The LNG Receiving Hub facility is an existing facility that has not been used for a long time. In order for this facility can be used again, all equipment and piping systems must first be conditioned to a temperature close to the operational temperature of LNG, which is -160 ^oC. The purpose of this approach is to determine the theoretical and actual volume of LNG used for the cooling down process of the LNG Hub facility, as well as to compare it with the cooling down process for the regasification facility. An analytical approach is used in this study to determine the ideal amount of LNG needed for cooling down the facility and compare it with the actual amount of LNG that is being used for cooling down the facility. From the results of the analysis, the theoretical LNG volume needed for cooling down the LNG Hub facility is 8,176 m³ and the actual volume is 7,013.6620 m³, while the actual value for cooling down the regasification facility is 11,573.19 m³. The actual volume for the LNG Hub facility is smaller compared to regasification which can be caused by the smaller volume of pipelines and the difference in the cooling down mechanism in both facilities.

Dobrota Đ., B. Lalić, and I. Komar, 2013. Problem of boil-off in LNG supply chain. Transactions on maritime science, Vol. 2, No. 02, pp. 91-100.

Clews R., 2016. Project finance for the international petroleum industry. 2016: Academic Press.

Yang Z., H. Chen, and M. Shao, 2017. The behavior of liquefied natural gas in storage tanks. Petroleum Science and Technology, Vol. 35, No. 2, pp. 206-210.

Kalbarczyk-Jedynak A. and W. Ślączka, 2018. Dimensioning of danger zones emerging as a domino effect of an LNG explosion for industrial plants located in the vicinity of inland transport fairways. New Trends in Production Engineering, Vol. 1, No. 1, pp. 73-79.

Ezzarhouni, A., 2015. Behind the design – outline how a sump well design can be used to increase LNG tank asset monetisation. Gaztransport & Technigaz (GTT), Saint-Rémy-lès-Chevreuse.

Morise, T., Shirakawa, Y., Meguro, T., 2007. Applying optimum commissioning technology of LNG receiving terminal. Gas Technology Institute, Barcelona.

Yuanling, S., 2019. Nitrogen drying and purging dynamic simulation of 200,000 m3 LNG storage tank. IGT International Liquefied Natural Gas Conference Proceedings, Shanghai.

Piasecki, T., Bejger, A., Wieczorek, A., 2021. Experimental studies of cargo tank cooldown in an LNG carrier. European Research Studies Journal Volume XXIV, No. 3B, 886-895.

Bakhshi P. and A. Touran, 2014. An overview of budget contingency calculation methods in construction industry. Procedia Engineering, Vol. 85, pp. 52-60.

Anwar, H., 2016. Optimasi proses cooling down LNG liquid loading arms di loading dock #2 PT Badak NGL. Politeknik Negeri Samarinda, Samarinda.

Kulitsa M. and D.A. Wood, 2020. Boil-off gas balanced method of cool down for liquefied natural gas tanks at sea. Advances in Geo-Energy Research, Vol. 4, No. 2, pp. 199-206.