Abrasive Wear of Digger Tooth Steel

Hussein Sarhan, Nofal Al-Araji, Rateb Issa & Mohammad Alia
International Journal of Engineering (IJE), Volume (4): Issue (6) 478
Abrasive Wear of Digger Tooth Steel
Hussein Sarhan sarhan_52@hotmail.com
Faculty of Engineering Technology, Department
of Mechatronics Engineering,
Al-Balqa' Applied University,
Amman, PO Box: 15008, Jordan
Nofal Al-Araji nofalaraji@yahoo.uk.com
Faculty of Engineering, Department of
Materials and Metallurgical Engineering,
Al-Balqa' Applied University,
Al-Salt, Jordan
Rateb Issa ratebissa@yahoo.com
Faculty of Engineering Technology, Department of
Mechatronics Engineering,
Al-Balqa' Applied University, Amman,
PO Box: 15008, Jordan
Mohammad Alia makalalia2000@yahoo.com
Faculty of Engineering Technology, Department
of Mechatronics Engineering,
Al-Balqa' Applied University, Amman,
PO Box: 15008, Jordan
Abstract
The influence of silicon carbide SiC abrasive particles of 20, 30, 40, 50 and
60 mµ size on carburized digger tooth steel was studied. Four types of steel, with
different hardness, were tested at two constant linear sliding speeds and under
various loads of 10, 20, 30, 40 and 50N. Tests were carried out for sliding time of
0.5, 1.0, 1.5, 2.0 and 2.5min. Experimental results showed that there was
consistent reduction in abrasive wear as the hardness of the materials was
increased. It was found that wear increased with the increase of applied load,
linear sliding speed and sliding time. Also, it was noticed that the wear increased
with increase in abrasive particle size, and the most effective size was 40 mµ .
SEM observations of the worm surface showed that the cutting and ploughing
were the dominant abrasive wear mechanisms.
Keywords: Abrasive Wear, Wear Resistance, Carburized Digger Tooth Steel.
1. INTRODUCTION
Wear processes in metals have been classified into many types depending on the mechanism
responsible for removal of material from the surface. Experiments have revealed that wear is a
very complex process. Wear predictions, even through flawed, can be used in a number of ways
besides estimating the wear rate. First, an equation for wear indicates the relative influence of
various parameters, such as load, hardness, linear sliding speed, and surface roughness that

