Whole-Process Project Cost Management Based on Building Information Modeling (BIM)

The whole-process project cost management based on building information modeling(BIM)is a new management method,aiming to realize the comprehensive optimization and improvement of project cost management through the application of BIM technology.This paper summarizes and analyzes the whole-process project cost management based on BIM,aiming to explore its application and development prospects in the construction industry.Firstly,this paper introduces the role and advantages of BIM technology in engineering cost management,including information integration,data sharing,and collaborative work.Secondly,the paper analyzes the key technologies and methods of the whole-process project cost management based on BIM,including model construction,data management,and cost control.In addition,the paper also discusses the challenges and limitations of the whole-process BIM project cost management,such as the inconsistency of technical standards,personnel training,and consciousness change.Finally,the paper summarizes the advantages and development prospects of the whole-process project cost management based on BIM and puts forward the direction and suggestions for future research.Through the research of this paper,it can provide a reference for construction cost management and promote innovation and development in the construction industry.

Integrating Virtual Reality and Energy Analysis with BIM to Optimize Window-to-Wall Ratio and Building’s Orientation for Age-in-Place Design at the Conceptual Stage

This study unfolds an innovative approach aiming to address the critical role of building design in global energy consumption, focusing on optimizing the Window-to-Wall Ratio (WWR), since buildings account for approximately 30% of total energy consumed worldwide. The greatest contributors to energy expenditure in buildings are internal artificial lighting and heating and cooling systems. The WWR, determined by the proportion of the building’s glazed area to its wall area, is a significant factor influencing energy efficiency and minimizing energy load. This study introduces the development of a semi-automated computer model designed to offer a real-time, interactive simulation environment, fostering improving communication and engagement between designers and owners. The said model serves to optimize both the WWR and building orientation to align with occupants’ needs and expectations, subsequently reducing annual energy consumption and enhancing the overall building energy performance. The integrated model incorporates Building Information Modeling (BIM), Virtual Reality (VR), and Energy Analysis tools deployed at the conceptual design stage, allowing for the amalgamation of owners’ inputs in the design process and facilitating the creation of more realistic and effective design strategies.

A Building Information Modeling-Life Cycle Cost Analysis Integrated Model to Enhance Decisions Related to the Selection of Construction Methods at the Conceptual Design Stage of Buildings

Life Cycle Cost Analysis (LCCA) provides a systematic approach to assess the total cost associated with owning, operating, and maintaining assets throughout their entire life. BIM empowers architects and designers to perform real-time evaluations to explore various design options. However, when integrated with LCCA, BIM provides a comprehensive economic perspective that helps stakeholders understand the long-term financial implications of design decisions. This study presents a methodology for developing a model that seamlessly integrates BIM and LCCA during the conceptual design stage of buildings. This integration allows for a comprehensive evaluation and analysis of the design process, ensuring that the development aligns with the principles of low carbon emissions by employing modular construction, 3D concrete printing methods, and different building design alternatives. The model considers the initial construction costs in addition to all the long-term operational, maintenance, and salvage values. It combines various tools and data through different modules, including energy analysis, Life Cycle Assessment (LCA), and Life Cycle Cost Analysis (LCCA) to execute a comprehensive assessment of the financial implications of a specific design option throughout the lifecycle of building projects. The development of the said model and its implementation involves the creation of a new plug-in for the BIM tool (i.e., Autodesk Revit) to enhance its functionalities and capabilities in forecasting the life-cycle costs of buildings in addition to generating associated cash flows, creating scenarios, and sensitivity analyses in an automatic manner. This model empowers designers to evaluate and justify their initial investments while designing and selecting potential construction methods for buildings, and enabling stakeholders to make informed decisions by assessing different design alternatives based on long-term financial considerations during the early stages of design.

Research on the Optimization of Green Building Performance Based on BIM Technology

With the acceleration of urbanization,the construction industry has developed rapidly worldwide but has also brought serious environmental problems.Traditional architectural design methods often only focus on the function and beauty of the building while ignoring its impact on the environment.In addition,the lack of effective design and construction management methods also led to high resource and energy consumption.To overcome this challenge,the concept of green building came into being.Green buildings emphasize reducing the negative impact of buildings on the environment and improving resource utilization efficiency throughout the entire life cycle.BIM technology provides strong support for achieving this goal.Based on this,starting from the role of BIM technology in green building performance optimization,this article analyzes the optimization of green building performance solutions based on BIM technology in detail to promote the sustainable development of buildings.

