International Journal of Engineering and Techniques - Volume 2 Issue 5, Sep – Oct 2016 RESEARCH ARTICLE
OPEN ACCESS
Design Modification and Analysis of Flywheel Using in Thresher Machine SIRGIREDDY CHINNAANKI REDDY1, N.KEERTHI2 1
M.Tech Student, Department of Mechanical Engineering, Assistant Professor, Department of Mechanical Engineering, Annamacharya Institute of Technology and sciences, Rajampet 2
Abstract: A flywheel is a mechanical device with a significant moment of inertia used as a storage device for rotational energy. Flywheels resist changes in their rotational speed, which helps steady the rotation of the shaft when aABSTRACT fluctuating torque : is exerted on it by its power source such as a piston-based engine, such as a piston pump, is placed on it. The flywheel are different types such as solid disk, Spoke type, rim type, tapered type. In solid disk flywheel type it is provided with hub and disk. Solid disk flywheels are less capable of storing energy. Then spoke type flywheel are capable of storing more energy with greater moment of inertia than any other type of flywheel. In this work solid disk, spoke type flywheel are designed by using CATIA software. The spoke type flywheel is modeled with 6 spokes and 5 spokes with and without taper. Structural analysis and Modal analysis by using ANSYS software is done to determine the stresses and frequencies respectively by considering the different materials Cast iron, Aluminum Alloy 6061 & S-glass materials. From the above analysis, the better material for the flywheel is determined.
I. INTRODUCTION A flywheel is an inertial energystorage device. It absorbs mechanical energy and serves as a reservoir, storing energy during the period when the supply of energy is more than the requirement and releases it during the period when the requirement of energy is more than the supply. Focuses on exploring the effects of flywheel geometry on its energy storage/deliver capability per unit mass, further defined as Specific Energy. Proposed computer aided analysis and optimization procedure results show that smart design of flywheel geometry could both have a significant effect on the Specific Energy performance and reduce the operational loads exerted on the shaft/bearings due to reduced mass at high rotational speeds. FE analysis is carried out for different geometry of the flywheel and maximum von misses stresses and total deformations are determined. Thresher machine much popular in Indian agriculture sector for threshing grains. Thresher machine are power driven constructed for separate the comb from grain. Thresher machine take power from electric motors or diesel engines. These machine are
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easily available in number of models by different output capacity. These machines used to separate the cob from grains. Now in India most of the farmer’s used thresher’s machine for threshing grain like soybean, maize, wheat, jawar, etc. In previous year farmer resort manual means of threshing, which results into less efficiency, more wastage and much cost spend on labor. Thresher machine constructed for separate cob from the grain. It was constructed from locally available and its cost is very low, affordable, easy transportable. II. MATERIAL SELECTION Due to the high density of cast iron the weight of the component is high. so it is necessary to reduce the weight of the component by considering high strength to weight ratio materials like aluminum alloy 6061 and s- glass. The material properties of these alternatives are shown in table 2.1.
Table 2.1: Material Properties Materi al
Density (kg/m3)
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Young’s modulus (MPa)
Poisson’ s ratio
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International Journal of Engineering and Techniques - Volume 2 Issue 5, Sep – Oct 2016 CAST IRON ALUMINI UM ALLOY 6061 S-GLASS
7810
240000
0.37
2700
68900
0.33
2.46
86900
0.28
III. MODELING 3.1 INTRODUCTION TO CATIA
Fig (3c): 5spoke without taper
CATIA is a one of the world’s leading high-end CAD/CAM/CAE software packages. CATIA (Computer Aided Three dimensional Interactive Application) is a multi-platform PLM/CAD/CAM/CAE commercial software suite developed by Dassault Systems and marketed world-wide by IBM.CATIA is written in the C++ programming language. CATIA provides open development architecture through the use of interfaces, which can be used to customize or develop applications. The application programming interfaces supported Visual Basic and C++ programming languages. Commonly referred to as 3D Product Lifecycle Management (PLM) software suite, CATIA supports multiple stages of product development.
