A Basic Experimental Study on Analysis of Leak Signal and Monitoring Method for Water Supply Pipe

Water supply systems are essential elements for human life and industry, and water leaks and water supply cut-off may cause major problems. Local water leaks and pipe failures in the water supply system are inevitable problems due to the aging of pipes. Therefore, leakage detection and prevention are required to monitor the integrity of the water supply system. This paper is a fundamental study on the applicability of the smart bolt, which was developed as a monitoring system to detect water leakage in water supply monitoring. Detection experiments were conducted using a smart bolt with a built-in strain sensor and an accelerometer. Through finite element analysis using ANSYS 2019 R2 and tensile strength testing, the strength of the smart bolt was confirmed to have the acceptable tensile strength. The smart bolt used in this study was verified to meet the allowable criteria of torque and tensile stress for a municipal water supply system. The frequency responses of the simulated leakage pipe system, according to the leakage of the valve and the main pipe, were analyzed, and a leak signal at the valve leak point was detected in the 60-Hz band. The main pipe leaking point was observed to produce a leak signal with a much higher-order mode than that of the valve leak point. Therefore, the smart bolt can be applied to detect warning leak signs from water supply valves and to monitor for loosening of the bolts.

Validation of Valve Leak Quantification With Non-Intrusive Acoustic Emission Technology

In the late 1980s and early 90s, several companies tested a range of acoustic devices for monitoring valve leakage during the check-valve diagnostic system research performed at the Utah State Water Research Laboratory as part of two separate nuclear-industry-sponsored initiatives. The acoustic sensor technology and analysis techniques evaluated were found helpful but no progress was made in non-intrusively quantifying the leak rate through the valves tested during these programs. Around that same time, oil & gas companies in the UK were experimenting with detection and quantification of valve leakage using acoustic emission (AE) technology. The AE sensors and signal-processing technology selected for the UK oil & gas effort responded to much higher frequencies compared to the sensors and systems used during the nuclear-utility initiative in the U.S. This research led to new products for detection and quantification of valve leakage in oil & gas applications. Because of minimum leak threshold and accuracy concerns, non-intrusive acoustic valve leak measurement has remained an elusive goal for commercial nuclear power. Various general-purpose acoustic tools have been trialed to detect leakage with mixed results because of complications caused by plant and system acoustic characteristics. Several of today’s moderately successful check-valve diagnostic systems employ acoustic sensors and can detect the most likely event representing flow cutoff when a check-valve disc fully closes, but leak-rate quantification with any of these systems is not possible. Correlation methods and other AE analysis techniques that have been developed to quantify leakage in steam systems have been generalized as small, medium, and large leakage classifications with no clear criteria for these levels. During the last couple of years, nuclear-plant engineers responsible for programs for compliance with Appendix J, “Primary Reactor Containment Leakage Testing for Water-Cooled Power Reactors,” to Part 50, “Domestic Licensing of Production and Utilization Facilities,” of Title 10, “Energy,” of the Code of Federal Regulations (Appendix J to 10 CFR 50) have made extensive use of a new acoustic valve leak-detection system known as MIDAS Meter®. Appendix J valve testing (also known as Type C testing) requires that sections of nuclear-plant piping be isolated by closing a number of valves, thereby creating a confined pressure boundary. The isolated piping within the boundary is pressurized with approximately 344.7 kilopascals (kPa) [50 pounds per square inch (psi)] of air and the leak-tightness of the boundary is evaluated. When the isolated piping exhibits excess leakage or cannot maintain the test pressure, the valves creating the boundary are evaluated one by one to find the culprit leaker. The process of finding and correcting the problem valve can take from hours to several days and may become an outage critical-path activity. Appendix J engineers have enjoyed considerable success with their newfound ability to quickly and confidently identify the leaking valves with MIDAS Meter® and remove their test programs from the critical path. MIDAS Meter® is a high-frequency acoustic-emission-based system which includes algorithms that convert the acoustic emission signal to leak rate. The basic algorithms were first developed from the field results obtained during the early development work for UK oil & gas operators and refined over the next 20 years. Though not originally validated under a quality-assurance (QA) program of the 10 CFR 50 type, nuclear plants that own MIDAS Meter® have been eager to go beyond simple troubleshooting and use the leak quantification results for nuclear applications, including safety-related decisionmaking. In order to support owners and avoid improper application of this very successful new tool, Score Atlanta embarked on an extensive validation program consistent with 10 CFR Part 50 requirements. A purpose-built leak-test flow loop and valve simulator apparatus were constructed in the Atlanta facility and testing began in early 2013. To support Appendix J users, the air testing was performed first and completed in July 2013. The water testing followed and should be completed in early 2014. Numerous combinations of leak path, leak-path geometry, and differential pressure were created and evaluated during the air phase of the program. Pressure was limited to 1034 kPa [150 psi] for air testing. The water testing includes pressures up to 8,618 kPa [1,250 psi] and a similar number of varying leak paths and pressure test points. This paper discusses the preliminary results of the test program, including any special limitations required for use of AE-derived valve leak results in nuclear safety-related applications. The full results of the test program and guidance for nuclear safety-related use of the technology are expected to be available ahead of the 2014 ASME-NRC Valve Symposium. Paper published with permission.

