4-3-2011.pdf


Al-Qadisiya Journal For Engineering Sciences       Vol. 4    No. 3    Year 2011

NEW WAVE OF CAD SYSTEMS AND ITS APPLICATION IN
DESIGN

Ass. Lecturer  Mahmoud  A .Hassan
Al-Qadisiyah University
College of Engineering
hasaaneng@yahoo.com

ABSTRACT
This paper provides some lighting needed for the implementation of the new wave of CAD

systems with emphasis on a general application as well as advanced. It is known that a
computational approach is used in both design and education so step-by-step examples are
introduced. Although the CAD systems are available but it needs a sound knowledge of many
subjects such that: strength of materials and machine design. This work depends on the torsion
theory but the input geometry was done inside the SolidWorks environment. The proper use of the
CAD tool needs to start from a published case and construct many models in order to reach the final
one. The process was done by exporting the geometry to other sophisticated engineering tools:
ANSYS The adequacy of the obtained results was obtained by comparing with the theoretical data.
Complex cases in both geometry and materials properties like plasticity are presented. Combining
these systems with the teaching subjects deepens the engineering knowledge in the design and
education.

KEYWORDS: CAD Systems, SolidWorks, ANSYS, Design.

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Al-Qadisiya Journal For Engineering Sciences       Vol. 4    No. 3    Year 2011

NOMENCLATURE
eq  Equivalent stress (N/m

2)

xy yz zx Normal stresses on the axises (N/m
2)

xy yz zx: Normal shear on the axises (N/m2)
: Principal stresses (N/m2)231

Ø : Shear strain
: Angle of rotation (rad)

r: Radius of shaft (m)
L: Length of the shaft (m)

INTRODUCTION
The simplicity of the new CAD systems and its high advanced simulation in much practical

application make these systems to be an engineering design tool. Although they depend on the finite
element method (FEM) as background for solution they can be used with minimum knowledge of
the method. The theory of the FEM stands behind the stage to enable the domination of the
engineering sense.
The direct link between the CAD geometry and the finite element package meshing and analysis is
a powerful step in design. The output graphic contours give a very good indication to modify or
accept the design
Liking the geometry from CAD system According to (solid work2007) with the high level of the
work like (Ansys ll 2009)is the key for many engineering analysis

STRESS CRITERIA
The criteria of failure of the design like maximum acceptable deformation, minimum natural

frequency and maximum stress level are our indications in designing a component. The stress
criteria are the essential player. Since the yield stress taken from stress-strain curve can be
compared directly to the equivalent stress taken from the stress criteria, a safety factor of the whole
component immediately appears.
Many useful books likes them of (George E.Dieter, 1988) linked the materials properties
The best stress criterion in the metal design is the Von Mises. It can be calculated from the state of
stresses at any point as:

 (1)

Or from the principal stresses as:

(2)

Assuming the material behaves with direct relation between the stress and the strain
as in the Figure( 1), the only material parameters we need to input are the modulus of elasticity and
the Poisson's ratio.

3-D TORSION
When a beam or shaft subjected to twisting moment (torque), the torsion is the stresses of that load.
The main features of the torsion problem are the shear stresses, the angle of rotation and the angle
of twist.
So, the 3-d stress analysis is the general procedure to find out the real response of the beam. There
are many direct stress formula to calculate the torsion but for uniform cross-section. The use of

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Al-Qadisiya Journal For Engineering Sciences       Vol. 4    No. 3    Year 2011

torsion machine test monitors the angle of twist and other parameters but it is limited as it is a lab
work.
A practical examples of torsion are demonstrated here as a 3-d stress analysis.
The book by (Paul M. Kurowisky 2005) given many useful examples but it needs more advance
approach for engineering problems

TORSION OF BEAM BOX
Four beams each of square cross section of 150 inches in length constructing a beam box of 1500
inches and a thickness of 3 inches. The torque applied is 300 lb.inches
Figure( 2) shows the geometry of the beam box.
A good study of torsional behavior of rectangular hollow section by (Daniel J Ridley-Ellis, John S
Owen & Gwynne Davies, 2002)
The mesh of the box beam is shown in figure (3)
The shear stresses are shown in figure (4)
Figure (5) shows the total deformations of the model
The angle of rotation is given by

