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Guidelines for Hazard Evaluation Procedures
Guidelines for Hazard Evaluation Procedures
Guidelines for Hazard Evaluation Procedures
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Guidelines for Hazard Evaluation Procedures

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Guidelines for Hazard Evaluation Procedures, 3rd Edition keeps process engineers updated on the effective methodologies that process safety demands. Almost 200 pages of worked examples are included to facilitate understanding. References for further reading, along with charts and diagrams that reflect the latest views and information, make this a completely accessible work. The revised and updated edition includes information not included in previous editions giving a comprehensive overview of this topic area.
LanguageEnglish
PublisherWiley
Release dateSep 23, 2011
ISBN9781118211663
Guidelines for Hazard Evaluation Procedures

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Guidelines for Hazard Evaluation Procedures - CCPS (Center for Chemical Process Safety)

Part I

Hazard Evaluation Procedures

Preface

Management Overview

1 Introduction to the Guidelines

2 Preparation for Hazard Evaluations

3 Hazard Identification Methods

4 Non-Scenario-Based Hazard Evaluation Procedures

5 Scenario-Based Hazard Evaluation Procedures

6 Selection of Hazard Evaluation Techniques

7 Risk-Based Determination of the Adequacy of Safeguards

8 Analysis Follow-Up Considerations

9 Extensions and Special Applications

Appendices (following Part II)

Appendix A – Additional Checklists and Forms

Appendix B – Supplemental Questions for Hazard Identification

Appendix C – Symbols and Abbreviations for Example Problem Drawings

Appendix D – Software Aids

Appendix E – Chemical Compatibility Chart

Appendix F – Organizations Offering Process Safety Enhancement Resources

Preface

The American Institute of Chemical Engineers (AIChE) has been closely involved with process safety and loss control issues in the chemical and allied industries for more than four decades. Through its strong ties with process designers, constructors, operators, safety professionals, and members of academia, AIChE has enhanced communication and fostered continuous improvement of the industry’s high safety standards. AIChE publications and symposia have become information resources for those devoted to understanding the causes of incidents and discovering better means of preventing their occurrence and mitigating their consequences.

The Center for Chemical Process Safety (CCPS) was established in 1985 by AIChE to develop and disseminate technical information for use in the prevention of major chemical incidents. CCPS is supported by nearly 100 sponsoring companies in the chemical process industry (CPI) and allied industries; these companies provide the necessary funding and professional experience for its technical subcommittees.

CCPS’ first project was the preparation of Guidelines for Hazard Evaluation Procedures. The goal of that groundbreaking project was:

...to produce a useful and comprehensive text prepared to foster continued personal, professional, and technical development of engineers in the areas of chemical plant safety, and to upgrade safety performance of the industry... The document will be updated periodically, and will serve as a basis for additional related topics such as risk management

CCPS achieved its stated goal with the publication of the Guidelines in 1985, and has since continued to foster the development of process safety professionals in all industries. For example, CCPS has developed 85 Guideline and Concept Books and has sponsored 23 international meetings since its inception. Planning and work on many other projects are also underway. This activity has occurred in the midst of many other changes and events that over the past years have fostered an unprecedented interest in hazard evaluation:

■ A number of incidents have occurred, even though many companies are seeking continuous improvement of process safety and have embraced the ideal of striving for zero incidents. Industry is learning from these incidents, and this hard-earned experience is an important additional source of information for process safety professionals in their quest to prevent major chemical incidents in the future.

■ Both private and public organizations, including government agencies, have become more concerned with ensuring the safety of industrial operations. This is exemplified by the formation and activities of the U.S. Chemical Safety and Hazard Investigation Board (Chemical Safety Board, or CSB), which has made several recommendations related to hazard evaluations.

■ Many organizations—including companies, industrial groups, and others concerned with the safe handling of hazardous materials—have made clear and definite commitments to the management of process safety. In 1989, CCPS published Guidelines for the Technical Management of Chemical Process Safety; followed in 2007 by Guidelines for Risk Based Process Safety. These publications outline strategies for companies to consider when designing management systems for use in preventing major chemical incidents. Other organizations have followed suit by proposing their own approaches for process safety management (PSM). In all of these PSM models, the use of hazard evaluation techniques plays a central role in helping to manage the risk of facilities and operations.

■ Many laws and regulations now place demands on organizations that handle hazardous materials. These include U.S. federal and state legislative initiatives, as well as international requirements such as the European Union’s Seveso II Directive. In 1992, the U.S. Occupational Safety and Health Administration (OSHA) promulgated a standard for Process Safety Management of Highly Hazardous Chemicals (29 CFR 1910.119). The U.S. Congress also amended the Clean Air Act by adding chemical incident prevention provisions that included broad-based process safety requirements for companies that use hazardous chemicals (U.S. Environmental Protection Agency’s Risk Management Program Rule, 40 CFR Part 68). These laws and regulations require facility owners and operators to employ hazard evaluation methods such as those recognized by CCPS. These requirements have sparked an increasing demand for practitioners who are qualified to use these methods.

■ International standards related to instrumented protective systems, notably IEC 61511 and its U.S. implementation (ANSI/ISA-84.00.01, IEC 61511 Mod), reference the use of scenario-based hazard evaluation procedures as part of the process of specifying required safety integrity levels for safety instrumented systems.

Because of the experience gained in the use of hazard evaluation techniques since 1985, and the increased impetus for companies to become involved in performing these studies, CCPS decided to revise the original Guidelines for Hazard Evaluation Procedures. Thus, as promised in CCPS’ original project mission statement, a significantly updated and expanded version was produced in 1992—Guidelines for Hazard Evaluation Procedures, Second Edition with Worked Examples. Recognition of further changes in the field of hazard evaluation and refinement in various methodologies led CCPS’ Technical Steering Committee to conclude a Third Edition was warranted and a project was initiated. This project has now been completed and the Guidelines for Hazard Evaluation Procedures, Third Edition is the result. Besides considerable updating of terminology, especially as it relates to the elements of an incident scenario, the major changes from the Second Edition include the following.

