TY - JOUR
T1 - FE8 type laboratory testing of white etching crack (WEC) bearing failure mode in 100Cr6
AU - Danielsen, H. K.
AU - Gutiérrez Guzmán, F.
AU - Muskulus, Michael
AU - Rasmussen, B. H.
AU - Shirani, M.
AU - Cornel, D.
AU - Sauvage, P.
AU - Wu, J.
AU - Petrov, R.
AU - Jacobs, G.
N1 - Accepted Author Manuscript
PY - 2019
Y1 - 2019
N2 - WEC is an aggressive and unpredictable failure mode affecting bearings in particular in the wind energy sector. This paper focuses on the most common used method for WEC laboratory accelerated testing, the FE8 type test rigs using martensitic through hardened 100Cr6 cylindrical roller thrust bearings, analyzing the load conditions, test results and damage quantification. The surface and sub-surface stress conditions as well as the surface frictional loading were analyzed using a half-space model. Simulations and experiments were conducted under different load conditions, including tests with different number of rollers and tests using dynamic load and speed. Tests under constant loads show a low load influence and prove that a WEC failure can occur both prematurely and after exceeding the rated lifetime. Dynamic conditions did not accelerate WEC failure, and only rollers (not washers) were affected by WEC under dynamic loading conditions. Damage characterization was performed using optical microscopy and ultrasound scanning. Advanced image analysis based on characterization of defect regions in the ultrasound scans was used for quantifying the subsurface damage. Tests showed WEC failure could be achieved consistently, however there were seemingly large random variations in the observed damage.
AB - WEC is an aggressive and unpredictable failure mode affecting bearings in particular in the wind energy sector. This paper focuses on the most common used method for WEC laboratory accelerated testing, the FE8 type test rigs using martensitic through hardened 100Cr6 cylindrical roller thrust bearings, analyzing the load conditions, test results and damage quantification. The surface and sub-surface stress conditions as well as the surface frictional loading were analyzed using a half-space model. Simulations and experiments were conducted under different load conditions, including tests with different number of rollers and tests using dynamic load and speed. Tests under constant loads show a low load influence and prove that a WEC failure can occur both prematurely and after exceeding the rated lifetime. Dynamic conditions did not accelerate WEC failure, and only rollers (not washers) were affected by WEC under dynamic loading conditions. Damage characterization was performed using optical microscopy and ultrasound scanning. Advanced image analysis based on characterization of defect regions in the ultrasound scans was used for quantifying the subsurface damage. Tests showed WEC failure could be achieved consistently, however there were seemingly large random variations in the observed damage.
UR - http://www.scopus.com/inward/record.url?scp=85073703726&partnerID=8YFLogxK
U2 - 10.1016/j.wear.2019.202962
DO - 10.1016/j.wear.2019.202962
M3 - Article
AN - SCOPUS:85073703726
SN - 0043-1648
VL - 434-435
JO - Wear
JF - Wear
M1 - 202962
ER -