A wireless drink container can monitor a person's hydration and prompt him or her to drink more if appropriate. The drink containers as described herein can monitor liquid levels and communicate with external devices about the liquid levels and rate of consumption. One or more sensors in the drink container monitor the liquid level within the container. A processor coupled to the sensor(s) estimates how much liquid has been removed from the container from changes in the liquid level and transmits a signal representing the change in liquid level to a smartphone or other external device. It also triggers an audio or visual indicator, such as an LED, that prompts the user to drink more based on the user's estimated liquid consumption and on the user's liquid consumption goals, which may be based on the user's physiology, activity level, and location.

A molten metal level measuring device in a continuous molten metal level measuring device uses temperature compensation. The device includes a cylindrical bobbin, a liquid level measuring unit helically wound around an outer surface of the bobbin, a circular inner cylinder in which the bobbin and the liquid level measuring part are located and which seals the bobbin and the liquid level measuring part from the outside and has the same axial direction as the bobbin, and a cylindrical protective tube in which the inner cylinder is located and which has the same axial direction as the bobbin and has one open end. Thermocouples extend axially in the space between the inner cylinder and the protective tube, and a control unit controls the liquid level measuring part to measure a liquid level of the molten metal based on the temperatures measured by the thermocouples.

Methods for determining variability in a state of a medium, include monitoring the medium and determining the variability in the state of the medium based on the processing of the response over time based on the response detected at the at least one receive element over time. Monitoring the medium can include generating a transmit signal, transmitting it into the medium using a transmit element, and receiving a signal from the medium at a receive element. The transmit and receive elements can be decoupled from one another. The transmit and receive elements can have differing geometry. The determined variability in the state of the medium can be used to provide notifications and/or take automated actions.

A wireless drink container can monitor a person's hydration and prompt him or her to drink more if appropriate. The drink containers as described herein can monitor liquid levels and communicate with external devices about the liquid levels and rate of consumption. One or more sensors in the drink container monitor the liquid level within the container. A processor coupled to the sensor(s) estimates how much liquid has been removed from the container from changes in the liquid level and transmits a signal representing the change in liquid level to a smartphone or other external device. It also triggers an audio or visual indicator, such as an LED, that prompts the user to drink more based on the user's estimated liquid consumption and on the user's liquid consumption goals, which may be based on the user's physiology, activity level, and location.

Embodiments described herein generally relate to devices, systems and methods for measuring a volume or number of doses remaining in a drug delivery device that is used for delivering a dose to a patient. In some embodiments, a dose measurement system for measuring the liquid volume in a container includes a light guide disposed and configured to reflect electromagnetic radiation toward the container. The dose measurement system also includes a light guide disposed and configured to emit electromagnetic radiation into the light guide. A plurality of sensors are located in the apparatus that are optically coupleable to the light guide and are disposed and configured to detect the electromagnetic radiation emitted by at least a portion of the light guide. The apparatus also includes a processing unit configured to receive data representing the portion of the detected electromagnetic radiation from each of the plurality of sensors. The processing unit is further operable to convert the received data into a signature representative of the electromagnetic radiation detected by the plurality of sensors.

Field device for process automation in industrial or private environments, which has an operating element with a button and a luminous display, the luminous display being set up for optical feedback of the operating command issued by a user to the button.

The present disclosure relates to an emptying detection device configured to provide an emptying signal to an emptying system for emptying a container, such as a dosing system including a suction lance, a corresponding suction lance and a corresponding emptying system. The emptying detection device is configured to determine a level of a liquid in the container relative to the emptying detection device, the emptying detection device comprising: a sending and receiving unit being configured to emit electromagnetic waves and to receive electromagnetic waves, and a transponder unit being configured to receive electromagnetic waves from the sending and receiving unit, and to emit a signal in response to the received electromagnetic waves. The sending and receiving unit is configured to emit electromagnetic waves at a frequency for which the liquid has a non-negligible absorption coefficient, and to provide an emptying signal to the emptying system in response to receipt of the signal from the transponder unit

TDR limit level switch determines whether or not the measuring probe is surrounded by the filling material on the basis of the positions relative to the transmission pulse that can be read out from the detected measuring signal and on the basis of the associated amplitudes of the reflections of the transmission pulse on the coupling point and on the end of the measuring probe. In this way, a limit level message can be formed in a simpler, more secure and more reliable manner.

Radiometric measuring arrangement for measuring and/or monitoring a measured variable, especially a fill level or a density, of a fill substance located in a container and a method executable therewith for detection of accretion formation in the container. The variable to be measured is measured by means of a measuring system, which during operation sends radioactive radiation along a measuring path through the container, and measures radiation intensity emerging from the container along the measuring path, and by means of a comparison measuring system, which sends radioactive radiation along a comparison path through the container and measures radiation intensity emerging from the container along the comparison path. The comparison path extends in such a manner through the container that in the case of the presence of an accretion layer on the inner walls of the container a ratio of a sum of the two segments of the measuring path extending through the accretion layer to the length of an additional segment of the measuring path (A, A) extending between these two segments is different from the ratio formed in the same manner for the comparison path, and an accretion formation occurring in ongoing operation is detected based on deviations ascertained in ongoing operation between the measurement results of the measuring system and the measurement results of the comparison measuring system.

Described is a method and system for a level measurement. An echo curve is analyzed, and both the level and the moisture content of the stored material is determined therefrom. The level measuring instrument works in such an energy-saving manner that it is sufficient to supply the instrument with power using a 4 . . . 20 mA two-wire conductor loop that is also used to transmit at least some of the measured values.