The effect of thermal stressing on perfluoropolyalkylethers at elevated temperatures

Fultz et al. have reported that the thermo‐oxidative properties of linear PFPAEs can be improved by stressing the fluid at elevated temperature (371°C) in the presence of air. A study of M‐50 steel coupons exposed to unstressed and stressed linear PFPAE fluids at 260 °C and 330 °C each reveal comple...

Full description

Saved in:
Bibliographic Details
Published in:Tribology letters 1998-01, Vol.5 (4), p.293-296
Main Authors: Cutler, J N, Sanders, J H, Fultz, G W, Eapen, K C
Format: Article
Language:English
Subjects:
Diffusion barriers
Diffusion layers
Exposure
Fluids
Fluorine
High temperature
Iron oxides
Oxidation
Substrates
Surface layers
Temperature
Thickness
Tribology
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Fultz et al. have reported that the thermo‐oxidative properties of linear PFPAEs can be improved by stressing the fluid at elevated temperature (371°C) in the presence of air. A study of M‐50 steel coupons exposed to unstressed and stressed linear PFPAE fluids at 260 °C and 330 °C each reveal complex surface layers. For the coupon exposed to the unstressed fluid at 260 °C, a subsurface layer is observed between the iron oxide and iron substrate that has been characterized as being composed of FeF2. In contrast, the coupon exposed to the stressed fluid has a marked increase in the iron oxide thickness ∼2–3 times) when compared to the unstressed sample and shows no evidence of a buried fluorine‐containing layer. An increase in temperature (330 °C) in the stressed fluid O–C test was required to form a subsurface FeF2 layer. It is proposed that the elimination of the fluorine layer found on the M‐50 substrate increases the upper temperature limit found from the oxidation–corrosion studies. The increase in the oxide layer thickness implies that the FeF2 layer found in the unstressed sample acts like a diffusion barrier which inhibits the outward movement of Fe0 and the decreased rate of iron oxide growth.
ISSN:1023-8883
1573-2711
DOI:10.1023/A:1019114329612