Towards building information modelling for existing structures

The transformation of cities from the industrial age (unsustainable) to the knowledge age (sustainable) is essentially a ‘whole life cycle’ process consisting of; planning, development, operation, reuse and renewal. During this transformation, a multi-disciplinary knowledge base, created from studies and research about the built environment aspects is fundamental: historical, architectural, archeologically, environmental, social, economic, etc is critical. Although there are a growing number of applications of 3D VR modelling applications, some built environment applications such as disaster management, environmental simulations, computer aided architectural design and planning require more sophisticated models beyond 3D graphical visualization such as multifunctional, interoperable, intelligent, and multi-representational. Advanced digital mapping technologies such as 3D laser scanner technologies can be are enablers for effective e-planning, consultation and communication of users’ views during the planning, design, construction and lifecycle process of the built environment. For example, the 3D laser scanner enables digital documentation of buildings, sites and physical objects for reconstruction and restoration. It also facilitates the creation of educational resources within the built environment, as well as the reconstruction of the built environment. These technologies can be used to drive the productivity gains by promoting a free-flow of information between departments, divisions, offices, and sites; and between themselves, their contractors and partners when the data captured via those technologies are processed and modelled into BIM (Building Information Modelling). The use of these technologies is key enablers to the creation of new approaches to the ‘Whole Life Cycle’ process within the built and human environment for the 21st century. The paper describes the research towards Building Information Modelling for existing structures via the point cloud data captured by the 3D laser scanner technology. A case study building is elaborated to demonstrate how to produce 3D CAD models and BIM models of existing structures based on designated technique

Building information modelling project decision support framework

Building Information Modelling (BIM) is an information technology [IT] enabled approach to managing design data in the AEC/FM (Architecture, Engineering and Construction/ Facilities Management) industry. BIM enables improved interdisciplinary collaboration across distributed teams, intelligent documentation and information retrieval, greater consistency in building data, better conflict detection and enhanced facilities management. Despite the apparent benefits the adoption of BIM in practice has been slow. Workshops with industry focus groups were conducted to identify the industry needs, concerns and expectations from participants who had implemented BIM or were BIM “ready”. Factors inhibiting BIM adoption include lack of training, low business incentives, perception of lack of rewards, technological concerns, industry fragmentation related to uneven ICT adoption practices, contractual matters and resistance to changing current work practice. Successful BIM usage depends on collective adoption of BIM across the different disciplines and support by the client. The relationship of current work practices to future BIM scenarios was identified as an important strategy as the participants believed that BIM cannot be efficiently used with traditional practices and methods. The key to successful implementation is to explore the extent to which current work practices must change. Currently there is a perception that all work practices and processes must adopt and change for effective usage of BIM. It is acknowledged that new roles and responsibilities are emerging and that different parties will lead BIM on different projects. A contingency based approach to the problem of implementation was taken which relies upon integration of BIM project champion, procurement strategy, team capability analysis, commercial software availability/applicability and phase decision making and event analysis. Organizations need to understand: (a) their own work processes and requirements; (b) the range of BIM applications available in the market and their capabilities (c) the potential benefits of different BIM applications and their roles in different phases of the project lifecycle, and (d) collective supply chain adoption capabilities. A framework is proposed to support organizations selection of BIM usage strategies that meet their project requirements. Case studies are being conducted to develop the framework. The results of the preliminary design management case study is presented for contractor led BIM specific to the design and construct procurement strategy

Lean construction, building information modelling and sustainability

This paper investigates the mutual relations of three current drivers of construction: lean construction, building information modelling and sustainability. These drivers are based on infrequently occurring changes, only incidentally simultaneous, in their respective domains. It is contended that the drivers are mutually supportive and thus synergistic. They are aligned in the sense that all require, promote or enable collaboration. It is argued that these three drivers should be implemented in a unified manner for rapid and robust improvements in construction industry performance and the quality of the constructed facilities and their benefits for stakeholders and wider society

Building information Modelling e Sicurezza

Il Building Information Modelling (BIM) è la capacità di progettare e controllare l’esecuzione della costruzione in un ambiente virtuale computerizzato, tridimensionale e dotato della dimensione temporale (4D), condiviso fra i principali operatori impegnati nel progetto. L’utilizzazione del BIM-4D per la sicurezza può migliorare la pianificazione della costruzione orientata alla sicurezza, fornendo layout di cantiere e piani di sicurezza più comprensibili per tutti gli operatori e può fornire una base per il controllo dell’assetto effettivo del cantiere ed essere il supporto per l’informazione, sia per l’individuazione dei fondamentali rischi presenti nel sito che per l’illustrazione delle relative misure preventive progettate. L’opportunità di utilizzare questa tecnologia per la pianificazione, la comunicazione e il controllo della sicurezza durante le fasi di costruzione è nota, ma all’atto pratico molte sono le problematiche ancora da risolvere, sia in relazione agli aspetti tecnologici/informatici che operativi

Building Information Modelling (BIM) standardization

BIM, short for Building Information Modelling, is a digital tool disrupting the construction industry as a platform for central integrated design, modelling, asset planning running and cooperation. It provides all stakeholders with a digital representation of a building's characteristics in its whole life-cycle and thereby holds out the promise of large efficiency gains. One particular area where standardisation on BIM is needed is the exchange of information between software applications used in the construction industry. The leading organisation in this domain is buldingSMART which has developed and maintains Industry Foundation Classes (IFCs) as a neutral and open specification for BIM data model. Other standardisation work include data dictionaries (International Framework for Dictionaries Libraries) and processes (data delivery manuals). ISO/TC 59/SC 13 "Organization of information about construction works", a subcommittee of the International Organization for Standardization (ISO) on the worldwide and CEN/TC 442 "Building Information Modelling", a technical committee of European Committee for Standardisation (CEN) on the European level develop and maintain standards in the BIM domain. Liaisons with a plethora of different institutions ensure the completeness and inclusiveness of the process as well as the smooth acceptance of adopted standards. Although BIM was originally devised for buildings the benefits such as less rework, fewer errors, enhanced collaboration, and design data that can ultimately be used to support operations, maintenance, and asset management mad it an attractive option also for infrastructure projects. As geographic information system (GIS) is a key element in any infrastructure project there is the need to integrate BIM and GIS. Both technologies use standard and open data formats, but they are different and presently there is no direct translation.JRC.E.4-Safety and Security of Building

Problem-based learning: enhancing students learning of building information modelling

Building Information Modelling (BIM) is an innovative collaborative process underpinned by digital technologies introduced to improve project performance in the Architecture, Engineering and Construction (AEC) industry. Growth in industry demands has necessitated BIM inclusion into the Higher Education (HE) curricula as both a pedagogic and practical objective to prepare and develop aspiring Built Environment (BE) professionals with the required competence for contemporary practice. However, comprehension of BIM concepts and developing the skill set required for its application can be overwhelming for students and crucial to mitigating this challenge is the adoption of appropriate learner-centred strategies. Problem-based Learning (PBL) is becoming a widespread strategy to address such concern. This paper evaluates the impact of PBL strategy on students accelerated learning of BIM based on a case study of an undergraduate BIM module. Findings from the study show PBL benefits on students’ knowledge acquisition (cognitive and affective) of BIM concept and development of transferable skills (academic and disciplinary) equipping them with capabilities to become BIM competent and workplace ready for the AEC industry