Risk-Based Method-Technology Integration on Spun Pile Production for Product and Service Quality
Vol. 10 No. 11 (2024): November
Research Articles
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Doi: 10.28991/CEJ-2024-010-11-015
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Hidayawanti, R., Latief, Y., & Gaspersz, V. (2024). Risk-Based Method-Technology Integration on Spun Pile Production for Product and Service Quality. Civil Engineering Journal, 10(11), 3683–3698. https://doi.org/10.28991/CEJ-2024-010-11-015
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[1] Orozco, F., Serpell, A., & Olenaar, K. (2011). Competitiveness factors and indexes for construction companies: Findings of Chile. Revista de La Construccion, 10(1), 91–107. doi:10.4067/s0718-915x2011000100009.
[2] Lomineishvili, K. (2021). How entrepreneurial management and continuous learning affect the innovation and competitiveness of companies? Economic Alternatives, 2021(3), 459–468. doi:10.37075/EA.2021.3.08.
[3] Wang, Z., Wang, T., Hu, H., Gong, J., Ren, X., & Xiao, Q. (2020). Blockchain-based framework for improving supply chain traceability and information sharing in precast construction. Automation in Construction, 111. doi:10.1016/j.autcon.2019.103063.
[4] Reichenbach, S., & Kromoser, B. (2021). State of practice of automation in precast concrete production. Journal of Building Engineering, 43. doi:10.1016/j.jobe.2021.102527.
[5] Hidayawanti, R., & Latief, Y. (2023). Raw Material Optimization With Neural Network Method in Concrete Production on Precast Industry. International Journal of GEOMATE, 24(102), 10–17. doi:10.21660/2023.102.g12146.
[6] Kosse, S., Vogt, O., Wolf, M., König, M., & Gerhard, D. (2022). Digital Twin Framework for Enabling Serial Construction. Frontiers in Built Environment, 8. doi:10.3389/fbuil.2022.864722.
[7] Hidayawanti, R., Latief, Y., & Gaspersz, V. (2024). Perceptron model application for traceability risk in spun pile manufacturing. Journal of Infrastructure, Policy and Development, 8(6), 4638. doi:10.24294/jipd.v8i6.4638.
[8] Nurjaman, H. N., Hariandja, B. H., & Sidjabat, H. R. (2008). The Use Of Precast Concrete Systems In The Construction Of Low-Cost Apartments In Indonesia. 14th World Conference on Earthquake Engineering (14WCEE), 22, 1–8. 12-17 October, 2008, Beijing, China.
[9] Noerpratomo, A. (2018). The influence of raw material inventory and production processes on product quality at CV. Banyu Biru Connection. Almana: Jurnal Manajemen dan Bisnis, 2(2), 20-30. (In Indonesian).
[10] Nurjaman, H., Faizal, L., Suaryana, N., Hariandja, B., Gambiro, Purnomo, & Wicaksono, S. (2017). Design, development, and application of precast and prestressed concrete system for rigid pavement in Indonesia. AIP Conference Proceedings, 1903, 030003. doi:10.1063/1.5011510.
[11] Gault, F. (2013). The Oslo Manual. Economics 2013: Handbook of Innovation Indicators and Measurement, 41–59. doi:10.4337/9780857933652.00010.
[12] Bateman, T., Snell, S., Konopaske, R. (2019). Management: Leading & Collaborating in a Competitive World (13th Ed). McGraw Hill, New York, United States.
[13] Putra, R. E., & Isvara, W. (2023). Qualitative Risk Analysis of Production Precast Spun Pile at Company-X. United International Journal for Research & Technology, 05(01), 51–60.
[14] Wiegmann, P. M., de Vries, H. J., & Blind, K. (2017). Multi-mode standardisation: A critical review and a research agenda. Research Policy, 46(8), 1370–1386. doi:10.1016/j.respol.2017.06.002.
[15] Velasquez Villagran, N., Estevez, E., Pesado, P., & De Juanes Marquez, J. (2019). Standardization: A Key Factor of Industry 4.0. Sixth International Conference on eDemocracy & eGovernment (ICEDEG), 350–354. doi:10.1109/icedeg.2019.8734339.
