Academic literature on the topic 'BIM (Building Information Model)'
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Journal articles on the topic "BIM (Building Information Model)":
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Bastos Porsani, Gabriela, Kattalin Del Valle de Lersundi, Ana Sánchez-Ostiz Gutiérrez, and Carlos Fernández Bandera. "Interoperability between Building Information Modelling (BIM) and Building Energy Model (BEM)." Applied Sciences 11, no. 5 (March 1, 2021): 2167. http://dx.doi.org/10.3390/app11052167.
Abstract:
Building information modelling (BIM) is the first step towards the implementation of the industrial revolution 4.0, in which virtual reality and digital twins are key elements. At present, buildings are responsible for 40% of the energy consumption in Europe and, so, there is a growing interest in reducing their energy use. In this context, proper interoperability between BIM and building energy model (BEM) is paramount for integrating the digital world into the construction sector and, therefore, increasing competitiveness by saving costs. This paper evaluates whether there is an automated or semi-automated BIM to BEM workflow that could improve the building design process. For this purpose, a residential building and a warehouse are constructed using the same BIM authoring tool (Revit), where two open schemas were used: green building extensible markup language (gbXML) and industry foundation classes (IFC). These transfer files were imported into software compatible with the EnergyPlus engine—Design Builder, Open Studio, and CYPETHERM HE—in which simulations were performed. Our results showed that the energy models were built up to 7.50% smaller than in the BIM and with missing elements in their thermal envelope. Nevertheless, the materials were properly transferred to gbXML and IFC formats. Moreover, the simulation results revealed a huge difference in values between the models generated by the open schemas, in the range of 6 to 900 times. Overall, we conclude that there exists a semi-automated workflow from BIM to BEM which does not work well for big and complex buildings, as they present major problems when creating the energy model. Furthermore, most of the issues encountered in BEM were errors in the transfer of BIM data to gbXML and IFC files. Therefore, we emphasise the need to improve compatibility between BIM and model exchange formats by their developers, in order to promote BIM–BEM interoperability.
2
Jeong, WoonSeong, Jong Bum Kim, Mark J. Clayton, Jeff S. Haberl, and Wei Yan. "Translating Building Information Modeling to Building Energy Modeling Using Model View Definition." Scientific World Journal 2014 (2014): 1–21. http://dx.doi.org/10.1155/2014/638276.
Abstract:
This paper presents a new approach to translate between Building Information Modeling (BIM) and Building Energy Modeling (BEM) that uses Modelica, an object-oriented declarative, equation-based simulation environment. The approach (BIM2BEM) has been developed using a data modeling method to enable seamless model translations of building geometry, materials, and topology. Using data modeling, we created a Model View Definition (MVD) consisting of a process model and a class diagram. The process model demonstrates object-mapping between BIM and Modelica-based BEM (ModelicaBEM) and facilitates the definition of required information during model translations. The class diagram represents the information and object relationships to produce a class package intermediate between the BIM and BEM. The implementation of the intermediate class package enables system interface (Revit2Modelica) development for automatic BIM data translation intoModelicaBEM. In order to demonstrate and validate our approach, simulation result comparisons have been conducted via three test cases using (1) the BIM-based Modelica models generated fromRevit2Modelicaand (2) BEM models manually created using LBNL Modelica Buildings library. Our implementation shows thatBIM2BEM(1) enables BIM models to be translated intoModelicaBEMmodels, (2) enables system interface development based on the MVD for thermal simulation, and (3) facilitates the reuse of original BIM data into building energy simulation without an import/export process.
3
Pérez-Andreu, Víctor, Antonio Adán Oliver, Carolina Aparicio-Fernández, and José-Luis Vivancos Bono. "Thermal Characterization of Buildings with as-is Thermal-Building Information Modelling." Buildings 13, no. 4 (April 6, 2023): 972. http://dx.doi.org/10.3390/buildings13040972.
Abstract:
Developing methodologies to accurately characterise the energy conditions of existing building stock is a fundamental aspect of energy consumption reduction strategies. To that end, a case study using a thermal information modelling method for existing buildings (as-is T-BIM) is reported. This proposed new method is based on the automatic processing of 3D thermal clouds of interior zones of a building that generates a semantic proprietary model that contains time series of surface temperatures assigned to its surface elements. The proprietary as-is T-BIM automatically generates an as-is BEM model with gbXML standards for energy simulation. This is a multi-zone energy model of the building. In addition, the surface temperature data series of the as-is T-BIM model elements permit the calculation of their thermal transmittances, increasing the calibration options of the obtained as-is BEM model. To test the as-is TBIM method, a case study compares the as-is BEM model obtained by as-is T-BIM methods with the one obtained by standard methods for the same building. The results demonstrate differences in geometry, transmittance, and infiltration values, as well as insignificant differences in annual air conditioning energy consumption or the comfort parameters tested. This seems to indicate shorter modelling times and greater accuracy of the as-is T-BIM model.
4
Sadeghi, Marjan, Jonathan Weston Elliott, Nick Porro, and Kelly Strong. "Developing building information models (BIM) for building handover, operation and maintenance." Journal of Facilities Management 17, no. 3 (July 1, 2019): 301–16. http://dx.doi.org/10.1108/jfm-04-2018-0029.
Abstract:
PurposeThis paper aims to represent the results of a case study to establish a building information model (BIM)-enabled workflow to capture and retrieve facility information to deliver integrated handover deliverables.Design/methodology/approachThe Building Handover Information Model (BHIM) framework proposed herein is contextualized given the Construction Operation Information Exchange (COBie) and the level of development schema. The process uses Autodesk Revit as the primary BIM-authoring tool and Dynamo as an add-in for extending Revit’s parametric functionality, BHIM validation, information retrieval and documentation in generating operation and maintenance (O&M) deliverables in the end-user requested format.FindingsGiven the criticality of semantics for model elements in the BHIM and for appropriate interoperability in BIM collaboration, each discipline should establish model development and exchange protocols that define the elements, geometrical and non-geometrical information requirements and acceptable software applications early in the design phase. In this case study, five information categories (location, specifications, warranty, maintenance instructions and Construction Specifications Institute MasterFormat division) were identified as critical for model elements in the BHIM for handover purposes.Originality/valueDesign- and construction-purposed BIM is a standard platform in collaborative architecture, engineering and construction practice, and the models are available for many recently constructed facilities. However, interoperability issues drastically restrict implementation of these models in building information handover and O&M. This study provides essential input regarding BIM exchange protocols and collaborative BIM libraries for handover purposes in collaborative BIM development.
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Soetjipto, Jojok Widodo, Ilham Kahfi Zarkasi, and Anita Trisiana. "Model of Building Maintenance Planning Using The Building Information Modeling (BIM)." Jurnal Permukiman 18, no. 1 (May 1, 2023): 1–15. http://dx.doi.org/10.31815/jp.2023.18.1-15.
Abstract:
Building maintenance is essential for the operation of the building to maintain the reliability and performance of the building to match its economic age. There are many buildings whose maintenance is inferior from a technical, administrative, and budgetary perspective, so an appropriate maintenance design model is needed according to the operational needs of the building. On the other hand, the development of digital information technology is getting faster and more widely used. One is Building Information Modeling (BIM), where the entire activity process works in collaboration and integration. Therefore, this study aims to develop a proper building maintenance design model using BIM. The method used is to apply building maintenance standards in Indonesia (Public Works Ministrial Regulation No 24/PRT/M/2008) in BIM supporting applications, namely Autodesk Revit (for visualizing 3D buildings) and Autodesk BIM 360 Ops (for maintenance management), as a case study using the Maintenance Management Design of Walini Station which is one of the Jakarta-Bandung fast train stations with very modern, complex and complicated building components. The maintenance design model is carried out through the following stages: (i) building modeling using Autodesk Revit based on shop drawings in 3D and can be applied to 4D and 5D needs; (ii) export Autodesk Revit results to the Autodesk BIM 360 Ops application because this application can store a database of all building operations; and (iii) conducting a maintenance design simulation using the Autodesk BIM 360 Ops application. The study results show that BIM technology can be used as a detailed, accurate, effective, efficient, and integrated maintenance design model. Keywords: Building Maintenance, Building Information Modeling (BIM), Autodesk Revit, Autodesk BIM 360 Ops, building maintenance model
6
Yang, Tianqi, and Lihui Liao. "Research on Building Information Model (BIM) Technology." World Construction 5, no. 1 (July 21, 2016): 1. http://dx.doi.org/10.18686/wcj.v5i1.1.
