Climate-resilient bioeconomy in the value-added cycle of wood and other renewable raw materials

Project background

Wood is the most important domestic raw material in Germany and, alongside other renewable resources, is an essential component for a sustainable bioeconomy. Wood has the potential to contribute significantly to the transformation from a fossil to a regenerative economy. At the same time, the forest must change, because climate change is severely affecting existing forests. Climate damage and calamities are the result.

The conversion of forests from conifers to climate climate-resistant mixed and deciduous forests is therefore becoming increasingly urgent. The industry will therefore have to deal with new types and assortments of wood and inferior qualities from damaging events. In addition, the available wood supply has been greatly reduced by forest conversion and damaging events.

The material use of new wood species and waste wood in technical applications such as high-quality such as high-quality composite materials and components is therefore necessary. In addition, new products and their components without without an existing recycling concept in a sustainable industry. Material waste wood cycles must be developed in order to make greater use of the carbon sequestration in wood and reduce the harvesting pressure on forests. reduce the harvesting pressure on forests.

Project objective

The aim is to develop expertise in the processing value chain of new types of wood and the material utilization of waste wood for transfer to research and teaching. This project therefore focuses on the technical processing of new types of wood and secondary new wood species and secondary waste wood assortments and qualities by means of mechanical and thermomechanical processing and recycling methods.

Furthermore secondly, digital data is used to parameterize the processes in order to scale scaling processes and evaluating them in terms of sustainability and optimize process management using AI-based approaches and analyze possible applications for material development (Figure 1). In addition, when utilizing secondary raw materials, the pollutants/contaminants and volatile components (VOCs), which can be an obstacle to cascade use.

Project procedure

Innovation

With the work of the proposed focus area, it will be possible to strengthen the sustainable use of primary materials and the recycling of strengthen wood composites. This will be achieved in particular through the characterization of new material systems and new wood-based composite materials.

The new wood species resulting from forest conversion will be analyzed, as well as the new wood assortments and qualities from old and damaged wood, made available for various applications and products. In the project process chains examined in the project are the pulping of the wood and the further processing into wood-based composites (such as insulation boards) as well as the further processing of plastics into technical fiber composite fiber composite components (such as automotive applications).

Based on digital data and supported by artificial intelligence artificial intelligence, the new manufacturing processes can be scaled and evaluated ecologically and economically. This makes it possible to derive potential for improvement and optimize the processes for processing new wood assortments directly during their development.

Strengthening the closed-loop recycling of wood composites and the material utilization of waste wood offers the potential to potential to manufacture products with a high degree of vertical integration, low fossil resource intensity and high CO2 reduction potential. This means that This focus area makes a significant contribution to the climate neutrality government's goal of climate neutrality by 2050 and to the objectives of the of the Bavarian bioeconomy strategy (including the reduction of fossil consumption of resources, protection of domestic, renewable resources, cascading use).