A. Satyanaga, Gerarldo Davin Aventian, Yerkezhan Makenova, Aigerim Zhakiyeva, Zhuldyz Kamaliyeva, Sung-Woo Moon, Jong R. Kim
{"title":"Building Information Modelling for Application in Geotechnical Engineering","authors":"A. Satyanaga, Gerarldo Davin Aventian, Yerkezhan Makenova, Aigerim Zhakiyeva, Zhuldyz Kamaliyeva, Sung-Woo Moon, Jong R. Kim","doi":"10.3390/infrastructures8060103","DOIUrl":null,"url":null,"abstract":"BIM (Building Information Modelling) is used to create and manage data during design, construction, and operation. It helps to effectively manage resources and optimize processes in the construction industry. Geotechnical engineering is one of the complex disciplines that may require BIM integration. Various data types must be provided in a timely manner and require real-time feedback, fast processing, and construction guidance. The first problem presented in the paper is the use of the traditional 2D-based method used by engineers for a particular task. It seems to be impractical when some adjustments are included. Another issue is the lack of communication between the workers. It poses the problem of information exchange and misunderstanding during the interpretation of technical data. This paper aims to find different integration techniques and steps for integrating geotechnical data into the BIM process. Methods used to examine the topic are qualitative research, literature review, and case studies. These methods were useful for studying the problems and introducing the soil information into the BIM application. Firstly, a case study with I-BIM was considered, and the BIM–FEM–BIM interaction was applied to introduce geotechnical information with Plaxis 3D. The results have shown that further development of BIM in infrastructure is needed. Another case study explored the present state of the geotechnical design in BIM and potential solutions. The new frameworks were recreated: many boreholes were imported to the BIM, and a 3D geometric model of the entire hill was created for the hill fortification structure with soil clogging. The last two studies in Malaysia modeled a 3D subsurface and used two geotechnical formats, AGS and CVS. The first includes more information than the second; however, the second can be used for a more generalized model. Overall, BIM–FEM interaction can be used as a geometric model for data transfer. However, the open data format of the Industry Foundation Class (IFC) or geotechnical data format of the AGS and CVS were suggested to be used for greater flexibility. It was also found that excessive information makes the model loaded and complex. Therefore, it was recommended that big data be summarized properly with minimal loss of necessary data. Further research is needed to understand data transmission schemes of geotechnical information better. Moreover, it is recommended to put all the strategies directly into practice to create a geotechnical design.","PeriodicalId":13601,"journal":{"name":"Infrastructures","volume":" ","pages":""},"PeriodicalIF":2.7000,"publicationDate":"2023-06-06","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"2","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Infrastructures","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.3390/infrastructures8060103","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"CONSTRUCTION & BUILDING TECHNOLOGY","Score":null,"Total":0}
引用次数: 2
Abstract
BIM (Building Information Modelling) is used to create and manage data during design, construction, and operation. It helps to effectively manage resources and optimize processes in the construction industry. Geotechnical engineering is one of the complex disciplines that may require BIM integration. Various data types must be provided in a timely manner and require real-time feedback, fast processing, and construction guidance. The first problem presented in the paper is the use of the traditional 2D-based method used by engineers for a particular task. It seems to be impractical when some adjustments are included. Another issue is the lack of communication between the workers. It poses the problem of information exchange and misunderstanding during the interpretation of technical data. This paper aims to find different integration techniques and steps for integrating geotechnical data into the BIM process. Methods used to examine the topic are qualitative research, literature review, and case studies. These methods were useful for studying the problems and introducing the soil information into the BIM application. Firstly, a case study with I-BIM was considered, and the BIM–FEM–BIM interaction was applied to introduce geotechnical information with Plaxis 3D. The results have shown that further development of BIM in infrastructure is needed. Another case study explored the present state of the geotechnical design in BIM and potential solutions. The new frameworks were recreated: many boreholes were imported to the BIM, and a 3D geometric model of the entire hill was created for the hill fortification structure with soil clogging. The last two studies in Malaysia modeled a 3D subsurface and used two geotechnical formats, AGS and CVS. The first includes more information than the second; however, the second can be used for a more generalized model. Overall, BIM–FEM interaction can be used as a geometric model for data transfer. However, the open data format of the Industry Foundation Class (IFC) or geotechnical data format of the AGS and CVS were suggested to be used for greater flexibility. It was also found that excessive information makes the model loaded and complex. Therefore, it was recommended that big data be summarized properly with minimal loss of necessary data. Further research is needed to understand data transmission schemes of geotechnical information better. Moreover, it is recommended to put all the strategies directly into practice to create a geotechnical design.
BIM (Building Information modeling)用于在设计、施工和运营过程中创建和管理数据。它有助于有效地管理建筑行业的资源和优化流程。岩土工程是一门复杂的学科,可能需要BIM集成。各种数据类型必须及时提供,需要实时反馈、快速处理和施工指导。本文提出的第一个问题是工程师在特定任务中使用传统的基于2d的方法。当包括一些调整时,它似乎是不切实际的。另一个问题是工人之间缺乏沟通。它在技术数据解释过程中产生了信息交换和误解的问题。本文旨在寻找将岩土工程数据集成到BIM过程中的不同集成技术和步骤。用于检查主题的方法是定性研究,文献综述和案例研究。这些方法对于研究问题和将土壤信息引入BIM应用程序非常有用。首先,以I-BIM为例,采用BIM-FEM-BIM交互方式引入Plaxis 3D岩土工程信息。结果表明,BIM在基础设施中的进一步发展是必要的。另一个案例研究探讨了BIM中岩土工程设计的现状和潜在的解决方案。新的框架被重新创建:许多钻孔被导入到BIM中,整个山丘的3D几何模型被创建为具有土壤堵塞的山丘防御结构。在马来西亚进行的最后两项研究模拟了三维地下,并使用了两种岩土技术格式,AGS和CVS。第一种比第二种包含更多的信息;然而,第二种方法可以用于更一般化的模型。总体而言,BIM-FEM相互作用可以作为数据传递的几何模型。然而,建议采用工业基础等级(IFC)的开放数据格式或AGS和CVS的岩土数据格式,以获得更大的灵活性。研究还发现,过多的信息会使模型负载过重,变得复杂。因此,建议对大数据进行适当的汇总,尽量减少必要数据的损失。为了更好地理解岩土工程信息的数据传输方案,需要进一步的研究。此外,建议将所有策略直接付诸实践,以创建岩土工程设计。