INSTITUTE OF PETROLEUM PETROLEUM MEASUREMENT MANUAL PART XIII Fidelity and Security of Measurement Data Section 3 Electrical and/or Electronic Data Capture Systems for Flow Metering
INSTITUTE OF PETROLEUM PETROLEUM MEASUREMENT MANUAL PART XIII Fidelity and Security of Measurement Data SECTION 3 ELECTRICAL AND/OR ELECTRONIC DATA CAPTURE SYSTEMS FOR FLOW METERING SEPTEMBER 1985 Published on behalf of THE INSTITUTE OF PETROLEUM, LONDON by JOHN WILEY & SONS Chichester New York Brisbane Toronto Singapore
Copyright 1986 by The Institute of Petroleum, London All rights reserved. No part of this book may be produced by any means, or transmitted, or translated into a machine language without the written permission of the publisher. Library of Congress Cataloging in Publication Data : Main entry under title : Fidelity and security of measurement data. (Petroleum measurement manual ; Pt. 13) "September 1985." Includes Index. Contents : -section 3. Electrical and/or electronic data capture systems for flow metering. 1. Petroleum products-measurement. 2. Flow meters- Reliability. I. Institute of Petroleum (Great Britain) II. Series TP691.P446 1983 pt. 13 665.5'0212 s 85-26525 1665.5'02121 ISBN 0 471 90962 9 (pbk. : v.3) British Library Cataloguing in Publication Data : Petroleum measurement manual. Pt. 13 : Fidelity and security of measurement data. Section 3 : Electrical and/or electronic data capture systems for flow metering 1. Petroleum products-measurement-standards I. Institute of Petroleum 665.5'38'0287 TP691 ISBN 0 471 90962 9 Printed and bound in Great Britain
CONTENTS Foreword ix Acknowledgements _ x Introduction xi 1 Glossary of Terms 1 1.1 Introduction 1 1.2 Definitions 1 2 Examples of Measuring Systems Subject to Integrity Control 3 3 System Design Principles and Quality Requirements 4 3.1 Introduction 4 3.2 System approval 4 3.3 The measuring system 5 3.4 Mains power supply failure _ 6 3.5 Equipment connected to computers or other peripheral devices 6 3.6 Equipment immunity to electrical disturbances 7 3.7 Environmental factors 7 3.8 Materials of construction 8 3.9 Performance tests 8 3.10 Mechanical tests 9 4 Possible Sources of Error in Measurement Systems 11 4.1 Introduction 11 4.2 Common types of transducer signal 11 4.3 Common failure and corruption mechanisms for digital signals and recommended practices for protection 11 4.4 Common failure and corruption mechanisms for analogue signals and recommended practices for protection 12 4.5 Data sources and the need to maintain integrity 13 4.6 Integrity of the flow computer 13 4.7 Specific problems associated with flow measurement 14 4.8 Specific problems associated with temperature measurement 15 4.9 Specific problems associated with density measurement 16
4.10 Specific problems associated with pressure measurement-static and differential 4.11 Prover integrity 4.12 Pulse interpolation 5 System Monitoring Classification 5.1 Introduction 5.2 Level definitions 5.3 Proving 6 Measurement Indicators 6.1 Primary indicators 6.2 Multiple indicators 6.3 Corruption 6.4 Technical requirements 6.5 Display tests 7 Power Supply Unit 7.1 Introduction 7.2 Power supply units 7.3 Battery power supplies 7.4 Provision of standby power supplies (battery back-up) 8 Transmission Distances 8.1 Introduction 8.2 Transmission distances for serial data communication 8.3 Current loop serial data communication 8.4 Modems 8.5 Other transmission techniques 9 Prevention of Unauthorized Access 9.1 Introduction 9.2 Keys and codes 9.3 Security sealing 10 Installation 10.1 Introduction 10.2 General requirements 10.3 Cabling considerations 11 Commissioning and Acceptance Testing Procedures 11.1 Introduction 11.2 Personnel 11.3 Safety 11.4 Commissioning 11.5 Test equipment 11.6 Acceptance testing 11.7 Signal transmission _ 11.8 Signal processing 11.9 Digital data communication 12 Periodic Testing, Inspection and Maintenance 12.1 Introduction vi
12.2 Personnel 35 12.3 Safety 35 12.4 Testing and inspection 35 12.5 Maintenance 36 12.6 Records 36 Appendix A Figures 1 to 14 37 B References 50 C Abbreviations 52 vii
FOREWORD Measurement accuracy is essential in the sale, purchase and handling of petroleum products. It avoids disputes between buyer and seller and provides the reliable means of control over losses. Accurate measurement involves the use of standardized equipment and procedures. The Petroleum Measurement Committee of the Institute of Petroleum is responsible for the production and maintenance of standards covering the various aspects of static and dynamic measurement of petroleum. These standards are issued as separate Parts and Sections of Parts of the Institute's Petroleum Measurement Manual, which was first published in 1952. Membership of the IP working panels is made up of experts from the oil industry, equipment manufacturers and government authorities. Liaison is maintained where appropriate with parallel working groups of the Committee on Petroleum Measurement of the American