materials
Article
Micro-Magnetic and Microstructural Characterization
of Wear Progress on Case-Hardened 16MnCr5
Gear Wheels †
Marina Knyazeva 1,*, Julian Rozo Vasquez 1, Leonard Gondecki 2 , Max Weibring 2 ,
Fabian Pöhl 3, Monika Kipp 4, Peter Tenberge 2, Werner Theisen 3, Frank Walther 1,*
and Dirk Biermann 4
1 Department of Materials Test Engineering, TU Dortmund University, 44227 Dortmund, Germany;
julian.rozo@tu-dortmund.de
2 Chair of Industrial and Automotive Drivetrains, Ruhr University Bochum, 44780 Bochum, Germany;
leonard.gondecki@rub.de (L.G.); max.weibring@rub.de (M.W.); peter.tenberge@rub.de (P.T.)
3 Chair of Materials Technology, Ruhr University Bochum, 44780 Bochum, Germany;
poehl@wtech.rub.de (F.P.); theisen@wtech.rub.de (W.T.)
4 Institute of Machining Technology, TU Dortmund University, 44227 Dortmund, Germany;
kipp@isf.de (M.K.); biermann@isf.de (D.B.)
* Correspondence: marina.knyazeva@tu-dortmund.de (M.K.); frank.walther@tu-dortmund.de (F.W.)
† Paper dedicated to Professor Michael Pohl on the occasion of his 75th birthday.
Received: 22 October 2018; Accepted: 12 November 2018; Published: 15 November 2018 
Abstract: The evaluation of wear progress of gear tooth flanks made of 16MnCr5 was performed
using non-destructive micro-magnetic testing, specifically Barkhausen noise (BN) and incremental
permeability (IP). Based on the physical interaction of the microstructure with the magnetic field,
the micro-magnetic characterization allowed the analysis of changes of microstructure caused by
wear, including phase transformation and development of residual stresses. Due to wide parameter
variation and application of bandpass filter frequencies of micro-magnetic signals, it was possible to
indicate and separate the main damage mechanisms considering the wear development. It could
be shown that the maximum amplitude of BN correlates directly with the profile form deviation
and increases with the progress of wear. Surface investigations via optical and scanning electron
microscopy indicated strong surface fatigue wear with micro-pitting and micro-cracks, evident in
cross-section after 3× 105 cycles. The result of fatigue on the surface layer was the decrease of residual
compression stresses, which was indicated by means of coercivity by BN-analysis. The different
topographies of the surfaces, characterized via confocal white light microscopy, were also reflected in
maximum BN-amplitude. Using complementary microscopic characterization in the cross-section,
a strong correlation between micro-magnetic parameters and microstructure was confirmed and wear
progress was characterized in dependence of depth under the wear surface. The phase transformation
of retained austenite into martensite according to wear development, measured by means of X-ray
diffraction (XRD) and electron backscatter diffraction (EBSD) was also detected by micro-magnetic
testing by IP-analysis.
Keywords: wear; non-destructive testing; micro-magnetic testing; surface fatigue
1. Introduction
The lifetime of gears is limited by different damage mechanisms such as tooth root break, pitting
or scuffing. Focusing on tooth flank fatigue, it is important to be able to monitor the fatigue progress
over time and to understand the interlinking processes of initiation and growth of cracks as well as the
Materials 2018, 11, 2290; doi:10.3390/ma11112290 www.mdpi.com/journal/materials
Materials 2018, 11, 2290 2 of 17
interaction between the lubricant and the tooth material. Micro-pitting describes a wear and fatigue
phenomenon, which mainly occurs on highly loaded and case-hardened tooth flanks in slow running
gear stages of industrial gears. The fatigue phenomenon is decisively influenced by the geometry
of the gear, the loading and the chemical reactions between the tooth material and the additives of
the oil within the atmosphere [1]. The term micro-pitting describes the matt grey areas on tooth
flanks, which are primarily formed on areas with negative sliding speeds and high sliding paths.
The phenomenon starts first with short cracks on the tooth’s flank surface whereas the crack density
increases with the number of load changes. At the same time, existing cracks grow deeper into the
material or return back to the surface. At a certain crack density, small microscopic particles break out
of the surface and the characteristic grey surface is formed. With an increasing number of microscopic
outbreaks, a profile form deviation emerges, which starts at the tooth root.
The structural health monitoring (SHM) involves the development of non-destructive
methodologies to measure and control the integrity of components at every moment [2]. In this
work, the micro-magnetic testing is applied as a non-destructive technique to characterize the
micro-pitting-related wear on the tooth flanks of gears, since its progress leads to microstructural
changes correlated to the magnetic properties of the material. The results are compared with other
techniques like profilometry; X-ray diffraction; and light and scanning electron microscopy, including
electron backscatter diffraction analysis.
2. Materials and Methods
With the aim of the development of SHM-techniques, the focus of the present work is a
multi-technique characterization of the flanks of gear teeth subjected to different states of wear,
identified from 0 to 4, depending on different loading conditions. The investigation was performed
beginning with characterization of wear progress on the surface, using a group of non-destructive
techniques as profilometry via confocal white light interferometry, X-ray diffraction (XRD) and
micro-magnetic testing, followed by a microstructural characterization via light and scanning electron
microscopy (SEM). The micro-magnetic testing was applied for a depth-sensitive description of the
properties of ferromagnetic materials and verified by means of the electron backscatter diffraction
(EBSD) analysis, carried out on the cross-sections.
2.1. Wear Tests
In order to generate specimens from tooth flanks in different wear states, a specific test program
based on the micro-pitting test according to FVA (Forschungsvereinigung Antriebstechnik) information
sheet 54/7 [3] was performed on a standard FZG (Forschungsstelle für Zahnräder und Getriebebau)
gear test rig [4]. This test method was defined to primarily analyze the influence of the lubricant on
the formation of fatigue-related wear on the tooth flank.
The operating conditions including the loading, the circumferential speed and the macro and
micro geometry of the gear set were specified in a way that the contact between the surfaces of the tooth
is under mixed friction conditions. The standard FZG gear test rig with a center distance of 91.5 mm
consists of a test gear box containing the test gears and a strain gear box connected by couplings, as
can be seen in Figure 1. A constant torque was applied to the system by tensioning the two halves
of the load coupling at standstill. The test oil was injected into the tooth contact at a temperature of
90 ◦C with a flow rate of 2 l/min [5]. The gear set is made of 16MnCr5 (1.7131, SAE 5115) and the tooth
geometry complies with the standard-C according to FVA 54/7 [3].
Materials 2018, 11, 2290 3 of 17
Materials 2018, 11, x FOR PEER REVIEW  3 of 17 
 
 
(a) 
 
