        TY  - JOUR
T1  - Investigation of Fatigue Behavior for Construction Vehicle Shafts
AU  - Çetin, Furkan
AU  - Palanduz, Tolga
AU  - Soyusinmez, Tuğrul
AU  - Güzelipek, Oğuzcan
AU  - Kaplan, Anıl
PY  - 2022
DA  - December
JF  - Cukurova University Journal of Natural and Applied Sciences
JO  - CUNAS
PB  - Cukurova University
WT  - DergiPark
SN  - 2822-2938
SP  - 1
EP  - 12
VL  - 1
IS  - 4
LA  - en
AB  - Induction surface hardened low alloyed medium carbon steels are frequently utilized in essential automotive and machine applications that demand high fatigue resistance. The right combination of hardening depth and the magni-tude and distribution of residual compressive stresses in the surface layer de-termines the fatigue behavior of induction hardened components to a large extent.Axles are connected within vehicles to provide two vital functions: •Carry torque from the engine to the wheels via a planetary gear arrange-ment, •Keep the wheels in relative alignment with each other and the vehicle&#039;s body. The circular motion of the drive wheels is maintained in most non-commercial vehicles by axle shafts, which are an essential component of the rear axle.Two axle shafts, which are used as powertrain element in construction vehi-cles hardened with induction heat treatment with SAE 4140 material stand-ard, were broken during operation. In this study, 2 failed axle shafts and 2 non-failed axle shafts were compared in order to determine the reason for the breakage.The parts were cut from 3 different regions and the images of the pieces were taken with a CARL ZEIZZ NEOPHOT 32, NIKON SMZ 1500 light mi-croscope. The microstructure and hardened case depths of the parts were checked.In microstructure images, it was seen that the structure was not completely homogeneous, However, it was un-derstood that this was not the cause of the failure. And also, It was determined that the grain size of G1 and G2 shafts was rougher than T1 and T2.T shafts have been observed to have a low hardened case depth in the spline area. In the conical end area of the shafts, the prior austenite grain was found to be considerably coarser because the edge above the groove was overheat-ed. Under the grove the inappropriate wave with decreasing of case-hardened depth have observed. It was determined that the reasons for the failure of the parts were low hard-ened case depth.  The effective case depths of the failed T-parts were found to be 6 mm, and the non-failed G-parts were greater than 8 mm.As a result of the studies, it was determined that the reason for the breakage of the parts was low hardened case depth caused by heat treatment
KW  - Fatigue Behavior
KW  - Heat Treatment
KW  - Construction Vehicle Shaft
KW  - Case Hardening Depth
CR  - [1]	Chaudhary, S. K., A. K. Rajak, and K. Ashish. &quot;Failure analysis of rear axle shaft of a heavy vehicle.&quot; Materials Today: Proceed-ings 38 (2021): 2235-2240.
CR  - [2]	V.J. Colangelo, F. A. Heiser, Analysis of metallurgical failures, N. Y., 1974.
CR  - [3]	D.J. Wulpi, Failure of shafts. In: Failure analysis and prevention. ASM handbook, vol.11 Metals park (OH): American society for metals, 1986, pp.459-82.
CR  - [4]	G.K. Nanaware, M.J. Pable, Failures of rear axle shafts of 575 DI tractors, Eng. Fail. Anal. 10 (6) (2003) 719–724.
 
[5]	Osman Asi, Fatigue failure of a rear axle shaft of an automobile, Eng. Fail. Anal. 13 (8) (2006) 1293–1302.
CR  - [6]	Gys van Zyl, Abdulmohsin Al-Sahli, Failure analysis of conveyor pulley shaft, Case Stud. Eng. Fail. Anal. 1 (2) (2013) 144–155.
CR  - [7]	Du. Jinfeng, Jun Liang, Lei Zhang, Research on the failure of the induced draft fan’s shaft in a power boiler, Case Stud. Eng. Fail. Anal. 5 (6) (2016) 51–58.
CR  - [8]	Xu Xiaolei and Yu Zhiwei, Failure analysis of a locomotive turbocharger mainshaft, Volume 16, Issue 1, 2009, p 495-502.
CR  - [9]	A.M Lancha, M Serrano, J Lapeña, D Gómez-Briceño, Failure analysis of a river water circulating pump shaft from a NPP, Eng. Fail. Anal. 8 (3) (2001) 271–291.
CR  - [10]	Dejan Momcˇilovic´, Zoran Odanovic´, Radivoje Mitrovic´, Ivana Atanasovska, Tom-azˇ Vuherer, Failure analysis of hydraulic turbine shaft, Eng. Fail. Anal. 20 (2012) 54–66.
CR  - [11]	R.W. Fuller, J.Q. Ehrgott, W.F. Heard, S.D. Robert, R.D. Stinson, K. Solanki, M.F. Hor-stemeyer, Failure analysis of AISI 304 stainless steel shaft, Eng. Fail. Anal. 15 (7) (2008) 835–846.
CR  - [12]	Xu D-H, Kuang Z-B. A study on the distribution of residual stress due to surface induc-tion hardening. J Eng Mats Tech Ž. Trans ASME 1996; 118:571-575.
CR  - [13]	Semiatin SL, Stutz DE. Induction heat treatment of steel. ASM, Carnes Publication Ser-vices, 1986.
CR  - [14]	Salchak, Yana Alekseevna, et al. &quot;Method of case hardening depth testing by using multifunctional ultrasonic testing instru-ment.&quot; IOP Conference Series: Materials Science and Engineering. Vol. 81. No. 1. IOP Publishing, 2015.
CR  - [15]	Shen Q et al (2008) Modern induction heat treatment technologies. p 1
CR  - [16]	Chen, Bo, et al. &quot;Investigation on Induction Hardening Treatment of Cylindrical Drive Gear Shaft.&quot; Society of Automotive Engineers (SAE)-China Congress. Springer, Singa-pore, 2016.
UR  - https://dergipark.org.tr/en/pub/cunas/issue//1213554
L1  - https://dergipark.org.tr/en/download/article-file/2808542
ER  -