Strojniški vestnik - Journal of Mechanical Engineering 69(2023)7-8, 326-338 Received for review: 2023-01-31
© 2023 The Authors. CC BY 4.0 Int. Licensee: SV-JME Received revised form: 2023-03-28
DOI:10.5545/sv-jme.2023.541 Original Scientific Paper Accepted for publication: 2023-05-15
*Corr. Author’s Address: Adiyaman University, Faculty of Engineering, Altinsehir Mah. 3005. Sok. No:13, Adiyaman, Turkey, kengin@adiyaman.edu.tr 326
Finite Element Analysis of Notch Depth and Angle  
in Notch Shear Cutting of Stainless-Steel Sheet
Engin, K.E.
Kaan Emre Engin
*
Adiyaman University, Faculty of Engineering, Turkey
Piercing is a crucial process in the sheet metal forming industry, and the surface quality of the pierced part is an important parameter that 
defines the overall quality of the product. However, obtaining a good surface quality is a challenging task that depends on the effect of several 
process parameters and necessitates the use of non-conventional procedures. Notch shear cutting is a relatively new progressive approach 
in which the workpiece is indented with a notch form with a predefined notch angle and depth, and then the indented workpiece is subjected 
to conventional piercing. In this study, conventional piercing and notch shear cutting processes were experimentally performed on 1.4301 
stainless steel sheet of 2 mm thickness. Then, finite element (FE) analyses were conducted utilizing Deform-2D software. After ensuring 
that the experimental and simulation works were consistent with each other, the FE analysis of notch shear cutting was carried out for three 
distinct notch depths (15 %, 30 %, and 60 % of the workpiece thickness) and six different notch angles (10º, 20º, 30º, 40º, 50º, and 60º). 
Investigations were performed on shear zone length distributions, which are direct indications of the surface quality on sheared workpieces, 
crack propagation angles, and required cutting loads. The best surface quality was obtained when the notch angle was set to 50º and the 
notch depth was set to 15 % of the workpiece thickness. It was also observed that notch angle and notch depth had a certain level of influence 
on required cutting load.
Keywords: metal cutting, notch cutting, piercing, surface quality
Highlights
• 	 The primary objective of the study was to determine the influence of notch angle and notch depth on surface quality and 
required cutting in notch shear cutting of 1.4301 sheets of 2 mm thickness. 
• 	 Both experimental and finite element (FE) analyses were performed to validate the consistency of two methods. Deform-2D 
software was utilized for numerical analysis whereas a die set was manufactured for experimental work. 
• 	 The overall best quality which surpassed the surface quality of piercing was achieved with a notch angle of 50º and a notch 
depth of 15 % of the workpiece thickness.
• 	 It was determined that when the notch angle increased, the required cutting load decreased. This was also true for increasing 
notch depth, but the load incurred during the generation of notch depth must be included in the total energy consumption.
0  INTRODUCTION
Piercing is a fundamental process in the sheet metal 
forming industry and is defined as the cutting of the 
sheet metal from the stock with a die set consisting 
of a predefined shaped punch and a lower die. The 
primary purpose of the piercing process is to avoid 
workpiece rework and maintain good surface quality. 
Burrs and protruding surfaces create an impediment to 
achieving this goal. Burrs can cause early tool wear, 
reduced corrosion resistance and because of their 
sharp formations, can become the primary source 
of accidents. These negative impacts result in poor 
overall process production quality. 
To remove these formations from the surface, 
conventional grinding and other cleaning procedures 
are necessary, resulting in additional labour hours, 
higher costs, and specific people being withdrawn 
from the main operating cycle and allocated solely to 
these deburring and cleaning activities [1].
Due to the nature of the process, numerous 
parameters should be adjusted and understanding the 
effect of these parameters is the key step to achieving 
good cutting results and lower energy consumption. 
Adjustments in clearance [2] and [3], cutting speed 
[4], workpiece and tool material [5], tip form [6], tool 
coatings [7] and wear characteristics [8] to [12] have 
significant effects on both surface quality and energy 
aspects in conventional piercing procedures. 
However, a relatively recent procedure known 
as “notch shear cutting” has been developed with the 
goal of improving the surface quality of sheared sheet 
components. A notch with specified characteristics is 
pushed onto the workpiece in this progressive method. 
The operation then proceeds with the conventional 
piercing method.
Few studies have investigated the notch shear 
cutting of sheets and related parameters. Studies 
investigating different aspects of the notch shear 
cutting proved that good surface quality with reduced 
burr formations can be achieved by using this method. 
Sachnik et al. [13] used workpieces DC04, 
1.4301, ENAW-6014 and CuSn6 with 1 mm thickness 
and performed both closed and open cuts with a 

