A method of making a fan annulus filler for use in a fan assembly of a gas turbine engine may include an annulus filler body formed of a polymer. The annulus filler body may include a surface coated with a nanocrystalline coating to form a flow surface.

A method of making a fan annulus filler for use in a fan assembly of a gas turbine engine may include an annulus filler body formed of a polymer. The annulus filler body may include a surface coated with a nanocrystalline coating to form a flow surface.

A system and method to form beam tunnels in interaction circuits. Forms, such as fibers or sheets can be located and secured above a substrate at a desired size and desired shape to form the final shape of the beam tunnels. Fiber holders can be utilized to position the forms above the substrate. A photoresist can then be applied over the substrate embedding the forms. A single exposure LIGA process can be performed on the photoresist, including the steps of ultraviolet photolithography, molding, and electroforming. After the process, the forms can be removed to leave the beam tunnels in the interaction circuits.

A system and method to form beam tunnels in interaction circuits. Forms, such as fibers or sheets can be located and secured above a substrate at a desired size and desired shape to form the final shape of the beam tunnels. Fiber holders can be utilized to position the forms above the substrate. A photoresist can then be applied over the substrate embedding the forms. A single exposure LIGA process can be performed on the photoresist, including the steps of ultraviolet photolithography, molding, and electroforming. After the process, the forms can be removed to leave the beam tunnels in the interaction circuits.

A strengthened component includes a sacrificial material mold of the component having an outer surface, an insert having an inner surface and an outer surface opposite and spaced from the inner surface such that the strengthening insert inner surface abuts the mold outer surface, and a metallic layer deposited over the exposed mold outer surface and the exposed strengthening insert outer surface, where the sacrificial material mold is removed from the strengthened component.

A strengthened component includes a sacrificial material mold of the component having an outer surface, an insert having an inner surface and an outer surface opposite and spaced from the inner surface such that the strengthening insert inner surface abuts the mold outer surface, and a metallic layer deposited over the exposed mold outer surface and the exposed strengthening insert outer surface, where the sacrificial material mold is removed from the strengthened component.

A motor component prepared by electrolyzing copper and a motor includes an iron core, guide bars, and end rings, wherein the guide bars are arranged in grooves on an outer circumference of the iron core, respectively, and the end rings are located at both ends of the iron core to connect the guide bars in short, the guide bars and the end rings together form an integral squirrel cage, and the guide bars and the end rings are made by a copper electrolyzing method. Thus, manufacturing processes of melting and casting refined copper are omitted, thereby lowering a requirement for energy efficiency of manufacturing process of a motor and achieving energy saving in the manufacturing process; there is no welding process, thereby avoiding welding points resulted from copper welding and improving the reliability of the motor component.

A motor component prepared by electrolyzing copper and a motor includes an iron core, guide bars, and end rings, wherein the guide bars are arranged in grooves on an outer circumference of the iron core, respectively, and the end rings are located at both ends of the iron core to connect the guide bars in short, the guide bars and the end rings together form an integral squirrel cage, and the guide bars and the end rings are made by a copper electrolyzing method. Thus, manufacturing processes of melting and casting refined copper are omitted, thereby lowering a requirement for energy efficiency of manufacturing process of a motor and achieving energy saving in the manufacturing process; there is no welding process, thereby avoiding welding points resulted from copper welding and improving the reliability of the motor component.

Embodiments provide a novel fabrication method and structure for reducing structural weight in radio frequency cavity filters and novel filter structure. The novel filter structure is fabricated by electroplating the required structure over a mold. The electrodeposited composite layer may be formed by several layers of metal or metal alloys with compensating thermal expansion coefficients. The first or the top layer is a high conductivity material or compound such as silver having a thickness of several times the skin-depth at the intended frequency of operation. The top layer provides the vital low loss performance and high Q-factor required for such filter structures while the subsequent compound layers provide the mechanical strength.

Embodiments provide a novel fabrication method and structure for reducing structural weight in radio frequency cavity filters and novel filter structure. The novel filter structure is fabricated by electroplating the required structure over a mold. The electrodeposited composite layer may be formed by several layers of metal or metal alloys with compensating thermal expansion coefficients. The first or the top layer is a high conductivity material or compound such as silver having a thickness of several times the skin-depth at the intended frequency of operation. The top layer provides the vital low loss performance and high Q-factor required for such filter structures while the subsequent compound layers provide the mechanical strength.