An airborne biological particle monitoring device collects particles floating in air. The monitoring device includes a processor, a camera sensor, and a set of approximately monochromatic illumination sources that correspond to a set of spectral curves. The camera sensor captures images of the particles providing a spectral analysis of the particles. The processor analyzes the images to identify the collected particles.

A particulate matter sensor including a light source, a photodetector, and a particle filter. The light source and the photodetector are arranged in the same plane as the particle filter. Integrated particulate matter sensors are operable to detect particulate matter by measuring an optical characteristic of a filter.

An assembly for checking the atmosphere within a first environment isolated from a second environment, which differs by air quality and/or composition of the atmosphere. The assembly includes an isolation element for isolating the first environment from the second environment, a sampling device to collect elements present in the atmosphere within the first environment, and a suction device. The isolation element has an item of isolating personal protective equipment, and the sampling device includes a cassette defining a compartment having an inlet orifice as the sampling orifice and an outlet orifice as the connection orifice, which can be connected to the suction device, an element for capturing the elements being researched, interposed between the two orifices, in the compartment, the cassette further having an attachment element for mounting the sampling device on the isolating personal protective equipment, and the sampling orifice opening into the isolated first environment.

A gas detecting module is disclosed. A gas-inlet concave and a gas-outlet concave are formed on a sidewall of a base. A gas-inlet-groove region and a gas-outlet-groove region are formed on a surface of the base. The gas-inlet concave is in communication with a gas-inlet groove of the gas-inlet-groove region, and the gas-outlet concave is in communication a gas-outlet groove of the gas-outlet-groove region. The gas-inlet-groove region and the gas-outlet-groove region are covered by a thin film to achieve the effectiveness of laterally inhaling and discharging out gas relative to the gas detecting module.

A portable sampling device includes a sampling housing at least partially enclosing an inner chamber; at least one pumping element disposed within the inner chamber and configured to facilitate airflow through the device; and at least one gas sensor disposed within the inner chamber and configured to detect and/or characterize one or more gases in the airflow.

A mobile power device capable of detecting gas is disclosed and includes a main body, a gas detection module, a driving and controlling board, a power module and a microprocessor. The main body includes a ventilation opening, a connection port and an accommodation chamber. The ventilation opening is in communication with the accommodation chamber. The gas detection module and the driving and controlling board are disposed within the accommodation chamber. The gas detection module, the power module and the microprocessor are fixed on and electrically connected to the driving and controlling board. The power module is capable of storing an electric energy and outputting the electric energy outwardly. The microprocessor enables the gas detection module to detect and operate. The microprocessor converts the detection information of the gas detection module into a detection data, which is stored and transmitted to the mobile device or an external device.

An improved device for collecting particulate matter suspended in the ambient air is disclosed comprising a container extending between an open first end and a closed second end defining a container interior. A container output communicates with a container interior located proximate the closed second end of the container. A filter cassette comprising a collection filter is permanently affixed to a filter holder. A retainer having a retainer input retains the filter cassette between the retainer input and the container output. An output connector connects the container output to a low pressure source for drawing ambient air into the retainer input for enabling the collection filter to collect particulate matter suspended in the ambient air entering the retainer input. Preferably, the filter holder and the filter are disposable.

A diffusive sampling device is used for quantitative measurement of chemicals in indoor and outdoor air. The sampling device includes a vial containing a sorbent on the inside bottom of the vial. The sampling device can be thermally vacuum cleaned before transport to the sampling location, and the sorbent can be chosen to allow the collection of either volatile or semi-volatile compounds (VOCs or SVOCs). After a diffusive sampling period (1 hour to 1 month), the vial is closed, and the collected sample is transferred to a laboratory for analysis. Using a thermal vacuum extraction focusing technique, the collected sample is rapidly delivered to a GCMS-compatible preconcentration device including a second sorbent for either split or splitless injection into a capillary based GCMS. No solvents are used during sampler preparation or analysis, and detection limits needed for monitoring of ambient or indoor air can be achieved for thousands of chemicals.

A sample extraction device and a desorption device for use in gas chromatography (GC), gas chromatography-mass spectrometry (GCMS), liquid chromatography (LC), and/or liquid chromatography-mass spectrometry (LCMS) are disclosed. In some examples, the sample extraction device includes a lower chamber holding a sorbent. The sample extraction device can extract sample headspace gas from a sample vial by placing the sorbent inside the vial and creating a vacuum to increase recovery of low volatility compounds, for example. Once the sample has been collected, the sample extraction device can be inserted into a desorption device. The desorption device can control the flow of a carrier fluid (e.g., a liquid or a gas) through the sorbent containing the sample and into a pre-column and/or a primary column of a chemical analysis device for performing GC, GCMS, LC, LCMS, and/or some other chemical analysis process.

A plug-in air quality detector, a control method, and a control circuit are provided in the field of air quality detection. The plug-in air quality detector comprises a casing, a sensor component, a control circuit and a connector component. The connector component includes a power supply terminal and a data terminal, and is configured to connect the plug-in air quality detector with a user device. As such, the detector may prompt a user of the air quality around the user without being configured with a dedicated power supply and a dedicated display screen, thereby achieving the effects of reducing the size and the weight of the air quality detector and improving the ease of use.