■ A new section on inherent safety reviews has been added, and the hazard evaluation method descriptions have been expanded to indicate how inherent safety concepts can be considered.

■ The hazard evaluation methodologies have been reorganized into scenario-based and non-scenario-based methods, with the recognition that scenario-based methods can be used in conjunction with aids such as risk matrices to determine the adequacy of safeguards and the priority to be placed on follow-up actions.

■ Qualitative and order-of-magnitude quantitative scenario risk estimation approaches are presented in a new chapter. These approaches are now in common use for determining the adequacy of safeguards.

■ A new section summarizing Layer of Protection Analysis (LOPA) has been added, and descriptions are given of how LOPA has been combined with hazard evaluation techniques.

■ Use of the cause-by-cause approach to documenting HAZOP Studies has been emphasized, to lessen the likelihood of overestimating scenario risks or crediting safeguards that do not apply to particular initiating cause / loss event combinations.

■ Other new sections have been added on evaluating procedure-based operations, evaluating the hazards of programmable systems, and addressing issues related to facility siting. New text on addressing human factors has been added to consideration of the Human Reliability Analysis technique.

■ An even greater emphasis has been placed on process life cycle considerations as they relate to hazard evaluations, including hazard reviews for management of change, and a new section discusses integrating hazard evaluations with other considerations such as reliability and security.

■ Additional checklists and forms have been included in the book chapters and in Appendix A.

Part I — Hazard Evaluation Procedures of these Guidelines describes methods used to identify and assess the significance of hazardous situations found in process operations or activities involving hazardous materials. However, these approaches are not limited in their application to the chemical manufacturing industry; they are also appropriate for use in any industry where activities create situations that have the potential to harm workers or the public; damage equipment or facilities; or threaten the environment through hazardous material releases, fires, or explosions.

Part I contains an overview for management and nine chapters. Appendices are located at the end of the book. The following list describes the organization of Part I.

Management Overview

■ Summarizes the use of hazard evaluation techniques as an integral part of a process safety management program

■ Describes how these techniques can be used throughout the life of a process to support many PSM activities

■ Lets managers know what they can realistically expect from a hazard evaluation and discusses important limitations found in the most commonly used techniques

Chapter 1 — Introduction to the Guidelines

■ Describes how hazard evaluation techniques fit into an overall PSM program

■ Relates the use of hazard evaluation techniques to risk management strategies

■ Introduces terminology used for evaluating process hazards in the context of a typical incident sequence of events

■ Introduces the role of safeguards in preventing and protecting against process upsets and mitigating the impacts of loss events

■ Shows how hazard evaluation techniques can be used throughout the lifetime of a process or operation

■ Outlines important theoretical and practical limitations of hazard evaluation techniques and summarizes what practitioners and management can reasonably expect from the use of these approaches

Chapter 2 — Preparation for Hazard Evaluations

■ Describes the infrastructure needed to support a hazard evaluation program

■ Gives examples of appropriate statements of scope for hazard evaluations

■ Outlines the skills and information needed to perform these studies

■ Addresses schedule and logistical considerations associated with the efficient execution of hazard evaluations

Chapter 3 — Hazard Identification Methods

■ Discusses the importance of identifying hazards and the contemporary approaches used in hazard identification

■ Illustrates the use of experience in analyzing material properties and process conditions for hazards

■ Presents several structured approaches for hazard identification, with examples

■ Describes the types of results that can be expected from hazard identification techniques, which can be used in subsequent hazard evaluation efforts

Chapter 4 — Non-Scenario-Based Hazard Evaluation Procedures

■ Explains the difference between scenario-based and non-scenario based hazard evaluations

■ Provides the following information for each of four non-scenario-based hazard evaluation techniques: purpose, description, types of results, resource requirements and analysis procedure

■ Illustrates each method with a brief example

Chapter 5 — Scenario-Based Hazard Evaluation Procedures

■ Provides the following information for each of eight hazard evaluation methods that are capable of being used to generate incident scenarios and evaluate scenario-based risks: purpose, description, types of results, resource requirements and analysis procedure

■ Illustrates each method with a brief example

Chapter 6 — Selection of Hazard Evaluation Techniques

■ Discusses factors that can influence selection of an appropriate hazard evaluation technique

■ Lists selection criteria and provides a flowchart of questions to help choose an appropriate method for a particular application

Chapter 7 — Risk-Based Determination of the Adequacy of Safeguards

■ Gives guidelines for when it is appropriate to perform a more detailed evaluation of scenario risks

■ Introduces the basic concepts of estimating loss event impacts, initiating cause frequency, and safeguard effectiveness

■ Gives examples of how these scenario risk estimates can be compared to risk criteria for determining the adequacy of safeguards

■ Introduces Layer of Protection Analysis (LOPA) as a technique to evaluate scenarios on an order-of-magnitude basis

Chapter 8 — Analysis Follow-Up Considerations

■ Discusses the importance of prioritizing the results and properly documenting a hazard evaluation

■ Gives general guidelines for communicating these results to managers so they can make appropriate risk management decisions

■ Presents strategies for tracking the changes made as a result of a hazard evaluation

Chapter 9 — Extensions and Special Applications

■ Gives further information on special related topics including human factors; facility siting; and evaluating hazards of procedure-based operations, programmable control systems, and reactive chemical systems

■ Discusses the combining of tools such as HAZOP with LOPA

Appendices. Located at the end of Part II— Worked Examples, the Appendices provide:

■ Example checklists and forms to help analysts perform various hazard evaluations

■ A legend of symbols and abbreviations used in drawings in Part II

■ A list of commercially available software aids for performing hazard evaluations

■ A chemical compatibility chart to aid in identifying hazards

■ A listing of organizations offering process safety enhancement resources.

