Crucial Developments in 3D Building Services Design and Coordination Field

Building services projects have benefited from many developments that have occurred in the last decade. Whether in the areas of MEP (M&E) systems design, 3D building services coordination, or interdisciplinary collaboration, the major advances seen in this field have emanated both from within the industry as well as from other sources, such as government regulations and economic developments.

•  Intelligent BIM Software for Planning and Design of Projects

One of the biggest changes in the modern building services industry is the use of intelligent building information modelling (BIM) software tools that allow for the creation of accurate and detailed representations of mechanical, electrical, plumbing, and fire protection systems using computable data. The fact that there are BIM tools more intelligent than ever and also which work across disciplines, such as architecture, structural engineering, and building services engineering, increases interdisciplinary coordination and reduces construction waste and rework.

For instance, the BIM models created using Autodesk Revit Architecture and Revit MEP can be used by building service designers for developing concept designs, schematics, and tender drawings. The same parametric model can be worked upon and used by contractors to create detailed installation and 3D MEP (M&E) coordinated drawings, including services-specific as well as multi-service coordinated plans, sections, and elevations. Furthermore, fabricators and installers can use the BIM model in conjunction with FAB MEP, a fabrication tool, to manufacture pre-assembled modules for installation on-site.

Not only does BIM allow creation of a coordinated 3D model, it also allows for information to be added to the model that can be used for project-critical purposes, including schedule creation, cost estimation, energy analysis and facilities management.

• Greater Interdisciplinary Collaboration

Due to the growing adoption of BIM tools industry-wide complemented by the availability of sophisticated hardware systems and online collaboration channels, there is a far greater degree of interdisciplinary coordination between different stakeholders involved in AEC projects. As a result, architects, structural engineers, MEP consultants, MEP engineers, main contractors (general contractors), cost estimators, and fabricators can seamlessly collaborate during the design and planning stages and avoid costly rework during the construction stages.

For instance, large-scale construction projects generally have a complicated project structure comprising diverse project teams based in different geographical areas. During the pre-construction stage, sharing and interlinking the BIM model prepared by architects, structural engineers, MEP specialists and contractors enables respective designs to stay coordinated. Due to cloud-based collaboration tools, team members can hold review sessions online without having to be physically present together.

•   Higher Degree of Pre-Fabrication and Just-In-Time Delivery for Installation

With the widespread use of parametric modelling techniques in MEP design and planning, a major trend is to use BIM models for pre-fabrication purposes with a view to enhance the logistical cycle on the construction site. When used in conjunction with CNC fabrication applications, such as FAB-MEP, the BIM design data can be used to create fabrication drawings that can be recognised by CNC machines. Such a BIM-led prefabrication can streamline the installation process on site and avoid costly miscalculations.

Taking into account the complexities of the MEP (M&E) systems industry, BIM-driven prefabrication and modularisation has led to multifaceted benefits: reduced rework, in-time project completion, cost savings and increased efficiency.

• Government Intervention 

Another critical development from outside the industry is the government policies in different parts of the world either promoting or mandating the use of BIM in varying levels for government-funded or private projects. In the US, the General Services Administration (GSA), through its Public Buildings Service (PBS) Office of Chief Architect (OCA), established the National 3D-4D-BIM Program in 2003. GSA mandated the use of spatial program BIMs as the minimum requirements for submission to OCA for Final Concept approvals of all major projects receiving design funding in 2007 and beyond.

In Europe, the UK Government has made Level 2 BIM compulsory for all publicly-funded projects from 2016 onwards with a view to trim the cost of public-funded projects and to reduce carbon emission to meet its EU commitments. Government agencies from the Scandinavian nations have played an important role. Senate Properties, Finland’s state property services agency, required the use of BIM for its projects since 2007. Neighbouring Norway and Denmark have also made sufficient headway towards adopting BIM practises in their public-funded projects. Statsbygg, the Norwegian government agency that manages public properties, including heritage sites, campuses, office buildings and other buildings, employed BIM in all its projects by 2010.

In Asia, Singapore was in the forefront of driving the adoption of BIM. After implementing the world’s first BIM electronic submission (e-submission) system for building approvals, the Building and Construction Authority (BCA) mapped the BIM Roadmap with the aim to adopt BIM for 80% of construction projects by 2015. In Hong Kong, the Housing Authority (HA) not only developed a set of modelling standards and guidelines for BIM implementation but also stated its intent to apply BIM to all its new projects by 2014-15. South Korea’s Public Procurement Service, which reviews designs of construction projects and provides construction management services for public institutions, has made BIM mandatory for all projects worth more than S$50 million and for all public sector projects by 2016.

