Bio Tiles
When it comes to building or renovating the house, there is at one point, where one has to decide on the tiles to be used. Tiles are a manufactured piece of hard-wearing material such as ceramic, stone, metal, or even glass, and generally used for covering roofs, floors, walls, showers, or other objects such as tabletops. Increasingly greater attention is being focused on the environment and safeguarding natural resources. As a result consumers are becoming more aware of the importance of protecting the environment. Over the last 10 years the focus of the ceramic tile industry, particularly within Europe, has been on adopting an integrated approach towards sustainability, to avoid pollution and limit the consumption of resources and meet these new demands. In line with the EU strategy of cutting annual primary energy consumption and a more sustainable use of renewable resources by 20% by 2020, researchers from Fraunhofer Institut für Werkstoffmechanik have come up with an innovative organic tile. Indeed, these tiles are more resource-efficient than their ceramic counterparts and unlock new creative options for design purposes. Bioplastics made of polylactides (PLA) are becoming more heat-resistant, thereby making them suitable for high-temperature filling processes in the food industry as well. But what makes them bio? The tiles consist of a mixture of linseed oil epoxy, various natural fibres and diatomaceous earth, a material that is procured from fossilized diatoms. New bio-based tile systems, like the ones designed at the Fraunhofer Institute for Mechanics of Materials IWM in Halle, are more environmentally friendly, lighter-weight and - depending on their manufacturing and material properties - more resource- and energy-efficient than conventional ceramic materials. 'The composite is not hard as glass and brittle like conventional epoxy, but flexible and more pliable instead. This makes it easier to work with the tiles,' as Andreas Krombholz, scientist in the natural composites division at IWM, describes another advantage. They also put a completely new spin on architectural perspectives. In the moulding process, they can be shaped on an entirely customized basis, and shaped into squares, triangles or circles, for example. Even patterns and colours can be tailor-made. Another design advantage is adding fluorescent pigments to the blend, which transforms into light tiles. This means they can be used for both outdoors and indoors, serving as illuminated guideposts on floors and walls. The same bio-tiles can also be installed in kitchens and bathrooms and can serve as indoor floor coverings. There are cost benefits to both producer and customer here: this is because the tiles can handle the impact noise abatement directly, so an entire work step can be dropped from the production process. Moreover, the packaging industry is increasingly using biopolymers made from polylactides (PLAs) as an environmentally friendly alternative to petroleum-based plastic. They are obtained from corn starch and completely biodegradable. Previously, however, PLA began to soften at about 60 ºC, so it was not suitable for heat-intensive processes. But now, researchers at the Fraunhofer Institute for Applied Polymer Research IAP in Potsdam have found a way to make this bioplastic even more heat-resistant. An interesting application comes from the food industry: The filling of yogurt in plastic cups, because this process takes place at higher temperatures. Cups made of PLA stereo complexes retain their shape and remain stable even at temperatures of up to 120 ºC. Dr. Johannes Ganster, division director at IAP, explains the principle behind this: 'To make PLA plastics more form-stable at higher temperatures, we introduced stereo complexes with special components of L-lactides and D-lactides. These right-and-left rotating molecules complement each other and make the bond even more stable.' Corporations have already expressed tremendous interest, because of the huge potential. Production of biopolymers made of PLA is independent of the growing scarcity of petroleum. In addition, they can be readily composted, and they are ideal for recycling by decomposition in lactic acid. The greatest advantage is that they have since become just as durable and sturdy as any petroleum-based plastic, and can even be used for other products, such as protective films, computer housing and shopping bags adding another step towards a bio-sustainable economy that Europe is aiming to reach.For more information, please visit: Fraunhofer Institute for Mechanics of Materials IWMH http://www.fraunhofer.de/en/about-fraunhofer.html
Countries
Germany