(b) 
Figure 1. FZG gear test rig: (a) photos; (b) schematic drawings. 
The test sequence defines four different load stages as outlined in Table 1. The first stage 
includes a short running-in at a pinion torque of 70 Nm and a second run with a pinion torque of 265 
Nm. Both runs consist of 1.5 × 105 load cycles. Stage two adds another 12 × 105, stage three 30 × 105 
and stage four 45 × 105 load cycles at a constant pinion torque of 265 Nm and a constant pinion speed 
of 2250 RPM. This test sequence was performed on two gear sets (1 and 2) whereas the test was 
always stopped after another load stage. Four sets of tooth flanks in different wear states (1–4) were 
generated. A synthetic industrial gear oil (ISO VG 100) was used throughout the entire test sequence. 
Table 1. Test sequence for each tooth flank [5]. 
Gear Set Flank Wear State 
Loading 
Pinion Torque 
(Nm) 
Hertzian Contact Stress 
at Pitch Point (MPa) 
Load 
Cycles 
(1 × 105) 
Total 
Load Cycles 
(1 × 105) 
1 
A 1 
70 795 1.5 
3 
265 1547 1.5 
B 2 
70 795 1.5 
15 265 1547 1.5 
265 1547 12 
2 
A 3 
70 795 1.5 
45 
265 1547 1.5 
265 1547 12 
265 1547 30 
B 4 
70 795 1.5 
90 
265 1547 1.5 
265 1547 12 
265 1547 30 
265 1547 45 
2.2. Wear Characterization Methodologies 
The areas of interest of micro-magnetic testing, microscopic analysis and micro-structural 
characterization of gears are shown in Figure 2. 
Figure 1. FZG gear test rig: (a) photos; (b) schematic drawings.
The t t s ence defines four different load stages as outlined i Table 1. The first stage includ s
a short running-i at a pinion torque f 70 Nm and a second ru with a pinion torque of 265 Nm.
Both runs consist of 1.5 × 105 load cycles. Stage two adds another 12 × 105, stage three 30 × 105 and
stage four 45 × 105 load cy les at constant pinion torque of 265 Nm and a constant pinion speed of
2250 RPM. This tes sequenc was performed on two gear s ts (1 and 2) whereas th tes was al ays
stopped after another load stage. Four sets of too h flanks in differe t wear states (1–4) were generated.
A synthetic industrial gear oil (ISO VG 100) was used throughout the entire est sequ nce.
Table 1. Test sequence for each tooth flank [5].
Gear Set Flank We r State
Loading
Pini n Torque
(Nm)
Hertzian Contact
Stress at Pitch
Point (MPa)
Load Cycles
(1× 105)
Total Load
Cycles (1× 105)
1
A 1
70 795 1.5
3265 1547 1.5
B 2
70 795 1.5
15265 1547 1.5
265 1547 12
2
A 3
70 795 1.5
45
265 1547 1.5
265 1547 12
265 1547 30
B 4
70 795 1.5
90
265 1547 1.5
265 1547 12
265 1547 30
265 1547 45
2.2. Wear Characterization Methodologies
The areas of interest of micro-magnetic testing, microscopic analysis and micro-structural
characterization of gears are shown in Figure 2.
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Figure 2. Areas of interest: (a) Three-dimensional scheme; (b) Cross-section; (c) Front view of the 
flank. CS: Cross-section; F: Flank; A: Used tooth root diameter; E: Tooth tip. 
2.2.1. Characterization of Wear Progress on the Surface 
In order to determine the fatigue-related wear on the tooth flank, the profile form deviation of 
the gears was determined by a Klingelnberg PNC65 CNC-controlled gear measuring machine 
(Klingelnberg AG, Zurich, Switzerland). The profile form deviation is defined as the difference 
between the worn flank and its initial state. The area of interest F1 is given in Figure 2. An autofocus 
measuring device, by Alicona Imaging GmbH (Raaba/Graz, Austria) is used to generate a 
microscopic image of the tooth flank, as is presented in Figure 3, in order to document the temporal 
development of the surface of the tooth flank. 
 
Figure 3. Tooth flank surface documentation of the pinion with an autofocus measuring device. 
A topographic characterization on the tooth flank was performed using a confocal white light 
microscope NanoFocus µSurf (NanoFocus AG, Oberhausen, Germany). The area of this inspection is 
defined in Figure 2 as F1 and it reaches from the tooth root (point A in Figure 2) to the tooth tip 
(point E in Figure 2). 
2.2.2. Microstructural Characterization by Light Microscope and Scanning Electron Microscope. 
A microstructural characterization of the wear progress of the teeth flank surface was 
performed by means of light microscopy and scanning electron microscopy (SEM). The inspection 
was focused on the area of the flank close to the tooth root, specified in Figure 2 as F2, using the light 
microscope Zeiss Axio Imager (Carl Zeiss AG, Oberkochen, Germany) and the SEM Tescan Mira 3 
XMU (TESCAN GmbH, Dortmund, Germany). A microstructural characterization of the 
cross-section area, defined as CS1 in Figure 2, was carried out in order to describe the wear progress 
on the surface and under it, in order to link these results with the micro-magnetic parameters. 
The EBSD was performed over the cross-section, specifically on the area marked as CS1 of the 
Figure 2, using the SEM Tescan Mira 3 XMU, equipped with a DigiView EBSD camera and the 
Team™ software of Edax Inc., (Weiterstadt, Germany). The OIM analysis™ software was used for 
the post-processing of the results. The specimens undergo metallographical preparation including 
cutting out, grinding and polishing using conventional suspensions (6, 3 and 1 µm). At a final step, 
i r s of interest: (a) Three-dimensional scheme; (b) Cross-section; (c) Front view of the flank.
CS: Cross-section; F: Flank; A: Used tooth r diameter; E: Tooth tip.
2.2.1. Characterization of Wear Progress on the Surface
In order to determine the fatigue-related wear on the tooth flank, the profile form deviation
of the gears was determined by a Klingelnberg PNC65 CNC-controlled gear measuring machine
(Klingelnberg AG, Zurich, Switzerland). The profile form deviation is defined as the difference
between the worn flank and its initial state. The area of interest F1 is given in Figure 2. An autofocus
measuring device, by Alicona Imaging GmbH (Raaba/Graz, Austria) is used to generate a microscopic
image of the tooth flank, as is presented in Figure 3, in order to document the temporal development
of the surface of the tooth flank.
Materials 2018, 11, x FOR PEER REVIEW  4 of 17 
 
 
Figure 2. Areas of interest: (a) Three-dimensional scheme; (b) Cross-section; (c) Front view of the 
flank. CS: Cross-section; F: Flank; A: Used tooth root diameter; E: Tooth tip. 
. . . t i i        
 r r to deter ine the fatigue-related wear on the tooth flank, the profile for  deviat on of 
the gears was det r ined by a Klingelnberg PNC65 CNC-control ed gear ri   
 , , ). The profile for  deviation is efi e  s   
   fl     .          .   
 device, by Alicona I aging G bH (Raaba/Graz, Austria) is us d to generate a 
icroscopic i age of the tooth flank, as is presented in Figure 3, in order o docu ent the te poral 
develop ent f t  surface of the tooth flank. 
 
