Application of the Green Building Concept (BGH) in High-Rise Office Buildings Based on Hybrid Dynamics to Improve Cost Performance

  • Ahmad Barri Barri Universitas Mercu Buana, Jakarta, Indonesia
  • Budiandru Universitas Muhammdiyah Prof. Dr. Hamka, Jakarta, Indonesia
Keywords: Green Building (GB), SEM-PLS, high-rise office buildings, Cost Performance, Hybrid Dynamic

Abstract

Global warming, including droughts, rising sea levels, melting polar ice caps, and solar storms, poses a very serious and significant threat to the planet due to current climate change. Green Buildings (GB) are buildings that achieve significant and measurable results in saving energy, water, and other resources by applying BGH principles based on the function and classification of the project. The Indonesian government's latest regulation, through the Technical Guidance on BGH Performance Evaluation Standards of the Ministry of Public Works and Public Housing (PUPR) for 2022, is a way to reduce carbon emissions and achieve the net zero emissions (NZE) target by 2060. Regulatory Review: This study aims to analyze the factors that most influence the implementation of green buildings by the Minister of Public Works and Public Housing ministry of high-rise office buildings in indonesia towards increasing costs using the hybrid dynamic method, using Structural Equation Modeling (SEM) - Partial Least Square (PLS).

References

Abdel-Galil, E., Ibrahim, A. H., & Alborkan, A. (2022). Assessment of transaction costs for construction projects. International Journal of Construction Management, 22(9), 1618-1631.

Abou Leila, M. M. S., & Alaboud, N. S. (2023). A Unified Sustainability Assessment Metrics for the Countries of the Gulf Cooperation Council-A Critical Study. Journal Architecture & Planning, 35(2).

Akram, M. W., Mohd Zublie, M. F., Hasanuzzaman, M., & Rahim, N. A. (2022). Global prospects, advance technologies and policies of energy-saving and sustainable building systems: A review. Sustainability, 14(3), 1316.

Al-Emran, M., Mezhuyev, V., & Kamaludin, A. (2019). PLS-SEM in information systems research: a comprehensive methodological reference. In Proceedings of the International Conference on Advanced Intelligent Systems and Informatics 2018 4 (pp. 644-653). Springer International Publishing.

Ascione, F., Bianco, N., Mauro, G. M., & Napolitano, D. F. (2019). Building envelope design: Multi-objective optimization to minimize energy consumption, global cost and thermal discomfort. Application to different Italian climatic zones. Energy, 174, 359-374.

Astoeti, D. R., & Dwijendra, N. K. A. (2022). Green Supply Chain Performance Based on Green Building Assessment (Case Study of Sukawati Art Market Construction Stage, Gianyar Regency). ASTONJADRO, 11(1), 94-107.

Buratti, C., Orestano, F. C., & Palladino, D. (2016). Comparison of the energy performance of existing buildings by means of dynamic simulations and artificial neural networks. Energy Procedia, 101, 176-183.

Dong, J., Li, R., & Wang, D. (2018, July). System Dynamics-Based Project Cost Risk Accession Control Modeling. In 2018 Eighth International Conference on Instrumentation & Measurement, Computer, Communication and Control (IMCCC) (pp. 81-86). IEEE.

Eddy, T., Agustina, A., & Purnomo, S. (2023, September). Influence of Sustainable Construction for The Environment and Social Community. In RSF Conference Series: Business, Management and Social Sciences, 3(3), 410-417.

Eromobor, S. O., & Das, D. (2013, October). Dynamic modelling approach for designing sustainable green buildings. In SB13 Southern Africa Conference.

Fadloli, L., Arifin, H. S., & Ridwan, W. A. (2023). Study on green concrete (porous concrete) sustainability in order to support the sustainable construction in Indonesia. Jurnal Pengelolaan Sumberdaya Alam dan Lingkungan (Journal of Natural Resources and Environmental Management), 13(3), 432-443.

Fan, Y., & Xia, X. (2017). A multi-objective optimization model for energy-efficiency building envelope retrofitting plan with rooftop PV system installation and maintenance. Applied energy, 189, 327-335.