suggest changes in wear that might result, if the sliding system is changed. Second, component
of the wear is also important in the failure analysis or in the study of any worn component of a
system. Quantitative analysis of wear starts with the concept that while a sliding system may be
loosing material in more than one way, another mechanism will dominate the overall wear rate
[1].
The failure of components in service can be often attributed to wear, erosion or corrosion-
enhanced wear and erosion. The phenomenon contributing to failure under all these conditions is
complex and often specific to the particular application. Material properties determining resistance
to wear and erosion are correspondingly complex, making it difficult to predict the service
behavior of a particular material. Generally, high hardness, rapid work hardening, and good
oxidation and corrosion resistance can all contribute to wear and erosion resistance. Common
materials currently used in sever wear and erosion applications include cobalt-based alloys, high
manganese stainless steels, and other chromium containing alloys [2]. Under different testing
conditions, all results showed that there was a decreasing trend in wear with increasing hardness
of hard metals [3]. In experiments testing wear mechanisms, once equilibrium surface conditions
have been established, the wear rate is normally independent of the area of contact. The wear
rate is therefore proportional to the load for only a small numbers of variations, but there is still a
small deviation between wear rate and load that forms a direct proportionality. Published
literatures concluded that wear rate is proportional to the load and independent of pressure
unless the area of contact was equivalent to one third of materials' hardness [4]. The most widely
used quantitative relationship among abrasive wear rate, material properties, load and sliding
speed, at the interface of two bodies loaded against each other in relative motion, was formulated
[5]. Also, it was reported that wear rates of some materials vary linearly with the applied load and
independent of pressure over a wide range. It was shown that there is an inverse relationship
between wear rates and hardness. Wear is quantified by weight or volume loss per unit of time or
per sliding distance. These simple results are marked in contrast to the majority of wear
experiments reported in literature. They suggest that wear is dependent on a large number of
variables and there is no general agreement about how the wear depends on such variables as
applied load, linear sliding speed, and apparent area of contact. Generally, the abrasive wear of
alloy steel is characterized by two modes, designated sever wear and mild wear. This has been
recognized by many investigators for a long time [6]. It has been found that, at the constant linear
sliding speed used, in the load range, where equilibrium mild wear operates, the sliding distance
for initiation of mild wear decreases logarithmically with the load. The slope of this decrement is
termed the running-in coefficient and is a quantitative measure of the running-in behavior of the
steel. The presence of 3% Cr markedly decreases the running-in coefficient, i.e. increases the
sliding distance required for the initiation of mild wear at a given load [7].
Hard metals could be an ideal solution for wear resistance. At present, hardened steel or some
technical ceramic materials, in bulk or as a surface coating, are often used. The main purpose of
these materials is to extend the life time of existing devices and/ or components by decreasing
their wear rate. A significant disadvantage of these materials is their relatively high friction
coefficient in dry contact conditions (heat development and energy loss). Moreover, their high
hardness renders them intrinsically difficult to shape and to finish using conventional methods [8].
High chromium content white cast irons have generally good wear resistance and toughness
properties. These types of cast irons are generally used in slurry pumps, brick dies, and several
mine drilling equipment. Rock chromium content cast iron materials have higher toughness than
have low chromium ones [9]. Investigations of the wear behavior of white cast irons under
different compositions were conducted against SiC and Al2O3 abrasive paper, and the results
showed that the wear rate was affected by the composition of white cast iron [10]. White cast iron
containing copper under erosive wear testing has been devised, and the results showed that a
linear relationship has been established between the percentage of copper and the amount of
erosion. Relative erosion is directly dependent on the carbide volume, carbide particle size and
also the angle of impact [7]. The results of wear test of hard boron carbide B4C thin films, and the
data obtained from pin-on-disc tests show that the abrasiveness of a contact is proportional to the
number of asperities in the contact and the effect of increasing the load is to enlarge the initial

apparent contact region, and the dependence of the wear rate on load follows relationships that
are similar to Hertzain relationships [11].
The aim of this work is to investigate the role of abrasive particles size and other factors on the
wear properties of carburized digger tooth steel. There are a number of different types of wear
testing methods. Low stress or scratching abrasion is probably the most predominate in the
mining industry. A quantitative method of measuring a materials resistance to this scratching type
abrasion is the pin-on-disc apparatus, (ASTM G99-05, 2006). This test characterizes materials
removed in terms of weight loss under a controlled set of laboratory conditions. Correlation to
actual field conditions which may be influenced by other wear parameters, such as the amount of
impact, corrosion, galling, etc. is required.
2. EXPERIMENTAL WORK
Pins of 8mm diameter and 80mm length for wear test were prepared by machining them from
digger tooth steel. The composition of the digger tooth steel used for this study is listed in Table
1. All pins were case hardened under pack carburizing conditions given in Table 2.
C% Si% Mn% Mo% Ni% Al% P% S% HRC
0.40-0.42 0.40 0.90-0.95 0.25 0.20 0.04 0.03 0.02 45
TABLE 1: Composition of the Digger Tooth Steel.
Group No. Holding time, h Cooling medium Heating temperature, o
C HRC
1 16 Air 980 64
2 12 Air 850 58
3 10 Air 750 52
TABLE 2: Carburizing Conditions of Test Pins.
The carburized pins were heated to 850o
C for 30min then water-hardened. Abrasive wear tests
were carried out at room temperature on a pin-on-disc apparatus shown in Figure 1. The steel
disc, φ 230mm, was covered with abrasive papers of different SiC particles size of 20-30-40-50-
60 µ m. Pins were pressed on the disc with different normal loads of 10-20-30-40-50N. Wear
data were collected after 0.5, 1.0, 1.5, 2.0, and 2.5min. Wear tests were carried out at two
different linear sliding speeds of 1.5 and 2.5m/s. Abrasive wear was determined from the change
in the weight using 1.00x10
-4
g precision digital scale. For each wear test a new pin has been
used in a new sliding position. Microscopic views of the test pins were taken, also worn surfaces
of pins were examined using scanning electron microscope.