Abstract:
All above<strong> </strong>this paper is to give the BIM scientific definition, describes the BIM six technical characteristics and points out the essence of BIM Technology, creatively put forward the mature styling BIM seven technical standards, depicting the BIM Technology Development Tools, and other technical fusion development realize the feasibility of the technical route, show the BIM building life cycle management strategies and methods based on, from the two dimensions of qualitative and quantitative, symbiosis is the example of the fused BIM Technology and energy consumption analysis tool. In the realization of green, smart and sustainable design BIM technology advantages to focus attention, the article finally, the BIM technology in China's engineering practice in the application of the prospects for the future.
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Yang, Tianqi, and Lihui Liao. "Research on Building Information Model (BIM) Technology." World Construction 5, no. 1 (July 21, 2016): 1. http://dx.doi.org/10.18686/wc.v5i1.58.
Abstract:
All above<strong> </strong>this paper is to give the BIM scientific definition, describes the BIM six technical characteristics and points out the essence of BIM Technology, creatively put forward the mature styling BIM seven technical standards, depicting the BIM Technology Development Tools, and other technical fusion development realize the feasibility of the technical route, show the BIM building life cycle management strategies and methods based on, from the two dimensions of qualitative and quantitative, symbiosis is the example of the fused BIM Technology and energy consumption analysis tool. In the realization of green, smart and sustainable design BIM technology advantages to focus attention, the article finally, the BIM technology in China's engineering practice in the application of the prospects for the future.
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Shi Yangle, Khoo Terh Jing, Chen Siyao, Ha Chin Yee, Deng Zihao, Lei Hao, and Sun Hui. "The efficacy of building information model in cost control of green buildings in Shanghai." Journal of Advanced Research in Applied Sciences and Engineering Technology 33, no. 1 (October 14, 2023): 471–89. http://dx.doi.org/10.37934/araset.33.1.471489.
Abstract:
With the rapid development of modern cities, green buildings have become an important way to reduce energy consumption and environmental impact. The focus of the industry has shifted towards controlling the costs associated with these green buildings. As a solution, Building Information Modelling (BIM), an integrated digital tool, has gained widespread usage in the cost control of green buildings, including in the city of Shanghai. As a centre city of China, Shanghai has both prospects and challenges in the field of green building cost control, it is extremely important to conduct this comprehensive study in Shanghai. Therefore, the primary objective of this study is to delve into the impact of BIM on the cost control of green buildings in Shanghai and unveil its effect during the implementation process of green building projects. To achieve this goal, the author used qualitative research and conducted in-depth interviews with engineers who have used BIM technology in various green building projects. The interviews explored the application of BIM and its effect on controlling costs. The findings of this study reveal that BIM has had a significantly positive impact on the cost control of green buildings in Shanghai. By implementing BIM, the efficiency of cost control has been enhanced throughout the entire life cycle of these environmentally friendly structures. This improvement stems from the ability of BIM to provide accurate and detailed information about the building's design, construction, and operation, enabling better decision-making and resource allocation. The implications of this study are twofold. First, it helps to theoretically understand the impact of BIM on green building cost control, especially in the context of Shanghai. This adds to the existing body of knowledge and furthers research in the field. Secondly, this study also fills the research gap of BIM in the cost control of green building projects in Shanghai.
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Egwunatum, Samuel, Esther Joseph-Akwara, and Richard Akaigwe. "Optimizing Energy Consumption in Building Designs Using Building Information Model (BIM)." Slovak Journal of Civil Engineering 24, no. 3 (September 1, 2016): 19–28. http://dx.doi.org/10.1515/sjce-2016-0013.
Abstract:
Abstract Given the ability of a Building Information Model (BIM) to serve as a multi-disciplinary data repository, this paper seeks to explore and exploit the sustainability value of Building Information Modelling/models in delivering buildings that require less energy for their operation, emit less CO2 and at the same time provide a comfortable living environment for their occupants. This objective was achieved by a critical and extensive review of the literature covering: (1) building energy consumption, (2) building energy performance and analysis, and (3) building information modeling and energy assessment. The literature cited in this paper showed that linking an energy analysis tool with a BIM model helped project design teams to predict and create optimized energy consumption. To validate this finding, an in-depth analysis was carried out on a completed BIM integrated construction project using the Arboleda Project in the Dominican Republic. The findings showed that the BIM-based energy analysis helped the design team achieve the world’s first 103% positive energy building. From the research findings, the paper concludes that linking an energy analysis tool with a BIM model helps to expedite the energy analysis process, provide more detailed and accurate results as well as deliver energy-efficient buildings. The study further recommends that the adoption of a level 2 BIM and the integration of BIM in energy optimization analyse should be made compulsory for all projects irrespective of the method of procurement (government-funded or otherwise) or its size.
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Carbonari, Giulia, Spyridon Stravoravdis, and Christine Gausden. "Building Information Model for Existing Buildings for Facilities Management." International Journal of 3-D Information Modeling 5, no. 1 (January 2016): 1–15. http://dx.doi.org/10.4018/ij3dim.2016010101.
Abstract:
The use of Building information modelling for the design and construction phase of a building has been thoroughly looked into by researchers and practitioners and there is evidence to support that it is beneficial for reducing cost, time and improving communication. Yet the potential use of BIM for the operational and management phase (Facilities management), besides maintenance schedules and equipment information and location, is still not clearly identified. The UK Government, institutional clients and major private owners are now demanding for BIM for new construction and major refurbishment but given that 70-75% of the current UK building stock will still be in use in 2050, a significant part of the existing facilities will not have an information model till the next major refurbishment, creating a major gap in the built environment. This paper presents a new framework aimed at creating information models for facilities management requiring minimal BIM skills and discusses the impact that models created for the operational stage would have on the whole life cycle of a building.
Dissertations / Theses on the topic "BIM (Building Information Model)":
1
Govan, Ivan, and Burim Berisha. "BIM Building Information Model : Hinder & Drivkraft." Thesis, Högskolan i Skövde, Institutionen för teknik och samhälle, 2012. http://urn.kb.se/resolve?urn=urn:nbn:se:his:diva-6587.
Abstract:
The construction industry is a costly business such in respect of capital for most construction defects which then require rework, tear down and rebuild again. This study is meaningful awareness of tools that can reduce this best through communication and information sharing between the parties. The construction industry is known as temporary projects organizations, where the construction project consists of several actors who have to communicate and share information between them to avoid mistakes later in the build time. These actors are bounded together thus for the duration of the project, then broken when the project has reached its end. The challenge here is for these actors to apply a tool that can help and simplify communications, information sharing, and perhaps the most important aspect is to create a routine for the association and the shattering of these actors. To implement such behavior using a tool such as BIM in the industry whose size perhaps is indescribable may be a very hard task. BIM (Building Information Model) could be seen as the solution to this problem because it acts as a portal where the actors involved must sign in and communicate, share information, and eventually create a behavior, a routine for this association and division of the actors following the end of the project. The technology could help the involved from the beginning of the project, already in the model stage, break down and prevent any construction barriers when the building has been placed in the works. In the current situation used paper models, 2D models and three-dimensional models, 3D, where the last one is a part of the BIM. BIM makes it also possible to implement 4D, price calculation for the construction from beginning to end and 5D ie construction details such as what kind of wood the door is made of, what kind of concrete it is, and even the amount of cable for the construction for example. BIM is seen as a information technology used primarily in construction, where to encounter several obstacles during the implementation and use of such technology is expensive to implement in a small operation, but it creates many drivers, many agents that have implemented BIM, which ultimately pays according to those who can afford and in the current situation using it
2
Jaffery, Syed Raza Ali. "Envisioning a building information model (BIM) integrated building performance visualization (iPViz) interface." Thesis, University of British Columbia, 2016. http://hdl.handle.net/2429/58925.