Fig (3d): 6 spoke with taper
Fig (3e): 6 spoke without taper
IV. DESIGN CALCULATIONS FOR DIFFERENT TYPES OF FLY WHEELS BY USING THRESHER MACHINE 1. Various Functional values of solid disk flywheel Material: Cast iron
Angular velocity (ω) = 2×π×N/ 60 = 2×π×738 / 60 ω = 77.28 rad/sec Surface speed (vs) = π×D×N / 60 = π×0.500×738/ 60 vs= 19.32 m/s Energy stored in flywheel (Ek) = ½ × I total× ω2 = ½ × 2.865 ×77.28 2 Ek = 8.555KJ Fig (3a): Solid Disk
Fig (3b): 5SpokeWith Taper
Specific energy (Ek, m) = Ek/ Mtotal = 8.555/ 85.938. (Ek, m) = 0.099kJ/kg Energy Density (Ek, v) = (Ek/ Mtotal) × ρ = 0.099×7810 (Ek, v) = 777.48KJ/m3
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International Journal of Engineering and Techniques - Volume 2 Issue 5, Sep – Oct 2016
CAST IRON:
Spoke
Spoke
withou
with
withou
with
t taper
taper
t taper
taper
Flywhe
Flywhe
Flywhe
Flywhe
el
el
el
el
29.71
10.71
31.48
10.986
11.193
0.991
0.487
1.429
0.493
0.501
738
738
738
738
738
2.959
1.454
1.475
1.472
1.496
0.0996
0.135
0.135
0.134
0.133
268.92
366.61
365.97
361.80
360.87
TABLE1 Funct
Sol
Optimi
Optim
Optim
Optimized
ional
d
zed
ized
ized
Six
Mass(K
value
Fly
Five
Five
Six
Spoke
g)
s
whe
Spoke
Spoke
Spoke
with taper
Momen
Flywheel
t of
el
withou
with
witho
t taper
taper
ut
inertia(I
Flywhe
Flywh
taper
)
el
eel
Flywh
Kg-m2
30.98
31.48
31.778
N
eel Mass(
85.9
Kg)
38
Mom
2.86
ent of
5
32.378
(R.P.M. )
1.41
1.429
1.427
1.45
Kinetic energy(
inerti
E)
a(I)
stored
Kg-
KJ Spe.
m2 738
N
738
738
738
738
Energy KJ/kg
(R.P.
Spe.
M.) Kinet
8.55
ic
5
4.210
4.267
4.261
4.329
Density KJ/ m3
S-GLASS:
energ y(E) store
Functio
Solid
Optimi
Optimi
Optimi
Optimi
d KJ
nal
Flywh
zed
zed
zed Six
zed Six
values
eel
Five
Five
Spoke
Spoke
Spoke
Spoke
withou
with
y
withou
with
t taper
taper
KJ/kg
t taper
taper
Flywhe
Flywhe
Flywhe
Flywhe
el
el
el
el
Spe.
0.09
Energ
9
0.135
0.135
0.134
Spe.
777.
1061.3
1058.6
1046.5
Densi
48
3
5
4
0.133
1044.41
ty KJ/
Mass(g)
27.069
9.758
9.915
10.01
10.198
m3
Momen
0.903
0.444
0.45
0.449
0.457
738
738
738
738
738
26964
1.325
1.343
1.340
1.364
t of inertia(I )
ALUMINUM ALLOY 6061:
Kg-m2 N
TABLE2
(R.P.M. )
Functio
Solid
Optimi
Optimi
Optimi
Optimi
nal
Flywh
zed
zed
zed Six
zed Six
Kinetic
values
eel
Five
Five
Spoke
Spoke
energy(
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International Journal of Engineering and Techniques - Volume 2 Issue 5, Sep – Oct 2016 E) stored KJ Spe.