Acquired Von Willebrand Syndrome In Mitral Valve Leak

Abstract 4657 Background Several studies have shown that between 15% to 25% of patients with severe aortic stenosis present bleeding episodes that may be attributed to an acquired von Willebrand syndrome (AVWS). Until now, to our knowledge, no association of AVWS with mitral valve disfunction has been reported. Design and Methods Four patients with mitral valve leak presented acquired abnormalities of von Willebrand factor (VWF) and a bleeding history. Two of them presented severe bleedings requiring blood transfusions. All of them were within an adequate range of oral anticoagulation. Results Prior to surgery, these patients presented an APTT prolonged and in two of them the closure time determined by the platelet function analyzer (PFA-100®) (with COL/ADP and COL/Epi) was prolonged also. Factor VIII procoagulant activity (FVIII:C), VWF antigen (VWF:Ag), VWF ristocetin cofactor activity (VWF:RCo) and VWF collagen binding (VWF:CB) were considerably elevated and the VWF multimers in plasma, showed a lower relative proportion of the high molecular weight VWF multimers (HMWM), to some extent similar to type 2A congenital von Willebrand disease (VWD). In two of them, the VWF:RCo/VWF:Ag or VWF: CB/VWF:Ag ratios were less than normal range (>0.7) while in the other two were normal. After surgery, FVIII:C, and VWF properties were extremely increased and the ratios VWF:RCo/VWF:Ag and VWF: CB/VWF:Ag > 0.7. After surgery, FVIII:C, VWF:Ag, VWF:RCo and VWF:CB increased considerably. The ratios were > 0.7. The PFA-100® (COL/ADP and COL/Epi) was corrected in the two patients who had it prolonged. The multimeric VWF profile were also corrected in all of them. Conclusions The present study describes acquired VWF qualitative alterations for the first time in mitral valve leak. When such alterations are important they may be associated or to contribute to a bleeding diathesis. This problem was reported previously in aortic valve stenosis in relationship with a suspected very high shear stress. This situation may be not usually present in mitral valve stenosis, but it seems that it must occur in the presence of mitral valve leak. Consequently, the AVWS should be taken into account in patients with mitral valve leak that present a bleeding diathesis, not explained by an excess of oral anticoagulation. ACKNOWLEDGEMENTS This work was supported by the Fondo de Investigación Sanitaria, F.I.S. Carlos III, Ministerio de Sanidad, Spain (FIS PI# 07/0229), and Consellería de Innovación e Industria, Xunta de Galicia (INCITE08ENA916109ES). Disclosures: No relevant conflicts of interest to declare.