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A condensation nucleus counter has a series of flow passageways forming a flow path, including a first passageway for carrying the gas stream having the particles to be detected which is preferably preheated A saturator is positioned to receive the flow of the gas stream and is made of a porous mate

A condensation nucleus counter has a series of flow passageways forming a flow path, including a first passageway for carrying the gas stream having the particles to be detected which is preferably preheated A saturator is positioned to receive the flow of the gas stream and is made of a porous material of a controlled pore size having a portion immersed in a liquid working fluid. The liquid working fluid moves by capillary action along the length of the saturator. Vapor from the working liquid will be transferred to the gas stream as it moves through the saturator. The gas stream then passes to a condenser that reduces the temperature of the gas stream and causes the working fluid vapor to condense on the particles in the gas stream to form droplets that can be detected and counted.

대표청구항 ▼

1. A continuous flow apparatus for detecting particles contained in a gas stream moving along a path, including:a source of a working fluid in liquid form;saturating means positioned along the path, for providing a vapor form of the working fluid to the gas stream, said saturating means including a

1. A continuous flow apparatus for detecting particles contained in a gas stream moving along a path, including:a source of a working fluid in liquid form;saturating means positioned along the path, for providing a vapor form of the working fluid to the gas stream, said saturating means including a porous metal in fluid communication with the fluid source and over which the gas stream passes;a heated metal block in thermal contact with the porous metal and spaced from the working fluid to heat said porous metal, the porous metal extending from the heated metal block to contact the working fluid;cooling means along the path of the gas stream and downstream of the saturating means to cause vapor condensation on the particles to form droplets in the gas stream; anda sensor downstream of the cooling means for detecting the droplets. 2. The apparatus of claim 1 wherein the porous metal has pores smaller than 500 μm in diameter. 3. A continuous flow apparatus for detecting particles in a gas stream, including:a source of a gas sample moving in a stream along a path, said gas sample containing fine particles and water vapor;a fluid source of a working fluid in liquid form;a saturator comprising a passageway along the path and in fluid communication with the fluid source, and operable to provide working fluid vapor to the gas,a cooler along the path and downstream of the saturator to cause vapor to condense on the particles in the gas stream to form droplets;a collector below the cooler to receive working fluid and water vapor condensing on the surface of the cooler and draining by gravity to the collector; anda sensor downstream of the cooler for detecting the droplets. 4. A continuous flow apparatus for detecting particles in a gas stream moving under pressure differentials, including:a fluid source of a vaporizable working fluid in liquid form;a saturator in fluid communication with the fluid source for providing working fluid vapor to the gas, said saturator including a porous material having a wall defining an interior space, and an orifice through which the gas stream moves to form a gas jet impinging into the interior space, said orifice having an area smaller than the cross-sectional area of the interior space;a gas cooler receiving the gas stream downstream of the saturator to cool the gas to cause vapor condensation on the particles in the gas stream to form droplets; anda sensor downstream of the gas cooler carrying the gas and detecting the droplets. 5. The apparatus of claim 4 wherein the average gas velocity flowing through the orifice is at least 50 cm/sec. 6. The apparatus of claim 4 wherein at least two orifices are used in the inlet to the saturator. 7. A continuous flow apparatus for detecting particles in a gas stream, including:a flow generator to draw a gas sample in a stream along a path through the apparatus;a fluid source of a working fluid in liquid form in a container and the liquid having an upper level;a saturator along the path and including a support block spaced from the upper level of the liquid with a fluid transfer element extending from the block to contact the liquid in the container to be in fluid communication with the fluid source for providing working fluid vapor to mix in the gas stream;a condenser along the path and downstream of the saturator for causing vapor of the working fluid in the gas stream to condense on the particles to form droplets, said condenser including a chamber with cold walls and an inlet orifice for admitting the gas stream into the chamber, said orifice providing a gas jet impinging into the interior space of the chamber; anda sensor downstream of the condenser for detecting the droplets in the gas stream. 