BSI PD CEN/TR 18077:2024
$215.11
Building information modelling. Digital twins applied to the built environment. Use cases
| Published By | Publication Date | Number of Pages |
| BSI | 2024 | 92 |
This document collates case studies of digital twins applied to the built environment, including infrastructures, in Europe. These case studies have been obtained from CEN experts and related EU research projects. This document identifies common characteristics to support further standardization work.
PDF Catalog
| PDF Pages | PDF Title |
|---|---|
| 2 | undefined |
| 7 | 1 Scope 2 Normative references 3 Terms and definitions 4 Abbreviations |
| 9 | 5 Objective 6 Methodology 6.1 Introduction 6.2 Table of compiled case studies |
| 12 | 7 Conclusions |
| 14 | Annex A (informative)Case study template |
| 15 | Annex B (informative)Case studies presented B.1 Case Study 1: D2EPC THESS. D^2EPC- BIM based DT- nZEB Smarthome DIH B.1.1 General information B.1.2 Main use of the DT B.1.3 Description of the DT |
| 16 | B.1.4 Main improvements beyond the state of the art B.1.5 Replication potential B.1.6 Relevant documents and links B.2 Case Study 2: D2EPC NICOSIA. Mixed-use University building, Nicosia, Cyprus B.2.1 General information B.2.2 Main use of the DT B.2.3 Description of the DT |
| 17 | B.2.4 Main improvements beyond the state of the art |
| 18 | B.2.5 Replication potential B.2.6 Relevant documents and links B.3 Case Study 3: PLANON DT. SMART CLIMATIZED ASSET/SPACE MANAGEMENT B.3.1 Description of the DT |
| 19 | B.3.2 Business value B.3.3 Key features |
| 21 | B.3.4 Replication potential B.3.5 Relevant documents and links B.4 Case Study 4: SAMBA. SAMBA Smart Advanced Multitenant Building Automation – DT for occupants and manager B.4.1 General information B.4.2 Main use of the DT |
| 22 | B.4.3 Description of the DT |
| 24 | B.4.4 Main improvements beyond the state of the art B.4.5 Replication potential B.4.6 Relevant documents and links B.5 Case Study 5: H2 ELECTRO. H2Energy Electrolyser – DT for technical marketing B.5.1 General information |
| 25 | B.5.2 Main use of the DT B.5.3 Description of the DT B.5.4 Main improvements beyond the state of the art B.5.5 Replication potential |
| 26 | B.5.6 Relevant documents and links B.6 Case Study 6: BRIDGE WEBGL. Bridge DT for technical marketing maintenance oriented B.6.1 General information B.6.2 Main use of the DT B.6.3 Description of the DT |
| 27 | B.6.4 Main improvements beyond the state of the art B.6.5 Replication potential |
| 28 | B.7 Case Study 8: CRANE. Real-time Discrete Event Simulation of Crane operations (HORIZON 2020 – NUMBER 958161 – Ashvin “Assistants for Healthy, Safe, and Productive Virtual Construction Design, Operation & Maintenance using a Digital Twin”) B.7.1 General information B.7.2 Main use of the DT B.7.3 Description of the DT |
| 29 | B.7.4 Main improvements beyond the state of the art B.7.5 Replication potential B.7.6 Relevant documents and links B.8 Case Study 9: KUBIK. KUBIK 4.0 DIGITAL TWIN B.8.1 General information |
| 30 | B.8.2 Main use of the DT B.8.3 Description of the DT |
| 31 | B.8.4 Main improvements beyond the state of the art |
| 32 | B.8.5 Replication potential B.8.6 Relevant documents and links B.9 Case study 10: BRIDGE ZUBIOTE. Steel Girder Rail Bridge: Pilot Case of Research Project ZUBIOT (Funded by SPRI – Hazitek Programme with Project Ref. Zl-2020/00902) B.9.1 General information B.9.2 Main use of the DT B.9.3 Description of the DT |
| 33 | B.9.4 Main improvements beyond the state of the art B.9.5 Replication potential |
| 34 | B.9.6 Relevant documents and links B.10 Case Study 13: BIM2TWIN. Digital Twin of Construction Execution B.10.1 General information B.10.2 Main use of the DT B.10.3 Description of the DT |
| 35 | B.10.4 Main improvements beyond the state of the art B.10.5 Replication potential B.10.6 Relevant documents and links |
