Greenhouse Gas Emissions Analysis (Case Study: Construction of a Satpol PP Building)

Khalijah Herma Wytti; Fajar Sri Handayani; Setiono Setiono

doi:10.47134/scbmej.v1i4.2699

Authors

Khalijah Herma Wytti Civil Engineering Study Program, Faculty of Engineering, Sebelas Maret University
Fajar Sri Handayani Civil Engineering Study Program, Faculty of Engineering, Sebelas Maret University
Setiono Setiono Civil Engineering Study Program, Faculty of Engineering, Sebelas Maret University

DOI:

https://doi.org/10.47134/scbmej.v1i4.2699

Keywords:

Construction Management, Greenhouse Gas Emissions, Life Cycle Assesment

Abstract

The development of the construction world is driven by the demands of meeting various needs, such as in this case study, namely the construction of the Bantul satpol PP Building to meet the needs of the legal apparatus. However, according to the United Nations Environtment Program in the Global Status Report for Buildings and Construction (2021) states that this development has a significant environmental impact, construction projects are responsible for 36% of energy consumption and 37% global CO₂ emissions by 2020. Therefore, this research aims of achieving Greenhouse Gas Emission (GHG) efficiency using the Life Cycle Assessment (LCA) method. Data analysis was applied through the Autodesk Revit program to get the material schedule and LCA approach within the scope of Cradle to Gate using ISO 14040 and 14044 guidelines. The structure of foundations, slabs, columns and beams became the object of research because the constituent materials in the form of concrete and steel are considered as CO₂ GHG contributors with the largest percentage, reaching 75% of the total emissions released (Luo et al., 2016). The analysis results show that the largest GHG estimate is located in the structural work of the Cradle to Gate scope which reaches 1,657,880.04 KgCO₂eq with the most critical process unit which is the material production process unit. Thus, project construction management can look for the best alternatives related to material selection or methods in the material production process that can reduce GHG emissions. This research can be applied to create a sustainable construction.

References

GLOBAL STATUS REPORT FOR BUILDINGS AND CONSTRUCTION Towards a zero-emissions, efficient and resilient buildings and construction sector. (2021). www.globalabc.org.

Dixit, G., Misal, G., Gulkari, V., & Upadhye, K. (2013). FORMULATION AND EVALUATION OF POLYHERBAL GEL FOR ANTI-INFLAMMATORY ACTIVITY. IJPSR, 4(3). www.ijpsr.com

Forth, K. (2023). Interactive visualization of uncertain embodied GHG emissions for design decision support in early stages using open BIM. Life-Cycle of Structures and Infrastructure Systems - Proceedings of the 8th International Symposium on Life-Cycle Civil Engineering, IALCCE 2023, 3634–3641. https://doi.org/10.1201/9781003323020-445

Gao, Y. (2024). Multi-information integration-based life cycle analysis of greenhouse gas emissions for prefabricated construction: A case study of Shenzhen. Environmental Impact Assessment Review, 104. https://doi.org/10.1016/j.eiar.2023.107330

Harjanto, T. R., Fahrurrozi, M., & Made Bendiyasa, I. (2012). Life Cycle Assessment Pabrik Semen PT Holcim Indonesia Tbk. Pabrik Cilacap: Komparasi antara Bahan Bakar Batubara dengan Biomassa. In Jurnal Rekayasa Proses (Vol. 6, Issue 2).

Hermawan, Farida Marzuki, P., Abduh, M., & Driejana, R. (2013). PERAN LIFE CYCLE ANALYSIS (LCA) PADA MATERIAL KONSTRUKSI DALAM UPAYA MENURUNKAN DAMPAK EMISI KARBON DIOKSIDA PADA EFEK GAS RUMAH KACA (031K). In Universitas Sebelas Maret (UNS)-Surakarta (Vol. 7, Issue 7). www.vtt.fi

Holzer, D. (2015). BIM and Parametric Design in Academia and Practice: The Changing Context of Knowledge Acquisition and Application in the Digital Age. International Journal of Architectural Computing, 13, 65–82. https://doi.org/10.1260/1478-0771.13.1.65

KUMANAYAKE, R., & LUO, H. (2018). Life cycle carbon emission assessment of a multi-purpose university building: A case study of Sri Lanka. Frontiers of Engineering Management, 0(0), 0. https://doi.org/10.15302/j-fem-2018055

Luo, Z., Yang, L., & Liu, J. (2016). Embodied carbon emissions of office building: A case study of China’s 78 office buildings. Building and Environment, 95, 365–371. https://doi.org/10.1016/J.BUILDENV.2015.09.018

Mohebbi, G. (2021). The role of embodied carbon databases in the accuracy of life cycle assessment (LCA) calculations for the embodied carbon of buildings. Sustainability (Switzerland), 13(14). https://doi.org/10.3390/su13147988

Morsi, D. M. A., Ismaeel, W. S. E., Ehab, A., & Othman, A. A. E. (2022). BIM-based life cycle assessment for different structural system scenarios of a residential building. Ain Shams Engineering Journal, 13(6). https://doi.org/10.1016/j.asej.2022.101802

Prabhakaran, A., Mahamadu, A.-M., Mahdjoubi, L., & Manu, P. (2020). An Approach for Integrating Mixed Reality into BIM for Early Stage Design Coordination. MATEC Web of Conferences, 312, 04001. https://doi.org/10.1051/matecconf/202031204001

Rahla Rabia, M. P., Kumar, D. S., Farooq, J., & Pachauri, R. K. (2021). Applications of Building Information Modeling for COVID-19 spread assessment due to the organization of building artifacts. In Data Science for COVID-19: Volume 2: Societal and Medical Perspectives (pp. 319–333). Elsevier. https://doi.org/10.1016/B978-0-323-90769-9.00009-8

Ramlan, M. (2002). PEMANASAN GLOBAL (GLOBAL WARMING).

SNI-2847-2019-Persyaratan-Beton-Struktural-Untuk-Bangunan-Gedung-1 (1). (n.d.).

Sun, C., Xu, H., Wan, D., & Li, Y. (2021). Building Information Modeling Application Maturity Model (BIM-AMM) from the Viewpoint of Construction Project. Advances in Civil Engineering, 2021. https://doi.org/10.1155/2021/6684031

Toroxel, J. L. (2024). A Review of Passive Solar Heating and Cooling Technologies Based on Bioclimatic and Vernacular Architecture. Energies, 17(5). https://doi.org/10.3390/en17051006

Zubair, M. U. (2024). BIM- and GIS-Based Life-Cycle-Assessment Framework for Enhancing Eco Efficiency and Sustainability in the Construction Sector. Buildings, 14(2). https://doi.org/10.3390/buildings14020360