Faten Albtoush, A. M., Doh, S. I., Abdul Rahman, A. R. B., & Albtoush, J. F. A. A. (2020). Factors effecting the cost management in construction projects. International Journal of Civil Engineering and Technology, 11(1).

Ghafiqie, A. (2012). Universitas Indonesia Pengembangan Model Sistem Dinamis Untuk Menganalisa Kontribusi Mrt Jakarta Terhadap Pad DKI Jakarta. Universitas Indonesia Library, 1-82.

Hapsari, M. A., & Putri, W. H. (2022, December). Challenges and Chances of Sustainable Construction in Indonesia: Policy Insights. In IOP Conference Series: Earth and Environmental Science (Vol. 1111, No. 1, p. 012085). IOP Publishing.

Husin, A. E., & Aulia, D. (2022). Dynamic Model-Based Risk Manageability in the Modular Construction of High-Rise Residential Buildings to Improve Project time Performance. Civil Engineering and Architecture, 10(6), 2541– 2553. https://doi.org/10.13189/cea.2022.100623

Husin, A. E., Prawina, R. S., Pangestu, R., & Priyawan, P., (2023). Application of the Green Retrofitting Concept in High-Rise Residential Buildings Using System Dynamics and M-PERT to Optimize Time Performance (p. Oakland Publishing and Quality Conferences, Ohio). Second International Conference on Scientific Research & Innovation (2ICSRI 2023), E-ISSN:1551-7616.

Husin, A. E., Prawina, R. S., Priyawan, P., Detty, K. B., Pangestu, R., Kristiyanto, K., & Sinaga, L. (2023). Optimizing Time Performance in implementing Green Retrofitting on High-Rise Residential by using Dynamic Systems and M-Pert. http://www.civilejournal.org/

Joseph Jr, F. (2021). Partial Least Squares Structural Equation Modeling (PLS-SEM) Using R: A Workbook. Springer International Publishing.

Juliardi, R. D., Misnan, M. S., Khalid, A. G., & Haron, L. (2019, October). Recognizing of Building Components to Achieve Green Performance for Renovation and Retrofitting Works. In IOP Conference Series: Earth and Environmental Science (Vol. 353, No. 1, p. 012017). IOP Publishing.

Lee, L. J. H., Leu, J. D., & Huang, Y. W. (2015, April). Implementation of enterprise resource planning using the value engineering and system dynamics methods. In 2015 2nd International Conference on Information Science and Control Engineering (pp. 764-768). IEEE.

Leon, H., Osman, H., Georgy, M., & Elsaid, M. (2018). System dynamics approach for forecasting performance of construction projects. Journal of Management in Engineering, 34(1), 04017049.

Li, C. Z., Hong, J., Fan, C., Xu, X., & Shen, G. Q. (2018). Schedule Delay Analysis of Prefabricated Housing Production: A Hybrid Dynamic Approach. Journal of Cleaner Production, 195, 1533-1545.

Porwal, A., Parsamehr, M., Szostopal, D., Ruparathna, R., & Hewage, K. (2023). The Integration of Building Information Modeling (BIM) and System Dynamic Modeling to Minimize Construction Waste Generation from change orders. International Journal of Construction Management, 23(1), 156-166.

Sumiyati, Y., & Purisari, R. (2019, November). The gaps of passive strategy option in Indonesia’s green building regulation. In IOP Conference Series: Materials Science and Engineering (Vol. 669, No. 1, p. 012047). IOP Publishing.

Wahyudi, M. A., Husin, A. E., & Amalia, N. (2023). Factors Influencing Cost Performance Improvement on the Concept of Green Retrofitting High-Rise Offices Using Structural Equationg Modelling-Part Least Square (SEM-PLS). ASTONJADRO, 12(2), 507-518.

Published
2024-01-05
How to Cite
Barri, A. B., & Budiandru. (2024). Application of the Green Building Concept (BGH) in High-Rise Office Buildings Based on Hybrid Dynamics to Improve Cost Performance. International Journal of Science and Society, 6(1), 273-291. https://doi.org/10.54783/ijsoc.v6i1.1010