Building Information Modelling For Green Building and IGBC Rating Analysis

Green building is defined by the Office of the Federal Environmental Executive as the practice of increasing the efficiency with which buildings and their sites use energy, water, and materials, and reducing building impacts of human health and the environment, through better design, construction, operation, maintenance, and removal throughout the complete life cycle. Green homes will have tremendous advantages, each tangible and intangible. The foremost tangible advantages area unit the reduction in water and energy consumption right from day one among occupancy. The energy savings may vary from twenty - half-hour and water savings around thirty - five hundredth. Intangible advantages of inexperienced homes embody increased air quality, wonderful day lighting, health & upbeat of the occupants, lower energy bills and conservation of scarce national resources. BIM stands for Building Information Modeling, and will be a 3D modelling technique that permits style, engineering and construction professionals to vogue and build with intelligence. BIM is “an integrated technique that's used to facilitate the exchange of style and construction information to project participants”. BIM used in the construction industry by providing 3D view of a project containing all parameters and its mechanism. The building and construction industry has been driven to adopt green building strategies for increasing sustainability concerns such as reducing CO2 emission and increase energy efficiency. Green building is the practice of creating structures and using processes that are environmentally responsible and resource-efficient throughout a building's life-cycle from design to construction, operation, maintenance and renovation. BIM in green buildings permits property styles, permitting architects and engineers to integrate and analyses building performance. BIM enhances style and construction potency, BIM has been regarded by several as vital chance in design Architecture, Engineering and Construction (AEC) business. BIM will be wont to simulate energy consumption quickly and accurately. It will facilitate eliminate energy waste. It integrates and analyzes data at the development stage. it's wont to find out energy potency. The BIM is that the constant modification conception permitting the AEC companies to Building Information Modelling (BIM) is a new and innovative technology, which has emerged in recent years and makes possible the efficient achievement of more sustainable designs. .It is believed that BIM is a critical element in reducing industry waste including wasted energy, adding value to industry products and decreasing environmental damage. Our current thrust is given to reducing energy usage further as carbon emissions in buildings. Energy potency is a vital feature in naming building materials as being environmentally friendly. The last word goal in mistreatment energy economical materials is to scale back the number of by artificial means generated power that has to be delivered to a lot. Building data Modelling tools facilitate users do complete energy analysis and explore totally different energy saving alternatives throughout the look stage. Using BIM technology to watch building performance may be employed in coming up with appropriate situations to maximize energy savings so as to match style and performance of buildings. As per the recent studies, BIM based mostly energy analysis is taken into account to be helpful for energy analysis of building. Basically, utilizing BIM as a knowledge or an information supply for energy analysis makes the info input additional economical and also the existing data additional reusable. Another objective of this comes to set up the programing of the complete work and determinative the value estimation analysis. Time and price controls area unit vital for any construction organization. BIM improves technical work on the planning stage by making 3D models that integrate all building‟s options and it higher represents the infrastructure‟s necessities. Those models will be increased if connected with schedule (4D) and costs (5D), the development can so be higher planned nearly entirely at the planning part. Correct estimation and coming up with of actual project prices also are vital for fulfillment in construction business. Handling the project value knowledge by BIM approach offer a chance to manage the development project prices a lot of expeditiously. As the construction costs unit known and connected to the development components and programing knowledge, the 5D building data model is formed. There is also the Scheduling and 4D modelling use of BIM. The 4D Model is created when the element of time is added to the 3D Model by creating a link with the model and the critical path method schedule. This can be done using a single application or by combining model collaboration software with standard scheduling software. The 4D Model is an essential tool to the BIM Process because it identifies collision between construction activities. The 4D Model is a necessary tool to the BIM method as a work and relationships between construction tools. The Estimating and 5D modelling use of BIM entails using the data stored in the BIM to extract information and transfer that information into construction estimates. As the design progresses or changes occur, these estimates can be quickly updated based on information derived from the BIM model. More ever now it's a need of a construction industry to integrate BIM technology with a cost control factor. After planning and value estimation the last objective of this project is to administer the classification system as per IGBC norms. That is one in all the simplest classification system in India for Green Buildings. Evaluating a building to be certified as “sustainable”, in line with a classification system, may be a varied and multi-phase method, that ensures that measures are taken for the building to attain bound performance levels in aspects like energy consumption reduction, conservation of resources, low carbon footprint etc. The three most prevailing rating system in India are LEED, IGBC and GRIHA. Existing Buildings can even be retrofitted and obtain the certificate from Rating Agencies of the World. By applying IGBC inexperienced homes criteria, homes that are feasible over the life cycle of the building is created. This rating programme could be a tool that allows the designer to use inexperienced ideas and criteria, therefore on cut back environmental impact, that are measurable. IGBC Green Homes is that the initial rating programme developed in Asian country, completely for the residential sector. IGBC green new buildings system could be a voluntary and consensus-based programme. The system has been developed supported materials and technologies that are presently obtainable. The target of IGBC green new buildings grading system is to facilitate a holistic approach to make environment-friendly buildings, through architecture design, water potency, effective handling of waste, energy potency, feasible buildings, and specialise in dweller comfort & well-being. The rating system evaluates bound necessary needs & credit points employing a prescriptive approach and others on a performance primarily based approach. The system is evolved therefore on be comprehensive and at an equivalent easily operating.

