Home » Product > Cable - Harsh Environment » The Evolution of Optical Fiber Cable Design for Sensor Applications

× Share this Presentation

Facebook
Twitter
Email
LinkedIn
Google+

First Name

Last Name

Company

Thank you!

Error - something went wrong!

The Evolution of Optical Fiber Cable Design for Sensor Applications

May 15, 2018

Share this Flipbook
Facebook
Twitter
Email
LinkedIn
Google+

The focus of this paper is to compare and contrast the cable construction differences between sensing applications and traditional telecommunications applications, review the significant design considerations for the associated application and outline several current design challenges necessary to enable reliable cable deployments.

Previous Flipbook

Novel Optical Fiber Design for Hydrogen-rich Harsh Environment

A new class of novel optical fiber structure were designed for improved use in harsh environments typical o...

Next Flipbook

Distributed Strain and Temperature Sensing Using Brillouin Scattering

This is a technology that allows the measurement of strain and temperature along a passive fiber optic elem...

Other content in this Stream

Ease Deployment with Sidewinder Rapid Cable Deployment System

AFL's new Sidewinder Rapid Cable Deployment System is specially dsigned to help those who work in industrial or harsh environments. Whether you're in the broadcast, military tactical, mining, or...

Read Article

Tactical Cable Selection Guide

Deploying cable in harsh environments doesn’t have to raise your blood pressure. Rely on AFL’s line of ruggedized tactical cables for superior performance and reliability.

Read Flipbook

Mechanics of Metallic Cable Structures for Downhole Optical Fiber Applications

This application note provides an overview of the importance of material selection for oil and gas applications involving high temperatures in conjunction with various mechanical loadings.

Read Flipbook

Benefits of Stainless Steel Tubes in Subsea Optical Cables

Inside of many subsea umbilical cables, optical fiber data communications is needed to monitor fluid flow rate, pressure and temperature at a subsea wellhead.

Read Flipbook

Variations and Design Considerations of Traditional Downhole Fiber Optic Cable for Oil and Gas Applications

Traditional Downhole Cables are designed to be rugged and durable for optimal performance in wellbore completions with severe mechanical loads, elevated temperatures, and production fluids.

Read Flipbook

A Fiber Optic Sensing Cable for Monitoring Enhanced Geothermal Systems

Research update on the suite of optical sensors for monitoring pressure and temperature in enhanced geothermal systems (EGS) that is also applicable to oil and gas wells.

Read Flipbook

High-Performance Hermetic Optical Fiber for Downhole Applications

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.

Read Flipbook

High Reliability Hermetic Optical Fiber for Oil and Gas Application

Optical fibers with improved hermeticity, strength and chemical resistance are presented.

Read Flipbook

Novel Optical Fiber Design for Hydrogen-rich Harsh Environment

A new class of novel optical fiber structure were designed for improved use in harsh environments typical of oil and gas applications.

Read Flipbook

Distributed Strain and Temperature Sensing Using Brillouin Scattering

This is a technology that allows the measurement of strain and temperature along a passive fiber optic element or waveguide path over long distances utilizing the phenomenon of Brillouin Scattering.

Read Flipbook

Distributed Temperature Sensing (DTS)

Distributed Temperature Sensing (DTS) is a technology that allows the measurement of temperature along a passive fiber optic element.

Read Flipbook

Benefits of Fiber Optics for Underground Mine Communications

Fiber optic cables and connectors are designed and qualified for use in mines by validating the mechanical strength required to install and operate the cable in an underground environment.

Read Flipbook

Return to Home