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Flaking
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Image
Published: 01 January 2002
Fig. 18 Fine flaking damage on the surface of a shaft that served as a roller-bearing inner raceway. The flaking originated along the ridges of the surface finish of the shaft.
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Published: 15 January 2021
Fig. 20 (a) Commercially pure titanium tube with flaking of brittle hydride layer at weld on inside diameter. Original magnification: 8×. (b) Thick, black etching layer of hydride at weld showing hydride needles in weld and base material. Kroll’s etch. (c) Intergranular fracture of high
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in A Survey of the Causes of Failure of Rolling Bearings
> ASM Failure Analysis Case Histories: Mechanical and Machine Components
Published: 01 June 2019
Fig. 1 Onset of flaking in a roller bearing.
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in A Survey of the Causes of Failure of Rolling Bearings
> ASM Failure Analysis Case Histories: Mechanical and Machine Components
Published: 01 June 2019
Fig. 2 Severe flaking in a roller bearing.
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in A Survey of the Causes of Failure of Rolling Bearings
> ASM Failure Analysis Case Histories: Mechanical and Machine Components
Published: 01 June 2019
Fig. 3 Flaking on one track of self-aligning type of ball bearing.
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in A Survey of the Causes of Failure of Rolling Bearings
> ASM Failure Analysis Case Histories: Mechanical and Machine Components
Published: 01 June 2019
Fig. 4 Flaking related to pitch of balls.
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in Brittle Fracture Leading to Failure of a Bridge Section
> ASM Failure Analysis Case Histories: Buildings, Bridges, and Infrastructure
Published: 01 June 2019
Fig. 2 The crack in each web terminated in a plastic hinge. Note paint flaking in area at tip of crack.
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Image
in Failures of Rolling-Element Bearings and Their Prevention
> Analysis and Prevention of Component and Equipment Failures
Published: 30 August 2021
Fig. 50 (a) Fine flaking damage on the surface of a shaft that served as a roller-bearing inner raceway. The flaking originated along the ridges of the surface finish of the shaft. (b) Flaking (also known as micropitting) due to poor lubrication within a cylindrical roller bearing
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in Case Study on Failure of Ball Bearing of an Aeroengine
> Handbook of Case Histories in Failure Analysis
Published: 01 December 2019
Fig. 2 ( a ) The rolling elements (balls) of the ball bearing. ( b ) Flaking damage on the surface of some of the balls of the bearing
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in Case Study on Failure of Ball Bearing of an Aeroengine
> Handbook of Case Histories in Failure Analysis
Published: 01 December 2019
Fig. 5 ( a ) SEM image captured at the probable origin of the flaking damage on the outer race of the ball bearing. ( b ) SEM image of the remaining portion of the flaking damage on the outer race of the ball bearing
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in Case Study on Failure of Ball Bearing of an Aeroengine
> Handbook of Case Histories in Failure Analysis
Published: 01 December 2019
Fig. 6 High-magnification SEM images captured at origin of the flaking damage on the outer race of the bearing
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in Hydrogen-Assisted Fracture of a 17-4PH Airplane Wing Component
> Handbook of Case Histories in Failure Analysis
Published: 01 December 1992
Fig. 5 SEM fractograph of mixed topography in flake 3 near flake-overload boundary (stippled area of Fig. 2 ). Rougher, brighter features are probably fatigue elements; remainder is grain-boundary morphology of flake. Other stippled areas are similar.
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Book Chapter
Series: ASM Failure Analysis Case Histories
Publisher: ASM International
Published: 01 June 2019
DOI: 10.31399/asm.fach.mech.c0047975
EISBN: 978-1-62708-225-9
... of the transmission. The center bearing of the transmission input-shaft ball-bearing stack had a broken cage and one ball was found to have been split into several pieces. Several scored balls and flaking damage in the raceways of the inner and outer rings was observed. The origin (area in rectangle) was oriented...
Abstract
An aircraft was grounded when illumination of the transmission oil-pressure light and an accompanying drop in pressure on the oil-pressure gage was reported by the pilot. No discrepancy in the bearing assemblies and related components was revealed by teardown analysis of the transmission. The center bearing of the transmission input-shaft ball-bearing stack had a broken cage and one ball was found to have been split into several pieces. Several scored balls and flaking damage in the raceways of the inner and outer rings was observed. The origin (area in rectangle) was oriented axially in the raceway and was flanked by areas of markedly different-textured flaking damage. Stringers of nonmetallic inclusions were revealed at the origin during metallographic examination of a section parallel to the axially oriented origin. Thus it was concluded that the failure was caused by contact fatigue mechanism (flaking) activated by the subsurface nonmetallic inclusions.