FIGURE 1: Schematic Diagram of a Typical Pin-on-Disc Tester.
3. RESULTS AND DISCUSSIONS
Effect of Sliding Time On The Total Weight Loss
The relationship between total weight loss TWL and sliding time for the specimens used in the
tests is shown in Figures 2-6. The specimens used in these tests were all subjected to the same
load (10N), linear sliding speed (1.5m/s), and abraded against SiC papers with different particle
size (20-60µ m). These plots showed that the total weight loss increased as the sliding time
increased. This increase in total weight loss was sharper until sliding time of 2.0min, and then the
relationship behaved as steady state, especially for the SiC particles size of 50-60µ m. This trend
may be due to the increase in temperature of the worn surface and the work hardening effects.
Thus, the specimen hardened to 64HRC will exhibit better wear resistance comparing with the
same specimen hardened to 45HRC [12].
0
20
40
60
80
100
120
140
160
180
0 0.5 1 1.5 2 2.5 3
Sliding time, min
Totalweightloss,mg
HRC=64 HRC=58 HRC=52 HRC=45
FIGURE 2: Effect of Sliding Time on the Total Weight Loss for Load = 10 N, Linear Sliding Speed = 1.5 m /s
and SiC Particles Size = 20µ m.

0
20
40
60
80
100
120
140
160
180
200
0 0.5 1 1.5 2 2.5 3
Sliding time, min
Totalweightloss,mg
FIGURE 3: Effect of Sliding Time on the Total Weight Loss for Load = 10 N, Linear Sliding Speed = 1.5 m /s
0
20
40
60
80
100
120
140
160
180
200
0 0.5 1 1.5 2 2.5 3
Sliding time, min
Totalweightloss,mg
FIGURE 4: Effect of Sliding Time on the Total Weight Loss for Load = 10 N, Linear Sliding Speed = 1.5m /s

0
20
40
60
80
100
120
140
160
180
200
0 0.5 1 1.5 2 2.5 3
Sliding time, min
Totalweightloss,mg
FIGURE 5: Effect of Sliding Time on the Total Weight Loss for Load = 10 N, Linear Sliding Speed = 1.5m /s
Effect Of Abrasive Articles Size On The Total Weight Loss
This means that the specimen with 64HRC is more abrasive wear resistant than that with the total
weight loss for four specimens with different hardness as a function of SiC particles size is shown
in Figure 6. The specimens were subjected to the same load (10N), sliding speed (1.5m/s), and
abraded against SiC papers with different particles size (20-60µ m) for 2.5min sliding time.
0
20
40
60
80
100
120
140
160
180
0 0.5 1 1.5 2 2.5 3
Sliding time, min
Totalweightloss,mg
FIGURE 6: Effect of Sliding Time on the Total Weight Loss for Load = 10 N, Linear Sliding Speed = 1.5 m/s
Figure 7 shows that the specimen with 45HRC is the most worn one, while the specimen with
60HRC is the least worn one, and the total weight loss has been increased with increasing in SiC
particles size. It is considered that the total weight loss for all specimens is maximum when they
are abraded by SiC of 40µ m size, which is the critical size, and then the effect of SiC particles

size has been decreased due to the change in their mechanical action from cutting to scratching
and deformation [13].
FIGURE 7: Effect of SiC Particles Size on the Total Weight Loss for Load = 10 N, Linear Sliding Speed =
1.5m/s and Sliding Time = 2.5 min.
Figures 8 and 9 show the worn surfaces of the specimens of 64HRC abraded under the same
abrasive wear conditions (load =10N, sliding speed=1.5m/s and sliding time=2.5min).
FIGURE 8: SEM Micrograph of Worn Surface of 64HRC Specimen Exposed to Abrasive Wear with 40 µ m
SiC.

