The reliability and stability of the system in the operation of the electric power system is very important, in order to provide comfort in service to consumers. The transformer is a very important component in the electric power system, because it is used as a voltage adjuster for the load being served. This study discusses the effect of loading and temperature on the life shrinkage of 36/60 MVA power transformers in block 3 and block 4 carried out at PT. PJB UBJ O&M PLTMG Arun Lhokseumawe, Aceh. From the calculation results after 4 years the transformer operates, if the transformer is given a 100% load, the transformer will experience an age difference of 2.52 p.u/day so that it has a remaining life for of 10 years. As for the transformer that is given a load of 90%, the transformer will experience an age difference of 1.44 p.u/day so that it has a remaining life to perform operations for another 18 years. Then for a transformer that is given a load of 80%, the transformer will experience an age difference of 0.67 p.u/day so that it will have a remaining life to carry out the operation again for another 38 years. From the above calculation, the origin of the temperature obtained for the ONAN type of cooler in block 3 is 0.71 p.u/day and in block 4 it is 0.70 p.u/day. While the ONAF type of cooler in block 3 is 0.004 p.u/day and in block 4 it is 0.005 p.u/day. This is in accordance with the regulation SPLN50/1982 regarding transformer life shrinkage.

Andika, D. A. Y., Agus Supardi, S. T., & others. (2018). Effect of Loading on the Life of the Power Transformer at the 150 kV . Palur Substation. Muhammadiyah University of Surakarta.

Bambang N, A., & others. (2020). Analysis of Transformer Costs Due to Total Power Loss Using the Annual Worth Method at the Wonogiri Hydroelectric Power Plant. Muhammadiyah University of Surakarta.

Efendi, S. R. I. M. (2018). Transformer Cooling System At PLTMG ARUN 184 MW. ETD Unsyiah.

Pandapotan, J., & Warman, E. (2016). Study of the Effect of Loading on Power Transformer Life Loss. Jurnal Singuda Ensikom, 3(1).

Perera, K., Lucas, J. R., Kumarasinghe, K., Dias, R., Athukorala, U., & Gunawardana, P. G. A. (2001). Estimation of optimum transformer capacity based on load curve. Trans. Inst. Elect. Eng. Sri Lanka, 3(1).

Petra, F. (2017). Overcurrent protection for 2000 KVA transformer, 3.3 KV/380-220 Volt voltage at PT Century Textile Indonesia.

Putra, R. K., & Murdiya, F. (2017). Characteristics of Alternating Current Translucent Voltage in Castor Oil (Jatropha curcas) as an Alternative to Liquid Insulation.Riau University.

Siahaan, C. (2018). Power Transformer Aging Model Assessment According to IEC/IEEE Standards and Economic Value Determination by Annual Rate Method.

Sigit, P., Sukamdi, T., & Karnoto, K. (2011). Analysis of the Effect of Loading on Power Transformer Life Loss. Department of Electrical Engineering, Faculty of Engineering Undip.

Situmorang, B. M. (2011). Analysis of Transformer Costs Due to Total Power Loss with the Annual Worth Method. University of Indonesia.

Solikhudin, M. (2010). Study of Interbus Interbus Transformer (IBT-1) 500/150 kV at GITET 500 kV Kembangan-West Jakarta. Faculty of Engineering, Postgraduate Program in Engineering, University of Indonesia. Jakarta.

Sulasno, I. (2001). TEngineering and Electric Power Distribution System. Volume I, Diponegoro University Publishing Agency, Semarang.

Syahputri Marantika, N. (2016). Calculation of Life Loss of 30 MVA Power Transformer Due to Loading on PT. Padang Cement. Padang State Polytechnic.