Literatura académica sobre el tema "BIM - Building Information Modeling"

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.

The article is devoted to evaluation of the possibility of usage BIM for existing buildings. While BIM processes are established for new buildings, the majority of existing buildings is not maintained, refurbished or deconstructed with BIM yet. However, it can play a significant role for better operation and maintenance and building facility management. Research in creating BIM for existing buildings has received growing attention in recent years. The objective of this paper is to explore potential opportunities and barriers in constructing BIM for existing buildings

As is common knowledge now, in 2016 it will be mandatory to use BIM on all public sector projects. This has clearly spurned a lot of interest in BIM within the construction industry. However, the industry appears to be struggling to find its feet as to what it needs to have in place before BIM based projects become a reality. Uses of BIM technology and associated processes have been categorized into 3 levels and the 2016 requirement is for Level 2 implementations only. This paper outlines the requirements of level 2 BIM implementation and assesses the status of the industry as a whole as to its readiness. There are various pre-requisites that need to be in place, mostly in relation to process protocols and standards. This paper gives an understanding of the roadmap that needs to be traversed in order to be ready for BIM. This paper presents an outline of the UK Government’s requirements for 2016 before discussing and assessing the UK construction industry’s readiness. Finally, the paper gives an outline of what needs to be in place for the government’s ambitions to be achieved as well as a summary of some of the challenges along the way and possible ways of addressing some of them.

With the ever-increasing population and historic highest energy demand, the energy efficiency of buildings is becoming crucial. Architectural firms are moving from traditional Computer-Aided Design (CAD) to BIM. However, nearly 40% of the energy consumption is due to buildings. Therefore, there is a need to integrate BIM with Building Energy Modeling (BEM), which presents an innovative opportunity to demonstrate the potential of BIM to minimize energy consumption by integrating building information software with data from existing energy-efficient building automation systems (EBAS). BEM is a form of computational analysis that can be used in conjunction with BIM or Computer-Aided Engineering (CAE) systems. In this paper, an attempt has been made to explore the existing literature on BIM and BEM and identify the effect of the integration of BEM in BIM in the design phase of the project. A recent survey from the last ten years (2012 to 2023) was carried out on Google Scholar, Web of Science, Science Direct, and Scopus databases. Inclusion/exclusion criteria were applied, and papers were scrutinized. From the results, it can be observed that the convergence of BIM and BEM is found to be useful in practical applications; however, projects with short life cycles might not be suitable for this solution. Challenges exist in the interoperability tools which have restrictions on data exchange. Binary translation is found to be the most suitable candidate for data exchange. The analysis further showed that the most used program for integrating BIM/BEM is Green Building Studio developed by Autodesk to improve construction and operational efficiencies.

With the advancement of Building Information Modeling (BIM) technology, BIM gains more importance and becomes a prerequisite in building projects. BIM is useful throughout a building lifecycle; from building bid, design, construction, completion, operation, and maintenance to building demolition. However, current information exchange surrounding BIM is still limited and bound to a single participant or organization and is also limited to a particular phase in the building lifecycle. This paper aims to explore BIM information exchange among many parties involved in a secure manner using a blockchain platform throughout the whole building lifecycle. In this research, many parties involved in the building project will be able to recognize one another through deployment of a permissioned blockchain. This information exchange uses Hyperledger Composer, a permissioned blockchain running on a blockchain platform called Hyperledger Fabric. Our experiment shows that BIM information exchange could be further improved. In this study, BIM information exchange can be implemented not only in one building phase but throughout the whole building lifecycle. It also facilitates BIM information exchange among multiple participants in a secure manner via a permissioned blockchain.

