Method for detecting heat exchanger tube failures when using...

Data processing: measuring – calibrating – or testing – Measurement system – Performance or efficiency evaluation

Reexamination Certificate

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C702S022000, C702S051000, C165S011100, C431S016000

Reexamination Certificate

active

06745152

ABSTRACT:

This invention relates to a fossil-fired thermal system such as a power plant or steam generator, and, more particularly, to a method for rapid detection of tube failures without need for direct instrumentation, thereby preventing serious damage and minimizing repair time on the effected heat exchanger.
BACKGROUND OF THE INVENTION
Although especially applicable to “The Input/Loss Method” when installed at coal-fired power plants, this invention may be applied to any on-line monitoring method, and other “Input/Loss methods”, installed at any thermal system burning a fossil fuel. Such monitoring is assumed to be conducted in a continuous manner (i.e., on-line), processing one monitoring cycle after another, each cycle includes determining stoichiometric balances of the combustion process. Specifically, The Input/Loss Method and its associated technologies are described in the following U.S. patent applications Ser. No. 09/273,711 (hereinafter termed '711) now U.S. Pat. No. 6,522,994 issued Feb. 18, 2003; U.S. Ser. No. 09/630,853 (hereinafter termed '853) now U.S. Pat. No. 6,584,429 issued Jun. 24, 2003; and U.S. Ser. No. 10/087,879 (hereinafter termed '879); and in their related provisional patent applications and Continuation-In-Parts. One of the Input/Loss methods, a rudimentary method, is described in U.S. Pat. No. 5,367,470 issued Nov. 22, 1994 (hereinafter termed '470), and in U.S. Pat. No. 5,790,420 issued Aug. 4, 1998 (hereinafter termed '420).
Large fossil-fired thermal systems, and especially coal-fired power plants, having large heat exchangers, are prone to tube leaks of their working fluid (typically water as liquid or steam). These tube leaks represent a potential for serious physical damage to heat exchangers due to pipe whip and/or steam cutting of metal given high leakages flowing at critical velocities. In a modern steam generating system, pressures of the working fluid commonly exceed 2300 psia; for a super-critical system, pressures of 3300 psia are not uncommon. Given failure of a heat exchanger tube, such fluid will experience many times critical pressure ratios as it expands into the combustion gases; that is, mixing with the products of combustion at essentially atmospheric pressure. When undetected, the damage from such tube failures may range from $2 to $10 million/leak forcing the system down for major repairs lasting up to a week. If detecte early, tube failures may be repaired before catastrophic damage, such repairs lasting only several days costing a fraction of the cost associated with late detection and catastrophic damage.
Tube failures in fossil-fired systems are typically caused by one the following general categories:
Metallurgical damage caused by hydrogen absorption in the metal resulting in either embrittlement or the formation of non-protective magnetite;
Caustic gouging caused by the presence of free hydroxide in the water;
Corrosion-fatigue damage caused from the water-side of the tube, compounded by stress;
Corrosion damage caused by impacts from ash particles associated with coal-fired systems;
Fatigue failure caused by oxidation and/or mechanical movement, compounded by stress; and
Overheating (e.g., from tube blockage) causing local creep.
Commonly, the physical leak initiates as a relatively small penetration, although initial breaks may also occur. For reference and further discussion see: Chapter 18, “Failure Analysis and In-Service Experience—Fossil Boilers and Other Heat Transfer Surface” of
The ASME Handbook on Water Technology for Thermal Power Systems
, P. Cohen, Editor, The American Society of Mechanical Engineers, New York, N.Y., 1989.
Present industrial art has practiced the detection of tube failures by either acoustic monitoring devices; through water balance testing; or through the monitoring of effluent H
2
O using inumentation mounted in the “smoke Stack”. Acoustic devices detect the unique noise created by fluids at critical velocities. However, acoustic devices rarely work in large steam generators, are expensive and require benchmarking with known acoustical signatures. Water balance testing may be conducted periodically on the entire system through which large water losses due to tube failures might be discovered. However, water balance testing is expensive, insensitive to small leaks, and typically may not be conducted at sufficient frequency to prevent serious damage. The use of an effluent H
2
O instrument has been shown to be sensitive to tube failures. However, effluent H
2
O instrumentation may not differentiate between originating sources of water (e.g., between high humidity in the combustion air, or high fuel water, or tube leakage). In practice all known methods suffer serious short-comings and are not reliable in detecting early tube failures.
The patents '470 and '420 make no mention of heat exchanger tube failures nor their detection. Although the technologies of Applications '711 and '853 support this invention, they make no mention of tube failures nor their detection without direct instrumentation. Application '879 supports this invention directly. '879 encompassing methods include water in-leakage representing tube leakage. There is no established art related to this invention; there is, however, a clear need for early detection of tube failures in fossil-fired systems
SUMMARY OF THE INVENTION
This invention relates to a fossil-fired thermal system such as a power plant or steam generator, and, more particularly, to a method for rapid detection of tube failures without direct instrumentation, thereby preventing serious damage and minimizing repair time on the effected heat exchanger. Tube failures are detected through use of combustion stoichiometrics, in combination with an ability to correct effluent data through use of optimization procedures. Further, this invention teaches how the stoichiometric mechanism of tube failure may be identified and reported to the system operator.
This invention addresses the deficiencies found in all present detection methods. Effluent water (at the Stack) may have any one or all of the following sources: heat exchanger tube leaks; combustion of hydrocarbon fuels; water added at the point of combustion (e.g., steam used to atomize fuel); free water born by the fuel; moisture carried by combustion air including air leakage; pollutant control processes resulting in the in-flow of water, and/or soot blowing processes using water to clean heat exchanger surfaces (typically used in coal-fired systems). All such sources of effluent water are addressed by this invention through combustion stoichiometrics in combination with an ability to correct effluent data through use of optimization procedures.
This invention adds to the technology associated with Input/Loss methods. Specifically The Input/Loss Method has been applied to computer software, installable on a personal computer termed a “Calculational Engine”, and has been demonstrated as being highly useful to power plant engineers. The Calculational Engine receives data from the system's data acquisition devices. The Calculational Engine's software consists of the EX-FOSS, FUEL and HEATRATE programs described in '711, and in
FIG. 2
herein, and the ERR-CALC program described in '879, and in
FIG. 3
herein ERR-CALC now incorporates the teachings of this invention. The Calculational Engine continuously monitors system heat rate on-line, i.e., in essentially real-time, as long as the thermal system is burning fuel. The application of this invention to The Input/Loss Method as taught in '711 and installed as part of the Calculational Engine significantly enhances the power plant engineer's ability to predict tube failures and reduce outage time required for repair.
The present invention provides a procedure for determining tube leaks in a fossil-fired thermal system such as a power plant or steam generator, using combustion stoichiometrics in combination with an ability to correct effluent data such that consistent fuel chemistry is co

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