New Paper Evaluates Space Station Fire Detector Performance

The paper explains that not all of the particles were consistently detected, so the authors recommend that the next generation of spacecraft fire detectors must be improved and tested against smoke from relevant space materials.

  • May 03, 2018

A new paper published in Fire Safety Journal by a team of NASA and NIST researchers describes their evaluation of smoke particles produced by five materials commonly used aboard crewed spacecraft and how well they can be detected by two traditional systems. A NIST news release on May 1 describes a tense moment in February 1997 aboard the Russian space station Mir, when its crew -- including U.S. astronaut Jerry Linenger -- had to extinguish a burning lithium-perchlorate canister that was designed to generate oxygen via a chemical reaction. "Although the fire was quickly subdued, a dense, life-threatening smoke—different in form and movement from its gravity bound counterpart on Earth—rapidly filled the station. Being confined in a limited area 360 kilometers (224 miles) above the nearest fire brigade made the situation even more precarious," the release states.

NASA has teamed with the National Institute of Standards and Technology (NIST) since 2002 to study the behavior of smoke in microgravity. The paper explains that not all of the particles were consistently detected, so the authors recommend that the next generation of spacecraft fire detectors must be improved and tested against smoke from relevant space materials.

They tested smoke particles from material used in experiments aboard the International Space Station, including cotton fiber, Kapton (a polymer for thermal insulation), silicone rubber (for seals and gaskets), Teflon (for insulating wires), and Pyrell (polyurethane foam for packing). While the large particles produced by overheating the cellulose, silicone, and Pyrell samples were easily picked up by the light-scattering photoelectric ISS detector, it frequently could not detect the smaller smoke particles from Teflon and Kapton.

Product Showcase

  • Magid® D-ROC® GPD412 21G Ultra-Thin Polyurethane Palm Coated Work Gloves

    Magid’s 21G line is more than just a 21-gauge glove, it’s a revolutionary knitting technology paired with an advanced selection of innovative fibers to create the ultimate in lightweight cut protection. The latest offering in our 21G line provides ANSI A4 cut resistance with unparalleled dexterity and extreme comfort that no other 21-gauge glove on the market can offer! Read More

  • Matrix's OmniPro Vision AI Collision Avoidance System

    OmniPro Vision AI is a state-of-the-art collision avoidance system that features NIOSH award-winning Visual Artificial Intelligence (AI) technology. This highly accurate, powerful system identifies and alerts on pedestrians, vehicles and specified objects, ensuring safer facilities, mining operations and industrial sites. With its web-based cloud application, OmniPro Vision AI also logs and analyzes a wide range of data related to zone breach notifications. Operating without needing personal wearable devices or tags, OmniPro has visual and audible zone breach alerts for both operators and pedestrians. Read More

  • NoiseCHEK Personal Noise Dosimeter

    SKC NoiseCHEK is the easiest-to-use dosimeter available! Designed specifically for OEHS professionals, SKC NoiseCHEK offers the easiest operation and accurate noise measurements. Everything you need is right in your palm. Pair Bluetooth models to your mobile devices and monitor workers remotely with the SmartWave dB app without interrupting workflow. Careful design features like a locking windscreen, sturdy clip, large front-lit display, bright status LEDs, and more make NoiseCHEK the top choice in noise dosimeters. Demo NoiseCHEK at AIHA Connect Booth 1003. Read More

Featured

Most   Popular

Artificial Intelligence