(3))/2(sin 1 rs

The relation between angle of twist and angle of rotation is taken from the strength of material
subject

lr /  (4)
R.S. Khurmi,2010).
Where s is the total deformation, r and L as shown in the figure (6)

BAR OF TRIANGULAR CROSS-SECTION
The sketch of 300mm cantilever bar cross-section is shown in figure (7)
The mesh of the this bar is shown in figure(8)
The steel bar was subjected to a torque of 2MN.mm
The equivalent stresses are shown in figure (9)

ELASTOPLASTIC ANALYSIS
In elastoplastic analysis, we have to introduce the stress-strain curve, This analysis is an advanced
tool which need a special treatment books of (Timoshenko, 1983) deals with  the case of exceeding
the elastic limit
The bilinear isotropic hardening type of plasticity was considered to cantilever bar as shown in
figure 10 .
The plastic strain are shown in figure 11

DISCUSSION OF RESULS
The stress analysis tool used is claimed to be aimed to students and designers. It is supposed to help
during the modeling work and not to be used as a final calculations tool. This work shows that this
is the case. The main advantage in this software is that it is very easy to use. The modeling is very
fast, although the solving time can be very long, especially when using result convergence. To get
the exact values of the stresses it is shown that one need to use the result out of analytic case with as
in the case of the torsion of the box beam.
Changing the cross-section area of the beam to another shape is a straight forwards task as in the
torsion of triangular cross-section beam.
During the early modeling work it is therefore always necessary to use a simple start. When
students use the analysis tool to get a hint if the model works, the exact published values are so



Al-Qadisiya Journal For Engineering Sciences       Vol. 4    No. 3    Year 2011

interesting to get out of modeling. It is shown here that the software gives very good results when it
comes to non-linear analysis. The problem of plasticity could be analyzed by introducing the real
stress-strain curve or even by using an approximate curve as the bilinear isotropic curve used with
the cantilever bar. There is one remark with this software. One cannot control the real mesh size,
only the relative size. It is a good custom to start with the default mesh of the software then refining
the mesh and checking the results until convergence specially with complicated shape models.

CONCLUSION
The method presented in this paper makes it possible to compute the torsion parameters

without of any control of elements or nodes. Importing of complex geometry from the CAD
package can be performed immediately. It has lots of automation for applying complex, realistic
load and boundary conditions easily.

There is no limit of the applications of these CAD systems in design. The practical importance of
the procedure lies in the simplicity and integrity

REFERENCES
 [1] George E. Dieter, Mechanical Metallurgy, 3rd Edition, McGraw-Hill Company, 1988

[2] Paul M. Kurowisky, Engineering Analysis with Cosmos Work Professional, SDC        Publications, 2005

[3] Daniel J Ridley-Ellis, John S Owen & Gwynne Davies, Theoretical and measured torsional  behaviors of
Rectangular Hollow Sections, Proceedings of the International Offshore and Polar Engineering Conference,
Japan, 2002

[4] Timoshenko, Strength of materials, 3rd Edition, Krieger Publications, 1983

[5] R.S. Khurmi, Strength materials, 23Editionm, S. Chand and Company LTD, 2010

[6] Ansys WorkBench Version 11 Documentation

[7] SolidWorks2007 Documentation.

Fig. (1) elastic and elastoplastic stress-strain curve



Al-Qadisiya Journal For Engineering Sciences       Vol. 4    No. 3    Year 2011

Figure (2) The beam box

Fig. (3) mesh of the beam box



Al-Qadisiya Journal For Engineering Sciences       Vol. 4    No. 3    Year 2011

Figure (4) The shear stresses in the x-z plane

Fig. (5) the total deformation of the beam box



Al-Qadisiya Journal For Engineering Sciences       Vol. 4    No. 3    Year 2011

Fig.(6) the geometric parameters of a shaft under torque

Fig. (7) cross-section of a the bar

Fig. (8) mesh of the bar



Al-Qadisiya Journal For Engineering Sciences       Vol. 4    No. 3    Year 2011

Fig.(9) Von-Mises stresses along the bar

Fig. (10) the elastoplastic stress-strain curve

Fig. (11) the plastic stain of the bar