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Radioisotope Techniques for Problem-Solving in Industrial Process Plants PDF

326 Pages·1986·8.454 MB·English
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RADIOISOTOPE TECHNIQUES FOR PROBLEM SOLVING IN INDUSTRIAL PROCESS PLANTS RADIOISOTOPE TECHNIQUES FOR PROBLEM SOLVING IN INDUSTRIAL PROCESS PLANTS Edited by J. S. CHARLTON Physics and Radioisotope Services Imperial Chemical Industries PLC Billingham, Cleveland, UK Leonard Hill Glasgow and London Published by Leonard Hill A member of the Blackie Group Bishopbriggs Glasgow G64 2NZ Furnival House 14-18 High Holborn London WCIV 6BX Copyright © 1986 John Stuart Charlton First published 1986 Softcover reprint of the hardcover Ist edition 1986 All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted, in any form or by any means electronic, mechanical, recording or otherwise, without the prior permission of the copyright holder. British Library Cataloguing in Publication Data Radioisotope techniques for problem-solving in industrial process plants. 1. Process control 2. Radioisotopes I. Charlton, J .S. 670.42'7 TS156.8 ISBN-13: 978-94-010-8306-5 e-ISBN-13: 978-94-009-4073-4 DO I: 10.1 007/978-94-009-4073-4 Photosetting by Thomson Press (India) Limited. Contents 1 Radioisotopes in industry J. S. Charlton 1.1 Introduction I 1.2 Historical perspective 2 1.3 Current uses of radioisotopes in problem-solving 5 1.4 Growth trends and the future 7 References 8 2 The basic physics of radioactivity E. A. Edmonds 9 2.1 Introduction 9 2.2 The structure of the atom 9 2.3 Isotopes 10 2.4 Ionizing radiations 11 2.5 Important concepts in radioactivity 19 2.6 Properties of radiations-interactions with matter 23 Select bibliography 29 3 Radiation detection K. James 30 3.1 Introduction 30 3.2 Methods of detection 30 3.3 The Geiger counter in more detail 35 3.4 The scintillation counter in more detail 41 3.5 Pulse processing equipment 45 4 Radioactive sources T. L. Jones 48 4.1 Production of radioactive sources 48 4.2 Radioisotopes from natural sources 49 4.3 Fission products 51 4.4 Neutron activation 52 4.5 Cyclotrons and accelerators 55 4.6 Radionuclide generators 56 References 57 5 Biological effects of radiation J. S. Charlton 58 5.1 Introduction 58 5.2 Ionizing radiations 58 5.3 Harmful effects of radiation: historical perspective 58 5.4 Radiological protection: historical perspective 59 5.5 Radiation dose 60 5.6 The hazards of ionizing radiations 61 5.7 Dose and risk 63 VI CONTENTS 5.8 ICRP recommendations 64 5.9 Doses in perspective 67 5.1 0 Conclusions 69 References 70 6 Radiological protection G. Reed 71 6.1 Protection against external radiation 72 6.2 Protection against internal radiation 79 6.3 Conclusions S3 7 Radioactive tracer applications T. L. Jones 84 7.1 Half-life 84 7.2 Specific activity 85 7.3 Type of radiation 86 7.4 Energy of radiation 87 7.5 Physical and chemical behaviour 89 7.6 Planning a radioisotope tracer investigation 90 References 96 8 Measurement of flow using radioactive tracers P. Johnson 97 8.1 Introduction 97 8.2 Pulse velocity method 98 8.3 Dilution methods 100 8.4 Application of radiotracer flow methods 104 References III 9 Measurement of residence times and residence-time distributions G. Reed 112 9.1 Introduction 112 9.2 Flow through ideal reactors 113 9.3 Flow through non-ideal reactors 114 9.4 Models for non-ideal flow 116 9.5 Calculation of parameters 119 9.6 Diagnosing malfunctions of process equipment 122 9.7 Equipment arrangement for measurement of RTD using radio tracers 125 9.8 Case histories 126 References 13 7 10 Leakage detection R. Roper 138 10.1 Introduction 138 10.2 Leak detection techniques 138 10.3 Description of radiotracer techniques 141 10.4 Detection equipment 148 10.5 Case histories 149 11 Miscellaneous radiotracer applications G. Reed 167 11.1 Mixing and blending studies 167 11.2 Measurement of volume 176 CONTENTS VB 11.3 Ventilation studies using radioisotopes 179 11.4 Line pigging 181 11.5 Corrosion and wear studies 183 References 187 12 Sealed-source applications J. S. Charlton 188 12.1 Introduction 188 12.2 Types of sealed source 189 12.3 Selection of measurement techniques 200 References 202 13 Gamma-ray absorption techniques J. S. Charlton 204 13.1 Introduction 204 13.2 Equipment for plant applications 205 13.3 Thickness measurement 207 13.4 Density measurement 214 13.5 Measurement of mass per unit area 221 13.6 Case histories 230 References 245 14 Radiation scattering techniques E. A. Edmonds 247 14.1 Introduction 247 14.2 Radiation scattering