| 36 | B.11 Case Study 14: ENERGY_TWIN. Digital Twins for commissioning of technical systems in building structures and energetic system optimization B.11.1 General information B.11.2 Main use of the DT B.11.3 Description of the DT |
| 37 | B.11.4 Main improvements beyond the state of the art B.11.5 Replication potential B.11.6 Relevant documents and links |
| 38 | B.12 Case study 15: BRIDGE BASt. FE 15.0677/2020/IRB – Conceptual investigation for the combination of components of the Digital Twin Bridge B.12.1 General information B.12.2 Main use of the DT B.12.3 Description of the DT |
| 40 | B.12.4 Main improvements beyond the state of the art B.12.5 Replication potential B.12.6 Relevant documents and links |
| 41 | B.13 Case Study 16: ROAD INFRA. Digital Twin of the Road for Pavement Management B.13.1 General information B.13.2 Main use of the DT B.13.3 Description of the DT |
| 42 | B.13.4 Main improvements beyond the state of the art |
| 43 | B.13.5 Replication potential B.13.6 Relevant documents and links B.14 Case Study 17: BRIDGE ROAD INFRA (HORIZON 2020 – NUMBER 958161 – Ashvin “Assistants for Healthy, Safe, and Productive Virtual Construction Design, Operation & Maintenance using a Digital Twin”) B.14.1 General information B.14.2 Main use of the DT |
| 44 | B.14.3 Description of the DT B.14.4 Main improvements beyond the state of the art |
| 45 | B.14.5 Replication potential B.14.6 Relevant documents and links |
| 46 | B.15 Case Study 18: BUILDING OFFICE (HORIZON 2020 – NUMBER 958161 – Ashvin “Assistants for Healthy, Safe, and Productive Virtual Construction Design, Operation & Maintenance using a Digital Twin”) B.15.1 General information B.15.2 Main use of the DT B.15.3 Description of the DT |
| 47 | B.15.4 Main improvements beyond the state of the art |
| 48 | B.15.5 Replication potential |
| 49 | B.15.6 Relevant documents and links B.16 Case Study 19: BRIDGE RAIL INFRA (HORIZON 2020 – NUMBER 958161 – Ashvin “Assistants for Healthy, Safe, and Productive Virtual Construction Design, Operation & Maintenance using a Digital Twin”) B.16.1 General information B.16.2 Main use of the DT |
| 50 | B.16.3 Description of the DT B.16.4 Main improvements beyond the state of the art |
| 51 | B.16.5 Replication potential B.16.6 Relevant documents and links |
| 52 | B.17 Case Study 20: SNCF. France rail infrastructure B.17.1 Description of the DT B.17.2 Replication potential B.17.3 Relevant documents and links |
| 53 | B.18 Case Study 21: ZADAR. Planning and optimization of maintenance activities on airports using unmanned aerial vehicles (UAVs) (HORIZON 2020 – NUMBER 958161 – Ashvin “Assistants for Healthy, Safe, and Productive Virtual Construction Design, Operation & Maintenance using a Digitial Twin”) B.18.1 General information B.18.2 Main use of the DT B.18.3 Description of the DT B.18.4 Main improvements beyond the state of the art |
| 54 | B.18.5 Replication potential B.18.6 Relevant documents and links B.19 Case Study 22: AVILES PORT. DIGITAL TWIN FOR SEA PORTS (SMART AND CONNECTED) B.19.1 General information B.19.2 Main use of the DT |
| 55 | B.19.3 Description of the DT B.19.4 Main improvements beyond the state of the art |
| 56 | B.19.5 Replication potential |
| 57 | B.19.6 Relevant documents and links B.20 Case Study 23: SETEC-StMALO. DIGITAL TWIN FOR DIAGNOSIS AND EVALUATION OF THE SAINT MALO PORT JETTY B.20.1 General information B.20.2 Main use of the DT B.20.3 Description of the DT |
| 58 | B.20.4 Main improvements beyond the state of the art B.20.5 Replication potential B.20.6 Relevant documents and links B.21 Case Study 24: LEGENDRE B.21.1 General information B.21.2 Main use of the DT B.21.3 Description of the DT |
| 59 | B.21.4 Main improvements beyond the state of the art |
| 60 | B.21.5 Replication potential B.21.6 Relevant documents and links |
