Sustainability Assessments of Hydrogen Peroxide-Based and Tertiary Butyl Hydroperoxide-Based Propylene Oxide Technologies

Bala Subramaniam

doi:10.1017/9781139026260.007

6 - Sustainability Assessments of Hydrogen Peroxide-Based and Tertiary Butyl Hydroperoxide-Based Propylene Oxide Technologies

Published online by Cambridge University Press: 15 September 2022

Bala Subramaniam

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Bala Subramaniam: Affiliation:
University of Kansas

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Summary

Propylene oxide (PO), a commodity chemical used for making antifreeze and plastics, has long been manufactured using technologies that make co-products that influence process economics and environmental footprint. In contrast, the hydrogen peroxide propylene oxide (HPPO) process (commercialized by Dow-BASF) uses titanium silicate as a catalyst and hydrogen peroxide (H2O2) as an oxidant to selectively produce PO without a co-product. Another alternate process (CEBC-PO) uses a homogeneous methyltrioxorhenium (MTO) catalyst and H2O2 to exclusively produce PO. This chapter compares the economics and environmental footprint of three technologies for making PO: HPPO, CEBC-PO and LyondelBasell that makes tertiary butyl alcohol (TBA) as a co-product. While the HPPO and CEBC-PO processes are profitable, the profitability of the LyondellBasell process depends on the demand and value for TBA. Cradle-to-gate LCA reveals that the environmental impacts of all three processes are similar, with most of the adverse impacts caused by using fossil-based sources (natural gas and transportation fuel) for producing the raw materials (isobutane, propylene and hydrogen peroxide).

Keywords

propylene oxide hydrogen peroxide heterogeneous catalyst homogeneous catalyst cradle-to-gate LCA

Type: Chapter
Information: Green Catalysis and Reaction Engineering
An Integrated Approach with Industrial Case Studies
, pp. 123 - 147

DOI: https://doi.org/10.1017/9781139026260.007 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2022

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References

Baer, H., Bergamo, M., Forlin, A., Pottenger, L. H. and Lindner, J., Propylene oxide. In Ullmann’s Encyclopedia of Industrial Chemistry (Weinheim: Wiley-VCH, 2012), pp. 313–35.Google Scholar

Weissermel, K., and Arpe, H.-J., Industrial Organic Chemistry. 4th ed. (Weinheim: Wiley-VCH, 2003).Google Scholar

Codignola, F., Method of hydrogenating alpha-methyl styrene to cumene, U.S. patent 3,127,452. 1964-03-31.Google Scholar

Zakoshansky, V. M. and Vassilieva, I. I., Wasteless economic method of production of phenol and acetone, U.S. patent 6,252,124 B1. 2001-06-26.Google Scholar

Hahn, H.-D., Dämbkes, G., Rupprich, N. and Bahl, H., Butanols. In Ullmann’s Encyclopedia of Industrial Chemistry (Weinheim: Wiley-VCH, 2012), pp. 417–28.Google Scholar

Nelson, E. C., Storm, D. A. and Patel, M. S., Preparation of MTBE from TBA and methanol, U.S. patent 4,918,244. 1990-04-17.Google Scholar

Lidderdale, T., Motor Gasoline Outlook and State MTBE Bans. Available at: www.eia.gov/outlooks/steo/special/pdf/mtbeban.pdf, last accessed May 29, 2020.Google Scholar

Winterberg, M., Schulte-Körne, E., Peters, U. and Nierlich, F., Methyl tert-butyl ether. In Ullmann’s Encyclopedia of Industrial Chemistry (Weinheim: Wiley-VCH, 2010), pp. 119–30.Google Scholar

Fischer, M., Butz, T. and Massonne, K., Preparation of Hydrogen Peroxide from Hydrogen and Oxygen, U.S. patent 6,872,377 B2. 2005-03-29.Google Scholar

Fischer, M., Kaibel, G., Stammer, A., Flick, K., Quaiser, S., Harder, W. and Massonne, K., Process for the Manufacture of Hydrogen Peroxide, U.S. patent 6,375,920 B2. 2002-04-23.Google Scholar

