Disclosed is a method for diagnosis of a two-conductor field instrument and a corresponding two-conductor field instrument. In a normal operating mode, an input voltage is provided and an output current is output. In a diagnostic operating mode, the method includes: providing a first diagnosis-input voltage and outputting a first diagnosis-output current during a first time interval, providing a second diagnosis-input voltage and outputting a second diagnosis-output current during a second time interval, determining the second time interval from the first time interval, registering a first and second diagnosis-output voltage as a function of the first and second diagnosis-output current, and checking the functionality of the two-conductor field instrument by the first and second diagnosis-input voltage, the first and second time interval, the first and second diagnosis-output electrical current, the first and second diagnosis-output voltage based on the input voltage and/or based on the output electrical current.

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 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.

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.

A measurement system includes an atomizer, an impactor, a particle counter, and a discharge reservoir. The atomizer has a liquid intake port and a gas intake port configured to aerosolize a liquid received at the liquid intake port. The impactor has an inlet coupled to the atomizer and has a first output port and a second output port. The impactor is configured to separate droplets wherein those droplets smaller than a selected cut point are directed to the first output port and those droplets larger than the selected cut point are directed to the second output port. The particle counter is coupled to the first output port and is configured to count particles larger than at least one particle size cut point. The discharge reservoir is coupled to the second output port.

A measurement system includes an atomizer, an impactor, a particle counter, and a discharge reservoir. The atomizer has a liquid intake port and a gas intake port configured to aerosolize a liquid received at the liquid intake port. The impactor has an inlet coupled to the atomizer and has a first output port and a second output port. The impactor is configured to separate droplets wherein those droplets smaller than a selected cut point are directed to the first output port and those droplets larger than the selected cut point are directed to the second output port. The particle counter is coupled to the first output port and is configured to count particles larger than at least one particle size cut point. The discharge reservoir is coupled to the second output port.

A liquid level detection device that is provided in a vessel and configured to detect a liquid level of fluid stored in the vessel includes a first plate formed in a plate shape, and a second plate formed in a plate shape and disposed to face the first plate. The first plate is disposed in such a manner that a surface opposite to a surface facing the second plate is orthogonal to a flow direction of fluid around the first plate in the vessel.

A liquid level detection device that is provided in a vessel and configured to detect a liquid level of fluid stored in the vessel includes a first plate formed in a plate shape, and a second plate formed in a plate shape and disposed to face the first plate. The first plate is disposed in such a manner that a surface opposite to a surface facing the second plate is orthogonal to a flow direction of fluid around the first plate in the vessel.

The disclosure relates to systems, devices, and methods for sensing the volume of liquid in a container, such as within a medical device. The systems, devices, and methods can measure the properties of a signal sent across a container using non-intrusive components that remain outside the container. The measured properties can be used to determine the volume of liquid in the container, as well as changes to the volume of liquid representing flow into and out of the container.