A sensor configured to measure rate of flow of fugitive emissions on a flow control. The configurations may include devices that are sensitive to low flow or low pressure. These devices may include piezo-electric films or foams. These materials may deflect in response to flow of fluid along the outer surface of the reciprocating shaft. In one implementation, the embodiments can generate average leak rate over time and measure against regulation or specifications to ensure appropriate operation (e.g., leak suppression) of the flow control. Storing this data can provide a database of information that allows operators to benchmark performance of the flow control, for example, to correlate leaks to a certain date or time. This feature may, in turn, permit the operators to also correlate the device-specific performance to overall plant or network operations.

A valve operator for a valve includes a valve operator housing defining at least one cavity and positioned to be at least partially contiguous with a valve stem passage of the valve. The cavity has a fixed volume and is sealed from the exterior environment. The valve operator includes a fugitive emissions detector having at least one sensor for measuring the pressure and temperature of the fluid within the interior of the cavity. The detector also includes a processor having an input for receiving data from the at least one sensor, a processing unit connected to the input to receive the data from the input and monitor changes in the amount of substance within the cavity by comparison of changes in temperature and pressure within the cavity and an output for providing an indication of fugitive emissions when the processor indicates an increase in substance within the cavity.

A leak detector assembly for use with a backflow prevention device includes a housing defining a passageway for receiving a fluid. A flap assembly couples to the housing for generating a low flow error signal indicating minimal fluid passing through the passageway and a fully actuated error signal indicating significant fluid passing through the passageway. The flap assembly includes a flap mounted in the passageway such that significant flow of the fluid moves the flap to generate the fully actuated error signal. The flap assembly also includes a sensing element on the flap to determine a presence of the fluid without movement of the flap to generate the low flow error signal based on a low flow of the fluid.

A flood prevention system includes a first load, a second load, a third load, a fourth load, a first compressor, a first temperature sensor, a second temperature sensor, and a controller. The first, second, third, and fourth loads are configured to use a refrigerant to remove heat from a first, second, third, and fourth space, respectively, proximate to the first, second, third, and fourth load, respectively. The first compressor is configured to compress the refrigerant from the fourth load. The first temperature sensor is configured to detect a first temperature of the refrigerant from the first load, the second load, and the third load. The second temperature sensor is configured to detect a second temperature of the refrigerant from the first load, the second load, the third load, and the compressor. The controller is configured to trigger an alarm in response to certain conditions.

A leak detector assembly for use with a backflow prevention device includes a housing defining a passageway for receiving a fluid. A flap assembly couples to the housing for generating a low flow error signal indicating minimal fluid passing through the passageway and a fully actuated error signal indicating significant fluid passing through the passageway. The flap assembly includes a flap mounted in the passageway such that significant flow of the fluid moves the flap to generate the fully actuated error signal. The flap assembly also includes a sensing element on the flap to determine a presence of the fluid without movement of the flap to generate the low flow error signal based on a low flow of the fluid.

A sensor configured to measure rate of flow of fugitive emissions on a flow control. The configurations may include devices that are sensitive to low flow or low pressure. These devices may include piezo-electric films or foams. These materials may deflect in response to flow of fluid along the outer surface of the reciprocating shaft. In one implementation, the embodiments can generate average leak rate over time and measure against regulation or specifications to ensure appropriate operation (e.g., leak suppression) of the flow control. Storing this data can provide a database of information that allows operators to benchmark performance of the flow control, for example, to correlate leaks to a certain date or time. This feature may, in turn, permit the operators to also correlate the device-specific performance to overall plant or network operations.

A device for detecting and catching a leak from a fire sprinkler includes a leak sensor configured to detect the leak, and a leak catcher configured to catch the leak before the leak makes contact with surrounding areas. The device also includes an alarm module configured to issue a notification upon detection of the leak, and a mounting mechanism configured to removably mount the leak sensor, the leak catcher, and the alarm module to the fire sprinkler in a manner that does not obstruct operation of the fire sprinkler.

A CNG leak detection system has a plurality of CNG tanks. A plurality of control valve mechanisms, equal in number to the plurality of CNG tanks, is coupled with each CNG tank. A sensor is coupled with each control valve mechanism. The sensor monitors the CNG in the tank. A processor is electrically coupled with the sensor. A display is coupled with the processor to display the sensed condition of at least one desired tank of the plurality of tanks.

A liquid leakage detector, LLD, configured to detect liquid leaking from a liquid containing/guiding element. The LLD comprises a pipe configured to receive liquid leaking from a predefined area of the liquid containing/guiding element and a sensor that detects liquid entering the pipe. The LLD comprises a first connection structure configured to be connected to and hereby bring the LLD into fluid communication with a first liquid transport structure of the liquid containing/guiding element, such that the first connection structure extends from and protrudes from the first liquid transport structure and a second connection structure configured to be connected to and hereby bring the LLD into fluid communication with a second liquid transport structure, such that the second connection structure extends from and protrudes from the second liquid transport structure. The LLD comprises an insulator arranged and configured to electrically separate the sensor from the liquid transport structures.

This application relates to a leak detector device (100) for detecting an internal leak in a fluid path. The leak detector comprises a housing (110) with a flow passage (120) extending through the housing (110), one or more pairs of temperature sensors (130, 140) for detecting a temperature difference between an outside of the housing (110) and the flow passage (120), one temperature sensor of each pair being arranged towards an outer surface of the housing (110) and the other temperature sensor of the pair being arranged towards an innersurface of the housing (110) that faces the flow passage (120), and an array of electrically conductive wires (150, 160) that extend across the flow passage (120). The array of electrically conductive wires (150, 160) comprises one or more positive polarity wires and one or more negative polarity wires. The application further relates to a corresponding method of leak detection.