Modeling and simulation of a spherical bearing mount.
Mihailidis, Athanassios ; Pupaza, Cristina ; Nerantzis, Ioannis 等
1. INTRODUCTION
Contact technology is a powerful functionality implemented in
advanced solvers which assists the user to obtain realistic simulation
results for complex assemblies and geometries. Formula SAE race cars
components such as spherical bearing mounts are special machine elements
requiring performance, reliability and safety. These assemblies are used
more than 70 times in a race car design. Modeling and simulation are
necessary in order to verify the suitability to the applied load and the
possibility of using smaller size mounts for future releases of the race
cars. Although recent structural reports regarding the mechanical
systems of race cars are available (Hill et al., 2001) (Johnson, 2003),
no information about spherical bearing mounts and bolted
highly-prestressed joints are included. Finite element analysis for
bolted joints (Kim et al., 2007), taking into account the pretension and
friction with different types of contact elements has been reported, but
simplified models were included in the assembly in order to reduce the
dimension of the model. The paper deals with modern contact technology
procedures applied on a spherical bearing mount, emphasizing the
efficiency of this functionality. Remarks regarding possible links with
optimization procedures integrated in solvers are also included.
2. SPHERICAL BEARING MOUNT
The A-arms, the pushrods, the shock absorbers and various levers of
modern formula SAE race cars are connected to the chassis, bell cranks
or wheel uprights by ball joints, also known as spherical bearings. The
spherical bearing mount considered in this study is supplied by Askubal
which provides the requiring technical data (Askubal, 2008).
Figure 1 shows the bearing mount. The outer ring is press-fitted to
a carrying ring which is welded to the carrying part (i.e. the A-arm or
the pushrod etc.). It is secured axially by deforming the lips, which
have been manufactured at both faces of the carrying ring. This design
has proved to be compact, light, reliable and cost effective. No further
investigation is needed. The inner ring is typically attached in a
U-holder or between two thin metal sheets with a thickness of 1,5-3 mm,
by using two identical spacers and a bolt. The cylindrical portions of
the spacers have a thickness of just 1 mm and are press-fitted, 0,015 mm
oversize, in the inner ring.
[FIGURE 1 OMITTED]
Due to their small thickness, their effect on the clearance of the
spherical bearing can be neglected. The load is transmitted from the
spherical bearing to the sheets entirely by the friction on the faces
A1, A2 and A3, A4. The required normal force is applied by the bolt,
which is mounted through the sheets and the spacers. The racing versions
of spherical bearing mounts are made of hardened steel and they operate
without clearance. Their attachment has to fulfill the following design
requirements: the connection must be completely clearance free, the
A-arms, the push-rods and the shock absorbers should be easy to
disassemble and reassemble.
3. MODELING AND SIMULATION
3.1 CAD and FEM models
The CAD model was completed using Autodesk's Mechanical
Desktop and Inventor, modifications were done in SolidWorks 2007 and
solved with ANSYS. Friction coefficients with a value of 0,12 were
included in the model for the faces A1, A2 and A3, A4 and between the
outer and inner ring a 0,04 value was considered. Corresponding
materials were properly assigned, as follows: the spacer--30CrNiMo6 with
[R.sub.p0,2]=1050N/[mm.sup.2], and the inner ring--100Cr6 hardened
steel.
[FIGURE 2 OMITTED]
Several load cases were performed. Finally, the bolt pretension was
20 KN, and the force acting on the carrying part was 2kN, when the
carrying part is 10[degrees] right positioned. Figure 2 shows the FEM
model which contains 144490 nodes and 36868 elements. Contact sizing,
refinement and hexahedral dominant mesh options were chosen in order to
obtain a sufficient refined mesh. The final error estimation energy,
which gives information for optimizing the mesh density was also
processed and controlled. No penetration between parts was detected.
3.2 Contact nonlinearities and FEM procedure
Contact conditions in assemblies are severe form of nonlinearities.