processes 248 14.3 Industrial applications 250 14.4 Case studies 252 References 268 15 Neutron techniques J. S. Charlton 269 15.1 Introduction 269 15.2 Neutron interactions 269 15.3 Techniques based upon neutron moderation 274 15.4 Neutron absorption techniques 282 15.5 Neutron activation techniques 285 15.6 Radiological protection aspects 288 15.7 Case histories 292 References 303 Appendix: Radiation measurement-statistical considerations K. James 305 A. I Introduction 305 A.2 Counting statistics 305 A.3 Correlation of sets of observations 306 A.4 Precision of a single measurement 307 A.5 Standard deviation of a ratemeter 308 A.6 Error propagation 308 A.7 Effect of background 309 A.8 Statistics of pulse height distributions 310 A.9 Detector efficiency 311 References 311 Index 313 Contributors J. S. Charlton, BSc, PhD Manager, Plant Services and Instruments, Physics and Radioisotopes Research Group E. A. Edmonds, BSc, MSc, PhD Process Applications Manager, Physics and Radioisotope Services Group K. James, BSc, PhD Nucleonic Instruments and Development Manager, Physics and Radio isotope Services Group P. Johnson, BSc, FInstP Former Group Manager, Physics and Radioisotope Services, and Past President, Tracerco Corporation T. L. Jones, BSc, PhD North-west Area Manager, Physics and Radioisotope Services Group G. Reed Radiological Protection Manager, Physics and Radioisotopes Research Group R.Roper Radiation Scientist, Physics and Radioisotope Services Group 1 Radioisotopes in industry J. s. CHARLTON 1.1 Introduction Radioactive materials, as sealed sources of ionizing radiation and as radioactive tracers, are used extensively throughout industry. The field of application is extremely wide: this book is concerned with the application of radioisotope techniques to process investigation on full-scale industrial plant. Our objective is to explore the many ways in which radioisotopes can be used to help industrial plant to operate more efficiently. Because of the sheer volume and diversity of radioisotope applications, a selective approach has been adopted. We have concentrated upon those applications which have proved to be the most useful in terms of economic benefit, realized either as savings or as improved production efficiency. As with any technology it is, of course, possible to achieve the benefits without a detailed understanding of the basic principles,just as one can make good use of an automobile with little or no knowledge of the workings of the internal combustion engine! Some understanding of the basics is nevertheless essential if one is to use the technology to its full effect and, equally importantly, appreciate its limitations. This background information is presented, in condensed form, in Chapters 2-4. Safety is clearly a further important consideration. It is well known that unrestricted exposure to radioactive materials can lead to health detriment. However, it also needs to be appreciated that these hazards are well understood and that through appropriate precautions they can be reduced to a negligible level. Chapters 5 and 6 discuss health physics and radiological protection and describe briefly the practical measures which are taken to protect both workers and public. The remainder of the book is devoted to the process applications of radioisotopes. Each chapter covers one technique or class of techniques. Both theory and experimental approach are described and, in addition, case histories are presented which, as well as illustrating the versatility of the technology, demonstrate the economic benefits which can be realized. In describing case histories and in examining several other aspects of radioisotope applications technology we have drawn upon the experiences of two organizations-the Physics and Radioisotope Services Group (PRS) of Imperial Chemical Industries PLC, and its associate company, Tracerco Corporation of Houston. PRS was established some 30 years ago solely to 2 RADIOISOTOPE TECHNIQUES exploit radioisotope technology, and, together with Tracerco, provides service to a broad spectrum of industry world-wide. It is the world's largest organization specifically devoted to providing contract problem-solving services using radioisotopes, and its activities will exemplify what radioisotope technology can achieve. 