Inadequate or delayed supply of raw materials or components needed for production can lead to line stoppages. Reducing the frequency and duration of line stoppages is crucial for maintaining efficiency and meeting production targets. It can happen due to logistics problemsThis research was conducted in the logistics department of an automotive component company. One of the causes is the procurement of tooling, which needs to be improved for production needs. The tooling factor is part of the logistics scope and is the highest factor causing lost opportunities and line stoppages. To minimize the impact of line production stoppages, manufacturers often implement strategies like implementing a minimum stock of insert components. The problem-solving methodology includes a five whys analysis, conducting a Pareto diagram, determining the service level of the stock level, and calculating the maximum-minimum stock level. Based on the result, 17 types of inserts must apply stock levels to avoid stock shortages.

Albrecht, M. (2014). Determining near optimal base-stock levels in two-stage general inventory systems. European Journal of Operational Research, 232(2), 342–349. https://doi.org/10.1016/j.ejor.2013.07.025

Amin Kadafi, M., & Delvina, A. (2021). Analisis pengendalian persediaan bahan baku dengan safety stock optimum. Forum Ekonomi, 23(3), 553–560. http://journal.feb.unmul.ac.id/index.php/FORUMEKONOMI

Basuki, B. (2019). Penentuan Safety Stock Speedometer Y9J Untuk Menghindari Terjadinya Stockout. Industrial Engineering Journal, 8(1), 37–40. https://doi.org/10.53912/iejm.v8i1.379

Chandra, J., & Sunarni, T. (2019). Perancangan Tata Letak Mi Instan Di Toko Amuk Dengan Mempertimbangkan Sistem Persediaan. Jurnal Ilmiah Teknik Industri, 7(1), 60–69. https://doi.org/10.24912/jitiuntar.v7i1.5038

Ducharme, C., Agard, B., & Trépanier, M. (2021). Forecasting a customer’s Next Time Under Safety Stock. International Journal of Production Economics, 234(June 2020). https://doi.org/10.1016/j.ijpe.2021.108044

Ekren, B. Y., & Ornek, M. A. (2015). Determining optimum (s, S) levels of floor stock items in a paint production environment. Simulation Modelling Practice and Theory, 57, 133–141. https://doi.org/10.1016/j.simpat.2015.06.009

Funaki, K. (2012). Strategic safety stock placement in supply chain design with due-date based demand. International Journal of Production Economics, 135(1), 4–13. https://doi.org/10.1016/j.ijpe.2010.11.015

Hasan, I. A., & Pulansari, F. (2023). Application of the Min-Max Stock Method in the Inventory Control of the Raw Materials for the Cement Production at PT XYZ. IJIEM (Indonesian Journal of Industrial Engineering & Management), 4(3), 303–309. https://doi.org/10.22441/ijiem.v4i3.20953

Helia, V. N., & Suyoto, A. W. (2018). Pengendalian Kualitas Produk Kantong Semen Dengan Menggunakan Seven Quality Control Tools (Studi Kasus Di Pt Xyz). Jurnal Ilmiah Teknik Industri, 5(3), 148–156. https://doi.org/10.24912/jitiuntar.v5i3.2102

Imansuri, F., Bifadhlih, N., Sumasto, F., Rusmiati, E., Dendra, F. G., & Suroso, F. (2024). Perencanaan Agregat Produksi Dengan Metode Peramalan dan Pola Permintaan Musiman: Studi Kasus Perusahaan Manufaktur Tiang Besi. Jisi: Jurnal Integrasi Sistem Industri, 11(2), 167–176. https://doi.org//10.24853/jisi.11.2.203-212

Imansuri, F., Ikhsanjani, A. M., Sumasto, F., Dendra, F. G., Suroso, F., & Rozi, M. F. (2025). Application of Material Requirement Planning in Bracket Chamber Production: A Case Study of Automotive Component Company. IJIEM - Indonesian Journal of Industrial Engineering and Management, 6(1), 119. https://doi.org/10.22441/ijiem.v6i1.26305

Katiandagho, I. G., & Trisyanto, R. (2022). Analisis dan Perancangan ROP, EOQ, Safety Stock Sistem Pengendalian Persediaan Bahan Baku Pada Rumah Makan Bubur Ayam Citarasa. Indonesian Accounting Literacy Journal, 2(1), 45–65. https://doi.org/10.35313/ialj.v2i1.3231

Keskin, G. A., Omurca, S. I., Aydin, N., & Ekinci, E. (2015). A comparative study of production-inventory model for determining effective production quantity and safety stock level. Applied Mathematical Modelling, 39(20), 6359–6374. https://doi.org/10.1016/j.apm.2015.01.037

Kushartini, D., and Almahdy, I. (2015). SISTEM PERSEDIAAN BAHAN BAKU PRODUK DISPERSANT DI INDUSTRI KIMIA. Jurnal PASTI, X(2), 217–234. https://publikasi.mercubuana.ac.id/index.php/pasti/article/view/1590

Moncayo-Martínez, L. A., Reséndiz-Flores, E. O., Mercado, D., & Sánchez-Ramírez, C. (2014). Placing safety stock in logistic networks under guaranteed-service time inventory models: An application to the automotive industry. Journal of Applied Research and Technology, 12(3), 538–550. https://doi.org/10.1016/S1665-6423(14)71633-5

Murti, K. B., Suhardi, B., & Hastuti, F. S. P. (2019). Penentuan Stock Minimal-Maksimal Dan Pola Perencanaan Produksi Pada Seksi Painting Plastic Di Pt. Abc. Seminar Dan Konferensi Nasional IDEC, 2–3.

Piranti, M. N., & Sofiana, A. (2021). Kombinasi Penentuan Safety Stock Dan Reorder Point Berdasarkan Analisis ABC sebagai Alat Pengendalian Persediaan Cutting Tools Integrating of Safety Stock and Reorder Point Based on ABC Analysis. Jurnal Teknik Industri, 7(1), 69–78.

Rachmawati, N. L., & Lentari, M. (2022). Penerapan Metode Min-Max untuk Minimasi Stockout dan Overstock Persediaan Bahan Baku. Jurnal INTECH Teknik Industri Universitas Serang Raya, 8(2), 143–148. https://doi.org/10.30656/intech.v8i2.4735

Sumasto, F., Arliananda, D. A., Imansuri, F., Aisyah, S., & Purwojatmiko, B. H. (2023). Enhancing Automotive Part Quality in SMEs through DMAIC Implementation: A Case Study in Indonesian Automotive Manufacturing. 1745, 57–74. https://doi.org/10.12776/QIP.V27I3.1889