Raw Materials and Consumables Required for Shielded Metal Arc Welding (SMAW) Training Practice: Development of a Multi-Criteria Framework for Technical and Vocational Education and Training Institutions
DOI:
https://doi.org/10.61227/arji.v8i3.817Keywords:
Shielded Metal Arc Welding, SMAW, TVET, vocational education, welding consumables, welding pedagogy, occupational safety, resource management, technical educationAbstract
The increasing demand for qualified welding specialists in manufacturing, construction, transportation, and energy sectors has intensified the need for effective welding education within Technical and Vocational Education and Training (TVET) systems. Shielded Metal Arc Welding (SMAW) remains one of the most widely taught welding processes because of its versatility, cost-effectiveness, and industrial relevance. However, many TVET institutions continue to face challenges related to the selection, planning, and management of training materials and consumables. Inadequate material selection frequently results in excessive waste, lower training efficiency, reduced weld quality, and increased occupational safety risks. This study develops a multi-criteria framework for selecting raw materials, welding consumables, auxiliary materials, and personal protective equipment for SMAW practical training. A mixed-methods research design was adopted, combining literature analysis, international standards review, expert evaluation, experimental training implementation, and statistical assessment. Three groups of trainees (n = 75) participated in experimental training programs utilizing different material-selection strategies. Training effectiveness was evaluated through weld quality indicators, skill acquisition rates, defect occurrence, material consumption, safety performance, and cost-efficiency metrics. The findings demonstrate that the systematic alignment of training materials with learner competency levels significantly improves educational outcomes. The proposed framework increased skill acquisition rates by 38%, reduced rework requirements by 47%, and improved overall training efficiency by approximately 25%. Furthermore, the integration of advanced personal protective equipment and localized ventilation systems substantially enhanced occupational safety performance. The study contributes a novel pedagogically adapted material-selection model and provides evidence-based recommendations for TVET institutions seeking to modernize welding curricula and optimize resource management.
Downloads
References
AWS. (2020). Structural welding code—Steel (AWS D1.1). American Welding Society.
ISO. (2017). ISO 9606-1: Qualification testing of welders. International Organization for Standardization.
ISO. (2018). ISO 3834: Quality requirements for fusion welding of metallic materials. ISO.
Callister, W. D., & Rethwisch, D. G. (2018). Materials science and engineering: An introduction. Wiley.
Kalpakjian, S., & Schmid, S. R. (2014). Manufacturing engineering and technology. Pearson.
Cary, H. B., & Helzer, S. C. (2005). Modern welding technology. Pearson.
Parvez, M. S., et al. (2021). Welding defects and quality control in SMAW processes. Journal of Manufacturing Processes, 64, 123–134.
Zhang, Y., & Liao, Z. (2022). Optimization of welding parameters in vocational training environments. Welding Journal, 101(4), 45–56.
Smith, R., & Patel, K. (2021). Competency-based welding education in TVET institutions. International Journal of Training Research, 19(3), 210–225.
Kumar, S., & Singh, R. (2020). Material utilization efficiency in manufacturing training systems. Journal of Cleaner Production, 255, 120–130.
UNESCO. (2021). TVET systems and skills development report. UNESCO Publishing.
ILO. (2020). Skills development for inclusive growth. International Labour Organization.
Banga, J., & Velde, D. W. (2018). Digitalization and skills development. ODI Working Paper.
Chua, B. H. (2019). Welding process optimization in industrial applications. Journal of Materials Processing Technology, 267, 12–24.
Li, X., et al. (2020). Arc stability and welding defect formation. Materials & Design, 195, 108–117.
Hasan, M., & Ahmed, T. (2021). Safety management in welding workshops. Safety Science, 140, 105–112.
Wang, J., et al. (2019). Lean manufacturing principles in vocational training. Procedia Manufacturing, 30, 45–52.
OECD. (2019). Skills outlook 2019. OECD Publishing.
UNESCO-UNEVOC. (2020). TVET for sustainable development.
Deming, W. E. (1986). Out of the crisis. MIT Press.
Juran, J. M. (1999). Quality handbook. McGraw-Hill.
Montgomery, D. C. (2017). Introduction to statistical quality control. Wiley.
Taguchi, G. (1986). Introduction to quality engineering. Asian Productivity Organization.
Heizer, J., Render, B. (2014). Operations management. Pearson.
Slack, N., et al. (2016). Operations management. Pearson.
Chen, Z., & Wu, H. (2020). Welding training effectiveness in technical education. Education and Training, 62(7), 789–804.
Ali, F., et al. (2021). Occupational hazards in welding industries. Journal of Safety Research, 78, 90–101.
Patel, M., & Kumar, D. (2022). Simulation-based welding training systems. Computers in Education Journal, 13(2), 55–70.
Rahman, M., et al. (2019). Cost analysis in vocational training institutions. International Journal of Educational Development, 66, 120–129.
UNESCO-UNEVOC. (2021). Skills for green economy.
OECD. (2020). Learning for jobs report.
Li, Y., & Zhang, H. (2021). Welding defect reduction strategies. Materials Science Forum, 1012, 33–44.