Goor, G., Glenneberg, J., Jacobi, S., Dadhabhoy, J. and Candido, E., Hydrogen peroxide. In Ullmann’s Encyclopedia of Industrial Chemistry (Weinheim: Wiley-VCH, 2019), pp. 1–40.Google Scholar

H1-Based Propylene Oxide (White Plains, New York: Nexant, Inc., 2008).Google Scholar

Lee, H.-J., Shi, T.-P., Busch, D. H. and Subramaniam, B., A greener, pressure intensified propylene epoxidation process with facile product separation. Chem. Eng. Sci., 62 (2007) 7282–89.Google Scholar

Busch, D. H., Subramaniam, B., Lee, H. -J. and Shi, T. -P., Process for Selective Oxidation of Olefins to Epoxides, U.S. patent 7,649,101 B2. 2010-01-19.Google Scholar

Lee, H.-J., Ghanta, M., Busch, D. H. and Subramaniam, B., Towards a CO₂-free ethylene oxide process: Homogeneous ethylene oxide in gas-expanded liquids. Chem. Eng. Sci., 65 (2010), 128–34.Google Scholar

Subramaniam, B., Busch, D. H., Lee, H.-J., Ghanta, M. and Shi, T.-P., Process for Selective Oxidation of Olefins to Epoxides, U.S. patent 8,080,677 B2. 2011-12-20.Google Scholar

Ghanta, M., Lee, H.-J., Busch, D. H. and Subramaniam, B., Highly selective homogeneous ethylene epoxidation in gas (ethylene)-expanded liquid: Transport and kinetic studies. AIChE J., 59 (2012), 180–87.Google Scholar

Ghanta, M., Development of an economically viable H₂O₂-based, liquid-phase ethylene oxide technology: Reactor engineering and catalyst development studies. PhD Dissertation, University of Kansas (2012).Google Scholar

Zhou, B., Rueter, M. and Parasher, S., Supported Catalysts Having a Controlled Coordination Structure and Methods for Preparing Such Catalysts, U.S. patent 7,011,807 B2. 2006-03-14.Google Scholar

Aspen HYSYS^®, Version 7.1 (Calgary, Alberta, Canada: Aspen Technologies, 2009).Google Scholar

Chilton, C. H., Popper, H. and Norden, R. B.. Modern Cost Engineering: Methods and Data (New York: McGraw-Hill, 1979).Google Scholar

Couper, J. R., Penney, W. R., Fair, J. R. and Walas, S. M., Chemical Process Equipment: Selection and Design, 2nd ed. (Oxford: Gulf Professional Publishing, 2005).Google Scholar

Matley, J., ed., Modern Cost Engineering: Methods and Data, Vol. II (New York: McGraw-Hill, 1984).Google Scholar

Peters, M. S. and Timmerhaus, K. D., Plant Design and Economics for Chemical Engineers, 4th ed. (New York: McGraw-Hill, 1991).Google Scholar

Ghanta, M., Modeling of the phase behavior of light (C₂ and C₃) olefins in liquid phase epoxidation systems and experimental determination of gas/liquid mass transfer coefficient. M.S. Thesis, University of Kansas (2012).Google Scholar

Ogaki, K., Takata, H., Washida, T. and Katayama, T., Phase equilibria for four binary systems containing propylene. Fluid Phase Equilibr., 43 (1988), 105–13.Google Scholar

Azarnoosh, A. and Mcketta, J. J., Solubility of propylene in water. J. Chem. Eng. Data., 4 (1959), 211–12.Google Scholar

Chen, X. and Wang, C., Vapor–liquid equilibria for propylene–methanol–water system. Trans. Tianjin Univ., 5 (1999), 101–4.Google Scholar

Vostrikova, V. N., Komarova, T. V., Platonov, V. M., Morozova, L. V., Moiseeva, T. P., Saenko, M. N. and Aerov, M. E., Liquid–vapor equilibrium in binary systems containing propylene oxide. Zhur. Prikl. Khim., 47 (1974), 568.Google Scholar

Yorizane, M., Sadamoto, S. and Yoshimura, S., Low temperature vapor–liquid equilibriums. Nitrogen-propylene and carbon dioxide-methane systems. Kag. Kog., 32 (1968), 257–64.Google Scholar