| 61 | B.22 Case Study 25: ETSICCP. Intelligent Management platform for Digital Twin of the Civil Engineering School of the Universidad Politécnica de Madrid B.22.1 General information B.22.2 Main use of the DT B.22.3 Description of the DT |
| 62 | B.22.4 Main improvements beyond the state of the art B.22.5 Replication potential |
| 63 | B.22.6 Relevant documents and links B.23 Case Study 26: IRRIGATION. Smart Irrigation Management B.23.1 General information B.23.2 Main use of the DT B.23.3 Description of the DT |
| 64 | B.23.4 Main improvements beyond the state of the art |
| 65 | B.23.5 Replication potential B.23.6 Relevant documents and links B.24 Case Study 27: LLOBREGAT. DT Sant Feliu de Llobregat B.24.1 General information B.24.2 Main use of the DT |
| 66 | B.24.3 Description of the DT |
| 67 | B.24.4 Main improvements beyond the state of the art B.24.5 Replication potential B.24.6 Relevant documents and links B.25 Case Study 28: HIDROPOWER. Powerplant Rabenstein (AUSTRIA) B.25.1 General information |
| 68 | B.25.2 Main use of the DT B.25.3 Description of the DT B.25.4 Main improvements beyond the state of the art |
| 69 | B.25.5 Replication potential |
| 70 | B.25.6 Relevant documents and links B.26 Case Study 29: NUCLEAR_DECOMM. Nuclear Decommissioning B.26.1 General information B.26.2 Main use of the DT |
| 71 | B.26.3 Description of the DT B.26.4 Main improvements beyond the state of the art B.26.5 Replication potential B.27 Case Study 30: ST_ETIENNE. Academic Building (Mines Saint Étienne, Institut Mines Télécom) B.27.1 General information |
| 72 | B.27.2 Main use of the DT B.27.3 Description of the DT |
| 73 | B.27.4 Main improvements beyond the state of the art B.27.5 Replication potential B.27.6 Relevant documents and links B.28 Case Study 31: ECOLE CENTRALE. AS-BUILT ASSET VISUALIZATION B.28.1 General information B.28.2 Main use of the DT B.28.3 Description of the DT |
| 74 | B.28.4 Main improvements beyond the state of the art B.28.5 Replication potential B.28.6 Relevant documents and links |
| 75 | B.29 Case Study 32: LILLE. AS-BUILT ASSET VISUALIZATION B.29.1 General information B.29.2 Main use of the DT B.29.3 Description of the DT B.29.4 Main improvements beyond the state of the art |
| 76 | B.29.5 Replication potential B.29.6 Relevant documents and links B.30 Case Study 33: TNO SPHERE. PREDICTIVE TWINS Apartment complex (SPHERE EU project, funded from the European Union’s H2020 programme under Grant Agreement No. 820805). B.30.1 General information B.30.2 Main use of the DT B.30.3 Description of the DT |
| 78 | B.30.4 Main improvements beyond the state of the art B.30.5 Replication potential B.30.6 Relevant documents and links B.31 Case Study 34: VTT. ABLOY FACTORY (SPHERE EU project, funded from the European Union’s H2020 programme under Grant Agreement No. 820805). B.31.1 General information B.31.2 Main use of the DT |
| 79 | B.31.3 Description of the DT |
| 81 | B.31.4 Main improvements beyond the state of the art |
| 82 | B.31.5 Replication potential B.31.6 Relevant documents and links B.32 Case Study 35: EGIS. GIROS: DIGITAL TWINS OF THE GIRONDE ESTUARY B.32.1 General information B.32.2 Main use of the DT B.32.3 Description of the DT |
| 84 | B.32.4 Main improvements beyond the state of the art B.32.5 Replication potential B.32.6 Relevant documents and links |
| 85 | B.33 Case Study 36: ANDRA B.33.1 General information B.33.2 Main use of the DT B.33.3 Description of the DT |
| 87 | B.33.4 Main improvements beyond the state of the art B.33.5 Replication potential B.33.6 Relevant documents and links |
| 88 | B.34 Case Study 37: VSB-TUO B.34.1 General information B.34.2 Main use of the DT B.34.3 Description of the DT |
| 90 | B.34.4 Main improvements beyond the state of the art B.34.5 Replication potential B.34.6 Relevant documents and links |
