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A crucial enabling technology for the secure implementation of the emerging hydrogen infrastructure are hydrogen ambient safety sensors.
Hydrogen detectors are required by the codes, but there is currently little guidance on how to deploy them. The Safety Sensor Testing Laboratory strives to bridge the gap between code requirements and end-user requirements in support of NREL Safety Codes and Standards Projects.
Manufacturers utilize different technologies to make sensors, resulting in a wide range of operating characteristics.
When installing sensors, it is important to understand these operating characteristics and to have products validated to meet the needs of each application.
In the market for hydrogen ambient safety sensors, the integration of the Industrial Internet of Things (IIoT) and the data generated by sensors to connect businesses’ most important assets is still in its infancy.
Digital technologies combined with advanced analytics have demonstrated an enormous untapped potential to enhance workplace safety and lessen employee risk.
The market is expected to expand exponentially in the future thanks to smart and low concentration HS technologies.
Among the various industries, the oil and gas industry is one of the largest and generates a global revenue of around US$ trillions annually.
The Global Hydrogen Ambient Safety Sensor market accounted for $XX Billion in 2022 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2023 to 2030.
NTM SenseH – Hydrogen Sensor – Designed for hydrogen monitoring, this ceramic sensor exhibits a highly sensitive, selective, and rapid response to the presence of hydrogen in ambient air.
It reliably measures hydrogen concentrations over a wide range of temperature and humidity variation and provides a repeatable response, even in the presence of other combustible gases.
Additionally, the NTM SenseH hydrogen sensor is immune to signal saturation upon continuous exposure to low levels of hydrogen, and recovers rapidly and completely upon hydrogen removal.
The sensor element employs a patent‐pending, chemi‐resistive ceramic technology, which provides accurate and reliable hydrogen detection.
It is a three‐pin calorimetric hydrogen sensor with a catalytically highly active and siloxane‐resistant sensor element and is based on a non‐isothermal calorimetric operation principle.
It contains on‐board electronics to reduce the effect of ambient temperature changes on hydrogen sensitivity and to provide appropriate output signals.
It is designed for use in a variety of applications which require a warning signal in the presence of potentially dangerous hydrogen concentrations in the ambient air