3D Building Information Modeling (BIM) | BIM Modelling

3D BIM Modeling

BIM Outsourcing

3D BIM Modeling: Key is to Interpret Client’s ‘Real’ Needs

The concept of building information modelling (BIM) has received universal acceptance from the building services, structural engineering and architectural fraternity mainly due to its need for lean construction and also its cross-disciplinary usability. 3D BIM modeling has existed for a number of years now and the industry is aggressively adapting itself to embrace the new workflows of the BIM process; however, there is still a lack of clarity amongst the owners (the clients) as to what exactly they can achieve from these models, what they need to achieve and how they can make optimum use of this concept.

3D BIM Modeling

This article seeks to explore some beliefs related to the use of BIM and sheds light on when it should be used and to what extent. For the sake of clarity, it is important to know the difference between non-BIM 3D CAD models and a parametric BIM models.

3D CAD models are virtual representations of a facility that provide only visual details. Applications such as AutoCAD Architecture and AutoCAD MEP are used to create 3D CAD models that can be used for design, development, construction and pre-fabrication. On the other hand, BIM models are intelligent models embedded with parametric details that are extremely important for design, development, construction, pre-fabrication, assembly, analysing energy performance and facility management of the built environment. For BIM projects, the details can be effectively shared between different project stakeholders: facility owners, designers/architects, MEP (M&E) engineers, fabricators, consultants and contractors. Revit Architecture and Revit MEP are applications used for BIM modelling whilst Navisworks is employed to detect clashes between different system models.

One of the most crucial aspects that helps decide whether BIM is actually required or not is gaining an in-depth understanding of the model’s purpose. More often than not, there is so much difference between client’s ‘stated’ needs and his/her ‘real’ needs.  In a lot of cases, clients state that they require a BIM model but actually what they require is a smart clash-free 3D model which can be used to extract respective construction drawings. In such scenarios, AutoCAD MEP or AutoCAD Architecture could easily be used to provide a 3D model that meets this need. Alternatively, a BIM software tool could be used to provide a 3D model without providing additional elements such as data rich 'information'.

In other cases, a BIM model may actually be the basis to plan, design, construct, and manage a particular facility. These scenarios require multidisciplinary project stakeholders to access the BIM model at different stages in the project lifecycle. As a result, the most important factor that dictates the success of any project employing BIM is the richness of ‘information’ embedded into the models. So, depending on the project’s scope, a full-fledged BIM model may contain valuable information, such as dimensions of building elements, quantity take-off data, material requirements, time scheduling, costing, prefabrication data, activity simulation, and energy performance. Other important factors that contribute to success of BIM include the data-sharing and interoperability standards to allow smooth multidisciplinary collaboration between key disciplines.

Irrespective of whether the client actually requires BIM or non-BIM CAD model, the BIM wave that has spread across the AEC industry has forced the agenda to adopt a more progressive approach to planning, designing and coordinating models and drawings. The industry continues to transition from non-BIM 2D approaches to collaborative BIM workflows and 3D CAD workflows and even that is a huge shift for the industry. This change is more often than not influenced by the demand side i.e. the clients.

Nevertheless, the current wave of change in favour of adopting BIM applications and processes has helped the entire AEC supply chain embrace intelligent virtual planning and development techniques for architectural and building services design, spatial coordination and collaboration.

Kuldeep Bwail is a Director at XS CAD Limited, one of the leading BIM outsourcing providers offering BIM Services to architects, engineers, MEP (M&E) consultants, and contractors across the UK, US, Australia, Canada, Europe, India and the Middle East.

BIM for Homebuilders

While Building Information Modeling remains just a buzzword for some of them, many of the homebuilders have adopted BIM and have considerably benefitted in terms of cost and time.  Building Information Modeling is an information-rich technology allowing digital representation of a building process simulating the design, planning, construction and operation of a facility. 

Decreasing productivity and tight margins were the major crises faced by the homebuilders.  BIM Modeling Services have changed the way buildings are built ensuring increased productivity, quality and accuracy of the design.  Using BIM, the homebuilders can view the building digitally before it is actually built, thus reducing the inefficiencies and flaws in the pre-construction stage. 

BIM also helps to retrieve accurate bill of quantities and gives estimation whether the desired building with quality, size mentioned could be built in the specified cost and time. Thus, it helps the homebuilders to take more informed decisions by getting prior knowledge of amount of material, cost and time involved for constructing a building. With more emphasis and need of green building in this era of environmental concerns, BIM with its ability to analyze the energy performance of a building facilitates designing of green building.

Though some of the homebuilders are yet to adopt BIM, the benefits of BIM to the homebuilders in constructing better homes are visible. The use of BIM by the homebuilders would be accelerated in the coming years, considering the overall increased productivity and time benefit that it offers.