The invention provides a method of verifying the health of a liquid level detection device, preferably a vibrating fork level switch, while the device remains in situ. The method includes, independently of the device, verifying if the fork tines are fully wet or fully dry. This step can be carried out by a further, independent, level measuring apparatus.

The invention provides a method of verifying the health of a liquid level detection device, preferably a vibrating fork level switch, while the device remains in situ. The method includes, independently of the device, verifying if the fork tines are fully wet or fully dry. This step can be carried out by a further, independent, level measuring apparatus.

A method of adjusting a quantization accuracy of a fill level radar for detecting a fill level of a container is provided, the method including the steps of: acquiring amplitude values of an echo curve of the fill level radar by an analog-to-digital converter (ADC); determining a first amplitude value of a first echo having a highest amplitude or a highest local amplitude maximum of the echo curve; determining a second amplitude value of a second echo having a lowest local amplitude maximum of the echo curve; setting an adjusted quantization accuracy as a function of a quotient of the first amplitude value and the second amplitude value; and determining the fill level of the container with the adjusted quantization accuracy. A field device including a fill level radar and/or an ultrasonic measuring device configured to perform the method is also provided.

A method of adjusting a quantization accuracy of a fill level radar for detecting a fill level of a container is provided, the method including the steps of: acquiring amplitude values of an echo curve of the fill level radar by an analog-to-digital converter (ADC); determining a first amplitude value of a first echo having a highest amplitude or a highest local amplitude maximum of the echo curve; determining a second amplitude value of a second echo having a lowest local amplitude maximum of the echo curve; setting an adjusted quantization accuracy as a function of a quotient of the first amplitude value and the second amplitude value; and determining the fill level of the container with the adjusted quantization accuracy. A field device including a fill level radar and/or an ultrasonic measuring device configured to perform the method is also provided.

A temperature control device includes a first tank that stores a first heat medium; a second tank that stores a second heat medium having a temperature different from a temperature of the first heat medium, and a first communication pipe configured to connect a position where an upper limit level of a height of a liquid level is located in an interior of the first tank and a position where a lower limit level of a height of a liquid level is located in an interior of the second tank.

A temperature control device includes a first tank that stores a first heat medium; a second tank that stores a second heat medium having a temperature different from a temperature of the first heat medium, and a first communication pipe configured to connect a position where an upper limit level of a height of a liquid level is located in an interior of the first tank and a position where a lower limit level of a height of a liquid level is located in an interior of the second tank.

A draft survey apparatus for gauging a barge by determining a weight of bulk materials loaded and discharged from the barge in water wherein the water level is provided. The draft survey apparatus includes a light source for emitting photons radially outward from the light source, a receiver for receiving the photons reflected off of the barge and surface, the receiver operable to sense a return angle of the photons, and a processor operable to determine a position of the objects and surfaces in three dimensional space based on the return angle of the photons and a time delay of photons between emission and receipt. The processor is operable to determine the weight of the bulk materials on the barge based on a height of barge above the water level.

Techniques for monitoring a well clean-up process are disclosed. In one embodiment, a method includes routing a multiphase fluid having oil and water to a separator of a well testing apparatus, separating the multiphase fluid into separate fluids via the separator, and routing the separated fluids away from the separator. The method also includes measuring flow rates of oil and water leaving the separator and determining individual flow rates of oil and water entering the separator as part of the multiphase fluid based on the measured flow rates of oil and water leaving the separator. Additional systems, methods, and devices are also disclosed.

Techniques for monitoring a well clean-up process are disclosed. In one embodiment, a method includes routing a multiphase fluid having oil and water to a separator of a well testing apparatus, separating the multiphase fluid into separate fluids via the separator, and routing the separated fluids away from the separator. The method also includes measuring flow rates of oil and water leaving the separator and determining individual flow rates of oil and water entering the separator as part of the multiphase fluid based on the measured flow rates of oil and water leaving the separator. Additional systems, methods, and devices are also disclosed.

A point level switch for industrial interface detection is described, the switch including a microwave waveguide sensor in place of the more commonly encountered vibrating fork.