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327 Finite Element Analysis of Notch Depth and Angle in Notch Shear Cutting of Stainless-Steel Sheet 
special progressive die. They mainly investigated the 
formation of burrs and how they change according to 
the notch placement on the workpiece. Both simulation 
and experimental works had been accomplished. The 
investigations were done for different values of notch 
cutting parameters as notch depth (30 % to 60 % of the 
sheet metal thickness), notch’s radius (0.05 mm, 0.125 
mm, and 0.2 mm) and clearance (6 %, 8 %, and 10 % 
of the material thickness). They showed that the burr 
formation is directly linked with the position of the 
notch and notch height. They also stated that around 
40 % notch heights gave the most burr-free surfaces.
Krinninger et al. [14] investigated the effect of 
notch parameters on the workpiece by using both 
experimental and finite element method (FEM) for 
sheet materials made of aluminium alloys ENAW-
5754 and ENAW-6014 with a thickness of 1.0 mm. 
The clearance between the die and punch was 3 % of 
the workpiece thickness. They designed a progressive 
die set to perform the experimental work. Notches 
were both applied from the topsides and downsides of 
the workpiece; 25 % and 40 % of the notch depths and 
a fixed value of 60º as the notch angle were applied on 
the workpieces. They discovered that while the topside 
notch could lower the required cutting forces, in 
general, there was no reduction in cutting forces when 
the percentage drop in sheet thickness was considered. 
With downside notches, they observed that a surface 
distribution without burr could be achieved.
Feistle et al. [15] performed notch shear cutting 
studies on press-hardened components (PHC) made 
of aluminium-silicon-coated manganese-boron 
steel (22MnB5) sheets at room temperature. The 
shearing of PHC steels at room temperature causes 
difficulties due to their higher mechanical properties. 
Moreover, the wearing of tools progresses rapidly, 
which contributes to the formation of more burrs at 
the edges of the workpieces. The workpieces had 
1.5 mm thickness. The die clearance was 15 % of 
the workpiece thickness. The notch angle was 60º. 
Notch depths were 16 % and 40 % of the workpiece 
thickness. Three notch variables (without notch, 
topside notch, and downside notch) were examined by 
both FEM and experimental methods. They measured 
the zone distributions on the sheared surfaces and 
calculated the required shearing force. They stated 
that cutting loads were reduced for notched specimens 
and provided improved surface quality free of burrs.
The existence of a notch on the workpiece 
introduces additional parameters to be investigated. 
The mentioned studies investigated some values 
of notch depth, but the notch angle values were 
generally limited to 60º. Furthermore, none of the 
studies investigated the effect of these parameters 
on stainless steels which are one of the most used 
materials in industrial applications. The surface 
quality and required cutting load change according 
to notch depth and notch angle for stainless steels 
should be investigated with varied values of these 
two parameters. If correct parameter adjustments can 
be established for 1.4301 sheets during notch shear 
cutting and high surface quality can be produced, 
then a technical advantage can be acquired over 
conventional piercing techniques.
To achieve this, experimental and computational 
validations for conventional piercing and notch 
shear cutting were conducted initially. Following the 
consistency of the findings between experimental 
and computational work, three different notch depths 
(15 %, 30 % and 60 % of the workpiece thickness) and 
six different notch angles (10º, 20º, 30º, 40º, 50º, and 
60º) were employed to execute the notch shear cutting 
of 1.4301 stainless steel sheet; the influence of these 
variables on the surface quality and required cutting 
load were investigated using finite element analysis.
1  PROCESS PARAMETERS
1.1  Notch Depth, Notch Angle, and Surface Distribution on 
the Workpiece
As an addition to the parameters of conventional 
piercing, notch shear cutting introduces new 
parameters such as notch depth, which is the 
percentage of the height of the notch to the thickness 
of the workpiece; notch angle, which is the angle value 
of the notch indented on the surface of the workpiece; 
and notch radius, which is the radius given to the tip 
of the notch.
Notch shear cutting is a progressive process. The 
related illustration of the steps of the process was given 
in Fig. 1. First, a notch indenter with a predetermined 
angle, depth, position, and radius is manufactured 
(Fig. 1a). In the second step, the indenter is forced 
against the workpiece, resulting in the development of 
a notch (Fig. 1b). Then, in the last step, the notched 
workpiece is subjected to conventional piercing and 
the process is completed (Fig. 1c). 
Shearing of the material is a complicated 
phenomenon. When a workpiece is pierced, it goes 
through a series of stages before being entirely 
ruptured. Zones typical of piercing are generated on 
the workpiece’s surface during these stages. Rollover 
(die roll) zone, shear (burnished) zone, fracture zone, 
and burr formation are the four zones mentioned. 
By measuring these zones and observing how much 

