Gas detector: Difference between revisions
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Oxygen deficiency gas monitors are used for employee and workforce safety. [[Cryogenics|Cryogenic]] substances such as [[liquid nitrogen]] (LN2), liquid [[helium]] (He), and liquid [[argon]] (Ar) are inert and can displace oxygen (O<sub>2</sub>) in a confined space if a leak is present. A rapid decrease of oxygen can provide a very dangerous environment for employees. With this in mind, an oxygen gas monitor is important to have when cryogenics are present. Laboratories, [[Magnetic resonance imaging|MRI]] rooms, pharmaceutical, semiconductor, and cryogenic suppliers are typical users of oxygen monitors. |
Oxygen deficiency gas monitors are used for employee and workforce safety. [[Cryogenics|Cryogenic]] substances such as [[liquid nitrogen]] (LN2), liquid [[helium]] (He), and liquid [[argon]] (Ar) are inert and can displace oxygen (O<sub>2</sub>) in a confined space if a leak is present. A rapid decrease of oxygen can provide a very dangerous environment for employees. With this in mind, an oxygen gas monitor is important to have when cryogenics are present. Laboratories, [[Magnetic resonance imaging|MRI]] rooms, pharmaceutical, semiconductor, and cryogenic suppliers are typical users of oxygen monitors. |
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Oxygen monitors use several types of sensors. There is an Oxygen Monitor which uses a Zirconium Oxide Sensor, and |
Oxygen monitors use several types of sensors. There is an Oxygen Monitor which uses a Zirconium Oxide Sensor, and the O2 Monitor that uses the Electrochemical (Disposable) Sensor. The Zirconium Oxide sensor is a 10+ Year Sensor which does not need calibration or maintenance. The most common sensor used is the Electrochemical Disposable Sensor. More recently, the Zirconium Oxide Sensors are becoming more well known for its long-life and ease of maintenance without calibration. EC sensors are disposable sensors which require calibration quarterly, and are required to be replaced after the sensor has been depleted. Life expectancy averages around 1-2 Years for the EC Sensor, whereas the Zirconium Oxide Sensor is 10+ Years. |
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Oxygen fraction in a breathing gas is measured by [[electro-galvanic fuel cell]] sensors. They may be used stand-alone, for example to determine the proportion of oxygen in a [[nitrox]] mixture used in [[scuba diving]],<ref name=DANnitrox>{{cite book |title=DAN Nitrox Workshop Proceedings |author=Lang, M.A. |year=2001 |publisher=Divers Alert Network |location=Durham, NC |page=197 |url=http://archive.rubicon-foundation.org/4855 |accessdate=2009-03-20 }}</ref> or as part of feeback loop which maintains a constant [[partial pressure]] of oxygen in a [[rebreather]].<ref name=Goble>{{cite journal |author=Goble, Steve |title=Rebreathers |journal=[[South Pacific Underwater Medicine Society]] Journal |volume=33 |issue=2 |year=2003 |pages=98–102 |url=http://archive.rubicon-foundation.org/7782 |accessdate=2009-03-20 }}</ref> |
Oxygen fraction in a breathing gas is measured by [[electro-galvanic fuel cell]] sensors. They may be used stand-alone, for example to determine the proportion of oxygen in a [[nitrox]] mixture used in [[scuba diving]],<ref name=DANnitrox>{{cite book |title=DAN Nitrox Workshop Proceedings |author=Lang, M.A. |year=2001 |publisher=Divers Alert Network |location=Durham, NC |page=197 |url=http://archive.rubicon-foundation.org/4855 |accessdate=2009-03-20 }}</ref> or as part of feeback loop which maintains a constant [[partial pressure]] of oxygen in a [[rebreather]].<ref name=Goble>{{cite journal |author=Goble, Steve |title=Rebreathers |journal=[[South Pacific Underwater Medicine Society]] Journal |volume=33 |issue=2 |year=2003 |pages=98–102 |url=http://archive.rubicon-foundation.org/7782 |accessdate=2009-03-20 }}</ref> |
Revision as of 22:36, 28 November 2012
A gas detector is a device which detects the presence of various gases within an area, usually as part of a safety system. This type of equipment is used to detect a gas leak and interface with a control system so a process can be automatically shut down. A gas detector can also sound an alarm to operators in the area where the leak is occurring, giving them the opportunity to leave the area. This type of device is important because there are many gases that can be harmful to organic life, such as humans or animals.
Gas detectors can be used to detect combustible, flammable and toxic gases, and oxygen depletion. This type of device is used widely in industry and can be found in a variety of locations such as on oil rigs, to monitor manufacture processes and emerging technologies such as photovoltaic. They may also be used in firefighting.
