Gas separation: apparatus – With control means responsive to sensed condition for... – Gas cutoff or diversion
Reexamination Certificate
2002-06-25
2003-12-02
Smith, Duane S. (Department: 1724)
Gas separation: apparatus
With control means responsive to sensed condition for...
Gas cutoff or diversion
C096S400000, C137S460000, C137S498000, C210S100000
Reexamination Certificate
active
06656254
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates generally to fluid flow control systems, and to mechanical failsafes or shut-off devices for preventing the flow of fluids (e.g., gas or liquid streams) upon breakage or failure of components in the system, such as filters or other components. More particularly, the invention relates to devices for preventing the flow of high-temperature (e.g., up to 1800° F.) gas streams upon filter damage.
2. Description of Background Art
Industrial systems in which fluids flow (such as gas turbine power plants, liquid fuel processing plants, hydraulic systems, pneumatic systems and the like), and in which gases are usually cleansed of entrained particulate matter or treated prior to coming into contact with system components that are susceptible to such particulate matter, usually provide filtration for removing impurities and/or restricting flow to system design levels. To prevent damage to system components and/or the environment, such systems often are provided with flow limiting or shut-off valve mechanisms. Upon the occurrence of damage, breakage or removal of filter components, these shut-off mechanisms stop the flow of fluid through the system.
In particular, high temperature and high pressure barrier filter systems are critical to the successful commercialization of PFBC and IGCC coal-based power plant systems. Presently the most commercially ready barrier filter systems are based on candle filter technology. These barrier filter systems generally employ a large number of individual, porous candle filter elements in parallel.
Pilot-scale candle filter-based systems have been shown to remove particulate matter down to a concentration of less than 1 ppm (part per million) when in good operating condition. However, in the event of the failure of even a single filter element, the filter system outlet dust loading will increase and thereby potentially damage gas turbine blades, contaminate other downstream processes, and limit the availability of the power system. A filter failure safeguard device which would prevent the flow of particle-laden gas through the failed filter element location would serve to minimize the potential damage to downstream equipment, minimize dust emissions, and allow the power plant to continue operation until a convenient or scheduled outage can be implemented.
Various types of flow limiting/shut-off mechanisms are known in the prior art, see e.g., U.S. Pat. Nos. 5,242,581; 3,261,146; 2,892,512; 2,833,117; 2,687,745; 2,680,451; 2,635,629; 1,983,791. Such mechanisms are characterized by their complicated structure, large number of moving parts, difficulty in installation, limited operational temperature ranges, and/or dependence on entrained particle concentration for activation of the shut-off feature.
There remains a need in the art for improvement to the structure of mechanical fluid flow shut-off devices.
SUMMARY OF THE INVENTION
The present invention provides an improvement to the prior art, by providing according to one embodiment a full-flow failsafe, including a filter element for filtering entrained particles from a flowing fluid stream, a shell having apertures at each end thereof for enabling the fluid stream to flow therethrough, a first one of the apertures being coupled to the filter element, a sealing plug movably positioned within the shell, the sealing plug being oriented in a first position during normal operation of the filter element to permit fluid flow through the shell, and, upon failure or breakage of the filter element, being moved by increased fluid velocity to a second position wherein the sealing plug forms a sealing contact with a second one of the apertures, and a locking mechanism supporting the sealing plug in the first position, and being moved to a locking position for securing the sealing plug in the second position in response to the movement of the sealing plug.
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Smith Duane S.
Southern Research Institute
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