Beschreibung
Inhaltsangabe1. Overview.- 1.1. Abstract. 1.2. Structure of the Book. 1.3. Problem Statement. 1.4. Safety Management. 1.5. Benefits to Business. 1.6. Research Significance. 2. Background.- 2.1. Industrial Practices. 2.2. Literature Review. 2.3. Commercial Products for Computer-Aided Safety Engineering. 3. Theoretical & Methodological Framework.- 3.1. Research Approach. 3.2. Object-Oriented Modeling Framework. 3.3. Plant Lifecycle OO Model Representation. 3.4. Plant Safety Model. 3.5. Fault Propagation Modeling. 4. Plant Enterprise Engineering Environment (PEEE).- 4.1. PEEE Functional Analysis. 4.2. Information Technology Infrastructure. 4.3. PEEE System Architecture. 4.4. PEEE Components. 4.5. CAPE-PSP. 5. Plant Modeling Environment (CAPE-ModE).- 5.1. CAPE-ModE Functional Analysis. 5.2. CAPE-ModE System Architecture. 5.3. CAPE-Mode Design Specifications. 5.4. Model Representation within CAPE-ModE. 5.4.1. UML Formal Definition Initiatives. 5.5. Mechanism. 5.6. Prototype CAPE-ModE. 6. Analysis of CAPE-SAFE.- 6.1. Object-Oriented Analysis Methodology. 6.2. Business Profile 'As Is'. 6.3. Business Enterprise Directions 'To Be'. 6.4. Requirements Analysis. 6.5. Safety Solution Challenges. 6.6. Process Threads. 6.7. Business Process Chart Diagrams. 6.8. Safety Design. 7. CAPE-SAFE Design.- 7.1. CAPE-SAFE Components. 7.2. CAPE-SAFE Integration in PEEE. 7.3. CAPE-SAFE Implementation within PEEE. 7.4. CAPE-SAFE Prototype System Development. 7.5. CAPE-SAFE Function Decomposition. 7.6. Positioning with CAPE-OPEN. 8. Mechanism.- 8.1. Safety Data Management. 8.2. Physical Data Model Specifications. 8.3. Automated Hazard Evaluation Results Structuring. 8.4. Safety Regulations. 8.5. Safety Procedures. 8.6. Safety Training. 9. Case Studies.- 9.1. Examples from HDS Plant. 9.2. Cause - Consequence Analysis of Reactor CGU using CAPE-SAFE.9.3. Examples from PVC Plant. 9.4. Examples from Oil Refinery. 9.5. CAPE-SAFE Utilization with Operator Interface System. 9.6. CAPE-SAFE Utilization with Plant Design Model. 9.7. CAPE-SAFE Utilization with Fault Detection System. 9.8. CAPE-SAFE Utilization with RCM-Based CMMS. 10. Discussion.- 11. Conclusion.- 12. Recommendations and Future Research.- References.- Appendices.- Appendix (1) Highlights on UML Standards from OMG. Appendix (2) Study on Middleware Technology. Appendix (3) Physical Data Model of CAPE-SAFE. Appendix (4) Java Source Code of PEEE. Appendix (5) Cause/Consequence Scenarios of Reactor Unit in HDS Plant.-Appendix (6) Useful Web Links. Appendix (7) Molecular Modeling Impact on CAPE-SAFE. Appendix (8) Manufacturing Process Modeling
Autorenportrait
Inhaltsangabe1. Overview.- 1.1. Abstract. 1.2. Structure of the Book. 1.3. Problem Statement. 1.4. Safety Management. 1.5. Benefits to Business. 1.6. Research Significance. 2. Background.- 2.1. Industrial Practices. 2.2. Literature Review. 2.3. Commercial Products for Computer-Aided Safety Engineering. 3. Theoretical & Methodological Framework.- 3.1. Research Approach. 3.2. Object-Oriented Modeling Framework. 3.3. Plant Lifecycle OO Model Representation. 3.4. Plant Safety Model. 3.5. Fault Propagation Modeling. 4. Plant Enterprise Engineering Environment (PEEE).- 4.1. PEEE Functional Analysis. 4.2. Information Technology Infrastructure. 4.3. PEEE System Architecture. 4.4. PEEE Components. 4.5. CAPE-PSP. 5. Plant Modeling Environment (CAPE-ModE).- 5.1. CAPE-ModE Functional Analysis. 5.2. CAPE-ModE System Architecture. 5.3. CAPE-Mode Design Specifications. 5.4. Model Representation within CAPE-ModE. 5.4.1. UML Formal Definition Initiatives. 5.5. Mechanism. 5.6. Prototype CAPE-ModE. 6. Analysis of CAPE-SAFE.- 6.1. Object-Oriented Analysis Methodology. 6.2. Business Profile 'As Is'. 6.3. Business Enterprise Directions 'To Be'. 6.4. Requirements Analysis. 6.5. Safety Solution Challenges. 6.6. Process Threads. 6.7. Business Process Chart Diagrams. 6.8. Safety Design. 7. CAPE-SAFE Design.- 7.1. CAPE-SAFE Components. 7.2. CAPE-SAFE Integration in PEEE. 7.3. CAPE-SAFE Implementation within PEEE. 7.4. CAPE-SAFE Prototype System Development. 7.5. CAPE-SAFE Function Decomposition. 7.6. Positioning with CAPE-OPEN. 8. Mechanism.- 8.1. Safety Data Management. 8.2. Physical Data Model Specifications. 8.3. Automated Hazard Evaluation Results Structuring. 8.4. Safety Regulations. 8.5. Safety Procedures. 8.6. Safety Training. 9. Case Studies.- 9.1. Examples from HDS Plant. 9.2. Cause - Consequence Analysis of Reactor CGU using CAPE-SAFE.9.3. Examples from PVC Plant. 9.4. Examples from Oil Refinery. 9.5. CAPE-SAFE Utilization with Operator Interface System. 9.6. CAPE-SAFE Utilization with Plant Design Model. 9.7. CAPE-SAFE Utilization with Fault Detection System. 9.8. CAPE-SAFE Utilization with RCM-Based CMMS. 10. Discussion.- 11. Conclusion.- 12. Recommendations and Future Research.- References.- Appendices.- Appendix (1) Highlights on UML Standards from OMG. Appendix (2) Study on Middleware Technology. Appendix (3) Physical Data Model of CAPE-SAFE. Appendix (4) Java Source Code of PEEE. Appendix (5) Cause/Consequence Scenarios of Reactor Unit in HDS Plant.-Appendix (6) Useful Web Links. Appendix (7) Molecular Modeling Impact on CAPE-SAFE. Appendix (8) Manufacturing Process Modeling
