Flare gas reduction: A case study of integrating regeneration gas in flash gas compression network

Flare gas reduction: A case study of integrating regeneration gas in flash gas compression network

•Regeneration gas from mercaptan removal unit is recycled via flash gas compression.•A new compression setup handled the new combined gas stream.•Process simulation and field operational tests were successful.•No safety or operability concern exists for the new configuration.•A 75% reduction of flar...

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Veröffentlicht in:Fuel (Guildford) 2022-06, Vol.318, p.123661, Article 123661
Hauptverfasser: Sarkari, Majid, Jamshidi, Behnaz, Ahmadi Khoshooei, Milad, Fazlollahi, Farhad
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Sprache:eng
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Carbon dioxide
Compression
Configurations
Flare gas
Flash gas compressors
Flow rates
Flow velocity
Gas compressors
Greenhouse gas emission
Low pressure
Mercaptan removal unit (MRU)
Regeneration
Regeneration gas
Streams
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container_start_page 123661
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creator Sarkari, Majid
Jamshidi, Behnaz
Ahmadi Khoshooei, Milad
Fazlollahi, Farhad
description •Regeneration gas from mercaptan removal unit is recycled via flash gas compression.•A new compression setup handled the new combined gas stream.•Process simulation and field operational tests were successful.•No safety or operability concern exists for the new configuration.•A 75% reduction of flare gas was achieved. The total flow rate of the outlet regeneration gas of two mercaptan removal units in South Pars Gas Complex, Phase 1, is 20,000 Nm3/hr (10,000 Nm3/hr from each unit). The outlet stream splits into two streams. The first stream, with a flow rate of 7,000 Nm3/hr, flows into the boiler as fuel. The second stream, with the flowrate of 13,000 Nm3/hr, is sent to flare. In this paper, multiple experiments, including operational tests and dynamic simulation, were performed to prevent the flaring of regeneration gas as the main flaring source and feed loss in the plant. This goal was obtained by recycling the regeneration gas and switching it from the flaring system to the production line via flash gas compressors. To accomplish this, a series of Low Pressure-Medium Pressure (LP-MP) flash gas compressors were connected to MP flash gas. The new LP-MP-MP configuration was able to handle all the regeneration gas of one gas train. This configuration reduced the flow rate of the flaring gas from 13,000 Nm3/hr to 3,000 Nm3/hr and one of the flare stacks could be turned off. In addition, CO2 and CH4 emission decreased by ∼ 75%.
doi_str_mv 10.1016/j.fuel.2022.123661
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subjects Carbon dioxide
Compression
Configurations
Flare gas
Flash gas compressors
Flow rates
Flow velocity
Gas compressors
Greenhouse gas emission
Low pressure
Mercaptan removal unit (MRU)
Regeneration
Regeneration gas
Streams
title Flare gas reduction: A case study of integrating regeneration gas in flash gas compression network
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