Exergy analysis of NGL recovery plant using a hybrid ACO<sub>R</sub>‐BP neural network modeling: a case study

Safarvand, Danial; Aliazdeh, Mostafa; Giri, Mohammad Samipour; Jafarnejad, Mahtab

doi:10.1002/apj.1857

Cited by 12 publications

(6 citation statements)

References 32 publications

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“…The exergy analysis method is a key issue for a better understanding the locations, causes, and magnitudes of process inefficiencies [7]. CEA is a useful technique to evaluate the performance of chemical processes [23].…”

Section: Conventional Exergy Analysismentioning

confidence: 99%

“…This shows a promising future for its natural gas and NGL recovery industries. In this regard, Iran's natural gas production has rapidly increased over the past two decades, from 0.9 Tcf in 1991 to 1127.7 Tcf in 2018 [6,7].…”

Section: Introductionmentioning

confidence: 99%

“…High energy consumption is the most important problem of NGL production technologies, especially in the refrigeration cycles [14]. Exergy analysis in such plants allows determining the most inefficient parts of a process where energy is wasted [7]. Raising the quality level of energy consumption is logical to improve the efficiency of these plants [13].…”

Section: Introductionmentioning

confidence: 99%

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Advanced exergy analysis of the natural gas liquid recovery process

et al. 2022

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Energy quality in each country is one of the important indicators of economic development, Which affects the economic growth of that country. Exergy analysis, considering all flow properties including pressure, temperature, composition, is a powerful way to evaluate the energy consumption of equipment such as natural gas and liquefied gas plants. Inefficiency of a system can be defined by the conventional exergy analysis method, While, irreversible resources and real potentials for system improvement can only be identified by the advanced exergy analysis method. This analysis splits conventional exergy destruction into two exogenous and endogenous parts according to origin, and also unavoidable and avoidable parts according to the ability to remove and modifications. In this method, the exergy concept was separated by considering the ideal and avoidable condition assumptions. As a real case study, a natural gas liquid plant 800, from National Iranian South Oil Company located in southwest of Iran was considered to be investigated by conventional exergy analysis, advanced exergy analysis methods. The results of conventional exergy analysis illustrated that the highest amount of exergy destruction belonged to compressor and heat exchanger with 509.99 and 629.04 kW, respectively. However, in the case of heat exchanger, despite having the highest rate of exergy destruction, it is not considered in modification priorities due to its low avoidable exergy destruction value. Also, advanced exergy analysis suggested that the exergy destruction of the compressor and heat exchanger will be reduced by improving performance of these components.

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Section: Conventional Exergy Analysismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Advanced exergy analysis of the natural gas liquid recovery process

et al. 2022

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“…The exergy destruction rate

((), {\overset{I}{true}}_{HE})

for the original heat exchangers or the LNG unit heat exchangers is calculated as the difference of the exergies of the incoming and the outgoing streams as presented in Equation

{\dot{I}}_{HE} = \sum {\dot{m}}_{in} e_{in} - \sum {\dot{m}}_{out} e_{out}

The exergetic efficiency of the heat exchangers is defined as the ratio of the increase in the cold streams exergy to the decrease in the hot streams exergy as illustrated in Equation .…”

Section: Exergy Analysismentioning

confidence: 99%

“…The exergy destruction and exergetic efficiency of the column equipped with condenser at top and reboiler at the bottom could be estimated by using Equations and , respectively

{\dot{I}}_{col} = \sum {\dot{m}}_{vap} e_{vap} + \sum {\dot{m}}_{liq} e_{liq} - \sum {\dot{m}}_{feed} e_{feed} - Q_{cond} + Q_{heat},

η_{col} = \frac{\sum {\dot{m}}_{vap} e_{vap} + \sum {\dot{m}}_{liq} e_{liq} - \sum {\dot{m}}_{feed} e_{feed} + Q_{cond}}{Q_{heat}},

where

{\dot{m}}_{vap}, {\dot{m}}_{liq}

, and

{\dot{m}}_{feed}

are the vapor, liquid, and feed flowrate of the column (kg/s), respectively; e vap , e liq , and e feed are the specific vapor, liquid, and feed flow exergy (kJ/kg), respectively; and Q heat and Q cond are the heat transfer rate added to the reboiler and removed from the condenser (kW), respectively.…”

Section: Exergy Analysismentioning

confidence: 99%

Liquefied petroleum gas recovery enhancement via retrofitting the refrigeration system of an existing natural gas liquid plant

Shehata

Bhran

Shoaib

et al. 2019

Asia-Pacific J Chem Eng

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Nowadays, gas processing for natural gas liquids (NGLs) recovery is becoming of great interest. However, many of the present NGLs recovery units in operation do not give the desired revenue. This study focuses on the retrofitting of an existing NGLs plant constructed in Egypt for maximizing LPG product recovery due to its high economic value. Various alternatives have been suggested to maximize LPG recovery, while achieving the same cooling target and ethane recovery in terms of power consumption and additional capital cost. The economic study shows that replacing the existing pure propane refrigerant used to recover C 5 + (pentane and heavier) in the existing plant by a mixed refrigerant type is the best retrofitting technique. Furthermore, the exergy of the whole NGL unit was studied to evaluate the exergetic performance of all suggested upgrading methods. Regarding the upgraded plant, the butanes and propane recoveries were increased by 13% and 7%, respectively, with 15.95% increase in LPG overall recovery. In addition, the solutions of operational problems that may appear in the glycol injection system, propane refrigeration facilities, and de-ethanizer unit facilities when switching from single refrigerant to mixed refrigerant have been taken into consideration.

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Analyses of exergy efficiency for forced convection heat transfer in a tube with CNT nanofluid under laminar flow conditions

et al. 2016

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Exergy analysis of NGL recovery plant using a hybrid ACO_R‐BP neural network modeling: a case study

Cited by 12 publications

References 32 publications

Advanced exergy analysis of the natural gas liquid recovery process

Advanced exergy analysis of the natural gas liquid recovery process

Liquefied petroleum gas recovery enhancement via retrofitting the refrigeration system of an existing natural gas liquid plant

Analyses of exergy efficiency for forced convection heat transfer in a tube with CNT nanofluid under laminar flow conditions

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Exergy analysis of NGL recovery plant using a hybrid ACOR‐BP neural network modeling: a case study

Cited by 12 publications

References 32 publications

Advanced exergy analysis of the natural gas liquid recovery process

Advanced exergy analysis of the natural gas liquid recovery process

Liquefied petroleum gas recovery enhancement via retrofitting the refrigeration system of an existing natural gas liquid plant

Analyses of exergy efficiency for forced convection heat transfer in a tube with CNT nanofluid under laminar flow conditions

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Exergy analysis of NGL recovery plant using a hybrid ACO_R‐BP neural network modeling: a case study