Handbook of loss prevention engineering: 2
Gespeichert in:
| Weitere Verfasser: | |
|---|---|
| Format: | Buch |
| Sprache: | English |
| Veröffentlicht: |
Weinheim
Wiley-VCH
2013
|
| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | XXVI S., S. 463 - 1106 Ill., graph. Darst. 25 cm |
Internformat
MARC
| LEADER | 00000nam a2200000 cc4500 | ||
|---|---|---|---|
| 001 | BV040974159 | ||
| 003 | DE-604 | ||
| 005 | 20130522 | ||
| 007 | t | ||
| 008 | 130429s2013 gw ad|| |||| 00||| eng d | ||
| 015 | |a 13,A17 |2 dnb | ||
| 016 | 7 | |a 1031741747 |2 DE-101 | |
| 035 | |a (OCoLC)854696605 | ||
| 035 | |a (DE-599)DNB1031741747 | ||
| 040 | |a DE-604 |b ger |e rakddb | ||
| 041 | 0 | |a eng | |
| 044 | |a gw |c XA-DE-BW | ||
| 049 | |a DE-83 |a DE-29T |a DE-92 | ||
| 245 | 1 | 0 | |a Handbook of loss prevention engineering |n 2 |c ed. by Joel M. Haight |
| 264 | 1 | |a Weinheim |b Wiley-VCH |c 2013 | |
| 300 | |a XXVI S., S. 463 - 1106 |b Ill., graph. Darst. |c 25 cm | ||
| 336 | |b txt |2 rdacontent | ||
| 337 | |b n |2 rdamedia | ||
| 338 | |b nc |2 rdacarrier | ||
| 700 | 1 | |a Haight, Joel M. |0 (DE-588)1032220406 |4 edt | |
| 773 | 0 | 8 | |w (DE-604)BV040974134 |g 2 |
| 856 | 4 | 2 | |m DNB Datenaustausch |q application/pdf |u http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=025952295&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |3 Inhaltsverzeichnis |
| 999 | |a oai:aleph.bib-bvb.de:BVB01-025952295 | ||
Datensatz im Suchindex
| _version_ | 1804150289902600192 |
|---|---|
| adam_text | IMAGE 1
CONTENTS TO VOLUME 1
PREFACE XVII
LIST OF CONTRIBUTORS XIX
PARTI ENGINEERING MANAGEMENT FOR LOSS PREVENTION ENGINEERING 1
1 MANAGEMENT SYSTEMS - LOSS PREVENTION ENGINEERING PROGRAMS AND POLICY 3
SHAKIRUDEEN SHAKIOYE
2 RESOURCE ALLOCATION AND EFFECTIVENESS MEASURES FOR LOSS PREVENTION 31
SAMUEL A. OYEWOLE
3 ENGINEERING SYSTEMS AND ENGINEERING ECONOMICS O F LOSS PREVENTION 53
JOEL M. HAIGHT
4 SAFETY MANAGEMENT AND CULTURE 71
BRIAN W. TINK AND BRIAN A. TINK
5 LEADERSHIP AND LOSS PREVENTION ENGINEERING: CREATING CONDITIONS TO GET
BEYOND COMPLIANCE TO HIGH PERFORMANCE 89 MICHELE LINDSAY
PART II DESIGN AND ANALYSIS O F PROTECTIVE SYSTEMS - GENERAL LOSS
PREVENTION ENGINEERING 113
6 GENERAL LOSS PREVENTION ENGINEERING PROGRAMS - INCLUDING FIRE LOSS
CONTROL 115 JEFFERY ROBINSON
7 PERMIT-TO-WORK SYSTEMS 141
JOHN W. MROSZCZYK
HTTP://D-NB.INFO/1031741747
IMAGE 2
| COR
8
9
10
11
12
13
14
15
16
17
18
19
EXCAVATION AND TRENCHING 159 MICHAEL W. HAYSLIP
MACHINE SAFEGUARDING 201 JOHN W. MROSZCZYK
BOILERS AND PRESSURE VESSELS: A BRIEF LOOK AT GENERAL SAFEGUARDS 231
PATRICK FORTUNE
WELDING AND CUTTING 261 JEFFERY S. HAIGHT
POWER TOOLS 277 WARREN K. BROWN
PERSONAL PROTECTIVE EQUIPMENT 303 CHRISTOPHER M. STROZ
POWERED INDUSTRIAL TRUCKS 327 THADDEUS M. PAJAK AND MARY HOERSTER
PART III ERGONOMICS AND HUMAN FACTORS ENGINEERING 355
BIOMECHANICS AND PHYSICAL ERGONOMICS 357 KYUNG-SUN LEE AND MYUNG-CHUL
JUNG
HUMAN FACTORS AND COGNITIVE ENGINEERING 373 ANAND THARANATHAN AND LING
ROTHROCK
VIRTUAL WORKING ENVIRONMENT 393 TEODOR WINKLER, JAROSLAW TOKARCZYK, AND
DARIUSZ MICHALAK
SHAPING OF WORKING CONDITIONS USING ICT TECHNOLOGY 423 DARIUSZ MICHALAK,
MAGDALENA ROZMUS, AND TEODOR WINKLER
SAFETY-ORIENTED VIRTUAL PROTOTYPING O F MINING MECHANICAL SYSTEMS 445
JAROSLAW TOKARCZYK, MAREK DUDEK, AND BOGDAN GICALA
IMAGE 3
CONTENTS I V I I
CONTENTS TO VOLUME 2
LIST O F CONTRIBUTORS XXIII
PART IV PROCESS SAFETY MANAGEMENT AND SYSTEM SAFETY ENGINEERING 463
20 PROCESS SAFETY REGULATIONS AROUND THE WORLD 465 REMIGIO
AGRAZ-BOENEKER 20.1 INTRODUCTION 465
20.2 PROCESS SAFETY - DRIVERS 465
20.3 DIFFERENCES AND COMMONALITIES 466 20.4 NON-REGULATORY APPROACHES
468 20.5 LESSONS LEARNED 470
20.6 EVOLVING FIELD 471
20.7 GENERAL DUTY 472
20.8 PROPOSED CHANGES TO REGULATIONS 473 20.9 SUMMARY 473
20.10 FUTURE OF PROCESS SAFETY 474 APPENDIX 20.A: PROCESS SAFETY DRIVERS
475 APPENDIX 20. B PROCESS SAFETY REGULATIONS AROUND THE WORLD 476
APPENDIX 20.C NON-REGULATORY APPROACHES 485
