Overview
ABSTRACT
The development of biobased epoxy resins and the replacement of the diglycidyl ether of Bisphenol A, the most widely used epoxy monomer, are challenges for the industry to comply with regulatory requirements and societal expectations. However, this substitution is accompanied by changes in the reactivity of the formulation and the final properties of the materials. This article proposes to detail the stakes of this substitution, as well as a detailed review of the research work carried out by academic laboratories, as well as of the commercial products in development to propose ways of access to less harmful and more respectful epoxy materials. of the environment.
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Sylvain CAILLOL: CNRS Research Director - Charles Gerhardt Institute, Montpellier, France
INTRODUCTION
The development of epoxy resins from renewable resources, and the substitution of some of their components deemed hazardous, are hot topics in scientific publications and industry alike. Indeed, most epoxy resins are made from the diglycidyl ether of bisphenol A (DGEBA), which is derived from the epoxidation of bisphenol A (BPA), an endocrine disruptor whose use is gradually being banned in most applications, in line with regulatory requirements. A number of BPA-free epoxy monomers are available, but not all of them can really be defined as substitutes for DGEBA. Indeed, it should be noted that DGEBA is based on a bisphenolic compound. The resulting physical and chemical properties are those of a rigid, aromatic ring-containing diepoxy monomer containing at least two reactive epoxy groups. Moreover, in most cases, the industry is looking for bio-based substitutes to further reduce environmental impact.
Focusing on aromatic biosourced substitutes, or at least rigid structures, this article proposes to detail the issues involved in this substitution, and to provide a detailed review of the research work carried out by academic laboratories, as well as of the commercial products under development to propose pathways to less harmful and more environmentally friendly epoxy materials.
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KEYWORDS
bisphenol A | BADGE | epoxy resins | epoxidation | biobased materials
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Functional materials - Bio-based materials
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Biobased epoxy resins
Bibliography
Patents
NOUAILHAS (H.), BURGUIÈRE (C.), CAILLOL (S.), BOUTEVIN (B.), FULCRAND (H.) and RAPIOR (S.). – Novel method for producing thermosetting epoxy resins. WO2010136725 (2010).
ROBINS (J.). – Epoxy resin curing agent, process and composition. US4503211A, 1985/03/05 (1985).
MORII (A.), NAKAMURA (H.) and SAITO (Y.). – Epoxy resin composition. EP0161576A2, 1985/11/21 (1985).
...Regulations
Commission Implementing Regulation (EU) No 321/2011 of 1 April 2011 Amending Regulation (EU) No 10/2011 as Regards the Restriction of Use of Bisphenol A in Plastic Infant Feeding Bottles.
Law no. 2010-729 of June 30, 2010 suspending the marketing of all packaging containing bisphenol A and intended for food products.
Inclusion of Substances of Very High Concern in the Candidate...
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