Closed loop self-cooling recuperative N2-expander cycle for energy

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Closed loop self-cooling recuperative N2-expander cycle for energy efficient and ecological natural gas liquefaction process Muhammad Abdul Qyyum, Kinza Qadeer, and Moonyong Lee ACS Sustainable Chem. Eng., Just Accepted Manuscript • DOI: 10.1021/ acssuschemeng.7b04679 • Publication Date (Web): 28 Feb 2018 Downloaded from http://pubs.acs.org on March 2, 2018

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ACS Sustainable Chemistry & Engineering

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Closed loop self-cooling recuperative N2-expander cycle for energy efficient

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and ecological natural gas liquefaction process

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Muhammad Abdul Qyyuma, Kinza Qadeera, and Moonyong Leea, * a

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School of Chemical Engineering, Yeungnam University, Gyeongsan 712-749, Rep. of Korea

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Authors mailing address:

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1st author: Muhammad Abdul Qyyum

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Email ID: [email protected]

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Process System Design and Control Laboratory # 401, School of Chemical Engineering, Yeungnam

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University, 280, Daehakro, Gyeongsan, GyeongBuk, Republic of Korea.

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2nd author: Kinza Qadeer

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Email ID: [email protected]

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Process System Design and Control Laboratory # 401, School of Chemical Engineering, Yeungnam

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University, 280, Daehakro, Gyeongsan, GyeongBuk, Republic of Korea.

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Corresponding author: Moonyong Lee

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Email ID: [email protected]

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Process System Design and Control Laboratory # 401, School of Chemical Engineering, Yeungnam

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University, 280, Daehakro, Gyeongsan, GyeongBuk, Republic of Korea.

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*

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Prof. Moonyong Lee

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Email: [email protected]

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Telephone: +82-53-810-2512

Correspondence concerning this article should be addressed to:

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Abstract

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Liquefied natural gas (LNG) has attracted global attention as a more environmentally friendly energy

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source when compared to other fossil fuels. The nitrogen (N2) expander liquefaction is the most green

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and safe process among the different types of commercial natural gas liquefaction processes, but its

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relatively low energy efficiency is a major issue. In this study, an innovative closed loop self-cooling

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recuperation technology was proposed to reduce the exergy losses of the N2 expander LNG process.

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The LNG process with the implementation of the proposed technology was modeled using a

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commercial process simulation tool, ASPEN HYSYS® v9. Subsequently, a modified coordinate

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descent optimization algorithm was employed to achieve maximum potential benefits of the proposed

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technology. The energy efficiency of the proposed LNG process was further improved by energy

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recovery from end flash gas and high-pressure natural gas feed. Finally, the energy efficiency of the

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proposed closed loop self-cooling recuperative N2 expander LNG process was significantly improved

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up to 80.5% compared to the existing N2 expander based LNG processes, depending on the feed

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natural gas conditions, composition, and design parameters.

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Keywords: Natural gas liquefaction; LNG; Closed loop self-cooling recuperation; N2-expander

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liquefaction process; Ecological liquefaction process; End flash gas.

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ACS Sustainable Chemistry & Engineering

Introduction

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Compared to other fuels, liquefied natural gas (LNG) mainly has low carbon dioxide emissions

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and can meet the ever increasing stringent environmental safety rules and regulations. The location of

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the natural gas reserves is of key importance in the economics of natural gas storage and

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transportation. The main methods for storing and transporting natural gas is compression, liquefaction,

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and physical adsorption. Liquefaction of natural gas, resulting in a material with 1/600th the original

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volume, has been considered to be the most cost effective transportation strategy, especially when

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compared to gaseous natural gas transportation. However, liquefaction is an energy intensive process,

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and the liquefaction of 1 kg of natural gas consumes 1,188 kJ of energy 1, which is equivalent to 30–

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35% of the total energy required for LNG production.2, 3 Although, the energy requirement for LNG

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production strongly depends on the plant site conditions4, 5 and involved liquefaction process such as

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SMR, DMR, C3MR, and cascaded.6

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LNG processes can be categorized by their use of two major technologies, mixed refrigerant

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based processes, and N2 expander based processes. To optimize these processes for large scale LNG

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production, a combination of different refrigeration cycles has been developed such as, single mixed

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refrigerant (SMR), cascade, propane precooled mixed refrigerant (C3MR), and dual mixed refrigerant

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(DMR) processes. Among these, the SMR and N2 expander processes offer more simplicity with the

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lowest amount of capital investment, making them the most feasible for offshore LNG production.3, 7-

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SMR process has inherent safety and environmental concerns. The presence of highly flammable

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hydrocarbon based refrigerants makes SMR less attractive due to its environmental hazards and safety

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concerns.

The SMR process is highly energy efficient when compared to N2 expander processes, however, the

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Table 1 summarizes the safety and environmental data for different refrigerants. The safety data

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shows that N2 as a refrigerant has zero occupational exposure limit (OEL), and a zero lower

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flammability limit (LFL). Furthermore, the American Society of Heating, Refrigerating, and Air-

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Conditioning Engineers (ASHRAE) has standardized 34 safety groups (2010a and 2010b), and

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categorized N2 refrigerant in the A1 category (i.e. no flame propagation), whereas, all other

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refrigerants are categorized as A3 (i.e. highly flammable). The environmental data shows zero global

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warming potential (GWP) for N2 refrigeration when compared to the ingredients of the mixed

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refrigerant. Table 1. Safety and environmental data for refrigerants.12

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Safety data Refrigerant

Environmental data

OEL

LFL

Std 34 safety

(PPMv)

(%)

group

Methane (CH4)

1000

4.8

A3

0.0

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Ethane (C2H6)

1000

3.1

A3

0.0

~20

Ethylene (C2H4)

200

3.1

A3

0.0