An explosion-proof electronic system. The system comprises a substantially explosion-proof enclosure, a disk that is free to rotate about an axis, where the disk is located within the enclosure, an optical sensor that is configured to sense rotation of the disk, where the optical sensor is located within the enclosure, and a processor that is coupled to the optical sensor and analyzes a rotation input from the optical sensor to control in part the operation of the electronic system.

A gas meter system is configured to: derive a unit heating value of a gas passing through a first gas meter; and estimate a heating value of a gas passing through a second gas meter provided separately from the first gas meter based on the heating value of the gas of the first gas meter that is arranged within a predetermined range with respect to the second gas meter on a gas supply pipe configured to supply the gas. The gas meter system and a heating value estimation method can estimate a heating value of a gas with high accuracy.

A system for remote detection of fluid leaks from a natural gas or oil pipeline including a laser light source for detecting a methane leak while sweeping in multiple directions, a Midwave Infrared (MWIR) detector optically coupled with the laser light source and a controller operatively connected to the laser light source and the MWIR detector for aggregating data collected by the laser light source and the MWIR using a nuropmophic flow detection algorithm including computational fluid dynamic models.

An end treatment for use with an ultrasonic gas flow meter includes an attenuation section having a pipe extending in a longitudinal direction and containing alternating sets of laterally spaced and vertically oriented first and second solid wall plates located between an inlet end and an outlet end of the pipe. One plate includes a first end connected to an inside wall of the pipe and another plate includes a second end that extends past a longitudinal centerline of the pipe to define a gap between the end of the plate and a respective opposing inside wall of the pipe. As the gas traverses the plates by flowing through the gaps, the ultrasonic waves are prevented from reflecting back to the flow meter.

Systems and methods use sound waves for evaluating a fuel. The fuel supplied from a storage tank to an engine by a feed pipe can be evaluated by determining its properties based on the velocity of one or more sound waves in the fuel.

A system and method for multi-spectral gas concentration analysis that includes using a library of multiple sets of optimized spectral sensitivities prepared in advance, and a multi-spectral IR gas analyzer tuned to a set of optimized spectral sensitivity. The multi-spectral IR gas analyzer measures spectral absorption of gas using one or more different sets of optimized spectral sensitivities.

A measurement unit (101) acquires a first value serving as a thermal conductivity index and a second value serving as a thermal diffusivity index, with respect to a fuel gas to be measured, at a first temperature, a second temperature, and a third temperature that are different from each other. A change rate calculation unit (102) calculates a temperature change rate κ.sub.1 of the first value between the first temperature and the second temperature, measured by the measurement unit (101), a temperature change rate κ.sub.2 of the first value between the second temperature and the third temperature, a temperature change rate α.sub.1 of the second value between the first temperature and the second temperature, and a temperature change rate α.sub.2 of the second value between the second temperature and the third temperature. A calorific value calculation unit (103) calculates the calorific value of the fuel gas through a calorific value calculation formula in which the κ.sub.1, κ.sub.2, α.sub.1, and α.sub.2 serve as explanatory variables and the calorific value serves as an object variable.

An apparatus for detecting the presence of liquid in a high pressure gas pipeline (4) is described. The apparatus comprises a sight glass (2), providing a window into the inside of the pipeline, and a light sensor (1), for receiving and sensing reflected light from the inside of the pipeline through the sight glass. The apparatus also comprises a processor, for automatically detecting the presence of a liquid based on the sensed reflected light. In this way, automatic detection of the presence of liquid in a gas pipeline can be achieved based on the measurement of reflected light, which can be expected to differ when liquid is present compared with when no liquid is present. No visual inspection by an operator is required—although the data can be stored for later operator use or verification if necessary.

A method for determining an energy content of a hydrogen-rich gas mixture using a gas density meter (101) is provided. The method includes the steps of providing a vibratory gas density meter (101) and meter electronics (112) with the gas density meter (101). The meter electronics (112) communicate with at least one external input (116). The meter electronics (112) are configured to measure a density of the hydrogen-rich gas mixture, measure a specific gravity of the hydrogen-rich gas mixture, and derive a calorific value of the hydrogen-rich gas mixture using the derived specific gravity and a plurality of constant values.

A system for remote detection of fluid leaks from a natural gas or oil pipeline including a laser light source for detecting a methane leak while sweeping in multiple directions, a Midwave Infrared (MWIR) detector optically coupled with the laser light source and a controller operatively connected to the laser light source and the MWIR detector for aggregating data collected by the laser light source and the MWIR using a nuropmophic flow detection algorithm including computational fluid dynamic models.