A system is provided for testing and sampling of crude oil that includes a crude oil sampler system with a circulation loop and a water cut meter incorporated into the circulation loop. The system provides for a water cut meter positioned downstream of a sample withdrawal point. As the sample of crude oil passes through the circulation loop, the water cut meter can be used to determine the percentage of water cut of the sample. After passing through the circulation loop and determination of the water cut, a secondary sub-sample of the crude oil may be drawn off from a draw-off valve. The secondary sub-sample may then be sent to a laboratory or testing center for further testing or verification of the initial water cut.

A fluidic device for capturing or detecting a sample substance contained in a solution includes at least two continuous circulation flow channels selected from the group consisting of: a first type continuous circulation flow channel which is formed of a first circulation flow channel and a second circulation flow channel and which is configured to circulate the solution in the first circulation flow channel and then circulate the solution in the second circulation flow channel; and a second type continuous circulation flow channel which is formed of a third circulation flow channel and a fourth circulation flow channel and which is configured to circulate the solution in the third circulation flow channel and then circulate and mix the solution in both of the third and fourth circulation flow channels, wherein any one of the circulation flow channels has a capturing section which captures the sample substance, and/or a detecting section which detects the sample substance.

A system for detecting analytes in a test sample, and a method for processing the same, is provided. The system includes a cartridge reader unit that has a control unit and a pneumatic system, and a cartridge assembly that prepares the samples with mixing material(s) through communication channels. The assembly has a memory chip with parameters for preparing the sample and at least one sensor. The assembly, pneumatic system, and control unit operate together to prepare the sample and provide the prepared sample to the sensor for detecting analytes, and also process measurements from the sensor to generate test results.

A method and device for detecting pyrethroid pesticide residues in crops. Reaction membrane is arranged on a bottom plate and provided with a check-up line and a quality control line; a first mounting block and a second mounting block are arranged on the bottom plate; a first slide is arranged in the first mounting block, a second slide is arranged in the second mounting block; a sample pad and a bonding pad are arranged in the first slide; a water absorption pad is arranged in the second slide; a liquid inlet provided with a pipe is formed in the first mounting block, a pressing hole provided with a press block is formed in the second mounting block; protrusions are respectively formed on the pipe and the press block; sliding grooves are formed in the liquid inlet and the pressing hole; and first springs are arranged between the protrusions and the sliding grooves.

Among other things, a diluted sample is generated based on mixing a small sample of blood with a one or more diluents. A thin film of the diluted sample is formed on the surface of a contact optical microscopy sensor. Red blood cells within a portion of the thin film of the diluted sample are illuminated using light of a predetermined wavelength. One or more images of the diluted sample are acquired based on illuminating the red blood cells within the portion of the thin film of the diluted sample. The acquired one or more images of the diluted sample are then processed. The mean corpuscular hemoglobin in the red blood cells within the portion of the thin film of the diluted sample is determined based on processing the acquired images of the diluted sample.

To uniformly dilute particulate matter contained in a sample gas, a diluter includes an inflow portion, a mixing portion, a discharge portion, a connection portion, and an introduction portion. The inflow portion allows a sample gas to flow in. The mixing portion has an inner diameter larger than that of the inflow portion, and mixes the sample gas with a dilution gas to generate a diluted sample gas. The discharge portion discharges the diluted sample gas. The connection portion has a first tapered part whose inner diameter increases from a side connected to the inflow portion toward a side connected to the mixing portion. The introduction portion introduces the dilution gas into an internal space from a position downstream of the connection between the first tapered part and the inflow portion.

The present invention relates to a quantitative evaluation method for concrete workability based on bottom resistance, including the following steps: step 1, carrying out a test for bottom resistance of fresh concrete; step 2, drawing a curve of inserting velocity of steel sheet over time; and step 3, quantitatively evaluating a concrete workability based on conditions of the bottom resistance. This method can quantitatively characterize the sinking condition of aggregate of the fresh concrete by effectively carrying out the test for bottom resistance of fresh concrete, calculating the inserting velocity of concrete and drawing the curves of displacement and velocity over time, so as to achieve the quantitative evaluation for concrete workability and overcome the defects of conventional methods that it is difficult to quantitatively characterize the segregation degree of concrete.

The present invention relates to a quantitative evaluation method for concrete workability based on bottom resistance, including the following steps: step 1, carrying out a test for bottom resistance of fresh concrete; step 2, drawing a curve of inserting velocity of steel sheet over time; and step 3, quantitatively evaluating a concrete workability based on conditions of the bottom resistance. This method can quantitatively characterize the sinking condition of aggregate of the fresh concrete by effectively carrying out the test for bottom resistance of fresh concrete, calculating the inserting velocity of concrete and drawing the curves of displacement and velocity over time, so as to achieve the quantitative evaluation for concrete workability and overcome the defects of conventional methods that it is difficult to quantitatively characterize the segregation degree of concrete.

A solution mixer comprising: a main flow path in which a solution circulates; at least one solution introduction flow path connected to the main flow path; and at least one solution discharge flow path connected to the main flow path, wherein the solution discharge flow path has at least one solution discharge flow path valve, and wherein the main flow path has at least one main flow path valve.

Embodiments disclosed herein relate to systems and methods for imaging a microscopic sample, for example in a liquid or a solid. The systems can be coupled to a portable electronic device and adjusted in three dimensions to allow for alignment of a lens assembly with an optical axis of a camera on a portable electronic device. This can allow for use across various-sized electronic devices, such as smartphones, tablets, and digital cameras. The systems can have a compact size, which allows for portable and/or at-home analysis of samples. The systems can be used to analyze sperm samples to detect fertility issues. The systems can be used to analyze soil or liquid samples to detect contaminants, such as microplastics.