Original Altair 4X 5X 10106729 O2 Gas Sensor MSA XCell O2 Oxygen Cell With Best Price

Supplemental Technical Data Sheet This information contained within this document is a supplement to the MSA transmitter user manual. Applicable Product(s): • ULTIMA® X5000 Gas Monitor • General Monitors S5000 Gas Monitor RANGE X5000 GAS CODE S5000 GAS CODE DEFAULT SPAN VALUE DEFAULT ALARM 1 DEFAULT ALARM 2 0–25% Vol. 16 D16 20.8 19.5 18.0 SENSOR DESIGN Non-consuming Electrochemical Sensor SAFESWAP Sensor can be changed under power WARRANTY/SHELF LIFE 3 years SENSOR LIFE2 > 5 years CALIBRATION FREQUENCY REGULATOR ZERO GAS For greatest accuracy and zero stability, allow powered sensor 24 hours to acclimate before performing first calibration. Every 3-6 months 1 LPM Not required ACCURACY1,4 < ±1% of measured value LINEARITY1 < ±2% of measured value OPERATING TEMPERATURE RANGE –40°C to 60°C (–40°F to 140°F) OPERATING HUMIDITY RANGE INTERMITTENT CONTINUOUS 0% to 100 % relative humidity 10% to 95% r.h. non-condensing OPERATING PRESSURE RANGE 800–1200 mbar TEMPERATURE EFFECT ZERO SENSITIVITY No effect No effect HUMIDITY EFFECTS No effect PRESSURE EFFECTS No effect ZERO DRIFT1 < 0.2% Vol/year SPAN DRIFT1 < 0.2% Vol/year RESPONSE TIME T50 1 T90 1 RECOVERY T90 1 < 6 seconds < 11 seconds < 13 seconds GAS EXPOSURE LIMITATION3 Not intended for continuous inert monitoring WARM-UP TIME (X5000, S5000)1 30 min. May require longer warm up times, see manual. For optimum sensor performance, allow sensor 24 hours to acclimate to conditions before performing first calibration. ADDITIONAL CONSIDERATIONS Lead-free design 1 All performance values are typical as applied to new sensors in ambient laboratory conditions. 2 Individual results may vary based on individual sensor environmental exposure conditions. 3 As tested per ISA standards. ⁴ Does not account for variances in calibration gas accuracy. Our Mission MSA’s mission is to see to it that men and women may work in safety and that they, their families and their communities may live in health throughout the world. MSA: WE KNOW WHAT’S AT STAKE. Note: This Bulletin contains only a general description of the products shown. While product uses and performance capabilities are generally described, the products shall not, under any circumstances, be used by untrained or unqualified individuals. The products shall not be used until the product instructions/user manual, which contains detailed information concerning the proper use and care of the products, including any warnings or cautions, have been thoroughly read and understood. Specifications are subject to change without prior notice. MSA operates in over 40 countries worldwide. To find an MSA office near you, please visit MSAsafety.com/offices. 0720-222-MC / 02.2020 MSAsafety.com/detection © MSA 2020 Why MSA XCell® O₂ Sensors? Longer Life! The electrochemical system in the MSA XCell O₂ Sensor uses a non-consuming chemical reaction. O₂ molecules entering the sensor react with the working electrode creating electron flow and water as a byproduct. At the counter electrode, water is converted back into O₂ molecules. The chemical reaction requires a low voltage, which is controlled by the application-specific integrated circuit (ASIC) in the XCell Sensor. Because nothing is consumed or “used up” as the sensor is functioning, the sensor has a longer lifespan. XCell O₂ Sensors have a typical life of more than four years. This non-consuming chemical reaction also means that the sensor can have a much longer shelf-life. The chemical reaction in a traditional lead-based O₂ sensor starts the second the sensor is manufactured. At this time, the chemical process whereby the lead is converted to lead oxide begins and the finite sensor life begins. The MSA XCell O₂ sensor is designed to have a very long shelf-life. While the sensor sits un-powered, no chemical reactions with O₂ are taking place and no life is being depleted from the sen