Kumar, P., et al. (2020). Arc welding process stability. Welding International, 34(6), 445–456.
Singh, R., et al. (2019). Productivity improvement in welding training. Journal of Manufacturing Systems, 52, 78–88.
Brown, D. (2018). Welding fundamentals and applications. McGraw-Hill.
Scott, J. (2020). Technical education and workforce development. Education + Training, 62(5), 500–515.
Zhao, L., et al. (2022). Decision-making models in engineering education. Expert Systems with Applications, 189, 116–128.
Saaty, T. L. (2008). Decision making with the analytic hierarchy process. International Journal of Services Sciences, 1(1), 83–98.
Wang, X., et al. (2020). Multi-criteria decision making in engineering. Omega, 95, 102–115.
ISO. (2015). ISO 14731: Welding coordination.
AWS. (2019). Welding handbook. AWS.
Groover, M. P. (2015). Automation, production systems, and CIM. Pearson.
UNIDO. (2020). Industrial skills development report.
NPTEL. (2019). Manufacturing processes II: Welding.
Lee, S., et al. (2021). Welding education technology integration. Journal of Engineering Education, 110(3), 456–470.
Kim, J., & Park, S. (2020). Safety compliance in vocational workshops. Safety Science, 128, 104–112.
UNESCO. (2022). Global education monitoring report.
ILO. (2021). World employment and social outlook.
Zhang, W., et al. (2019). Arc stability in SMAW processes. Journal of Materials Engineering and Performance, 28, 350–360.
Miller, D. (2017). Welding engineering basics. Springer.
O’Brien, R. (2020). Welding consumables and performance. Metallurgical Reviews, 65, 88–99.
ISO. (2020). ISO welding safety standards overview.
Additional Files
Published
How to Cite
Issue
Section
License
Copyright (c) 2026 Authors

This work is licensed under a Creative Commons Attribution 4.0 International License.
Similar Articles
- Joy Amaechi Okeke - Ezeanyanwu, Sylvia Chinwe Okere, Effectiveness of Internal Control Measures for Preventing Employee’s Fraud in Public Secondary Schools in Ebonyi State Nigeria , Action Research Journal Indonesia (ARJI): Vol. 7 No. 2 (2025): Action Research Journal Indonesia (ARJI)
- Ann Ngozi Ugobueze , The Impact of Motivation on Primary Education Teachers: A Study in Idemili South Local Government Area of Anambra State, Nigeria , Action Research Journal Indonesia (ARJI): Vol. 6 No. 4 (2024): Action Research Journal Indonesia (ARJI)
- Firmansyah Firmansyah, Gatot Kaca, Miftahul Husni, Emma Himayaturohmah, Mukti Ali, Revitalizing Adab Education in Pesantren as a Strategy for Strengthening the Morals of the Younger Generation , Action Research Journal Indonesia (ARJI): Vol. 7 No. 4 (2025): Action Research Journal Indonesia (ARJI)
- Nurul Azizah, Fadli Fadli, Jaya Gusnanda, Fitri Khairunisa, Fauziah Ahmad, Nadya Ranialini, IRE Students' Perception of The Relevance of IRE Learning In Higher Education: A Qualitative Study In An Academic Environment , Action Research Journal Indonesia (ARJI): Vol. 7 No. 3 (2025): Action Research Journal Indonesia (ARJI)
- M. Agung Alwanda, Rizki Saputra, An Analysis of Educational Philosophy and the Values of the Pancasila Student Profile as the Foundation of the Kurikulum Merdeka , Action Research Journal Indonesia (ARJI): Vol. 7 No. 4 (2025): Action Research Journal Indonesia (ARJI)
- Rachel Kalonga, Prospery M. Mwila, Effect of Class Size on Quality of Education in Public Secondary Schools in Temeke Municipality, Tanzania , Action Research Journal Indonesia (ARJI): Vol. 7 No. 2 (2025): Action Research Journal Indonesia (ARJI)
- Augusta Chiedu Assimonye, Chinasa Florence Okoh, Impact of curriculum Differentiation on Students’ interest in English Language in Secondary Schools , Action Research Journal Indonesia (ARJI): Vol. 7 No. 4 (2025): Action Research Journal Indonesia (ARJI)
- Bramianto Setiawan, Vina Iasha, Trends and Innovations in Character Building for Primary School Students in Indonesia , Action Research Journal Indonesia (ARJI): Vol. 6 No. 4 (2024): Action Research Journal Indonesia (ARJI)
- Adaobi Jennifer Iloakasia, Career Guidance Programs and the Impact They Have in Eradicating Gender Imbalances in STEM Education For Market Competitiveness , Action Research Journal Indonesia (ARJI): Vol. 6 No. 3 (2024): Action Research Journal Indonesia (ARJI)
- Sumarni Sumarni, Agus Salam, Aris Iwansyah, Nutrition Education for Young Children as a Means of Preventing Stunting in KB Al Mutchtaddin , Action Research Journal Indonesia (ARJI): Vol. 8 No. 2 (2026): Action Research Journal Indonesia (ARJI)
You may also start an advanced similarity search for this article.