• This typical case is selected in the project would be useful while considering the cases for residential sites. • This project will be identical for person who are associated with this type of work, who would be integrate and analyses information

• This will be beneficial for the people who are really conscious about the environmental impact of the building and believe in energy conservation. • The another future scope for this project is while achieving IGBC rating system, it can be increased if the remaining credits are attempted.

• Planning and Modelling of G+10 residential conventional as well as green building by using Revit. • Energy analysis of green building and conventional building by using Green Building Studio and comparison of their results. • To plan the Scheduling of project and determine the cost and estimating of G+10 Residential conventional and green building and compare their results.

In this study, BIM was used as an enabling technology for cloud-based building data services that integrated building data in the operational phase with a focus on energy management. Three main facts of green BIM are critically examined, namely the contributions and applications of BIM in the life cycle of green buildings, the various functions of environmental sustainability analyses provided by BIM programs, and the integration of green building assessment (GBA) with BIM. Also BIM functions for green analyses were identified and critically reviewed, including energy performance analyses and evaluations, natural ventilation system analyses, solar radiation and lighting analyses, water usage analyses and thermal comfort analyses. This study reveals that green BIM applications might bring varied edges for GBA, like estimating GBA scores, managing application documents, and enhance the potency of GBA method.

In this paper Implementation of BIM is able to eliminate the extra cost of design changes during the subsequent phases of construction process. BIM is also capable of enhancing the project delivery culture in future. BIM enabled sustainable design and to explore that BIM can potentially facilitate and benefit sustainable design. Inspection of the BIM contributions to sustainable building design. Analysis of the benefits and obstacles of using BIM to support sustainable design “Green” strategies using the inherent BIM software such as Revit include selection of the best building orientation and the appropriate degree of massing.

This paper presented a method to partially automate the procedures of implementing sustainable design for building projects at their conceptual stage by integrating BIM, energy analysis and cost estimation tools. Energy analysis, in order to have an accurate energy analysis of the proposed building, the 3D physical model should be converted into an analytical model by transferring all the spaces into rooms. Building Information Modelling tools help users do complete energy analysis and explore different energy saving alternatives during the design stage. This would help owners and designers make energy related decisions that have high impact on the proposed building life cycle cost.

In this study BIM applications for energy analysis have been introduced to improve the process at the design stage. This paper introduces a conceptual BIM-based model that can improve th evaluation process and meet the industry requirements for sustainable buildings. The required sets of data to analyse energy consumption in building is quite complex and includes data about the external environment, the shape and configuration of the building, equipment loads, lighting mechanical systems and air distribution. Therefore, for accurate prediction of energy consumption, integrated simulation tools should be used. This study shows a BIM model of a building includes design features, Building type, construction materials, System types (Heating/Cooling), Room type (Zone management), Project location (weather files), etc. which can be exported to a building simulation tool. The study shows various factors which affect the energy use of a building which include building location, size and shape and its parts, in internal spaces heat and light occurred which reduces need for energy use. It results to improve efficiency and reduce energy use with reducing heating and lighting units. In the energy simulation process, BIM is considered important factor used to create a high potential in sustainable building design. Thus, calculate the energy performance effectively before construct the building on site. In this study autodesk Revit software is used to analyze energy performance by adopted different building location.

The present study describes the definition of BIM. The definition adopted here it is as a systematic process of the management and wide information generated throughout building design development and operation. In this study the much efforts are targeted for reducing the gap between predicted and actual building performance. This study shows that accurate recreation of the entire building would have taken significant time, therefore a simplified representation of spaces and systems was chosen as a demonstrative BIM environment to which building performance data could be attributed and utilized. In that space and system data describing performance characteristics such as the maximum expected lighting, heating, cooling and small power loads for each space were taken from the simulated performance model and attributed to their respective spatial objects.

