Project Abstract

This project aims to develop and characterize novel bio-based polyurethane (bio-PU) foams, which have the potential to replace traditional petroleum-derived polyurethane foams in a wide range of applications. Polyurethanes are widely used in various industries, including automotive, construction, and furniture, due to their versatility, durability, and excellent thermal and mechanical properties. However, the reliance on fossil-based raw materials has raised concerns about the environmental sustainability of conventional polyurethanes. The growing demand for eco-friendly and renewable materials has driven the development of bio-based polyurethanes, which utilize renewable and sustainable feedstocks, such as vegetable oils, terpenes, and lignocellulosic biomass. These bio-based raw materials can be used to synthesize polyols, which are a key component in the production of polyurethane foams. By incorporating bio-based polyols into the polyurethane formulation, it is possible to reduce the dependency on petrochemical-derived raw materials and develop more sustainable foam products. The primary objective of this project is to design, synthesize, and characterize bio-based polyurethane foams with desirable physical, mechanical, and thermal properties. The project will explore the use of various bio-based polyols, such as those derived from vegetable oils or lignocellulosic biomass, in combination with conventional diisocyanates to create a range of bio-PU foam formulations. The project will focus on optimizing the foam synthesis process, including the selection of appropriate catalysts, blowing agents, and other additives, to achieve the desired foam properties. The characterization of the bio-PU foams will involve a comprehensive suite of analytical techniques, including physical property measurements (density, porosity, thermal conductivity), mechanical testing (compressive strength, tensile properties, and dynamic mechanical analysis), and thermal analysis (thermogravimetric analysis and differential scanning calorimetry). The impact of the bio-based polyol content and other formulation parameters on the final foam properties will be thoroughly investigated. Moreover, the project will explore the biodegradability and sustainability aspects of the developed bio-PU foams. The environmental impact of the production process and the end-of-life disposal options will be assessed, with the aim of promoting the use of these bio-based materials as a more sustainable alternative to traditional polyurethane foams. The successful completion of this project will contribute to the advancement of bio-based polymer technology and the development of environmentally friendly polyurethane foam products. The research findings will be disseminated through peer-reviewed publications and presentations at scientific conferences, ensuring that the knowledge gained from this project is shared with the broader scientific community. Furthermore, the project outcomes may lead to the development of new commercial applications for bio-PU foams, thus promoting the transition towards a more sustainable and circular economy.

Project Overview