Abstract:
The dispersed nature, complexity, and amount of information available in modern buildings with advanced management and control systems, makes it challenging for building operators to holistically understand building performance. One of the reasons is the lack of integration among multiple information sources and tools making it harder to align performance data with user’s experiential model of the physical systems. The goal of this research is to envision an integrated building performance visualization interface that provides contextually relevant, on-demand information to building operators. The research was executed in three sequential phases including an extensive literature review, a detailed case study, and development of a mockup prototype. I conducted an extensive literature review to capture the state-of-the-art in related academic domains and to establish a point-of-departure for the proposed research. The case study focused on a high performance building to understand operation and maintenance practices with an emphasis on building management systems (BMS). The case study involved two phases. In the first phase, I collected qualitative data by conducting interviews, contextual inquiries, and shadowing of building operators. In the second phase, I conducted a survey to collect quantitative data that further expanded upon the initial findings from first phase.
The results revealed several overlapping and interrelated challenges that were further analyzed and grouped into two sets of issues: visualization related and system’s interactivity related. I also identified two core problems in the overall use of the BMS: a lack of spatial and informational context, and disconnected monitoring of energy and system performance data. Based on the findings, I developed a BIM Integrated Performance Visualization (iPViz) interface mockup as a proof-of-concept to support the work of building operators. I demonstrated the proposed interface features by using storyboard illustrations based on task-specific scenarios. I designed the scenarios and storyboards to demonstrate the proposed interface’s ability to provide spatially contextual information in response to a building operator’s interactions. The research provides some future directions for the development of BIM-based performance visualization systems. Additional research is required to implement and evaluate the proposed solutions and to analyze their effectiveness in facilitating building management functions.Applied Science, Faculty of
Civil Engineering, Department of
Graduate
3
Engdahl, Jenny, and Madeleine Hedlund. "BIM för Hållbart Byggande." Thesis, Tekniska Högskolan, Högskolan i Jönköping, JTH, Byggnadsteknik, 2012. http://urn.kb.se/resolve?urn=urn:nbn:se:hj:diva-22514.
Abstract:
The purpose of this study is to facilitate sustainable building by the use of BIM. The goal is to determine which aspects of sustainable building, which can be analyzed mainly with BIM tools, but also other aids. The study is based on literature studies and interviews. The literature review examines aspects important for sustainable building by studying environmental certification systems applicable in Sweden, as well as the BIM tools available on the market to analyze these aspects. The literature also includes the concepts of BIM and sustainability in order to provide a clearer view of its meaning. The interviews have brought the study's overall understanding of the industry and guidance on the subject. The results are presented in a table, where the aspects relevant to sustainable building are listed. It can also be read which aspect the certification systems raise. Overall, the study shows 132 aspects distributed across seven areas: Site, Water and Wastewater, Energy and Pollution, Materials and Waste, Indoor and Wellbeing, City Design and finally Implementation and Management. The table also suggests BIM tools and other aids, which can be used in the analysis of a specific aspect. The study shows a slight majority of the aspects, 55 percent, are possible to analyze with BIM tools. The Site is the area with most aspects, which can be analyzed with BIM tools, 95 percent. And Materials and Waste resulted in least aspects with only ten percent. Overall, the study examined 35 different BIM tools. The aspects that require other means of analysis often generates important information about the project, from a sustainability point of view, and in many cases the information can be integrated in the BIM model manually. In the end, the project gets a packed BIM model with useful information, which follows the project all the way into management and later demolition and recycling. The study shows that sustainable building demands a holistic approach where several aspects should be considered in order to achieve sustainability. To analyze the aspects of sustainability requires that relevant and accurate information about the project be collected. Various proposals can be drawn and compared to generate the most sustainable option. A tool for this is BIM. BIM is defined partly as a method of work, building information modeling, but also as a virtual model, building information model. BIM facilitates the coordination of information gathering, both as a working method and a technical tool. This will contribute BIM to achieve the purpose sustainable building.Syftet med den här studien är att underlätta hållbart byggande genom användandet av BIM. Målet är att utreda vilka aspekter inom hållbart byggande som kan analyseras med fokus på i huvudsak BIM-verktyg, men också andra hjälpmedel. Studien bygger på litteraturstudier och intervjuer. I litteraturstudien undersöks aspekter som är betydelsefulla vid hållbart byggande genom att studera miljöcertifieringssystem som är tillämpningsbara i Sverige, samt vilka BIM-verktyg som finns att tillgå på marknaden för att analysera dessa aspekter. Litteraturstudien innefattar även begrepp rörande BIM och hållbarhet för att ge en klarare bild av dess innebörd. Intervjuerna har tillfört studien övergripande förståelse för branschen och vägledning i ämnet. Resultatet redovisas i en tabell, där de aspekter som är relevanta för hållbart byggande är listade. I tabellen går det även att utläsa vilka aspekter certifieringssystemen tar upp. Totalt visar studien på 132 aspekter fördelade inom sju delområden; Platsen, Vatten och Avlopp, Energi och Föroreningar, Material och Avfall, Inomhusklimat och Välmående, Stadens Gestaltning samt Genomförande och Förvaltning. I tabellen redovisas dessutom förslag på BIM-verktyg samt andra hjälpmedel som används vid analys av en specifik aspekt. Studien visar att en knapp majoritet av aspekterna, 55 procent, är möjliga att analysera med BIM-verktyg. Platsen är det delområde som visar flest aspekter som går att analysera med BIM-verktyg, 95 procent. Material och avfall resulterade i minst aspekter med endast tio procent. Sammantaget har studien undersökt 35 stycken olika BIM-verktyg. De aspekter som kräver andra hjälpmedel för analys genererar ofta information viktig för projektet ur hållbarhetssynpunkt, och går i många fall att integrera i BIM-modellen manuellt. Sammantaget medför det att projektet får en fullmatad BIM-modell med användbar information som följer projektet ända in i förvaltning och sedermera rivning och återvinning. Studien visar att hållbart byggande handlar om att ha en helhetssyn där flertalet aspekter ska beaktas för att uppnå hållbarhet. Det räcker således inte att bara se till exempelvis energihushållning för att anse att ett projekt är hållbart. För att analysera aspekter rörande hållbarhet krävs att relevant och riktig information om projektet insamlas. Då kan olika förslag utarbetas och jämföras för att ta fram det mest hållbara alternativet. Ett redskap för detta är BIM. BIM är definierat dels som en arbetsmetod, byggnadsinformationsmodellering, men också som en virtuell modell, byggnadsinformationsmodell. BIM underlättar samordningen av den insamlande informationen, både som arbetsmetod och som tekniskt verktyg. På så vis bidrar BIM till att uppnå syftet hållbart byggande.
4
Utiome, Erezi Ame Emmanuel. "Extending building information models to construction specifications." Thesis, Queensland University of Technology, 2015. https://eprints.qut.edu.au/84929/1/Erezi_Utiome_Thesis.pdf.
Abstract:
This project examined the role that written specifications play in the building procurement process and the relationship that specifications should have with respect to the use of BIM within the construction industry. A three-part approach was developed to integrate specifications, product libraries and BIM. Typically handled by different disciplines within project teams, these provide the basis for a holistic approach to the development of building descriptions through the design process and into construction.
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Mendez, Ronald Osiris. "The building information model in facilities management." Link to electronic thesis, 2006. http://www.wpi.edu/Pubs/ETD/Available/etd-050406-153423/.
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Eriksson, Michael. "BIM i förvaltningsskedet." Thesis, Tekniska Högskolan, Högskolan i Jönköping, JTH, Byggnadsteknik, 2012. http://urn.kb.se/resolve?urn=urn:nbn:se:hj:diva-19875.