Jubin, J. C., Jr., Oxidation of Isobutane to Tertiary Butyl Hydroperoxide, U.S. Patent 5,149,885. 1992-09-22.Google Scholar

Preston, K. L., Wu, C.-N. T., Taylor, M. E. and Mueller, M. A., Staged Epoxidation of Propylene with Recycle, U.S. patent 5,349,072. 1994-09-20.Google Scholar

Wu, C-N. T., Taylor, M. E. and Mueller, M. A., Controlled Epoxidation of Propylene, U.S. patent 5,410,077. 1995-04-25.Google Scholar

Ghanta, M., Fahey, D. R., Busch, D. H. and Subramaniam, B., Comparative economic and environmental assessments of H₂O₂-based and tertiary butyl hydroperoxide-based propylene oxide technologies. ACS Sustain. Chem. Eng., 1 (2013), 268–77.Google Scholar

Thomas, K. A. and Preston, K. L., Reaction of Isobutane with Oxygen. U.S. patent 5,436,375. 1995-07-25.Google Scholar

Zabetakis, M. G., Flammability Characteristics of Combustible Gases and Vapors (Washington, D.C.: U.S. Department of Interior, US Bureau of Mines, 1965).Google Scholar

Stein, T. W., Gilman, H. and Bobeck, R. L., Epoxidation Process, U.S. patent 3,849,451. 1974-11-19.Google Scholar

Vora, B. V. and Pujado, P. R., Process For Producing Propylene Oxide. U.S. patent 5,599,955. 1997-02-04.Google Scholar

Issacs, B. H., Preparation of Soluble Molybdenum Catalysts for Epoxidation of Olefins, U.S. Patent 4,590,172. 1986-05-20.Google Scholar

Wang, Y.-W., Duh, Y.-S. and Shu, C.-M., Characterization of the self-reactive decomposition of tert-Butyl hydroperoxide in three different diluents. Proc. Saf. Prog., 26 (2007), 299–303.CrossRef Google Scholar

Arai, M., Kobayahi, M. and Tamura, M., Explosion of methanol distillation column of detergent manufacturing plant, Failure Knowledge Database, 1991. Available at: www.shippai.org/fkd/en/hfen/HC1200063.pdf, last accessed June 1, 2020.Google Scholar

Botia, D. C., Riveros, D. C., Ortiz, P., Gil, I. D. and Sanchez, O. F., Vapor–liquid equilibrium in extractive distillation of the acetone/methanol system using water as entrainer and pressure reduction. Ind. Eng. Chem. Res., 49 (2010), 6176–83.Google Scholar

Pujado, P. R. and Hammerman, J. I., Integrated Process For the Production of Propylene Oxide, U.S. patent 5,599,956. 1997-02-04.Google Scholar

Thiele, G. F. and Roland, E., Propylene epoxidation with hydrogen peroxide and titanium silicalite catalyst: Activity, deactivation and regeneration of the catalyst. J. Mol. Cat. A-Chem., 117 (1997), 351–56.CrossRef Google Scholar

Bröcker, F. J., Haake, M., Kaibel, G., Rohrbacher, G., Schwab, E. and Stroezel, M., Isothermal Operations of Heterogeneously Catalyzed Three Phase Reactions. U.S. patent 7,576,246. 2009-08-18.Google Scholar

Teles, J. H., Rehfinger, A., Müller, U., Wenzel, A., Rudolf, P., Harder, W., Rieber, N. and Bassler, P., Method for Producing an Epoxide, U.S. patent application 2003/0187284 A1. 2003-10-02.Google Scholar

Lozowski, D., Business news. Chem. Eng., 117 (2010), 71–72.Google Scholar

U. S. Energy Information Administration. Electricity. 2011. Available at: www.eia.gov/energyexplained/index.cfm?page=electricity_in_the_united_states, last accessed June 1, 2020.Google Scholar

U. S. Energy Information Administration. Natural Gas. 2011. Available at: www.eia.gov/energyexplained/natural-gas/, last accessed June 1, 2020.Google Scholar

U.S. Bureau of Labor Statistics. 2010. Available at: www.bls.gov/cpi/, last accessed June 1, 2020.Google Scholar

Engineering News Record. 2010. Available at: www.enr.com, last accessed June 1, 2020.Google Scholar

