DAVID SCOTT BURTON, M.D.
Osteopathic Medicine at 900, Salt Lake City, UT

7562647, Jul 21, 2009

Mar 29, 2006

11/394291

David R. Burton - Salt Lake City UT, US
Jeffrey C. Holm - Sandy UT, US
James M. Yates - Sandy UT, US

High Performance Coatings, Inc. - Bluffdale UT

F02N 3/00

1231883, 137375, 298884, 251368

An inlet valve is partially coated with a protective coating to resist corrosion and gas impingement when used in an internal combustion engine. The inlet valve has a hard cladding that is shaped to function as a valve seat. The hard cladding forms an interface with the valve head body, which is typically made of a softer metallic material than the hard cladding. The protective coating is bonded to the inlet valve and covers the cladding-body interface. The protective coating is resistant to corrosion, wear from gas impingement, and can withstand the high temperatures reached in internal combustion engines. Internal engines incorporating the valves are more durable and less susceptible to catastrophic valve failure. A method for making the inlet valves generally includes masking a portion of the valve stem and the valve seat, applying a protective coating to cladding-body interface, and curing the protective coating or otherwise bonding the protective coating to the inlet valve.

2008003, Feb 7, 2008

Mar 26, 2007

11/690988

David Burton - Salt Lake City UT, US
James Yates - Sandy UT, US

High Performance Coatings, Inc. - Bluffdale UT

H05B 6/00

427595000

A method of manufacturing valves and other engine valves with a corrosion and heat resistant coating comprises applying a protective coating in the form of a slurry to the engine part and curing the protective coating using infrared radiation. The protective coating may include one or more of metal and/or ceramic materials, one or more of organic and/or inorganic binders, and a solvent (e.g., water or volatile organic solvent). The method may include masking a portion of the engine valve to limit the area that is coated by the protective coating. The emissivity of the protective coating is generally greater than about 0.7 in order to more effectively absorb infrared radiation during the curing process. The protective coating is typically cured by heating to a temperature of about 100° C. to about 650° C. using infrared radiation. The protective coating helps prolong the life of the valve and resists wear and breakage in locations prone to breakage.

7559991, Jul 14, 2009

Jul 19, 2006

11/458634

David R. Burton - Salt Lake City UT, US
Jeffrey C. Holm - Sandy UT, US
James M. Yates - Sandy UT, US

High Performance Coatings, Inc. - Bluffdale UT

B05C 5/02

118641, 118 66, 118320, 118504, 118505

A system for applying a coating to an engine valve and curing the coating using infrared radiation includes a spraying device, an infrared oven, and a movable track. A plurality of engine valves is transported through the system on the movable track. The spraying device applies a protective coating composition on a portion of the engine valves. The coating composition has a high emissivity value that allows the coating to be rapidly and efficiently cured as the coated engine valves travel through the infrared oven.