Abstract:
Syftet med den här studien är att förbättra informationsflödet från projektering och produktion in i förvaltningen. Detta för att väcka ett intresse hos förvaltare och för att visa att det finns pengar att spara genom att ta hand om informationen från projekteringen och produktionen. Tidigare studier inom området BIM visar att stor fokus läggs på projektering och produktion men det är ett väldigt litet fokus på förvaltningen när man talar om BIM. Målet är att konkret kunna visa vad informationen är värd och att visa vilken information förvaltare använder och var den finns i byggprocessens skeden före förvaltningen. Rapporten bygger på en litteraturstudie, intervjuer och beräkningar. Förvaltare har blivit tillfrågade vilken information de använder i förvaltningen och sedan har projektör och entreprenör blivit tillfrågad ifall denna information finns att tillgå i projekteringen och produktionen. Värderingen av informationen har sedan gått till på två sätt. Det ena sättet är att bedöma kostnaden av att uppdatera information mot kostnaden att ta fram information på nytt. Det andra sättet är att med hjälp av nyckeltal (kronor per kvadratmeter) och den lista med typ av information som förvaltare använder, som sammanställts från intervjuerna, ta reda på vad information är värd. Det första sättet att värdera visar att det kostar lika mycket att hålla relationsritningar (A) uppdaterade i som minst 18år och i som mest 50år som att ta fram informationen helt på nytt. Nästan samma gäller för BIM-modell med avseende på relationsritningar (A). Fast där är kostnaden för framtagning på nytt lika stor som att hålla den uppdaterad i som minst 22år och i som mest 58år. Det andra sättet att värdera visar att mindre än 25% av den information man kan finna i projekteringen och eller i produktionen är värd cirka 10% av projekteringskostnaden.The purpose of this study is to improve the flow of information from the design and construction phase into the facility management. This in order to make the facility managers see the advantages with BIM and to show that there is money to be saved by retrieving the information from the design and the construction phase. Earlier studies show that there actually has been quite little research done within BIM in the facility management and that the main focus has been at the design and the construction phase. The aim with the study is to specify the value of the information and to show which information facility managers use and where it can be retrieved from within the earlier phases of the construction process. The report is based on a literature study, interviews and calculations. A number of facility managers have been asked which types of information they use and designers and entrepreneurs have then been asked if these types of information can be found in the design and the construction phase. The information has been valued in two different ways. In one way the information was valued by comparing the cost between updating existing information or recreate the same type of information. The other way of valuing the information was to find out the worth of information by using key figures (SEK per square meter) and the list of information that facility managers use, which was made up from the interviews. The first way of valuing shows that the cost of producing as built drawings (A) in the facility management cost as much as keeping the same type of information updated for at least 18years and as most 50years. Almost the same goes for a BIM-model. Only there the difference is that the cost of producing a BIM-model focused on as built drawings (A) in the facility management cost as much as keeping the same type of information updated for at least 22years and as most 58years. The other way that the information was valued shows that less than 25% of the information that can be found in the design and/or construction phase is worth circa 10% of the projecting fee.
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Sjödin, Magnus, and Tobias Rasping. "Analys av BIM-processen i ombyggnadsprojekt." Thesis, KTH, Byggvetenskap, 2011. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-92567.
Abstract:
Idag används BIM, byggnadsinformationsmodellering, i fler och fler nybyggnadsprojekt och det finns mängder med information att inhämta om detta både i tryckta tidskrifter och på internet. En obesvarad fråga är dock hur arbetsgången ser ut när BIM ska användas i ombyggnadsprojekt. Informationen som går att finna om detta är begränsad trots att ombyggnadsprojekt utgör en betydande del av byggverksamheten, såväl i Sverige som internationellt. Målet med denna rapport är därför att undersöka hur ombyggnadsprojekt i dagsläget utförs med BIM som arbetssätt. Processen att arbeta med BIM har undersökts i detalj för att klargöra hur den ser ut idag och för att identifiera den problematik som just ombyggnationer medför. Denna undersökning har genomförts i två pågående projekt enligt en gemensam analysmodell för att klargöra skillnader och likheter. För att klargöra arbetsprocessen så har ett flertal intervjuer med inblandade i projekten genomförts. Genom ett enkätutskick till båda projekten så har ett jämförbart underlag även tagits fram. Projektens modeller har också undersökts för att klargöra deras detaljeringsnivå. Den stora problematik som identifierats med ombyggnadsprojekt är att eftersom arbetet sker mot befintliga byggnadsdelar måste dessa kontrolleras och hanteras. Av denna anledning behöver därför många gånger en inmätning av dessa göras för att kontrollera och komplettera det underlag som finns tillgängligt eller för att skapa ett helt nytt. Detta är en tidig del i processen och något som måste göras innan ett vidare arbete med att upprätta en modell kan utföras. Gemensamt för båda projekten har varit att använda sig av modellen för att samgranska olika discipliners material med syftet att upptäcka och på så sätt minimera antalet kollisioner i produktionen. Analysen har visat på ganska stora skillnader i arbetssätt beroende på projektens förutsättningar. Den största skillnaden är att det i ett av projekten finns ett intresse ifrån beställaren att en modell ska levereras, för att senare kunna användas i förvaltningen. Beställarens intresse har resulterat i att BIM har använts i större utsträckning i det projektet med bland annat kostnader kopplade till modellen. Något som har framkommit är också att arbetssättet BIM måste standardiseras, möjligtvis genom att företaget tar fram en BIM-manual som kan användas i alla projekt som ska använda sig av BIM. Erfarenhetsåterföring efter genomförda projekt måste även ske för att denna manual ska vara aktuell.Currently BIM (Building Information Modeling) is used to a higher extent in new construction projects and there is a lot of information to gather about this both in magazines and online. An unanswered question is how the workflow looks like when BIM is used in reconstruction projects. The information that can be found about this is limited despite the fact that reconstruction projects represent a significant proportion of the construction business, both in Sweden and internationally. The aim of this report is to examine how reconstruction projects currently is carried out with BIM. The BIM process has been studied in detail to clarify the current situation and to identify the problems that reconstruction adds. The study was conducted on two ongoing projects in accordance to a common analytical model to clarify the similarities and differences between them. In order to clarify the work process several interviews has been conducted with the project personnel. Through a questionnaire, a survey of both projects has been performed. Project models have also been studied to clarify their level of detail. The major problem that has been identified with reconstruction projects is that the work is carried out on existing building elements that have to be verified. For this reason a detail survey often must be done to verify and add to existing drawing and documentations. The survey is an early part of the process and something that must be done before any further work to establish a model can be done. Common to both projects is the use of the model to coordinate the various disciplines content in order to minimize the number of collisions in the production. The analysis has shown quite significant differences in methods depending on project conditions. The main difference is that in one of the projects the client wants to use the model in the property management and therefore a model must be delivered. The client’s interest led to a wider use of BIM in the project, including costs connected to the objects in the model. Something that has become clear is that BIM as a work tool must be standardized, possibly through a BIM manual drafted by the company, which can be used in all projects that will make use of BIM. Feedback with lessons learned must be added to the manual for it to stay updated.
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Tauscher, Helga. "Configurable nD-visualization for complex Building Information Models." Doctoral thesis, Saechsische Landesbibliothek- Staats- und Universitaetsbibliothek Dresden, 2017. http://nbn-resolving.de/urn:nbn:de:bsz:14-qucosa-228894.