Figure 3. Tooth flank surface documentation of the pinion with an autofocus measuring device. 
A topographic characterization on the tooth flank was perfor ed using a confocal white light 
icroscope NanoFocus µSurf (NanoFocus AG, Oberhausen, Ger any). The area of this inspection is 
defined in Figure 2 as F1 and it reaches fro  the tooth root (point A in Figure 2) to the tooth tip 
(point E in Figure 2). 
2.2.2. icrostructural Characterization by Light icroscope and Scanning Electron icroscope. 
A icrostructural characterization of the wear progress of the teeth flank surface was 
perfor ed by eans of light icroscopy and scanning electron icroscopy (SE ). The inspection 
was focused on the area of the flank close to the tooth root, specified in Figure 2 as F2, using the light 
icroscope Zeiss Axio I ager (Carl Zeiss AG, Oberkochen, Ger any) and the SE  Tescan ira 3 
X U (TESCAN G bH, Dort und, Ger any). A icrostructural characterization of the 
cross-section area, defined as CS1 in Figure 2, was carried out in order to describe the wear progress 
on the surface and under it, in order to link these results with the icro- agnetic para eters. 
The EBSD was perfor ed over the cross-section, specifically on the area arked as CS1 of the 
Figure 2, using the SE  Tescan ira 3 X U, equipped with a DigiView EBSD ca era and the 
Tea  software of Edax Inc., ( eiterstadt, Ger any). The OI  analysis  software was used for 
the post-processing of the results. The speci ens undergo etallographical preparation including 
cutting out, grinding and polishing using conventional suspensions (6, 3 and 1 µ ). At a final step, 
Figure 3. Toot fla s rf c t ti f t i i
i t ri ti t t fl i l i li
i a oFocus µSurf (NanoFocus AG, Oberhausen, Germany). The area of this inspection
is defined in Figure 2 as F1 and it reaches from the t oth r ot (point A in Figure 2) to t e t t i
i t i i .
. . . Mi t t l t i ti i t Mi i l t Mi
microstructural char cterization of the w ar progress of the teeth flank surface was performed
by means of light microscopy and scanning electro micros opy (SEM). The inspection was focused
on the area of the fl nk close to the to th r ot, specified in Figure 2 as F2, sing the light microscope
Zeiss Axio Imager (Carl Zeiss AG, Oberkochen, Germany) a d the SEM Tescan Mira 3 XMU (TESCAN
GmbH, Dortmund, Germany). A microstructural characterizati n of the cross-section area, defined as
CS1 in Figure 2, was carried out in order to describe the wear progress on the surface and under it,
i order to link these results with the micro-magnetic parameters.
S was performed over the cros -section, specifically on the rea marked as CS1 of
the Figure 2, using the SEM Tescan Mira 3 XMU, equi ped with a DigiView EBSD camera
m™ ., W it , m . M l i ™
Materials 2018, 11, 2290 5 of 17
the post-processing of the results. The specimens undergo metallographical preparation including
cutting out, grinding and polishing using conventional suspensions (6, 3 and 1 µm). At a final step,
the surface was polished with a colloidal SiO2 suspension (oxide polishing suspension, OPS). The EBSD
measurements were performed with the table tilted at 70◦, using an electron beam energy of 25 to
30 kV, working distance circa 20 mm and magnification of 2500×, with a final inspection area of
20 µm × 20 µm.
2.2.3. X-ray Diffraction (XRD)
Residual stresses and the amount of retained austenite were measured by means of X-ray
diffraction (XRD) using a portable X-ray device type µ-X360 of Pulstec Industrial Co., Ltd. (Nakagawa,
Japan). The measurements were performed on the area of interest F2 from Figure 2. Based on the
cosα-method, introduced by Taira et al. [6] and further developed by Sasaki and Hirose [7], the device
contains an image plate acting as a two-dimensional detector that enables the capturing of the entire
Debye-ring at once during a single measurement. Further methodological details are available in
References [8,9].
The measurements were conducted using CrKα-radiation with a wavelength of 2.29 Å, an X-ray
tube voltage of 30 kV and a current of 1 mA, focused by a Φ = 0.5 mm collimator. Macroscopically
determined elastic constants were given as E = 210 GPa and ν = 0.3. The lattice parameter was set to
be 2.8664 Å for all samples. In consideration of the target material, the diffraction line h, k, l (211),
the corresponding 2θ-diffraction angle of 156.3◦ and an x-ray incidence angle of ψ0 = 35◦ were chosen
during the determination of residual stresses, which was adjusted to ψ0 = 18◦ for the measurement of
retained austenite. The samples were positioned at a distance of 20 ± 1 mm, determined by means of
the automatically measured 2θ-angle, for the measurement of retained austenite and the identification
of residual stresses.
The relative amount of retained austenite was calculated based on the area ratio of the detected
austenitic peak profile, with regards to the total amount of both martensitic and austenitic share
according to the detected peak intensities, and the corresponding FWHM-values (full width at half
maximum), detected at half peak-maximum, such as the cosα-angle.
2.2.4. Micro-Magnetic Testing
The micro-magnetic tests, based on the cyclic magnetization of a ferromagnetic material, were
carried out on the area of interest F2, shown in Figure 2. The applied magnetic field strength H,
the magnetic flux density B, also known as magnetic induction, and the magnetization M which is the
vector sum of the magnetic moments of all the atoms of the material in a small volume, are related to
each other with the magnetic constant or permeability of free space µ0, through Equation (1) [10].
B = µ0(H + M), (1)
The magnetization curves obtained with the measuring equipment, describe the variation of the
magnetic flux density B or the magnetization M, with respect to the applied magnetic field strength
H. These curves were taken from the first quadrant of the hysteresis loop, as presented in Figure 4.
From a demagnetized state in B = H = 0, the magnetization increases until a saturation point S. At this
point, the magnetization is no longer reversible, and therefore, if the magnetic field is decreased,
the magnetization will come back not along the initial line, but describing a new one along S-R.
In the point R, at H = 0, the magnetic flux density B reaches a point called remanence or residual
magnetization. A further increase of the magnetization will place the magnetization flux density B
at a zero value, where point C can be found, known as the coercive force or coercivity Hc. A further
decrease of magnetization leads the curve to the negative part of the loop, reaching a saturation point
and completing the hysteresis loop without crossing the initial null state [11].
Materials 2018, 11, 2290 6 of 17
Materials 2018, 11, x FOR PEER REVIEW  6 of 17 
 