Strojniški vestnik - Journal of Mechanical Engineering 69(2023)7-8, 326-338
328 Engin, K.E.
they dominate the overall surface length, the surface 
quality of the sheared workpiece can be assessed. 
a) 
b) 
c) 
Fig. 1.  The illustration of the steps of notch shear cutting and 
related components; a) manufactured indenter with predetermined 
notch properties, b) formation of notch on the workpiece and,  
c) conventional piercing of the notched workpiece
Rollover and burrs are the least desired zones on 
the surface, and investigations often involve methods 
and parameter modifications for eliminating these 
zones. Stahl et al. [16] implemented two-stage shear 
cutting instead of one-stage shear cutting of truck 
frame parts and revealed the effects of different 
process parameters on the improvement of surface 
quality and burr formations along with fatigue 
enhancement of the sheared parts. Mucha and Tutak 
[17] studied the impact of clearance on the burr size 
formed on a thin steel sheet with a 55 HRC hardness 
during the blanking of angled hooks, as well as the 
wear characteristics of the punch. Nishad et al. [18] 
collected and compared the methodologies used 
to improve the process and elaborated on how the 
parameters of the process impact the result. A long 
shear zone length is the most desired situation.
The illustration of these zones was given in Fig. 
2. Denting the surface with a notch before piercing 
has the potential to reduce burr forms while extending 
the shear zone length. 
Fig. 2.  Zone distributions on the sheared surface
Notch angle and depth are essential parameters 
that can influence crack propagation and orientation 
as well as zone distributions. 
Determining the optimal values of these 
parameters are important. The upper limit of the notch 
angle value was set using a fine-blanking approach.
Generally, a notch is produced on the workpiece 
prior to cutting using a v-ring indenter to keep the 
workpiece in place and the side angle of the v-ring 
indenter is normally kept constant as 60º in related 
procedures like fine blanking. From this point of 
view, the upper limit of the notch angle was set at 60º; 
moreover, 10º, 20º, 30º, 40º, and 50º were added to 
observe how they influenced the results. From low to 
high, notch depths were set at 15 %, 30 %, and 60 % 
of the workpiece thickness, respectively.
2  EXPERIMENTAL METHODOLOGY
The first step in the study was to conduct the 
experiments. Although this study relied heavily on 
finite element (FE) analysis, computational results 
should be cross-checked with experimental data. If 
computational and experimental work for piercing and 
notch shear cutting could be verified to be consistent 
with one another, the simulation work would be 
expanded to study the influence of other notch shear 
cutting parameters. 
The stock material was 1.4301 stainless steel 
sheet. The mechanical characteristics of the material 
have crucial importance in shear-cutting processes. 
Due to this situation, the mechanical characteristics 
of 1.4301 sheet were determined as the beginning 
phase of the research. If the mechanical characteristics 

Strojniški vestnik - Journal of Mechanical Engineering 69(2023)7-8, 326-338
329 Finite Element Analysis of Notch Depth and Angle in Notch Shear Cutting of Stainless-Steel Sheet 
of the workpiece material were defined with errors 
in the software, the results would almost certainly 
differ from those obtained via experimental work. 
1.4301 stainless steel sheet is used in a variety of 
industrial applications, including mining, maritime 
and structural applications as well as the manufacture 
of bolts, screws, and containers [19]. 
Tensile tests were used to get the stress-strain 
graphs that the software required. A stock 1.4301 
stainless steel sheet was supplied from local sheet 
metal vendors. The dimensions of the stock material 
were 2000 mm × 1000 mm with 2 mm thickness to 
satisfy the tensile testing standards. The chemical 
composition and the mechanical properties of the 
material according to the manufacturer’s sheets are 
given in Tables 1 and 2. 
Table 1.  Chemical composition of 1.4301 sheet
Composition Weight [%] Composition Weight [%]
C 0.08 Si 0.75
Mn 2.0 S 0.03
P 0.04 Ni 9.0
Cr 19.0
Table 2.  Mechanical Properties of 1.4301 sheet
Properties Value Properties Value
Tensile strength 515 MPa Elongation at break 60 %
Yield strength 210 MPa Hardness (Rockwell B) 80
Using a water jet, the specimens were cut out 
of the stock according to ASTM E8 standards, 
considering the rolling directions (0º, 45º, 90º). The 
goal of using a water jet is to lessen the thermal effects 
that arise on the material‘s surface. The sides of the 
specimens were also polished to prevent the notch 
effect from occurring during tensile tests. Fig. 3 shows 
the dimensions of the test specimen (Fig. 3a) and the 
actual test specimen (Fig. 3b). 
a) 
b) 
Fig. 3.  a) Dimensions, and b) the actual image of one of the 
tensile test specimens
Fig. 4 depicts the metallographic structure of 
1.4301 sheet observed by using a scanning electron 
microscope (Zeiss Gemini SEM 500). A Shimadzu 
AG-X Plus tensile testing machine was used to 
measure the engineering curve of 1.4301 sheet.
To reduce the margin of error, the tensile tests 
were repeated six times at room temperature for each 
rolling direction at a strain rate of 0.05 s
-1
.
Fig. 4.  Metallographic structure of 1.4301 stainless steel sheet
First, engineering stress was measured, and then 
true stress is obtained by using true stress-strain 
equations expressed in Eqs. (1) and (2) as:
	σ
t
 = σ(1 +ε), (1)
	ε
t
 = ln(1 +ε), (2)
where σ
t
 and σ
 
represent true and engineering stresses, 
ε
t
 and ε	are true and engineering strains. The obtained 
engineering and true stress-strain curve of 1.4301 
sheet were given in Fig. 5. 
Fig. 5.  True and engineering stress-strain diagram  
of 1.4301 stainless steel sheet
In the second phase, both piercing and notch shear-
cutting operations were carried out experimentally. A 
manufactured die set was used to perform piercing 
and notch shear cutting. It consisted of six parts: the 

