | USPTO Patent Grants |
| Abstrakt: | A heater plate is constructed with an embedded thermal diffusion layer of pyrolytic graphite to provide increased temperature uniformity in a critical heating surface. The heater has first and second metal plates with a heater element contained within the first plate and a core of the pyrolytic graphite diffusion layer sandwiched between the heater element and the second metal plate. The diffusion layer may be sputter metal coated to improve bonding of the layer to the plates. |
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