Abstract Building Information Modelling (BIM) has a high potential to assist in designing a green building. Integrating BIM and building rating tools can help designers design buildings that fit the minimum requirements of green certification. Without BIM, green certifications are performed manually and after project completion. Incorporating BIM and building rating tools in the early decision-making process of a project is more significant to enhance building sustainability. The study aims to review the extent of integration of building rating tools with BIM for green certification in the current research. Upon screening the relevant publications, it is discovered that only a small number of studies have been conducted that link BIM and green assessment tools. Only a total of 19 studies are eligible for the review process. The content analysis results of these studies point out that LEED is the most used building rating tool for integration with BIM. The integration is mostly made by using Autodesk Revit and Dynamo. The major focus for the integration is on the energy and atmosphere sub-category as the credit allocation is the highest. More studies integrating the BIM-building rating tool are needed to automate the green certification process.

Die Anforderungen an den Planungsprozess, insbesondere hinsichtlich der Planungsqualität, nehmen bei steigendem Kostendruck immer mehr zu. Gleichzeitig verlaufen der Planungs- sowie der begleitende Kommunikationsprozess zwischen den unterschiedlichen beteiligten Gewerken zunehmend digital. Der Planungsansatz des Building Information Modeling (BIM) verfolgt eben diese Ziele, im Wesentlichen aber bei der Planung und dem Betrieb von Gebäuden. Im Beitrag wird untersucht, wie sich der BIM-Ansatz auf die Fabrikplanung übertragen lässt.   The requirements of the planning process, in particular with regard to the planning quality, rise more and more with increasing cost pressure. At the same time, the planning process and the accompanying communication process between the different work areas involved are increasingly digital. The planning approach of Building Information Modeling (BIM) pursues precisely these goals, but essentially in the planning and operation of buildings. The article examines how the BIM approach can be transferred to factory planning.

The use BIM technology for new buildings have been proving his efficiency since the technology had established, the efficiency in costs estimation, construction management, resource saving incresed the interest to use BIM for existing building. The researchers covered a wide range of potential benefits for BIM in existing buildings such as: Facilities management, restoration and retrofit planning, deconstruction process, assessment and monitoring, maintenance and energy efficiency. In this paper the use of BIM for estimating the degree of physical deterioration is covered, based on the method included in the literature in Russian federation.

"Nowadays, many companies in the Architecture/Engineering/Construction (AEC) industry are using Building Information Modeling (BIM) in achieving a faster, sustainable and more economic project. Among the new developed concepts and BIM applications, two of the concepts most frequently used with the support of BIM technology in the planning, organization and scheduling of projects are 4D and 5D in which a 3D model is tied to its time execution (4D) at any point in time and its corresponding cost (5D). However, most of these applications concentrate on modeling the building but it does not include a corresponding modeling of the site in which the building is located. To date, there are few studies and systematic implementation of the site and the building integrated into one BIM model. This site-building integrated model can also be conceptualized as ¡°6D BIM¡± model. The benefit of integrating the site and building together into one model is that the building is no longer treated in isolation of its surround site but incorporates extremely helpful short-term and long-term information for the owner, designer, and builder regarding site topography, landscaping, access roads, ground conditions and the location of site utilities. Major existing research and technology issues that are preventing this site-building integration deal with functionality and interoperability of the BIM software, different orientation and coordination of building model and site model. The objectives of this thesis are to explore current organizational and technological issues preventing this integration, to investigate a feasible method to create a site-linked BIM model, and to discuss the benefits and limitations of bringing BIM concept to the site conditions. The research has been conducted by an extensive review on the literature related to the topic of interest published primarily by AEC. A review on current applications of Geographic Information Systems (GIS) has also been included because of the wider context provided by this technology to the specific topic of this research. Related BIM software developed by three different vendors ¡ªhas been discussed and compared to determine the level of feasibility and operational features of technological support necessary to implement the site-linked BIM model. A case study based on the design and construction of the WPI Recreational & Sports Center, currently under construction, was developed to explore and understand the details that are involved in creating a new site model and to link it with the existing 3D building model. What has been learned from the analysis of this case study is presented, discussed and analyzed in terms of benefits and limitations. Recommendations for future extensions from both the research aspect and the technology support aspect finally presented. These include the creation of 3D BIM Campus Map, which is one site model with several building models placed on it to facilitate future planning of new building and/or maintenance and operation of the current buildings and campus infrastructure.   "