Strojniški vestnik - Journal of Mechanical Engineering 69(2023)7-8, 326-338
330 Engin, K.E.
punch, upper die block, guides, a fixed-type blank 
holder, lower die, and lower die block. The blank 
holder and die blocks were constructed of S235JR, 
while the remainder of the components were made of 
heat-treated 1.7225 steel. The die set (Fig. 6a) and its 
exploded view (Fig. 6b) are shown.
Due to the progressive nature of notch shear 
cutting, which necessitates the formation of a notch on 
the workpiece’s surface before conventional piercing 
can begin, a special hollow punch was produced to be 
used as an indenter. The manufactured hollow punch’s 
tip sides had a 60º notch angle and a notch tip radius 
of 0.5 mm. The depth of the hollow was adjusted to 
1.2 ± 0.1 mm to prevent the hollow punch to penetrate 
further than the notch depth of 60% of the workpiece 
thickness. The total length of the punch was 80 mm. 
Fig.7 shows the illustration of the hollow punch (Fig. 
7a) and the formation of the notch indenter (Fig. 7b).
Clearance between the die and the punch was 
calculated according to Eq. (3) as:
 C = 100((D
m
-D
p
)/2t) [%] , (3)
where D
m
 is the lower die diameter, D
p
 is the punch 
diameter and t is the workpiece thickness.
a) 
b) 
Fig. 6.  a) The die set, and b) it’s exploded view 
The die clearance was fixed at 5 % of the 
thickness of 1.4301 sheet, which was 2 mm, for both 
experimental and computational work. 
a) 
b) 
Fig. 7.  a) Illustration and b) dimensions of hollow punch in [mm]
The lower die diameter was 10 mm; based on 
Eq. (3), the calculated and fabricated punch diameter 
to perform a conventional piercing process was 
9.80 mm. The total length of the punch was 80 mm. 
Experiments were conducted utilizing a hydraulic 
press with a capacity of 300 kN and under a ram speed 
of 1 mm/s. To keep the punches in place, a punch 
holder was manufactured and attached to the press’s 
ram.
a) 
b) 
Fig. 8.  a) Notch indentations on the workpiece, and  
b) conventionally pierced workpiece

Strojniški vestnik - Journal of Mechanical Engineering 69(2023)7-8, 326-338
331 Finite Element Analysis of Notch Depth and Angle in Notch Shear Cutting of Stainless-Steel Sheet 
The piercing operation was carried out using the 
manufactured die set while the notch shear-cutting 
process was carried out in a progressive manner. 
The notch is first produced on the downside of the 
workpiece. Following that, the standard piercing 
process was performed. Fig. 8 shows an example of 
notch creation on the workpiece surface (Fig. 8a) and 
one of the typically pierced workpieces (Fig. 8b), 
respectively.
3  NUMERICAL SIMULATION AND MODEL VERIFICATION
Deform-2D software was used to execute the 
computational work. Sheet metal shearing is one 
of the many forming techniques that the software 
can model. The software employs axisymmetric 
modelling which implies that only half of the setup is 
required to run it. The workpiece was modelled as a 
plastic object, whereas the punch, lower die and blank 
holder were defined as rigid bodies. Shear friction 
occurs when the workpiece deforms and is a function 
of the yield stress. The friction between the workpiece 
and the shearing tools was assumed to remain constant 
and was calculated as follows in Eq. (4):
 fs = mk , (4)
where ƒ
S
 is the frictional stress, k the shear yield stress, 
and m the friction factor. According to the software’s 
database, shear friction was given a value of 0.12.
Large plastic stresses are generated over a narrow 
zone between the punch and the die during shearing. 
At that small deformation zone, the material was 
considered to be isotropic and yielding followed 
Holloman’s equation which was stated in Eq. (5) as: 
  

K
n
, (5)
where σ is the effective stress, ε the effective strain, 
K is the material constant, and n the strain hardening 
exponent [20].
Deform-2D database includes the material 
properties for 1.4301 stainless steel. Fig. 9 
demonstrated the consistency of the flow stress-
strain curve of 1.4301 stainless steel in Deform-2D’s 
database and the computed flow stress-strain curve 
obtained from the tensile tests by using Holloman’s 
equation.
Fracture initiation in a piercing process usually 
begins at the punch’s or lower die’s contacting edge. 
For computational studies, the fraction criterion is 
critical because good criterion choice brings the 
outcome values closer to the experimental results.
For the purposes of numerical analyses, the 
normalized Cockroft and Latham fracture criterion 
were utilized.
Fig. 9.  Flow stress-strain curve of 1.4301 stainless steel
The criterion indicates that when effective strain 
equals the critical value (C), fracture initiation begins 
at the point where the value is reached. The criterion 
was given in Eq. (6) as:
 