APPENDIX 20.D: GOOD ENGINEERING PRACTICES (GEPS) LISTED IN THE OSHA NEP
FOR REFINERIES (CPL 03-00-004) 489 APPENDIX 20.E: THE AUTHOR S
SUGGESTION FOR A POSSIBLE OUTLINE FOR A PROCESS SAFETY MANAGEMENT
PROGRAM, BASED ON CONCEPTS DERIVED FROM THE MAIN PROCESS SAFETY DRIVERS
490 APPENDIX 20.F: ABBREVIATIONS USED IN THE APPENDICES 497
REFERENCES 498
21 ANALYTICAL METHODS IN PROCESS SAFETY MANAGEMENT AND SYSTEM SAFETY
ENGINEERING - PROCESS HAZARD ANALYSIS 501 PAUL BAYBUTT 21.1 INTRODUCTION
501
21.2 OVERVIEW OF PHA 502
21.3 PHA AND DECISION-MAKING 504 21.4 STAGES AND STEPS IN PHA 506
21.5 PHA PROJECT INITIATION 507
21.6 HAZARD IDENTIFICATION 507 21.7 SELECTING A PHA METHOD 509 21.8
DEFINING THE PURPOSE, SCOPE, AND OBJECTIVES O F THE STUDY 509 21.9
SELECTING A TEAM 510
21.9.1 TEAM MEMBERS 510 21.9.2 TEAM SIZE AND COMPOSITION 513 21.9.3
LEADERSHIP AND FACILITATION SKILLS 514
IMAGE 4
V I I I I CONTENTS
21.10 COLLECTING AND PREPARING REFERENCE INFORMATION AND DATA 5 14
21.11 ESTIMATING THE EFFORT INVOLVED AND SCHEDULING STUDY SESSIONS 516
21.12 BRIEFING/TRAINING TEAM MEMBERS 517 21.13 ARRANGING REQUIRED
FACILITIES 517 21.14 OTHER ITEMS 518
21.15 SUBDIVIDING THE PROCESS 518 21.16 PERFORMING AN INHERENT SAFETY
REVIEW 520 21.17 FIRST SESSION 520
21.18 RECORDING PHA STUDIES 522 21.19 MAKING WORKSHEET ENTRIES 524
21.19.1 INITIATING EVENTS (CAUSES) 524 21.19.2 INTERMEDIATE EVENTS 526
21.19.3 CONSEQUENCES 527
21.19.4 SAFEGUARDS 527 21.19.5 ENABLERS 528 21.19.6 RISK RANKING 529
21.19.7 RECOMMENDATIONS 531
21.20 SPECIAL TOPICS 532 21.20.1 MULTIPLE FAILURES 532 21.20.2 HUMAN
FACTORS 534 21.20.3 FACILITY SITING 535 21.20.4 UTILITIES 536 21.20.5
MODES O F OPERATION 537 21.20.6 PROCESS CHANGES 538
21.20.7 PROCEDURES 538 21.20.8 NON-STEADY-STATE PROCESSES 539 21.20.9
QUALITY CONTROL 539 21.20.10 LIMITATIONS AND CAUTIONS 540
21.21 REVALIDATION 540 21.22 REPORT PREPARATION 542 21.23 FOLLOW-UP 542
ACKNOWLEDGMENTS 544 APPENDIX 21.A. DESCRIPTIONS O F PHA METHODS 544
APPENDIX 21.B. COMPARISON O F PHA METHODS 551 REFERENCES 552
22 SAFETY INSTRUMENTED SYSTEMS 555
GEOFFREY S. BARNARD
22.1 INTRODUCTION 555
22.1.1 HISTORY 555
22.1.2 FUNCTIONAL SAFETY ENGINEERING STANDARDS 556 22.1.3 REGULATORY
REQUIREMENTS 557 22.1.4 NOTES ON THIS CHAPTER 557 22.2 FUNDAMENTALS 558
22.2.1 LAYERS O F PROTECTION 558
IMAGE 5
CONTENTS I I X
22.2.2 CONTROL VERSUS SAFETY 560
22.2.3 ACCESS RESTRICTION 560 22.2.4 TESTING AND DIAGNOSTICS 562 22.2.5
REDUNDANCY AND FAULT TOLERANCE 562 22.2.6 INDEPENDENCE AND DIVERSITY 562
22.2.7 INTEGRATED CONTROL AND SAFETY 563 22.3 PLANNING AND MANAGEMENT
564 22.3.1 FUNCTIONAL SAFETY LIFE-CYCLE PROCESS 564 22.3.2 POLICIES,
PROCEDURES, AND DOCUMENTATION 566 22.3.3 ROLES AND RESPONSIBILITIES 567
22.3.4 PERFORMANCE MANAGEMENT 567 22.4 ANALYSIS PHASE 569
22.4.1 PROCESS HAZARD ANALYSIS 569 22.4.2 LAYERS OF PROTECTION ANALYSIS
570 22.4.3 SAFETY INTEGRITY LEVEL DETERMINATION 572 22.4.4 SAFETY
INSTRUMENTED FUNCTION DESIGN AND SAFETY REQUIREMENTS
SPECIFICATIONS 573 22.4.5 SAFETY INTEGRITY LEVEL VERIFICATION 575 22.4.6
JUSTIFICATION 579 22.5 REALIZATION PHASE 580
22.5.1 HARDWARE 580
22.5.2 APPLICATION PROGRAM 581 22.5.3 INTERFACES 582
22.5.4 FABRICATION AND INSTALLATION 582 22.5.5 INTEGRATION AND FACTORY
ACCEPTANCE TESTING 583 22.5.6 MAINTENANCE AND TESTING PROCEDURES 584
22.5.7 COMMISSIONING AND SITE ACCEPTANCE TESTING 585 22.5.8 PRE-STARTUP
SAFETY REVIEW 586 22.5.9 FUNCTIONAL SAFETY ASSESSMENTS 586 22.6
OPERATION PHASE 587
22.6.1 INSPECTION, MAINTENANCE, AND PROOF-TESTING 587 22.6.2 MANAGEMENT
O F CHANGE 588 22.6.3 PERFORMANCE MONITORING AND CONTINUOUS IMPROVEMENT
589 22.7 CONCLUSION 590
REFERENCES 590
23 ANALYTICAL METHODS IN PROCESS SAFETY MANAGEMENT AND SYSTEM SAFETY
ENGINEERING - LAYERS O F PROTECTION ANALYSIS 593 PAUL BAYBUTT 23.1
INTRODUCTION 593
23.2 OVERVIEW OF LOPA 595 23.2.1 NATURE O F LOPA 595 23.2.2 HAZARD
SCENARIOS 596 23.2.3 LOPA CHARACTERISTICS 598 23.2.4 TIMING O F LOPA 599
IMAGE 6
X I CONTENTS
23.3 SCENARIO RISK 599
23.3.1 MEANING OF RISK 599 23.3.2 LOPA APPROACHES 599 23.3.3 RISK
CALCULATION 600 23.3.4 USE O F RISK ESTIMATES 601
