Reference projects

Medium-density fiberboard (MDF) is widely used in furniture construction. It has a very homogeneous surface that can be coated particularly smoothly. Furthermore, it can be produced economically and sustainably from regionally available wood and recycled waste wood. As a result, it also plays a major role in the construction industry - for example as a substrate for floor coverings or wall panels. Through this research project, we are aiming to make MDF and similar fiberboards even more sustainable. In collaboration with industrial partners, we are developing a formaldehyde-free adhesive system with bio-based materials that are available on the market at low cost. The special highlight: The new adhesive system functions without conventional adhesives.

Particle boards are a sustainable and inexpensive construction material for houses and furniture. They can be produced from regionally available wood residues and recycled waste wood. Through this research project, particle boards will become even more sustainable. In collaboration with industrial partners, we are developing particle boards that are produced using a new kind of adhesive which should not contain any health-critical formaldehyde and which consists entirely of biogenic raw materials. Furthermore, we are conducting tests to determine whether the particle boards can be produced using alternative types of wood, which will be increasingly available in the future as a result of forest restructuring.

Organic sheets made from fiber-reinforced plastic can be formed using processes similar to those applied in steel- or aluminum-sheet processing. Until now, primarily glass fibers – as well as carbon or aramid fibers and petrochemical plastics – have been utilized for production. In collaboration with the Institute for Bioplastics and Biocomposites (IfBB) at Hannover University of Applied Sciences and Arts, we are developing a sustainable and competitive alternative: bio organic sheets made from natural fibers and bioplastics with improved material properties and a high level of recyclability. Diverse products could thereby become more sustainable - including vehicles, housings, cladding and sports equipment. Thanks to the good availability of inexpensive raw materials, bio organic sheets also have strong market potential.

Small city apartments, house moves, and changes in living and working circumstances: These days, furniture has to fulfill demanding requirements in terms of functionality and flexibility. In collaboration with research partners and companies, we develop furniture that meets these requirements and is furthermore sustainable. The starting point is the new and further development of compounds, foams and imitation leather made from lignin - a plant-based residual material from industry. The aim is the creation of modular, lightweight furniture that can be easily disassembled, transported, repaired and repurposed. In other words, the service life of the material should be as long as possible. A further focus of the project is the recyclability of the furniture - from entire assemblies through to the single-type separation and preparation of the individual materials. Possibilities for the transfer of materials to other areas of application – such as the fashion industry and the motorhome sector – are also being considered.

Building with timber provides an important contribution towards climate protection. When combined with concrete, the range of applications for wooden structures can be extended. A bonding technology co-developed by the Fraunhofer WKI enables the accelerated production of timber-concrete composite elements (TCC elements). In the current “SafeTeCC” research project, we are optimizing and standardizing the manufacturing process in order to make it suitable for use on construction sites and to ensure process reliability. Simultaneously, the component properties are to be optimized. The aim is to establish the utilization of TCC elements in multi-story building construction - as a competitive alternative to precast steel-reinforced concrete elements. In this way, we are helping to increase the proportion of renewable raw materials in the construction sector and, consequently, to achieve climate and sustainability goals.

More and more houses are being insulated by means of external thermal insulation composite systems (ETICS). Whilst this saves energy, the façades are increasingly being colonized by algae. This is not only detrimental to the aesthetics but also to the diffusion capacity of the surface coating. Moisture damage can thereby result. In order to reduce algae growth, façade coatings containing biocides have often been used up to now. The problem here is that the biocides are leached out within a few years. Consequently, environmental pollution and increasing algae growth on the façade can occur. In collaboration with industry partners, we are developing a bio-based, weather-resistant façade paint that will physically prevent microbial growth. It could provide ETICS façades with long-term protection against algae - without any biocides whatsoever.

Aerogels are highly porous, light-as-a-feather materials with extraordinary properties: extremely low thermal conductivity, low sound transmission, and a high adsorption effect on volatile organic compounds. They are excellently suited both for lightweight construction and as filter materials, and are therefore considered a material of the future. In collaboration with research and industrial partners, we are developing a process for the production of aerogels on the basis of waste wood. From the aerogels, we are creating prototypes of insulation materials and pollutant-adsorbing indoor-air filters that can be utilized in buildings and vehicles. Furthermore, transfer possibilities to applications in exhaust-gas cleaning are to be demonstrated. A further project objective: The raw materials required to manufacture the aerogels are to be recovered from the products. With this sustainable material solution, we are supporting health protection as well as the fight against climate change and resource scarcity.

Hybrid lightweight-construction materials made from renewable raw resources are increasingly gaining importance on the market. With such materials, resource- and climate-friendly products can be manufactured that fulfill several functions - for example, load-bearing construction products with integrated thermal and sound insulation as well as durable (upholstered) furniture and packaging. Efficient component geometries enable substantial weight savings with simultaneous high mechanical stability. In collaboration with research and industry partners, we are developing a process for the manufacture of complexly shaped products made from wood or agricultural materials and bioplastics by means of automated molding machines. One important component of the material and technology development is furthermore the highest possible material recyclability of the products after the end of the first period of use.

Lightweight cars, trucks and trains made from renewable raw materials can contribute towards the protection of resources and the climate. As a joining technology for the production of lightweight components, adhesive bonding offers particular advantages and is therefore increasingly gaining in importance. In collaboration with research and industry partners, we are developing a bio-based, switchable PU adhesive for large surfaces. This should enable the production of panel-shaped laminated materials made from wood or wood and metal, which are not formed into 3D components until a later stage in the process chain. This opens up new possibilities for the flexible, economically efficient production of sustainable lightweight vehicles as well as for repair purposes and recycling. The special feature: Thanks to the re-detachable adhesive bond, it should be possible to separate the wood and metal according to type and with as little damage as possible.

Wood is constantly gaining in importance as a natural and sustainable construction material for buildings. As yet, however, no satisfactory fire-protection solution exists for wood in exterior applications. A lack of flame retardancy is an exclusion criterion for wooden components in tall or large-scale buildings (building classes 4 and 5), unless an expensive and time-consuming approval is applied for in individual cases. In collaboration with our project partner, we are developing an environmentally friendly flame-retardant coating for wood which is exposed to the elements. This should not require an additional top coat and should be transparent when applied. As a result, we are helping to increase the utilization of wooden façades and other exterior components made from wood in the construction industry - for example in high-rise buildings, schools and hospitals.