Abstract: This invention relates generally to characterizing bioaerosols and, more particularly, to a system for recovering, quantifying, identifying, and assessing the metabolic activities of bioaerosols based on their major biopolymer profiles (lipids, carbohydrate and protein) and more specific their genetic materials (DNA/RNA), such as airborne viruses, bacteria, fungi and pollens.

Abstract: A particle detector for rapidly detecting and identifying sub 20 nm particles in Ultra Pure Water (UPW) is disclosed. The detector has a nano particle extractor, a nanoparticle collector, and a tracer particle introducer. The extractor limits the size of droplets output to a predetermined size. The extractor includes (1) a liquid sample inlet, (2) a nebulizer connected to the liquid sample inlet (the nebulizer has a gas supply, and an outlet), (3) an impactor arranged to receive material output from the nebulizer, (4) an evaporator connected to the nebulizer and impactor for providing an aerosol at the extractor outlet, and (5) an aerosol connected to the evaporator. The collector us connected to the extractor and has: (1) a collector inlet connected to the aerosol outlet of the extractor, (2) a vapor condensation growth tube connected to the collector inlet, and (3) a repositionable particle capture plate arranged to receive material output from the growth tube at spatially varying positions.

Abstract: This invention relates generally to characterizing bioaerosols and, more particularly, to a system for recovering, quantifying, identifying, and assessing the metabolic activities of bioaerosols based on their major biopolymer profiles (lipids, carbohydrate and protein) and more specific their genetic materials (DNA/RNA), such as airborne viruses, bacteria, fungi and pollens.

Abstract: A particle detector for rapidly detecting and identifying sub 20 nm particles in Ultra Pure Water (UPW) is disclosed. The detector has a nano particle extractor, a nanoparticle collector, and a tracer particle introducer. The extractor limits the size of droplets output to a predetermined size. The extractor includes (1) a liquid sample inlet, (2) a nebulizer connected to the liquid sample inlet (the nebulizer has a gas supply, and an outlet), (3) an impactor arranged to receive material output from the nebulizer, (4) an evaporator connected to the nebulizer and impactor for providing an aerosol at the extractor outlet, and (5) an aerosol connected to the evaporator. The collector us connected to the extractor and has: (1) a collector inlet connected to the aerosol outlet of the extractor, (2) a vapor condensation growth tube connected to the collector inlet, and (3) a repositionable particle capture plate arranged to receive material output from the growth tube at spatially varying positions.

Abstract: A system and process for respirator fit-testing are disclosed. The system includes conduits for taking first and second aerosol samples, from inside of the respirator mask and from outside of the mask, respectively. The samples are provided to a radial differential mobility analyzer for generating first and second modified samples corresponding to the aerosol samples. The modified samples are provided to a condensation particle counter, which generates first and second concentration values representing concentrations of suspended elements in the respective modified samples. Comparison of the concentration values yields a fit factor indicating how effectively the respirator seals against leaks. Alternative embodiment systems employ a cylindrical DMA, an electrical precipitator, or an inertial separating device in lieu of the radial DMA. For generating concentration values, an electrometer, a photometer or an optical particle counter can be used in lieu of the condensation particle counter.

Abstract: A condensation nucleus counter (1) for measuring particulate concentration within a gaseous environment, including an inlet orifice (3) leading to a flow path (5) within saturator (4). The resultant vapor (10) enters a condenser section (11) wherein the particulate matter suspended within serves as the nucleus for condensation. The enlarged droplets (23) thus formed enter a conventional optical particle counter section (15).