Methods of improving accuracy of droplet metering using at least one on-actuator reservoir as the fluid input. In some embodiments, the on-actuator reservoir that is used for metering droplets includes a loading port, a liquid storage zone, a droplet metering zone, and a droplet dispensing zone. The on-actuator reservoirs are designed to prevent liquid flow-back into the loading port and to prevent liquid from flooding into the droplet operations gap in the dispensing zone.

Methods of improving accuracy of droplet metering using at least one on-actuator reservoir as the fluid input. In some embodiments, the on-actuator reservoir that is used for metering droplets includes a loading port, a liquid storage zone, a droplet metering zone, and a droplet dispensing zone. The on-actuator reservoirs are designed to prevent liquid flow-back into the loading port and to prevent liquid from flooding into the droplet operations gap in the dispensing zone.

A method and apparatus for determining particle contamination of a process fluid is disclosed herein. In one example, a fluid resistivity measurement probe is provided. The system includes an upstream fluid conduit, a downstream fluid conduit, and a measuring section. The measuring section has a metal rod, and a ground electrode. The ground electrode surrounds and is coaxial with the metal rod. The upstream fluid conduit is coupled to a first end of the ground electrode. The downstream fluid conduit is coupled to a second end of the ground electrode. The metal rod and the ground electrode define a space therebetween. The space flows a fluid from the upstream fluid conduit to the downstream fluid conduit.

A bin volume predictor can receive data characterizing measurements of a temperature at a plurality of temperature sensors of a temperature sensor cable that is positioned to extend along a height of the storage bin in an interior of the storage bin and data characterizing measurements of an ambient temperature of an exterior of the storage bin. The bin volume predictor identifies, based on the measured temperature for temperature sensors in the interior of the storage bin, a topmost covered temperature sensor of the temperature sensor cable. Moreover, the bin volume predictor determines, based on the identified topmost covered temperature sensor, an amount of material stored in the storage bin.

In some examples, a processor on a vehicle may determine, based at least partially on information obtained from a sensor, that a fuel level of the vehicle is increasing. Further, the processor may determine that the fuel level has stabilized for a threshold time. In addition, the processor may determine an amount of fuel added to the vehicle, and may send, over a wireless network to a computing device, a communication indicating the amount of fuel added. In some cases, the computing device may compare the amount of fuel indicated in the communication from the processor with an amount of fuel indicated in information received from a point-of-sale device for determining a difference.

In some examples, a processor on a vehicle may determine, based at least partially on information obtained from a sensor, that a fuel level of the vehicle is increasing. Further, the processor may determine that the fuel level has stabilized for a threshold time. In addition, the processor may determine an amount of fuel added to the vehicle, and may send, over a wireless network to a computing device, a communication indicating the amount of fuel added. In some cases, the computing device may compare the amount of fuel indicated in the communication from the processor with an amount of fuel indicated in information received from a point-of-sale device for determining a difference.

This application addresses a wireless system for the determination of the height of liquid or molten metal levels containing metal, shaft, matte or slag in smelting furnace. Specifically, it addresses a wireless system that allows, without the presence of cables, the sending and receiving of a signal outside of the smelting furnace, in order to determine, on-line, the height of the phases, including the height of the slag-matte interface and the total level of the bath.

There is proposed an apparatus and method for measuring fluid usage from a container. The apparatus in one form includes a proximity sensor or sensors positioned in, or adjacent, an outlet of said container and configured to monitor the presence or absence of said fluid within or adjacent said outlet, an angle sensor for determining a first angle of said container when said fluid begins to flow through the outlet, and for determining a second angle of said container when said fluid stops flowing through said outlet, and a transmitter for sending data from the proximity sensor/s and angle sensor or processed data therefrom, to a computing device and/or display unit, wherein the data or processed data is used to calculate or indicate a volume of the fluid having passed through the outlet.

Systems and methods for storing fluid and sensing volume are described. In some embodiments, a system may include a container having an internal volume that is configured to change as fluid enters or exits the container, a first loop disposed on a first side of the container, and a second loop disposed on a second side of the container. A first current traveling through one of the first loop and the second loop may induce a second current in the other of the first loop and the second loop, and a magnitude of the second current may vary based on changes in the internal volume of the container.

A system for determining a fluid level includes a front end and a measurement probe. The measurement probe receives a pulse from the front end and returns a partially reflected pulse and a fully reflected pulse to the front end. The partially reflected pulse is evaluated to determine a liquid level within a tank that includes the measurement probe. The measurement probe includes a conductive trace configuration to provide a time delay to prevent pulse build up.