The invention relates to a sensor device and a method for detecting properties of a liquid. The liquid is accommodated in an inner chamber 14. A capacitor arrangement 22, 26 in the inner chamber has spaced, opposing capacitor surfaces 24a, 24b, 28a, 28b so that at least part of the liquid accommodated in the inner chamber 14 is arranged between the capacitor surfaces 24a, 24b, 28a, 28b. An evaluation device 30 for supplying an output signal A depending on a capacitance value C1, C2 of the capacitor arrangement 22, 24 comprises an excitation circuit 32 and an evaluation circuit 34. The excitation circuit 32 has at least one measuring resistor R1, R2, R1a, R1b and means for applying an AC voltage to a series circuit consisting of the measurement resistor R1, R2, R1a, R1b and the capacitor arrangement 22, 24. The evaluation circuit 30 has means for supplying the output signal A by measuring a voltage U1, U2 across the capacitor arrangement 22, 24.

A device for controlling an optical recognition unit with the help of a capacitive filling level measurement in liquid containers having a sensor with a measuring electrode, a conductive base plate suitable for arranging at least one liquid container or a carrier unit having at least one receptacle for receiving a liquid container, a sensor electronics unit that is connected to the measuring electrode and the base plate adapted to determine a capacitance between the measuring electrode and base plate, an evaluation unit, and a control unit for controlling the optical recognition unit, is disclosed.

Provided is a liquid sensor capable of relatively accurately detecting the liquid level even if vibration or the like occurs. The liquid sensor is configured to detect a liquid level in a state in which at least a portion of the liquid sensor is immersed in liquid. This liquid sensor includes a substrate. The substrate is provided with a hole. An inner circumferential surface of the substrate is formed around the hole. A first electrode and a second electrode facing the first electrode are formed on the inner circumferential surface. The liquid sensor further includes a detection circuit. The detection circuit is configured to detect capacitance between the first and second electrodes.

A liquid level sensing system for a vehicle tank may include a liquid level display including a display panel and a first number of visual indicators carried by the display panel. The system may also include capacitive sensors to be coupled to the vehicle tank to sense a second number of possible liquid levels being greater than the first number of visual indicators. In addition, the system may include a controller configured to drive the visual indicators in a modulation pattern based upon the capacitive sensors to thereby display a sensed liquid level having a resolution corresponding to the second number of possible liquid levels.

A capacitive level-sensor device, for detecting the level of a medium contained in a container, is configured for being installed on the outside of the container, in a position substantially resting against a wall of the container that is made at least in part of an electrically insulating material. The circuit support has, in a sensing region thereof, at least one first plurality of first capacitive elements, which comprise at least one first array of first electrodes, preferably set at a distance apart from one another along a level-detection axis, the first electrodes being made of an electrically conductive material and being arranged at least in part in a position corresponding to at least one first side of a supporting structure of the circuit support. The first electrodes are covered with at least one insulation or protection layer made of an electrically insulating and sealing material, which is selected from materials that include silicon, or its derivatives or compounds, and materials that include fluorine derivatives or compounds.

The system and techniques disclose herein describe a radio-frequency identification (RFID) capacitance liquid measurement and tag (RCLMT) system for detecting a volume of liquid in a container (liquid level detection), for example an amount of wine inside of a wine bottle. The RCLMT system includes a RFID chip, flexible printed circuit board (PCB), capacitive strips, and adhesive which implements a RFID tag-based sensor that advantageously uses low power and has low cost. Further, a user platform, including the RCLMT system and computer software applications (apps) and a backend system (e.g., cloud service) is described herein. The RCLMT system acts as a passive liquid level detection sensor, which enables the amount of a liquid beverage, such as alcohol, that is inside of a container to be automatically and accurately ascertained.

A first detection electrode is provided on an insulating layer. A second detection electrode is provided away from the first detection electrode on the insulating layer, and forms a capacitance together with the first detection electrode. The protection layer covers the first detection electrode and the second detection electrode, has a thickness d satisfying 1 μm≤d≤10 μm, and is made of zirconia or alumina. The protection layer is a sintered body.

The present application discloses a manual-automatic integrated self-adaptive pump with an infrared water level detection function, which comprises a pump housing, a water pumping assembly, a base, a vacuum cofferdam, a water outlet pipeline, a volute, an exhaust port, a sensor adjusting mechanism and an infrared liquid level sensing assembly. In this way, the manual-automatic integrated self-adaptive pump with the infrared water level detection function provided by the present application has a compact structure, can be easily installed, has strong adaptability, can realize manual and automatic free switching, can realize more accurate detection of remaining water level, has a longer service life, and can solve the problem of sensing the water level in the field.

A pathogen transport modelled biomimetic sensor includes a stack of capacitive electrodes with a plurality of gaps therebetween. The gaps and electrodes are structured and arranged to model an outer layer and one or more sublayers of fresh food of interest. The electrodes are arranged to provide multiple measurable impedances that are affected in response to cell or polymeric biofilm presence that affects the electrostatic field around and between the electrodes and consequently changes the measurable impedances.

A printed circuit board device includes: a first capacitive sensor configured to measure a first capacitance within a contained volume having known dimensions, wherein the first capacitance changes as a substance is received into the contained volume; a second capacitive sensor having a plurality of trigger points at a plurality of corresponding known heights within the contained volume, the second capacitive sensor configured to detect when the substance received into the contained volume has reached each of the corresponding known heights within the contained volume; and wherein at least one of a level of the substance within the contained volume, a volume of the substance within the contained volume, or a flow rate of the substance into the contained volume is determined based on data from the first capacitive sensor and the second capacitive sensor.