An example liquid level sensor is described. The liquid level sensor includes a first layer, a stretchable electrode layer provided on the first layer, and a second layer provided on the stretchable electrode layer. The stretchable electrode layer includes a first stretchable receiver electrode and a stretchable transmitter electrode. The liquid level sensor can include an electrical connector for coupling the liquid level sensor to a computing device. The computing device can be configured to determine a liquid level within the container and wirelessly transmit data indicative of the liquid level.

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.

Devices and corresponding methods for capacitive foam detection in liquid containers are disclosed. The device has a sensor with a measurement electrode having a plurality of sub-electrodes, a bottom plate that is used as a counter electrode for arranging a liquid container, a sensor electronic unit that is connected to the measurement electrode and the bottom plate and is adapted to determine an impedance, in particular a capacitance, between the measurement electrode and the bottom plate, and an evaluation unit, the measurement electrode being arranged substantially perpendicularly to the bottom plate.

Disclosed is a method for parametering an apparatus for determining and/or monitoring a predeterminable fill level, wherein the apparatus includes a sensor unit and an electronics. The method includes determining an influence interval for a received signal received by the sensor unit as a function of an environmental parameter, determining a first value for the received signal or for a variable derived from the received signal corresponding to a first switch state, determining a second value for the received signal or for a variable derived from the received signal corresponding to a second switch state, and determining a third value for the received signal or for a variable derived from the received signal corresponding to a first switching point based on the first switch state and/or the second switch state and taking into consideration the at least one influence interval.

A sensor is provided for generating an output signal for detecting a limit level of a medium, a filling level of the medium, and/or for differentiating between different media, the sensor including: a processor to process a measurement signal generated using the sensor; and a reference unit to generate a reference signal, the processor is further configured to perform temperature compensation using the reference signal, the processor and the reference unit each having a signal conversion unit to provide temperature-dependent signal conversion, the signal conversion units being thermally coupled to one another, and the temperature compensation includes compensating for temperature dependency of the signal conversion unit of the processor using a thermal coupling.

A fire suppressant storage device (20) comprising: a tank (22) having a first port and an interior for storing fire suppressant; and a discharge assembly mounted to the first port. The discharge assembly has a discharge valve (48) and a discharge conduit (50) at least partially within the interior. The discharge conduit has an interior surface (60) and an exterior surface (58). The discharge assembly further comprises a gauge (80) on the discharge conduit.

Embodiments are directed to a simple, tool-less, and automated connection between a transfer probe and a capacitive liquid level detection printed circuit assembly (PCA) for use in a clinical analyzer in an in vitro diagnostics (IVD) environment in a hospital or laboratory setting. Advantageously, a single user connection is required: a fitting that is used to attach fluid tubing of the transfer arm to a probe, resulting in a mechanical, fluid, and electrical connection between the probe and the transfer arm. A PCA comprises a plurality of spring-loaded pins and capacitive liquid level detection circuity. A probe comprises a primary tube nested within a secondary tube, wherein the primary tube and the secondary tube comprise respective heads at respective top portions thereof forming a set of electrically isolated surfaces. The fitting secures the probe within a transfer arm and establishes the connection between the PCA and the probe.

This disclosure discusses a fluid property sensor, comprising an electrical circuit assembly (ECA) including an external interface coupled to a common interface bus; a fluid level sensor coupled to the common interface bus to indicate a fluid level and/or a pressure sensor coupled to the common interface bus to indicate a pressure event; and/or a driver circuit coupled to the common interface bus, configured to communicate characteristics of the fluid level sensor and the pressure sensor.

A device for monitoring a liquid level of a liquid storage tank for a vehicle is capable of improving sensing sensitivity of a liquid level sensor by employing a structure capable of amplifying an electromotive force, which is generated by an electrode, at an electromotive force amplification layer including a carbon micro coil (CMC) and accurately sensing a frozen state of a liquid to perform a heating function so as to resolve the frozen state of the liquid.

The invention is an impedance threshold level sensor, comprising: a measuring probe which can be influenced by a medium surrounding the measuring probe in a measuring capacitance, the measuring probe comprising a measurement electrode and a reference electrode insulated from the measurement electrode, between which the measuring capacitance is formed, a measuring resonant circuit, in which the measuring probe is arranged as a capacitance-determining element, an electronic unit having a signal generator for exciting the measuring resonant circuit and a signal detector for determining a response signal of the measuring resonant circuit, a signal processing unit for generating a measurement signal, which is connected to the electronic unit, wherein the measurement electrode and the reference electrode are designed and arranged such that an increasing filling level of the medium reaches the reference electrode earlier than or together with the measurement electrode.