An apparatus for measuring liquid volume in a container includes a plurality of light sources for emitting electromagnetic radiation (EMR) toward the container, a plurality of sensors optically coupleable to the plurality of light sources, each sensor of the plurality of sensors for detecting the EMR emitted by at least a portion of the plurality of light sources, a temperature sensor for measuring at least one temperature associated with a liquid in the container, and at least one processor for receiving data representative of the portion of the detected EMR from each of the plurality of sensors, comparing the at least one measured temperature to a temperature guideline to identify any temperature events associated with the received data; normalizing the received data based on any temperature events associated with the received data; and converting the normalized data into a signature representative of the EMR detected by the plurality of sensors.

A water thermometer includes a housing; a thermometer assembly arranged in the housing; a suspending part, connected to the housing; and a lighting assembly arranged in the suspending part and configured to illuminate the thermometer assembly.

The present invention relates to a sensor for measuring temperature of a fluid within a vessel, the vessel having a first region and a second region and the fluid having a temperature profile extending between the first region and the second region, the sensor comprising an array of elements, each element having a temperature-dependent parameter, the array being capable of deployment within or adjacent the vessel such that the array extends along the vessel for measuring the temperature profile, the elements of the array being coupled together between an input and an output, the input being coupled or capable of being coupled to a driving source for driving the sensors, and the output being coupled or capable of being coupled to a detector for measuring an aggregate of the temperature-dependent parameter from the array of elements. The invention further relates to a fluid temperature controller comprising a first input for receiving a first signal indicating a measurement of an aggregate of a temperature-dependent parameter from a sensor deployed within or adjacent a vessel containing a fluid having a temperature profile, a second input for receiving a second signal indicating a (preferably absolute) temperature of the fluid in the vessel and a processor configured to calculate a total thermal energy of the fluid in the vessel based on the first and second signals. The invention also relates to a combination comprising a sensing arrangement and a controller; a device; and a system.

Various embodiments include a method for determining the thermal consumption of an energy system having a thermal energy storage unit, wherein the energy system generates a total thermal energy within a time range comprising: determining a thermal charging energy of the thermal energy storage unit within the time range; determining a thermal discharging energy of the thermal energy storage unit within the time range; and calculating a resulting thermal consumption within the time range using a sum of the total thermal energy and the difference between the ascertained thermal discharging energy and the ascertained thermal charging energy.

A measurement method for measuring the temperature of water in a meter includes the steps of: causing an emitter transducer of the meter to emit an ultrasonic measurement signal, and acquiring an electrical measurement signal produced by a receiver transducer of the meter; measuring a speed of the ultrasonic measurement signal in the water and a level of the electrical measurement signal; using the level of the electrical measurement signal to determine whether the temperature of the water is less than or greater than an inflection temperature corresponding to a point of inflection; estimating the temperature of the water from the speed of the ultrasonic measurement signal by using a first formula if the temperature of the water is less than the inflection temperature, and by using a second formula if the temperature of the water is greater than the inflection temperature.

A water leakage detection device for a water and sewage pipe is provided. The water leakage detection device includes a sound detector installation pipe having a tubular shape with the same cross-section as that of a hole formed in the water and sewage pipe at an interval and configured to allow one end thereof to be fixed and installed in the hole, and an adjustment valve installed on the inside spaced apart from an end part of the other end of the sound detector installation pipe at a predetermined interval and configured to adjust whether to introduce water inside the water and sewage pipe to the sound detector installation pipe.

A system includes sensors for monitoring signals, and a processing system executes one or more methods for identification of system events, from the signals, corresponding to state changes and performance of the system and/or its subcomponents. Event identification is performed with classification and/or other machine learning algorithms, with generation of novel training data sets. The sensor(s) can also be used to determine power consumption information about the system and/or its subcomponents. The system processes event-associated outputs for execution of actions for improving system performance, along with other downstream applications.

This refrigeration device comprises: a high temperature side refrigerant circuit in which a high temperature side refrigerant circulates; a low temperature side refrigerant circuit in which a low temperature side refrigerant circulates; and a cascade heat exchanger that cools the low temperature side refrigerant with the high temperature side refrigerant. In the low temperature side refrigerant circuit, a low temperature side decompressor is disposed downstream of the cascade heat exchanger and a temperature sensor is installed in a piping portion between the cascade heat exchanger and the low temperature side decompressor.

Systems and methods for monitoring underwater structures are provided. First and second sets of point cloud data that are obtained at different times are compared to determine whether the location of the underwater structure has changed. For detecting vibration, a series of range measurements taken along a line intersecting the underwater structure are compared to one another to determine an amplitude and frequency of any vibration present in the underwater structure. For detecting temperature, the ratio of different components of return signals obtained from a point in the water surrounding the underwater structure is measured to derive the temperature of the water. Leak detection can be performed by scanning areas around the underwater structure. Monitoring systems can include a primary receiver for range measurements, and first and second temperature channel receivers for temperature measurements.

Sensors, methods, and computer program products for air bubble detection are provided. An example method includes determining a first moving average for a first period of time based upon first temperature data and determining a second moving average for the first period of time based upon second temperature data. The method includes determining a first air presence parameter based upon a comparison between the first temperature data and the first moving average and a comparison between the second temperature data and the second moving average. The method includes determining a second air presence parameter based upon a comparison between the first temperature data, the second temperature data, and calibrated air thresholds. The method includes determining a third air presence parameter based upon a comparison between a first temperature data entry and each second temperature data entry. An air bubble within a fluid flow system is detected based upon the parameters.