Methods and systems for estimating remaining or utilized scrubbing capacity of a gas scrubber are described. Inside the gas scrubber, a reaction gas is produced by an exothermic or endothermic reaction. Temperature sensors are positioned along the gas flow path, and temperature readings are obtained. Temperature differences between pairs of adjacent temperature sensors are determined. The largest temperature difference for each such pair is recorded. A recent temperature difference is normalized by dividing the recent difference by the largest recorded for the same pair. One or more of the normalized temperature differences may be weighted. The normalized temperature differences and/or the weighted temperature differences are combined to provide a life-value, which is indicative of the remaining or utilized scrubbing capacity of the gas scrubber.

A calorimetry sensor having a porous substrate and a temperature sensitive resistive coating. The calorimetry sensor has a known temperature coefficient of resistance. A process utilizes the known temperature coefficient of resistance and monitors changes in resistance of the calorimetry sensor to determine changes in temperature (heat) within an environment, such as during reactions within an ALD reactor.

A calorimetry sensor having a porous substrate and a temperature sensitive resistive coating. The calorimetry sensor has a known temperature coefficient of resistance. A process utilizes the known temperature coefficient of resistance and monitors changes in resistance of the calorimetry sensor to determine changes in temperature (heat) within an environment, such as during reactions within an ALD reactor.

An expectation module determines an expected average power consumption of a heat pump for a predetermined period as a function of indoor and outdoor temperatures of the building during the predetermined period. A difference module determines a power difference between an average power consumption of the heat pump during the predetermined period and the expected average power consumption of the heat pump for the predetermined period. A grade determination module determines a grade of the heat pump for the predetermined period based on the power difference of the predetermined period. A reporting module generates a displayable report including the grade of the heat pump for the predetermined period.

An expectation module determines an expected average power consumption of a heat pump for a predetermined period as a function of indoor and outdoor temperatures of the building during the predetermined period. A difference module determines a power difference between an average power consumption of the heat pump during the predetermined period and the expected average power consumption of the heat pump for the predetermined period. A grade determination module determines a grade of the heat pump for the predetermined period based on the power difference of the predetermined period. A reporting module generates a displayable report including the grade of the heat pump for the predetermined period.

A pump controller or control device for determining a through-flow quantity in a fluid delivery system, in which a fluid is delivered by a pump, the pump including an electromotor operated at a first speed when the electromotor is in operation and the through-flow quantity being determined from a measured motor power and the speed. A method of using the pump controller or control device includes (i) increasing the first speed to a second speed which is greater than the first speed; (ii) determining a second through-flow quantity at the second speed from the motor power and the second speed; (iii) determining a third through-flow quantity from the second through-flow quantity by extrapolation of the second speed to the first speed, wherein the third through-flow quantity is the target variable; and, (iv) reducing the speed back to the first speed once the second through-flow quantity has been determined.

A pump controller or control device for determining a through-flow quantity in a fluid delivery system, in which a fluid is delivered by a pump, the pump including an electromotor operated at a first speed when the electromotor is in operation and the through-flow quantity being determined from a measured motor power and the speed. A method of using the pump controller or control device includes (i) increasing the first speed to a second speed which is greater than the first speed; (ii) determining a second through-flow quantity at the second speed from the motor power and the second speed; (iii) determining a third through-flow quantity from the second through-flow quantity by extrapolation of the second speed to the first speed, wherein the third through-flow quantity is the target variable; and, (iv) reducing the speed back to the first speed once the second through-flow quantity has been determined.

A sensor capsule for a heat flux sensor includes a hot end and a cold end. The sensor capsule includes a thermal conductor extending from the hot end toward the cold end, and a plurality of temperature sensors coupled to the thermal conductor at different distances from the hot end.

A sensor capsule for a heat flux sensor includes a hot end and a cold end. The sensor capsule includes a thermal conductor extending from the hot end toward the cold end, and a plurality of temperature sensors coupled to the thermal conductor at different distances from the hot end.

A method for determining the temperature of a metal strip (1) inside a cooling apparatus (4) of a hot rolling installation is implemented by an electronic device (12). This method includes acquiring a temperature measure of a strip portion at a current time instant; estimating, at the current time instant, a heat flux extracted from the strip portion inside the cooling apparatus according to a thermal model, and computing a strip portion temperature at a next time instant from the acquired temperature measure and the estimated extracted heat flux. The thermal model models an air cooling of the strip portion, a coolant header cooling of the strip portion by a coolant header and a remaining coolant cooling of the strip portion, wherein for the coolant header cooling the model models both an impingement cooling of the strip portion and a parallel flow cooling of the strip portion.