23.4 RISK TOLERANCE CRITERIA 601 23.4.1 ALARP PRINCIPLE 601 23.4.2 FORM
O F RISK TOLERANCE CRITERIA 602 23.4.3 TYPES O F RISK TOLERANCE CRITERIA
603 23.4.4 DETERMINING TOLERABLE RISK 605 23.4.5 USE O F RISK TOLERANCE
CRITERIA 605 23.5 STAGES AND STEPS IN LOPA 606
23.6 INITIATING A PROJECT 607
23.7 PREPARING FOR LOPA 608
23.7.1 DECIDING ON A LOPA APPROACH 608 23.7.2 DECIDING ON TOLERABLE RISK
CRITERIA 609 23.7.3 SELECTING HAZARD SCENARIOS FOR ANALYSIS 609 23.7.4
DETERMINING WHICH SCENARIO ELEMENTS WILL BE ADDRESSED 610
23.7.5 DECIDING ON CRITERIA FOR QUALIFYING SAFEGUARDS AS IPLS 611 23.7.6
OBTAINING AND USING FAILURE DATA 612 23.7.6.1 DATA SOURCES 612 23.7.6.2
STANDARDIZED DATA 613 23.7.6.3 USE O F DATA 614 23.8 PREPARING FOR A
STUDY 615
23.8.1 DEFINING THE PURPOSE, SCOPE, AND OBJECTIVES 615 23.8.2 SELECTING
A TEAM 615 23.8.3 COLLECTING INFORMATION AND DATA NEEDED 616 23.8.4
ESTIMATING THE EFFORT REQUIRED AND SCHEDULING STUDY SESSIONS 616
23.8.5 BRIEFING/TRAINING TEAM MEMBERS 617 23.8.6 ARRANGING REQUIRED
FACILITIES 617 23.8.7 ADDRESSING OTHER ITEMS 617 23.9 CONDUCTING A STUDY
6 18
23.9.1 CONDUCTING THE FIRST SESSION 618 23.9.2 RECORDING SCENARIO
INFORMATION 619 23.9.2.1 STUDY WORKSHEETS 619 23.9.2.2 FORMAT AND
CONTENT O F LOPA WORKSHEETS 621
23.9.2.3 USE O F LOPA WORKSHEETS 622 23.9.3 ASSIGNING INITIATING EVENT
FREQUENCIES 623 23.9.4 ADDRESSING ENABLERS 623 23.9.5 ASSIGNING ENABLER
PROBABILITIES/MULTIPLIERS 624
23.9.6 IDENTIFYING EXISTING IPLS 625 23.9.7 ASSIGNING IPL PFDS 626
23.9.8 DOCUMENTING IPLS 626 23.9.9 ESTIMATING SCENARIO CONSEQUENCE
SEVERITY AND FREQUENCY 629
23.9.10 EVALUATING SCENARIO RISK 629
IMAGE 7
CONTENTS I X I
23.9.11 ASSESSING COMPLIANCE WITH TOLERABLE RISK CRITERIA 629
23.9.12 DEVELOPING RECOMMENDATIONS FOR ANY NEEDED RISK REDUCTION 629
23.9.13 ADDRESSING QUALITY ASSURANCE 630 23.9.14 REVALIDATING PREVIOUS
STUDIES 630 23.9.15 PREPARING A REPORT 630 23.9.16 FOLLOWING UP 631
23.9.16.1 ADDRESSING RISK REDUCTION NEEDED 631
23.9.16.2 VERIFYING THAT IPLS DO NOT INTRODUCE ADDITIONAL HAZARDS 633
23.9.16.3 VERIFYING IPL ADEQUACY 633 23.9.16.4 MODIFYING THE PSM PROGRAM
633 23.9.16.5 AUDITING IPLS 633 23.10 LIMITATIONS, CAUTIONS, AND
PITFALLS 633
ACKNOWLEDGMENTS 635 REFERENCES 635
24 CHEMICAL REACTION SAFETY 637 JOHN C. WINCEK 24.1 INTRODUCTION 637
24.1.1 NEED FOR REACTIVE CHEMICAL MANAGEMENT 637 24.1.1.1 MORTON
INTERNATIONAL, INC. 637 24.1.1.2 MFG CHEMICAL, INC. 638 24.1.1.3 T2
INCIDENT 638 24.1.1.4 CSB IMPROVING REACTIVE HAZARD MANAGEMENT 639
24.1.2 SUMMARY 639
24.2 CHEMICAL REACTION HAZARDS 639 24.2.1 PROTECTING AGAINST
CATASTROPHIC INCIDENTS 641 24.3 IDENTIFYING REACTION HAZARDS 641 24.3.1
LITERATURE SURVEY 641 24.3.2 INCIDENTS 642
24.3.3 PRESENCE OF HIGHLY UNSTABLE ATOMIC GROUPS 643 24.3.4 THEORETICAL
HEAT OF REACTION CALCULATIONS 644 24.3.4.1 HEATS O F FORMATION 644
24.3.4.2 BOND ENERGY SUMMATION 644
24.3.4.3 GROUP CONTRIBUTION METHOD O F BENSON 644 24.3.4.4 OXYGEN
BALANCE 644 24.3.4.5 COMPUTER METHODS 645 24.3.4.6 INCOMPATIBILITIES 645
24.4 DETERMINE THE WORST-CASE CONSEQUENCES 646
24.4.1 SCREENING TESTS 646 24.4.1.1 DIFFERENTIAL SCANNING CALORIMETRY
(DSC) 646 24.4.1.2 INSULATED EXOTHERM TEST 647 24.4.1.3 DECOMPOSITION
PRESSURE TEST 647
24.4.1.4 CARIUS TUBE 648 24.4.1.5 ADVANCED REACTIVE SYSTEMS SCREENING
TOOL (ARSST) 648 24.4.1.6 RAPID SCREENING DEVICE (RSD) 650
IMAGE 8
X I I I CONTENTS
24.4.1.7 THERMAL SCREENING UNIT (TSU) 650
24.4.1.8 MICRO REACTION CALORIMETER (URC) 650 24.4.1.9 INTERPRETATION O
F SCREENING DATA 650 24.4.2 REACTION HAZARD EVALUATION 653 24.4.2.1
INTRODUCTION 653
24.4.2.2 CHARACTERIZING THE DESIRED REACTION 654 24.4.2.3 CHARACTERIZING
THE RUNAWAY AND SECONDARY REACTIONS 656 24.4.2.4 STOESSEL S CRITICALITY
CLASSES 661 24.5 ASSESSING CHEMICAL REACTION RISKS 663 24.6 IDENTIFYING
PROCESS CONTROLS 666 24.6.1 SELECTION OF REACTOR TYPE 667 24.6.1.1 BATCH
REACTORS 667 24.6.1.2 SEMI-BATCH REACTORS 667 24.6.1.3 CONTINUOUS
REACTORS 668
24.6.1.4 CONTINUOUS STIRRED TANK REACTOR (CSTR) 668 24.6.1.5 PLUG FLOW
