TY - JOUR
T1 - Process intensification education contributes to sustainable development goals. Part 1
AU - Fernandez Rivas, David
AU - Boffito, Daria C.
AU - Faria-Albanese, Jimmy
AU - Glassey, Jarka
AU - Afraz, Nona
AU - Akse, Henk
AU - Boodhoo, Kamelia V.K.
AU - Bos, Rene
AU - Cantin, Judith
AU - (Emily) Chiang, Yi Wai
AU - Commenge, Jean Marc
AU - Dubois, Jean Luc
AU - Galli, Federico
AU - de Mussy, Jean Paul Gueneau
AU - Harmsen, Jan
AU - Kalra, Siddharth
AU - Keil, Frerich J.
AU - Morales-Menendez, Ruben
AU - Navarro-Brull, Francisco J.
AU - Noël, Timothy
AU - Ogden, Kim
AU - Patience, Gregory S.
AU - Reay, David
AU - Santos, Rafael M.
AU - Smith-Schoettker, Ashley
AU - Stankiewicz, Andrzej I.
AU - van den Berg, Henk
AU - van Gerven, Tom
AU - van Gestel, Jeroen
AU - van der Stelt, Michiel
AU - van de Ven, Mark
AU - Weber, R. S.
N1 - Publisher Copyright:
© 2020 Institution of Chemical Engineers
PY - 2020/7
Y1 - 2020/7
N2 - In 2015 all the United Nations (UN) member states adopted 17 sustainable development goals (UN-SDG) as part of the 2030 Agenda, which is a 15-year plan to meet ambitious targets to eradicate poverty, protect the environment, and improve the quality of life around the world. Although the global community has progressed, the pace of implementation must accelerate to reach the UN-SDG time-line. For this to happen, professionals, institutions, companies, governments and the general public must become cognizant of the challenges that our world faces and the potential technological solutions at hand, including those provided by chemical engineering. Process intensification (PI) is a recent engineering approach with demonstrated potential to significantly improve process efficiency and safety while reducing cost. It offers opportunities for attaining the UN-SDG goals in a cost-effective and timely manner. However, the pedagogical tools to educate undergraduate, graduate students, and professionals active in the field of PI lack clarity and focus. This paper sets out the state-of-the-art, main discussion points and guidelines for enhanced PI teaching, deliberated by experts in PI with either an academic or industrial background, as well as representatives from government and specialists in pedagogy gathered at the Lorentz Center (Leiden, The Netherlands) in June 2019 with the aim of uniting the efforts on education in PI and produce guidelines. In this Part 1, we discuss the societal and industrial needs for an educational strategy in the framework of PI. The terminology and background information on PI, related to educational implementation in industry and academia, are provided as a preamble to Part 2, which presents practical examples that will help educating on Process Intensification.
AB - In 2015 all the United Nations (UN) member states adopted 17 sustainable development goals (UN-SDG) as part of the 2030 Agenda, which is a 15-year plan to meet ambitious targets to eradicate poverty, protect the environment, and improve the quality of life around the world. Although the global community has progressed, the pace of implementation must accelerate to reach the UN-SDG time-line. For this to happen, professionals, institutions, companies, governments and the general public must become cognizant of the challenges that our world faces and the potential technological solutions at hand, including those provided by chemical engineering. Process intensification (PI) is a recent engineering approach with demonstrated potential to significantly improve process efficiency and safety while reducing cost. It offers opportunities for attaining the UN-SDG goals in a cost-effective and timely manner. However, the pedagogical tools to educate undergraduate, graduate students, and professionals active in the field of PI lack clarity and focus. This paper sets out the state-of-the-art, main discussion points and guidelines for enhanced PI teaching, deliberated by experts in PI with either an academic or industrial background, as well as representatives from government and specialists in pedagogy gathered at the Lorentz Center (Leiden, The Netherlands) in June 2019 with the aim of uniting the efforts on education in PI and produce guidelines. In this Part 1, we discuss the societal and industrial needs for an educational strategy in the framework of PI. The terminology and background information on PI, related to educational implementation in industry and academia, are provided as a preamble to Part 2, which presents practical examples that will help educating on Process Intensification.
KW - Chemical engineering
KW - Education challenge
KW - Entrepreneurship
KW - Industry challenge
KW - Pedagogy
KW - Process design
KW - Process intensification
KW - Sustainability
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U2 - 10.1016/j.ece.2020.04.003
DO - 10.1016/j.ece.2020.04.003
M3 - Review article
AN - SCOPUS:85086144368
SN - 1749-7728
VL - 32
SP - 1
EP - 14
JO - Education for Chemical Engineers
JF - Education for Chemical Engineers
ER -