The Guidelines for Hazard Evaluation Procedures contain information useful to both the inexperienced analyst and the accomplished practitioner. Chapters 1 through 3 are important for both the beginner and experienced hazard analyst. The experienced analyst may wish to scan the ideas on selecting an appropriate hazard evaluation method (Chapter 6); after that, to proceed directly to the appropriate sections in Chapters 4 and 5, which give the detailed steps for performing the chosen technique, and/or to Chapter 9, which gives information on special applications. Chapters 7 and 8 advise all analysts—regardless of their hazard evaluation experience—of ways to prioritize, document, and communicate the results of the hazard evaluations. The Overview figure on the next page shows how these chapters are interrelated.

Part II — Worked Examples for Hazard Evaluation Procedures, the companion to the Guidelines, provides the novice hazard analyst with realistic examples in which various hazard evaluation techniques are used throughout the life of a process. Experienced hazard analysts that are selected to provide in-house training will find Part II extremely helpful as they develop training programs. Moreover, even the experienced practitioner should find the Worked Examples helpful when designing and executing corporate PSM programs.

As was true for the original Guidelines for Hazard Evaluation Procedures and the Second Edition with Worked Examples, these Guidelines do not contain a complete program for managing the risk of chemical operations, nor do they give specific advice on how to establish a hazard analysis program for a facility or an organization. However, they do provide some of the insights that should be considered when making risk management decisions and designing risk management programs. Furthermore, they describe what users can reasonably expect from their performance of high quality hazard evaluations.

These Guidelines cannot replace hazard evaluation experience. This book should be used as an aid for the initial training of hazard analysts and as reference material for experienced practitioners. Only through frequent use will beginners become skilled in hazard evaluation techniques and be able to perform efficient hazard evaluations. Using these Guidelines within the framework of a complete PSM program will help organizations continually improve the safety of their facilities and operations.

p1_image001.gif

Management Overview

A hazard evaluation is an organized effort to identify and analyze the significance of hazardous situations associated with a process or activity. Specifically, hazard evaluations are used to pinpoint weaknesses in the design and operation of facilities that could lead to chemical releases, fires, or explosions. These studies provide organizations with information to aid in making decisions for improving safety and managing the risk of operations. Hazard evaluations usually focus on process safety issues, like the acute effects of unplanned chemical releases on plant personnel or the public. These studies complement more traditional industrial health and safety activities in which protection against slips or falls, use of personal protective equipment, and monitoring for employee exposures to industrial chemicals are considered. Although primarily directed at providing safety-related information, many hazard evaluation techniques can also be used to investigate operability, economic, and environmental concerns.

Hazard evaluation is the cornerstone of an organization’s overall process safety management (PSM) program. Although hazard evaluations typically involve the use of qualitative techniques to analyze potential equipment failures and human errors that can lead to incidents, the studies can also highlight gaps in the management systems of a process safety program. In addition, individual hazard evaluation techniques can be used as a part of many other PSM program elements. For example, hazard evaluation techniques can be used (1) to investigate the possible causes of an incident that has occurred; (2) as part of a facility’s management of change program; and (3) to identify critical safety equipment for special maintenance, testing, or inspection as part of a facility’s mechanical integrity program.

Hazard evaluations should be performed throughout the life of a process as an integral part of an organization’s PSM program. These studies can be performed to help manage the risk of a process from the earliest stages of research and development (R&D); in detailed design and construction; periodically throughout the operating lifetime; and continuing until the process is decommissioned and dismantled. By using this life cycle approach in concert with other PSM activities, hazard evaluations can efficiently reveal deficiencies in design and operation before a unit is sited, built, or operated, thus making the most effective use of resources devoted to ensuring the safe and productive life of a facility.

Part I —Hazard Evaluation Procedures contains a brief overview of the purpose, benefits, costs, and limitations of various hazard evaluation techniques for those with a need for basic information. It also contains how to details on preparing for hazard evaluations, techniques for identifying hazards, strategies for selecting appropriate hazard evaluation techniques, procedures for using hazard evaluation methods, and advice on documenting and using the results of a study. Part I contains specific steps for performing a hazard evaluation using the following techniques:

These techniques represent the approaches for hazard evaluation most often used in the chemical process industry (CPI). For completeness, other less commonly used techniques are also briefly reviewed. The advice contained in the Guidelines for Hazard Evaluation Procedures is based on the experience of process safety professionals with many years of practice in applying hazard evaluation techniques in the CPI and allied industries.

Part II — Worked Examples is included for those who wish to become more experienced in the use of hazard evaluation technology and for those responsible for training analysts to use these methods. With the guidance provided in Parts I and II, analysts should be able to understand the basics of hazard evaluation and begin performing hazard evaluations of simple processes using the less complicated hazard evaluation techniques. With practice using the techniques described in the Hazard Evaluation Procedures and the Worked Examples, and with experience gained from participating in actual studies, a hazard analyst should be able to scope, organize, lead, and document hazard evaluations of most types of processes and operations with a minimum of outside assistance.

