BSI PD IEC TR 63283-2:2022
$215.11
Industrial-process measurement, control and automation. Smart manufacturing – Use cases
| Published By | Publication Date | Number of Pages |
| BSI | 2022 | 170 |
PDF Catalog
| PDF Pages | PDF Title |
|---|---|
| 2 | undefined |
| 6 | CONTENTS |
| 11 | FOREWORD |
| 13 | INTRODUCTION Figures Figure 1 – Related subjects to Smart Manufacturing |
| 15 | 1 Scope 2 Normative references 3 Terms and definitions 3.1 General 3.2 General terms and definitions |
| 17 | 3.3 Business roles |
| 18 | 3.4 Human roles |
| 20 | 3.5 Technical roles acting as object only |
| 22 | 3.6 Technical roles acting as subject or object |
| 25 | 4 Abbreviated terms and acronyms Table 1 – Abbreviated terms and acronyms |
| 26 | Figure 2 – Overall structure of use cases 5 Conventions 5.1 General 5.2 Description of use cases |
| 27 | Figure 3 – Value added processes within a manufacturing company 5.3 Selection guidance for elaborated use cases 5.4 Reference frame for use cases |
| 28 | Figure 4 – Example for value added processes across different companies 5.5 Clustering of use cases |
| 29 | Figure 5 – Illustration of the use case cluster 5.6 Developing additional use cases 6 Use cases 6.1 Use case cluster “Order-controlled production” 6.1.1 Manufacturing of individualized products |
| 30 | Figure 6 – Business context of “Manufacturing of individualized products” |
| 31 | Figure 7 – Technical perspective of “Manufacturing of individualized products” |
| 33 | 6.1.2 Flexible scheduling and resource allocation |
| 34 | Figure 8 – Business context of “Flexible scheduling and resource allocation” Figure 9 – Technical perspective of “Flexible scheduling and resource allocation” |
| 36 | Figure 10 – Business context of “Outsourcing of production” 6.1.3 Outsourcing of production |
| 37 | Figure 11 – Technical perspective of “Outsourcing of production” |
| 39 | 6.1.4 Engineering of design for manufacturing and request/order management |
| 40 | Figure 12 – Business context of “Engineering of design for manufacturing and request/order management” Figure 13 – Technical perspective of “Engineering of design for manufacturing and request/order management” |
| 42 | 6.1.5 Intra-facility logistics |
| 43 | Figure 14 – Business context of “Intra-facility logistics” Figure 15 – Technical perspective of “Intra-facility logistics” |
| 44 | 6.1.6 Decision support for product configuration |
| 45 | Figure 16 – Business context of “Decision support for product configuration” Figure 17 – Technical perspective of “Decision support for product configuration” |
| 46 | 6.2 Use case cluster “Adaptable factory” 6.2.1 Modularization of production systems |
| 47 | Figure 18 – Business context of “Modularization of production systems” Figure 19 – Technical perspective of “Modularization of production systems” |
| 50 | 6.2.2 Reconfiguration of adaptable production systems |
| 51 | Figure 20 – Business context of “Reconfiguration of adaptable production systems” Figure 21 – Technical perspective of “Reconfiguration of adaptable production systems” |
| 52 | 6.2.3 Migration to adaptable production systems |
| 53 | Figure 22 – Business context of “Migration to adaptable production systems” |
| 54 | Figure 23 – Technical perspective of “Migration to adaptable production systems” |
| 55 | 6.2.4 Standardization of production technologies |
| 56 | Figure 24 – Business context of “Standardization of production technologies” Figure 25 – Technical perspective of “Standardization of production technologies” |
| 58 | 6.2.5 Adaptable robot cells |
| 59 | Figure 26 – Business context of “Adaptable robot cells” |
| 60 | Figure 27 – Technical perspective of “Adaptable robot cells” |
| 61 | 6.3 Use case cluster “Management of assets” 6.3.1 Administration of assets |
| 62 | Figure 28 – Business context of “Administration of assets” Figure 29 – Technical perspective of “Administration of assets” |
| 64 | 6.3.2 Virtual representation of physical assets |
| 65 | Figure 30 – Business context of “Virtual representation of physical assets” |