Series: ASM Failure Analysis Case Histories
Publisher: ASM International
Published: 01 June 2019
DOI: 10.31399/asm.fach.mech.c0047968
EISBN: 978-1-62708-225-9
... was installed in contact with the inner ring for accurate positioning of the microdrum. The particles contained in residue achieved after cleaning of the grease on bearings with a petroleum solvent were attracted by a magnet and detected under a SEM (SEM) to be flaked off particles from the outer raceway...
Abstract
The radial-contact ball bearings (type 440C stainless steel and hardened) supporting a computer microdrum were removed for examination as they became noisy. Two sizes of bearings were used for the microdrum and a spring washer that applied a 50 lb axial load on the smaller bearing was installed in contact with the inner ring for accurate positioning of the microdrum. The particles contained in residue achieved after cleaning of the grease on bearings with a petroleum solvent were attracted by a magnet and detected under a SEM (SEM) to be flaked off particles from the outer raceway surface. Smearing, true-brinelling marks, and evidence of flaking caused by the shifting of the contact area (toward one side) under axial load, was revealed by SEM investigation of one side of the outer-ring raceway. The true-brinelling marks on the raceways were found to be caused by excessive loading when the bearing was not rotating or during installation. It was concluded that the bearings had failed in rolling-contact fatigue. The noise was eliminated and the preload was reduced to 30 lb by using a different spring washer as a corrective measure.
Book Chapter
Series: ASM Failure Analysis Case Histories
Publisher: ASM International
Published: 01 June 2019
DOI: 10.31399/asm.fach.conag.c0047474
EISBN: 978-1-62708-221-1
... (150 ksi). A hydrogen flake approximately 5 cm (2 in.) in diam was observed at the center of the fracture surface. Beach marks indicative of fatigue encircled the hydrogen flake and covered nearly all of the remaining fracture surface. The failure of this linkways caused by an excessive hydrogen...
Abstract
A 10-cm (4-in.) chain link used in operating a large dragline bucket failed after several weeks in service. The link was made of cast low-alloy steel (similar to ASTM A487, class 10Q) that had been normalized, hardened, and tempered to give a yield strength of approximately 1034 MPa (150 ksi). A hydrogen flake approximately 5 cm (2 in.) in diam was observed at the center of the fracture surface. Beach marks indicative of fatigue encircled the hydrogen flake and covered nearly all of the remaining fracture surface. The failure of this linkways caused by an excessive hydrogen content. Two steps were taken to combat this type of failure. First, when service conditions did not require high hardness to combat wear, the links were produced of a steel having a yield strength of about 690 MPa (100 ksi) rather than 1034 M
Series: ASM Failure Analysis Case Histories
Volume: 3
Publisher: ASM International
Published: 01 December 2019
DOI: 10.31399/asm.fach.v03.c9001795
EISBN: 978-1-62708-241-9
... Abstract A ball bearing in a military jet engine sustained heavy damage and was analyzed to determine the cause. Almost all of the balls and a portion of the outer race were found to be flaking, but there were no signs of damage on the inner race and cage. Tests (chemistry, hardness...
Abstract
A ball bearing in a military jet engine sustained heavy damage and was analyzed to determine the cause. Almost all of the balls and a portion of the outer race were found to be flaking, but there were no signs of damage on the inner race and cage. Tests (chemistry, hardness, and microstructure) indicated that the bearing materials met the specification requirements. However, closer inspection revealed areas of discoloration, or nonuniform contact marks, on the ID surface of the inner ring. The unusual wear pattern suggested that the bearing was not properly mounted, thus subjecting it to uneven or eccentric loading. This explains the preferential nature of the flaking on the outer race and points to an assembly error as the root cause of failure.
Image
Published: 01 January 2002
Fig. 37 Microstructures of failed crankcase shown in Fig. 36 . (a) Normal flake graphite from a thick-wall section. (b) Type B rosette graphite from a thin-wall section. Both etched with picral. 200×. Source: Ref 11
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in Cracked Cast Iron Crankcases
> ASM Failure Analysis Case Histories: Processing Errors and Defects
Published: 01 June 2019
Fig. 3 Structure of first crankcase, etch: Picral. 200 × Normal flake graphite
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Published: 01 December 1993
Fig. 7 Micrograph showing flake graphite observed in the fractured sample. Unetched. 62×
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in Microstructural Features of Prematurely Failed Hot-Strip Mill Work Rolls: Some Studies in Spalling Propensity
> ASM Failure Analysis Case Histories: Steelmaking and Thermal Processing Equipment
Published: 01 June 2019
Fig. 2 Optical micrograph showing typical flake graphite morphology in the shell region of roll sample HSM #4; magnification 100×
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