REACTORS 668 24.6.2 PROCESS SAFEGUARDS 668 24.6.3 POTENTIAL SAFEGUARDS
670
24.6.3.1 ADDITION RATE CONTROL 671 24.6.3.2 ADDITION TEMPERATURE 671
24.6.3.3 CRASH COOLING 671 24.6.3.4 INHIBITOR INJECTION 672 24.6.3.5
SAFETY INSTRUMENTED SYSTEMS 672
24.6.3.6 EMERGENCY RELIEF SYSTEM DESIGN 672 24.7 BASIS OF SAFETY
SELECTION 673 24.7.1 PROCESS DESCRIPTION 673 24.7.2 PROCESS CHEMICALS
674
24.7.3 PROCESS HAZARDS, CAUSES, AND CONSEQUENCES 674 24.7.4 SAFETY
OBJECTIVES 674 24.7.5 PROCESS SAFEGUARDS 675 24.7.6 SAFE OPERATING
ENVELOPE 675
24.8 CONCLUSION 676
REFERENCES 677
25 APPLICATION O F SYSTEMS ENGINEERING TO SAFETY AND RISK MANAGEMENT: A
HUMAN-SYSTEMS INTEGRATION PERSPECTIVE 681 TAREQ AHRAM AND WALDEMAR
KARWOWSKI 25.1 INTRODUCTION 681
25.2 SYSTEMS ENGINEERING 681 25.3 HUMAN-SYSTEMS INTEGRATION 684 25.4
SYSTEMS MODELING LANGUAGE 689 25.5 HUMAN-SYSTEMS INTEGRATION MODEL
DOMAINS 696
REFERENCES 697
IMAGE 9
CONTENTS I X I I I
26 MANAGEMENT O F CHANGE 701
TRACEY Z A M AND AARON HADE 26.1 INTRODUCTION 701
26.2 WHAT IS MANAGEMENT OF CHANGE (MOC)? 703 26.3 WHY IS MOC IMPORTANT
706
26.4 DEVELOPING A FORMAL MOC PROGRAM 707 26.5 EXECUTING THE CHANGE 712
26.6 SCALABLE MOC 720
26.7 PITFALLS TO AVOID 721
26.8 SUCCESS STORIES 722
26.9 CONCLUSION 722
26.10 TOOLS AND RESOURCES 723 26.10.1 WEB SITES 723 26.10.2 GENERAL
INTEREST BOOKS 723 26.11 ACCREDITATION GROUPS 723
REFERENCES 723 FURTHER READING 724
27 THE IMPORTANCE O F FOSTERING A STRONG INDUSTRIAL SAFETY CULTURE AND
CHANGE MANAGEMENT 725 JEFFERY M. KRAMER 27.1 INTRODUCTION 725
27.2 PROCESS DESCRIPTION 727
27.2.1 PROCESS INPUTS 727 27.2.2 CORRECTIVE ACTIONS 728 27.2.3 OTHER
INPUTS 729
27.2.4 INDUSTRIAL SAFETY CULTURE MONITORING PANEL (ISCMP) 729 27.2.5
SITE LEADERSHIP TEAM (SLT) 729 27.2.6 FACILITY RESPONSE 730 27.2.1
COMMUNICATION 730
27.2.8 EXTERNAL INPUT 730 27.2.9 REGULATORY OVERSIGHT 730 27.2.10
PERFORMANCE TRENDS 730 27.2.11 CORRECTIVE ACTION PROGRAM 731 27.2.12
REPORT 731 27.3 SITE LEADERSHIP TEAM INDUSTRIAL SAFETY CULTURE REVIEW
731 27.3.1 OFF-SITE INDUSTRIAL SAFETY REVIEW BOARD 732 27A CHANGE
MANAGEMENT 732
27.4.1 CHANGE MANAGEMENT PLAN - APPLICABLE TO ONLY ONE FACILITY 739
27.4.1.1 DEVELOPMENT AND INITIAL REVIEW 739 27.4.1.2 CHANGE CHAMPION 743
27.4.1.3 STAKEHOLDERS 743
27.4.1.4 TRAINING MANAGER 743 27.4.1.5 HUMAN RESOURCES MANAGER 743
27.4.1.6 INFORMATION MANAGEMENT NUCLEAR SYSTEMS MANAGER 744
IMAGE 10
X I V I CONTENTS
27.4.2 FINAL APPROVAL 744
27.4.3 IMPLEMENTATION 744 27.4.3.1 CHANGE CHAMPION 744 27.4.3.2 SPONSOR
744 27.5 CONCLUSION 745
REFERENCES 745
28 CONTRACTOR SAFETY MANAGEMENT 747 MICHAEL FARRIS 28.1 INTRODUCTION 747
28.1.1 TERMINOLOGY 748 28.1.2 THE CONTRACTOR PERSPECTIVE 748 28.1.3 THE
CONTRACT 749 28.2 CONTRACTOR MANAGEMENT 750 28.2.1 THE PROCESS MODEL 750
28.2.1.1 OVERVIEW 750 28.2.1.2 PROCESS STAGES 751 28.2.1.3 AUDITS 752
28.2.1.4 REAL-TIME SNAPSHOTS 753
28.2.2 BUSINESS RELATIONSHIP CYCLE 754 28.2.2.1 CONTRACT LIFE CYCLE 754
28.2.2.2 OPERATOR KEY PLAYERS 755 28.2.2.3 CONTRACT PHASES, ISSUES,
SOLUTIONS 756 28.2.3 THE PURPOSE OF A CONTRACTOR MANAGEMENT SYSTEM 758
28.2.3.1 DATE TO THE PROM 758 28.2.3.2 SELECT THE SAFEST CONTRACTOR 758
28.2.3.3 SELECT THE BEST CONTRACTOR FOR THE JOB 759 28.2.4
CONTRACTOR-OPERATOR RELATIONSHIPS; INSIDE THE FENCE OR RUNNING LOOSE 759
28.2.4.1 INSIDE THE FENCE 759 28.2.4.2 RUNNING LOOSE 760
28.2.4.3 NEITHER O F THE ABOVE 761 28.2.5 TYPICAL ISSUES AND SPECIAL
CONSIDERATIONS 761 28.2.5.1 BUT WHAT A B O U T . . . 761 28.2.5.2 MOM
AND POP 762 28.2.5.3 OFF-SITE SERVICES 762
28.2.5.4 THE ONLY GAME I N TOWN 762 28.2.5.5 APPLES TO ORANGES 763
28.2.5.6 DECISIONS MADE IN A VACUUM 763 28.3 THE SCORE: QUESTIONNAIRES
AND CONTRACTOR RANKING SYSTEMS 763
28.3.1 INTRODUCTION 763 28.3.1.1 SCORING SYSTEMS 763 28.3.1.2 DATA SET 1
- COMPONENT SCORE 763 28.3.1.3 DATA SET 2 - LOSS METRICS 764
28.3.1.4 RANKING SYSTEM 1 - COLOR CODES 764
IMAGE 11
CONTENTS I X V
28.3.1.5 RANKING SYSTEM 2 - LETTER GRADES 764
28.3.1.6 QUESTIONNAIRES 765 28.3.2 FORMULAS 766
28.3.2.1 FORMULA 1 - EQUAL WEIGHTS ON 100% SCALE 766 28.3.2.2 FORMULA 2
