Toward an environmentally sustainable natural gas‐based ethylene production process through exergy‐aided pinch analysis

Abstract: This paper presents a case study on improving the energy integration of a gasbased ethylene process by focusing on major sources of thermal exergy losses.Exergy analysis is used to find the main sources of thermal exergetic inefficiency. Thermal solutions are then developed, leading to a comprehensive list of cold and hot process streams that could potentially reduce exergy losses from these sources. Pinch analysis is then carried out to screen these streams so only those, which can minimize the energy require… Show more

“…Energy integration could also lead to beneficial environmental savings by increasing energy efficiency, and thus reducing the external energy demand. Furthermore, detailed exergy analysis can help to improve the overall energy efficiency of the process [690] and there are good examples of this for other processes in the literature [691][692][693][694][695][696]. Furthermore, biomass fractionation, into relatively high concentration streams of cellulose, hemicellulose, and lignin, may provide an opportunity to reduce the costs.…”

The multi-scale challenges of biomass fast pyrolysis and bio-oil upgrading: Review of the state of art and future research directions

“…Energy integration could also lead to beneficial environmental savings by increasing energy efficiency, and thus reducing the external energy demand. Furthermore, detailed exergy analysis can help to improve the overall energy efficiency of the process [690] and there are good examples of this for other processes in the literature [691][692][693][694][695][696]. Furthermore, biomass fractionation, into relatively high concentration streams of cellulose, hemicellulose, and lignin, may provide an opportunity to reduce the costs.…”

The multi-scale challenges of biomass fast pyrolysis and bio-oil upgrading: Review of the state of art and future research directions

Environmental sustainability assessment of an ethylene oxide production process through Cumulative Exergy Demand and ReCiPe

Membrane engineering for a sustainable production of ethylene