The present invention provides a brake dust measurement system that can accurately measure an amount of brake dust produced. The brake dust measurement system, in which a specimen having a brake is placed in a chamber and which measures brake dust produced from the brake, includes a sampling unit that samples air inside the chamber, an elemental analysis unit that performs elemental analysis of sampled air sampled by the sampling unit, a storage unit that stores elemental content information of a single or multiple elements contained in the brake, and a calculation unit that calculates an amount of brake dust contained in the sampled air on the basis of elemental analysis results of the elemental analysis unit and the elemental content information.

The present invention relates to a system for analysing volatile organic compounds (VOCs) in soil comprising an apparatus and a soil VOC sensor strip, wherein the apparatus comprises a sampling chamber for receiving soil, a sensor strip aperture in the sampling chamber for positioning the sensor strip in fluid communication with the sampling chamber, a power source and an electrical resistance detector, wherein the sensor strip comprises a flexible substrate with a first surface and an array of semiconductor polymer sensors arranged on the first surface, wherein each of the semiconductor polymer sensors comprises a pair of electrodes, wherein the pair of electrodes comprises a first electrode and a second electrode, wherein a semiconductor polymer is disposed between the first electrode and the second electrode, and wherein the sensor strip is electrically connectable to the power source and the electrical resistance detector.

An apparatus for generating gas from a sample (battery) by pyrolysis of the sample in order to collect or analyze gas generated inside the sample due to the thermal behaviors of the sample. More specifically, provided is an apparatus wherein not only gas generated due to the thermal behaviors of a sample (battery) can be generated by heating the sample (battery itself), but also a series of processes provided to collect or analyze the generated gas can be automatically controlled.

Apparatuses and methods of measuring a hydrogen diffusivity of a metal structure including during operation of the metal structure, are provided. A hydrogen charging surface is provided at a first location on an external surface of the structure. In addition, a hydrogen oxidation surface is provided at a second location adjacent to the first location on the external surface of the structure. Hydrogen flux is generated and directed into the metal surface at the charging surface. At least a portion of the hydrogen flux generated by the charging surface is diverted back toward the surface. A transient of the diverted hydrogen fluxes measured, and this measurement is used to determine the hydrogen diffusivity of the metal structure in service.

A collection device for collecting volatile organic compounds (VOCs) from a living biological sample is disclosed. The collection device comprises a housing defining an interior chamber and an inlet and outlet each fluidly communicating with the interior chamber. The housing is formed by an upper surface, a lower surface, and a substantially circular sidewall extending between the upper and lower surfaces. The interior chamber comprises a substantially cylindrical volume enclosed by the housing and configured to receive the living biological sample. The inlet and the outlet may extend through the upper surface and may be substantially diametrically opposed with respect to the circular sidewall. The collection device may be configured to pass fluid in a substantially laminar flow path through the inlet, across the interior chamber, and out of the outlet. At least a portion of the housing may comprise a substantially transparent material configured to transmit light therethrough.

A chamber and a system for real-time analysis of gas generated inside a secondary battery. The chamber and system are capable of adjusting temperature while directly applying heat to the secondary battery. The system may include a chamber, a pump module, and an analysis module. The chamber may include a first housing which is insulative, and configured to house the secondary battery mounted in an inner space surrounded by the first housing, a second housing which is thermally conductive and surrounding the first housing, an inlet connected to the pump module, a temperature sensor configured to measure a temperature of the secondary battery or a temperature inside the chamber, and a first heat generation member configured to heat the secondary battery, the first heat generation member being configured to be inserted into the second housing.

The present disclosure relates to methods, devices, and systems for measuring nitric oxide released from a material. For example, a method of measuring nitric oxide release from a material can include introducing a continuous flow of a carrier gas into a sample holding chamber via a carrier gas inlet at an effective flow rate, introducing an amount of the nitric oxide releasing material into the sample holding chamber via a separate sample inlet to contact the continuous flow of the carrier gas, directing the carrier gas and released nitric oxide out of the sample holding chamber via a nitric oxide outlet toward a nitric oxide detector, and quantifying an amount of released nitric oxide using the nitric oxide detector.

An open dynamic flux chamber (10) comprising: a cylindrical box-like body having a bottom opening designed to be rested on an emitting surface; an inlet (15) for a vector gas, positioned on said box-like body; a hole (16) for taking measurements, positioned on said box-like body; at least one vent hole (17) positioned on said box like body to place the mixture of gas present in said box like body in contact with the outside environment; characterized in that said flux chamber (10) has an flat upper base (1) and comprises a tubular shaped windbreak (40) positioned above said upper base (11) to protect said at least one vent hole (17) and having a length greater than 30 cm and a width greater than 5 cm.

Sewer gas sampling and analyzing devices include a dish-shaped manhole insert having a manhole insert interior and a manhole insert exterior outside the manhole insert interior; a manhole insert vent valve carried by the manhole insert, the manhole insert vent valve having a valve inlet disposed in fluid communication with the manhole insert exterior and a valve outlet and the manhole insert vent valve facilitates substantially unrestricted flow of gas from the valve inlet to the valve outlet; and a gas detector unit disposed in fluid communication with the valve outlet of the manhole insert vent valve. Sewer gas sampling and analyzing methods are also disclosed.

An example method for collection and analysis of particles from a particle generating source enclosed within an enclosure having an inlet and an outlet is described. The method includes supplying filtered air into the enclosure through the inlet, extracting, with a vacuum source, an aerosol stream including particles from the particle generating source through the outlet, directing the aerosol stream from the outlet of the enclosure to the vacuum source via a sampling tower. The sampling tower includes at least one nozzle for sampling the aerosol stream. The method includes detecting, with a detection instrument coupled to the nozzle, at least one characteristic of the particles in the aerosol stream, and outputting data concerning the detected characteristic of the particles in the aerosol stream to a computing device.