ICIS. 2010. Available at: www.icis.com/explore/commodities/chemicals/, last accessed June 2, 2020.Google Scholar

Baitz, M., Makishi-Colodel, C., Kupfer, T., Pflieger, J., Schuller, O., Hassel, F., Kokborg, M. and Fong, L., GaBi Database and Modelling Principles, Version 5.0, PE International, Germany. Available at: www.gabi-software.com/fileadmin/gabi/documentation5/GaBi_5_Modelling_Principles.pdf, last accessed Jan 19, 2020.Google Scholar

Bare, J. C., Developing a Consistent Decision-making Framework by Using the U.S. EPA’s TRACI (Cincinnati, OH: US Environmental Protection Agency, 2002). Available at: https://clu-in.org/conf/tio/lcia/AICHE2002paper.pdf, last accessed June 2, 2020.Google Scholar

Bare, J. C., Hofstetter, P., Pennington, D. W. and Udo de Haes, H. A., Life cycle impact assessment workshop summary: Midpoints versus endpoints: the sacrifices and benefits. Int. J. Life Cycle Assess., 5 (2000), 319–26.Google Scholar

Bare, J. C., Norris, G. A., Pennington, D. W. and McKone, T., TRACI: The tool for the reduction and assessment of chemical and other environmental impacts. J. Ind. Ecol., 6 (2002), 49–78.CrossRef Google Scholar

Schmidt, R., Griesbaum, K., Behr, A., Biedenkapp, D., Voges, H.-W., Garbe, D., Paetz, C., Collin, G., Mayer, D. and Höke, H., Hydrocarbons. In Ullmann’s Encyclopedia of Industrial Chemistry (Weinheim: Wiley-VCH, 2014), pp. 1–74.Google Scholar

Zimmermann, H., Propene. In Ullmann’s Encyclopedia of Industrial Chemistry (Weinheim: Wiley-VCH, 2013), pp. 1–18.Google Scholar

Welch, V. A., Fallon, K. J. and Gelbke, H.-P., Ethylbenzene. In Ullmann’s Encyclopedia of Industrial Chemistry (Weinheim: Wiley-VCH, 2005), pp. 451–64.Google Scholar

Austin, G. T., Shreve’s Chemical Process Industries, 5th ed. (New York: McGraw Hill, 1985), p. 833.Google Scholar

Windmeier, C. and Barron, R. F., Cryogenic technology. In Ullmann’s Encyclopedia of Industrial Chemistry (Weinheim: Wiley-VCH, 2013), pp. 2–71.Google Scholar

Ott, J., Gronemann, V., Pontzen, F., Fiedler, E., Grossman, G., Kersebohm, D. B., Weiss, G. and Witte, C., Methanol. In Ullmann’s Encyclopedia of Industrial Chemistry (Weinheim: Wiley-VCH, 2012), pp. 1–27.Google Scholar

Scriven, E. F. V. and Murugan, R., Pyridine and pyridine derivatives. In Ullmann’s Encyclopedia of Industrial Chemistry (Weinheim: Wiley-VCH, 2005), pp. 1–53.Google Scholar

BASF Catalysts-Metal Prices. 2010. Available at: https://apps.catalysts.basf.com/apps/eibprices/mp/, last accessed June 8, 2020.Google Scholar

Toxic Release Inventory-LyondellBasell Chemical Company Bayport Facility 2012. Available at: https://enviro.epa.gov/triexplorer/tri_release.chemical, last accessed June 3, 2020.Google Scholar

Ouyang, X., Zornes, S. I. and Katz, A. S., Highly Active, Selective, Accessible and Robust Zeolitic Ti: Epoxidation Catalyst. U.S. Patent 20160067694A1. 2016-04-10.Google Scholar

Maiti, S. K., Ramanathan, A. and Subramaniam, B., 110th Anniversary: Near-total epoxidation selectivity and hydrogen peroxide utilization with Nb-EISA catalysts for propylene epoxidation. Ind. Eng. Chem. Res., 58 (2019), 17727–35.Google Scholar

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6 - Sustainability Assessments of Hydrogen Peroxide-Based and Tertiary Butyl Hydroperoxide-Based Propylene Oxide Technologies

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