Comcork Low Profile is an ecologically sustainable resilient flooring that contains recycled cork which makes up 70% of its content. Low Profile has a small and low circular stud surface profile and is manufactured in 27 fashion colours.
The secret behind Comcork Flooring is its unique blend of cork and rubber. Cork is a naturally renewable resource and is made up of an amazing cell structure with millions of little air pockets. There are about 40 million air pocket cells in every cm² of cork. These act like mini heat, sound and shock absorbers. Combine this with the flexibility and strength of rubber and you have a product that offers some very special benefits.
Comcork Low Profile is flexible. It can withstand vibrations and movement when installed in public transport vehicles. The cork component of Comcork provides excellent acoustic and thermal properties, providing a quieter and ‘softer underfoot’ experience for users, a definite advantage for flooring installed in schools. The superior frictional properties of cork and rubber means Comcork Flooring also has excellent slip resistance properties providing customer safety even when wet. Comcork Low Profile is suitable for heavy duty applications and is designed for heavy pedestrian traffic.
» Learn more on the Logic Australia Pty Ltd website
Sustainability attributes
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GECA rated
Good Environmental Choice Australia (GECA) and Environmental Choice New Zealand (ECNZ) are eco-labelling organizations that rate the environmental performance of products over their entire life cycle. Developed in accordance with international eco-labelling standards, GECA and ECNZ help consumers to understand the environmental impact of the products they specify by providing independent third-party assessments.
Ecospecifier rated
Ecospecifier conducts life cycle assessments to help architects, designers, builders and specifiers to choose environmentally preferable products and materials. The Ecospecifier Knowledge Base provides detail on the environmental performance of products and technologies under various rating schemes, including Green Star, BASIX, the Building Code of Australia, NABERS and ABGR.
Low embodied energy
Like embodied energy, embodied water is the water used to create and distribute a product or material (as distinct from water used during its operation). Reducing the amount of embodied water in a product’s manufacture and distribution can lessen its impact on the environment.
Low embodied water
Embodied energy refers to the energy consumed in producing and distributing products and materials. This spans the extraction of resources, processing and manufacturing, and distribution of the final product. Products and materials with low embodied energy generally require simpler manufacturing processes – for example, natural resources such as timber require less processing than aluminium and other metals. Specifying products with low embodied energy can reduce pollution, depletion of resources and degradation of the environment.
Emits low VOCs
Volatile organic compounds (VOCs) are emissions from carbon-containing compounds that pollute the air. VOCs are released from many common building products including solvents, paints and lacquers, adhesives, fabrics, carpets, printed paper, board products and composite timber. Rating schemes often categorize VOC content as low, very low, ultra low and zero.
Supported by take-back program
A take-back program sees the manufacturer accept used products from consumers, before recycling or refurbishing them for future use. The philosophy underlying a take-back program is that manufacturers should be responsible for their products throughout their entire life, also known as a “cradle to cradle” approach to manufacturing. Reclamation programs streamline recycling for consumers and encourage manufacturers to produce recyclable products and materials.
Designed for disassembly
Design for disassembly is a manufacturing strategy that anticipates the future reuse of individual components or materials, enabling a product to be broken into its constituent parts for reuse or recycling. Design for disassembly can make recycling easier, resulting in less use of new resources, less energy consumption and less landfill. In economic terms, design for disassembly gives further value to products beyond their original life. Disassembling a structure rather than demolishing it can also reduce impact on the environment by reducing dust released during demolition, reducing land degradation and reducing transport costs of disposing of materials to landfill.
Production waste is recyclable
Manufacturing processes inevitably produce waste; environmentally responsible manufacturers ensure this waste is minimized and recyclable. Production waste can sometimes be reprocessed for reuse in the same production process. Alternatively, production waste may be reused in the manufacture of other products or materials (post-industrial recycled content).
Post-industrial recycled content
Post-industrial recycled content is essentially scrap material – waste products generated during manufacturing processes that has not been used and will not be reused in the production process. As with post-industrial recycled content, reusing these materials reduces consumption of virgin resources and stops usable industrial by-products from becoming landfill.
Post-consumer recycled content
Consumer goods that have served their purpose, been recycled and reprocessed are considered post-consumer recycled content. This includes products used by households, industry and commerce that, after recycling, can be reused as parts of new products or materials. Examples of post-consumer recycled content include recycled rubber tyres transformed into roofing and flooring products, and old newspaper processed into cellulose insulation.
Locally made
Specifying locally produced materials and products offers both economic and environmental advantages. Use of locally made products and materials minimizes transportation and shipping costs, as well as reducing the amount of energy used in transportation and any pollution that may result. In regard to natural resources – timber or stone, for example – locally sourced products can be better suited to a particular region’s climate and conditions. Further, choosing locally made products supports regional economies and local producers.