FIGURE 9: SEM Micrograph of Worn Surface of 64HRC Specimen Exposed to Abrasive Wear with 60 µ m
SiC.
Figures 10 and 11 show the SEM micrographs of worn surfaces of digger tooth steel before case
hardening (45HRC) and after case hardening (64HRC) abraded under the same abrasive wear
conditions (applied load =50N, linear sliding speed =2.5m/s, and sliding time =2.5min). It is clear
from Figs. 10 and 11 that the surface damage before case hardening is more than that after case
hardening45HRC.
FIGURE10: SEM Micrograph of Worn Surface of 45 HRC Specimen Exposed to Abrasive Wear with 40µ m
SiC Particles, 50 N load, and 2.5m/s Linear Sliding Speed.

FIGURE11: SEM Micrograph of Worn Surface of 64 HRC Specimen Exposed to Abrasive Wear with 40µ m
SiC Particles, 50 N Load, and 2.5m/s Linear Sliding Speed.
Effect Of Load On The Total Weight Loss
The total weight loss of the specimens as a function of applied load after 2.5min sliding time with
1.5-2.5m/s sliding speed and SiC particles size of 40µ m is shown in Figures 12 and 13. The
plots on the mentioned figures show that the total weight loss for all specimens has been
increased with increasing the applied load at constant linear sliding speed. Also, the plots show
that the total weight loss has been increased with increasing the linear sliding speed under
constant test conditions. Transition curve has been obtained for each specimen. The transition
curves show three distinct regions: mild wear, transitional wear indicating a possible change in
wear mechanism, and sever wear. These regions become clearer as the HRC of the specimens
increases. The transitional wear region occurs between 20-40N loads for 1.5m/s linear sliding
speed, and 20-30N loads for 2.5m/s linear sliding speed. This trend is related to the temperature
effect at the worn surface [3].

0
50
100
150
200
250
300
0 10 20 30 40 50 60
Applied load, N
Totalweightloss,mg
FIGURE 12: Effect of Applied Load on the Total Weight Loss under Sliding Speed =1.5m /s, Sliding Time
=2.5 min and SiC Particles size =40 µ m.
0
50
100
150
200
250
300
0 10 20 30 40 50 60
Applied load, N
Totalweightloss,mg
FIGURE 13: Effect of Applied Load on the Total Weight Loss under Sliding Speed =2.5m/s, Sliding Time
=2.5min, and SiC Particles Size =40µ m.
Effect Of Specimens Hardness On The Total Weight Loss
As mentioned earlier, wear depends on a number of parameters including material hardness. The
specimens used in wear tests were all subjected to the same test conditions, but due to their
individual hardness, some of them, such as specimen with 64HRC, were more resistant to wear
than others [11]. Figure 14 shows a trend for decreasing wear with increasing specimens'
hardness and the wear in specimen of 45 HRC is twice greater than the wear in specimen of 64
HRC. The microstructure of heat treated test specimens before case hardening is shown in
Figure 15. Concerning Figure 16, it shows the optical microscope photograph of steel carburized
16h to surface carbon content 0.9%, while Figure 17 shows the optical microscope photograph of
water-hardening steel-case hardness was 64HRC and core hardness was 45HRC. Figures 16

and 17 show the appearance of carbide layer on the surface, which increases the hardness, and
as a result, the abrasive wear has been reduced comparing with the digger tooth steel
microstructure shown in Figure 15, before case hardening.
0
50
100
150
200
250
300
0 20 40 60 80
Hardness, HRC
Totalweightloss,mg
FIGURE 14: Effect of Hardness on the Total Weight Loss under Applied Load =50N, Sliding Time =2.5min,
Linear Sliding Speed =2.5m/s, and SiC Particles Size = 40µ m.
FIGURE15: Optical Microscope Photograph of Heat Treated Digger Tooth Steel before Case Hardening
Showing Fine Grain of Ferrite and Pearlite.