[16] Yang, J., Zhou, L., Qu, Y., Jin, X., & Fang, S. (2023). Mechanism of Innovation and Standardization Driving Company Competitiveness in the Digital Economy. Journal of Business Economics and Management, 24(1), 54–73. doi:10.3846/jbem.2023.17192.
[17] Hyland, J., & Karlsson, M. (2021). Towards a management system standard for innovation. Journal of Innovation Management, 9(1), XI–XIX. doi:10.24840/2183-0606_009.001_0002.
[18] Tidd, J. (2021). A Review and Critical Assessment of the ISO56002 Innovation Management Systems Standard: Evidence and Limitations. International Journal of Innovation Management, 25(1), 2150049. doi:10.1142/S1363919621500493.
[19] Hoonsopon, D. (2009). The empirical study of the impact of product innovation factors on performance of new products: Radical and incremental product innovation. Ph.D. Thesis, Chulalongkorn University, Bangkok, Thailand.
[20] Pan, M., & Pan, W. (2019). Determinants of Adoption of Robotics in Precast Concrete Production for Buildings. Journal of Management in Engineering, 35(5), 05019007. doi:10.1061/(asce)me.1943-5479.0000706.
[21] Fu, Y., Downey, A., Yuan, L., Pratt, A., & Balogun, Y. (2021). In situ monitoring for fused filament fabrication process: A review. Additive Manufacturing, 38. doi:10.1016/j.addma.2020.101749.
[22] O'g, B. O. N. (2021). The Role of Quality Management System in Increasing Product Quality in Enterprises. Web of Scientist: International Scientific Research Journal, 2(12), 228–233.
[23] Feng, C., & Ma, R. (2020). Identification of the factors that influence service innovation in manufacturing enterprises by using the fuzzy DEMATEL method. Journal of Cleaner Production, 253. doi:10.1016/j.jclepro.2020.120002.
[24] Nyadzayo, M. W., Leckie, C., & Johnson, L. W. (2023). Customer participation, innovative aspects of services and outcomes. Marketing Intelligence and Planning, 41(1), 1–15. doi:10.1108/MIP-03-2022-0090.
[25] Truong, N. T., Dang-Pham, D., McClelland, R. J., & Nkhoma, M. (2020). Service innovation, customer satisfaction and behavioural intentions: a conceptual framework. Journal of Hospitality and Tourism Technology, 11(3), 529–542. doi:10.1108/JHTT-02-2019-0030.
[26] Nimfa, D. T., Uzir, M. U. H., Maimako, L. N., Eneizan, B., Latiff, A. S. A. L., & Wahab, S. A. (2021). The Impact of Innovation Competitive Advantage on Product Quality for Sustainable Growth among SMEs: An Empirical Analysis. International Journal of Business Science and Applied Management, 16(3), 39–62. doi:10.69864/ijbsam.16-3.152.
[27] Mohamed, H. A. E., & Eltohamy, A. I. (2022). Critical Success Factors for Competitiveness of Egyptian Construction Companies. Sustainability (Switzerland), 14(17). doi:10.3390/su141710460.
[28] Aboutorab, H., Hussain, O. K., Saberi, M., Hussain, F. K., & Chang, E. (2021). A survey on the suitability of risk identification techniques in the current networked environment. Journal of Network and Computer Applications, 178. doi:10.1016/j.jnca.2021.102984.
[29] Kasap, D., & Kaymak, M. (2007). Risk Identification Step of the Project Risk Management. PICMET '07 - 2007 Portland International Conference on Management of Engineering & Technology, 2116–2120. doi:10.1109/picmet.2007.4349543.
[30] Alfreahat, D., & Sebestyén, Z. (2022). A construction-specific extension to a standard project risk management process. Organization, Technology and Management in Construction, 14(1), 2666–2674. doi:10.2478/otmcj-2022-0011.
[31] PMI (2021). The Standard for Project Management and a Guide to the Project Management Body of Knowledge (7th Ed.). PMBOK Guide, Project Management Institute (PMI), Upper Darby, United States.
[32] Satyadharma, W. R. (2022). Optimization of the spun pile production process using connector rings on the mold. Seminar Nasional Insinyur Profesional (SNIP), 2(1). doi:10.23960/snip.v2i1.39.