| 66 | Figure 31 – Technical perspective of “Virtual representation of physical assets” |
| 67 | 6.3.3 Feedback loops |
| 68 | Figure 32 – Business context of “Feedback loops” |
| 69 | Figure 33 – Technical perspective of “Feedback loops” |
| 70 | 6.3.4 Update and functional scalability of production resources |
| 71 | Figure 34 – Business context of “Update and functional scalability of production resources” Figure 35 – Technical perspective of “Update and functional scalability of production resources” |
| 72 | 6.3.5 Condition monitoring of production resources |
| 73 | Figure 36 – Business context of “Condition monitoring of production resources” |
| 74 | Figure 37 – Technical perspective of “Condition monitoring of production resources” |
| 75 | 6.3.6 Self-optimization of production resources |
| 76 | Figure 38 – Business context of “Self-optimization of production resources” Figure 39 – Technical perspective of “Self-optimization of production resources” |
| 77 | 6.4 Use case cluster “Optimization of production execution” 6.4.1 Optimization of operations |
| 78 | Figure 40 – Business context of “Optimization of operations” |
| 79 | Figure 41 – Technical perspective of “Optimization of operations” |
| 80 | 6.4.2 Simulation in operation |
| 81 | Figure 42 – Business context of “Simulation in operation” Figure 43 – Technical perspective of “Simulation in operation” |
| 82 | 6.4.3 Optimization of operation through machine learning |
| 83 | Figure 44 – Business context of “Optimization of operation through machine learning” |
| 84 | Figure 45 – Technical perspective of “Optimization of operation through machine learning” |
| 85 | 6.4.4 Service workflow management for production systems |
| 86 | Figure 46 – Business context of “Service workflow management for production systems” |
| 87 | Figure 47 – Technical perspective of “Service workflow management for production systems” |
| 88 | 6.4.5 Successive improvement of production systems |
| 89 | Figure 48 – Business context of “Successive improvement of production systems” Figure 49 – Technical perspective of “Successive improvement of production systems” |
| 91 | 6.5 Use case cluster “Energy efficiency” 6.5.1 Design for energy efficiency |
| 92 | Figure 50 – Business context of “Design for energy efficiency” Figure 51 – Technical perspective of “Design for energy efficiency” |
| 93 | 6.5.2 Optimization of energy |
| 94 | Figure 52 – Business context of “Optimization of energy” |
| 95 | Figure 53 – Technical perspective of “Optimization of energy” |
| 96 | 6.5.3 Design for participation in decentralized energy networks |
| 97 | Figure 54 – Business context of “Design for participation in decentralized energy networks” Figure 55 – Technical perspective of “Design for participation in decentralized energy networks” |
| 98 | 6.5.4 Participation in decentralized energy networks |
| 99 | Figure 56 – Business context of “Participation in decentralized energy networks” Figure 57 – Technical perspective of “Participation in decentralized energy networks” |
| 100 | 6.6 Use case cluster “Design and engineering” 6.6.1 Seamless models |
| 101 | Figure 58 – Business context of “Seamless models” |
| 102 | Figure 59 – Technical perspective of “Seamless models” |
| 103 | 6.6.2 Simulation in design and engineering |
| 105 | Figure 60 – Business context of “Simulation in design and engineering” |
| 106 | Figure 61 – Technical perspective of “Simulation in design and engineering” |
| 107 | 6.6.3 Virtual commissioning of production systems |
| 108 | Figure 62 – Business context of “Virtual commissioning of production systems” |
| 109 | Figure 63 – Technical perspective of “Virtual commissioning of production systems” |
| 110 | 6.6.4 Optimization in design and engineering through machine learning |
| 111 | Figure 64 – Business context of “Optimization in design and engineering through machine learning” Figure 65 – Technical perspective of “Optimization in design and engineering through machine learning” |
| 112 | 6.6.5 Immersive training of production system personnel |
