The Impact of Electri?ed Process Heating on Process Design, Control and Operations-Reference-Cited by-同舟云学术

The Impact of Electri?ed Process Heating on Process Design, Control and Operations

Published:2024-07-09 Issue: Volume:3 Page:570-577
ISSN:2818-4734
Container-title:Systems and Control Transactions
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Author:

Rho Jong Hyun¹,Baldea Michael¹²,Endler Elizabeth E.³,Herediac Monica A.¹,Bojovic Vesna³,Pajand Pejman³

Affiliation:

1. The University of Texas at Austin, McKetta Department of Chemical Engineering, Austin, TX, USA

2. The University of Texas at Austin, Oden Institute for Computational Engineering and Sciences, Austin, TX, USA

3. Shell International Exploration and Production, Houston, TX, USA

Abstract

We study the impact of switching from combustion heating to electric heating in processes comprising high temperature reaction/separation sequences, where the heat supporting the reaction(s) is substantially provided by combusting a reaction byproduct (fuel gas). A canonical process structure is de?ned. It is shown that the conventional combustion- based process presents signi?cant interactions. An asymptotic analysis is utilized to investigate and compare the dynamic responses of the conventional and electric process configurations. It is demonstrated that the dynamic behavior of the two processes exhibits two timescales, with the faster corresponding to the evolution of the temperatures of the units with high heat duty, and the slow time scale capturing the variables involved in the material balance. A simpli?ed ethylene cracking process example is used to demonstrate these findings.

Publisher

PSE Press

Reference12 articles.

1. McMillan C, Schoeneberger C, Zhang J, Kurup P, Masanet E, Margolis R, Meyers S, Bannister M, Rosenlieb E, and Xi W. Opportunities for solar industrial process heat in the United States. Technical Report NREL/TP-6A20- 77760, National Renewable Energy Laboratory, Golden, CO, (2021)

2. Schoeneberger C, McMillan CA, Kurup P, Akar S, Margolis R, and Masanet E. Solar for industrial process heat: A review of technologies, analysis approaches, and potential applications in the United States. Energy, 206:118083, (2020)

3. Schiffer ZJ and Manthiram K. Electrification and decarbonization of the chemical industry. Joule, 1(1):10-14, (2017)

4. Electric Power Research Institute (EPRI). Program on technology innovation: Industrial electrotechnology development opportunities. Technical Report 1019416, EPRI, Palo Alto, CA, (2009)

5. Layritz LS, Dolganova I, Finkbeiner M, Luderer G, Penteado AT, Ueckerdt F, and Repke JU. The potential of direct steam cracker electrification and carbon capture & utilization via oxidative coupling of methane as decarbonization strategies for ethylene production. Applied Energy, 296:117049, (2021)