[33] Andika Okayana. (2023). Evaluation of Production Process Flow with Line Balancing Method to Increase Round Pile Production Capacity at PT. Adhi Persada Beton Plant Mojokerto-East Java. Jurnal Teknik Industri, 13(1), 90–97. doi:10.25105/jti.v13i1.17520.
[34] Naim, M. A., Rimawan, E., & Putri, A. (2020). Relayout Production Facility of PC. Spun Pile Using Systematic Layout Planning in ABC Factory. International Journal of Innovative Science and Research Technology, 5(8), 1620–1629. doi:10.38124/ijisrt20aug614.
[35] Pop, G. I., & Èší®È›u, A. M. (2021). Identifying the influence of technical resources knowledge on product quality requirements in a global engineering process. International Journal of Mechatronics and Applied Mechanics, 1(9), 225–231. doi:10.17683/ijomam/issue9.32.
[36] Moreira, B. M. D. N., Gouveia, R. M., Silva, F. J. G., & Campilho, R. D. S. G. (2017). A Novel Concept of Production and Assembly Processes Integration. Procedia Manufacturing, 11, 1385–1395. doi:10.1016/j.promfg.2017.07.268.
[37] Lager, T., Simms, C. D., & Frishammar, J. (2023). Managing Ideation and Concept Integration in the Product Innovation Work Process for Non-Assembled Products. International Journal of Innovation and Technology Management, 20(3), 2350016. doi:10.1142/S0219877023500165.
[38] Fattouh, A., Chirumalla, K., Ahlskog, M., Behnam, M., Hatvani, L., & Bruch, J. (2023). Remote integration of advanced manufacturing technologies into production systems: integration processes, key challenges and mitigation actions. Journal of Manufacturing Technology Management, 34(4), 557–579. doi:10.1108/JMTM-02-2022-0087.
[39] Kıral, I. A., Kural, Z., & Çomu, S. (2014). Risk identification in construction projects: Using the Delphi method. 11th International Congress on Advances in Civil Engineering, 21-25 October, 2014, Istanbul, Turkey.
[40] Renzi, A. B., & Freitas, S. (2015). The Delphi Method for Future Scenarios Construction. Procedia Manufacturing, 3, 5785–5791. doi:10.1016/j.promfg.2015.07.826.
[41] Fielding, N. G. (2012). Triangulation and Mixed Methods Designs: Data Integration with New Research Technologies. Journal of Mixed Methods Research, 6(2), 124–136. doi:10.1177/1558689812437101.
[2] Lomineishvili, K. (2021). How entrepreneurial management and continuous learning affect the innovation and competitiveness of companies? Economic Alternatives, 2021(3), 459–468. doi:10.37075/EA.2021.3.08.
[3] Wang, Z., Wang, T., Hu, H., Gong, J., Ren, X., & Xiao, Q. (2020). Blockchain-based framework for improving supply chain traceability and information sharing in precast construction. Automation in Construction, 111. doi:10.1016/j.autcon.2019.103063.
[4] Reichenbach, S., & Kromoser, B. (2021). State of practice of automation in precast concrete production. Journal of Building Engineering, 43. doi:10.1016/j.jobe.2021.102527.
[5] Hidayawanti, R., & Latief, Y. (2023). Raw Material Optimization With Neural Network Method in Concrete Production on Precast Industry. International Journal of GEOMATE, 24(102), 10–17. doi:10.21660/2023.102.g12146.
[6] Kosse, S., Vogt, O., Wolf, M., König, M., & Gerhard, D. (2022). Digital Twin Framework for Enabling Serial Construction. Frontiers in Built Environment, 8. doi:10.3389/fbuil.2022.864722.
[7] Hidayawanti, R., Latief, Y., & Gaspersz, V. (2024). Perceptron model application for traceability risk in spun pile manufacturing. Journal of Infrastructure, Policy and Development, 8(6), 4638. doi:10.24294/jipd.v8i6.4638.
[8] Nurjaman, H. N., Hariandja, B. H., & Sidjabat, H. R. (2008). The Use Of Precast Concrete Systems In The Construction Of Low-Cost Apartments In Indonesia. 14th World Conference on Earthquake Engineering (14WCEE), 22, 1–8. 12-17 October, 2008, Beijing, China.
