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Reference Number EP/J013749/1
Title The development of effective grain refiner for the production of high performance light metal castings
Status Completed
Energy Categories Energy Efficiency(Transport) 20%;
Not Energy Related 80%;
Research Types Basic and strategic applied research 100%
Science and Technology Fields PHYSICAL SCIENCES AND MATHEMATICS (Metallurgy and Materials) 100%
UKERC Cross Cutting Characterisation Not Cross-cutting 100%
Principal Investigator Dr N Hari-Babu
No email address given
Ctr for Advanced Solidification Tech
Brunel University
Award Type Standard
Funding Source EPSRC
Start Date 01 August 2012
End Date 31 October 2013
Duration 15 months
Total Grant Value £121,144
Industrial Sectors Communications; Electronics
Region London
Programme Non Theme Specific
 
Investigators Principal Investigator Dr N Hari-Babu , Ctr for Advanced Solidification Tech, Brunel University (100.000%)
Web Site
Objectives
Abstract Aluminium-Silicon (Al-Si) alloys are important alloys as they are lightweight (2.7 g/cc), easily recycled, corrosion resistant, durable and environmentally friendly. In comparison with steel (7.8 g/cc), they have higher strength to weight ratio. 90% of aluminium shape castings are based on these Al-Si alloys and currently, ~ 5 million tonnes per annum are being used in automotive industry. The average car manufactured in 2006 contained between 110-145 kg of Aluminium, compared to ~1000 Kg of Steel. Life cycle analysis suggest that, a 100 kg weight reduction through substituting Steel with Aluminium parts would result in a saving of 900 litres of petrol during the car's life span (200,000 km) and 2,000Kg of CO2 savings (10 g/km). The big problem for the light metal industry in increasing the further use of these lightweight Al-Si alloys with respect to replacing steel in the transport sector is the lack of ductility and yield strength associated with the large grain structure, defects and large intermetallic particles. Since Al-Si alloys are difficult to grain refine, widespread adoption is currently constrained due to excessive casting defects and inadequate mechanical properties. Higher Si levels in these alloys results in large grains, which make casting difficult, thus resulting in very high rejection rates, up to 60% for high value critical components.Ti based grain refiners used for non-cast (wrought) Al alloys are less effective in cast Al-Si alloys due to reaction between Si and Ti. Brunel has invented an effective grain refiner that can revolutionize the foundry casting process for these Al-Si casting alloys, significantly reducing the casting defects and producing superior mechanical properties that, despite (deliberately) limited publicity, is already generating significant market interest within the materials supply chain. The Brunel grain refiner (BGR) improves castability of a wide range of aluminium alloys; eliminates hot-tearing, a common problem in castings; it improves much needed tensile strength and ductility; improves homogeneity in mechanical properties across the component; it enables thin-wall cast structures; and it tolerates high impurity levels (aluminium scrap can now be manufactured with superior properties). Additionally, it is expected to enable the casting of large and complex shaped structures using sand moulds and reduce the high (up to 60%) rejection rate during manufacture of high value components.The unique selling points of the Brunel Grain refiner are that it is highly effective for bulk castings and easily employable by the industry. Currently there exists no effective grain refiner for Al-Si castings and previously difficult to produce high performance bulk castings without defects can now be easily processed. Delivering benefits to a wide range of casting techniques, it should enable the production of castings with superior properties, allowing aluminium to replace a growingproportion of steel parts in the automotive sector. This will put the UK in the forefront of metallurgical technological developments. Very substantial environmental benefits are foreseen due to light-weighting and concomitant reductions in energy consumed and CO2 emitted
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Added to Database 24/09/12