The benefits of a hazard evaluation program can be substantial, although none of these effects can easily be measured over a short period of time. These benefits can include:

■ Fewer incidents over the life of a process

■ Reduced consequences of incidents that do occur

■ Improved emergency response

■ Improved training and understanding of the process

■ More efficient and productive operations

■ Improved regulatory and community relations

However, these benefits cannot be realized without a significant investment. Depending upon the size and complexity of a process or operation, a hazard evaluation can require from several hours to many months to complete. Moreover, the documentation, training, and staff resources required to support a hazard evaluation program over the life of a facility can be extensive. Because of the large resource commitments necessary to maintain a vigorous hazard evaluation program, it is important that an organization have strategies in place to use properly trained and skilled people for performing this type of work. It is also extremely important that the appropriate hazard evaluation techniques are selected for each process or operation to ensure that effort is not wasted by over-studying a problem with a more detailed approach than is necessary.

Users and reviewers of hazard evaluations need to be aware that even in an efficient and high quality hazard evaluation program there are a number of limitations:

1. Analysts can never be certain they have identified all hazards, potential incident situations, causes, and effects.

2. Most of the time, the results and benefits of performing hazard evaluations cannot be directly verified. The savings from incidents that are prevented cannot be readily estimated.

3. Hazard evaluations are based on existing knowledge of a process or operation. If the process chemistry is not well known, if the relevant drawings or procedures are not accurate, or if the process knowledge available from a study team does not reflect the way the system is actually operated, then the results of a hazard evaluation may be invalid. This could lead managers to make poor risk management decisions.

4. Hazard evaluations are very dependent on the subjective judgment, assumptions, and experience of the analysts. The same process, when analyzed by different teams of competent analysts, may yield somewhat different results.

Performing high quality hazard evaluations throughout the lifetime of a process cannot guarantee that incidents will not occur. However, when used as part of an effective process safety management program, hazard evaluation techniques can provide valuable input to managers who are deciding whether or how to reduce the risk of chemical operations. With programs such as these in place, organizations will be well positioned to strive for continual improvement in process safety.

Understanding hazards and risks is one of the four pillars upon which risk-based process safety is established. Another of the pillars is committing to process safety. To commit to process safety, facilities need to focus on:

■ Developing and sustaining a culture that embraces process safety

■ Identifying, understanding, and complying with codes, standards, regulations, and laws

■ Establishing and continually enhancing organizational competence

■ Soliciting input from and consulting with all stakeholders, including employees, contractors, and neighbors.

Each of the above areas of focus is essential to conducting effective hazard evaluations. In addition, since the management systems for each of these elements should be based on an organization’s current understanding of the risk associated with the process with which the workers will interact, it can be seen that understanding hazards and risks is an important part of a commitment to process safety.

1

Introduction to the Guidelines

A hazard is a physical or chemical condition that has the potential for causing harm to people, property, or the environment. A hazard evaluation is an organized effort to identify and analyze the significance of hazardous situations associated with a process or activity. Specifically, hazard evaluations are used to pinpoint weaknesses in the design and operation of facilities that could lead to hazardous material releases, fires, or explosions. These studies provide organizations with information to help them improve the safety and manage the risk of their operations.

Hazard evaluations usually focus on process safety issues, like the acute effects of unplanned chemical releases on plant personnel or the public. These studies complement more traditional industrial health and safety activities, such as protection against slips or falls, use of personal protective equipment, monitoring for employee exposure to industrial chemicals, and so forth. Many hazard evaluation techniques can also be used to help satisfy related needs (e.g., operability, economic, and environmental concerns). Although hazard evaluations typically analyze potential equipment failures and human errors that can lead to incidents, the studies can also highlight gaps in the management systems of an organization’s process safety program. For example, a hazard evaluation of an existing process may reveal gaps in the facility’s management of change program or deficiencies in its maintenance practices.

From its inception, the Center for Chemical Process Safety (CCPS) has recognized the importance of hazard evaluations; in fact, the first book in CCPS’ series of guidelines dealt with hazard evaluation procedures.¹ Because of the ongoing and increased emphasis on performing hazard evaluations, CCPS commissioned the development of the Guidelines for Hazard Evaluation Procedures, Third Edition. The purpose oí Part I — Hazard Evaluation Procedures is to provide users with a basic understanding of the concepts of hazard evaluation, as well as information about specific techniques so they will be able to perform high quality hazard evaluations within a reasonable amount of time. Several chapters on new topics, including preparing for studies, identifying hazards, and following up after completed analyses are included in the Guidelines.

In addition, because of the ongoing need to train a large number of competent hazard evaluation practitioners, this document includes the companion, Part II — Worked Examples. The Worked Examples give detailed illustrations of how the various hazard evaluation techniques can be used throughout the lifetime of a process as a part of a company’s process safety management (PSM) program. People responsible for hazard evaluation training in their organizations will find both the Hazard Evaluation Procedures and the Worked Examples to be valuable resources.

The remainder of the Introduction explains some basic terminology and concepts of hazard evaluation and its relationship to risk management. It outlines various incident prevention and risk management strategies and discusses how hazard evaluation can provide important information to organizations who are striving for incident-free operation. This section also discusses how hazard evaluations can be performed throughout the life of a process as part of a PSM program. Finally, some limitations that should influence the interpretation and use of hazard evaluation results are presented.

1.1 Background

Formal hazard evaluations have been performed in the chemical process industry (CPI) for more than thirty years. Other less systematic reviews have been performed for even longer. Over the years, hazard evaluations have been called by different names. At one time or another, all of the terms listed in Table 1.1 have been used as synonyms for hazard evaluation, with some of the terms having different shades of meaning depending on the context and usage.

An important prerequisite or starting point for performing a hazard evaluation is the identification of process hazards, since hazards that are not identified cannot be further studied. Chapter 3 describes frequently used hazard identification methods and discusses their use in hazard evaluation efforts. An efficient and systematic hazard evaluation, preceded by a thorough hazard identification effort, can increase managers’ confidence in their ability to manage risk at their facilities.