A Study of Prospective Barriers,Benefits and Measures for Building Information Modeling(BIM)Adoption in Nepalese AEC Industry

The construction industry needs modern construction methodology and technology to improve sustainability and production performance.Building Information Modelling(BIM)technology supports improving the quality of products by reducing design and construction defects,risks to the health and safety of workers,and reduce overall project cost and delivery time.The BIM has capabilities,but it is still undiscovered and unable to exploit the full scale of its benefits in the Architectural Engineering and Construction(AEC)industry.There is a trend to adopt the BIM level 1,which is limited to 2D and only in a few cases 3D models uses in the design and construction of residential and commercial buildings,particularly in Nepal.Hence,this paper focuses on providing insight into the BIM benefits and identifies the potential barriers while adopting BIM Level 3 in Nepal.This was accomplished by developing a 4DBIM model of a multi-story residential building in Nepal and conducting the industry survey via focus group with the AEC professionals based on the developed 4DBIM model.A comprehensive literature review was conducted and presented the findings of the BIM benefits and barriers while adopting BIM.The study found that commercial and governmental projects can immediately be adopted BIM technology.It is concluded that the unavailability of skilled BIM users and the lack of proper policies for BIM adoption are key barriers in Nepal.Hence,the new policy is required to achieve and exploit the full scale of the BIM benefits and improve the project delivery in terms of quality,cost and time including the health and safety of workers and the sustainability of the AEC industry.

基于BIM技术与模拟退火算法的村镇轻钢框架结构智能设计方法

传统村镇住宅结构设计需要进行大量的人工试算与重复建模,而受制于建设成本,村镇住宅无法像城镇住宅一样通过设计师进行专业的结构设计与验算,其安全性与经济性均难以满足要求。为此,提出一种村镇轻钢框架结构智能设计方法,包括智能建模与智能优化两个环节。基于图层自动识别算法、光学字符识别技术、自适应分块算法提出村镇轻钢框架结构BIM智能建模方法,包括图层识别、轴文本数据提取、墙体轮廓提取等,智能建模结果基本满足实际工程要求。基于提出的两阶段模拟退火算法给出村镇轻钢框架结构的智能优化方法,优化速度较快,优化效果良好。通过实际工程案例对提出的智能设计方法进行验证,结果表明,提出的村镇轻钢框架结构智能设计方法具有可行性,与传统的人工设计方法相比,设计周期可缩短70%以上,材料用量、结构设计指标接近人工设计结果。

BIM技术在建筑碳排放计算领域研究进展

结合国内外相关文献,对BIM技术在建筑碳排放计算领域的研究进展进行综述。通过对研究进程的归纳,以及对建筑碳排放计算政策、计算方法、BIM技术适用性等影响因素的分析,总结BIM技术在建筑碳排放计算领域的研究现状。基于当前研究成果,将BIM技术在建筑碳排放计算领域的研究内容划分为理论方法、工具平台、应用价值三个层面。理论方法主要关注计算边界和计算方法的确定、BIM模型的数据提取方式以及BIM模型的参数扩展内容;工具平台主要探讨BIM建模工具、人工处理及算法程序、BIM软件插件、BIM平台系统的具体应用;应用价值主要体现基于BIM技术的建筑碳排放计算在建筑设计、物化、运营等各阶段的成果效益。三个层面虽已取得许多研究成果但也存在问题和难点。未来的研究可以在数字技术融合和信息管理完善两个方面深入发展。

基于BIM的公路工程标准化EBS分解方法

工程结构分解(EBS)是公路工程全寿命周期信息化管理的基础。为了提高公路工程建设期信息化水平,基于BIM技术应用,提出了公路工程标准化EBS分解方法。标准化分解方法根据工程中不同路段,梳理专业划分以及空间位置划分原则,并依据行业标准,确定标准化EBS结构的叶子节点,提供公路工程EBS结构树模板示例。研究结果旨在提高高速公路数字化交付中的数据处理标准建设,为实施公路工程数字化提供基础支持。

