Brightgreen’s D900 is the world’s first LED downlight that matches the brightness, light quality and beam width of a 50W halogen, while using only a quarter of the power. At 16W and 900 lumens, the D900 is currently the brightest downlight on the market. The light’s high CRI offers exceptional light quality (CRI 90) and is universally dimmable, working with all normal leading and trailing edge dimmers, as well as C Bus systems.
The D900 is built for the Australian climate and lasts up to thirty years, with a five year warranty guaranteeing the product. Since winning last year’s prestigious DesignEX and DesignBUILD Best New Product Award, the D900 has received both national and international acclaim.
Other features and benefits include:
- Zero fire risk
- Solid state fan (keeps the temperature cool)
- Gimbled
- No UV light
- Mercury and heavy metal free
- No flickering
- 90mm hole cutout (same as halogen)
» Learn more on the Brightgreen website
Sustainability attributes
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Recyclable
Recyclable products and materials can be reprocessed and transformed into new goods at the end of their useful life. Materials composed of a single substance (for example, aluminium or concrete) are generally easier to dismantle and recycle than those composed of multiple substances. Employing recyclable materials offers several benefits – reduced use of new resources, reduced landfill, reduced costs for manufacturers.
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).
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.
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.
Packaging is reduced
The aim is to reduce the amount of packaging required to effectively house and transport products and materials, resulting in less waste material destined for landfill, lower manufacturing costs for producers, and reduced transportation costs. Some manufacturers implement returnable packaging systems or heavily in recyclable packaging. Paper, glass, metal and board packaging can be readily recycled.
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.
Reduces waste or pollution
Streamlined production processes can reduce the environmental impact of manufacturing. Environmentally responsible manufacturers focus upon reducing emissions, minimizing waste created during production, and ensuring energy-efficient operation. Waste-reducing production can also reduce costs, as manufacturers can make better use of resources.
Reduces heating or cooling load
Heating and cooling load is the amount of energy consumed to maintain a desired temperature within a building. Project design – and the materials and products employed – plays a significant role in optimizing the performance of heating and cooling systems, to reduce the energy expended on internal climate control. Elements that affect heating and cooling load include heat transferred through glass windows and doors, infiltration of outside air, and the impact of people, lighting and electronic equipment.
Reduces energy consumption
Making use of materials and products that reduce energy consumption can have a major influence on the environmental impact of a building project. Teaming passive design strategies (orientation, building shape, natural lighting and ventilation) with low-energy lighting, thermally efficient insulation and low-e glass can reduce a project’s reliance on heating and cooling systems, resulting in lower energy consumption. Likewise, use of energy-efficient appliances, alternative energy systems (solar, hydro) and building management systems can also reduce the project’s carbon footprint.
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.
ISO 14001 compliant
The international environmental management standard ISO 14001 assists manufacturers with the management, control and reporting of their environmental performance. Developed by the International Organization for Standardization, the standards enable manufacturers to develop a streamlined environmental management system (EMS) to minimize the impact of their operations on the environment. Compliant companies can seek certification from accredited auditors.