TWI Frequently asked questions
This process was discovered by William Roentgen in 1895 and was soon applied to medicine and then to industrial components. It is based on the principle that radiation is absorbed and scattered as it passes through an object. If there are variations in thickness or density (e.g. due to defects) in an object, more or less radiation passes through and affects the film exposure. Flaws show up on the film, usually as dark areas.
With training, an inspector can tell, from the shape of the dark areas on the film, what and where the flaws are. If the flaw in the object makes little difference to the through thickness of the object, it is unlikely to show on the radiograph. A lamination can, therefore, be difficult to detect by radiography. Cracks parallel to the beam, porosity, slag inclusions and root defects show very well.
The biggest disadvantage is that short wavelength radiations are ionising. This means they can cause chemical changes in the human body. No ionising radiation is safe, as small amounts can cause genetic damage and increase the likelihood of cancers. Stringent safety precautions are needed when using radiography and this makes it rather time consuming, disruptive and expensive.
Industrial radiography uses two sources of penetrating radiation:
- X-ray sets, of varying power, that run from an electric mains or on-site generators
- Radioactive isotopes, carried in shielding containers, which do not need a supply of electricity
Books on Radiography:
- R Hamshaw, Introduction to the Non-Destructive Testing of Welded Joints, 2nd edition, Abington Publishing, Cambridge, UK, 1996 (ISBN 1 85573 314 5)
- R Halmshaw, Industrial Radiography, published by Agfa Gevaert, Mortsel, Belgium, 1986
- Radiography in Modern Industry, 4th Edition, published by Kodak Ltd, Rochester, New York, USA, 1980
- Alan Martin and Samuel A Harbison, An Introduction to Radiation Protection, published by Chapman and Hall, 1986, 3rd edition, 1986 (ISBN 0-412-27810-3)