BIM模型编码可变性检验与自动匹配方法研究

为解决BIM元素变更导致的Web-BIM系统数据库与BIM元素无法匹配的问题,本研究首先根据各类BIM文件的特点,选择Rvt文件作为编辑BIM文件,选择Gltf文件作为Web端加载文件。对BIM模型的编码可变性进行了验证,结果表明对BIM构件尺寸修改、属性修改、位置移动等操作均不会改变构件的编码;若对BIM构件进行删除,该构件会被赋予新的编码,但其他构件的编码均不会被影响。本研究提出一种BIM模型变更前后自动匹配方法,通过建立元素识别和跟踪数据库、元素匹配算法、用户交互及确认、更新质量信息、定期检查等步骤,可以实现BIM模型变更前后Web端与BIM元素的匹配,为建筑项目的管理提供了有力的工具。

重型施工机械安拆吊装作业视觉可达性BIM仿真分析

为提高重型施工机械安拆吊装作业安全工效,改善安拆作业过程中人员的可视性,提出基于可视锥法的多主体视觉可达性建筑信息模型(BIM)仿真方法。首先,通过重型施工机械视觉任务分解,得到重型施工机械多主体视觉任务;其次,以wk-35型电铲安拆作业为研究对象,分析起重驾驶司机-信号工-司索工多主体视觉任务,运用计算机辅助三维交互应用(CATIA)人因仿真模块,构建安拆吊装作业多主体视觉的BIM仿真场景;然后,采用可视锥法,计算安拆吊装作业过程多主体视觉可达性量值,测度多主体视觉可达性水平,构建重型机械施工机械多主体视觉评价模型;最后,调节BIM模型的过程参数,推演多主体视觉变化趋势,评价安拆吊装作业多主体视觉可达性。结果表明:安拆作业中起重司机在起升下降过程中视觉可达性较差,在平移过程中视觉可达性较好;信号工和司索工的位置与其视觉可达性联系紧密,当信号工处于视野刚好覆盖起重司机和司索工的位置时,其视觉可达性最好,而司索工需不断调整位置,使其视觉可达性达到最佳。

基于BIM 5D的项目安全与质量协同管理研究

为解决项目质量和安全管理无法直观表达、提前预防、及时整改等问题,本研究将BIM技术引入项目安全与质量管理工作中,验证了基于BIM 5D的工程安全与质量协同管理的可行性。通过研究得出:通过“事前预防”的BIM技术(建立Revit模型、深化设计、施工模拟、可视化技术交底),将项目质量和安全问题提前暴露,减少返工造成的不必要麻烦,保证物资的有序进场和合理堆放,为安全文明施工提供基础;通过“事中控制”的BIM 5D+智慧工地决策系统,将质量、安全问题进行归集、分析,将分析结果以图表呈现,对关键问题进行预警,及时发现问题并整改。上述方法保证了项目安全,提升了工程质量,为施工企业应用BIM 5D提供了参考。

基于BIM和知识图谱的自动审查方法

本文在设计合规性审查中引入知识图谱技术,提出以规范知识图谱为核心的自动审查系统。通过对中国规范及结构设计规则(以下统称为规范)分析,提出面向规范最小语义单元的规范知识图谱元结构,建立了反映建筑规范复杂语义逻辑元结构的链接规则,进而以元结构为基元提出了规范知识图谱的构建方法。通过从图谱中获取数据,驱动代码生成模块自动生成用于信息检索和审查的可执行规范审查代码,可实现BIM模型的自动审查。

基于工业基础类标准的钢结构BIM全数据交互技术

研究了适用于各类钢结构的基于工业基础类标准(IFC)的全数据交互技术,可以导出钢结构模型完整的几何信息与附加属性,使通用建筑BIM软件能够进行模型信息读取并编辑其中的参数化构件;可以将模型全信息导入钢结构主流详图设计软件Tekla进行解析并重生成结构模型,实现模型二次编辑与施工出图。经工程实例验证,该成果应用于钢结构建筑信息模型(BIM)数据交互时信息传递完整、模型转换质量高,避免了钢结构不同设计阶段的重复建模,极大提升了设计效率。

基于大语言模型的BIM正向设计问答系统研究

在正向设计中,设计人员能够通过BIM技术进行设计和管理建筑项目,以支持决策。然而,BIM正向设计过程中的信息处理和知识共享仍面临诸多挑战,尤其是在快速获取和应用复杂建筑规范及设计知识方面。为解决上述问题,本研究基于大语言模型(LLM)设计了一套BIM正向设计问答系统,旨在探究LLM在BIM正向设计场景中的实际应用。通过采用基于QLoRA的LLM微调方式提高模型的专业性,并构建本地知识库形成问答系统,最后设计评价指标对系统进行主客观性能评估、专业问答对比分析。实验结果表明,该系统在专业领域性能表现良好,并能根据特定设计场景生成建议和解决方案,验证了本系统的可行性和优越性。