[9] Noerpratomo, A. (2018). The influence of raw material inventory and production processes on product quality at CV. Banyu Biru Connection. Almana: Jurnal Manajemen dan Bisnis, 2(2), 20-30. (In Indonesian).
[10] Nurjaman, H., Faizal, L., Suaryana, N., Hariandja, B., Gambiro, Purnomo, & Wicaksono, S. (2017). Design, development, and application of precast and prestressed concrete system for rigid pavement in Indonesia. AIP Conference Proceedings, 1903, 030003. doi:10.1063/1.5011510.
[11] Gault, F. (2013). The Oslo Manual. Economics 2013: Handbook of Innovation Indicators and Measurement, 41–59. doi:10.4337/9780857933652.00010.
[12] Bateman, T., Snell, S., Konopaske, R. (2019). Management: Leading & Collaborating in a Competitive World (13th Ed). McGraw Hill, New York, United States.
[13] Putra, R. E., & Isvara, W. (2023). Qualitative Risk Analysis of Production Precast Spun Pile at Company-X. United International Journal for Research & Technology, 05(01), 51–60.
[14] Wiegmann, P. M., de Vries, H. J., & Blind, K. (2017). Multi-mode standardisation: A critical review and a research agenda. Research Policy, 46(8), 1370–1386. doi:10.1016/j.respol.2017.06.002.
[15] Velasquez Villagran, N., Estevez, E., Pesado, P., & De Juanes Marquez, J. (2019). Standardization: A Key Factor of Industry 4.0. Sixth International Conference on eDemocracy & eGovernment (ICEDEG), 350–354. doi:10.1109/icedeg.2019.8734339.
[16] Yang, J., Zhou, L., Qu, Y., Jin, X., & Fang, S. (2023). Mechanism of Innovation and Standardization Driving Company Competitiveness in the Digital Economy. Journal of Business Economics and Management, 24(1), 54–73. doi:10.3846/jbem.2023.17192.
[17] Hyland, J., & Karlsson, M. (2021). Towards a management system standard for innovation. Journal of Innovation Management, 9(1), XI–XIX. doi:10.24840/2183-0606_009.001_0002.
[18] Tidd, J. (2021). A Review and Critical Assessment of the ISO56002 Innovation Management Systems Standard: Evidence and Limitations. International Journal of Innovation Management, 25(1), 2150049. doi:10.1142/S1363919621500493.
[19] Hoonsopon, D. (2009). The empirical study of the impact of product innovation factors on performance of new products: Radical and incremental product innovation. Ph.D. Thesis, Chulalongkorn University, Bangkok, Thailand.
[20] Pan, M., & Pan, W. (2019). Determinants of Adoption of Robotics in Precast Concrete Production for Buildings. Journal of Management in Engineering, 35(5), 05019007. doi:10.1061/(asce)me.1943-5479.0000706.
[21] Fu, Y., Downey, A., Yuan, L., Pratt, A., & Balogun, Y. (2021). In situ monitoring for fused filament fabrication process: A review. Additive Manufacturing, 38. doi:10.1016/j.addma.2020.101749.
[22] O'g, B. O. N. (2021). The Role of Quality Management System in Increasing Product Quality in Enterprises. Web of Scientist: International Scientific Research Journal, 2(12), 228–233.
[23] Feng, C., & Ma, R. (2020). Identification of the factors that influence service innovation in manufacturing enterprises by using the fuzzy DEMATEL method. Journal of Cleaner Production, 253. doi:10.1016/j.jclepro.2020.120002.
[24] Nyadzayo, M. W., Leckie, C., & Johnson, L. W. (2023). Customer participation, innovative aspects of services and outcomes. Marketing Intelligence and Planning, 41(1), 1–15. doi:10.1108/MIP-03-2022-0090.
[25] Truong, N. T., Dang-Pham, D., McClelland, R. J., & Nkhoma, M. (2020). Service innovation, customer satisfaction and behavioural intentions: a conceptual framework. Journal of Hospitality and Tourism Technology, 11(3), 529–542. doi:10.1108/JHTT-02-2019-0030.