- EQUAL WEIGHTS, 100 MINUS DEMERITS 766 28.3.2.3 FORMULA 3 - NO-GO ITEMS
767 28.3.3 THE X-FACTOR: TAKING A HARD LOOK AT LOSS METRICS 767 28.3.3.1
DATA DISPLAY: KEEP IT CLEAR AND SIMPLE 767 28.3.3.2 LOSS METRICS 767
28.3.3.3 THE X-FACTOR: A SECRET FORMULA FOR GRADING CONTRACTORS 768
28.3.3.4 COMPARING MULTIPLE COMPANIES 769 28.4 SUMMARY AND CONCLUSION
770 28.4.1 DOES THE RUBBER MEET THE ROAD? 770 28.4.2 CONCLUSION 771
29 EMERGENCY PREPAREDNESS AND RESPONSE 773 LEO J. DEBOBES REFERENCES 782
30 SECURITY AND TERRORISM 785
MOHAMMED NASIR MOHAMMED ISMAIL 30.1 SECURITY AND TERRORISM 785 30.2 THE
OKLAHOMA CITY BOMBING 786 30.3 THE 9/11 ATTACKS 786
30.4 LESSONS LEARNED FROM THE OKLAHOMA CITY BOMBING AND 9/11 787 30.5
BIOTERRORISM 789
30.6 CYBER TERRORISM 791
30.7 CONCLUSION 791
REFERENCES 792
PARTV OCCUPATIONAL HEALTH AND ENVIRONMENTAL ENGINEERING 795
31 CONTROL O F CHEMICAL HAZARDS 797
MARJORY E. ANDERSON 31.1 INTRODUCTION 797
31.2 CONSIDERATIONS 797
31.2.1 WHAT IS THE PROCESS BEING DEVELOPED? 798 31.2.2 WHAT CHEMICAL(S)
WILL BE USED? 798 31.2.3 HOW WILL DELIVERY O F CHEMICALS BE
ACCOMPLISHED? 800 31.2.4 HOW AND WHERE WILL PROCESS CHEMICALS BE STORED?
801 31.2.5 ARE THERE ANY COMPATIBILITY ISSUES WITH THE CHEMICALS TO BE
USED IN
THE PROCESS? 803
31.2.6 WHAT ARE ALL THE WAYS IN WHICH THE CHEMICALS WILL BE USED WITHIN
THE PROCESS? 803
IMAGE 12
X V I | CONTENTS
31.2.7 HOW WILL CHEMICAL RELEASES AND SPILLS BE CONTROLLED AND CLEANED
UP? 805
31.2.8 HOW WILL PROCESS CHEMICALS BE DISPOSED O F ? 806 31.2.9 OSHA
REQUIREMENTS 807 31.3 CONTROL METHODS 808
31.3.1 HIERARCHY OF CONTROLS 809 31.3.2 SPECIFIC CONTROLS 811 31.3.3
VENTILATION AND HOODS 811 31.3.4 SCRUBBERS 812
31.3.5 CLOSED SYSTEMS 813 31.3.6 AUTOMATION 814 31.3.7 BARRIERS, DIKES,
AND OTHER SEPARATIONS 815 31.3.8 MONITORS AND MONITORING DEVICES 816
31.3.9 OTHER CONTROLS 817 31.4 CONCLUSION 818
REFERENCES 818
32 CONTROL O F PHYSICAL HAZARDS 821
MARJORY E. ANDERSON 32.1 INTRODUCTION 821
32.2 CONSIDERATIONS 821
32.2.1 HIERARCHY O F CONTROLS 822 32.2.2 SPECIFIC CONTROLS 824 32.2.3
WALKING AND WORKING SURFACES AND VARYING LEVELS 824 32.2.4 CONFINED
SPACE 826
32.2.5 MACHINERY, MATERIALS, AND EQUIPMENT 827 32.2.6 POWER SOURCES 829
32.2.7 TEMPERATURE 831 32.2.8 SOUND LEVELS 833
32.3 CONTROL METHODS 835
32.3.1 FALL PROTECTION 836 32.3.2 GUARDS 843
32.3.3 VENTILATION 846 32.3.4 LOCKOUT/TAGOUT 847 32.3.5 LAYOUT 848
32.3.6 SENSORS 850
32.4 CONCLUSION 851
REFERENCES 852
33 CONTROL O F AIR POLLUTION 855
TYLER NGUYEN
33.1 INTRODUCTION 855
33.2 HISTORY OF AIR POLLUTION REGULATIONS 856 33.3 BENEFITS OF THE CLEAN
AIR ACT AND AMENDMENTS (CAAA) FROM 1990 TO 2020 857
IMAGE 13
CONTENTS | XVII
33.4 ATMOSPHERIC FACTORS 858 33.4.1 COMPOSITION 858 33.4.2 ATMOSPHERIC
LAYERS 859 33.4.3 EFFECTS OF WEATHER 860 33.5 AIR POLLUTION TYPES,
SOURCES, AND EFFECTS 861 33.5.1 TYPES AND SOURCES O F OUTDOOR POLLUTANTS
863 33.5.2 EFFECTS O F AIR POLLUTION PROBLEMS 867 33.6 INDOOR AIR
QUALITY 870
33.6.1 LEGIONELLA 872 33.6.2 SICK BUILDING SYNDROME 875 33.7 AIR
POLLUTION CONTROL 875
33.7.1 ACID DEPOSITION 876 33.7.2 SMOG 878
33.7.3 GLOBAL WARMING 879 33.7.4 STATIONARY SOURCES 880 33.7.5 CONTROL O
F STATIONARY SOURCES 881 33.7.5.1 PARTICULATE CONTROL 881 33.7.5.2 GAS
CONTROL 883
33.7.6 CONTROL OF MOBILE SOURCES 887 33.8 BEST PRACTICES AND SOLUTIONS
889 33.8.1 TAXATION AND INCENTIVES 891 33.8.2 TAX CREDITS 892 33.8.3
HYBRID CARS 892
33.8.4 HYDROGEN AS FUEL 893 33.9 CONCLUSION 893
ACKNOWLEDGMENTS 893 REFERENCES 893
34 HAZARDOUS WASTE MANAGEMENT AND ENGINEERING 897 DARRYL C. HILL 34.1
INTRODUCTION 897
34.2 IMPACT O F HAZARDOUS WASTE 897 34.3 HAZARDOUS WASTE REGULATION 898
34.4 HAZARDOUS WASTE MANAGEMENT STRATEGIES 899 34.5 HAZARDOUS WASTE
TREATMENT 899
34.6 HAZARDOUS WASTE MINIMIZATION 901 34.7 HAZARDOUS WASTE REMEDIATION
901 34.8 HAZARDOUS WASTE TECHNOLOGIES 903 34.8.1 WASTE EXCHANGE 909
34.9 LIFE-CYCLE ASSESSMENT 910 34.10 CONCLUSION 911 REFERENCES 911
IMAGE 14
X V I I I | CONTENTS
PART VI INCIDENT INVESTIGATION AND ROOT CAUSE ANALYSIS METHODOLOGY