Hazard evaluations usually focus on the potential causes and consequences of episodic events, such as fires, explosions, and unplanned releases of hazardous materials, instead of the potential effects of conditions that may routinely exist such as a pollutant emitted from a registered emission point. Also, hazard evaluations usually do not consider situations involving occupational health and safety issues, although any new issues identified during the course of a hazard evaluation are not ignored and are generally forwarded to the appropriate responsible person. Historically, these issues have been handled by good engineering design and operating practices. In contrast, hazard evaluations also focus on ways that equipment failures, software problems, human errors, and external factors (e.g., weather) can lead to fires, explosions, and releases of toxic material or energy.

Hazard evaluations can occasionally be performed by a single person, depending upon the specific need for the analysis, the technique selected, the perceived hazard of the situation being analyzed, and the resources available. However, most high-quality hazard evaluations require the combined efforts of a multidisciplinary team. The hazard evaluation team uses the combined experience and judgment of its members along with available data to determine whether the identified problems are serious enough to warrant change. If so, they may recommend a particular solution or suggest that further studies be performed. Sometimes a hazard evaluation cannot give decision makers all the information they need, so more detailed methods may need to be used such as Layer of Protection Analysis (LOPA) or Chemical Process Quantitative Risk Analysis (CPQRA).

The purpose of these Guidelines is to provide practitioners and potential users of the results of hazard evaluations with information about identifying hazards, selecting a hazard evaluation technique appropriate for a particular need, using a particular method, and following up on the results. This document is designed to be useful to the veteran hazard analyst as well as the novice. It also provides some guidance to those faced with using, reviewing, or critiquing the results of hazard evaluations so they will know what to reasonably expect from them. Special emphasis is placed on the theoretical and practical limitations of the various hazard evaluation techniques presented.

Table 1.1 Hazard evaluation synonyms

1.2 Relationship of Hazard Evaluation to Risk Management Strategies

Over the past few years, remarkable progress has been made toward institutionalizing formal process safety management (PSM) programs within chemical process industry companies. This crescendo of activity was sparked by a variety of factors including (1) the occurrence of major industrial incidents, (2) aggressive legislative and regulatory process safety initiatives reflecting a reduced public risk tolerance, and (3) the evolution and publication of model PSM programs by several industrial organizations.²-⁹ Perhaps even more significant was the increased awareness and the enlightened self-interest of companies that realized, in the long run, operating a safer plant leads to more profitable business performance and better relationships with communities and regulatory agencies.

In 1989, CCPS published its Guidelines for Technical Management of Chemical Process Safety, which outlined a twelve-element strategy for organizations to consider when adopting management systems to ensure process safety in their facilities.¹⁰ This strategy has been more recently updated and expanded to reflect an emphasis on risk-based process safety, as reflected in the twenty elements listed in Table 1.2.¹⁶ Two of the elements in this table address the identification of hazards, assessment of risk, and selection of risk control alternatives throughout the operating lifetime of a facility. Other elements such as management of change, incident investigation, and asset integrity and reliability can also involve the use of hazard evaluation techniques.

Implementing a PSM program can help an organization manage the risk of a facility throughout its lifetime. Managers must, at various times, be able to develop and improve their understanding of the things that contribute to the risk of the facility’s operation.¹¹-¹³ Developing this understanding of risk requires addressing three specific questions (also shown in Figure 1.1):

square What can go wrong?

square What is the potential impact (i.e., how severe are the potential loss event consequences)?

square How likely is the loss event to occur?

Table 1.2 CCPS elements of risk-based process safety

Figure 1.1 Aspects of understanding risk

c01_image001.jpg

The effort needed to develop this understanding of risk will depend upon (1) how much information the organization possesses concerning potential incidents and (2) the specific circumstance that defines the organization’s need for better risk information. In any case, managers should first use their experience and knowledge to understand the risk their organizations face in operating a facility. If the organization has a great deal of pertinent, closely related experience with the subject process or operation, then little formal analysis may be needed. In these situations, experienced-based hazard evaluation tools (e.g., checklists) are commonly used to manage risk.

On the other hand, if there is not a relevant or adequate experience base, an organization may have to rely on analytical techniques for developing answers to the three risk questions to satisfactorily meet the organization’s risk management needs. In these situations, organizations typically use predictive hazard evaluation techniques to creatively evaluate the significance of potential incidents.

Using hazard evaluation techniques is one way to increase a company’s understanding of the risk associated with a planned or existing process or activity so that appropriate risk management decisions can be made.

1.3 Anatomy of a Process Incident

One definition of process safety is the sustained absence of process incidents at a facility. To prevent these process incidents, one must understand how they can occur. Using hazard evaluation methods can help organizations better understand the risks associated with a process and how to reduce the frequency and severity of potential incidents. Section 1.2 showed how hazard evaluation procedures fit into an overall strategy for risk management. The purpose of Sections 1.3 and 1.4 is to discuss some of the salient features of process incidents by presenting the anatomy of typical process incidents.¹⁴

A process hazard represents a threat to people, property and the environment. Examples of process hazards are given in Table 1.3. Process hazards are always present whenever hazardous materials and hazardous process conditions are present. Under normal conditions, these hazards are all contained and controlled.

An incident is defined as an unplanned event or sequence of events that either resulted in or had the potential to result in adverse impacts. Thus, an incident sequence is a series of events that can transform the threat posed by a process hazard into an actual occurrence.

Table 1.3 Elements of process incidents

c01_image002.jpg

The first event in an incident sequence is called the initiating cause, also termed the initiating event or, in the context of most hazard evaluation procedures, just the cause. The types of events that can initiate incident sequences are generally equipment or software failures, human errors, and external events. Table 1.3 gives some examples.

