NEW METHODS FOR ULTRASONIC NDE OF DIFFICULT MATERIALS
Reference Number
EP/I021027/1
Title
NEW METHODS FOR ULTRASONIC NDE OF DIFFICULT MATERIALS
Status
Completed
Energy Categories
Nuclear Fission and Fusion(Nuclear Fission, Other nuclear fission)
Not Energy Related
Other Power and Storage Technologies(Electric power conversion)
Not Energy Related
Other Power and Storage Technologies(Electric power conversion)
Research Types
Basic and strategic applied research
Science and Technology Fields
PHYSICAL SCIENCES AND MATHEMATICS (Physics)
PHYSICAL SCIENCES AND MATHEMATICS (Metallurgy and Materials)
PHYSICAL SCIENCES AND MATHEMATICS (Metallurgy and Materials)
UKERC Cross Cutting Characterisation
Not Cross-cutting
Principal Investigator
Professor P Withers
Materials
University of Manchester
Materials
University of Manchester
Award Type
Standard
Funding Source
EPSRC
Start Date
12 July 2011
End Date
11 July 2014
Duration
36 months
Total Grant Value
£45,945
Industrial Sectors
Mechanical engineering
Region
North West
Programme
NC : Engineering
Industrial Collaborator
Project Contact, Rolls-Royce PLC
Project Contact, National Nuclear Laboratory
Project Contact, Shell International Ltd
Project Contact, Weidlinger Associates, Inc., USA
Project Contact, Serco Group plc
Project Contact, National Nuclear Laboratory
Project Contact, Shell International Ltd
Project Contact, Weidlinger Associates, Inc., USA
Project Contact, Serco Group plc
Web Site
Objectives
Linked to grant EP/I019731/1
Abstract
In many engineering applications, materials that exhibit heterogeneous or otherwise acoustically scattering microstructure are employed, examples include austenitic steels and alloys, concrete and fibre reinforced composites. In ultrasonic non destructive evaluation (NDE) of such highly scattering media, the defect target signal is frequently obscured by clutter echoes, caused by numerous, relatively small (relative to the ultrasonic wavelengths), stationary reflectors, which form part of the internal microstructure of the material. The extent of this clutter can be significant and even defects that are larger than these randomly scattering regions can be difficult to detect. This type of time-invariant clutter noise cannot be reduced by the standard time averaging or correlation techniques that are used to reduce time varying random electrical noise. Accordingly, defect identification invariably involves a compromise between achievable resolution, which is determined partly by wavelength in the material, and the noise arising from scattering in the propagation medium. This project will investigate a range of methods for improved ultrasonic NDE of difficult materials. The approach will involve a combination of ultrasonic beam modelling, novel transducer design and array signal processing methods
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Added to Database
07/12/10
