This invention pertains to the field of air sampling devices, more specifically, an air sampler in the general shape of an airfoil and a method for sampling air using the airfoil shaped sampler.
The collection of statistically significant quantities of particulates and contaminants of interest in atmospheric analysis typically requires high rates of airflow. Electro-mechanical air-moving devices such as pumps, fans, and blowers force air over devices such as filters and absorbents in order to provide the required airflow in typical sampling applications. Such active air-moving devices are generally costly, noisy, and heavy, and require a power source.
A need exists for a small lightweight particulate air sampler designed for use on the earth's surface as well as on vehicles. A need exists for a small lightweight air sampling device for detection of airborne chemicals particulate and contaminants at low levels of concentration. Military, homeland defense and other demands exists for an inexpensive vehicle mounted air sampler.
Applicants provide an air sampling device comprised of a frame and media members, the media members for engaging the frame, and the device for passing through the air to collect particulates when the air passes through the media members. More specifically, Applicants provide a frame for engaging media members, the frame constructed in the shape of one or more airfoils, having leading and trailing edges.
The airfoil shaped apparatus is effective, lightweight, inexpensive, and capable of mass production. It mounts to any moving carrier, and collects air samples as the carrier moves through the air.
The airfoil shaped device produces differential air pressures and air velocities over its surface according to the application of Bernoulli's law. Differential pressure provides for particulate separation according to mass and size of the individual particles, thus offering a built-in passive filtration capability.
Users of Applicants' airfoil shaped air sampler may use any vehicle, including but not limited to, a lightweight, unmanned, radio-controlled airborne vehicle, including a glider, for deploying the air sampler. Such use provides an efficient, lightweight, and highly mobile platform for Applicants' airfoil shaped air sampler.
The present invention includes a frame constructed in the shape of an airfoil. At the leading and trailing edges the airfoil typically has gaps of varying and variable dimension through which air can pass when the frame is suspended in the airflow in or around the moving carrier. The airfoil shape creates differential pressures and velocities on the top and bottom airfoil surfaces and the leading edge and trailing edge, an effect being that particulates of different size and mass tend to be separated into different air streams over, under, and through the airfoil. The airfoil itself can be constructed, at least in part, of an absorbent media which is sized to pick up particulate matter, or the airfoil may include a frame upon which an absorbent media will rest, the absorbent media for retention of particulate particles as the carrier passes through the air.
The earth sampler device of Applicants' present invention may also be designed to sample airborne chemicals. That is, airborne particulates and/or chemicals may be sampled with Applicants' present device. Indeed, Applicants' present invention may include a second airfoil shape through which a pressure differential can drive an air sample across an absorbent carbon based bed, which would pick up some chemicals in the air.
Applicants' present invention may include a means to mount the airfoil device on a moveable vehicle such as a small, lightweight, unmanned, airborne “drone,” a ground vehicle or a water craft. The means to mount may include a power server on gears to fold the air sampling device from a position in the air stream to position out of the air stream.
The air sampling device is typically small, in chord about 3.5 inches from leading edge to trailing edge and 1.3 inches in thickness (as measured between the upper and lower airfoils at the maximum point of separation). Chord range is 1.0 to 12.0 inches (preferred) and thickness range is 0.5 to 6.0 inches (preferred). The maximum width as measured across end plates (18A and 18B) is preferably about 1.5 inches (preferred range 0.5 to 3.0 inches) and the leading edges of the cup shaped frame member (17E and 17F) may be spaced apart from the adjacent airfoil by, preferably 0.25 inches (preferred range 0.1 to 1.0 inches). The preferred width of open end (17A) is about 0.5 inches (preferred range 0.1 to 1.0 inches). This is equal, in this embodiment, to the width of the leading edge gap and the trailing edge gap. The length of the inlet (I) defined by the leading edge gap is typically about 1.5 inches. Note that size of inlet (I) is typically about the same as outlet (O) defined by trailing edge gap (22).
Air flows through airfoil surface filters and inside and through the pleated or cup shaped frame member. The cup shaped frame member increases the surface area of the absorbent media that is exposed to the flowing air and tends to collect the particles of highest mass in the center pleat. Thus, the airfoil filter tends to preferentially collect particles separated by mass.
Applicants' novel air sampler (10) works without a pump or a fan. Air is pushed through the filter media by the force of air entering the inlet, and air is pulled through the filter media by the pressure differential that forms across the top and bottom of the upper and lower airfoil members as the airfoil moves through the air. The use of an electrostatic filter media provides a more efficient collection of particulates. Further, the general aerodynamic shape provides a reduction of drag. The lower pressure zones on the airfoil surfaces enhance flow through the filter. The airflow will also separate particulate deposition on absorbent media according to the size and mass of the particles. Computer testing of a model built according to dimensions set forth above yielded, at a speed of approximately 30 mph, 400 liters per minute sample volume.
When the second airfoil is fastened, as with fasteners (28), to an end plate, as here in end plate (18A), it can been seen that air passing through inlet (I) can be drawn through port (24) by the low pressure created when air flows over curved surface (22A), the air passing from the interior defined by the upper and lower airfoil through the port and through the filtering assembly. Sorbent bed (26C) may be made of Carboxen™, an activated charcoal. Carboxen is available from Scientific Instrument Services, Inc.
Although the invention has been described with reference to specific embodiments, this description is not meant to be construed in a limited sense. Various modifications of the disclosed embodiments, as well as alternative embodiments of the inventions will become apparent to persons skilled in the art upon the reference to the description of the invention. It is, therefore, contemplated that the appended claims will cover such modifications that fall within the scope of the invention.
This application claims priority from provisional patent No. 60/387,228 filed Jun. 7, 2002.
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3710557 | Couchman et al. | Jan 1973 | A |
3802167 | Turman | Apr 1974 | A |
3868222 | Barringer | Feb 1975 | A |
3977479 | Sainsbury | Aug 1976 | A |
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Number | Date | Country | |
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20040050183 A1 | Mar 2004 | US |
Number | Date | Country | |
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60387228 | Jun 2002 | US |