Radiography Testing

Radiography testing (RT) is one of the most widely used non destructive test (NDT) method. With the help of this method we can detect hidden flaws or discontinuities present in welds such as cracks, porosity & blow holes, slag, flux or oxide inclusions, lack of fusion, incomplete penetration, Mismatch and tungsten inclusion etc.

Short wavelength electromagnetic radiations such as X-rays or Gamma rays (γ) are used for Radiography testing. Both X-rays and Gamma rays have very high intensity and hence they are able to penetrate material of any thickness. This high penetrating power is used during radiography testing.

The part to be inspected (Test material) is placed between the radiation source and a sensitive film. If the material is sound or flawless, entire rays (either X-rays or Gamma rays) pass through the material very evenly. But if the material contains any flaw (or flaws), than the rays which will pass through the flaws will get absorbed to a small extent due to the change in the density. Please note that those rays which will not encounter any flaw will remain intact and will pass through the material evenly. These rays are finally made to fall on a light sensitive film placed on the back side of the material being inspected.

The material (being inspected) and the sensitive film are kept under exposure of radiation (either X-rays or Gamma rays) for a certain period of time then the film is developed. Once the film is developed, it is called as radiograph.

The density of the film or the amount of darkness on the film will vary depending upon the amount of radiation reaching the film. The darker area on a radiograph indicates more exposure (higher radiation intensity) as compared to the lighter areas which receives less exposure. This variation in the image darkness reveals the presence of flaws or discontinuity inside the film. This variation in the darkness may also be used to determine the thickness or composition of the test material.

Please note that most of the defects possess lesser density than the sound parent metal, hence they transmit radiation (either X-rays or Gamma rays) much better than the sound metal does. Hence the film appears to be darker at the area exposed by the defects.

As explained earlier that both X-rays and Gamma rays are electromagnetic radiation having short wavelength but very high intensity, now I will explain about the steps to be followed for doing radiography.

Radiography by using X-rays:

X-rays are produced by an X-ray tube, which is an evacuated tube (usually made of glass) and it contains an electrically heated filament and a tungsten anode. The electrically heated filament releases electrons which are made to hit on the tungsten anode. Due to the collision of high velocity electrons with the tungsten anode, X-rays are emitted.

These X-rays are allowed to pass through the test material. A cassette containing film is placed behind the test material (part to be inspected). A penetrameter (or Image Quality Indicator IQI) is placed on the side of the source adjacent to the weld.

After the prescribed time of exposure the source is turned off and the film is send for development in the dark room (A dark room is a place where the film is developed). After development the film is inspected with the help of a viewer.

Radiography by using Gamma-rays:

Gamma rays are produced by radioactive isotopes. Nucleus of a radioactive isotope remains unstable. Commonly used isotopes for industrial radiography are:

  1. Cobalt 60 (Co 60):  Half-life of 5.3 years
  2. Iridium 192 (Ir192): Half-life of 72 days
  3. Caesium-137 (Cs137) : Half-life of 30 years

A lead or tungsten alloy container of sufficient thickness is used containing the the gamma ray source (300 mg). Such containers are used to provide necessary protection. These Gamma rays are allowed to pass through the test material. A cassette containing film is placed behind the test material (part to be inspected). A penetrameter (or Image Quality Indicator IQI) is placed on the side of the source adjacent to the weld. Rest of the procedures is same as X-ray technique.

This is the first part of this topic second part will be uploaded soon, Please leave your valuable feedback.

19 comments

  1. Can u also describe about the problems which we will face in the site where we come to know about those on experience……. With ur experience I want to let know what doubts made ur job more difficult in the site…. And please explain even about the ‘T’ joint and Butt joint as well……recently we completed ASNT level-2…..and now we are working on RT……ur little information is also very useful for us…..so pls give an answer…..we will be waiting………….

  2. Sir I have questions regarding penetrameter selection, how much penetrameter is Required for 6 mm, 10 mm, 12 mm, As Per Set A and Set B, how we can go Up side or Downside?

  3. Did you tend to use X-Ray or Gamma-Ray more in the field? What are the advantages/disadvantages of using one over the other in fieldwork.

  4. Very informative article thanks for publishing, please provide us with the same article for radiation safety during radiography testing.
    Regards

  5. Sir , you have explained very well. please describe also the radiographic technical process like SWSI, DWSI, DWDI , elliptical position, panoramic shot and selection of IQI please describe in brief.

    1. I am very interested in your continaul education programme.
      I am a level 2 ASME certified inspector in the five basic NDT courses and I have been working for the pass 6 years. I wish to do a level III course with RT as major.
      With BSc. And a welding diploma.
      Do You have any advise for me.
      Thanka

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