The present disclosure relates to aspirating smoke detectors (ASD). In an ASD, ambient air is aspirated and is fed to a fire detector unit for determining a signal level. For normal operation, the suction power is set to a nominal airflow value and this is increased from a minimum signal level value in order to shorten the transport time of aspirated smoke through the suction pipe to the fire detector unit. In some embodiments, an interruption signal provided for normal operation is output if the airflow exceeds an upper limit value for a minimum period. Independently thereof, the suction power is increased from the minimum signal level value only to the extent that the airflow does not exceed the upper limit value. Or, regardless thereof, the suction power is increased only for a timespan smaller than the minimum period in which the airflow exceeds the upper limit value.

A hybrid gas sampling device can combine the functionality of both whole air and sorbent based samplers. The sampling device can be used for collecting light to very heavy organic compounds, for subsequent thermal desorption into a GC or GCMS for quantitative measurement. The sampling device isolates collected samples of gas phase matrices in a sample vessel, provided with sorbent elements from a removable sample extraction device. The sampling device is operated by drawing a vacuum on the chamber through the sample extraction device after sampling, and then completing the extraction of the heavier organic compounds using a static, diffusive extraction under vacuum to allow optimal deposition of the heavier compounds on the sorbent. The vacuum container is cooled to draw any excess water back into the container, thereby dehydrating attached sorbent element(s) in preparation for thermal desorption into a GC or GCMS, eliminating interferences in the MS analyzer.

A handheld portable oxygen monitor for monitoring oxygen includes one or more of (1) a replaceable dust filter element removably disposed in a gas inlet pathway extending from an gas inlet port to an oxygen sensor, (2) an oxygen sensor module including the oxygen sensor and a circuit board on which the oxygen sensor is mounted, the oxygen sensor module being removably mounted to a circuit board holder, (3) configurable gas pathway components within the oxygen monitor housing, and (4) a controller operable to enable a remote device to (a) control one or more operations of the oxygen monitor, (b) receive real-time oxygen monitoring data from the oxygen monitor for display on the remote device, (c) upload logging event data from the oxygen monitor storage, (d) obtain system information from the oxygen monitor storage, and (e) perform firmware updates on the oxygen monitor to modify its programming.

A handheld portable oxygen monitor for monitoring oxygen includes one or more of (1) a replaceable dust filter element removably disposed in a gas inlet pathway extending from an gas inlet port to an oxygen sensor, (2) an oxygen sensor module including the oxygen sensor and a circuit board on which the oxygen sensor is mounted, the oxygen sensor module being removably mounted to a circuit board holder, (3) configurable gas pathway components within the oxygen monitor housing, and (4) a controller operable to enable a remote device to (a) control one or more operations of the oxygen monitor, (b) receive real-time oxygen monitoring data from the oxygen monitor for display on the remote device, (c) upload logging event data from the oxygen monitor storage, (d) obtain system information from the oxygen monitor storage, and (e) perform firmware updates on the oxygen monitor to modify its programming.

The present application discloses a portable odor detector and a method for operating the same, especially for a disposable hygiene product or its raw materials, comprising a housing, a display screen, a battery assembly, a circuit board and a sampling unit, wherein the sampling unit comprises a heat-resistant housing in which a detection chamber is defined, an odor sensor is arranged in the detection chamber.

A hydrocarbon generation pyrolysis simulation experimental device for centrifugal continuous gas sampling of a hydrocarbon source rock, including a centrifugal turntable, a motor, a quartz sample tube, a heating set, a cooling set, a rotary joint mounted coaxially with a rotating shaft of the centrifugal turntable, a vacuum pump, and vacuum gas collecting pipes, wherein a sealing plug is arranged at an orifice of the quartz sample tube, a thermocouple and a first exhaust pipeline connected with an inlet of the rotary joint are mounted on the sealing plug, the rotary joint is communicated with a vacuum pump through a second exhaust pipeline, a plurality of vacuum gas collecting pipes are respectively communicated with the second exhaust pipeline through an electromagnetic valve, a vacuum pump switching valve is mounted on the second exhaust pipeline at an inlet end of the vacuum pump, and a control circuit board is mounted on the centrifugal turntable.

A hydrocarbon generation pyrolysis simulation experimental device for centrifugal continuous gas sampling of a hydrocarbon source rock, including a centrifugal turntable, a motor, a quartz sample tube, a heating set, a cooling set, a rotary joint mounted coaxially with a rotating shaft of the centrifugal turntable, a vacuum pump, and vacuum gas collecting pipes, wherein a sealing plug is arranged at an orifice of the quartz sample tube, a thermocouple and a first exhaust pipeline connected with an inlet of the rotary joint are mounted on the sealing plug, the rotary joint is communicated with a vacuum pump through a second exhaust pipeline, a plurality of vacuum gas collecting pipes are respectively communicated with the second exhaust pipeline through an electromagnetic valve, a vacuum pump switching valve is mounted on the second exhaust pipeline at an inlet end of the vacuum pump, and a control circuit board is mounted on the centrifugal turntable.

A particle detecting module is provided and includes a base, a piezoelectric actuator, a driving circuit board, a laser component, a particulate sensor and an outer cover. A gas-guiding-component loading region and a laser loading region are separated by the base. By the design of the gas flowing path, the driving circuit board covering the bottom surface of the base, and the outer cover covering the surfaces of the base, an inlet path is defined by the gas inlet groove of the base, and an outlet path is defined by a gas outlet groove of the base. Consequently, the thickness of the particle detecting module is drastically reduced.

A particle detecting module is provided and includes a base, a piezoelectric actuator, a driving circuit board, a laser component, a particulate sensor and an outer cover. A gas-guiding-component loading region and a laser loading region are separated by the base. By the design of the gas flowing path, the driving circuit board covering the bottom surface of the base, and the outer cover covering the surfaces of the base, an inlet path is defined by the gas inlet groove of the base, and an outlet path is defined by a gas outlet groove of the base. Consequently, the thickness of the particle detecting module is drastically reduced.

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.