Tese de Doutoramento em Arquitetura, com a especialização em Conservação e Restauro apresentada na Faculdade de Arquitetura da Universidade de Lisboa para obtenção do grau de Doutor.
As metodologias associadas ao software BIM (Building Information Modeling) representam nos dias de hoje um dos sistemas integrados mais utilizado para a construção de novos edifícios. Ao usar BIM no desenvolvimento de projetos, a colaboração entre os diferentes intervenientes num projeto de arquitetura, engenharia e construção, melhora de um modo muito significativo. Esta tecnologia também pode ser aplicada para intervenções em edifícios existentes. Na presente tese pretende-se melhorar os processos de registo, documentação e gestão da informação, recorrendo a ferramentas BIM para estabelecer um conjunto de diretrizes de fluxo de trabalho, para modelar de forma eficiente as estruturas existentes a partir de nuvens de pontos, complementados com outros métodos apropriados. Há vários desafios que impedem a adoção do software BIM para o planeamento de intervenções em edifícios existentes. Volk et al. (2014) indica que os principais obstáculos de adoção BIM são o esforço de modelação/conversão dos elementos do edifício captados em objetos BIM, a dificuldade em actualizar informação em BIM e as dificuldades em lidar com as incertezas associadas a dados, objetos e relações que ocorrem em edifícios existentes. A partir desta análise, foram desenvolvidas algumas diretrizes de fluxo de trabalho BIM para modelação de edifícios existentes. As propostas indicadas para as diretrizes BIM em edifícios existentes, incluem tolerâncias e standards para modelar elementos de edifícios existentes. Tal metodologia permite que as partes interessadas tenham um entendimento e um acordo sobre o que é suposto ser modelado. Na presente tese, foi investigado um conjunto de tópicos de pesquisa que foram formuladas e colocadas, enquadrando os diferentes obstáculos e direcionando o foco de pesquisa segundo quatro vectores fundamentais: 1. Os diferentes tipos de dados de um edifício que podem ser adquiridos a partir de nuvens de pontos; 2. Os diferentes tipos de análise de edifícios; 3. A utilização de standards e BIM para edifícios existentes; 4. Fluxos de trabalho BIM para edifícios existentes e diretrizes para ateliers de arquitectura. A partir da pesquisa efetuada, pode-se concluir que é há necessidade de uma melhor utilização da informação na tomada de decisão no âmbito de um projeto de intervenção arquitetónica. Diferentes tipos de dados, não apenas geométricos, são necessários como base para a análise dos edifícios. Os dados não geométricos podem referir-se a características físicas do tecido construído, tais como materiais, aparência e condição. Além disso, o desempenho ambiental, estrutural e mecânico de um edifício, bem como valores culturais, históricos e arquitetónicos, essenciais para a compreensão do seu estado atual. Estas informações são fundamentais para uma análise mais profunda que permita a compreensão das ações de intervenção que são necessárias no edifício. Através de tecnologias Fotogrametria (ADP) e Laser Scanning (TLS), pode ser gerada informação precisa e actual. O produto final da ADP e TLS são nuvens de pontos, que podem ser usadas de forma complementar. A combinação destas técnicas com o levantamento tradicional Robotic Total Station (RTS) fornece uma base de dados exata que, juntamente com outras informações existentes, permitem o planeamento adequado da intervenção. Os problemas de utilização de BIM para intervenção em edifícios existentes referem-se principalmente à análise e criação de geometria do edifício, o que geralmente é uma etapa prévia para a conexão de informação não-geométrica de edifícios. Por esta razão, a presente tese centra-se principalmente na busca de diretrizes para diminuir a dificuldade em criar os elementos necessários para o BIMs. Para tratar dados incertos e pouco claros ou informações semânticas não visíveis, pode-se complementar os dados originais com informação adicional. Os fluxos de trabalho apresentados na presente tese focam-se principalmente na falta de informação visível. No caso de projetos de remodelação, a informação não visível pode ser adquirida de forma limitada através de levantamentos ADP ou TLS após a demolição de alguns elementos e/ou camadas de parede. Tal metodologia permite um melhor