The algorithm used for solving boundary or contact nonlinearities is the
Newton-Raphson procedure. The finite element discretization yields a set
of simultaneous equations:
[K ]{u} = {[F.sup.a]} (1)
where [K]--coefficient matrix; {u}--vector of unknown DOF values,
{[F.sup.a]}--vector of applied loads. Equation (1) is nonlinear because
[K] is a function of unknown degrees of freedom values and can be
written (Bathe, 1996):
[[K.sup.T.sub.i]]{[DELTA][u.sub.i]} = {[F.sup.a]} -
{[F.sub.i.sup.nr]} (2)
{[u.sub.i+1]} = {[u.sub.i] + {[DELTA][u.sub.i]} (3)
where [[K.sup.T.sub.i]]--Jacobian matrix (tangent matrix);
i--subscript representing the current equilibrium iteration;
{[F.sup.nr.sub.i]}--vector of restoring loads corresponding to the
element internal loads. The solver options were: iterative, contact
stiffness updating after each iteration, weak springs included to
facilitate solution, preventing numerical instability, force convergence
value, contact interface treatment: add offset value, no ramping.
3.3. Results
Figure 3 contains a plot of the equivalent von-Mises stress, on the
pre-tensioned bolted joint. When processing the results, the sheet
bracket was hidden in order to show the contact stress distribution. The
maximum von Misses stress was 473 MPa and the maximum normal stress 137
MPa. The highest value of the stress acts on spacers, parts manufactured
from materials with excellent strength characteristics: tensile yield
strength [[sigma].sub.yield]=789 MPa, and tensile ultimate strength
[[sigma].sub.u]=1050 MPa.
[FIGURE 3 OMITTED]
3.4. Verification
Because the big number of spherical mounts included in the SAE race
cars and the high levels of the stress obtained multiple checks were
performed. The theoretical value for the displacement along Z axis was
0,0246 mm and the value obtained through simulation was 0,0241 mm (Fig.
4.). The error can be considered even lower taking into account that the
pre-tensioned bolt assembly was modeled as a bar under tension.
[FIGURE 4 OMITTED]
This allows the reduction of the spherical bearing mount size
without an increased potential for failure, but additional checks
regarding the dynamical behavior of the assembly are necessary,
especially when the load is applied with shock.
4. COUPLING CONTACT ANALYSIS WITH OPTIMIZATION PROCEDURES
Recent contact features implemented in solvers allow the user to
rapidly obtain stress evaluation in complicated assemblies, but handling
and maintaining the parameters definition is not easy. Usually, when
transferring data between CAD-CAE systems the definition of the
parameters in a text format is not available anymore. The DS option
allows the definition of geometrical parameters in a late stage of the
design without returning to the CAD system. This is an important
advantage because parametrical optimization procedures can be accessed.
5. CONCLUSION
The research revealed the possibility of using smaller size bearing
mounts for future releases of the race cars, which means the reduction
of the total weight. Contact technology supports the designer in rapidly
evaluating solutions, and allows the reduction of the total weight of a
product in cases were reliability, safety and integrity are required.
The procedure has the following advantages: it is simple and fast; no
assumptions have to be done regarding the load input and no empirical
factors have to be used. Mesh quality in the contact region is
controlled, model parameterization is possible and the user can edit the
solver input file. Future development of the procedure in optimization
loops has also been investigated. The possibility of applying the same
procedure to internal spur gears was already done and promising results
are in progress.
6. REFERENCES
Askubal (2008). Rod ends and spherical bearings. Available from:
http://www.askubal.de. Accessed: 2008-04-12
Bathe, J.K. (1996). Finite Elements Procedures, Prentice-Hall Inc.,
ISBN 0-13-301458-4, New Jersey, USA
Hill, J.; Binderup, A.; McBride, H.; Nimmergut, B. (2001). American
Solar Challenge, PrISUm Odyssey Structural Report, Available from:
http://xnet.rrc.mb.ca/solacar/ downloads/structuralReport.pdf. Accessed:
2008-03-06
Johnson, D. (2003). American Solar Challenge 2003 Structural
Report. Team Lxu, Yale University 10 Marston Hall, Ames, Iowa 50011.
Available from: http://www.eng.yale.edu/TeamLux/TLProject_Web/docs/4-JL_Structural_Report.pdf. Accessed: 2008-03-10
Kim, J.; Yoon, J. C. & Kang, B-S. (2007). Finite element
analysis and modeling of structure with bolted joints. Applied
Mathematical Modeling, Vol. 31, Issue 5, May 2007, p. 895-911. Elsevier
Inc., Available from: http://www.sciencedirect.com/. Accessed: 2008-04-1