FIGURE16: Optical Microscope Photograph of Steel Carburized 16h to a Surface Carbon Content 0.9%
Showing Carbide Surface Layer.
FIGURE 17: Optical Microscope Photograph of Water-Hardening Steel. Case Hardness = 64HRC; Core
Hardness=45HRC Showing Light Gray Martensitic Zone.
Effect Of Linear Sliding Speed On The Total Weight Loss
Figures 12 and 13 show the effect of linear sliding speed on the total weight loss. The total weight
loss in all specimens abraded under the same abrasive conditions increased as the linear sliding
speed increased from 1.5m/s to 2.5m/s. This is due to the increase of the contact surfaces
temperature, which leads to softening of the worn surface.

4. CONSLUSION
Based on the results of this study, the following conclusions can be made:
1. The total weight loss increases with increase of abrasive particles size, and the maximum wear
occurs with a critical abrasive particles size of 40µ m.
2. There is a significant reduction in wear as the hardness of materials increases.
3. Abrasion resistance of materials depends at the same time on a number of factors, such as
their hardness, microstructure, applied load, sliding time, sliding speed, and other wear test
conditions.
4. The total weight loss increases as the exposed time to abrasive surface, linear sliding speed,
and applied load increases.
5. The transitional wear region decreases as the linear sliding speed increases.
6. As the hardness of abraded materials increases the three types of wear regions (mild,
transitional, and sever) become more distinct.
7. Examination of worn surfaces shows that ploughing, cutting, and fracture are the dominant
abrasive wear mechanism.
5. REFERENCES
1. Carrie K. Harris, Justin P. Broussard and Jerry K. Keska. “Determination of Wear in a Tribo-
system”. In Proceedings of the ASEE Gulf-South Western Annual Conference, 2002
2. Carima Sharma, M. Sundararaman, N. Prabhu and G.L. Goswami. “Bull. Mater. Sci.”, vol. 26,
No. 3, Indian Academy of Sciences, 311-314, India, 2003
3. M.G. Gee, A.J. Gant. “CMMT (MN) 046 Rotating Wheel Abrasion Tests on Hard Metals and
Ceramics”. National Physical Laboratory, 20:170-190, UK, May 1999
4. J.F. Archard, W. Hirst. “The Wear of Materials under Unlubricated Conditions”. In Proce.
Royal Soc., A-236: 71-73, June 1958
5. ASTM. “Standard Test Method for Wear Testing with a Pin-on-Disc Apparatus”. May 2000
6. Q.M. Farrell, T.S. Eyre. “The Relationship between Load and Sliding Speed Distance in the
Initiation of Mild Wear in Steels”. Wear, 15: 359-372, March 1970
7. F.M. Borodich et al. “Wear and Abrasiveness of Hard Carbon-Containing Coatings under
Variation of the Load”. Surface and Coatings Technology, 179:78-82, 2004
8. A.G. Evans, D.B. Marschall and D.A. Rigney. “Fundamentals of Friction and Wear of
Materials”. ASM, p. 439, 1981
9. “Metals Handbook”, 9
th
ed. 15 Casting, (1988)
10. N. Al-Araji. “Erosion Resistance of White Cast Iron”. Journal of Engineering and Technology,
34: 70-80, University of Technology, Baghdad, Iraq, 1984
11. “Timken Latrobe Steel, Wear Resistance of Tool Steels”, Marlborough, MA, (2002)
12. N. Al-Araji, H. Sarhan. “Abrasive Wear of Al-Mn Alloys”, Dirasat, Engineering Sciences, 32(1):
68-77, Jordan University, 2005
13. Cetinkaya. “An Investigation of the Wear Behaviors of White Cast Irons under Different
Compositions”. Material and Design, 2004.

Abrasive Wear of Digger Tooth Steel

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