*
,









0
f
dC (6)
where σ
*
 is the maximum principal stress, ε
–f
 the 
fracture strain, C the critical value (damage factor), 
and σ and ε are the expressions of effective stress 
and effective strain. 
To simplify the criterion, the ratio between 
maximum principal and effective stress was assumed 
to be constant at the shearing zone. This assumption 
resulted in ε
–f
 = C meaning that crack initiation starts 
at the point where effective strain and critical values 
become equal [21].
The critical value, C, can be evaluated by a tensile 
test regardless of the working operation. The critical 
value of 1.4301 sheet was defined as 0.54, which was 
acquired from the conducted tensile test.
The software employs a step-based iteration 
mechanism; at each step, it verifies the workpiece’s 
values. If the values described by mesh formations 
on the workpiece approach the critical value, element 
deletion is applied to the associated meshes to view 
the fracture initiation and propagation. This function 
is governed by two parameters: “fracture steps” and 
“fracture elements.” The value of fracture steps sets 
the step interval at which the simulation pauses and 
element deletion is performed. This value was selected 
as 1, the minimal value. This signifies that element 
deformation is considered at each step. Fracture 
elements are the number of elements that must exceed 

Strojniški vestnik - Journal of Mechanical Engineering 69(2023)7-8, 326-338
332 Engin, K.E.
the critical damage value for the simulation to halt 
and delete elements. This value was set as the system 
default to 4. Automated mesh generation was used and 
defined to be executed for every 0.02 mm progression 
of the top die to provide optimum re-meshing.
Element deletion improves visualization 
coherence with experimental outcomes. However, 
negative aspects of this approach include volume 
deterioration and excessive mesh deletion if mesh 
element numbers are maintained low. Low mesh 
numbers result in an imprecise representation of 
the shear region where the zones interweave. This 
circumstance results in inaccurate calculations of the 
cutting load and interpretations of the zone lengths 
derived from simulation results.
The density of the meshes at the shear zone 
must be as dense, small, and numerous as possible to 
prevent volume loss and accurate propagation of the 
fracture, which enables consistent visualization of the 
variation in zone distribution. Initially, the meshes on 
the workpiece were evaluated with varying element 
counts; however, as the element count reached 8,100, 
isoparametric quadratic elements, it was determined 
that there was no change in cutting load above this 
element count. Tough, to obtain optimum surface 
distribution on the sheared workpieces, 10,000 
isoparametric quadratic elements which are the 
maximum number of elements that can be defined in 
Deform-2D and 9,786 number of nodes with 0.03 mm 
element size were used. The simulation parameters 
were given in Table 3.
Table 3.  Simulation parameters
Parameter Value
No. of elements 10,000
No. of Nodes 9,786
Element size 0.03 mm
Fracture steps 1
No. of fracture elements 4
Remesh criteria Every 0.02 mm of the punch penetration
In addition, mesh elements were stacked as 
closely as possible with the use of mesh windows 
to raise the total number of elements in the shearing 
zone. 
For both piercing and notch shear cutting 
processes, the distribution of zones and the cutting 
load values were estimated after conducting both 
computational and experimental work.
The numerical analysis phase of the notch 
shear-cutting process required two sequential steps 
to duplicate experimental conditions for the most 
accurate results. Fig. 10 shows the steps applied 
during the computational work of notch shear cutting. 
First, it was necessary to push the predefined notch 
indenter into the workpiece (Fig. 10a) and produce the 
indentation (Fig. 10b). The notched workpiece was 
then placed in a typical piercing setup (Fig. 10c) and 
the following steps were carried out (Fig. 10d). 
a) 
b) 
c) 
d) 
Fig. 10.  The steps of simulation process; a) formation of notch  
at the downside of the workpiece, b) notched workpiece,  
c) conventional piercing, and d) completion of the process
3.1  Ideal Crack Condition
During a shearing operation, the fracture of the 
material begins at the corners of the punch and 
die that are in contact. The creation of a fracture 
propagates rapidly, resulting in the separation of 