 
Figure 4. Scheme of hysteresis loop with main parameters of micro-magnetic analysis. 
Ferromagnetic materials are divided into different magnetic domains, which are spontaneously 
magnetized regions separated by domain walls. The magnetization vectors in these regions are 
oriented in different directions, but their sum is zero for the whole material, and the leakage of 
magnetic flux into the surrounding air space is reduced [12]. During the magnetization, the change 
of the flux density B proceeds by rotation of the magnetization and by the motion of the domain 
walls, which can find obstacles during the increment of the magnetic field strength H. After breaking 
these obstacles away, sudden jumps occur, called Barkhausen jumps. These discontinuous changes 
of B, induce voltage peaks that can be detected as Barkhausen noise, shown in the Figure 4, and these 
are used as one measuring strategy during the present study. Another important methodology is the 
incremental permeability Δµ, also illustrated in Figure 4, obtained by the ratio of the flux density 
swing ΔB to the corresponding field strength excursion ΔH [10]. 
The micro-magnetic testing was carried out by means of two devices. The 3MA II, 
manufactured by Fraunhofer IZPF (Saarbrücken, Germany), allows the analysis of harmonics (HA), 
Barkhausen noise (BN), incremental permeability (IP) and eddy current signals (EC). In BN analysis, 
the detected signals enable the creation of the BN profile curve, illustrated in Figure 4, showing the 
BN amplitude as a function of the magnetic field H, namely M(H). From this curve, the obtained 
parameters were the maximum amplitude Mmax and the magnetization amplitude H at the point, 
which is the coercivity Hc, reported in BN analysis as Hcm. On the other hand, the IP curve, presented 
also in Figure 4, resulting from the superposition of two alternating magnetic fields, with differences 
in frequency and amplitude of magnetization (fField1 >> fField2 and HField1 << HField2). In this way, small 
hysteresis loops are created, whose slopes represent the incremental permeability Δµ and their 
projection over the magnetic field strength H, creates the profile curve µ(H), as presented in Figure 
4. The coercivity Hc will be the magnetization amplitude H at the maximum permeability, µ. This is 
reported as Hcµ and is the coercive magnetic field acquired by IP analysis [13]. 
The other applied equipment was the FracDim manufactured by Fraunhofer IKTS (Dresden, 
Germany), suitable for the analysis of BN and harmonics, with the particularity of allowing the 
changing of filter bandpass, in order to determine the microstructure-sensitive magnetization in 
dependence of depth. With this device the maximum amplitude of the BN profile curve Mmax was 
obtained for different ranges of bandpass frequencies. FracDim does not work directly with the 
magnetic field H, but with a correlated parameter called magnetic flow, Phi. Therefore, the BN 
envelope, M (Phi) will exhibit the maximum amplitude Mmax at Phicm, which is a parameter directly 
correlated with the coercive magnetic field Hc [14]. 
To assess the properties at different depths, the micro-magnetic tests were carried out using 
different ranges of bandpass frequencies. The electromagnetic signals of certain frequency pass 
through the electrically conducting material and are attenuated by eddy current damping, in a way 
that the amplitude of the field at a skin depth, δ, decays to 1/e (around 37%) of its value at the surface 
[15]. With this concept, it is possible to compute the skin depth effect using Equation (2), which has 
been widely used in many works [16,17]. 
δ = ට ஡஠ ୤ ஜ, (2)
Figure 4. Sche e of hysteresis loop ith ain para eters of icro- agnetic analysis.
ti regions epar ted by domain walls. The magnetization vectors in these regions are oriented
in diff rent directions, but heir sum is ze o for the whole mat rial, and the le kage of magnetic flux
into the surrounding air space is reduced [12]. Du ing the magnetization, the change of the flux density
B proceeds by ro ation of the magnetization and by the motion of the domain walls, which can find
obstacles during the increment of the magnetic field strength H. After breaking these obstacles way,
sudden jumps occur, called Barkhausen jumps. These disco tinuous c anges of B, induce voltage
peaks that can be det cted as B rkhausen noise, shown in the Figure 4, and these are used as on
m asuring strategy during he present study. Another important methodology is e incremental
permeability ∆µ, also illustrated in Figure 4, obtained by the rat o of the flux density swing ∆B to the
corresponding field strength excursion ∆H [10].
micro-magnetic tes ing was c rried out by means of two devices. The 3MA II, manufactured
by Fraunhofer IZPF (Saarbrücken, Germany), allows the an ysis of harmonics (HA), Barkhausen
noise (BN), i cremental permeability (IP) and eddy current signals (EC). In BN analysis, the detected
signals enable the creation of the BN profile curve, illustrated in Fig re 4, showin the BN amplitud
as a funct on of the magnetic field H, n mely M(H). From this curve, the obtained pa ame ers were the
maxi um amplitud Mmax and the magn tization amplitude H at the point, which is the co rcivity
Hc, reported in BN analysis as Hcm. On the other hand, the IP curve, presented also in Figure 4,
re ulting from the perposition of two alternati g magnetic fields, with difference in frequency and
amplit de of magnetization (fField1 >> fField2 a d HField1 << HField2). In this way, small hysteresis loops
are created, whose slopes represent the incremental permeability ∆µ and their projection over the
magnetic field s rength H, creates the profile cu ve µ(H), as presented in Figure 4. The coercivity Hc
will b th magnetization amplitude H at the m ximum permeability, µ. This is reported as Hcµ and i
the coercive mag etic field acquir d by IP analysis [13].
,
, ,
i fil , i t t r i t icr str t - i i i i i
. i i i t i a lit f the B profile curve Mmax
i i f ba s freq e ci . i i l i
i fi l , it a correlate para eter calle agnetic flo , Phi. ,
l , ( i) ill ex i it the axi u amplitude Mmax t icm, i i t i tl
l t it t i ti fiel c .
s t r rti t iff r t t , t i ti t t i t i
i t f ba fre e ci . l t ti i l t i
t t l t i ll ti t i l tt t t i , i
t t t a plitude of the field t a skin depth, δ, decays to 1/e (around 37%) of its value at th
Materials 2018, 11, 2290 7 of 17
surface [15]. With this concept, it is possible to compute the skin depth effect using Equation (2),
which has been widely used in many works [16,17].
δ =
√
ρ
pi f µ
, (2)
where δ is the skin depth in mm, ρ is the electrical resistivity in Ω·mm2/m, f is the filter bandpass
frequency in Hz, and µ is the magnetic permeability in V·s/A·m.
3. Results
3.1. Wear Progress on the Surface of Gear Wheels Teeth
The following results were obtained from the non-destructive and destructive tests performed
on the gear teeth, between the points A and E along the flank F, as defined in Figure 2. In Figure 5,
the results of the profile form deviation measurements are given for a single tooth of each gear flank.
In the wear state 2, a first local material removal starting at the tooth root with a depth of 4 µm appears.
The maximum amount of wear continuously increases to 12 µm in wear state 4. Additionally, the local
wear also grows to the pitch point.
aterials 2018, 11, x FOR PEER REVIEW  7 of 17 
 
where δ is the skin depth in mm, ρ is the electrical resistivity in Ω·mm2/m, f is the filter bandpass 
frequency in Hz, and μ is the magnetic permeability in V·s/A·m. 
3. Results 
3.1. Wear Progress on the Surface of Gear Wheels Teeth 
The following results were obtained from the non-destructive and destructive tests performed 
on the gear teeth, between the poi ts A and E along the flank F, as defined in Figure 2. In Figure 5, 
the results of the profile form deviation measurements are given for a single tooth of each gear flank. 
In the wear state 2, a first local material removal starting at the tooth root with a depth of 4 µm 
appears. The maximum amount of wear continuously increases to 12 µm in wear state 4. 
Additionally, the local wear also grows to the pitch point. 
Figure 6 shows the microscopic images of tooth surfaces in all different wear states taken on 
inspection areas of the gear teeth defined in Figure 2 as F1. In the initial state, the grinding grooves 
and their orientation vertically to the circumferential rolling and sliding direction are clearly visible. 
With an increasing number of load cycles, the surface characteristics change significantly. Starting at 
the tooth root, the surface is smoothed towards the pitch point. Some microscopic break-outs on the 
tooth flank are visible but they are smeared up by the surrounding material. 
 