Abstract:
With the ongoing development of building information modelling (BIM) towards a comprehensive coverage of all construction project information in a semantically explicit way, visual representations became decoupled from the building information models. While traditional construction drawings implicitly contained the visual representation besides the information, nowadays they are generated on the fly, hard-coded in software applications dedicated to other tasks such as analysis, simulation, structural design or communication. Due to the abstract nature of information models and the increasing amount of digital information captured during construction projects, visual representations are essential for humans in order to access the information, to understand it, and to engage with it. At the same time digital media open up the new field of interactive visualizations. The full potential of BIM can only be unlocked with customized task-specific visualizations, with engineers and architects actively involved in the design and development process of these visualizations. The visualizations must be reusable and reliably reproducible during communication processes. Further, to support creative problem solving, it must be possible to modify and refine them. This thesis aims at reconnecting building information models and their visual representations: on a theoretic level, on the level of methods and in terms of tool support. First, the research seeks to improve the knowledge about visualization generation in conjunction with current BIM developments such as the multimodel. The approach is based on the reference model of the visualization pipeline and addresses structural as well as quantitative aspects of the visualization generation. Second, based on the theoretic foundation, a method is derived to construct visual representations from given visualization specifications. To this end, the idea of a domain-specific language (DSL) is employed. Finally, a software prototype proofs the concept. Using the visualization framework, visual representations can be generated from a specific building information model and a specific visualization descriptionMit der fortschreitenden Entwicklung des Building Information Modelling (BIM) hin zu einer umfassenden Erfassung aller Bauprojektinformationen in einer semantisch expliziten Weise werden Visualisierungen von den Gebäudeinformationen entkoppelt. Während traditionelle Architektur- und Bauzeichnungen die visuellen Reprä̈sentationen implizit als Träger der Informationen enthalten, werden sie heute on-the-fly generiert. Die Details ihrer Generierung sind festgeschrieben in Softwareanwendungen, welche eigentlich für andere Aufgaben wie Analyse, Simulation, Entwurf oder Kommunikation ausgelegt sind. Angesichts der abstrakten Natur von Informationsmodellen und der steigenden Menge digitaler Informationen, die im Verlauf von Bauprojekten erfasst werden, sind visuelle Repräsentationen essentiell, um sich die Information erschließen, sie verstehen, durchdringen und mit ihnen arbeiten zu können. Gleichzeitig entwickelt sich durch die digitalen Medien eine neues Feld der interaktiven Visualisierungen. Das volle Potential von BIM kann nur mit angepassten aufgabenspezifischen Visualisierungen erschlossen werden, bei denen Ingenieur*innen und Architekt*innen aktiv in den Entwurf und die Entwicklung dieser Visualisierungen einbezogen werden. Die Visualisierungen müssen wiederverwendbar sein und in Kommunikationsprozessen zuverlässig reproduziert werden können. Außerdem muss es möglich sein, Visualisierungen zu modifizieren und neu zu definieren, um das kreative Problemlösen zu unterstützen. Die vorliegende Arbeit zielt darauf ab, Gebäudemodelle und ihre visuellen Repräsentationen wieder zu verbinden: auf der theoretischen Ebene, auf der Ebene der Methoden und hinsichtlich der unterstützenden Werkzeuge. Auf der theoretischen Ebene trägt die Arbeit zunächst dazu bei, das Wissen um die Erstellung von Visualisierungen im Kontext von Bauprojekten zu erweitern. Der verfolgte Ansatz basiert auf dem Referenzmodell der Visualisierungspipeline und geht dabei sowohl auf strukturelle als auch auf quantitative Aspekte des Visualisierungsprozesses ein. Zweitens wird eine Methode entwickelt, die visuelle Repräsentationen auf Basis gegebener Visualisierungsspezifikationen generieren kann. Schließlich belegt ein Softwareprototyp die Realisierbarkeit des Konzepts. Mit dem entwickelten Framework können visuelle Repräsentationen aus jeweils einem spezifischen Gebäudemodell und einer spezifischen Visualisierungsbeschreibung generiert werden
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Håkansson, Lisa, and Julia Dannfors. "BIM i produktion : En undersökning om hur BIM kan implementeras i produktion." Thesis, Uppsala universitet, Byggteknik, 2019. http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-389669.
Abstract:
The object of this report is to investigate how to implement BIM into the production part of the construction industry. How NCC should act to make the transformation as smooth and easy as possible. BIM, Building Information Modelling, is a way of working where you gather all information in one place. All disciplines work in a 3Dmodel and have information about their component in that model. For example, you can create a specific wall with its different layers, that will make it easier to calculate offers from subcontractors and also make the daily work with other orders easier if you know what the wall is build of. You can also use the model for collision controles. This make everything more efficient and make it easier to collaborate between different disciplines.By interviewing people from the industry, mainly from the production, we found that there already are softwares on the market that NCC are using that is easy to use even if you haven't worked a lot with digital tools before. The problem is how to spread the information about these softwares so that more projects can use them. Another difficulty is how to get the craftsmen to use these softwares. The people we interviewed thought that the lack of interest for digital tools, and the older generation, is the main reason why the implementation will be challenging. Our conclusion is that NCC need to find a systematic way to educate their employees in the digital tools that they are using. They need to get better to spread the word about those digital tools within the company so that their employees understand how much they can help and will start to use them. The craftsmen should use the tools to help visualize what they are building and the on-site manager should have a software with more features.Syftet med arbetet är att undersöka hur BIM kan implementeras i byggbranschen på ett bra och smidigt sätt ute i produktion. Detta ger NCC ett underlag för hur de ska gå tillväga för att denna process ska gå så lätt och smidigt som möjligt men också för att minska risken att fokus hamnar på fel ställe och att implementeringen utförs på ett sådant sätt att personalen blir mer negativa mot digitala hjälpmedel i produktionen. Då yrkesarbetarna är de som hittills jobbat minst med digitala hjälpmedel har störst vikt lagts vid att undersöka hur implementeringen kommer att påverka dem och hur man ska göra för att få med dem i denna förändring. BIM, Building Information Modeling, är egentligen byggbranschens digitalisering. Det bygger på att projekteringen utförs i 3D och sedan byggs modellen på med information som gör att arbetet kan effektiviseras och göras smidigare. Det går till exempel att rita upp hur väggarna är uppbyggda i skikt för att underlätta för kalkylatorn vid upphandlingar med underentreprenörer men också i produktion vid beställning av material. Detta minimerar dubbeljobb och effektiviserar produktionen. I projekteringen används det bland annat vid kollisionskontroller där olika discipliners modeller läggs ihop för att se om installationerna krockar någonstans. I förvaltning kan det användas genom att produkterna som använts läggs in i modellen, till exempel vilken armatur, för att sedan lätt kunna hitta den informationen när armaturen senare behöver bytas ut. Det pratas ofta om att BIM är dyrt och det stämmer att det blir en högre kostnad i början av projekten. Däremot sparas tid och pengar i produktion och förvaltning. Fel som tidigare har upptäckts i produktion och har behövt lösas på plats så gott som försvinner. Genom att intervjua personer som börjat använda sig av BIM i produktion har upptäckten gjorts att det finns bra och lätthanterliga program som underlättar och effektiviserar vissa delar av produktionen. Två av dessa program som används på NCC idag är Bluebeam och Dalux. Bluebeam används som dokumenthantering där länkar mellan olika ritningar gör att det går snabbt och enkelt att hoppa mellan ritningar. Dalux är ett lättanvändligt program där du kan se projektet i 2D och 3D samtidigt vilket ger en lättare förståelse för vad som ska byggas genom att du kan gå omkring i projektet i 3D. Dalux har även en gratis app som alla yrkesarbetare skulle kunna använda för att öka förståelsen av vad dom bygger vilket skulle kunna göra att frågorna till arbetsledningen skulle minska. Ett problem är då hur man ska lösa det med mobiler och surfplattor till alla, om man inte får använda sin egen eller äger någon privat. Ett annat problem med digitaliseringen är att hårdvarorna är väldigt ömtåliga och ska användas i en hård miljö samt så har internet en tendens att krascha med jämna mellanrum vilket gör att man alltid måste ha en backup av de aktuella ritningarna och modellerna. En annan fråga är hur man ska få alla att använda sig av de digitala verktygen. Här är de som intervjuats överens om att det med största sannolikhet handlar om hur intresserad man är av teknik och att det är en generationsfråga. De menar att det med generationsskiftet kommer bli lättare att implementera BIM i yrkesarbetarnas arbete. För att implementera BIM i produktion på ett så bra och smidigt sätt som möjligt bör ordentliga utbildningar av platsledning och yrkesarbetarna genomföras för att sprida kunskapen om vilka möjligheter som finns inom företaget men också för att ge personalen en bra grund så att de känner sig säkra i programmen när de ska börja användas. Det kan öka intresset även hos de som varit negativt inställda från början. Yrkesarbetarna bör använda programmen som visuell hjälp genom att gå omkring i 3D modellen och för att snabbare kunna navigera sig mellan olika ritningar genom länkar. Arbetsledarna kan ha en högre svårighetsgrad med fler funktioner, bland annat olika lager och möjligheten att uppdatera ritningar och modeller.