0.099
0.135
0.135
0.133
0.133
245.05
334.24
332.1
329.49
329.18
Energy KJ/kg Spe. Density KJ/ m3
TABLE 3
5.3a: strain
5.3b: strain
V. STRUCTURAL ANALYSIS 5.1
STRUCTURAL
FLYWHEEL
5,
6
ANALYSIS SPOKES
OF
WITH
&
WITHOUT TAPER MATERIAL – CAST IRON,, ALUMINUM ALLOY AND S-GLASS S
5.3c: strain
5.1a: Total Deformation
5.1b: Total Deformation
5.4b: Total Deformation
5.1c: Total Deformation
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5.4c: Total Deformation
5.2a:: stress
5.5a: stress
5.2b: stress
5.4a: Total Deformation
5.5b: stress
5.3c: stress
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International Journal of Engineering and Techniques - Volume 2 Issue 5, Sep – Oct 2016 FLY WHEEL 5SPOKES WITH TAPER TABLE 6 Material
5.5c: stress
Deformation
Stress
(mm)
(N/mm2)
Strain
Cast iron
0.00085004
1.2511
5.7912e-6
Aluminum
0.0010211
0.43619
7.0661e-6
0.0007353
0.40124
5.18e-6
alloy 6061
RESULTS TABLE FOR STRUCTURAL ANALYSIS
S-Glass
SOLID TYPE FLY WHEEL TABLE 4 Material
Deformation
FLY WHEEL 6 SPOKES WITH OUT TAPER Stress
TABLE 7
Strain
2
(mm)
(N/mm )
Cast iron
0.00015504
0.4205
1.7559e-6
Aluminum
0.00019786
0.14474
2.1123e-6
Material
Deformation
Stress
(mm)
(N/mm2)
Strain
Cast iron
0.00076355
1.4135
6.9717e-6
Aluminum
0.00091828
0.49595
8.409e-6
0.00066215
0.45897
6.093e-6
alloy 6061 S-Glass
0.00015274
0.13125
1.5592e-5
alloy 6061 S-Glass
FLY WHEEL 5 SPOKES WITH OUT TAPER
FLY WHEEL 6SPOKES WITH TAPER
TABLE 5 Material Cast iron Aluminum
Deformation
Stress
(mm)
(N/mm2)
0.00087526 0.0010512
1.5117 0.52656
TABLE 8 Strain Material
alloy 6061 S-Glass
Stress
Strain 2
(mm)
(N/mm )
Cast iron
0.00072998
1.1306
5.2326e-6
Aluminum
0.00087853
0.3917
6.3579e-6
0.00079954
0.35808
5.8558e-6
6.9587e-6 8.5049e-6
Deformation
alloy 6061 0.00075682
0.48468
6.2483e-6
S-Glass
5.7 COMPARISION OF DEFORMATION
The comparison of maximum deformation in all the cases considered here shows that’s S Sglass epoxy gives the least deformation while the aluminum alloy 6065 gives largest deformation.
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International Journal of Engineering and Techniques - Volume 2 Issue 5, Sep – Oct 2016 models of flywheel are less than the respective yield stress values of all materials. So using all materials and all models are safe under given working conditions.
Fig: 5.7: Comparison Of Deformation
5.8 COMPARISION OF STRESS
The comparison of stress in all cases considered here shows that’s. The stress values are less for solid type. When the weights are considered by using solid type, flywheel is heavier which results in mechanical losses. The weight of flywheel with 5 spokes without taper is less and also its stress values are within range, using flywheel with 5 spokes without taper is good.
By comparing the results between models of flywheel, the stress values are less for solid type. When weights are considered by using solid type, the flywheel is heavier which results in mechanical losses. The weight of flywheel with 5 spokes without taper is less and also its stress values are within range, using flywheel with 5 spokes without taper is good. By comparing the results between materials S – Glass is good due to its less stresses and deformations. By observing the modal analysis results, the deformation values are less for Solid type flywheel but the frequencies are more. If the frequencies are more, vibrations will increase. The flywheel with 5 spokes without taper has fewer frequencies, so using this model is good. By using the material Aluminum alloy 6061 is better since its frequencies are less than Cast Iron and S – Glass. So it can be concluded that flywheel with 5 spokes without taper is good and S – Glass material is good.
REFERENCES
Fig: 5.8 Comparison Of Stress
VI.
CONCLUSION
By observing the weight of the flywheels for different materials, flywheel with 5 spokes without taper and by using material S – Glass has less weight. By observing the structural analysis results, the stress values for all materials and for all
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