Petroleum Institute, and is extended as necessary to embrace other organizations concerned with quantitative measurement in other countries and in other industries. Users are invited to send comments, suggestions, or details of experience with this issue to : The Secretary, Petroleum Measurement Committee, Institute of Petroleum, 61 New Cavendish Street, London W 1 M 8AR, United Kingdom. The Petroleum Measurement Manual is widely used by the petroleum industry and has received recognition in many countries by consumers and the authorities. In order to promote their wide adoption internationally, it is the policy to submit selected standards through the British Standards Institution to Technical Committee 28-Petroleum Products and Lubricants-of the International Organization for Standardization (ISO) as potential International Standards. A full List of Parts and Section of the Petroleum Measurement Manual (PMM) is available on request from the Institute of Petroleum. Note The IP Petroleum Measurement Standards are recommended for general adoption but they must be read and interpreted in conjunction with weights and measures, safety and other regulations in force in a particular country in which it is intended to apply them. Such regulatory requirements shall have precedence over corresponding clauses in the standards. The Institute disclaims responsibility for any personal injury, or loss or damage to property howsoever caused, arising from the use or abuse of any Part or Section of the Manual. ix
ACKNOWLEDGEMENTS The following members of the IP Petroleum Measurement Committee and its Sub-Committees have been associated with the production of this Section of the Petroleum Measurement Manual. G. Anderson L. Blackmore H. C. Boulter R. L. Day P. A. M. Jelffs J. E. Miller P. D. O'Connell L. N. Philp R. Shepherd P. R. Silverwood S. G. Simmons J. W. Stansfeld G. R. Watson P. B. Watson F. E. J. Wilson - Sarasota Automation ICE Petrochemical Engineering Ltd. Shell UK Exploration and Production ICE Petrochemical Engineering Ltd. Redwood International Ltd. Consultant Institute of Petroleum Department of Energy Spectra-Tek UK Ltd. AOT Systems BP International Ltd. Solartron Electronic Group Ltd. Shell UK Exploration and Production Whessoe Systems and Controls Ltd. Petrol Pump Manufacturers' Association x
INTRODUCTION During the last decade there has been a rapid increase in the use of electrical or electronic data capture systems designed to facilitate the determination of physical quantities such as length, mass, volume, etc. The application of these technologies and other advanced technologies such as laser and fibre optic transmission of data, has enhanced the control that can be applied to complex measuring systems. Single and multi-component streams can with confidence be managed to indicate volume at standard conditions continuously or intermittently at frequent intervals, in step with integration into the system of variable data such as density, pressure, temperature and the results of in-line proving. Such systems can be vulnerable to disturbance arising from the environment in which they are used, for example from functional failures and ratio variations in multi-component streams. The purpose of this Code of Practice is to assist manufacturers and users of complex flow measuring systems designed to convert measured volume to volume at standard conditions or to mass units, to meet certain criteria for the design, installation, operation and maintenance of such systems. The object is to establish and maintain the integrity of the system and the indicated data against influences acting to impair the fidelity of the measured result. The Code recommends solutions which constitute good practice in this field at this time, but it is not claimed that the recommendations are wholly comprehensive. The recommendations are, however, considered to be Practicable and to satisfy the immediate needs of industries associated with the metering and proving of hydrocarbon fluids in the Bulk Commercial and Royalty Metering, Customs and Excise Revenue Account, and Custody Transfer in general. It is not intended that the recommendations should inhibit technological progress in the industry and therefore, amendments may be introduced as and when required. Where other codes or standards are referred to in the text it should be assumed, unless otherwise stated, that the latest editions are referred to. For convenience the latest editions (at the time of publication of this Code) are listed in Appendix B. The following forms of measurement are covered in this Code. (a) Line Volume-The volume recorded for a fluid flow that has passed through a metering system without correction other than for the meter factor. (b) Standard Volume-The line volume corrected to standard temperature and pressure. (c) Mass-The mass recorded for a fluid flow that has passed through a metering system. This is derived from measurements of line volume and density. xi