Figure 5. Profile form deviation of the gear teeth for the different wear conditions. 
profile form deviation [µm]
A
E
-5    0     5   10   15
1 2 3 4
-5    0     5   10   15 -5    0     5   10   15 -5    0     5   10   15
wear state:
Figure 5. Profile form deviation of the gear teeth for the different wear conditions.
Figure 6 shows the microscopic images of tooth surfaces in all different wear states taken on
inspection areas of the gear teeth defined in Figure 2 as F1. In the initial state, the grinding grooves
and their orientation vertically to the circumferential rolling and sliding direction are clearly visible.
With an increasing number of load cycles, the surface characteristics change significantly. Starting at
the tooth root, the surface is smoothed towards the pitch point. Some microscopic break-outs on the
tooth flank are visible but they are smeared up by the surrounding material.
Materials 2018, 11, 2290 8 of 17
Materials 2018, 11, x FOR PEER REVIEW  8 of 17 
 
 
Figure 6. Surface development of gear teeth for the different wear conditions. 
Figure 7 shows the surface topography of exemplary areas of 200 µm × 200 µm of the teeth, 
taken in the area F1 of Figure 2, for the initial ground surface and the different wear states. The 
upper and lower envelope profiles of surface topography describe the wear progress in dependence 
of loading states. By means of upper envelope profile, the flattening of the grinding marks with the 
formation of running tread surface is clearly recognizable. The simultaneous process of occurrence 
of micro-pitting is easy to distinguish on the lower envelope profile. 
Figure 6. Surface development of gear teeth for the different wear conditions.
7 shows the surface topography of exemplary areas of 200 µm × 200 µm of the teeth, aken
in the area F1 of Figure 2, for the initial ground su face and the different wear states. The upper and
low r e ve pe profiles of surfac t pog aphy desc ibe the wear progress in depende ce of loading
states. By me n of upper envelo e profil , th flattening of the gri ding marks with the formation of
running tread surface is clearly re ognizable. The simultaneous process of occurren of micro-pitting
is easy to distinguish on the lower envelope profile.
Materials 2018, 11, 2290 9 of 17
Materials 2018, 11, x FOR PEER REVIEW  9 of 17 
 
 
Figure 7. Surface topography of the gear teeth for the different wear conditions. 
3.2. Microstructural Characterization 
The results of microscopy obtained by means of light microscope and scanning electron 
microscope are presented in Figure 8.  
According to the specified areas of interest CS1 and F2 in Figure 2, the surface inspection was 
performed on the direct contact zone of the flanks, close to the tooth root. The evolution of the 
surface in each wear condition is consistent with the results presented in Figure 6. The initial state of 
the gear wheels teeth surface shows the grinding marks of the fabrication process. As it was revealed 
by means of confocal microscopy, after a short loading time in wear condition 1, many of the 
grinding marks disappeared and the surface became flatter forming running treads. Some 2–3 
µm-deep cracks are already recognizable in the cross-section at this wear state. In the following wear 
conditions, simultaneously to the formation of treads, spalls of micro-pitting, recognizable as grey 
areas, appear, and their density and size grow with the wear progress. With an increase of loading 
cycles on the teeth, the enforced apparition and increment of size and depth of cracks is 
recognizable. For instance, in the wear condition 2, the crack size increases up to ca. 6 µm and 
reaches in the two final wear states approx. 8 µm. The material which was broken due to surface 
fatigue was shredded and smeared up in the spalls, which prevents an additional abrasion and 
slows down the wear progress at later wear states. 
. rf t
3.2. Microstructural Characterization
The results of microscopy obtained by means of light microscope and scanning electron
microscope are presented in Figure 8.
According to the specified areas of interest CS1 and F2 in Figure 2, the surface inspection was
performed on the direct contact zone of the flanks, close to the tooth root. The evolution of the surface
in each wear condition is consistent with the results presented in Figure 6. The initial state of the
gear wheels teeth surface shows the grinding marks of the fabrication process. As it was revealed by
means of confocal microscopy, after a short loading time in wear condition 1, many of the grinding
marks disappeared and the surface became flatter forming running treads. Some 2–3 µm-deep cracks
are already recognizable in the cross-section at this wear state. In the following wear conditions,
simultaneously to the formation of treads, spalls of micro-pitting, recognizable as grey areas, appear,
and their density and size grow with the wear progress. With an increase of loading cycles on the
teeth, the enforced apparition and increment of size and depth of cracks is recognizable. For instance,
in the wear condition 2, the crack size increases up to ca. 6 µm and reaches in the two final wear states
approx. 8 µm. The material which was broken due to surface fatigue was shredded and smeared
up in the spalls, which prevents an additional abrasion and slows down the wear progress at later
wear states.
Materials 2018, 11, 2290 10 of 17
Materials 2018, 11, x FOR PEER REVIEW  10 of 17 
 
In
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ea
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 (a) (b) (c) 
Figure 8. Microstructural characterization of wear in gear teeth by means of: (a) light microscope 
(200×) in area F2; (b) SEM on the surface (2000×) in area F2; (c) SEM on cross-section (2000×) in area 
CS1. 
3.3. Electron Backscatter Diffraction 
The results of the electron backscatter diffraction (EBSD) measurements representing an 
integral analysis of the microstructure up to 20 µm under the surface are summarized in Figure 9. 
Figure 8. Microstructural characterization of wear in gear teeth by means of: (a) light microscope
(200×) in area F2; (b) SEM on the surface (2000×) in area F2; (c) SEM on cross-section (2000×) in
area CS1.
3.3. Electron Backscatter Diffraction
The results of the electron backscatter diffraction (EBSD) measurements representing an integral
analysis of the microstructure up to 20 µm under the surface are summarized in Figure 9.
Materials 2018, 11, 2290 11 of 17
Materials 2018, 11, x FOR PEER REVIEW  11 of 17 
 
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 (a) (b) (c) (d) 
Figure 9. EBSD on cross-sections of gear teeth (surface is shown at the bottom): (a) Fit map; (b) 
Inverse Pole Figure (IPF) map; (c) Phase map: green: bcc-lattice (martensite), red: fcc-lattice 
(austenite); (d) Kernel Average Misorientation (KAM) respect the first neighbor: blue: minimum 
misorientation, red: maximum misorientation. 
The dark areas in Fit-maps (Figure 9a) indicate the distorted crystal lattice, and therefore, the 
grain boundaries and areas with high deformation become well recognizable. Due to its strongly 
distorted bcc-lattice, the former retained austenite transformed into martensite can be indicated by 
dark areas in Fit-maps. The Inverse Pole Figure (IPF)-map (Figure 9b) is a representation of the 
different orientations of the crystal lattice, and the Phase-map (Figure 9c) indicates the phases; 
therefore, it is possible to characterize the austenite amount and its transformation in dependence of 
wear progress. The Phase-map reveals also the quantitative transformation of retained austenite into 
martensite, given as a graph in Figure 10. The Kernel Average Misorientation (KAM) (Figure 9d) 
r . on cros -sections of gear teeth (surface is shown at the bottom): (a) Fit map; (b) Inverse
Pol Figure (IPF) map; (c) Phase map: green: bcc-lattice (mar ensite), ed: fcc-lattice (austenite);
d) Kern l Average Misori ntation (KAM) respect the fi st neighbor: blue: minimum misorientation,
red: maximum misorientation.
The dark areas in Fit-maps (Figure 9a) indicate the distorted crystal lattice, and therefore, the grain
bou daries and areas with high deformati n bec me well recognizable. Due to its str ngly distorted
bcc-lattice, the former retained auste ite transformed into artensite can be indicated by dark areas
in Fit-m ps. The Inverse Pole Figure (IPF)-map ( igure 9b) is a representation of the differ nt
orientations of the crystal lattice, and the Ph se-map (Figure 9c) indicates the phases; t erefore, it is
possible to characterize the usten te amount a d its transforma ion i depende ce of w ar progress.
Materials 2018, 11, 2290 12 of 17
The Phase-map reveals also the quantitative transformation of retained austenite into martensite, given
as a graph in Figure 10. The Kernel Average Misorientation (KAM) (Figure 9d) quantifies the average
misorientation around the measurement points of the maps, with respect to the first nearest neighbour.
As expected, bigger misorientations are present at the grain boundaries equivalent to the information
presented in Fit-maps. No correlation of wear progress and increase of deformation were detected.
Materials 2018, 11, x FOR PEER REVIEW  12 of 17 
 