The initiating cause can be understood by considering the anatomy of an incident from an operations perspective, as presented in Figure 1.2. In the Normal operations mode, all process hazards are contained and controlled, and the facility is operating within established limits and according to established operating procedures. The operational goals during normal operation can be summarized as optimizing production and keeping the facility within the bounds of the normal operating procedures and limits. Key systems involved in keeping the facility operating normally include the primary containment system typically consisting of piping and vessels, the basic process control system (BPCS) including sensors and final control elements, functional process equipment such as pumps and distillation columns, and the execution of operational tasks according to established operating procedures. These key systems are supported by activities such as inspections, functional testing, preventive maintenance, operator training, management of change, and facility access control.

An initiating cause has as its result a shift from a Normal to an Abnormal operations mode, as soon as the operation departs from its established operating procedures or safe operating limits. In the context of hazard evaluation procedures, this abnormal mode is termed a deviation. For example, loss of cooling water supply to an exothermic reaction system can be an initiating cause for a runaway reaction incident sequence. As soon as the cooling water supply (pressure and/or flow rate) drops below the minimum established limit, it can be considered an initiating cause, and the plant is in an abnormal situation. The plant operational goal changes when an abnormal situation is detected. Instead of the goal of keeping the plant operating within normal limits, the operational goal becomes returning the plant to normal operation if possible; and, if this is not possible, bringing it to a safe state such as shutting down the unit before a loss event can occur.

If the situation in this example is allowed to continue uncorrected, a runaway reaction may result, with possible outcomes of an emergency relief discharge to the atmosphere (if the system is so configured) or a vessel rupture due to overpressurization. At this point, the operating mode transitions from an abnormal situation—which may be able to be corrected and brought back under control—to an Emergency situation. (The term emergency in this context refers to the emergency operations mode after a loss event occurs. Emergency procedures may actually be activated even before the relief discharge or vessel rupture event.) The operational goal again changes in an emergency situation, with the objective now being to minimize injuries and losses (mitigate the loss event impacts).

Key Concept: the Loss Event

In the anatomy of an incident, the beginning of an Emergency situation is termed the loss event (Figure 1.3), since some degree of loss or harm is likely to ensue once a loss event has occurred. The loss event is the point of time in an incident sequence when an irreversible physical event occurs that has the potential for loss and harm impacts. Examples include opening of a non-reclosing emergency relief device such as a rupture disk, release of a hazardous material to the environment, ignition of flammable vapors or an ignitable dust cloud, and overpressurization rupture of a tank or vessel. Other examples are given in Table 1.3. Note that an incident might involve more than one loss event, such as a flammable liquid spill (first loss event) followed by ignition of a flash fire and pool fire (second loss event) that heats up an adjacent vessel and its contents to the point of rupture (third loss event).

Figure 1.2 Anatomy of a catastrophic incident, from Reference 17 (Note: This Figure is included only to help understand initiating causes and loss events in relation to Normal, Abnormal, and Emergency operational modes and highlighted key operational goals)

c01_image003.jpg

Figure 1.3 Basic incident sequence without safeguards

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Figure 1.4 Identifying the initiating cause and the loss event in an incident scenario

c01_image005.jpg

Figure 1.4 might be helpful in identifying the initiating cause and loss event in an incident sequence. The initiating cause is at the transition from the Normal to the Abnormal mode of operation, and the loss event is at the transition from the Abnormal to the Emergency mode of operation.

The initiating cause may proceed directly to the loss event if there are no intervening safeguards or if the initiating cause is so severe that the design basis for the safeguards is violated. An example would be sufficient vehicle movement to cause mechanical failure of a simple unloading hose while transferring a hazardous material. As soon as the vehicle-movement initiating cause occurs, the irreversible physical event (unloading hose failure with release of hazardous material to the surroundings) would be realized. More often, there is a series of intermediate events that link an initiating cause to the loss event, due to the presence of preventive safeguards as described in Section 1.4.

The severity of consequences of the loss event is termed the impact (see Figure 1.3). The impact is a measure of the ultimate loss and harm of a loss event. It may be expressed in terms of numbers of injuries and/or fatalities, extent of environmental damage, and/or magnitude of losses such as property damage, material loss, lost production, market share loss, and recovery costs.

The full description of a possible incident sequence is a scenario. A scenario is an unplanned event or incident sequence that results in a loss event and its associated impacts, including the success or failure of safeguards involved in the incident sequence (see Section 1.4 regarding the role of safeguards). Thus, each scenario starts with an initiating cause as previously described, and terminates with one or more incident outcomes. The outcomes may involve various physical or chemical phenomena, which can be evaluated using consequence analysis methodologies, to determine the loss event impacts.

Hazard evaluation methods can help users understand the significance of potential incident sequences associated with a process or activity. This understanding leads to identification of ways to reduce the frequency and severity of potential incidents, thus improving the safety of process operations.

1.4 The Role of Safeguards

In the context of hazard evaluation procedures, any device, system or action that would likely interrupt the chain of events following an initiating cause is known as a safeguard.¹⁸ Different safeguards can have very different functions, depending on where in an incident sequence they are intended to act to reduce risks, as illustrated in an event-tree format in Figure 1.5.

One way of characterizing safeguards that is useful in hazard evaluations is to view the safeguards in relation to the loss event. A preventive safeguard intervenes after an initiating cause occurs and prevents the loss event from ensuing. A mitigative safeguard acts after the loss event has occurred and reduces the loss event impacts. Thus, preventive safeguards affect the likelihood of occurrence of the loss event, whereas mitigative safeguards lessen the severity of consequences of the loss event. As will be discussed later, more than one loss event is possible for a given initiating cause, depending on the success or failure of safeguards. Figure 1.6, which is a bow-tie diagram as further described in Section 5.7, provides another illustration of how preventive and mitigative safeguards relate to hazards, initiating causes, loss events, and impacts.

