Abstract
Innovative bio-based composites combining humins as biorefinery by-product with keratin or lignin as wastes or industrial side-products were developed. The bio-composites were prepared using three types of matrix formulations allowing the synthesis of elastic to rigid thermosets. These matrices were combined with chicken feathers powder, non-woven chicken feathers mat or lignin to produce bio-composites. A maximum quantity of bio-fillers was used, around 10 wt.%. The effect of the bio-fillers on the matrix’s crosslinking was studied by rheology and DSC. Then, the obtained materials were analyzed by TGA, DMA, tensile tests, water absorption and SEM. The results show a very good compatibility of the humins matrix with the bio-fillers, without any preliminary modification of the matrix, that is exceptional for the point of view of a composite. The overall performances of the neat matrix were maintained or improved through the composites. Therefore, bio-composites with potentially interesting thermal and mechanical properties have been synthesized. In the case of the elastic ductile matrix the Young’s modulus value was improved from 1 to 22 MPa, while for the rigid matrix the increase was from 106 to 443 or 667 MPa, in the case of composites with non-woven chicken feathers mat or lignin. To our knowledge this is the first study combining humins matrix with keratin. The obtained bio-composites are sustainable materials linked via the used raw materials to the circular economy and biomass valorization.
Highlights
One of the main problems faced by humanity currently and in the future is the intense pollution of the environment due to the production and use of materials based on fossil derivatives and due to the increasing amount of industrial wastes (Brostow & Hagg Lobland, 2017)
The results show a very good compatibility of the humins matrix with the bio-fillers, without any preliminary modification of the matrix, that is exceptional for the point of view of a composite
Humins were mixed with comonomers like poly diglycidyl ether (PEGDE) and glycerol diglycidyl ether (GDE)
Summary
One of the main problems faced by humanity currently and in the future is the intense pollution of the environment due to the production and use of materials based on fossil derivatives and due to the increasing amount of industrial wastes (Brostow & Hagg Lobland, 2017). The need to significantly reduce the environmental pollution has led to the investigation and development of new materials from renewable resources. An important source of protein is the chicken feathers, a by-product from the poultry industry (Garrido, Peรฑalba, de la Caba, & Guerrero, 2019). The chicken feathers are composed of 91% keratin, 8% water and 1% fats (Bansal & Singh, 2016; Ana Laura Martรญnez-Hernรกndez & Carlos Velasco-Santos, 2012; Reddy & Yang, 2007; Tesfaye, Sithole, Ramjugernath, & Chunilall, 2017). The largest amount of feathers is deposited in landfills or burned, leading to environmental pollution, and to the loss of a very rich resource of high protein raw material
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