Improving productivity and performance is a continuous process in all manufacturing companies. Since a product fabrication process mostly consists of many production and work steps, there is always an opportunity for small improvement. If conducted consistently and continually, a series of small improvements can yield a considerable increase in overall productivity and performance. In this paper, the effort undertaken in an automotive spare part manufacturing company to reduce downtime due to the dandori process is presented. Dandori is the installation or setup required between the production of two different spare part types. The setup includes stocking in incomplete lots of product, or the cripple parts, of one type and stocking out the cripple parts of the other. The existing dandori process consisted of 12 steps and required 190.2 seconds. The development of a storage management system was proposed to reduce the downtime required to fill the production check sheets and to find the correct drawer in the storage room. The new dandori process consists of 19 steps and requires 140.4 seconds. The manual check sheet filling was replaced with QR code scanning and data input on a computer, while the manual finding of the correct drawer was assisted by the LED indicators. Production data for the duration 4 months before and 4 months after the improvement was analyzed. The availability rate of the process increases from 84.87% to 89.34%, and the overall equipment effectiveness (OEE) increases from 73.11% to 78.37%. The obvious increases encourage further continuous improvement cycle in the company.

Arkadiusz, G., and Aleksander, N. (2017). Application of OEE coefficient for manufacturing lines reliability improvement. Proceedings of the 2017 International Conference on Management Science and Management Innovation (MSMI 2017). doi:10.2991/msmi-17.2017.42

Craig, J. C. and Webb, J. (1998). Microsoft Visual Basic 6.0 Developer's Workshop. New York: Microsoft Press, 1998.

Davis, R. K., (1995). Productivity Improvements Through TPM. Great Brittain: Prentice Hall.

Gani, A. J. and Bendatu, L. Y. (2015). Perbaikan Proses Dandori di PT. Astra Otoparts Tbk. Divisi Adiwira Plastik. Jurnal Tirta, 3(2), 1-8.

Krachangchan, K. and Thawesaengskulthai, N. (2018). Loss time reduction to improve overall equipment effectiveness (OEE). 2018 5th International Conference on Industrial Engineering and Applications (ICIEA). https://doi.org/10.1109/iea.2018.8387132

Lestari, W. P. and Wulandari, I. A. (2023). Effectiveness Analysis of Milling Machine Using Overall Equipment Effectiveness and Determination of Preventive Maintenance Using Age Replacement. https://doi.org/10.21070/ups.1966

Moradizadeh, H. and Mayorga, R. V. (2014). Overall equipment effectiveness and overall line efficiency measurement using fuzzy inference systems. Proceedings of the International Conference on Fuzzy Computation Theory and Applications. https://doi.org/10.5220/0005155101990204

Nakajima, S. (1988). Introduction to Total Productive Maintenance, Tokyo: Productivity Press.

Schuber, E. F. (2006). Light-Emitting Diodes. New York: Cambridge University Press.

Sitompul, E., Wulandari, T., and Galina, M. (2022). A Prototype of an IoT-based Production Performance and Quality Monitoring System Using NodeMCU ESP8266. Jurnal Ilmu Elektroteknika (Techne). 21(1), 45-62.

Subagio, D. et al. (2016). Rancang Bangun PLC Training Kit Divisi Service Parts and Welding Production Berbasis PLC Omron CJ2M-CPU11," TECHNOLOGIC, 7(2), 1-8.

Wibowo A. (2019). OEE (Overall Equipment Effectiveness. KAIZENPRO. https://www.kaizenpro.asia/2019/01/oee-overall-equipment-effectiveness.html.

Widagdo et al. (2005) Handout Toyota Production System Training for PT. Astra Daihatsu Motor's Vendor. Jakarta: PT. Astra Daihatsu Motor.