Strojniški vestnik - Journal of Mechanical Engineering 69(2023)7-8, 326-338
333 Finite Element Analysis of Notch Depth and Angle in Notch Shear Cutting of Stainless-Steel Sheet 
Fig. 12 depicts a comparison of the change in 
cutting load between simulation and experimental 
tests. 
Fig. 12.  Comparison of required cutting load between 
computational and experimental work
The experimental and numerical findings were 
within 5 % range of each other on average. This 
was the outcome of the experimental environment’s 
external influences such as dust, additional friction 
between tools and load cell accuracy. The rest of the 
research was carried out with computational work 
once the measurements were verified to be identical.
Figs. 13 and 14 compare the zone distribution 
for conventional piercing and notch shear cutting, 
respectively.
Fig. 13.  Comparison of zone distributions between computational 
and experimental work (Piercing)
Fig. 14.  Comparison of zone distributions between computational 
and experimental work (Notch shear cutting)
The computational work was completed by 
following the outlined sequential stages to replicate the 
experimental work. First, three values of notch depth 
material at the intersection with the opposite corner. 
The ideal crack ( Φ) occurs when the required angle 
of crack propagation ( θ) is directed toward the punch 
and die cutting edges. In many instances, however, 
the real propagation ( β) of a fracture does not follow 
this anticipated pattern, resulting in secondary cracks 
that cause surface flaws on the workpiece. When the 
angle values of β and θ are closest, the optimal cutting 
condition may be attained.
This situation can be expressed in Eq. (7) as:
 Φ = β	–	θ ≅ 0 . (7)
The ideal crack propagation angle can be 
expressed in Eq. (8) as:
  









Arctan ,
c
tu
p
 (8)
where C is the clearance, t the sheet metal (workpiece) 
thickness, and u
p
 the punch penetration corresponding 
to the first crack initiation within the sheet. The 
directions of angle β and angle θ	were illustrated in 
Fig. 11.
Fig. 11.  Illustration of Ideal crack propagation angle ( θ) and real 
crack propagation angle ( β)
4  RESULTS AND DISCUSSION
Both experimental and numerical work were 
performed under the clearance value of 5 % of the 
workpiece thickness which was 2 mm, with a 10 mm 
lower die diameter and 9.80 mm punch diameter for 
conventional piercing with a punch speed of 1 mm/s.
Throughout the notch formation sequence, the 
hollow punch with a 60º notch angle, a notch tip 
radius of 0.5 mm, and a notch depth of 60 % of the 
workpiece thickness (1.2 ± 0.1 mm) was utilized. 
During the second phase (piercing after notch 
generation) of notch shear cutting, the same settings 
as with conventional piercing were employed.

Strojniški vestnik - Journal of Mechanical Engineering 69(2023)7-8, 326-338
334 Engin, K.E.
(15 %, 30 % and 60 % of the material thickness) and 
6 different notch angles (10º, 20º, 30º, 40º, 50º, and 
60º) with 0.5 mm notch tips were virtually penetrated 
to the downside of 1.4301 sheet with 2 mm thickness. 
After the material was notched, the piercing stage of 
the process was simulated using the configuration in 
which the lower die diameter was 10 mm, the punch 
speed was 1 mm/s, and the clearance was 5 % of 
the material thickness. As in the experimental study, 
the punch diameter was 9.80 mm, no radiuses were 
specified at the punch’s edges, and the tip of the notch 
was aligned with the punch’s cutting edge at shearing 
in every simulation.
Required cutting loads to shear the workpiece, 
fracture propagation angles and zone distributions 
were investigated. In cutting operations, cutting load 
is an important parameter that specifies the required 
loading capacity of the press and plays a crucial role 
in overall energy usage. It was discovered that the 
cutting loads necessary to shear notched materials 
were less than the load value for the piercing operation 
(28.5 kN). The deeper the notch penetrated into the 
material; the less cutting force was required at the 
sequential piercing step. This outcome was anticipated 
due to the reduction in material thickness following 
the creation of a notch in the workpiece. A 15 % notch 
depth resulted in the highest whereas 60 % notch depth 
resulted in the lowest required cutting load for each 
notch angle. For example, when the notch angle was 
fixed to 60º, the required cutting loads were obtained    
22.2 kN for 15 % notch depth, 16.6 kN for 30 % notch 
depth, 11.8 kN for 60 % notch depth, respectively. 
The effect of the notch depth on the required cutting 
load is unique to notch shear cutting, regardless of the 
workpiece shape, and is consistent with the literature 
[22]. Another observation was made on the effect of 
notch angles. Apart from the notch depth, the required 
cutting load decreases with increasing notch angle 
due to the decrease in the cross-sectional area of the 
workpiece between the punch and die. The changes 
in required cutting load according to notch depths and 
angles are given in Fig. 15.
Although it might be thought that a deeper 
notch has the advantage of a lower cutting load, it is 
important to remember that two phases are necessary 
to complete the entire notch shear-cutting process. If 
load comparisons were conducted exclusively for the 
shearing portion of the operation, it might be argued 
that a notch could reduce the cutting load. 
To account for each phase of the operation, 
however, 15 kN should be added to the total load 
values which was the average of the loads required 
to form the notch into the surface of 1.4301 sheet for 
each of the depths listed. 
Fig. 15.  Cutting load change according to notch angle  
and notch depth
Fig. 16 illustrated the disparities between the 
ideal angle ( θ) of crack propagation and the real angle 
( β) of crack propagation. 
Fig. 16.  The	dif f erence	be tw een	real	crac k	pr o pagatio n	angle	(β)	
and	ideal	crac k	pr o pagatio n	angle	(θ)
The best surface quality can be achieved when 
the difference between these two angles is closest to 
zero. 
The distribution of zones and the propagation of 
cracks are interrelated; therefore, an improper crack 
propagation difference will lead to secondary cracks 
and protruding surfaces.
Deform-2D can measure distances on the 
sheared workpiece in relation to zone distributions, 
and the character of the cut (smooth or protruded) 
can be clearly visualized and estimated by using the 
software’s post-processor section once the simulation 
is complete. Fig. 17 shows the shear zone percentage 
change according to notch depth and notch angle.
A comparison of Figs. 15 and 16 demonstrated 
that the difference between crack propagation angles 
and shear zone percentages were in correlation. For 
piercing processes, the optimal zone distribution 

