Abstract: A piston ring with a coated outer surface is provided. The coating is disposed on end sections of the outer surface adjacent a gap. Typically, a middle section of the outer surface located between the end sections is not coated. The coating can be formed of CrN or DLC, and the CrN coating can be applied by physical vapor deposition (PVD). The end sections of the outer surface, upon which the coating is applied, are rough. For example, the outer surface can be blasted or otherwise textured to achieve the rough surface. The rough surface retains oil and distributes stress better than a smooth surface, and thus reduces crazing and flaking of the coating.

Abstract: A piston ring with a coated outer surface is provided. The coating is disposed on end sections of the outer surface adjacent a gap. Typically, a middle section of the outer surface located between the end sections is not coated. The coating can be formed of CrN or DLC, and the CrN coating can be applied by physical vapor deposition (PVD). The end sections of the outer surface, upon which the coating is applied, are rough. For example, the outer surface can be blasted or otherwise textured to achieve the rough surface. The rough surface retains oil and distributes stress better than a smooth surface, and thus reduces crazing and flaking of the coating.

Abstract: A piston ring with a coated outer surface is provided. The coating is disposed on end sections of the outer surface adjacent a gap. Typically, a middle section of the outer surface located between the end sections is not coated. The coating can be formed of CrN or DLC, and the CrN coating can be applied by physical vapor deposition (PVD). The end sections of the outer surface, upon which the coating is applied, are rough. For example, the outer surface can be blasted or otherwise textured to achieve the rough surface. The rough surface retains oil and distributes stress better than a smooth surface, and thus reduces crazing and flaking of the coating.

Abstract: A piston ring with a coated outer surface is provided. The coating is disposed on end sections of the outer surface adjacent a gap. Typically, a middle section of the outer surface located between the end sections is not coated. The coating can be formed of CrN or DLC, and the CrN coating can be applied by physical vapor deposition (PVD). The end sections of the outer surface, upon which the coating is applied, are rough. For example, the outer surface can be blasted or otherwise textured to achieve the rough surface. The rough surface retains oil and distributes stress better than a smooth surface, and thus reduces crazing and flaking of the coating.

Abstract: An engine component, for example a piston ring, including a wear resistant coating applied by physical vapor deposition (PVD) is provided. The coating includes tetrahedral amorphous carbon (ta-C), the carbon of the coating includes sp3 hybrid orbitals, and the coating includes boron in an amount of 0.1 wt. % to 4.0 wt. %, based on the total weight of the coating. The doped boron makes the coating less sensitive to the ion energy during the physical vapor deposition (PVD) process, improves adhesion of the coating, and expected to reduce compressive stress in the coating. Thus, the boron-doped ta-C coating can be applied to a greater thickness compared to ta-C coatings without the doped boron. In addition, there is a strong indication that the addition of boron will maintain a high level of sp3 bonded carbon and a high microhardness.

Abstract: A cylinder liner includes a body formed of a metal material extending circumferentially around a center axis with an outer surface facing away from the center axis. A thermal barrier coating including an insulating material having a thermal conductivity of not greater than 5 W/(m·K) is applied to the outer surface. The thermal barrier coating is thermally applied to the outer surface at a velocity of 100 to 1,000 m/s, for example by a high velocity oxygen fuel (HVOF) spray, a plasma spray, or a detonation gun.

Abstract: Ultra-miniature electrical contacts are provided with the strength and resilience necessary to give stable low resistance connection, to minute areas of a device, such as a thousand or so closely spaced surface pads of an integrated circuit. Each contact is initially formed on a substrate as a thin, narrow elongated flat body comprised of selectively deposited layers of metal. Depending on the final configuration desired for the contact, the metal of one metal layer has a coefficient of thermal expansion such as chromium (Cr), and the metal of another layer has a coefficient of thermal expansion such as copper (Cu). Each contact is permanently formed (by differential expansion of the metal layers when heated) into a three-dimensional structure and is then made “robust” by a covering of a specialized stiffening metal plating which adds substantial strength to the contact.

Abstract: Ultra-miniature electrical contacts are provided with the strength and resilience necessary to give stable low resistance connection, to minute areas of a device, such as a thousand or so closely spaced surface pads of an integrated circuit. Each contact is initially formed on a substrate as a thin, narrow elongated flat body comprised of selectively deposited layers of metal. Depending on the final configuration desired for the contact, the metal of one metal layer has a coefficient of thermal expansion such as chromium (Cr), and the metal of another layer has a coefficient of thermal expansion such as copper (Cu). Each contact is permanently formed (by differential expansion of the metal layers when heated) into a three-dimensional structure and is then made “robust” by a covering of a specialized stiffening metal plating which adds substantial strength to the contact.