This book describes efficient and safe repair operations for pipelines, and develops new methods for the detection and repair of volumetric surface defects in transmission pipelines. It also addresses the physics, mechanics, and applications of advanced materials used for composite repair of corroded pipelines.
Presenting results obtained in the European Commissions INNOPIPES FRAMEWORK 7 programme, it develops long-range ultrasonic and phased array technologies for pipeline diagnostics, and explores their interactions with discontinuities and directional properties of ultrasonic antenna array. The book subsequently shares the results of non-destructive testing for different types of materials applications and advanced composite repair systems, and characterizes the mechanical properties by means of fracture methods and non-destructive techniques.
In turn, the book assesses the currently available technologies for reinforcement of pipelines, drawing on the experience gai
ned by project partners, and evaluates the recovery of the carrying capacity of pipeline sections with local corrosion damage by means of analytical and numerical procedures. It develops an optimization method based on the planning of experiments and surface techniques for advanced composite repair systems, before validating the numerical models developed and experimentally gauging the effectiveness of composite repair with the help of full-scale hydraulic tests.
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PART I Non-destructive Testing of Transmission Pipelines |
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Long-Range Ultrasonic and Phased Array Technologies |
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3 | (12) |
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T- and L-Types of Long-Range Guided Waves for Defect Detection |
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15 | (16) |
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Directional Properties of Ultrasonic Antenna Array |
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31 | (14) |
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Interaction of Low-Frequency Guided Waves with Discontinuities |
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45 | (18) |
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Vibration-Based Damage Detection of Steel Pipeline Systems |
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63 | (10) |
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Localization of Impact Damage in Thin-Walled Composite Structure Using Variance-Based Continuous Wavelet Transform |
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73 | (18) |
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Identification of Defects in Pipelines Through a Combination of FEM and ANN |
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91 | (16) |
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Dynamic Properties of Thin-Walled Structures Under Changing Pressure Conditions in the Contact Fluid |
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107 | (10) |
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PART II Volumetric Surface Defects in Transmission Pipelines |
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Characterisation of Volumetric Surface Defects |
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117 | (20) |
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Assessment of the Remaining Strength Factor and Residual Life of Damaged Pipelines |
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137 | (16) |
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Assessment of Interacting Volumetric Surface Defects |
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153 | (16) |
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PART III Materials Used for the Composite Repair Systems of Transmission Pipelines |
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Review on Materials for Composite Repair Systems |
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169 | (22) |
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Techniques for Non-destructive Material Properties Characterisation |
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191 | (18) |
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Characterization of Elastic Properties of Metals and Composites by Laser-Induced Ultrasound |
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209 | (18) |
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Experimental Characterization of Composite Material Properties |
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227 | (14) |
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PART IV Technologies Used for the Composite Repair Systems of Transmission Pipelines |
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Comparative Analysis of Existing Technologies for Composite Repair Systems |
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241 | (28) |
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Design of Composite Repair Systems |
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269 | (20) |
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PART V Simulation of Advanced Composite Repair Systems of Transmission Pipelines |
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Finite Element Stress Analysis of Pipelines with Advanced Composite Repair |
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289 | (22) |
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Finite-Element Modeling of a Repaired Pipeline Containing Two Volumetric Surface Defects |
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311 | (10) |
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Assessment of the Reinforcement Capacity of Composite Repair Systems for Pipelines with Interacting Defects |
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321 | (18) |
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Modeling of the Contact Interaction Between Steel Pipe and Composite Bandage |
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339 | (14) |
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Experimental and Numerical Research of Renovated Pipeline Prototype with Surface Defect |
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353 | (16) |
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Analytical Modeling of the Damaged Zone of Pipelines Repaired with Composite Materials Systems |
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369 | (18) |
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Optimal Design of Composite Repair Systems of Transmission Pipelines |
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387 | (14) |
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PART VI Testing of Advanced Composite Repair Systems of Transmission Pipelines |
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Development of an Experimental Programme for Industrial Approbation |
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401 | (16) |
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Inner Pressure Testing of Full-Scale Pipe Samples |
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417 | (14) |
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Effectiveness Assessment of Composite Repair Systems |
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431 | (18) |
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Errata to: Non-destructive Testing and Repair of Pipelines |
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1 | |
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| Index |
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449 | |
Prof., Dr.Sc.Ing. Evgeny Barkanov graduated from Riga Polytechnical Institute, Faculty of Technical Appliances and Automation in 1986 with the first-class Dipl.-Ing. He defended the Dr.Sc.Ing.thesis on Mechanics of Deformable Solids in 1993 at Riga Technical University. He is the author of 3 textbooks and more than 100 scientific publications in the field of computational mechanics, mechanics of composite materials, vibration damping and optimization. He improved the qualification and carried out scientific investigations abroad via TEMPUS JEP, TEMPUS IMG, the Royal Society, the British Council, NATO Research Fellowship, Konferenz der Deutschen Akademien der Wissenschaften, DFG, DAAD, NSC of Taiwan, SOCRATES. He is leader/contractor in many national and international projects (FRAMEWORK 5: SANDWICH; FRAMEWORK 6: ALCAS, FRIENDCOPTER, INTERSHIP, CASSEM, DE-LIGHT, MOMENTUM, SAND.CORe; FRAMEWORK 7: COALINE, INNOPIPES; MATERA: ADYMA; COST: COINAPO). He is a member of the Prof
essor Council in the Civil Engineering and Architecture, Promotion Councils RTU P-03 and RTU P-06, and RTU Academic Assembly. He is expert in the Latvian Ministry of Education and Science, Latvian Council of Science, EU FRAMEWORK 6-7 and HORIZON 2020 programs.