• The first step contains literature review relevant to the study. In that BIM and energy analysis software and factors affecting building energy use, are reviewed. This is accustomed understanding the relation between building energy location and energy use. • Second step consist of selection of site and planning of G+10 residential building with the help of AutoCAD. The same plan can be used for conventional and green building. • Third step consist of modelling of G+10 plan in Revit software for conventional as well as green building. The green building is replaced by using certain green materials which are energy and cost efficient. required for energy model is location of site, latitude and longitude of building etc. Solar panels are given in this building to store energy use which is the best practices for green building. Also the provision of rainwater harvesting is given in the revit model. Rainwater harvesting is that the assortment and storage of rain, instead of permitting it to escape. Rainwater is collected from a roof-like surface and redirected to a tank, cistern, deep pit, aquifer or a reservoir with percolation. This provision can improve the sustainability of building.

• In fifth step the calculated energy analysis result for conventional as well as green building is compared. Energy analysis using BIM tools (Revit and Green Building studio) and Energy plus. These tools were used to study the thermal and energy performance of a well-insulated test cell and to study the impact of a change of thermal mass and insulation thickness to figure out the advantage and disadvantage of each tool. • In sixth step Predicting, Planning, and controlling the schedule for G+10 building project are critical requirements for effective project implementation in the construction industry. The scheduling of the construction process is subjected to many variables and unpredictable factors, such as the resource availability, environmental conditions,

• In seventh step Costing of G+10 building is done. A cost estimate is the main type of target data to obtain at the outset of any project, which enables the project manager to define the project budget. Cost planning of the construction project can be performed through several steps using software. The 3D model can be formed in multiple formats such as Revit, ArchiCAD. • In eighth step The Indian Green Building Council (IGBC) has launched „IGBC Green Residential societies Rating System to implement measures that will reduce the consumption of natural resources. The main objective to launch IGBC Green Residential Societies Rating System is to develop as many green societies as possible. Benefits of IGBC Rating System, 20-30% reduction in Energy cost, 30-50% reduction in Water requirement and improved health & wellbeing of occupants. • In ninth step calculated Result and Discussion for conventional as well as green building on expected outcomes.

the Confederation of Indian Industry (CII) was formed in the year 2001. The vision of the council is, "To enable a sustainable built environment for all and facilitate India to be one of the global leaders in the sustainable built environment by 2025".The council offers a wide array of services which include developing new green building rating programmes, certification services and green building training programmes. Green building rating brings together a host of sustainable practices and solutions to reduce the environmental impacts. Green building design provides an integrated approach considering life cycle impacts of the resources used. Benefits of Green Residential Societies Rating System • 20-30% reduction in Energy cost • 30-50% reduction in Water requirement • Improved health & wellbeing of occupants The guidelines detailed under each credit enables the design and construction of green Residential Societies of all sizes and types. Different levels of green building certification are awarded based on the total credits earned.

Certified 30 – 39 Best Practices Silver 40 – 49 Outstanding Performance Gold 50 – 64 National Excellence Platinum 65 & above Global Leadership

1 No Smoking in Common Areas 3 2 Maintenance of Facility 4 3 Basic Amenities 2 4 Green Housekeeping in common areas 1 5 Green Education for Occupants 1 6 Minimize Heat Exposure – 6 8 Design for Differently Abled 3 9 Facilities for Health & Wellbeing 2 10 Rain Water Harvesting : 10, 20, ……100% 10 11 Landscape Areas: 20, 25, …… 40% 5 12 Water Sub Metering 4 13 Water Efficient Fixtures : 40, 50, …… 90% 6 14 On-Site STP: 50, 75, 95% 3 15 Automatic water level controllers 1 16 CFC Free Appliances 3 17 Efficient Lighting Fixtures: 25, 50, 75, 95% 4 18 Solar power for street & Common Area Lighting: 20, 30 ……. 80% 7 19 Energy metering 2 20 Solar Water Heating Systems: 20, 30. …… 70% 6 21 Waste Segregation 4 22 Organic Waste Management - 20, 40, 60, 80, 90% 5 23 E-waste Management 1 24 Water Meters for Dwelling units (50, 75, 100%) 3 25 Reuse of treated waste water for landscaping 1 26 Fresh water treatment plant 1 27 Electric charging points for vehicles in common areas (2.5%, 5%) 2 28 LPG/CNG Gas geysers for water heating (20, 40%) 2 29 Day-Light / Motion Sensors in common areas 1 30 IGBC Accredited Professional 1

Roof: Concrete Roof Green Roof Wall: Brick Wall Cavity Wall Door: Door Material without Glazing Door Material with Glazing Window: Standard Dimension Window Material without Glazing Change in Dimension Window Material with Glazing Solar Panel Not Applied Area: 459m² Panel Cost: $1.21per Watt Time Occupancy 58% 58% Electric Cost: $0.08 / kWh $0.08 / kWh Fuel Cost: $0.01 / MJ $0.01 / MJ Water Cost: $0.69/ m³ $0.69/m³ Rainwater Harvesting: No Yes Native Vegetation Landscaping: No Yes Greywater Reclamation: No Yes Weather Station: Distance to your project: Latitude = Longitude = GBS_04R20_266136 12357.8 km 42.4509 -71.0785 GBS_04R20_266136 12357.8 km 42.4509 -71.0785

