Upstream Oil and Gas Subsidiary SI is a natural gas processing company that operates an H2S removal unit to convert natural gas rich in CO2 and H2S into sweet gas. The main problem of this unit is the high temperature of lean amine entering the Amine Contactor. The purpose of this study is to determine the factors of high lean amine temperatures, evaluate the lean amine cooler, amine regenerator overhead cooler, and plate exchanger performance, and determine the optimal process design configuration and operating parameters. The method used is the simulation of the H2S removal unit with Aspen HYSYS, followed by a comparative analysis between simulation data and equipment design data. The independent variables of this study include Reboiler duty, reflux ratio, and heat transfer area in the Plate Exchanger, with the main dependent variable being lean amine temperature. The results showed that the high lean amine temperature was caused by a decrease in the performance of the Lean Amine cooler and amine regenerator overhead cooler, as seen from the UA and LMTD values of the simulation results which were smaller than the design. In contrast, the Plate Exchanger still functions well with a UA value greater than the design. Optimization was carried out by adjusting the process design and operating parameters of the H2S removal unit. The optimized design involves bypass reflux from the regenerator to the rich amine stream entering the rich/lean amine exchanger and increasing the heat transfer surface area of the plate exchanger to 62.17 m². The influential operating parameters are reboiler duty, liquid flow rate to the mixer, and plate exchanger heat transfer surface area. Optimal operating conditions were achieved at a Reboiler duty of 1,642 kW, a liquid flow rate of 1.4 m³/h, the reflux to Mixer ratio is 100%, and a heat transfer surface area of 62.17 m². In addition, it can be concluded that the optimization of process design and operating parameters successfully reduced the lean amine inlet temperature of the Amine Contactor.

H2S removal unit, lean amine temperature, operating parameters, optimization, process design.

Abdel-Aal, H.K., 2003, Petroleum Engineering. National Research Center Egypt.

Adikharisma, R., 2014,Analisis Kinerja Proses CO2 Removal pada Kolom Absorber di Pabrik Amoniak Unit 1 PT. Petrokimia Gresik. Institut Teknologi Sepuluh Nopember.

Alexander, M.n.t., Neraca Massa dan Neraca Energi Pengelolaan Sampah Terpadu - Penujah Kabupaten Tegal. Jurnal Ilmiah TEKNOBIZ, 8(3), 129–138. doi: 10.35814/teknobiz.v8i3.894.

Aulia, H.N., 2022, Simulasi Aspen HYSYS pada Kolom Absorbsi Gas CO2 dengan Solven Metildietanolamine (MDEA). Jurnal Teknologi Technoscientia, 14(2), 85–90. doi: 10.34151/ technoscientia.v14i2.3579.

Aziz, P.A., Rachmat, M., Chandra, S., Daton, W. N. & Tony, B., 2023, Techno-Economic Solution for Extending CCUS Application in Natural Gas Fields: A Case Study of B Gas Field in Indonesia. Scientific Contributions Oil and Gas, 46(1), 19-28. doi: 10.29017/SCOG.46.1.1321.

Christie, J. & Geankoplis., 1983, Transport Process and Unit Operation. PTR Prentice- Hall Inc, Englewood Cliffs, New Jersey.

Edgar, T.F., Himmelblau, D.M. & Lasdon, L. S., 2001, Optimization of Chemical Processes (2nd ed.). McGraw-Hill.

Fatimura, M., Fitriyanti, R. & Masriatini, R., 2018, Penanganan Gas Asam (Sour Gas) yang Terkandung dalam Gas Alam Menjadi Sweetening Gas. Jurnal Redoks, 3(2), 55–67. doi: 10.31851/ redoks.v3i2.2390.

Fuqoha, I., 2012, Perancangan dan Estimasi Biaya Unit Pemisahan Gas Asam dengan Kandungan CO2 dan H2S Tinggi. Universitas Indonesia.

Giffari, F., Widiastuti, P., Rosmayati, L., Nofrizal & Kusdiana, D., 2021, A New Approach for East Natuna Gas Utilization. Scientific Contributions Oil and Gas, 44(3), 215-221. doi: 10.29017/ SCOG.44.3.713.

Halimah, M.R., Nasrulza, Azhari, Meriatna & Sulhatun., 2024, Optimasi Penggunaan Solven MDEA (Metildietanolamine) pada Absorpsi Gas CO2 dengan Simulasi Aspen HYSYS V.11. Chemical Engineering Journal Storage, 4(3), 325-337. doi: 10.29103/cejs.v4i3.14893.

Jones, D., S., J., 2016, Handbook of Petroleum Processing.

Kurniawan, D., H., 2024, Redesain Electric Submersible Pump (Esp) pada Sumur yang Mengandung Gas “W- 30” Lapangan “A”. Lembaran Publikasi Minyak dan Gas Bumi, 58(1), 1-11. doi: 10.29017/LPMGB.58.1.1610.

Mahfud, M. & Sabara, Z., 2018, Industri Kimia Indonesia (1st ed.). Deepublish.

McCabe, W.L, Smith, J.C. & Peter, H., 1993, Unit Operations of Chemical Engineering Fifth Edition (5th ed.). McGraw-Hill Book Company.

Michael, S., 2021, Analisis Gas Sweetening untuk Menghilangkan Gas H2S dan CO2 dari Produksi Gas yang Akan Dipasarkan Menggunakan Metode Numerik. Universitas Islam Riau.

Kementerian Pendidikan dan Kebudayaan Republik Indonesia. 2015. Gas Processing. Kementerian Pendidikan dan Kebudayaan Republik Indonesia.

Mujiyanti, S.F., 2018, Desain Plantwide Control pada Gas Processing Facility (GPF) Plant. Institut teknologi Sepuluh November.

Rahmatika, F.A., Ariq, Y.N., Susianto & Taufany, F., 2019, Pra-Desain Pabrik LPG dari Gas Alam. Jurnal Teknik ITS, 8(2), 46–51. doi: 10.12962/ j23373539.v8i2.43597.

Smith, J.M., Ness H.C.V. & Abbott, M.M., 2005, Introduction to Chemical Engineering Thermodynamics Seventh Edition (7th ed.). McGraw-Hill Book Company.

Sopurta, A., Siregar, P.I. & Ekawati, E., 2014, Perancangan Sistem Simulasi HYSYS & Integrasi dengan Programmable Logic Controller-Human Machine Interface: Studi Kasus pada Plant Kolom Distilasi Etanol-Air. Jurnal Otomasi Kontrol Dan Instrumentasi, 6(1), 1. doi: 10.5614/joki.2014.6.1.1.

Sugihardjo, 2022, CCUS-Aksi Mitigasi Gas Rumah Kaca dan Peningkatan Pengurasan Minyak CO2-EOR. Lembaran Publikasi Minyak dan Gas Bumi, 56(1), 21-35. doi: 10.29017/LPMGB.56.1.916.

Wuryanti, S., 2016, Neraca Massa dan Energi. Politeknik Negeri Bandung.

Yaws, C.L., 1999, Chemical Properties Handbook. McGraw-Hill Companies.