中国BIM体系下装配式建筑可视化图谱分析

为有效解决建筑工业化和智能化协同发展所面临的问题,中国正积极促进建筑信息模型(Building Information Modeling,BIM)支持下装配式建筑的发展。运用了文献计量分析方法,对2011—2021年中国BIM体系下装配式建筑的研究趋势、作者和机构集群及研究热点关键词进行了可视化图谱分析,旨在提高建筑从业者对BIM体系下装配式建筑的综合认知。研究发现:跨地域机构研究承接协同、“装配式建筑-BIM-EPC”一体化及运营维护的全生命周期设计管理是未来的重点研究方向。

亭子口灌区一期工程第Ⅳ标段BIM正向设计优化与应用

灌区工程线路长、范围广、渠系建筑物众多,随着BIM技术在工程建设领域应用越来越广,在灌区设计中利用BIM进行三维正向设计与优化,有助于提高灌区设计质量,提升灌区整体管理水平。结合亭子口灌区一期工程第Ⅳ标段,介绍了利用水工建筑物三维参数化正向设计、BIM技术进行隧洞进出口三维开挖正向设计、深挖方暗渠优化设计、主支洞交叉段三维正向设计、BIM模型在运维阶段的应用等应用点,为类似工程设计提供了经验。

化工厂区建筑全生命周期碳平衡BIM控制模型仿真

为了更准确评估化工厂生产工艺中化学反应产生的碳排放平衡,提出了化工厂区建筑全生命周期碳平衡BIM模型仿真方法。使用AutoDesk Revit BIM软件,构建化工厂范围及建筑的BIM模型,计算碳化吸收、生物燃料碳排放回收、回收阶段碳吸收,获取建筑全生命周期碳吸收量总和。将计算结果输入BIM模型中,设计数据加工过程,计算碳排放总量与碳吸收总量差值,以此为输入数据构建碳平衡BIM模型,实现碳平衡控制。通过仿真实验可知,使用所研究方法除了在3~5月内碳排放量等于碳吸收量外,其余时间碳排放量均小于碳吸收量,所有时间内化工厂区建筑全生命周期均处于碳平衡状态,具有较强碳平衡效果。

基于BIM技术的福州市连江县仁坂黄家祖厝建模研究

文章运用三维激光技术对福州市连江县仁坂黄家祖厝进行数据收集,对建筑要素进行系统性梳理,利用BIM技术的“族嵌套”方式构建“族”库以及可视化建筑信息模型。将BIM技术与福州古厝结合,为福州古厝保护研究工作提供了新的方式。仁坂黄家祖厝模型建立对福州其余古厝保护研究工作有着巨大的参考价值。

基于BIM和语义网的轨道智能运维管理方法

建筑信息模型(BIM)技术对提高轨道运维管理效率具有重要的推进作用。然而,不同的检查和维护活动产生的数据异构性高、时空关系复杂,阻碍了BIM解释和整合数据的进程。为此,开发了一个基于工业基础类(IFC)和语义Web技术的轨道运维本体(TOMO),其具有3个功能:①基于轨道运维生命周期的应用需求,简化BIM模型信息;②引入映射规则,建立数据提取与转换模块,集成多源异构数据,结构化定义数据之间复杂的时空关系;③结合数据驱动技术,研究轨道精调智能优化的方法,提供弹性决策支持。最后,以某高速铁路静检数据为例,验证了该框架的有效性与实用性,对于促进领域数据互操作性、降低运维人员劳动强度和提高运维管理智能化程度具有实际的工程指导意义。

基于BIM技术的装配式建筑建设项目安全风险管理及优化

针对传统的装配式建筑管理中存在管理水平粗糙、精细化程度低等问题,研究运用BIM及相关信息技术建立基于BIM相关信息技术的建设项目安全风险管理平台,并设计建筑项目对比实验。研究结果显示未使用BIM技术进行安全管理的3#装配式建筑安全等级为三级,综合确定度为0.65325,而使用BIM技术进行安全管理的5#装配式建筑安全等级为四级,综合确定度为0.7190。综上所述BIM技术能实现装配式建筑建设项目的安全管理的优化,减少施工工程中的事故风险,保障人员的生命安全和财产安全。