Strojniški vestnik - Journal of Mechanical Engineering 69(2023)7-8, 326-338
335 Finite Element Analysis of Notch Depth and Angle in Notch Shear Cutting of Stainless-Steel Sheet 
(best surface quality) occurs when the rollover and 
crack zone lengths are minimal and free of burr 
formation while the shear zone length is maximal; 
15 % of the notch depth with 10º, 20º, and 30º notch 
angles resulted in burr formation, which was the least 
desirable outcome. The development of protrusions 
reduced as the notch angle increased, and at 50º the 
longest shear zone length and the shortest crack zone 
with almost no protrusions were reached. 
From Fig. 16, it was observed that the closest 
values to zero amongst all notch depths and all notch 
angles were achieved when notch angle value was 
selected as 50º and the notch depth value was selected 
as 15 % of the workpiece thickness. Fig. 17 confirmed 
this result, the shear zone percentage, 24.56 %, was 
also the highest at these values.
Fig. 17.  Shear zone percentage change according to  
notch depth and notch angle
The shear zone length of the specimen measured 
after piercing (22.6 %) could only be surpassed by 
using these values. This situation showed that a 
technical advantage can be obtained over conventional 
piercing with proper adjustments. The relationship 
between crack propagation angles and shear zone 
percentages was in accordance with previous studies. 
Using the angles of crack propagation, Hambli et 
al. [23] devised an algorithm for predicting optimal 
clearance. They established a tolerance convergence 
percentage of 1 % and stated that an optimal clearance 
could be reached when the difference between crack 
angles satisfied this value, indicating that no secondary 
cracks occurred, and good surface quality was 
acquired. Engin and Eyercioglu [24] and [25] studied 
the influence of different process parameters on 
1.4301 stainless steel sheets with different thicknesses 
and diameters. They observed that the best surface 
quality on the sheared workpieces was achieved when 
the difference between crack propagation angles was 
minimal. Fig. 18 displays the surfaces of sheared 
workpieces in relation to the notch depth, notch angle, 
and independently for piercing, as established by the 
Deform-2D software.
A further observation was made on another 
impact of notch depth. It was determined that the 
length of the shear zone dropped dramatically when 
the notch depth increased, independent of the notch 
angle. This is due to the workpiece’s pre-deformation 
during notch formation. 
When the workpiece was subjected to the 
conventional piercing phase, which was the second 
step of the process, shear and fracture zones were 
generated following the top portion of the notch. 
In the case of deeper notches, there remained a 
reduced region for shear zones to develop, and this 
was the main reason for the drop in shear zone length. 
Figs. 17 and 18 demonstrated that the crack zone 
dominated the surface and the shear zone decreased 
below 7 % for notch angles between 40º and 60º and 
for 60 % notch depth. This case revealed that even 
though pre-deformation (notch) on the workpiece 
appeared to make the shearing region less affected 
during piercing, deeper notches were not a guarantee 
of high surface quality and notch angles should be 
taken into consideration.
Regardless of notch depth, notch angles 
determined the crack propagation course and, in 
turn, affected the shear zone length. It was clearly 
understood that the obtained results depended on 
the combined effect of notch angle and notch depth 
values. For every notch depth value, the notch angle 
difference altered the crack propagation. As indicated 
before, for 15 % notch depth, lower notch angle values 
resulted in burr formation. When notch angle values 
increased, burr formations started to reduce up to a 
limit where the best surface quality could be obtained. 
In the event of higher notch depths, such as 30 %, the 
shear zone lengths decreased incrementally from 15 % 
to 10 % between 10º and 30º notch angles but reached 
their peak at a 40º notch angle with a length value of 
22.43 %, and then started to decrease again. 
This situation showed that for every value of 
notch depth, there exists a notch value at which the 
shear zone length could reach its peak height. 
This criterion was met with a 50º notch angle at 
15 % notch depth, a 40º notch angle at a 30 % notch 
depth, a 20º notch angle at a 60 % notch depth for 
1.4301 sheet, respectively.
However, it should be clearly stated that the 
general form of the sheared surfaces is also an 
important parameter. As mentioned before, the 
primary objective was to obtain the best possible 
surface quality to transcend conventional piercing. 
For deeper penetrations such as 30 % and particularly 

