Methods of forming a shear-mode chemical/physical sensor for liquid environment sensing on V-shaped grooves of a [100] crystal orientation Si layer and the resulting devices are provided. Embodiments include forming a set of V-shaped grooves in a [100] Si layer over a substrate; forming an acoustic resonator over and along the V-shaped grooves, the acoustic resonator including a first metal layer, a thin-film piezoelectric layer, and a second metal layer in an IDT pattern or a sheet; and forming at least one functional layer along a slope of the acoustic resonator.

The magnetic chip detector system can have a first conductor member and a second conductor member both exposed to a liquid flow path and separated from one another by gap, each one of the conductor members having a magnetic field oriented into the liquid flow path, at least a first one of the magnetic fields being actively modifiable; an electrical energy source configured to induce a current circulation across the gap; and a meter configured to measure a response of the gap to the induced current circulation.

A method and system for diagnosing a condition of an air-breathing aircraft engine are described. The method comprises obtaining a sample of lubricating fluid from the engine, filtering the sample to obtain a plurality of particles from the lubricating fluid, obtaining chemical composition data for the plurality of particles, determining a quantity of volcanic ash in the lubricating fluid by considering each one of the particles as composed partially of volcanic ash and partially of at least one other material and determining a first percentage of surface area of the particles covered by the volcanic ash and a second percentage of the surface area of the particles covered by the at least one other material, the volcanic ash having associated thereto a predetermined chemical composition, and diagnosing a condition of the engine based on the quantity of volcanic ash found in the lubricating fluid.

A detection device for tiny particles in a liquid is provided. The detection device comprises includes a flow cell, a laser, a scattered light collection device, a photoelectric detector, a fiber Bragg grating and a first optical fiber coupler, wherein scattered light collected by the scattered light collection device is sent to the fiber Bragg grating through the first optical fiber coupler, and reflected light of the fiber Bragg grating after receiving the scattered light is sent to the photoelectric detector through the first optical fiber coupler. The device can eliminate most scattered light generated by the liquid, and reduce the interference of the scattered light of the liquid to scattered light signals generated by the particles, so that the scattered light signals captured by the photoelectric detector are mainly light signals generated by the particles.

A system and method are described for rendering a characteristic for a set of particles passing through a measurement volume of a particle optical measurement system. The method includes acquiring raw particle data for the particles passing through the measurement volume. The raw particle data comprises a set of raw particle records. Each particle record comprises at least: a trajectory of at least one particle, and a second primary mark of the at least one particle whose value influences an effective sampling area corresponding to the measurement volume. The method includes generating and storing an effective sampling area based upon: the trajectory of the at least one particle, and the second primary mark. Thereafter, an ensemble characteristic is rendered for the set of particles by performing an operation on the sampling area-corrected set of particle records.

Disclosed herein is a system for performing urinalysis of transurethral patients. The system includes a tubing set to receive urine from a urethral catheter. A detector assembly is operatively coupled between the tubing set and a urinalysis module coupled. The system can perform urinalysis of a urine sample disposed within the tubing set and render urinalysis information on a display of the module. Also disclosed is a method of performing urinalysis that can include operations of: (i) placing a urine sample within a cuvette of a urinalysis system, the cuvette including a lumen extending between an inlet and an outlet; (ii) projecting coherent light into the sample; (iii) collecting output light exiting the sample; (iv)extracting urinalysis data from the collected light; and (v) rendering urinalysis results on a display of the system.

Method, device, and system for identifying a model-based time dependent light scattering signature that includes receiving an experimental time dependent light scattering signature comprising experimental data descriptive of an average molecular weight of protein components in a solution over time. The method further includes identifying an Ansatz for evaluating the experimental time dependent light scattering signature, the Ansatz being an initial model-based time dependent light scattering signature, the initial model-based time dependent light scattering signature identifying at least one key variable. The method also includes adjusting the at least one key variable in the initial model-based time dependent light scattering signature until a final model-based time dependent light scattering signature is identified. In some instances, the final model-based time dependent light scattering signature identifies at least one protein aggregation mechanism.

An electric meter for measuring metal impurities in a fuel tank, comprising: a frame; two electric electrodes supported by the frame; an electric measurement meter connected to the two electric electrodes by using two conductive wires; the electric measurement meter serving to measure the electric properties between the two electric electrodes. In use, the frame with the two electric electrodes is placed into a fuel tank and is sunk into the bottom of the fuel tank; and the electric force of the two electric electrodes will attract the metal impurities in the fuel tank so that the electric measurement meter can measure the electric properties between the two electric electrodes; by the electric property, it can be used to determine the quantity of the metal impurities within the fuel tank so as to determine whether the fuel tank exists too much metal impurities and is needed to be cleaned.

The objective of the present invention is to provide a particle detection device and a particle detection method that can individually and continuously detect a wide range of particles. The objective is achieved by a particle detection device including: a particle separation channel through which particles are separated according to particle sizes in a perpendicular direction to the flow of fluid; and two or more particle recovery channels that are connected to and branched from the particle separation channel, in which each of the particle recovery channels includes a particle detection unit that includes an aperture and an electric detector.

The present disclosure relates to devices, systems, and methods for quantitative measurements of colloid properties with a depletion force sensor. An example system of the present disclosure may include a well, a mass, a sensor, and a processor. The well may be contain a test fluid. The mass has a surface which may be immersed in the test fluid during operation. The sensor may include a sensing element which may be immersed in the test fluid during operation. The sensing element may include a sensor face separated from the surface of the mass by a gap. The sensor may measure a force on the sensing element relative to the mass. The processor may be coupled to the sensor and may determine properties of the test fluid based on the force.