Roof $19466.37 $58836.68 Wall $54587.27 $148195.06 Door $30165.48 $33709.34 Window $20872.08 $32877.1 Total $125091.2 $273618.18

1 No Smoking in Common Areas 3 2 Maintenance of Facility 4 3 Basic Amenities 2 Occupants 6 Minimize Heat Exposure – Roof: 30, 40, …… 80% 5 7 Design for Differently Abled 3 8 Rain Water Harvesting : 10, 20, ……100% 8 9 Landscape Areas: 20, 25, …… 40% 5

Certified 30-39 Best Practices By the following method, The total credit points=32 So, project is under category of certified and with recognition of Best Practices.

• From the above report we concluded that Green building reduces energy consumptions in numerous ways. Decrease embodies energy of the building through well-organized design, use of recycled and local materials and recycling construction waste. • Green building design reduces energy consumption over its lifespan. • Strategically placing windows and skylight can terminate the need for electrical lighting during the day. High quality insulation shrink temperature regulation costs in both summer and winter. • Green building consumes minimum water as compared to conventional building. • A rating system is very important to identify the green features of the building and also in guiding the building to be sustainable. • The total credit points obtained is 32 so, this work is under category of certified and with recognition of Best Practices. green building : A criticle review and future directions. Yujie Llu, Zhilei Wu, Ruidong Chang, Yongkui Li. 2017, Automation in construction. 2. Building information modelling (BIM) for sustainable building design. Fan, Kam-din Wong and Qing. 3/4, Hong Kong, China : Emerald Group Publishing Limited, 2013, Vol. 31. 3. Integrating BIM with green building Certification System, Eneergy Analysis and Cost Estimating Tools to conceptually Design Sustainable Building. Jrade, Farzad Jalaei and Ahmad. Ottawa : s.n., 2014. 4. Sustainable BIM-based Evaluation of Buildings. Ibrahim Motawa, Kate Carter. Edinburgh : Elsevier Ltd., 2013. 5. Green Building Based on BIM. Neelam Sharma, Bhupinder Kaur and Amit Goel. Mohali, Punjab, India: S.N., 2018, Vol. 11(26). 6. Building Information modeling for sustainable design and LEED rating analysis. Salman Azhar, Wade A. Carlton, Darren Oslen, Irtishad Ahmad. Miami, FL, USA : s.n., 2010. 7. BIM application to building energy performance visualisation and management: Challenges and potential. Tristan Gerrish, Kirti Ruikar, Malcolm Cook, Mark Johnson, Mark Phillip, Christine Lowry. United Kingdom : Elsevier B.V., 2017. 8. Green building based on Building Information Modelling. Neelam Sharma, Er. Bhupinder Kaur, Er. Sandeep Salhotra. 02, Panjab, India : s.n., 2018, Vol. 05. 9. Assessment and Remodelling of a Conventional Building Into a Green Building Using BIM. Abhinaya K.S., V.R. Prasath Kumar, L. Krishnaraj. Kattankulathur, Chennai, Tamil Nadu, India : s.n., 2017, Vol. 7. 10. .BIM BASED CONCEPTUAL FRAMEWORK FOR LEAN AND GREEN INTEGRATION. Ritu Ahuja, Anil Sawhney and Mohammed Arif. Oslo, Norwey : s.n., 2014. 11. Scope of Building Information Modeling (BIM) in India. Mukharjee, J. Vinoth Kumar

12. BIM-based Sustainability Analysis: An Evaluation of Building Performance Analysis Software. Salman Azhar, Justine Brown, Rizwan Farooqui. Auburn, Alabama and Miami, Florida : s.n., 2008. 13. Green BIM-based building energy performance analysis . Chein-Jung Chen, Shang-yuan Chen, Syuan-hao Li and Hsiu-ting Chiu. Taiwan : s.n., 2017, Vol. 14. 14. Adaptation of Green Building Design Concept with BIM into A New Construction Market in the AEC/FM Industry. G. Mounika, B. Hema. 9, Kadapa, India : s.n., 2018, Vol. 1. 15. A Review on Green BIM Potentials in Enhancing the Construction Industry Practice. Noor Akmal Adillah Ismail, Hazwani Ramli, Elma Dewiyana Ismail, Raja Rafidah Raja Muhammad Rooshdi, Shaza Rina Sahamir, and Nur Hidayah Idris. Selangor, Malaysia : EDP Sciences, 2019.

Post Graduate Student, Civil Department, PVPIT, Bavdhan, Pune, India