Special Report                                                                   Special Report


 Pipe inspection using radiography &   retrofi tted  onto  conventional  fi lm-based  more than eight inches and there is in-  Fluoroscopy, which is faster and safer
 software simulation  systems, eliminating the need for costly  suffi  cient  clearance  between  pipelines  than traditional radiography, can be
       processing chemicals and equipment.  running in a pipe rack. It is possible to  used to quickly reveal corrosion and
 Radiography for pipeline inspections    scan pipelines of wider diameters by  other internal pipeline defects.
 Tangential  fi lm-based  radiography   CR testing can be performed on the  taking only a section of the pipeline in
 is used to measure and monitor a pipe’s   bends of the piping to check for cor-  one shot. Consequently, multiple shots  Benefi ts of DR
 wall thickness  and  the possible pre-  rosion or erosion. This is an accurate  will be required to cover the full dia-  DR is faster, safer (using up to 80%
 sence of corrosion. During the examina-  system but takes  a lot of  time to test  meter of some pipelines, thus making the  less radiation) and more effi  cient than
 tion of the pipeline, the steel pipes are   each bend. Also, larger diameter pipes  process more time consuming. Figure-5  conventional fi lm radiography, making
 placed sideways  to show  its crossing   require a cobalt source, hence making  shows a schematic diagram of a PR setup  it an ideal corrosion inspection tool for
 section. The radiography beam is then   use of this technique in a running plant  showing  a radiation source, insulated  complex piping networks. Unlike other
 exerted and projected onto a fi lm, thus   is not possible for larger diameters. The  pipeline,  fi lm,  and  the  radiographic  inspections methods, DR does not re-
 taking a direct measurement of the wall   image  in  Figure-4  was  taken  by  CR  image showing the cross-section of in-  quire the erection of scaff olding, access
 thickness of the pipe. This is captured   technique, showing  corrosion depo-  sulation thickness. The detailed radio-  platforms and complex logistics. Addi-
 on  the  fi lm  and  is  measured  and   sits at the elbow of an insulated pipe.  graph shows full diameter scan of the  tionally, no mechanical  probe adjust-
 reviewed against an expected thickness.  Wall thickness  reduction is  calculated  insulated pipeline indicating suspected  ments are needed over wide dimensional
       using software.  Before  measurement,  CUI locations as had been shown in  ranges.  Therefore, DR can result in
 Pipeline inspections using software   the software needs to be calibrated on  Figure-2.  CUI  was  indeed  revealed  signifi cantly less operational downtime
 simulation and discrete tomography   Fig. 3: Radiograph showing full diameter scan of an insulated pipeline showing suspected CUI   reference wedges, such as a known-size  when the insulation was opened.  and yield faster results. Reduced down-
 A  software simulation  using  discrete   locations   steel ball or an identical pipe piece.  time  also translates to decreased cost
 tomography can  also be performed to  techniques are: computed radiography  material. The plate is then scanned by a   Fluoroscopy/Real-Time Radiography   of the radiography process.
 reconstruct  the  pipe’s  cross-section  (CR), profi le radiography (PR), and fl u-  laser, which produces a digital image   Profi le Radiography (PR)  (RTR)
 with its corrosion defects.  Discrete  oroscopy/real-time radiography (RTR).  that can be viewed, edited and shared   PR is a proven technique to detect   RTR works by converting invisible   While  DR can produce images
 tomography can be applied  although   by a computer.  the internal wall thickness reduction of  X-rays into visible forms of light. X-ray  with similar resolution to conventional
 there  are only two known factors in  Computed Radiography (CR)  small-bore piping. The technology can  radiation is emitted on one side of the  X-rays, the post-processing techniques
 the object to be reconstructed: the pipe   CR uses X-ray producing devices   CR systems can be easily transpor-  also be applied to fi nd CUI, provided  material, where it penetrates the object  applied to  the  digital image can  im-
 specimen itself and air. Software simu-  similar to those found in conventional  ted to the fi eld for on-site weld and wall   that  source-to-fi lm  distance  (SFD)  is  and is captured by sensors on the other  prove overall  quality. Image  editing
 lation  is  a  cost-eff ective  approach  for  X-ray testing; however, instead of fi lm,  thickness  profi le  inspections  for  both   suffi  cient to cover the entire pipe dia-  side.  These sensors,  which work by  software can also be used to make other
 presenting the data measurements and  images are captured on reusable imag-  insulated and uninsulated piping struc-  meter  in one shot.  This may become  fl uorescence, convert X-rays into light  adjustments to  the digital X-ray  to
 projections. It can be optimised using a  ing plates coated with a phosphor-based  tures. If needed, CR images can also be   diffi  cult when the pipeline diameter is  to produce real-time digital images.  improve the measuring and inspection
 general optimisation strategy of simu-                                   capabilities.
 lated  annealing.  Figure-3  shows  a  re-
 presentative radiograph of an insulated                                     Other  benefi ts  of  digital  radio-
 pipeline  showing suspected corrosion                                    graphy include:
 under insulation (CUI) locations.                                           Reduced exposure time;
                                                                             Elimination of fi lm waste;
 Detecting corrosion with digital radio-                                     Improved data management; and
 graphy (DR)                                                                 Automated image archiving
 One of the most popular imaging
 techniques, X-ray inspection, has been                                   Applications of DR
 used in the oil and gas industry for over                                   The non-destructive nature of  DR
 100 years.  The constant evolution of                                    makes it ideal for identifying defects in
 this technology has led to a multitude                                   sensitive pipeline infrastructure such as
 of innovations. One of the latest deve-                                  those found in the oil and gas industry.
 lopments is DR, which refers to a group                                  The level of detail that can be obtained
 of advanced radiographic inspection                                      allows it to be used for numerous ins-
 techniques that use digital imaging as                                   pection  applications, including  detect-
 opposed to traditional fi lm.                                             ing and measuring: uniform corrosion;
                                                                          erosion corrosion; CUI; fl ow-assisted-
 For pipeline corrosion inspections,    Fig. 5: Schematic diagram of profi le radiography set up (the image shows cross-section of   corrosion;  corrosion  under  pipe  sup-
 three of the most common types of DR   Fig. 4: CR radiograph showing corrosion deposits at the elbow of an insulated pipe  insulation thickness   ports; and welding corrosion.


 168  Chemical Weekly  July 29, 2025  Chemical Weekly  July 29, 2025                                   169


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