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Ignjatovic, Jelena. "Utredning av projekteringsverktygets ROL utvecklingsbehov : En anpassning för norsk marknad." Thesis, Högskolan Väst, Avdelningen för maskinteknik och naturvetenskap, 2015. http://urn.kb.se/resolve?urn=urn:nbn:se:hv:diva-9445.
Abstract:
Rail Overhead Line (ROL) is a design tool, owned by the company Bentley Systems AB. The design tool is used by overhead line engineers at Sweco Rail to design contact line for electric railway. Sweco Rail intends to establish themselves on the Norwegian market together with their sister company Sweco A/S. Before entry into the new market, a development of ROL is required. The objective with the thesis has been to identify the requirements and the development needs, which are required to adapt ROL against the Norwegian market.The administrations Jernbaneverket and Trafikverket, which are major customers to Sweco, requires more often that Building Information Model (BIM) is to be used in their projects. The goal with the use of BIM is to lead the work to a more efficient management, as well as reduce the risk of information being lost between various stages and processes within the projects. Before entry on the Norwegian market, it is therefore necessary of Sweco Rail and Bentley to adjust ROL in order to be able to deliver 3D-models. The 3D-models have to fulfill the requirements that the Norwegian administration Jernbaneverket demands of the use of BIM in projects.To identify the development needs that are required for a Norwegian adjustment of ROL; interviews, observations and a study of governing documents was performed. Customer needs were identified and translated to requirements. These requirements led to the identified development needs.The result showed that 56 development needs have to be fulfilled before ROL can be used as a design tool on the Norwegian market. The identified development needs include actions with the intention that the design tool can be used in greater extension on the Swedish market. Sweco and their resources can rectify 22 of the 56 development needs. For the remaining 34 development needs, the owners Bentley Systems need to take responsibility for the solutions that is required to satisfy the needs.Rail Overhead Line (ROL) är ett projekteringsverktyg, vilket ägs av företaget Bentley Systems AB och används av kontaktledningsprojektörer på Sweco Rail. Projekteringsverktyget används för att projektera kontaktledningsanläggningar. Sweco Rail AB har för avsikt att etablera sig på den norska marknaden tillsammans med systerbolaget Sweco A/S. Inför etableringen på den nya marknaden erfordras en utveckling av ROL för att verktyget skall kunna nyttjas vid projektering i Norge. Syftet med arbetet har varit att identifiera de krav och utvecklingsbehov som krävs i avsikt att anpassa ROL för den norska marknaden.Det blir allt mer vanligt att förvaltningarna Jernbaneverket och Trafikverket, vilka är stora kunder till Sweco, ställer krav på att arbetssättet Building Information Model (BIM) skall användas i projekt. Målet med användningen av BIM är att få en effektivare förvaltning samt reducera risken för att information försvinner mellan olika skeden i projekten och processer. Inför etableringen på den norska marknaden behöver därför Sweco och Bentley Systems anpassa ROL för att bland annat kunna leverera 3D-modeller vilka uppfyller de krav norska Jernbaneverket ställer på användningen av BIM i projekt.För att identifiera utvecklingsbehoven, vilka krävs för en norsk anpassning av ROL, genomfördes intervjuer, observationer samt en studie av styrdokument. Kundbehov identifierades och översattes till krav, vilka även låg till grund för de identifierade utvecklingsbehoven.Resultatet av arbetet visade att det finns 56 stycken utvecklingsbehov, vilka behöver uppfyllas för att ROL skall kunna användas vid projektering för den norska marknaden. Av de identifierade utvecklingsbehoven återfinns även åtgärder av verktyget vilka skulle kunna gynna projekteringen på den svenska marknaden. 22 stycken av de 56 utvecklingsbehoven kan Sweco åtgärda med hjälp av sina resurser på företaget. För de resterande 34 utvecklingsbehoven behöver ägarna av ROL, Bentley Systems, ta ansvar för de lösningar som krävs för att behoven skall tillfredsställas.
Books on the topic "BIM (Building Information Model)":
1
Race, Steve. BIM demystified: An architect's guide to Building Information Modelling/Management (BIM). 2nd ed. London: Riba Publishing, 2013.
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Race, Steve. Bim demystified: An architect's guide to Building Information Modelling/Management (BIM). London: Riba Publishing, 2012.
3
Schrammel, Florian, and Ernst Wilhelm. Rechtliche Aspekte im Building Information Modeling (BIM). Wiesbaden: Springer Fachmedien Wiesbaden, 2016. http://dx.doi.org/10.1007/978-3-658-15706-7.
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Albrecht, Matthias. Building Information Modeling (BIM) in der Planung von Bauleistungen. Hamburg: disserta Verlag, 2015.
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Reddy, K. Pramod. BIM for building owners and developers : making a business case for using BIM on projects. Hoboken, N.J: John Wiley & Sons, 2011.
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Deutsch, Randy. BIM and integrated design: Strategies for architectural practice. Hoboken, N.J: Wiley, 2011.
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Deutsch, Randy. BIM and integrated design: Strategies for architectural practice. Hoboken, N.J: Wiley, 2011.
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Jernigan, Finith E. Big BIM, little bim: The practical approach to building information modeling : integrated practice done the right way! Salisbury, Md: 4Site Press, 2007.
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Jernigan, Finith E. Big BIM, little bim: The practical approach to building information modeling : integrated practice done the right way! 2nd ed. Salisbury, MD: 4Site Press, 2008.
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Barnes, Peter. BIM in principle and in practice. London: ICE Publishing, 2015.
Book chapters on the topic "BIM (Building Information Model)":
1
Hjelseth, Eilif. "BIM-based Model Checking (BMC)." In Building Information Modeling, 33–61. Reston, VA: American Society of Civil Engineers, 2015. http://dx.doi.org/10.1061/9780784413982.ch02.
2
Wu, Wei, and Raja R. A. Issa. "An Integrated Green BIM Process Model (IGBPM) for BIM Execution Planning in Green Building Projects." In Building Information Modeling, 135–65. Reston, VA: American Society of Civil Engineers, 2015. http://dx.doi.org/10.1061/9780784413982.ch06.
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Harfmann, Anton C. "Component-Based BIM: A Comprehensive, Detailed, Single-Model Strategy." In Building Information Modeling, 187–96. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2015. http://dx.doi.org/10.1002/9781119174752.ch14.
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Doukari, Omar, Mohamad Kassem, and David Greenwood. "Building Information Modelling." In Disrupting Buildings, 39–51. Cham: Springer International Publishing, 2023. http://dx.doi.org/10.1007/978-3-031-32309-6_3.
Abstract:
AbstractFrom its origins as a computer-aided three-dimensional modelling tool, Building Information Modelling (BIM) has evolved to incorporate time scheduling, cost management, and ultimately an information management framework that has the potential to enhance decision-making throughout the whole life-cycle of built assets. This chapter summarises state-of-the-art BIM and its benefits. It then considers the particular characteristics of deep renovation projects, the challenges confronting their delivery, and the potential for using BIM to meet the challenges. This includes the application of Artificial Intelligence (AI) and Machine Learning (ML) to BIM models to optimise deep renovation project delivery. The prospects for this are encouraging, but further development work, including the creation of ontologies that are appropriate for renovation work, is still needed.
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Isikdag, Umit. "Sensor Service Architectures for BIM Environments." In Enhanced Building Information Models, 99–116. Cham: Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-21825-0_7.