entendimento das camadas de materiais não visíveis dos elementos do edifício, quando a intervenção é uma demolição parcial. Este processo é útil apenas se uma parte do material do elemento é removida e não pode ser aplicada a elementos não intervencionados. O tratamento da informação em falta pode ser feito através da integração de diferentes tipos de dados com diferentes origens. Devem ser implementados os fluxos de trabalho para a integração da informação. Diferentes fluxos de trabalho podem criar informação em falta, usada como complemento ou como base para a tomada de decisão quando não há dados disponíveis. Relativamente à adição de dados em falta através da geração de nuvem de pontos, os casos de estudo destacam a importância de planear o levantamento, fazendo com que todas as partes compreendam as necessidades associadas ao projeto. Além da precisão, o nível de tolerância de interpretação e modelação, requeridos pelo projeto, também devem ser acordados e entendidos. Nem todas as ferramentas e métodos de pesquisa são adequados para todos os edifícios. A escala, os materiais e a acessibilidade do edifício desempenham um papel importante no planeamento do levantamento. Para lidar com o elevado esforço de modelação, é necessário entender os fluxos de trabalho necessários para analisar a geometria dos elementos do edifício. Os BIMs construídos são normalmente gerados manualmente através de desenhos CAD e/ou nuvens de pontos. Estes são usados como base geométrica a partir da qual a informação é extraída. A informação utilizada para planear a intervenção do edifício deve ser verificada, confirmando se é uma representação do estado actual do edifício. As técnicas de levantamento 3D para capturar a condição atual do edifício devem ser integradas no fluxo de trabalho BIM, construído para capturar os dados do edifício sobre os quais serão feitas as decisões de intervenção. O resultado destas técnicas deve ser integrado com diferentes tipos de dados para fornecer uma base mais precisa e completa. O atelier de arquitetura deve estar habilitado com competências técnicas adequadas para saber o que pedir e o que utilizar da forma mais adequada. Os requisitos de modelação devem concentrar-se principalmente no conteúdo deste processo, ou seja, o que modelar, como desenvolver os elementos no modelo, quais as informações que o modelo deve conter e como deve ocorrer a troca de informações no modelo. O levantamento das nuvens de pontos deve ser efectuado após ter sido estipulado o objetivo do projeto, standards, tolerâncias e tipo de conteúdo na modelação. As tolerâncias e normas de modelação são diferentes entre empresas e países. Independentemente destas diferenças, os documentos standard têm como objetivo produzir e receber informação num formato de dados consistente e em fluxos de trabalho de troca eficiente entre os diferentes intervenientes do projeto. O pensamento crítico do fluxo de trabalho de modelação e a comunicação e acordo entre todas os intervenientes são os principais objetivos das diretrizes apresentadas nesta tese. O estabelecimento e o acordo de tolerâncias de modelação e o nível de desenvolvimento e detalhes presentes nas BIMs, entre as diferentes partes envolvidas no projeto, são mais importantes do que as definições existentes atualmente e que são utilizadas pela indústria da AEC. As ferramentas automáticas ou semi-automáticas para extração da forma geométrica, eliminação ou redução de tarefas repetitivas durante o desenvolvimento de BIMs e a análise de condições de ambiente ou de cenários, são também um processo de diminuição do esforço de modelação. Uma das razões que justifica a necessidade de standards é a estrutura e a melhoria da colaboração, não só para os intervenientes fora da empresa, mas também dentro dos ateliers de arquitetura. Os dados e standards de fluxo de trabalho são difíceis de implementar diariamente de forma eficiente, resultando muitas vezes em dados e fluxos de trabalho confusos. Quando tal situação ocorre, a qualidade dos resultados do projeto reduz-se e pode ficar comprometida. As normas aplicadas aos BIMs construídos, exatamente como as normas aplicadas aos BIMs para edifícios novos, contribuem para a criação de informação credível e útil. Para atualizar um BIMs durante o ciclo de vida de um edifício,é necessário adquirir a informação sobre o estado actual do edifício. A