How Low Temperatures Impact Dye Penetrant Testing

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Dye Penetrant Testing on Pipe

 

In this article, we look at how lower inspection temperatures affect the performance of dye penetrant testing cleaners, penetrant and developers

 

The operating temperature range for penetrant inspection as specified in ASTM E1417 Standard Practice for Liquid Penetrant Testing is 4°C to 52°C, but how is the penetrant inspection affected at temperatures below 4°C and can the inspection process be adjusted to achieve acceptable results?

To answer these questions, we evaluated SKC-S cleaner/remover, SKL-SP2 solvent removable dye penetrant and SKD-S2 non-aqueous developer at a range of temperatures in order to figure out what NDT inspectors can expect when using these, or similar quality dye penetrant products when inspecting at lower temperatures

 

Cleaning at lower temperatures

At lower temperatures in the range of 0°C – 10°C, the solvent cleaner will take longer to dry.

We used 24°C as our ambient, standard operating temperature, and observed how decreasing temperatures impacted how quickly the solvent cleaner dried. Below are our suggested drying time for solvent-based cleaner/removers at lower temperatures.
 

Temperature Cleaner Drying Time
24°C Standard
10°C 2 x Standard
4°C 3 x Standard
0°C 4 x Standard

 

It is critical to make sure the solvent has evaporated during the precleaning step either by wiping with a clean, lint free cloth or using air dryers to ensure a clean and dry part prior to penetrant application. Unevaporated cleaner remaining in indications can impede penetrant entry into the surface breaking indications.

 

Dwelling at lower temperatures

Penetration time should also be extended since the viscosity of penetrant increases with decreasing temperatures, which slows down penetration and can significantly impact the test results.
 

Temperature Dwell Time
24°C Standard
7°C 2 x Standard
0°C 2.5 x Standard

 

Developer at lower temperatures

Developer drying time is more of a challenge and our tests showed the developing action is impeded because of the slower solvent evaporation. When the developer dries, the indications become fuzzy or show excessive bleed out.

Penetrant Developer

We were not able to get good results at 0°C because the developer remained wet and did not dry within a reasonable amount of time. At 3 – 4°C, and with some air movement, developer film will dry at 5 times the standard time at 24°C.
 

Temperature Developer Drying Time
24°C Standard
4°C 5 x Standard

 

A positive note is at low temperatures, we found good indications with extremely small and tight defects. The slow drying rate of the developer film allows greater bleed out of the penetrant from the defect. For large defects, longer development time caused excessive bleed out making indication interpretation more difficult.

 

Safety is a make-or-break factor in a technician's world – we list details around hazards, storage, recycling, and shipping of NDT aerosols here.

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