JURNAL SAINS DAN HUMANIORA CENDEKIA

Inovasi pengelolaan lingkungan menjadi bagian integral dari strategi keberlanjutan industri BBM. Artikel ini mengkaji lima program inovasi di Fuel Terminal Parepare yang dijalankan oleh PT Pertamina Patra Niaga: (1) SMILE (Smart Mobility for Low Emission)-rute distribusi, (2) SEALZERO (Smart Enhancement and Leakage Zero Optimization)-pengelolaan limbah B3, (3) STEELIGHT (Steel for Emergency Light & Fight)-pemanfaatan scrap besi, (4) WATCH (Workflow Automation for Time Consumption and Handling)-efisiensi energi, dan (5) GREEN DRIP (Filtrasi Air AC untuk Hidroponik)-efisiensi air. Metode yang digunakan mencakup deskripsi teknis, kuantifikasi penghematan (energi, konsumsi bahan bakar, air, limbah), dan analisis integratif terhadap kontribusi terhadap terminal hijau. Hasil menunjukkan pengurangan konsumsi solar sebanyak ≈ 2.573.438 L/tahun dan penurunan emisi sebesar 0,071995 ton CO₂-eq melalui SMILE; pengurangan limbah B3 hingga 0,005 ton melalui SEALZERO; penghematan energi sebesar 7.072 kWh (≈ 25,46 GJ) melalui WATCH; efisiensi air sebesar ~9,44 m³ melalui GREEN DRIP; serta pemanfaatan scrap hingga 0,016 ton besi melalui STEELIGHT. Pembahasan menyoroti bagaimana integrasi program-program tersebut memperkuat model transformasi menuju “Terminal BBM Hijau”. Kesimpulan menegaskan bahwa perubahan sistem operasional sederhana dengan dasar lingkungan dapat menghasilkan dampak strategis bagi efisiensi dan keberlanjutan. Rekomendasi mencakup skala perluasan, pemantauan lanjutan, dan pengembangan metrik keberlanjutan.

Keywords: Kata kunci: BBM, inovasi lingkungan, efisiensi, emisi, terminal hijau, perusahaan energi.

Aziz, R., Yusoff, M., & Halim, N. (2022). Assessment of Condensate Water Quality for Hydroponic Application. Journal of Water Sustainability, 12(3), 85–94.

Demir, E., Bektaş, T., & Laporte, G. (2014). A Review of Recent Research on Green Road Freight Transportation.European Journal of Operational Research, 237(3), 775–793.

De Groote, O., & Verboven, F. (2020). Subsidies and the Diffusion of Solar Photovoltaic Panels in the European Union.Energy Economics, 91, 104872.

Fava, J., et al. (2019). Life Cycle Assessment: Theory and Practice. Springer.

Ghisellini, P., Cialani, C., & Ulgiati, S. (2016). A Review on Circular Economy: The Expected Transition to a Balanced Interplay of Environmental and Economic Systems. Journal of Cleaner Production, 114, 11–32.

Graedel, T. E., & Allenby, B. R. (2010). Industrial Ecology and Sustainable Engineering. Pearson.

Hines, P., & Rich, N. (1997). The Seven Value Stream Wastes and Their Relationship with Lean Manufacturing.International Journal of Operations & Production Management, 17(1), 1–12.

IEA. (2023). Digitalization and Energy Efficiency. International Energy Agency.

Kemp, R., & Pearson, P. (2007). Final Report MEI Project about Measuring Eco-innovation. Maastricht: European Commission.

Lee, Y., & Kim, S. (2021). Carbon Emission Analysis in Petroleum Supply Chains. Energy Policy, 156, 112393.

McKinnon, A. C. (2018). Decarbonizing Logistics. Kogan Page.

Porter, M. E., & van der Linde, C. (1995). Toward a New Conception of the Environment-Competitiveness Relationship.Journal of Economic Perspectives, 9(4), 97–118.

Sukarni, & Herlambang, B. (2020). Analisis Life Cycle Assessment Distribusi Bahan Bakar Minyak terhadap Emisi CO₂ di Indonesia. Jurnal Energi dan Lingkungan, 16(1), 25–33.

Zhao, L., Chen, J., & Liu, Q. (2022). Preventing Fuel Leakage in Petrochemical Facilities: Environmental and Economic Perspectives. Journal of Environmental Management, 317, 115287.