Utilising cold energy from liquefied natural gas (LNG) to reduce the electricity cost of data centres

Journal article

Authors/Editors

YANIN SUKJAI

Strategic Research Themes

Energy Efficiency (Sustainable Energy & Environment)

Publication Details

Author list: Sermsuk M., Sukjai Y., Wiboonrat M., Kiatkittipong K.

Publisher: MDPI

Publication year: 2021

Journal: Energies (1996-1073)

Volume number: 14

Issue number: 19

ISSN: 1996-1073

eISSN: 1996-1073

URL: https://www.scopus.com/inward/record.uri?eid=2-s2.0-85117857622&doi=10.3390%2fen14196269&partnerID=40&md5=888de27820ac4aad8ee0677c921ffc40

Languages: English-Great Britain (EN-GB)

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Abstract

The Office of the National Broadcasting and Telecommunications Commission has reported that, from 2014 to 2018, Thailand’s internet usage has grown six‐fold to 3.3 million terabytes per annum. This market trend highlights one of the policies of Thailand 4.0, with the aim of making Thailand a hub for information transfer in ASEAN. As a result, there will be a massive demand growth for data storage facilities in the near future. Data centres are regarded as the brain and heart of the digital industry and are essential for facilitating businesses in organising, processing, storing and disseminating large amounts of data. As the energy demand for equipment cooling contributes to over 37% of the total energy consumption, the data centres of the world’s leading companies, such as Amazon, Google, Microsoft and Facebook, are generally located in cold climate zones, such as Iceland, in order to reduce operating costs for cooling. Due to this reason, the possibility of data centres in Thailand is limited. Beneficially, PTTLNG, as the first liquified natural gas (LNG) terminal in Thailand, has processed the import, receiving, storage and regasification of LNG. The high abundance of cold energy inherently presented in LNG is normally lost to the surroundings during regasification. Presently, PTTLNG’s LNG receiving terminal utilises a heat exchanger with propane as an intermediate fluid to transfer cold energy from LNG to water. This cold energy, in the form of cold water, is then used in several projects within the LNG receiving terminal: (1) production of electricity via an organic Rankine cycle capacity of 5 MWh; (2) cooling the air inlet of gas turbine generators to increase the generator efficiency; (3) replacing refrigerant heating, ventilation and air conditioning systems within buildings; (4) development of winter plantations with precision agriculture to replace imported products. Therefore, this study focuses on the potential and future use for LNG cold energy by performing a thermodynamic and economic analysis of the use of LNG cold energy as a source to produce cold water at 7 °C, with the total cold energy of 27.77 to 34.15 MW or 7934 t to 9757 t of refrigeration depending on the target pressure of the natural gas to replace the conventional cooling system of data centres. This research has the potential to reduce the cooling operation costs of data centres by more than USD 9.87 million per annum as well as CO2 emissions by 34,772 t per annum. In an economic study, this research could lead to a payback period of 7 years with IRR 13% for the LNG receiving terminal and a payback period of 2.21 years with IRR 45% for digital companies. © 2021 by the authors. Licensee MDPI, Basel, Switzerland.

Keywords

Cold energy utilisation, Data centre, Free cooling, Intermediate fluid vaporiser