| 113 | Figure 66 – Business context of “Immersive training of production system personnel” |
| 114 | Figure 67 – Technical perspective of “Immersive training of production system personnel” |
| 115 | 6.6.6 Co-creation in design |
| 116 | Figure 68 – Business context of “Co-creation in design” |
| 117 | Figure 69 – Technical perspective of “Co-creation in design” |
| 118 | 6.7 Use case cluster “Product and production services” 6.7.1 Value-based services for production resources |
| 120 | Figure 70 – Business context of “Value-based services for production resources” Figure 71 – Technical perspective of “Value-based services for production resources” |
| 122 | 6.7.2 Benchmarking of production resources |
| 123 | Figure 72 – Business context of “Benchmarking of production resources” Figure 73 – Technical perspective of “Benchmarking of production resources” |
| 124 | 6.7.3 Production resource as-a-service |
| 125 | Figure 74 – Business context of “Production resource as-a-service” |
| 126 | Figure 75 – Technical perspective of “Production resource as-a-service” |
| 127 | 6.8 Use case cluster “IT-infrastructure and software” 6.8.1 Device configuration |
| 128 | Figure 76 – Business context of “Device configuration” Figure 77 – Technical perspective of “Device configuration” |
| 130 | 6.8.2 Information extraction from production systems |
| 131 | Figure 78 – Business context of “Information extraction from production systems” Figure 79 – Technical perspective of “Information extraction from production systems” |
| 132 | 6.8.3 Rule-driven software applications |
| 134 | Figure 80 – Business context of “Rule-driven software applications” Figure 81 – Technical perspective of “Rule-driven software applications” |
| 135 | 6.8.4 Integration of engineering-tools |
| 136 | Figure 82 – Business context of “Integration of engineering-tools” |
| 137 | Figure 83 – Technical perspective of “Integration of engineering-tools” |
| 138 | 6.8.5 Human-machine interface |
| 140 | Figure 84 – Business context of “Human-machine interface” Figure 85 – Technical perspective of “Human-machine interface” |
| 141 | 6.8.6 Cyber security infrastructure and setup |
| 142 | Figure 86 – Business context of “Cyber security infrastructure and setup” |
| 143 | Figure 87 – Technical perspective of “Cyber security infrastructure and setup” |
| 145 | 6.8.7 Cyber security management and maintenance |
| 146 | Figure 88 – Business context of “Cyber security management and maintenance” Figure 89 – Technical perspective of “Cyber security management and maintenance” |
| 148 | 6.8.8 Engineering for cyber security |
| 149 | Figure 90 – Business context of “Engineering for cyber security” Figure 91 – Technical perspective of “Engineering for cyber security” |
| 150 | 6.8.9 Support for tactical and strategic decision making |
| 151 | Figure 92 – Business context of “Support for tactical and strategic decision making” Figure 93 – Technical perspective of “Support for tactical and strategic decision making” |
| 153 | 6.8.10 Additive manufacturing |
| 154 | Figure 94 – Business context of “Additive manufacturing” |
| 155 | Figure 95 – Technical perspective of “Additive manufacturing” |
| 157 | Annex A (informative)Use case template |
| 158 | Annex B (informative)General understanding of use cases |
| 159 | Figure B.1 – Classification of use cases in terms of IIRA Figure B.2 – Relation between selected templates for use cases |
| 160 | Annex C (informative)Relation to use cases in the draft elaboration Table C.1 – Use cases in the draft elaboration |
| 162 | Annex D (informative)Additional draft use cases D.1 General D.2 Inter-facility logistics D.2.1 Objective D.2.2 Overview |
| 163 | Figure D.1 – Business context of “Inter-facility logistics” D.2.3 Business context D.2.4 Technical perspective D.2.5 Interaction of roles D.2.6 Expected change and impact D.2.7 Recommendations for standardization |
| 164 | D.3 Safety setup and management |
| 165 | Bibliography |
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