quantifies the average misorientation around the measurement points of the maps, with respect to 
the first nearest neighbour. As expected, bigger misorientations are present at the grain boundaries 
equivalent to the information presented in Fit-maps. No correlation of wear progress and incre se of 
d formation were detected. 
 
Figure 10. Austenite fraction of different wear conditions of gear teeth obtained by EBSD. 
3.4. X-ray Diffraction 
As illustrated in Figure 11 and summarized in Table 2, the amount of retained austenite is the 
highest for the initial condition and considerably lower for all conditions after wear testing. 
Table 2. Residual stresses and amount of retained austenite, measured by x-ray diffraction analysis 
for the different wear conditions. 
Wear Condition Stress, σ (MPa) Retained Austenite (Vol. %) 
0 −447 ± 30 16.0 ± 0.2 
1 −496 ± 9 8.5 ± 0.2 
2 −435 ± 5 8.8 ± 0.5 
3 −490 ± 9 7.2 ± 0.3 
4 −517 ± 4 7.1 ± 0.3 
 
Figure 11. Residual stresses and amount of retained austenite, measured by x-ray diffraction analysis 
for the different wear conditions. 
However, the amount of retained austenite is predominantly decreasing with increasing 
amounts of wear, as it drops from an initial amount of 16% down to 7% for wear condition 4. The 
residual stress analysis revealed that the analyzed positions have negative residual stresses in all 
conditions. Generally, the compressive stresses tend to further decrease from condition 0 to 4 (from 
−447 MPa to −517 MPa). 
3.5. Micro-Magnetic Testing 
i r 10. t it fr ti f iffere t ear conditions of gear teeth obtained by EBSD.
3.4. X-ray Diffraction
As illustrated in Figure 11 and summarized in Table 2, the amount of retained austenite is the
highest for the initial condition and considerably lower for all conditions after wear testing.
Materials 2018, 11, x FOR PEER REVIEW  12 of 17 
 
quantifies the average misorientation around the measurement points of the maps, with respect to 
the first nearest neighbour. As expected, bigger misorientations are present at the grain boundaries 
equivalent to the information presented in Fit-maps. No correlation of wear progress and increase of 
deformation were detected. 
 
Figure 10. Austenite fraction of different wear conditions of gear teeth obtained by EBSD. 
3.4. X-ray Diffraction 
As illustrated in Figure 11 and summarized in Table 2, the amount of retained austenite is the 
highest for the initial condition and considerably lower for all conditions after wear testing. 
Table 2. Residual stresses and amount of retained austenite, measured by x-ray diffraction analysis 
for the different wear conditions. 
Wear Condition Stress, σ (MPa) Retained Austenite (Vol. %) 
0 −447 ± 30 16.0 ± 0.2 
1 −496 ± 9 8.5 ± 0.2 
2 −435 ± 5 8.8 ± 0.5 
3 −490 ± 9 7.2 ± 0.3 
4 −517 ± 4 7.1 ± 0.3 
 
Figure 11. Residual stresses and amount of retained austenite, measured by x-ray diffraction analysis 
for the different wear conditions. 
However, the amount of retained austenite is predominantly decreasing with increasing 
amounts of wear, as it drops from an initial amount of 16% down to 7% for wear condition 4. The 
residual stress analysis revealed that the analyzed positions have negative residual stresses in all 
conditions. Generally, the compressive stresses tend to further decrease from condition 0 to 4 (from 
−447 MPa to −517 MPa). 
3.5. Micro-Magnetic Testing 
t r c iti s.
Table 2. Residual stresses and amount of retained austenite, measured by x-ray diffraction analysis for
the different wear conditions.
Wear Condition Str ss, σ (MPa) Retained Austenite (Vol. %)
0 −447 ± 30 16.0 ± 0.2
1 −496 ± 9 8.5 ± 0.2
2 −435 ± 5 8.8 ± 0.5
3 −490 ± 9 7.2 ± 0.3
4 −517 ± 4 7.1 ± 0.3
o ever, the amount of retained austenite is predominantly decreasing with increasing amounts
of wear, as it drops from an initial mount of 16% down to 7% for wear c ndition 4. The residual
stress analysis revealed that the analyzed positions have negative residual stresses in all conditions.
Ge erally, the compressive stresses tend to further decrease from condition 0 to 4 (from −447 MPa to
51 ).
Materials 2018, 11, 2290 13 of 17
3.5. Micro-Magnetic Testing
The results of the micro-magnetic investigation are reported in Figure 12. In Figure 12a,
the maximum amplitudes of the Barkhausen noise curve, Mmax and the coercive magnetic force,
and Hcµ, obtained by the incremental permeability profile, are shown. These two parameters are
compared with the progress of the profile form deviation ∆d. The deviations reported in Figure 12
correspond to the average of measurements on three gears teeth, performed according to Figure 5.
It can be seen that the value of Mmax increases proportionally to wear progress, shown in the profile
deviation. Inversely, the coercivity parameter Hcµ presents a linear decrease with the augment of
the wear.
Materials 2018, 11, x FOR PEER REVIEW  13 of 17 
 
The results of the micro-magnetic investigation are reported in Figure 12. In Figure 12a, the 
maximum amplitudes of the Barkhausen noise curve, Mmax and the coercive magnetic force, and Hcµ, 
obtained by the incremental permeability profile, are shown. These two parameters are compared 
with the progress of the profile form deviation Δd. The deviations reported in Figure 12 correspond 
to the average of measurements on three gears teeth, performed according to Figure 5. It can be seen 
that the value of Mmax increases proportionally to wear progress, shown in the profile deviation. 
Inversely, the coercivity parameter Hcµ presents a linear decrease with the augment of the wear. 
 
(a) 
 
(b) 
Figure 12. Results of micro-magnetic testing: (a) Mmax and Hcµ by BN and IP, respectively, using 
3MAII; (b) Hcm and Phicm by BN-analysis using 3MAII and FracDim, respectively. 
Another result of the micro-magnetic investigation is that the coercive magnetic force obtained 
by the Barkhausen noise profile curve Hcm, correlates with the parameter Phicm. The development of 
these parameters, presented in Figure 12b, is phenomenollogically similar to changes of residual 
stresses and retained austenite, obtained by XRD analysis (Figure 11).  
Using different filter bandpass frequencies, the results of Mmax were obtained and reported in 
Figure 13a for the different wear states. The behaviour of Mmax for each filter bandpass frequency is 
consistent with the results presented in Figure 12a, presenting an incremental development for 
higher loading cycles. In each individual wear state, it can be seen that increased Mmax values are 
registered for higher ranges of bandpass frequencies, which demonstrates that the highest wear state 
is on the surface and it diminishes when the depth increases. 
 
