Different types of fiber lenses have formed a large family of fiber components in fiber laser, medical, and telecom industries. By using CO2 laser fusion technology, many components with extreme geometries and critical requirements, which were very hard to make in the past, can now be easily manufactured. These newly developed fiber lenses are reviewed and discussed for their merits and key features in this article.
The recently released Fujikura PCS-100 is a novel stripping tool for removing polyimide coating from optica...
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The LZM-125 series consists of splicing glass processing systems and fiber ablation machines that use a CO2 laser heat source to perform splicing, tapering, lensing, ablation and more.
White paper will show how a metal-coated fiber is capable of withstanding temperatures up to 500°C.
This blog summarizes the four key problems of metal-coated fibers and how AFL's specialty fibers address these challenges.
Verrillon VHT500 is a pure silica core single-mode design with a protective metal coating that allows it to operate at temperatures up to 500°C.
The VHT5000 product is a specialty optical fiber that has ultimate performance multimode fiber with metallic coating, rated for 500°C service.
This series consists of an 80 µm cladding fiber design that exhibits extremely low macro-bend loss and high compatibility with standard 125 µm standard single-mode fibers.
Demonstration of low attenuation metal-coated optical fiber and cable capable of withstanding temperatures up to 500°C. Performance will be validated by using a DTS instrument to measure temperature.
The recently released Fujikura PCS-100 is a novel stripping tool for removing polyimide coating from optical fibers.
AFL's unique patented PZ Fiber design offers very broad polarizing bandwidth (~200nm), high exstinction ratio (>40 dB), low attenuation and does not require bending to operate.
Optical fibers have been used in the petroleum industry for years and in this paper we demonstrate improved reliability of recently developed hermetic, high operating temperature optical fiber.
Optical fibers with improved hermeticity, strength and chemical resistance are presented.
A new class of novel optical fiber structure were designed for improved use in harsh environments typical of oil and gas applications.