monitorização de dados pode ser composta por fotografias, PCM, dados de sensores, ou dados resultantes da comparação de PCM e BIMs e podem representar uma maneira de atualizar BIMs existentes. Isto permite adicionar continuamente informações, documentando a evolução e a história da construção e possibilita avaliar possíveis intervenções de prevenção para a sua valorização. BIM não é geralmente usado para documentar edifícios existentes ou intervenções em edifícios existentes. No presente trabalho propõe-se melhorar tal situação usando standards e/ou diretrizes BIM e apresentar uma visão inicial e geral dos componentes que devem ser incluídos em tais standards e/ou linhas de orientação.
ABSTRACT: Building information modeling (BIM) is most often used for the construction of new buildings. By using BIM in such projects, collaboration among stakeholders in an architecture, engineering and construction project is improved. This scenario might also be targeted for interventions in existing buildings. This thesis intends to enhance processes of recording, documenting and managing information by establishing a set of workflow guidelines to efficiently model existing structures with BIM tools from point cloud data, complemented with any other appropriate methods. There are several challenges hampering BIM software adoption for planning interventions in existing buildings. Volk et al. (2014) outlines that the as-built BIM adoption main obstacles are: the required modeling/conversion effort from captured building data into semantic BIM objects; the difficulty in maintaining information in a BIM; and the difficulties in handling uncertain data, objects, and relations occurring in existing buildings. From this analysis, it was developped a case for devising BIM workflow guidelines for modeling existing buildings. The proposed content for BIM guidelines includes tolerances and standards for modeling existing building elements. This allows stakeholders to have a common understanding and agreement of what is supposed to be modeled and exchanged.In this thesis, the authors investigate a set of research questions that were formed and posed, framing obstacles and directing the research focus in four parts: 1. the different kind of building data acquired; 2. the different kind of building data analysis processes; 3. the use of standards and as-built BIM and; 4. as-built BIM workflows and guidelines for architectural offices. From this research, the authors can conclude that there is a need for better use of documentation in which architectural intervention project decisions are made. Different kind of data, not just geometric, is needed as a basis for the analysis of the current building state. Non-geometric information can refer to physical characteristics of the built fabric, such as materials, appearance and condition. Furthermore environmental, structural and mechanical building performance, as well as cultural, historical and architectural values, style and age are vital to the understanding of the current state of the building. These information is necessary for further analysis allowing the understanding of the necessary actions to intervene. Accurate and up to date information information can be generated through ADP and TLS surveys. The final product of ADP and TLS are the point clouds, which can be used to complement each other. The combination of these techniques with traditional RTS survey provide an accurate and up to date base that, along with other existing information, allow the planning of building interventions. As-built BIM adoption problems refer mainly to the analysis and generation of building geometry, which usually is a previous step to the link of non-geometric building information. For this reason the present thesis focus mainly in finding guidelines to decrease the difficulty in generating the as-built-BIMs elements. To handle uncertain data and unclear or hidden semantic information, one can complement the original data with additional missing information. The workflows in the present thesis address mainly the missing visible information. In the case of refurbishment projects the hidden information can be acquired to some extend with ADP or TLS surveys after demolition of some elements and wall layers. This allows a better understanding of the non visible materials layers of a building element