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ISOALKY Technology: Next-Generation Alkylate Gasoline Manufacturing Process Technology Using Ionic Liquid Catalyst

  • Hye Kyung TimkenEmail author
  • Huping Luo
  • Bong-Kyu Chang
  • Elizabeth Carter
  • Matthew Cole
Chapter
  • 141 Downloads
Part of the Green Chemistry and Sustainable Technology book series (GCST)

Abstract

Chevron and Honeywell UOP have developed a next-generation alkylate gasoline manufacturing process, ISOALKY Technology, which has performance benefits (yield, product octane number, safety, and environmental) over the conventional acid-based processes, while the economical costs for capital plant construction and operation are comparable to the conventional processes. The ISOALKY Catalyst is a non-volatile ionic liquid that operates efficiently via on-line regeneration. ISOALKY Technology is for greenfield plants as well as for retrofit and expansion of existing alkylation plants. Chevron has entered into an alliance agreement with Honeywell UOP, proven experts in alkylation technology, to license this technology to the industry. UOP is the exclusive licensor of the ISOALKY Technology. Chevron made the final investment decision to retrofit and convert its approximately 5,000 barrel per day (BPD), that is, 190 kton/year, alkylate production plant in its refinery from a hydrofluoric acid technology to the ISOALKY Technology. Construction for the conversion project began in 2018, with the ISOALKY Plant due for startup in 2020. Chevron will own the first ISOALKY Plant in the world.

Keywords

Alkylation Commercialization Ionic liquid catalyst ISOALKY Technology Refinery 

Notes

Acknowledgements

We thank many of our colleagues who contributed to the development of ISOALKY Technology ranging from researchers for strategic research and sub-process development, operators and constructors of various units, chemists for fundamental data collection, and process engineers for design and operation of various scale-up plants. We thank the Chevron Salt Lake City refinery for hosting the demo plant, providing operational resources, and leading the commercial plant implementation. Finally, we thank the Chevron and Honeywell UOP management for strong support and commitment throughout the development and commercialization process.

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Copyright information

© Springer Nature Switzerland AG 2020

Authors and Affiliations

  • Hye Kyung Timken
    • 1
    Email author
  • Huping Luo
    • 1
  • Bong-Kyu Chang
    • 1
  • Elizabeth Carter
    • 2
  • Matthew Cole
    • 2
  1. 1.Chevron Energy Technology CompanyRichmondUSA
  2. 2.Honeywell UOPDes PlainesUSA

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