Plastic Structure Spare Parts 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.
Plastic XFP Bracket 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.
Plastic XFP LR Bracket 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.
Plastic XFP SR Bracket 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.
QSFP 100G Dust Plug 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.
QSFP 100G Dust Top is made using injection molding processes, and injection molding can produce parts of various 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.
QSFP 100G Rubber Plug 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.
QSFP AOC 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.
QSFP AOC 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.
QSFP AOC 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.
QSFP AOC 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.
QSFP AOC 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.
QSFP 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.
QSFP Cable 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.
QSFP Cable 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.
QSFP Cable 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.
QSFP Cable 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.
QSFP Cable 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.
QSFP Cable 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.
QSFP DAC 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.
QSFP DAC 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.
QSFP MPO 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.
QSFP MPO Dust Plug 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.
QSFP MPO Dust Top 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.
QSFP MPO Hand Shank 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.
QSFP MPO Latch is made using injection molding and stamping 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.
QSFP MPO Rack is made using injection molding processes, and QSFP MPO 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.
QSFP MPO Rubber Plug 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.
QSFP MPO 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.
QSFP Optical Cable 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.