whenever it is a partial demolition. This process is only useful if a part of the element material is removed, it can not be applied to the non intervened elements. The handling of visible missing data, objects and relations can be done by integrating different kind of data from different kind of sources. Workflows to connect them in a more integrated way should be implemented. Different workflows can create additional missing information, used to complement or as a base for decision making when no data is available. Relating to adding missing data through point cloud data generation the study cases outlined the importance of planning the survey, with all parts understanding what the project needs are. In addition to accuracy, the level of interpretation and modelling tolerances, required by the project, must also be agreed and understood. Not all survey tools and methods are suitable for all buildings: the scale, materials and accessibility of building play a major role in the survey planning. To handle the high modeling/conversion effort one has to understand the current workflows to analyse building geometry. As-built BIMs are majorly manually generated through CAD drawings and/or PCM data. These are used as a geometric basis input from where information is extracted. The information used to plan the building intervention should be checked, confirming it is a representation of the as-is state of the building. The 3D surveys techniques to capture the as-is state of the building should be integrated in the as-built BIM workflow to capture the building data in which intervention decisions are made. The output of these techniques should be integrated with different kind of data to provide the most accurate and complete basis. The architectural company should have technical skills to know what to ask for and to use it appropriately. Modeling requirements should focus primarily on the content of this process: what to model, how to develop the elements in the model, what information should the model contain, and how should information in the model be exchanged. The point clouds survey should be done after stipulating the project goal, standards, tolerances and modeling content. Tolerances and modeling guidelines change across companies and countries. Regardless of these differences the standards documents have the purpose of producing and receiving information in a consistent data format, in efficient exchange workflows between project stakeholders. The critical thinking of the modeling workflow and, the communication and agreement between all parts involved in the project, is the prime product of this thesis guidelines. The establishment and agreement of modeling tolerances and the level of development and detail present in the BIMs, between the different parts involved on the project, is more important than which of the existing definitions currently in use by the AEC industry is chosen. Automated or semi-automated tools for elements shape extraction, elimination or reduction of repetitive tasks during the BIMs development and, analysis of environment or scenario conditions are also a way of decreasing the modeling effort. One of the reasons why standards are needed is the structure and improvement of the collaboration not only with outside parts but also inside architectural offices. Data and workflow standards are very hard to implement daily, in a practical way, resulting in confusing data and workflows. These reduce the quality of communication and project outputs. As-built BIM standards, exactly like BIM standards, contribute to the creation of reliable and useful information. To update a BIMs during the building life-cycle, one needs to acquire the as-is building state information. Monitoring data, whether consisted by photos, PCM, sensor data, or data resulting from the comparison of PCM and BIMs can be a way of updating existing BIMs. It allows adding continuously information, documenting the building evolution and story, and evaluating possible prevention interventions for its enhancement. BIM environments are not often used to document existing buildings or interventions in existing buildings. The authors propose to improve the situation by using BIM standards and/or guidelines, and the authors give an initial overview of components that should be included in such a standard and/or guideline.
N/A