8. The apparatus of claim 7 wherein the average gas velocity flowing through the orifice is at least 50 cm/sec. 9. The apparatus of claim 8 wherein at least two orifices are used to form the inlet orifices. 10. The apparatus of claim 7 further including a thermo electric module in thermal relation to a heat conducting support spaced from the liquid working fluid to selectively provide heating or cooling needed to keep the saturator at a desired temperature. 11. A continuous flow apparatus for detecting particles in a gas stream, including:means to draw a gas sample in a gas stream along a path, said gas sample containing fine particles;a source of a working fluid in liquid form in a supply container;a saturator for providing working fluid vapor to the gas stream, said saturator including a thermoelectric module in thermal relation to a heat conducting support spaced from the liquid working fluid, the saturator having a first portion extending from the support to engage the liquid working fluid to conduct the working fluid to a second portion of the saturator;a cooler along the path and downstream of the saturation means to cause vapor condensation on the particles to form droplets; andsensing means receiving the gas stream downstream of the cooler for detecting the droplets. 12. A continuous flow apparatus for detecting particles in a gas stream, including:a flow inducing apparatus to draw a gas sample in a stream along first, second and third passageways connected in series, said gas sample containing fine particles;a fluid source of a working fluid in liquid form;a heater to heat the gas sample to a selected temperature while the gas stream moves along the first passageway;a saturator having the second passageway connected to receive the gas stream from the first passageway, the saturator having a heated element in fluid communication with the working fluid for providing working fluid vapor to the gas stream as the gas stream moves through the second passageway; anda cooler having the third passageway to receive the gas stream from the second passageway to cause vapor condensation on particles in the gas stream to form droplets. 13. The continuous flow apparatus of claim 12, wherein an orifice is positioned between the first and second passageways to form a gas jet in the second passageway. 14. The continuous flow apparatus of claim 13, wherein a saturator heated element comprises a tube forming the second passageway, the tube being porous and having a portion in the working fluid source and other portions of the tube being spaced from the fluid source, the pores in the saturator causing capillary movement of the working fluid liquid to the surface of the second passageway. 15. The continuous flow apparatus of claim 14, wherein said tube is a porous metal tube, having a generally upright axis, the orifice between the first and second passageway being at an upper end of the tube, and the second passageway being connected to the third passageway with a tubular connector at a lower end of the third passageway. 16. The continuous flow apparatus of claim 14 and a plug in an interior of the tube spaced from the portion of the tube in the working fluid source to block the interior. 17. The continuous flow apparatus of claim 12, further characterized by an orifice between the second passageway and the third passageway, said third passageway carrying a gas jet formed by said orifice. 18. The continuous flow apparatus of claim 12, wherein the cooler comprises a block, and a thermoelectric cooler in heat conducting relation to the block. 19. The continuous flow apparatus of claim 12, and a sensor comprising a light scattering droplet counter connected to receive the gas stream from the third passageway. 20. A multi-channel, continuous flow apparatus for detecting particles in at least two separate gas streams, comprising a common fluid source containing a working fluid in liquid form for all channels, a common heating block for heating saturators for all channels, and a common cooling block to provide cooling for all channels, each channel of the apparatus being for detecting particles in a respective separate gas stream, each channel including:an apparatus creating a pressure differential to draw a gas sample in a stream along a path, said sample gas containing fine particles;a saturator in thermal contact with the common heating block along the path and in fluid communication with the common fluid source for providing working fluid vapor intermixed with the sample gas;a cooler in the form of a passageway in the common cooling block along the path and downstream of the saturator to cause vapor condensation on the particles to form droplets; anda particle detector downstream of the cooler for detecting droplets in the gas stream. 21. The apparatus of claim 20, wherein said saturator for each channel is supported on a support in close thermal contact with the saturator for each of the other channels and the saturators being held at substantially the same temperature. 22. The apparatus of claim 21, wherein said cooler for each channel is supported on the support in close thermal contact with the cooler of other adjacent channels and at substantially the same temperature.