Figure 1.5 Preventive and mitigative safeguards function after an initiating cause has occurred

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Figure 1.6 Generic bow-tie diagram showing relation of safeguards to loss event

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Contain and Control

Although not considered to be safeguards as defined above, the containment and control of process hazards serve critical functions in avoiding or reducing the likelihood of initiating causes and ensuing incident scenarios. Note that, in this context, containment refers to the primary containment system consisting of piping, vessels and other process equipment designed to keep hazardous materials and energies contained within the process. Secondary containment systems such as diked areas and berms are mitigative safeguards.

Typical contain and control measures include:

square Proper design and installation of the primary containment system, along with inspections, testing, and maintenance to ensure the ongoing mechanical integrity of the primary containment system

square Guards and barriers to reduce the likelihood of an external force such as maintenance activities or vehicular traffic impacting process piping or equipment

square Basic process control system (BPCS) design, installation, management, and maintenance to ensure successful control system response to anticipated changes and trends such as variations in feed compositions, fluctuations in utility parameters such as steam pressure and cooling water temperature, ambient condition changes, gradual heat exchanger fouling, etc.

square Operator training to reduce the likelihood of a procedure being improperly performed

square Segregation, dedicated equipment, and other provisions to reduce the likelihood of incompatible materials coming into contact with each other

square Management of change with respect to materials, equipment, procedures, personnel, and technology.

The objectives of contain and control are to keep process material confined within its primary containment system and to keep the process within safe design and operating limits, thus avoiding abnormal situations and loss of containment events that could lead to loss, damage and injury impacts. Containment and control measures, such as those listed above, affect the frequency of initiating causes.

It should be noted that many practitioners consider containment and control measures to also be safeguards. However, they do not meet the definition of a safeguard given earlier as any device, system, or action that would likely interrupt the chain of events following an initiating cause. Most of these measures apply not only to individual scenarios but to the entire process or facility, so the repeated listing of measures such as Operator training and Mechanical integrity program in the Safeguards column on hazard evaluation worksheets only makes it more difficult for the review team to assess the overall effectiveness of the preventive and mitigative safeguards in interrupting the chain of events following the initiating cause. If the desire is to give credit for having these general measures in place, they can be listed in a separate Primary Containment and Control of Process Hazards or similar section in a hazard evaluation report, rather than be included throughout the hazard evaluation worksheets.

Preventive Safeguards

Preventive safeguards intervene after an initiating cause has occurred and process conditions are abnormal or out of control. They act to regain control or achieve a safe state when an abnormal process condition is detected, thus interrupting the propagation of the incident sequence and avoiding the loss event (irreversible physical event with potential for loss and harm impacts, such as a hazardous material release, fire, or explosion). Preventive safeguards do not affect the likelihood of initiating causes, but do affect the probability that a loss event will result, given that an initiating cause occurs. Preventive safeguards thus affect the overall scenario frequency. Typical preventive safeguards include:

square Operator response to bring an upset condition back within safe operating limits

square Operator response to a safety alarm or upset condition to manually shut down the process before a loss event can occur

square Instrumented protective system designed and implemented to automatically bring the system to a safe state upon detection of a specified abnormal condition

square Ignition source control implemented to reduce the probability of ignition given the presence of an ignitable mixture, thus preventing the loss event of a fire, dust explosion, confined vapor explosion or vapor cloud explosion

square Emergency relief system acting to relieve vessel overpressurization and prevent the loss event of a bursting vessel explosion

square Other last-resort preventive safety systems such as manual dump or quench systems.

The objective of preventive safeguards is to avoid a loss event or a more severe loss event, given the occurrence of an initiating cause. An example of avoiding a more severe loss event is if mechanical failure of a piping system immediately results in loss of containment of a flammable liquid (which is both an initiating cause and a loss event, since no preventive safeguards intervene), ignition source control can avoid a different, more severe loss event of a fire or vapor cloud explosion.

Preventive safeguards should be considered as systems that must be designed, maintained, inspected, tested, and operated to ensure they are effective against particular incident scenarios. For safety instrumented systems, this is termed the safety integrity level (SIL). CCPS¹⁹ provides guidance on the life cycle management of instrumentation and control systems to achieve a specified level of integrity.

Both qualitative and quantitative methodologies can be used to identify and classify safeguards. Layer of Protection Analysis (LOPA), an order-of-magnitude method that builds on traditional hazard evaluation results to determine the required integrity of safeguards, is summarized in Section 7.6.

The following example illustrates how operator response to a safety alarm can be considered as a preventive safeguard system having several essential parts. Figure 1.7 shows the example reaction process used to illustrate Fault Tree Analysis in Section 5.5. The process consists of a reactor for a highly unstable process that is sensitive to small increases in temperature. It is equipped with a deluge for emergency cooling to protect against an uncontrolled reaction. To prevent a runaway reaction during an increase in temperature, the inlet flow of process material to the reactor must be stopped or the deluge must be activated. The reactor temperature is monitored by a sensor (T1) that automatically activates the deluge by opening the deluge water supply valve when a temperature rise is detected. At the same time, sensor T1 sounds an alarm in the control room to alert the operator of the temperature rise. When the alarm sounds, standard operating procedure calls for the operator to push the inlet valve close button to shut the inlet valve and stop inlet flow to the reactor and to push the deluge open button in the control room if the deluge is not activated by sensor T1. If the inlet valve closes or the deluge is activated, system damage due to an uncontrolled reaction is averted. (Note that the example process is described in this manner for illustrative purposes only; this would not likely be the best way to arrange a reactive process of this nature.)