Building Information Modeling (BIM) is the latest development in the Architecture, Engineering and Construction (AEC) Industry. This development can be used for planning, design, construction, operation and maintenance of any facility. The majority of the users of BIM technology are architects. Although its benefits had been highlighted and underlined especially in comparison with older developments such us Computer Aided Design (CAD) tools, its implementation is considered still in an early stage due to low adoption from architects. Right now in Sweden and more specifically in the Stockholm area, the construction sector is booming due to the increased demand for housing.  Thus, there is an increased demand for more houses in a shorter time. BIM is a technology that can enhance the society in terms of design and construction with regard to the building environment. This can be achieved by avoiding human errors, decreasing project costs, increasing the productivity and quality, and reducing the project delivery time. Moreover, BIM can assist the management team in maintaining and operating different facilities. The focus of this research is on the barriers to adopting BIM technology in architectural companies. Furthermore, the attempt will be to investigate the individual, organizational and technical aspects that affect BIM adoption.  This study will implement a qualitative research method by in-depth interviewing four professionals in the area of architectural design. This investigation will be driven by the main research question, which is: What are the barriers to adopting Building Information Modeling (BIM) in architectural companies?

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

This thesis treats Building Information Modeling, BIM, in the production stage. Briefly described BIM is virtual model of a building object where all information about the object is gathered. All the involved operators in the construction project have access to the model and can gather or share information about the project. There are several ways to apply BIM in the production stage. This thesis primarily deals with visualization of the object, preparation and planning, the ability to take amounts from the model and coordination and clash control. The basic issue was highlighted by Byggdialog AB. The company has a vision about how they want to use BIM in all the different stages in a building project. Byggdialog want their partnering entrepreneurs to develop their BIM usage in the production stage in order to fulfill this vision. Goodtech is one of Byggdialogs partnering entrepreneurs and is the company that has been studied during this thesis. The goal with this thesis was to develop proposals as to how the BIM usage in the production stage can improve. The purpose was to make the partnering entrepreneurs understand why it is important and helpful to use BIM. The intention was also that other partnering entrepreneurs should be able to use this thesis while working with BIM in the production stage. The methods to collect information have been visits to construction sites, literature search, and interviews. The interviewees represented different operators that can affect the usage of BIM in the production stage. This thesis resulted in concrete proposals as to how the partnering entrepreneur can improve their BIM usage. Proposals as to how Byggdialog can ensure that their entrepreneurs are using BIM correct have also been developed. Today the partnering entrepreneur uses BIM to visualize the building object. As a suggestion the entrepreneur should also use the BIM model while preparing and planning their work and in order to calculate material amounts . It’s important that the entrepreneur understand how the model can be used and what kind of information it contains in order to enable these applications. It’s also important that the design phase is carefully executed. Proposals as to how this can be achieved is to educate the staff in BIM and how it should be used, that the partnering entrepreneur participates in the coordination meetings and that the partnering entrepreneur place greater demands on their electrical consultant. In order for Byggdialog to ensure that their partnering entrepreneurs are using BIM correct they should offer them education about BIM and how it works, make the BIMmodel more user-friendly and place demands on how they want BIM to be used in the project specifications.
Detta examensarbete handlar om byggnadsinformationsmodellering, BIM, i produktionen. Kort förklarat är BIM en virtuell modell av ett byggobjekt, där all information som rör byggnaden samlas. Alla aktörer i ett byggprojekt har tillgång till denna modell och kan, genom denna, samla in eller dela ut information som rör objektet. Det finns olika tillämpningar av BIM i produktionen, denna studie behandlar främst visualisering, arbetsberedning och planering, mängdavtagning och samordning och kollisionskontroller. Grundproblematiken lyftes fram med hjälp av uppdragsgivaren Byggdialog AB. Företaget har en vision om hur BIM ska användas i byggprocessens olika skeden. Byggdialog upplever att deras partneringentreprenörer, PE, bör utveckla sin BIManvändning i produktionen för att denna vision ska kunna uppfyllas. Goodtech är en av Byggdialogs partneringentreprenörer och är det företag som studerats i detta examensarbete. Målet med arbetet var att, med utgångspunkt från teorier samt Byggdialogs vision, ge förslag till hur partneringentreprenören kan utveckla BIM-användningen i produktionen. Syftet var att få partneringentreprenören att förstå nyttan med att använda BIM i produktionsskedet. Avsikten har också varit att andra partneringentreprenörer ska ha nytta av denna studie vid användning av BIM i produktionen. De metoder som användes var studiebesök, litteraturstudie och intervjustudie. Intervjuobjekten representerade olika yrkeskategorier som alla kan påverka användningen av BIM i produktionen. Detta examensarbete resulterade i konkreta förslag till hur partneringentreprenören kan förbättra BIM användningen. Även förslag till hur Byggdialog kan säkerställa att deras PE använder BIM korrekt togs fram. Idag använder partneringentreprenören BIM främst för att visualisera byggobjektet. Förslagsvis bör de även använda BIM vid arbetsberedning/planering av arbetet. Partneringentreprenören har också förutsättningar för mängdavtagning ur modellen. För att möjliggöra dessa tillämpningar är det viktigt att partneringentreprenören förstår hur 3D - modellen kan användas, samt vilken information som finns i den. Det är även viktigt att modellen är noggrant projekterad. Förslag till hur detta kan uppnås är genom att partneringentreprenören utbildar sig inom BIM och hur det används, att de deltar i BIM-samordningsmötena samt att de ställer högre krav på sin elprojektör. Byggdialog kan säkerställa att deras PE använder BIM korrekt genom att erbjuda utbildningstillfällen, anpassa BIM-modellen efter användaren och ställa krav i förfrågningsunderlaget.

