LED lighting products used in lighting applications and their subsequent environmental impact are growing rapidly. However, there are no in-depth updated studies that show how to assess and compare them for eco-design purposes. This research aims to add insights in this area to inform eco-design by assessing and comparing the environmental impact of a new LED eco-lighting product with an existing LED lighting product. A cradle to grave Life Cycle Assessment (LCA) was conducted using ReCiPe Midpoint and Endpoint (H) life cycle impact assessment method with Simapro software. The system boundaries included all product life cycle stages, except the maintenance of the luminaires and the manufacturing of the packaging. A novel functional unit was defined for the assessment, which is more suitable for the LED lighting products. Six scenarios were considered, including three probable useful lives of the luminaires (1,000, 15,000 and 40,000 h) and two end of life options (domestic bin and recycling centre). The LCA results revealed that the new eco-lighting product has about 60% less environmental impact than the existing lighting product in all scenarios. The life cycle stages with the highest environmental impact are: 1) Use, 2) Manufacturing, 3) End of Life and 4) Transport. Based on the results obtained, recommendations for eco-design of LED lighting products were proposed, and challenges of application of LCA for the eco-design were discussed.
The migration of primary Si grains during the solidification of Al-18 wt%Si alloy under a high-gradient magnetic field has been investigated experimentally. It was found that under a gradient magnetic field, the primary Si grains migrated toward one end of the specimen, forming a Si-rich layer, and the thickness of the Si-rich layer increased with increasing magnetic flux density. No movement of Si grains was apparent under a magnetic field below 2.3 T. For magnetic fields above 6.6 T, however, the thickness of the Si-rich layer was almost constant. It was shown that the static field also played a role in impeding the movement of the grains. The primary Si grains were refined in the Si layer, even though the primary silicon grains were very dense. The effect of the magnetic flux density on the migratory behavior is discussed.
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