Strojniški vestnik - Journal of Mechanical Engineering 69(2023)7-8, 326-338
336 Engin, K.E.
60 % notch depths, the increase in the notch angle 
resulted in the reduction of burr formation; however, 
the form of the workpiece gradually deteriorated 
and took a conical shape at the downside. This 
circumstance is equally undesirable. At high values 
of notch depth, it must be considered that the use of 
wider notch angles may result in the deformation of 
the sheared material’s shape.
Typically, the outputs of piercing/ shearing 
processes are restricted to the parameters applied 
specifically for that workpiece material. The same 
situation applies to this research. In terms of zone 
distributions, a 50º notch angle and 15 % notch 
depth outperformed the shear zone length value 
of conventional piercing to produce the greatest 
surface quality and form. However, it is limited to 
Notch depth [°]
Notch angle [%]
Piercing
15 30 60
10
20
30
40
50
60
Fig. 18.  Visual representation of sheared parts as a function of notch depth and notch angle generated by the Deform-2D software

Strojniški vestnik - Journal of Mechanical Engineering 69(2023)7-8, 326-338
337 Finite Element Analysis of Notch Depth and Angle in Notch Shear Cutting of Stainless-Steel Sheet 
1.4301 sheets if and only if these conditions are 
satisfied. Any change in the notch forming position, 
clearance, punch/die diameters, shearing speed and, 
most importantly, the workpiece material modifies 
every effect and may result in varied outputs. Due to 
the interdependent interactions between regulating 
parameters, it is difficult to establish an optimal setting 
for shearing and cutting operations that accounts for 
all process variables and workpiece materials.
5  CONCLUSIONS
The main aim of this study was to determine the 
effect of notch angle and notch depth on the surface 
distribution and required cutting force during notch 
shear cutting of 1.4301 stainless steel sheet workpieces 
to fill a gap in the literature due to an absence of 
research on notch shear cutting of commonly used 
stainless steels. Compared to piercing, notched 
shear cutting is a relatively novel method for cutting 
metal sheets. Conventional piercing and notch shear 
cutting were carried out to compare the results to 
those obtained from simulations. The remainder of 
the study is then completed virtually. Using Deform-
2D software, a FEM study of notch shear cutting was 
performed for three different notch depths (15 %, 
30 %, and 60 % of the workpiece thickness) and six 
different notch angles (10º, 20º, 30º, 40º, 50º, and 60º). 
The results obtained in this study are summarized 
below.
•	 For specimens with deeper notches and wider 
notch angles, the required cutting load was 
observed to decrease. In addition, cutting 
specimens with notches required less load 
than conventional piercing. This is a direct by-
product of the material’s decreased thickness 
due to the notch formation on the workpiece. 
Due to the progressive nature of the operation, 
the load applied during notch formation must be 
added to the total value of the required cutting 
load, resulting in an increase in total energy 
consumption. In addition, it may take longer to 
complete the whole process than piercing, which 
is not a progressive operation like notch shear 
cutting. 
•	 There was an ideal value for each notch depth 
and notch angle at which the sheared surface 
was as good as possible in comparison to the 
other values for these two parameters. This 
condition was achieved at a 50º notch angle for 
a 15 % notch depth, at a 40º notch angle for a 30 
% notch depth, and at a 20º notch depth for 60 
% notch angles, respectively. In contrast to the 
ideal values, however, values that depart from 
them might lead to increased surface flaws. In 
addition, the specimen’s base became conical due 
to the increasing notch depths and notch angles 
(such as 60 % notch depth and 60º notch angle) 
which is undesirable. The shear zone length of the 
specimen estimated after piercing (22.6 %) could 
only be exceeded by notch shear cutting with a 
50º notch angle and 15% notch depth (24.4 %). 
The remaining shear zone values were inadequate 
for shearing 1.4301 sheets when compared to 
conventional piercing.
•	 If surface quality is of the highest significance 
and no rework of the produced workpieces is 
necessary during the production, notch shear 
cutting can produce better results than piercing, 
particularly in preventing burr forms. However, 
to attain the maximum shear zone length with 
no burrs, preliminary work should be conducted 
prior to application, since any uncorrected value 
may cause the shear zone to be shorter than 
piercing. Hence, obtaining the optimal settings 
is a complex and expensive operation to be 
accomplished through experimental trial and 
error, FEM simulations are required to conduct 
the work. Nonetheless, it is a time-consuming 
endeavour. Notch shear cutting seems feasible 
when utilized for mass manufacturing.
•	 All findings are explicitly limited to the shearing 
of 1.4301 stainless steel sheets and under the 
specified parameters. Any change in the material 
properties or unstudied aspects, such as notch 
position, various clearance values and cutting 
speed, might substantially vary the obtained 
results.
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