Dalla raffigurazione artistica fino alla modellazione digitale, passando per il disegno tecnico, la rappresentazione del progetto d’architettura ha conosciuto nel tempo evoluzioni significative che solo di recente hanno raggiunto l’apice nell’utilizzo di modelli cognitivi in grado di collezionare ed organizzare il patrimonio di informazioni che gravitano attorno all’intero processo edilizio. L’impiego sempre più diffuso dello strumento informatico, insieme al coordinamento delle specializzazioni nelle molte discipline coinvolte nel progetto, ha favorito negli ultimi anni l’adozione del Building Information Modeling un processo che permette di rivoluzionare il mondo delle costruzioni, coprendo molteplici aspetti del ciclo di vita per un manufatto edilizio. Questa Tesi intende presentare in maniera specifica le tappe che hanno consentito il formarsi del BIM. La migliore capacità di gestione, un linguaggio comune tra i progettisti, un’ottimizzazione di risorse e costi, unito ad un controllo convincente ed accurato delle fasi di lavoro, sono alcune delle potenzialità non ancora completamente espresse dal Building Information Modeling che è destinato a divenire una consapevolezza strategica nel bagaglio culturale del professionista contemporaneo.

Integrated building design necessitates the Architecture-Engineering-Construction-Owner-Operator (AECOO) Industry’s participants to collaborate efficiently with each other through the different phases of a building. Nevertheless, to reduce the energy consumption and CO2 emissions of a building, the emphasis is on the early design phases, since if accurate energy calculations and strategies are developed in an early design stage, the sustainable footprint of the building will be significantly reduced. That said, Building Information Modelling (BIM) promotes collaboration among the stakeholders by allowing them to design and store and access the data related to a project into one building information model. Furthermore, this model can be used for energy analysis through Building Energy Modelling (BEM) tools in the early design stages of the project, and through the whole life-cycle. For this, BIM and BEM tools must be able to communicate and exchange information with one another, seamlessly. This means that these tools should be interoperable. However, currently, there are some issues in the BIM to BEM exchange process, which obliges the user to check for the interoperability issues and fix them manually. Therefore, as a result of these interoperability issues, the BIM to BEM process in not automated, and creating an accurate BIM-based BEM is quite time-consuming, laborious and prone to human-made errors. Hence, this thesis aims to systematically investigate the interoperability issues and the state of automated data exchange between BIM and BEM tools, based on the Industry Foundation Class (IFC) exchange data schema. For this, Revit and IDA-ICE are used as BIM, and BEM tools, respectively. The outcome is the presentation of a set of interoperability issues that were found based on the investigation of 19 case studies, with some suggestions for Revit and IDA-ICE developers and future researchers in the end.

O Building Information Modeling (BIM) para Facility Management (FM) é um método para fornecer ambientes de trabalho seguros, eficazes e eficientes. A manutenção é o período mais longo no ciclo de vida de um edifício, onde a maioria (85%) das despesas operacionais naturalmente se acumulam. No entanto, devido à falta de conhecimento sobre o assunto, muitos gerentes não dão a devida importância ao FM. Para tanto, foi realizada uma Revisão Sistemática da Literatura (RSL) com o objetivo de identificar os temas de pesquisa mais frequentes para a FM com a adoção do BIM, bem como as ferramentas mais utilizadas para o BIM-FM.Esta pesquisa foi desenvolvida como uma parte inicial de uma dissertação de mestrado. Os resultados das pesquisas de 2010 a 2018 relacionadas à aplicação do BIM no Gerenciamento de Instalações são apresentados neste artigo. No total, 81 artigos foram analisados. A ferramenta BIM mais utilizada foi o Revit e, para FM, o padrão COBie. O assunto mais explorado na literatura revisada é a “Proposta da estrutura BIM-FM” e, por isso, uma estrutura BIM-FM é proposta. Há uma lacuna quando se trata de custos na implementação e operação do BIM-FM, abrindo espaço para pesquisas sobre o assunto.

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.

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.

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.

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.

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.

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.