SFP Sleeve Handle is made using injection molding and stamping processes, and injection molding can produce parts of various sizes and complexity. Small features, intricate geometries, and thin walls can be captured with ease using the injection molding process. Injection-molded components can be post-processed via various surface finishing options such as painting and texturing.
SFP+Protection is made using injection molding processes, and injection molding can produce parts of various sizes and complexity. Small features, intricate geometries, and thin walls can be captured with ease using the injection molding process. Injection-molded components can be post-processed via various surface finishing options such as painting and texturing.
SFP+Protective Case is made using injection molding processes, and injection molding can produce parts of various sizes and complexity. Small features, intricate geometries, and thin walls can be captured with ease using the injection molding process. Injection-molded components can be post-processed via various surface finishing options such as painting and texturing.
SFP+Sleeve is made using injection molding processes, and injection molding can produce parts of various sizes and complexity. Small features, intricate geometries, and thin walls can be captured with ease using the injection molding process. Injection-molded components can be post-processed via various surface finishing options such as painting and texturing.
SFP56 AOC Hand Shank is made using injection molding processes, and injection molding can produce parts of various sizes and complexity. Small features, intricate geometries, and thin walls can be captured with ease using the injection molding process. Injection-molded components can be post-processed via various surface finishing options such as painting and texturing.
SFP56 AOC Handle is made using injection molding processes, and injection molding can produce parts of various sizes and complexity. Small features, intricate geometries, and thin walls can be captured with ease using the injection molding process. Injection-molded components can be post-processed via various surface finishing options such as painting and texturing.
SFP56 AOC Latch is made using injection molding processes. The primary benefit of using injection precision parts is their ability to maintain exact specifications, leading to enhanced product quality and reliability. Small features, intricate geometries, and thin walls can be captured with ease using the injection molding process. Injection-molded components can be post-processed via various surface finishing options such as painting and texturing.
XFP BD Rack is made using injection molding processes, and injection molding can produce parts of various sizes and complexity. Small features, intricate geometries, and thin walls can be captured with ease using the injection molding process. Injection-molded components can be post-processed via various surface finishing options such as painting and texturing.
XFP BD Support is made using injection molding processes, and injection molding can produce parts of various sizes and complexity. Small features, intricate geometries, and thin walls can be captured with ease using the injection molding process. Injection-molded components can be post-processed via various surface finishing options such as painting and texturing.
XFP ER Brace is made using injection molding processes, and injection molding can produce parts of various sizes and complexity. Small features, intricate geometries, and thin walls can be captured with ease using the injection molding process. Injection-molded components can be post-processed via various surface finishing options such as painting and texturing.
XFP ER Rack is made using injection molding processes, and injection molding can produce parts of various sizes and complexity. Small features, intricate geometries, and thin walls can be captured with ease using the injection molding process. Injection-molded components can be post-processed via various surface finishing options such as painting and texturing.
XFP ER Support is made using injection molding processes, and injection molding can produce parts of various sizes and complexity. Small features, intricate geometries, and thin walls can be captured with ease using the injection molding process. Injection-molded components can be post-processed via various surface finishing options such as painting and texturing.