1.2 Historical perspective It is now almost ninety years since BecquereP discovered the phenomenon of radioactivity. For fifty years thereafter, the use of radioactivity was virtually confined to medical, research, military and power-generation applications. However, in the late 1940s and 1950s the increasing availability of man-made radioisotopes produced in nuclear reactors resulted in a greatly expanded sphere of application. The oil industry, in particular, was quick to appreciate the potential of radioisotope techniques-the first recorded industrial use of radioisotopes involved oil-well tracer studies 2. Research institutes and industrial companies world-wide began to explore potential uses of radioisotopes and ionizing radiations. To examine the factors 1950s I : General interest in radiation processing. Team established I II : to investigate value of this : Worldwide research stimulated by : I I technology to lei (mid-1950o)1 I I I I : availability of sources of ionizing radiation.: I I I I I I I I I I I Team becomes centre I : I Development of new and improved :of radioisotope expertise in leI.: radioactive sources and methods I I of radiation detection. I I I I I I I I I I I Late 19505 to mid-1960s I I I II R&D applications. II Use of sealed and Radiolabelled I unsealed sources of Evolution of radioisotope techniques both I compounds in I radiation in plant and : for research and engineering applications. laboratory studies. : process investigation. I I Figure 1.1. The origin of a radioisotope applications service. RADIOISOTOPES IN INDUSTRY 3 which shaped the development of the technology, it is instructive to refer to our example of ICI's Physics and Radioisotope Services Group. Within ICI, interest was initially centred upon the possibility of using sources of ionizing radiation to induce chemical reactions (Figure 1.1). The findings here were not as encouraging as had been hoped. Though radiation processing possessed unique advantages in a limited number of situations, in the majority of cases large-scale radiation sources could not compete with conventional process technologies. However, while radioisotopes as a processing tool appeared to have limited use, it was already clear that there was considerable scope for them in process investigation, and that it was this sphere of activity which possessed the greatest potential for economic benefit. The ICI Group was fortunate in being located at Billingham in the north east of England, at the centre of one of the largest chemical complexes in Europe, and benefited greatly from close association with production personnel-a classic case of 'solutions in search of problems' and 'problems in search of solutions' being brought together in close proximity. Considerable savings resulted through using radioisotope techniques to investigate operational characteristics and to diagnose faults on full-scale process plant. An important feature was the unique ability conferred by the properties of ionizing radiation to investigate problems without disrupting the process in any way. In particular, shutdown time could be avoided or reduced to a minimum. Process applications activity was therefore considerably stimulated by the construction, accelerating throughout the 19 60s and 1970s, of very large single-stream production units (Figure 1.2). The financial con sequences of shutdown of a unit of size comparable (say) with that of the 500000 te p.a. No.5 Olefines Plant at Wilton, Cleveland, were so large that a considerable investment of time and resources was made in on-line sur veillance and fault-finding techniques, among which radioisotope methods were found to be by far the most versatile. By 1970, the use of radioactive tracers had become routine to the extent that PRS Group could economically justify the purchase of its own radioisotope production facility, a TRIGA Mark I nuclear reactor. This was installed at the Group's headquarters in 1971 and continues to function as a safe and reliable source of radioisotopes. As is often the case, meeting the existing need (by the purchase of the nuclear reactor) stimulated an even greater demand: tracer applications which had hitherto been impossible because they depended upon the availability of a particular radiotracer (for example, material of very short half-life) became feasible, and further expansion of process applications resulted. Continued development of this technology throughout the 1970s was directed more by economic than technical influences. Concerns about the continued availability and conservation of fossil fuel resources (especially oil and gas) led to the extensive use of radioisotope techniques to provide the basic information for energy-conservation studies. Additionally, and very B

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