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Adekunle, Samuel A., Clinton Aigbavboa, Obuks Ejohwomu, Wellington D. Thwala, and Mahamadu Abdul-Majeed. "Global BIM Adoption Strategies." In A Building Information Modelling Maturity Model for Developing Countries, 20–28. London: Routledge, 2023. http://dx.doi.org/10.1201/9781003373919-5.
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Isikdag, Umit. "The Future of Building Information Modelling: BIM 2.0." In Enhanced Building Information Models, 13–24. Cham: Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-21825-0_2.
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Adekunle, Samuel A., Clinton Aigbavboa, Obuks Ejohwomu, Wellington D. Thwala, and Mahamadu Abdul-Majeed. "Conceptualisation of the BIM Maturity Model." In A Building Information Modelling Maturity Model for Developing Countries, 71–104. London: Routledge, 2023. http://dx.doi.org/10.1201/9781003373919-9.
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Dudhee, Vishak, and Vladimir Vukovic. "Integration of Building Information Modelling and Augmented Reality for Building Energy Systems Visualisation." In Springer Proceedings in Energy, 83–89. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-63916-7_11.
Abstract:
AbstractBuildings consist of numerous energy systems, including heating, ventilation, and air conditioning (HVAC) systems and lighting systems. Typically, such systems are not fully visible in operational building environments, as some elements remain built into the walls, or hidden behind false ceilings. Fully visualising energy systems in buildings has the potential to improve understanding of the systems’ performance and enhance maintenance processes. For such purposes, this paper describes the process of integrating Building Information Modelling (BIM) models with Augmented Reality (AR) and identifies the current limitations associated with the visualisation of building energy systems in AR using BIM. Testing of the concept included creating and superimposing a BIM model of a room in its actual physical environment and performing a walk-in analysis. The experimentation concluded that the concept could result in effective visualisation of energy systems with further development on the establishment of near real-time information.
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Luo, Xiu, and Amar Jain. "Application of Computer BIM Software Technology in Building Information Model." In Cyber Security Intelligence and Analytics, 295–302. Cham: Springer International Publishing, 2022. http://dx.doi.org/10.1007/978-3-030-96908-0_37.
Conference papers on the topic "BIM (Building Information Model)":
1
Kumar, S. Suresh, and J. J. McArthur. "Streamlining Building Information Model creation using Agile project management." In BIM 2015. Southampton, UK: WIT Press, 2015. http://dx.doi.org/10.2495/bim150201.
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OLUGBOYEGA, OLUSEYE, and ABIMBOLA WINDAPO. "MODEL OF INFORMATION SHARING AND EXCHANGE IN A BUILDING INFORMATION MODELLING SUPPLY CHAIN." In BIM 2019. Southampton UK: WIT Press, 2019. http://dx.doi.org/10.2495/bim190111.
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Carbonari, G., S. Stravoravdis, and C. Gausden. "Building information model implementation for existing buildings for facilities management: a framework and two case studies." In BIM 2015. Southampton, UK: WIT Press, 2015. http://dx.doi.org/10.2495/bim150331.
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Bukunov, Alexander Sergeevich, and Olga Victorovna Bukunova. "Information exchange in the common system when creating building information model." In II International Conference “BIM in Construction & Architecture”. Saint Petersburg State University of Architecture and Civil Engineering, 2019. http://dx.doi.org/10.23968/bimac.2019.010.
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"Enhancing Green Building Performance through Integrated BIM Model Optimization Strategies." In International Conference on Cutting-Edge Developments in Engineering Technology and Science. ICCDETS, 2024. http://dx.doi.org/10.62919/jggj1232.
Abstract:
This research paper explores the role of Building Information Modeling (BIM) in enhancing the performance of green buildings through integrated optimization strategies. The study delves into how BIM, as a multidisciplinary platform, facilitates the efficient design, construction, and operation of sustainable structures by enabling precise modeling, analysis, and visualization of building performance criteria. By integrating BIM with green building standards and environmental simulation tools, the paper outlines methods to optimize energy efficiency, resource management, and environmental sustainability. The research focuses on various case studies where BIM has been successfully employed to achieve superior sustainability outcomes in building projects. The analysis includes a comprehensive review of BIM capabilities in energy modeling, material optimization, and lifecycle assessment, aiming to provide actionable insights for architects, engineers, and sustainability consultants. The findings suggest that leveraging BIM for green building projects not only enhances environmental performance but also contributes to economic and operational efficiency, offering a competitive edge in the architecture, engineering, and construction (AEC) industry.
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Lomio, Francesco, Ricardo Farinha, Mauri Laasonen, and Heikki Huttunen. "Classification of Building Information Model (BIM) Structures with Deep Learning." In 2018 7th European Workshop on Visual Information Processing (EUVIP). IEEE, 2018. http://dx.doi.org/10.1109/euvip.2018.8611701.
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Bouazza, T., C. E. Udeaja, and D. Greenwood. "The use of building information modelling (BIM) in managing knowledge in construction project delivery: a conceptual model." In BIM 2015. Southampton, UK: WIT Press, 2015. http://dx.doi.org/10.2495/bim150101.
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Maalek, Reza, and Feyzullah Yavan. "Automatic alignment of point clouds onto building information model (BIM) in regular rectangular buildings." In 3rd International Civil Engineering and Architecture Conference. Golden Light Publishing, 2023. http://dx.doi.org/10.31462/icearc.2023.cme960.
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STANGE, MATTHIAS. "RETROSPECTIVE STUDY ON THE ITERATIVE METHODS OF ARCHITECTURAL VISUALIZATION FROM THE NEOLITHIC TO THE DIGITAL BUILDING INFORMATION MODEL." In BIM 2021. Southampton UK: WIT Press, 2021. http://dx.doi.org/10.2495/bim210161.
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Li, Huijing. "Design of Building Engineering Information Fusion Method Based on BIM Model." In 2021 Smart City Challenges & Outcomes for Urban Transformation (SCOUT). IEEE, 2021. http://dx.doi.org/10.1109/scout54618.2021.00037.
Reports on the topic "BIM (Building Information Model)":
1
Kalin, Mark, and Robert Weygant. Specifiers Properties Information Exchange (SPie): Minimum Building Information Model (BIM) Object Definitions. Fort Belvoir, VA: Defense Technical Information Center, March 2013. http://dx.doi.org/10.21236/ada587606.
2
McGarrigle, M. Embedding Building Information Modelling into Construction Technology and Documentation Courses. Unitec ePress, November 2014. http://dx.doi.org/10.34074/rsrp.005.
Abstract:
The aim of this research is to generate a resource to assist construction lecturers in identifying opportunities where Building Information Modelling [BIM] could be employed to augment the delivery of subject content within individual courses on construction technology programmes. The methodology involved a detailed analysis of the learning objectives and underpinning knowledge of the course content by topic area, within the residential Construction Systems 1 course presently delivered at Unitec on the National Diplomas in Architectural Technology[NDAT], Construction Management [NDCM] and Quantity Surveying [NDQS]. The objective is to aid students’ understanding of specific aspects such as planning controls or sub-floor framing by using BIM models, and investigate how these could enhance delivery modes using image,animation and interactive student activity. A framework maps the BIM teaching opportunities against each topic area highlighting where these could be embedded into construction course delivery. This template also records software options and could be used in similar analyses of other courses within similar programmes to assist with embedding BIM in subject delivery.
3
McGarrigle, M. Embedding Building Information Modelling into Construction Technology and Documentation Courses. Unitec ePress, November 2014. http://dx.doi.org/10.34074/rsrp.005.
Abstract:
The aim of this research is to generate a resource to assist construction lecturers in identifying opportunities where Building Information Modelling [BIM] could be employed to augment the delivery of subject content within individual courses on construction technology programmes. The methodology involved a detailed analysis of the learning objectives and underpinning knowledge of the course content by topic area, within the residential Construction Systems 1 course presently delivered at Unitec on the National Diplomas in Architectural Technology[NDAT], Construction Management [NDCM] and Quantity Surveying [NDQS]. The objective is to aid students’ understanding of specific aspects such as planning controls or sub-floor framing by using BIM models, and investigate how these could enhance delivery modes using image,animation and interactive student activity. A framework maps the BIM teaching opportunities against each topic area highlighting where these could be embedded into construction course delivery. This template also records software options and could be used in similar analyses of other courses within similar programmes to assist with embedding BIM in subject delivery.
