Phenol-formaldehyde resins with suitable bonding strength synthesized from “less-reactive” hardwood lignin fractions

The substitution of phenol by lignin in phenol-formaldehyde (PF) resins is one of the most promising end uses of lignin valorization. Lignin from grasses and softwood has been the focus of the studies in this field as they present a higher number of theoretical reactive sites for resin synthesis. He...

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Published inHolzforschung Vol. 74; no. 2; pp. 175 - 183
Main Authors Lourençon, Tainise V., Alakurtti, Sami, Virtanen, Tommi, Jääskeläinen, Anna-Stiina, Liitiä, Tiina, Hughes, Mark, Magalhães, Washington L.E., Muniz, Graciela I.B., Tamminen, Tarja
Format Journal Article
LanguageEnglish
Published Berlin De Gruyter 01.02.2020
Walter de Gruyter GmbH
Subjects
Aldehydes
Bonding strength
Chemical composition
Chemical reactions
Consumption
Formaldehyde
formaldehyde consumption
Hardwoods
kraft
Lignin
Phenol formaldehyde resins
phenolic resins
Phenols
Polymers
reactive sites
Resin bonding
Resins
Softwoods
technical lignin
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Summary:The substitution of phenol by lignin in phenol-formaldehyde (PF) resins is one of the most promising end uses of lignin valorization. Lignin from grasses and softwood has been the focus of the studies in this field as they present a higher number of theoretical reactive sites for resin synthesis. Herein we examined the composition and chemical reactivity of “less-reactive” hardwood lignin fractions and their performance in PF resins, synthesized by substituting 50 wt% of the phenol with lignin. Before resin synthesis, the samples were hydroxymethylated and the maximum formaldehyde consumption was recorded. By doing so, we observed that hardwood fractions consumed formaldehyde close to the theoretical calculation, whereas the reference softwood lignin consumed only about ¼ of the theoretical value. In the resin synthesis, we added formaldehyde to the formulation according to the measured maximum formaldehyde consumption. Thus, low values of free formaldehyde in lignin-PF (LPF) resins were achieved (<0.23%). Moreover, the resin bonding strength displayed similar performance irrespective of whether the LPF resins were made with softwood or hardwood lignin (range of 3.4–4.8 N mm at 150°C and 45–480 s of press time). Furthermore, we concluded that hardwood kraft lignins present no disadvantage compared to softwood lignins in PF resin applications, which have significant practical implications.
ISSN:0018-3830
1437-434X
DOI:10.1515/hf-2018-0203