AND MANAGEMENT 913
35 HOW TO CONDUCT EFFECTIVE INCIDENT INVESTIGATIONS 915 KEVIN MCMANUS
35.1 INTRODUCTION 915
35.2 WHAT IS THE PURPOSE OF THE INVESTIGATION? 915 35.3 WHY
INVESTIGATIONS FAIL 917 35.4 THE BASIC INVESTIGATION PROCESS 918 35.5
INVESTIGATION RESOURCE REQUIREMENTS 920 35.6 USING TEAMS TO CONDUCT
INVESTIGATIONS 922 35.7 SOURCES O F EVIDENCE 923 35.8 MINIMIZING THE
EROSION O F EVIDENCE 925 35.9 FINDING THE ROOT CAUSES O F INCIDENTS AND
PROBLEMS 928 35.10 HOW TO DEVELOP EFFECTIVE CORRECTIVE ACTIONS 929 35.11
TIPS FOR IMPROVING AN INVESTIGATION PROCESS 932 35.12 CONCLUSION 934
REFERENCES 934
36 INCIDENT INVESTIGATIONS - LESSONS LEARNED - DEVELOPMENT AND
COMMUNICATIONS 937 DAVID JANNEY 36.1 INTRODUCTION 937
36.2 INTERNAL LESSONS 937
36.3 DISTRIBUTION 938
36.4 EXTERNAL LESSONS 939
36.5 COLLECTION OF DATA 939
36.6 DISSEMINATION O F DATA 940 36.7 INDUSTRY AND DISCIPLINE
PARTICIPATION 940 36.8 REGULATORY ACTIONS AND CHANGES 941 36.9 SUPPLIERS
941
36.10 IN REVIEW 941
36.11 CASE STUDY - LESSONS LEARNED 942 REFERENCES 944
37 MANAGING RECORDS, INVESTIGATION AND RECOMMENDATION MANAGEMENT AND
CLOSURE 947 DAVID JANNEY 37.1 INTRODUCTION 947
37.2 REPORTING 947
37.3 STORAGE AND PROTECTION 948 37.4 RETENTION 948
37.5 CONFIDENTIALITY 951
37.6 LEGAL ISSUES 951
37.7 REGULATORY CONSIDERATIONS 952
IMAGE 15
37.8 TYPES O F RECORDS 952
37.9 RECOMMENDATION MANAGEMENT AND CLOSURE 953 37.10 ESCALATION 953
37.11 CORRECTIVE ACTIONS 955 37.12 IMPLEMENTATION, VERIFICATION, AND
VALIDATION 956 37.13 IN REVIEW 956
REFERENCES 956
PART VII FIRE PROTECTION ENGINEERING 959
38 FIRE DYNAMICS 961
CHRISTOPHER C. VENN 38.1 OVERVIEW 961
38.2 PART A - QUALITATIVE DESCRIPTION OF FIRE DYNAMICS 38.2.1
CHARACTERIZE THE DECISION 962 38.2.2 RESOLVE ACCURACY REQUIRED 963
38.2.3 ESTABLISH THE PERFORMANCE REQUIREMENTS 963 38.2.4 DESIGN THE
PROTECTION 963 38.2.5 ANALYZE THE RESIDUAL RISK 964 38.2.6 STAGES IN A
FIRE ACCIDENT 965 38.2.6.1 IDENTIFY LEAK OPPORTUNITIES 965 38.2.6.2
RELEASE RATE AND PHASE 966
38.2.6.3 IGNITION TIMING AND LOCATION 966 38.2.6.4 FLAMMABILITY 967
38.2.6.5 IGNITION SOURCES 968 38.2.6.6 IGNITION CONTROL 970 38.2.7 FIRE
TYPE 971
38.2.7.1 VAPOR 971 38.2.7.2 TWO PHASE 972 38.2.7.3 LIQUIDS 973 38.2.7.4
SOLIDS 974 38.2.7.5 METALS 974 38.2.8 FIRE GROWTH 975 38.2.9 EXPLOSION
976
38.2.10 FIRE AFTER EXPLOSION 978 38.2.10.1 IDENTIFICATION O F TARGETS O
F INTEREST 978 38.2.11 CONCLUSIONS 981 38.3 PART B: PREDICTIVE METHODS
981 38.3.1 LIQUID RELEASE 981 38.3.2 GAS RELEASE 982 38.3.3 MULTIPHASE
RELEASE 983 38.3.4 PIPELINES 983 38.3.5 DISPERSION MODELING 984 38.3.5.1
EXTERNAL RELEASES 984
38.3.5.2 RELEASE IN AN ENCLOSED AREA 985
IMAGE 16
X X | CONTENTS
38.3.6 GAS BUILD-UP CORRELATIONS 985
38.3.7 FIRE ANALYSIS 986 38.3.7.1 JET FIRE 986 38.3.7.2 FIREBALL 986
38.3.7.3 POOL FIRE 986
38.3.7.4 RADIANT HEAT 988 38.3.7.5 SMOKE 988 38.3.7.6 EXPLOSION 989
38.3.7.7 BLOWOUT 990 38.3.7.8 SUBSEA RELEASES 990 38.3.8 CONCLUSIONS 992
REFERENCES 995 PUBLISHED BOOKS, REPORTS AND PAPERS 995 REGULATORY AND
INDUSTRY BODY PUBLICATIONS 996 ONLINE RESOURCES AND DATABASES 997
39 FIRE PREVENTION AND PROTECTION 999 CRAIG ARTHUR BROWN 39.1
INTRODUCTION 999
39.2 BASIC PRINCIPLES 999
39.2.1 PREVENTION FIRST 1000 39.2.2 PROTECTION 1000 39.3 DESIGN BASICS
1001
39.3.1 DESIGN DEVELOPMENT 1001 39.4 PRACTICAL DESIGN CONSIDERATIONS 1003
39.4.1 FACILITY LAYOUT AND CONSTRUCTION CONSIDERATIONS FOR FIRE SAFETY
1003 39.4.2 LAYOUT OBJECTIVES 1003
39.4.3 LAYOUT AND SPACING 1004 39.4.4 DRAINAGE SYSTEMS 1005 39.4.5
EQUIPMENT SPACING, FIREPROOFING, AND ELECTRICAL CLASSIFICATION 1005
39.4.6 DESIGN FOR LOCAL CONDITIONS 1007
39.4.7 PROTECTION O F CRITICAL EQUIPMENT 1008 39.4.8 PROTECTION FOR
UTILITIES 1009 39.4.9 PLANT EQUIPMENT ACCESS 1009 39.4.10 SECURITY 1009
39.4.11 EVACUATION 1010 39.4.12 BLOCK LAYOUT AND ROADS 1010 39.4.13
RESTRICTED AND UNRESTRICTED ROADS 1011 39.4.14 PROTECTION O F THE PUBLIC
THROUGH SPACING 1011 39.4.15 PLANT-TO-PLANT SPACING 1011 39.4.16
TEMPORARY BUILDINGS 1012 39.5 OIL AND GAS FACILITIES 1014