Figure 1.7 Emergency cooling system schematic

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The operator response preventive safeguard system would require all of the following to occur in order to successfully protect against the consequence of concern:

1. The temperature sensor is at the right location and responds with inconsequential time delay, giving a correct output signal corresponding to the increase in reactor temperature.

2. A relay or other device successfully operates at the proper safety limit setting to send a signal to the alarm module.

3. The high temperature alarm functions to annunciate the proper audible and/or visual warning in the control room.

4. The operator is present in the control room at the time the alarm sounds.

5. The ambient noise level and distractions are sufficiently minimal such that the operator is alerted by the alarm signal.

6. The operator decides to respond to the alarm and not just acknowledge it.

7. The operator makes the correct diagnosis as to the meaning of the alarm based on the operator’s training, experience, and preconceptions of the state of the process.

8. The operator responds to the alarm in time to avert the loss event.

9. The operator actuates the correct push buttons to stop the inlet flow and/or activate the deluge.

10. The inlet flow is stopped in time by successful functioning of the inlet valve close button and the inlet valve; or, the deluge is activated in time by successful functioning of the deluge push button, deluge valve, and deluge piping and nozzles, and an adequate supply of fire water is available.

It should be noted that, for this example, the operator response to the alarm to actuate the deluge system is not independent of the automatic deluge system, since they share a common temperature sensor and a common final control element (deluge water supply valve). Likewise, the operator-actuated inlet flow isolation system and the deluge system are not independent of each other, since they share a common temperature sensor. Thus, a hazard evaluation team would need to evaluate the effectiveness of the overtemperature safeguards by examining both the operator responses and the automatic safety systems together rather than as independent protective systems. This assessment of the independence of preventive safeguards is an important part of a hazard evaluation, regardless of whether the evaluation is performed using a qualitative or a quantitative technique.

Mitigative Safeguards

A mitigative safeguard acts to reduce the severity of consequences of a loss event; i.e., the sum total of safety, business, community, and environmental impacts resulting from a fire, explosion, toxic release, or other irreversible physical event. Typical mitigative safeguards include:

square Reclosing emergency relief devices such as safety relief valves, acting to reduce the duration of a hazardous material release loss event if the emergency relief discharges to the atmosphere

square Secondary containment (e.g., double-walled system, secondary enclosure)

square Explosion blast and missile containment structures / barricades

square Fire/release detection and warning systems

square Automatic or remotely actuated isolation valves

square Fire extinguishers, sprinkler systems, and fire water monitors

square Deluge, foam, and vapor mitigation systems

square Fire-resistant supports and structural steel

square Storage tank thermal insulation

square Blast-resistant construction of occupied buildings

square Loss-event-specific personal protective equipment (e.g., splash goggles, flame-retardant clothing, escape respirators)

square Emergency response and emergency management planning.

The objective of mitigative safeguards is to detect and respond to emergency situations in such a way as to reduce the impacts of loss events as compared to the unmitigated impacts without the safeguards.

When performing detailed, scenario-based hazard evaluations, a useful distinction can be drawn between those mitigative safeguards designed to act after the loss event occurs and affect the source term (i.e., the release parameters of magnitude, rate, duration, orientation, temperature, etc. that are the initial conditions for determining the consequences of the loss event) and those mitigative safeguards designed to reduce the impacts of the released material or energy on people, property and the environment. Examples of the first category of mitigative safeguards (which could be called source-mitigative safeguards) include excess flow valves, dry-break connections on unloading hoses, automatic release detection and isolation systems, and engineered vapor release mitigation systems such as deluges and water curtains. Examples of the second category of mitigative safeguards (which could be called receptor-mitigative safeguards and are sometimes termed response rather than mitigation) include the buffer distance to surrounding populations, occupied building blast resistance, fire-resistant construction, specialized personal protective equipment evacuation or shelter-in-place procedures, and other emergency response actions including firefighting. Section 7.2 includes a discussion of how these different types of safeguards are evaluated when assessing scenario risk.

1.5 Hazard Evaluation Throughout a Plant Lifetime

Many organizations have published model programs for process safety management (PSM). All of these PSM approaches embrace a consistent theme: Hazard evaluations should be performed throughout the life of a facility. As an integral part of its PSM program, an organization can use the results of hazard evaluations to help manage the risk of each phase of process activity. Hazard evaluations can be done efficiently from the earliest stages of R&D, in detailed design and construction, during commissioning and start-up, periodically throughout the operating lifetime, and until the process is decommissioned and dismantled.¹⁰’¹⁵ A more complete discussion of hazard evaluation at different plant life cycle stages, including as part of managing changes, can be found in Chapter 6, Sections 6.4 and 6.6. Two aspects of hazard evaluation throughout a plant lifetime warrant particular emphasis:

square Using this life cycle approach in association with other PSM activities can efficiently reveal deficiencies in design and operation before a unit is sited, built or operated, thus making the most effective use of resources devoted to ensuring the safe and productive life of a facility.

square Regardless of the technique used for conducting hazard evaluations throughout the operating lifetime of a facility, each study, along with its documented information and assumptions, should be updated or revalidated on a periodic basis.

An important part of performing hazard evaluations throughout a plant lifetime is knowing which technique is the best one for the study. Chapter 5 discusses many factors that influence this decision and provides the logic behind choosing an appropriate technique. One of the most important factors that influences which hazard evaluation technique an analyst chooses is how much information is available to perform the work. Some hazard evaluation methods may be inappropriate or impossible to perform at a particular life cycle stage because of inadequate process information.

1.6 Hazard Evaluation and Regulations

Although most companies in the chemical processing industries conduct hazard evaluations voluntarily because they

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