4
Rojas, Eddy, Carrie Dossick, and John Schaufelberger. Developing Best Practices for Capturing As-Built Building Information Models (BIM) for Existing Facilities. Fort Belvoir, VA: Defense Technical Information Center, August 2010. http://dx.doi.org/10.21236/ada554392.
5
Rojas, Eddy, Carrie Dossick, and John Schaufelberger. Evaluating Alternative Methodologies for Capturing As-Built Building Information Models (BIM) For Existing Facilities. Fort Belvoir, VA: Defense Technical Information Center, August 2010. http://dx.doi.org/10.21236/ada554414.
6
Li, Hang, Hosam Hegazy, Xiaorui Xue, Jiansong Zhang, and Yunfeng Chen. BIM Standards for Roads and Related Transportation Assets. Purdue University, 2023. http://dx.doi.org/10.5703/1288284317641.
Abstract:
With the industry foundation classes (IFC) building information modeling (BIM) standard (ISO 16739) being adopted by AASHTO as the national standard for modeling bridge and road infrastructure projects, there comes a great opportunity to upgrade the INDOT model development standard of roads and related assets to 2D+3D BIM. This upgrade complies with the national standard and creates a solid foundation for preserving accurate asset information for lifecycle data needs. This study reviewed the current modeling standards for drainage and pavement at different state DOTs and investigated the interoperability between state-of-the-art design modeling software and IFC. It was found that while the latest modeling software is capable of supporting interoperability with IFC, there remain gaps that must be addressed to achieve smooth interoperability for supporting life cycle asset data management. Specifically, the prevalent use of IfcBuildingElementProxy and IfcCourse led to a lack of differentiation in the use of IFC entities for the representations of different components, such as inlets, outfalls, conduits, and different concrete pavement layers. This, in turn, caused challenges in the quality assurance (QA) of IFC models and rendered the conventional model view definition (MVD)-based model checking insufficient. To address these gaps and push forward BIM for infrastructure at INDOT, efforts were made in this project to initially create model development instruction manuals that can serve as the foundation for further development and the eventual establish a consistent and comprehensive IFC-based modeling standards and protocols. In addition, automated object classification leveraging invariant signatures of architecture, engineering, and construction (AEC) objects was investigated. Correspondingly, a QA method and tool was developed to check and identify the different components in an IFC model. The developed tool achieved 91% accuracy on drainage and 100% accuracy in concrete pavement in its tested performance. These solutions aim to support the lifecycle management of INDOT transportation infrastructure projects using BIM and IFC.
7
Gonzalez-Esteban, Cristina. Black Sea Wreck Virtual Reconstruction to Reinvigorate Archaeological Data and Comparative Studies. Honor Frost Foundation, 2023. http://dx.doi.org/10.33583/mags2021.07.
Abstract:
This short report tests a repeatable methodology for creating detailed virtual reconstructions where the model is a scientific container of the reconstruction information. The project reconstructed a Black Sea shipwreck using a photogrammetry survey and proposed a hypothesis of how it would have looked prior to sinking. To this “shell”, the metadata and paradata were added using BIM: Extended Matrix and Graphic Scale of Evidence. Academically, the “source-based reconstruction” opened a new spectrum of questions related to the ship and its community (chronology, building, propulsion, usage). The models also reported potential as public engagement tools, displaying the scientific background of archaeology.
8
Guo, Xingzhou, Chi Tian, Jinwu Xiao, Yunfeng Chen, and Jiansong Zhang. Life Cycle Integration of Building Information Modeling in Infrastructure Projects. Purdue University, 2022. http://dx.doi.org/10.5703/1288284317356.
Abstract:
Building Information Modeling (BIM) can provide solutions to many challenges of asset management, such as missing data, incompatible software, and an unclear business process. However, current implementation of BIM in infrastructure projects has only considers limited factors, such as technology application and digital information delivery, while issues of system compatibility and information needs are still missing. Different aspects of a business are interdependent and an incompatible development of various factors might result in different levels of BIM implementation or even project failure. Comprehensive research is needed to explore the key factors and challenges of BIM implementation in infrastructure projects. This study conducted interviews and surveys with key stakeholders of infrastructure projects to explore the challenges and potential solutions of BIM implementation. Interviews were conducted with 37 professionals and surveys were conducted with 102 professional stakeholders, including owners, designers, contractors, and software vendors. Four main factors, challenges, and potential solutions were identified from content analysis of the interviews and further validated by the surveys. These factors include process factor (when), technology factor (how), people factor (who), and information factor (what). Corresponding solutions are proposed to refine the current workflow and practices.
9
Soto, Carolina, Sebastian Manriquez, Nayib Tala, Claudia Suaznabar, and Pauline Henriquez. Guía para la implementación de Building Information Modelling a nivel de pilotos en proyectos de construcción pública. Banco Interamericano de Desarrollo, November 2022. http://dx.doi.org/10.18235/0004528.
Abstract:
Este documento consolida las metodologías y aprendizajes de Planbim de Chile y del Banco Interamericano de Desarrollo (BID) en la incorporación de la metodología de Building Information Modelling (BIM) en proyectos piloto. En la región de América Latina y el Caribe (ALC), se observa un aumento gradual y consistente del número de proyectos de construcción que incorporan la metodología de BIM, ya sea por el requerimiento de los contratantes o por iniciativa propia de las firmas involucradas. El uso de BIM tiene un impacto positivo en la reducción de costos y plazos para la ejecución y la operación de las obras, y aumenta la trazabilidad, transparencia y sostenibilidad de los proyectos durante todo su ciclo de vida. Entre los desafíos más importantes para la adopción de BIM, cabe destacar el bajo uso de estándares y protocolos estructurados. Sin ellos, se produce una alta heterogeneidad en los procesos de trabajo con BIM, lo cual genera malentendidos y atrasos. Este documento se constituye en una herramienta práctica y aplicada que busca facilitar el proceso de implementación de BIM en proyectos de obras y edificaciones públicas de forma estandarizada y consistente con los estándares internacionales, y así contribuir a acelerar la adopción de BIM en ALC.
10
Carreño, Úrsula, Zoila Llempén, and Andrés Muñoz Miranda. El impulso del sector público en la implementación de Building Information Modelling en países de América Latina. Banco Interamericano de Desarrollo, January 2023. http://dx.doi.org/10.18235/0004711.
Abstract:
Building Information Modelling (BIM) es una innovación revolucionaria que, implementada adecuadamente, promete un importante ahorro en los gastos de infraestructura al facilitar la colaboración digital entre equipos multidisciplinarios para la planificación, el diseño, la construcción, y la operación de obras de infraestructura. Este estudio describe los avances y el impacto de la metodología BIM en países de América Latina. Sobre la base de información obtenida a partir de entrevistas realizadas a referentes del sector público, describe cómo se han superado los principales retos de gestión y capacitación, además de los fiscales y normativos. Concluye que si bien en América Latina el uso de BIM es incipiente por parte del sector público (se inició en Chile en 2016), existe un intenso trabajo de transición en los países focos del análisis: Brasil, Chile, Colombia, Costa Rica y Perú. Se destaca también el rol fundamental del liderazgo del sector público para la adopción de BIM, ya que dicho sector está en condiciones de disminuir los costos de transacción entre una mayor cantidad de actores, debido a que posibilita compartir y trabajar con la información, proponer y generar las vías o los canales de comunicación necesarios para fortalecer los mecanismos de transparencia y la rendición de cuentas, y permite considerar y gestionar adecuadamente los retos asociados: administrativos, legales, financieros, tecnológicos y de fortalecimiento de la capacidad institucional.