(a) 
 
(b) 
Figure 13. (a) Maximum amplitude of the BN profile curve for different filter bandpass frequencies, 
using FracDim; (b) Correlation of bandpass frequencies and depth, calculated based on the equation 
for skin effect. 
To establish the correlation between skin depth and the filter bandpass frequency, Equation (2) 
was applied. For the material of the gear teeth, 16Mn5Cr, the electrical resistivity given in data 
sheets, is 0.16 Ω·mm2/m. The magnetic permeability was measured using Incremental Permeability, 
i re 12. s lt of icro- agnetic testing: ( ) by , using
II; ( ) c by BN-analysis using 3 A I and FracDi , respectively.
Another result of the icro- agnetic investigation is that the coercive agnetic force obtained
by the Barkhausen noise profile curve c , correlates with the parameter Phicm. The development
of these parameters, presented in Figure 12b, is pheno enollogically si ilar to changes of residual
stresses and retained austenite, obtained by XRD analysis (Figure 11).
Using different filter bandpass frequencies, the results of Mmax ere obtained and reported in
Figure 13a for the different wear states. The behaviour of Mmax for each filter bandpass frequency is
consistent with the results presented in Figure 12a, presenting an incremental development for higher
loading cycles. In each individual wear state, it can be seen that increased Mmax values are registered
for higher ranges of bandpass frequencies, which demonstrates that the highest wear state is on the
surface and it diminishes when the depth increases.
aterials 2018, 11,    I   13 f 17 
 
 r lt  f t  i r - ti  i ti ti  r  r rt  i  i r  . I  i r  , t  
i  lit  f t  r  i  r , ax  t  r i  ti  f r ,  cµ, 
t i   t  i r t l r ilit  r fil , r  .  t  r t r  r  r  
it  t  r r  f t  r fil  f r  i ti  .  i ti  r rt  i  i r   rr  
t  t  r  f r t   t r  r  t t , rf r  r i  t  i r  . It    
t t t  l  f ax i r  r rti ll  t  r r r ,  i  t  r fil  i ti . 
I r l , t  r i it  r t r cµ r t   li r r  it  t  t f t  r. 
 
( ) 
 
( ) 
i r  . s lts f icr - tic t sti : ( ) ax  cµ    I , r s cti l , si  
I; ( ) c   ic   - l sis si  II  i ,  
t r r lt f t  i r - ti  i ti ti  i  t t t  r i  ti  f r  t i  
 t  r  i  r fil  r  c , rr l t  it  t  r t r ic .  l t f 
t  r t r , r t  i  i r  , i  ll i ll  i il r t   f r i l 
tr   r t i  t it , t i    l i  ( i r  ).  
i  iff r t filt r  fr i , t  r lt  f ax r  t i   r rt  i  
i r   f r t  iff r t r t t .  i r f ax f r  filt r  fr  i  
i t t it  t  r lt  r t  i  i r  , r ti   i r t l l t f r 
i r l i  l . I   i i i l r t t , it    t t i r  ax l  r  
r i t r  f r i r r  f  fr i , i  tr t  t t t  i t r t t  
i   t  rf   it i i i   t  t  i r . 
 
( ) 
 