[26] Nimfa, D. T., Uzir, M. U. H., Maimako, L. N., Eneizan, B., Latiff, A. S. A. L., & Wahab, S. A. (2021). The Impact of Innovation Competitive Advantage on Product Quality for Sustainable Growth among SMEs: An Empirical Analysis. International Journal of Business Science and Applied Management, 16(3), 39–62. doi:10.69864/ijbsam.16-3.152.
[27] Mohamed, H. A. E., & Eltohamy, A. I. (2022). Critical Success Factors for Competitiveness of Egyptian Construction Companies. Sustainability (Switzerland), 14(17). doi:10.3390/su141710460.
[28] Aboutorab, H., Hussain, O. K., Saberi, M., Hussain, F. K., & Chang, E. (2021). A survey on the suitability of risk identification techniques in the current networked environment. Journal of Network and Computer Applications, 178. doi:10.1016/j.jnca.2021.102984.
[29] Kasap, D., & Kaymak, M. (2007). Risk Identification Step of the Project Risk Management. PICMET '07 - 2007 Portland International Conference on Management of Engineering & Technology, 2116–2120. doi:10.1109/picmet.2007.4349543.
[30] Alfreahat, D., & Sebestyén, Z. (2022). A construction-specific extension to a standard project risk management process. Organization, Technology and Management in Construction, 14(1), 2666–2674. doi:10.2478/otmcj-2022-0011.
[31] PMI (2021). The Standard for Project Management and a Guide to the Project Management Body of Knowledge (7th Ed.). PMBOK Guide, Project Management Institute (PMI), Upper Darby, United States.
[32] Satyadharma, W. R. (2022). Optimization of the spun pile production process using connector rings on the mold. Seminar Nasional Insinyur Profesional (SNIP), 2(1). doi:10.23960/snip.v2i1.39.
[33] Andika Okayana. (2023). Evaluation of Production Process Flow with Line Balancing Method to Increase Round Pile Production Capacity at PT. Adhi Persada Beton Plant Mojokerto-East Java. Jurnal Teknik Industri, 13(1), 90–97. doi:10.25105/jti.v13i1.17520.
[34] Naim, M. A., Rimawan, E., & Putri, A. (2020). Relayout Production Facility of PC. Spun Pile Using Systematic Layout Planning in ABC Factory. International Journal of Innovative Science and Research Technology, 5(8), 1620–1629. doi:10.38124/ijisrt20aug614.
[35] Pop, G. I., & Èší®È›u, A. M. (2021). Identifying the influence of technical resources knowledge on product quality requirements in a global engineering process. International Journal of Mechatronics and Applied Mechanics, 1(9), 225–231. doi:10.17683/ijomam/issue9.32.
[36] Moreira, B. M. D. N., Gouveia, R. M., Silva, F. J. G., & Campilho, R. D. S. G. (2017). A Novel Concept of Production and Assembly Processes Integration. Procedia Manufacturing, 11, 1385–1395. doi:10.1016/j.promfg.2017.07.268.
[37] Lager, T., Simms, C. D., & Frishammar, J. (2023). Managing Ideation and Concept Integration in the Product Innovation Work Process for Non-Assembled Products. International Journal of Innovation and Technology Management, 20(3), 2350016. doi:10.1142/S0219877023500165.
[38] Fattouh, A., Chirumalla, K., Ahlskog, M., Behnam, M., Hatvani, L., & Bruch, J. (2023). Remote integration of advanced manufacturing technologies into production systems: integration processes, key challenges and mitigation actions. Journal of Manufacturing Technology Management, 34(4), 557–579. doi:10.1108/JMTM-02-2022-0087.
[39] Kıral, I. A., Kural, Z., & Çomu, S. (2014). Risk identification in construction projects: Using the Delphi method. 11th International Congress on Advances in Civil Engineering, 21-25 October, 2014, Istanbul, Turkey.
[40] Renzi, A. B., & Freitas, S. (2015). The Delphi Method for Future Scenarios Construction. Procedia Manufacturing, 3, 5785–5791. doi:10.1016/j.promfg.2015.07.826.
[41] Fielding, N. G. (2012). Triangulation and Mixed Methods Designs: Data Integration with New Research Technologies. Journal of Mixed Methods Research, 6(2), 124–136. doi:10.1177/1558689812437101.
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