Gas detectors are usually battery operated. They transmit warnings via a series of audible and visible signals such as alarms and flashing lights, when dangerous levels of gas vapors are detected. As detectors measure a gas concentration, the sensor responds to a calibration gas, which serves as the reference point or scale. As a sensor’s detection exceeds a preset alarm level, the alarm or signal will be activated. As units, gas detectors are produced as portable or stationary devices. Originally, detectors were produced to detect a single gas, but modern units may detect several toxic or combustible gases, or even a combination of both types.[1]
Types
Gas detectors can be classified according to the operation mechanism (semiconductors, oxidation, catalytic, infrared, etc.).Gas detectors come in two main types: portable devices and fixed gas detectors. The first is used to monitor the atmosphere around personnel and is worn on clothing or on a belt/harness. Examples of gases monitored are HCL, Oxygen, HF, Hbr, LEL, and corrosives. The second type of gas detectors are fixed type which may be used for detection of one or more gas types. Fixed type detectors are generally mounted near the process area of a plant or control room. Generally, they are installed on fixed type mild steel structures and a cable connects the detectors to a SCADA system for continuous monitoring and where a tripping interlock can be activated for an emergency situation.
Newer gas analyzers can break up the component signals in a complicated aroma to identify several gasses simultanouesly.[2]
Gas detector calibration
All gas detectors must be calibrated on a schedule. Of the two types of gas detectors, portables must be calibrated more frequently due to the regular changes in environment they experience. A typical calibration schedule for a fixed system may be quarterly, bi-annually or even annually with some of the more robust units. A typical calibration schedule for a portable gas detector is a daily bump test accompanied by a monthly calibration.[3] Almost every portable gas detector out there has a specific calibration gas requirement which is available from the manufacturer you purchased your monitor from.
Oxygen concentration
Oxygen deficiency gas monitors are used for employee and workforce safety. Cryogenic substances such as liquid nitrogen (LN2), liquid helium (He), and liquid argon (Ar) are inert and can displace oxygen (O2) in a confined space if a leak is present. A rapid decrease of oxygen can provide a very dangerous environment for employees. With this in mind, an oxygen gas monitor is important to have when cryogenics are present. Laboratories, MRI rooms, pharmaceutical, semiconductor, and cryogenic suppliers are typical users of oxygen monitors.
Oxygen monitors use several types of sensors. There is an Oxygen Monitor which uses a Zirconium Oxide Sensor, and the O2 Monitor that uses the Electrochemical (Disposable) Sensor. The Zirconium Oxide sensor is a 10+ Year Sensor which does not need calibration or maintenance. The most common sensor used is the Electrochemical Disposable Sensor. More recently, the Zirconium Oxide Sensors are becoming more well known for its long-life and ease of maintenance without calibration. EC sensors are disposable sensors which require calibration quarterly, and are required to be replaced after the sensor has been depleted. Life expectancy averages around 1-2 Years for the EC Sensor, whereas the Zirconium Oxide Sensor is 10+ Years.
Oxygen fraction in a breathing gas is measured by electro-galvanic fuel cell sensors. They may be used stand-alone, for example to determine the proportion of oxygen in a nitrox mixture used in scuba diving,[4] or as part of feeback loop which maintains a constant partial pressure of oxygen in a rebreather.[5]
Hydrocarbons and VOCs
Detection of hydrocarbons can be based on the mixing properties of gaseous hydrocarbons – or other volatile organic compounds (VOCs) – and the sensing material incorporated in the sensor.[6] The selectivity and sensitivity depends on the molecular structure and concentration; however it is difficult to design a sensor capable of detecting only one single type of molecule.
Combustible
Other
- Flame ionization detector
- Nondispersive infrared sensor
- Photoionization detector
- Zirconium oxide sensor cell
- Catalytic sensors
- Metal oxide semiconductor
- Gold film
- Detector tubes
- Sample collection and chemical analysis
- Piezoelectric microcantilever
- Holographic Sensor
- Thermal Conductivity Detector
Notable manufacturers
* BAPIwww.bapihvac.com
- Honeywell Analytics
- Sensor Electronics Corporation
- Dräger
- Industrial Scientific Corporation
- ESP Safety Inc.
- Buveco Sensor Electronics Corporation Gasdetection B.V.
- [BAPI]
See also
References
- ^ How Gas Detectors Work
- ^ Wali, Russeen (2012). "An electronic nose to differentiate aromatic flowers using a real-time information-rich piezoelectric resonance measurement". Procedia Chemistry. doi:10.1016/j.proche.2012.10.146.
{{cite journal}}
: CS1 maint: date and year (link) - ^ Moore, James. "Calibration: Who Needs It?". Occupational Health and Safety Magazine.
- ^ Lang, M.A. (2001). DAN Nitrox Workshop Proceedings. Durham, NC: Divers Alert Network. p. 197. Retrieved 2009-03-20.
- ^ Goble, Steve (2003). "Rebreathers". South Pacific Underwater Medicine Society Journal. 33 (2): 98–102. Retrieved 2009-03-20.
- ^ holographic sensor