39.6 NATURAL GAS VEHICLE FUELING STATIONS 1014 39.7 HAZARD VERSUS RISK
1015
39.8 PRACTICAL OPERATIONS CONSIDERATIONS 1016
IMAGE 17
CONTENTS X X I
39.9 FLOATING ROOF TANK OPERATION CONSIDERATIONS 1017
39.10 INVESTIGATING AND REPORTING ON FIRE LOSSES 1019 39.10.1 OVERVIEW
1019 39.10.2 DATA COLLECTION 1019 39.10.3 INVESTIGATION TEAM 1022
39.10.4 TIME LINE 1022 39.10.5 ROOT CAUSE ANALYSIS 1022 39.11 FIRE
REPORTING 1024 39.11.1 IMPORTANCE 1024 39.11.1.1 WHAT FIRES SHOULD BE
REPORTED? 1024 39.11.2 DEFINITIONS 1024 39.11.2.1 REPORTABLE FIRE 1024
39.11.2.2 RECORDABLE FIRE 1025 39.11.3 PREPARATION OF A REPORT 1025
39.11.4 REPORT FORM 1026 39.11.4.1 SOURCES O F FUEL AND OXYGEN 1026
39.11.4.2 SOURCE O F IGNITION 1026 39.11.5 HOW TO ESTIMATE LOSS 1027
39.12 EXAMPLE ROOT CAUSE ANALYSIS REPORT O F FIRE 1028 39.13 FIRE
SUPPRESSION EQUIPMENT 1028 39.13.1 SINGLE FIRE CONCEPT 1028 39.13.2 FIRE
FIGHTING METHODS 1028
39.13.2.1 USE OF WATER AS AN EXTINGUISHING AGENT 1028 39.13.2.2 LAYOUT
AND SIZE 1032 39.13.2.3 BEST PRACTICE CONSIDERATIONS FOR SPRINKLER
SYSTEMS 1032 39.13.2.4 FIRE EXTINGUISHER AND EQUIPMENT INSPECTION AND
MAINTENANCE 1033 39.13.2.5 EXPLOSION SUPPRESSION 1035 39.14 ROLES AND
RESPONSIBILITIES 1036
39.14.1 MANAGERIAL 1036 39.14.2 SUPERVISORY 1036 39.14.2.1 EMPLOYEES
1036 39.15 CONCLUSION 1037
REFERENCES 1037
40 THE SCIENCE AND ENGINEERING O F EXPLOSIONS 1041 DAVID G. LILLEY 40.1
INTRODUCTION 1041
40.2 FUNDAMENTALS O F EXPLOSIONS 1043 40.2.1 BASICS 1043 40.2.2
EXPLOSION CHARACTERIZATION 1046 40.2.3 VAPOR CLOUD EXPLOSIONS 1047
40.3 TYPES OF EXPLOSIONS 1048 40.3.1 DIFFUSE EXPLOSIONS 1048 40.3.2
CONCENTRATED EXPLOSIONS 1048 40.3.3 DIFFERENCES BETWEEN CONCENTRATED AND
DIFFUSE EXPLOSIONS 1049
IMAGE 18
X X I I | CONTENTS
40.3.4 EFFECTS OF AN EXPLOSION 1049
40.4 COMBUSTION AND CHEMISTRY O F EXPLOSIONS 1050 40.4.1 COMBUSTION 1050
40.4.2 EXPLOSIONS, LOWER AND UPPER FLAMMABILITY LIMITS, AND MIXTURES OF
GASES 1051
40.4.3 ESTIMATING FLAMMABILITY LIMITS 1053 40.4.4 ESTIMATING THE
STOICHIOMETRIC CONCENTRATION AND LFL AND UFL FOR A TYPICAL C - H - 0
FUEL 1053 40.5 IGNITION 1055
40.5.1 IGNITION ENERGY 1055 40.5.2 AUTOIGNITION 1056 40.5.3 ADIABATIC
COMPRESSION 1056 40.6 BLAST DAMAGE DUE TO OVER-PRESSURIZATION 1058
40.6.1 BASICS 1058
40.6.2 PROCEDURE FOR ESTIMATING THE OVERPRESSURE AT ANY GIVEN DISTANCE
1058 40.6.2.1 ENGLISH ENGINEERING UNITS 1062 40.6.2.2 SI UNITS 1062 40.7
BLAST FRAGMENT MISSILE DAMAGE 1062 40.7.1 BASICS 1062
40.7.1.1 ENGLISH ENGINEERING UNITS 1063 40.7.1.2 SI UNITS 1063 40.8
EVOLUTION O F FLAMMABLE MATERIAL 1064 40.8.1 BASICS 1064
40.8.2 FLOW O F LIQUID THROUGH A HOLE 1065 40.8.3 FLOW O F VAPOR THROUGH
A HOLE 1066 40.9 DISPERSION AND POSSIBLE IGNITION O F RELEASED MATERIAL
1067 40.9.1 PLUME MODEL 1068 40.9.2 PUFF MODEL 1069
40.9.3 POSSIBLE IGNITION O F RELEASED MATERIAL 1070 40.10 PLUME
DISTRIBUTION CALCULATIONS 1071 40.10.1 PARAMETER EFFECTS 1072 40.11 PUFF
DISTRIBUTION CALCULATIONS 1074 40.11.1 PARAMETER EFFECTS 1076 40.12
CONCLUSION 1076
REFERENCES 1080
INDEX 1083
|
| any_adam_object | 1 |
| author2 | Haight, Joel M. |
| author2_role | edt |
| author2_variant | j m h jm jmh |
| author_GND | (DE-588)1032220406 |
| author_facet | Haight, Joel M. |
| building | Verbundindex |
| bvnumber | BV040974159 |
| ctrlnum | (OCoLC)854696605 (DE-599)DNB1031741747 |
| format | Book |
| fullrecord | <?xml version="1.0" encoding="UTF-8"?><collection xmlns="http://www.loc.gov/MARC21/slim"><record><leader>01097nam a2200301 cc4500</leader><controlfield tag="001">BV040974159</controlfield><controlfield tag="003">DE-604</controlfield><controlfield tag="005">20130522 </controlfield><controlfield tag="007">t</controlfield><controlfield tag="008">130429s2013 gw ad|| |||| 00||| eng d</controlfield><datafield tag="015" ind1=" " ind2=" "><subfield code="a">13,A17</subfield><subfield code="2">dnb</subfield></datafield><datafield tag="016" ind1="7" ind2=" "><subfield code="a">1031741747</subfield><subfield code="2">DE-101</subfield></datafield><datafield tag="035" ind1=" " ind2=" "><subfield