A sample agitation system for an automated sampling device is described. In an example implementation, the sample agitation system includes a sample probe configured to contact a sample positioned within a sample vessel. Further, the sample agitation system includes an actuator coupled to the sample probe that is configured to stir the sample positioned within the sample vessel in one or more rotational directions. The directions may include, but are not limited to, clockwise motion, anti-clockwise motion, or the like. In some implementations, a sample probe support arm can be coupled to the sample probe and/or the actuator. The actuator can move the sample probe support arm in a translational, a rotational, and/or a vertical direction to rotate the sample probe and stir the sample.

There is described an equipment and method for analysis of a fluid, suspension, solution, dispersion or fluid emulsion that automatically analyzes the characteristic properties of the samples of the fluids, such as paints, enamels, and dyes, among others, so that adjustments can be made to the fluid to meet the optical properties such as color, opacity, hue, saturation (tinting power), covering and luminosity, from the spectrometric measurement technique by transmission analysis of film having radiated fixed thickness.

The invention relates to a system for processing liquid and/or solid compounds, comprising a vessel (3) and a holding device (5) for the vessel (3), the holding device (5) comprising a stop (15) against which the vessel (3) rests after being inserted into the holding device (5) and a supply unit (7) opposite the stop (15), the supply unit (7) comprising a closing element (9), which can be set to a first and a second position, wherein in the first position of the closing element (9) the vessel (3) can be inserted into the holding device (5) and in the second position of the closing element (9) the vessel (3) inserted into the holding device (5) is pressed against the stop (15) by the closing element (9).

The invention is concerned with improvements in the technical field of laboratory devices. To this end, what is proposed, inter alia, is a laboratory device (1) that has, on its housing (2), at least one coupling interface (3) and at least one mating coupling interface (4) compatible with the coupling interface (3). The coupling interface (3) and the mating coupling interface (4) are configured to transfer power and/or to transfer information.

An analyte identifying and sorting apparatus for sorting a target analyte based on an identification result of analytes dispersed in a liquid. The apparatus includes an identification unit including an analyte storage section configured to store analytes dispersed in a liquid, a pressure control section configured to feed the liquid to a flow path provided to extend downward from the analyte storage section, a light irradiation section configured to irradiate light to the analytes, an optical information measurement section measuring optical information of the analytes, and a determination section determining whether the analyte is a target analyte or a non-target analyte based on the optical information. Also included is a sorting unit that includes a sorting nozzle connected to the identification unit and sorts a sorted solution containing the target analyte to the vessel, an effluent collection section having a suction nozzle to suck and collect an effluent involving an effluent discharged from a tip of the sorting nozzle, and a collection vessel configured to collect the sorted solution containing the target analyte. A moving unit moves the sorting nozzle and/or the collection vessel, a control unit moves the sorting nozzle and/or the collection vessel based on the optical information, and a stirring unit including a stirring member in an inner space of the analyte storage section.

Provided is an automatic analyzer to control a temperature of a reagent supplied to a magnetic separator with high accuracy. The automatic analyzer includes a magnetic separator that separates a magnetic component and a non-magnetic component from liquid obtained by reacting a sample with a first reagent, a storage unit that accommodates a second reagent, a pipe used to supply the second reagent to the magnetic separator, and a heat exchanger that adjusts a temperature around the pipe. It is preferable that the heat exchanger includes a heat absorption and dissipation unit and a fan that blows air heat-exchanged by the heat absorption and dissipation unit, and the air blown from the fan is blown onto the pipe.

The present invention discloses a spectral-potentiometric-thermometric multi-dimensional titration analysis instrument, which comprises a spectral titration measurement device, a thermometric titration measurement device and a potentiometric titration measurement device which are arranged in parallel, meets the simultaneous measurement requirements of different analysis methods in chemical analysis, improves the measurement precision of different measurement methods, and effectively reduces the workload of separate experiments. The present invention further provides a usage method of the analysis instrument, provides analysis results of different angles and different characterization parameters for the change process of the material structure in the chemical reaction by conducting comparison analysis on data obtained using different measurement techniques, and effectively reduces the workload of titration analysis.

The present invention provides a device (1) for detecting contamination with a photosynthesis inhibitor, the device including a collection device (10) configured to collect a test liquid, a light-blocking pretreatment tank (21) configured to store the test liquid (2) collected by the collection device in a state of containing phytoplankton, a stirring device configured to maintain a floating state of the phytoplankton in the test liquid stored in the pretreatment tank, an irradiation light source configured to irradiate the phytoplankton in the test liquid stored in the pretreatment tank with weak light having an underwater photon flux density that does not cause photoinhibition, a drainage conduit (40) configured to allow the test liquid discharged from the pretreatment tank to flow thereinto, and a fluorescence quantum efficiency measuring machine (50) provided for the drainage conduit and configured to measure a fluorescence quantum efficiency of the phytoplankton in the test liquid discharged from the pretreatment tank, and a method for detecting contamination with a photosynthesis inhibitor, the method including a liquid supply step, a storing and weak-light irradiation step, and a fluorescence quantum efficiency measurement step.

An automatic analysis device has a plurality of types of photometers having different quantitative ranges, and an analysis control unit for quantifying the desired component in specimens based on measurement values of one or more photometers selected from among the plurality of types of photometers. The analysis control unit: sets a switching region in an overlap region of respective quantitative ranges of the plurality of types of photometers, said switching region having a greater width than does the variation in quantitative values of the desired component based on the measurement values of photometers having the same specimen; compares the quantitative value of a quantitative range portion that corresponds to the switching region and the quantitative values of the desired component based on the measurement values of the photometers; and selects a photometer to be used in quantitative output of the desired component from among the plurality of types of photometers.

A nucleic acid extracting device includes a reagent containing unit, a mixing unit, and a flow channel unit. The reagent containing unit contains a specimen, a magnetic bead, and a reagent for extracting. The mixing unit includes a mixing chamber and a stirring assembly. The mixing chamber includes a chamber portion and a tube portion. The stirring assembly includes a main body and an extension. The main body is provided in the chamber portion. The tube portion connects the chamber portion. And the extension connects the main body and extends into the tube portion. The extension and an inner wall of the tube portion have first and second gaps therebetween respectively along first and second directions of the tube portion. The first gap is less than the second gap. The flow channel unit is connected between the reagent containing unit and the mixing unit.