Prof., Ph.D. Eng. Andrei Dumitrescu graduated from the Technological Equipment Faculty of the Petroleum and Gas Institute of Ploiesti (presently PGUP) in 1989 with Merit Diploma (top position in the class). He defended the Ph.D thesis in Technical Sciences (Oilfield Equipment) in 1998 at the Petroleum-Gas University of Ploiesti (PGUP). He is the main/only author of 3 textbooks and co-author of other 6 textbooks and of more than 55 scientific publications in the field of petroleum equipment (mainly oilfield tubulars and transmission pipelines), materials technologies and production systems engineering. He had an experience abroad (in Italy) as R&D Sealines Engineer for Snamprogetti, S.p.A. an
d SeniorSealines Engineer for Saipem, S.p.A. He is leader/contractor in several national projects and for one European project (FRAMEWORK 7: INNOPIPES). He is a member of the Professors Council of the Mechanical and Electrical Engineering Faculty, of the PGUP Senate, and of the PGUP Senate Bureau. He is the Editor-in-Chief of the Petroleum-Gas University of Ploiesti Bulletin, Technical Series, and expert of the Technical Committee 89 (Industrial valves) of ASRO (Romanian Standards Association). He is a member of the European Structural Integrity Society, Society of Petroleum Engineers, and Treasurer of the Romanian Association of Fracture Mechanics.
Dr Sc Ivan A. Parinov received his MSc degree in Mechanics from Rostov State University, Department of Mechanics and Mathematics in 1978 (Rostov-on-Don, Russia), his PhD in Physics and Mathematics from Rostov State University in 1990, and his Dr Sc from the South-Russian State Technical University i
n 2008. He is aCorresponding Member of the Russian Academy of Engineering (2014). He has worked at the I.I. Vorovich Mathematics, Mechanics and Computer Sciences Institute of the Southern Federal University (former Rostov State University) since 1978, where he is now the Chief Research Fellow.
From 1993 to 2016 he was the Head of the Research Grants and Programs from Soros Foundation, Collaboration for Basic Science and Education (COBASE, USA), Russian Foundation for Basic Research (13 grants), and Russian Ministry for Science and Education (7 grants and scientific proposals).
He has published more than 280 scientific-technical publications, including 21 monographs (in particular, 4 books published with Springer and 11 books with Nova Science Publishers). He holds 11 Russian patents.
Dr Parinov has been a reviewer for the Zentralblatt für Mathematik (Germany) and Mathematical Reviews (USA) since 1994 (ca. 450 reviews), as well as the journal SOP Tra
nsactions on TheoreticalPhysics (Scientific Online Publishing) since 2013. Further, he is an Active Member of the New York Academy of Sciences, American Mathematical Society, European Mathematical Society, and Indian Structural Integrity Society, and holds the title Honorary Member of the All-Russian Society of Inventors and Rationalizers.
His research interests include R&D of novel materials and composites (in particular, high-temperature superconductors and ferro-piezoelectrics), fracture mechanics and strength physics, acoustic emissions, optics, mathematical modeling, and various applications of advanced materials and composites.