code="a">(OCoLC)854696605</subfield></datafield><datafield tag="035" ind1=" " ind2=" "><subfield code="a">(DE-599)DNB1031741747</subfield></datafield><datafield tag="040" ind1=" " ind2=" "><subfield code="a">DE-604</subfield><subfield code="b">ger</subfield><subfield code="e">rakddb</subfield></datafield><datafield tag="041" ind1="0" ind2=" "><subfield code="a">eng</subfield></datafield><datafield tag="044" ind1=" " ind2=" "><subfield code="a">gw</subfield><subfield code="c">XA-DE-BW</subfield></datafield><datafield tag="049" ind1=" " ind2=" "><subfield code="a">DE-83</subfield><subfield code="a">DE-29T</subfield><subfield code="a">DE-92</subfield></datafield><datafield tag="245" ind1="1" ind2="0"><subfield code="a">Handbook of loss prevention engineering</subfield><subfield code="n">2</subfield><subfield code="c">ed. by Joel M. Haight</subfield></datafield><datafield tag="264" ind1=" " ind2="1"><subfield code="a">Weinheim</subfield><subfield code="b">Wiley-VCH</subfield><subfield code="c">2013</subfield></datafield><datafield tag="300" ind1=" " ind2=" "><subfield code="a">XXVI S., S. 463 - 1106</subfield><subfield code="b">Ill., graph. Darst.</subfield><subfield code="c">25 cm</subfield></datafield><datafield tag="336" ind1=" " ind2=" "><subfield code="b">txt</subfield><subfield code="2">rdacontent</subfield></datafield><datafield tag="337" ind1=" " ind2=" "><subfield code="b">n</subfield><subfield code="2">rdamedia</subfield></datafield><datafield tag="338" ind1=" " ind2=" "><subfield code="b">nc</subfield><subfield code="2">rdacarrier</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Haight, Joel M.</subfield><subfield code="0">(DE-588)1032220406</subfield><subfield code="4">edt</subfield></datafield><datafield tag="773" ind1="0" ind2="8"><subfield code="w">(DE-604)BV040974134</subfield><subfield code="g">2</subfield></datafield><datafield tag="856" ind1="4" ind2="2"><subfield code="m">DNB Datenaustausch</subfield><subfield code="q">application/pdf</subfield><subfield code="u">http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=025952295&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA</subfield><subfield code="3">Inhaltsverzeichnis</subfield></datafield><datafield tag="999" ind1=" " ind2=" "><subfield code="a">oai:aleph.bib-bvb.de:BVB01-025952295</subfield></datafield></record></collection> |
| id | DE-604.BV040974159 |
| illustrated | Illustrated |
| indexdate | 2024-07-10T00:36:34Z |
| institution | BVB |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-025952295 |
| oclc_num | 854696605 |
| open_access_boolean | |
| owner | DE-83 DE-29T DE-92 |
| owner_facet | DE-83 DE-29T DE-92 |
| physical | XXVI S., S. 463 - 1106 Ill., graph. Darst. 25 cm |
| publishDate | 2013 |
| publishDateSearch | 2013 |
| publishDateSort | 2013 |
| publisher | Wiley-VCH |
| record_format | marc |
| spelling | Handbook of loss prevention engineering 2 ed. by Joel M. Haight Weinheim Wiley-VCH 2013 XXVI S., S. 463 - 1106 Ill., graph. Darst. 25 cm txt rdacontent n rdamedia nc rdacarrier Haight, Joel M. (DE-588)1032220406 edt (DE-604)BV040974134 2 DNB Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=025952295&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis |
| spellingShingle | Handbook of loss prevention engineering |
| title | Handbook of loss prevention engineering |
| title_auth | Handbook of loss prevention engineering |
| title_exact_search | Handbook of loss prevention engineering |
| title_full | Handbook of loss prevention engineering 2 ed. by Joel M. Haight |
| title_fullStr | Handbook of loss prevention engineering 2 ed. by Joel M. Haight |
| title_full_unstemmed | Handbook of loss prevention engineering 2 ed. by Joel M. Haight |
| title_short | Handbook of loss prevention engineering |
| title_sort | handbook of loss prevention engineering |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=025952295&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
| volume_link | (DE-604)BV040974134 |
| work_keys_str_mv | AT haightjoelm handbookoflosspreventionengineering2 |