( ) 
i r  . ( ) i  lit  f t   r fil  c r  f r iff r t filt r ss fr ci s, 
si  r c i ; ( ) rr l ti  f ss fr ci s  t , c lc l t  s   t  ti  
f r s i  ff ct. 
 t li  t  rr l ti  t  i  t   t  filt r  fr , ti  ( ) 
 li . r t  t ri l f t  r t t , r, t  l tri l r i ti it  i  i  t  
t , i  .  · 2/ .  ti  r ilit   r  i  I r t l r ilit , 
Fig re 13. (a) axi a lit e of t e rofile c r e for iffere t filter a ass fre e cies,
si rac i ; ( ) rrelati f a ass fre e cies a e t , calc late ase t e e ati
f r s i effect.
Materials 2018, 11, 2290 14 of 17
To establish the correlation between skin depth and the filter bandpass frequency, Equation (2)
was applied. For the material of the gear teeth, 16Mn5Cr, the electrical resistivity given in data sheets,
is 0.16Ω·mm2/m. The magnetic permeability was measured using Incremental Permeability, since this
property is not constant but changes with the increase of the magnetization amplitude. Therefore the
magnetic permeability was measured at a magnetization amplitude of 50 A/cm, for each wear state and
calculated with 0.019 V·s/A·m as an average permeability. Based on this estimation, the approximated
correlation of depth range, depending on the filter bandpass frequency, was calculated. The resulting
curve given in Figure 13b illustrates that the higher the filter bandpass frequency, the closer to the
surface is the analysis.
4. Discussion
4.1. Surface Investigation
As the contact situation was chosen to be under severe mixed friction conditions, the material
removal starting at the tooth root and propagating towards the pitch point is to be expected,
as illustrated in Figure 5. The mechanisms leading to the wear-related fatigue are well publicized in
References [18–20]. As the matching tip edge of the driven gear gets in contact with the driving pinion,
the local Hertzian pressure exceeds the nominal pressure at the pitch point of 1.5 GPa and the gliding
speed is at its negative maximum. Therefore, the induced shear stresses at the tooth surface initiate
first cracks at the asperities of the grinding grooves which propagate with a length of a few µm against
the direction of the thrust in the depth of the material. Under further loading, the cracks crosslink and
single micrometer-sized wear particles break off (micro-pitting) at stochastically distributed points
from the affected surface area. This continuous process leads to a material removal of the weakened
tooth flank areas. Nevertheless, the microscopic images in Figure 6 underline the presence of a certain
additive package in the base oil. Under the test conditions, a mineral base oil with no additives (e.g.,
anti-wear, extreme pressure) leads to a tooth surface almost entirely affected with micro pitting and
a bigger local material removal. However, the used synthetic industrial gear oil almost prevents the
formation of microscopic break outs as only a few are visible on the surface in wear state 4, as can be
seen in Figure 6 [21].
4.2. Microstructural Characterization
The microscopic analysis by means of light and scanning electron microscope, presented in
Figure 8, describe the evolution of wear progress on the contact surface. The initial state is the
characteristic surface finishing for these components after manufacturing, where some striations can
be noticed along the grinding direction. No cracks were indicated in cross-sections, but the surface
imperfections are susceptible areas for crack initiation after 3 × 105 cycles of load. On the subsequent
wear states, due to the strain gradient during the different load conditions, so-called “frosted” areas
appear, as well as the micro-spalling associated with the pitting, according to Reference [22]. The size
and amount of spalls increase under higher load cycles, as well as the size and amount of cracks.
These results are consistent with the profile form deviation (Figure 5) and the topography (Figure 7)
investigations of the surfaces. The changes in the profile geometry can be explained and evidenced
from a microscopical point of view as a sum of the before described defects over the whole surface.
The amount of retained austenite was measured by means of both X-ray diffraction (Figure 11)
and EBSD-analysis (Figure 9). Due to the high carbon content after heat treatment (including case
hardening) the microstructure consists of tempered martensite with approximately 16 % retained
austenite. During wear testing the initial content of retained austenite is reduced to approximately
3–7%. This indicates a mechanically-induced transformation of retained austenite to martensite by
cyclic stresses and induced strains during wear testing. As it was shown due to the combination of
X-ray and EBSD techniques, the transformation of austenite to martensite occurs in a first step in the
upper layer close to the surface. The martensitic transformation in underlying layers follows stepwise
Materials 2018, 11, 2290 15 of 17
by a continuous increase of loading cycles. No severe plastic deformation in neighbor grains was
detected by EBSD in underlying areas, as reported in KAM-maps result (Figure 9d), indicating the
prevalence of stress-induced mechanisms of martensitic transformation. The transformation from
austenite to martensite leads to an increase in volume, which results in the rise of compression stress
and might have a positive effect on the wear behavior. In References [23,24], it was shown that
retained austenite can have a beneficial effect on wear and fatigue behavior of steel and cast iron.
However, the effect of retained austenite on the wear behavior is controversial and depends on the
actual tribological system [25].
As mentioned above, the cyclic loading also leads to a rearrangement of residual stresses in the
material. After heat treatment (quenching with martensitic phase transformation) the analyzed surface
region (few µm depth) has high compressive stresses that tends to further decrease during cyclic
loading. The initial residual stress state can highly influence the deformation behavior since there
is a superimposition with the contact stresses during wear testing. Generally, the further reduction
of residual stresses can be attributed to accumulation of plastic strain, transformation of retained
austenite and damage processes. In general, residual stresses can also reduce and suppress crack
initiation and propagation.
4.3. Micro-Magnetic Testing
The microstructural investigations with the aim to evaluate the micro-magnetic analysis show
good correlation between parameters such as the maximum amplitude of the Barkhausen noise curve
Mmax, significantly increasing by the wear progress and corresponding to the profile deviation ∆d,
as well as the arising and growing of cracks. Simultaneously, the trend of coercive magnetic field Hcµ,
acquired by incremental permeability, presents a linear decrease, since Mmax and the coercive field
force Hc are opposed to each other [13]. The evolution of Mmax and Hcµ helps to estimate the degree
of deformation and surface damage done to the wear, since the microstructural changes affect the
response of the magnetic domains. These results agree with previous works, where the micro-magnetic
parameter Mmax, increases linearly with the raise of the engineering stress [26–29]. A sudden jump in
both micro-magnetic parameters Mmax and Hcµ occurs after 3 × 105 cycles, mainly caused by phase
transformation from austenite to martensite, formation of cracks and increased dislocation density.
Due to the fact that surface fatigue is the dominating wear mechanism in the present experimental
setup, an increase of defect density and lattice distortion occurs mainly in a thin layer close to the
surface, as it can be evaluated in the Fit-maps acquired by means of EBSD. The fraction of dark areas in
Fit-maps significantly expands by increasing the loading cycles, mostly due to austenite transformation.
The coercive magnetic fields Hcm and Phicm acquired by Barkhausen noise analysis (Figure 12b)
show high sensitivity to the development of the residual stresses and correlates with the amount of
retained austenite (Figure 11). The sudden drop of the coercive magnetic field after 3·× 105 cycles
follows the general trend of coercivity presented in Figure 12a, mainly caused by cracks formation and
austenite transformation. By following wear conditions, a further decrease of the retained austenite
and of the compressive residual stresses occurs, leading, according to References [26–29], to increasing
of the coercive field force Hcm and Phicm. The further decrease of both parameters indicates the strong
concurrent influence of crack formation, as it was detected by coercive field force Hcµ.
One of the most important possibilities of the micro-magnetic testing is the depth-dependent
determination of microstructural changes under the surface. According to the concept of the skin
depth effect [15], the magnetic signal decays at a determined distance, depending on the frequency,
the permeability and conductivity of the material. This correlation is presented in the trend curves
of Mmax in Figure 13a. There, the Mmax increases with the wear progress in all analyzed depths.
The higher bandpass filter frequency representing the depth close to the surface shows the highest
Mmax values, which is in accordance with the fact that the plastic deformation and phase transformation
manifest at first on the surface. The characteristic jump between the initial state and the first wear
condition is also most distinctive for the trend curve representing areas close to the surface. Both facts
Materials 2018, 11, 2290 16 of 17
indicate the concentration of deformation and damage in this area, associated with martensitic
transformation and the appearance of cracks, as it was verified by means of XRD and EBSD-analysis.
The surface cracks indicate surface fatigue as a prevailing wear mechanism.
It can be concluded that the wear degree decreases gradually with the depth, presenting
a maximum deformation and damage on the surface and can be successfully analyzed via
micro-magnetic measurements.
5. Conclusions
The combination of different techniques for surface analysis like profilometry, topography analysis,
X-ray diffraction, microscopy and micro-magnetic testing allows for the acquiring of comprehensive
information of the superficial state of the gear wheels tooth flanks. The results reveal quantitative
information regarding the numerical deviation of the geometries in order to validate the wear progress.
The qualitative assessments of wear development on the surface with respect to the formation of
running surface, origin and growing of defects like micro-pitting and cracks help to identify wear
mechanisms as surface fatigue.
The micro-magnetic testing was successfully applied for a non-destructive characterization of
the wear progress on the surface of flanks of gear teeth. The results were verified with conventional
techniques for microstructural characterization. On one hand, the micro-magnetic parameters such as
the maximum amplitude of the Barkhausen noise curve and the coercivity analyzed by incremental
permeability are more sensitive to the wear progress, due to their correlation with the profile deviation.
On the other hand, the coercivity acquired by Barkhausen noise analysis shows high sensitivity
with the behaviour of the austenite transformation and the evolution of residual stresses, obtained
by means of X-ray diffraction. A depth-sensitive analysis performed by means of micro-magnetic
testing, using different filter bandpass frequencies during magnetization shows good correlation with
profile of residual stress under wear surface. Therefore, the micro-magnetic measurements were
successfully verified as a tool for comprehensive analysis of wear progress and can be applied for
Structure Health Monitoring.
Author Contributions: Conceptualization, F.W., P.T., W.T. and D.B.; Data curation, M.K. (Marina Knyazeva),
J.R.V., F.P., L.G. and M.K. (Monika Kipp); Investigation, M.K. (Marina Knyazeva), J.R.V., L.G., F.P., M.K.
(Monika Kipp) and M.W.; Project administration, M.K. (Marina Knyazeva), F.W. and D.B.; Supervision, M.K.
(Marina Knyazeva), P.T., W.T., F.W. and D.B.; Writing—Original draft, M.K. (Marina Knyazeva), J.R.V., L.G., F.P.
and M.K. (Monika Kipp); Writing—Review & editing, M.K. (Marina Knyazeva), J.R.V., L.G., F.P., P.T., W.T., F.W.
and D.B.
Funding: This research received no external funding.
Acknowledgments: We acknowledge financial support by Deutsche Forschungsgemeinschaft (DFG, German
Research Foundation) and TU Dortmund University within the funding program Open Access Publishing.
Conflicts of Interest: The authors declare no conflict of interest.
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