Version 1.0 6/18/2008 1 Adams/Car Tutorial Modifying Suspension Hardpoints Overview In ADAMS/Car hardpoints are the building blocks for larger components. The hardpoints are essentially the joint locations for the parts of the vehicle. In ADAMS/Car you will move suspension hardpoints to change suspension kinematics, steering hardpoints to change steering characteristics, etc. For example, you can move the outer steering tierod connection to the upright to adjust Ackermann steering. When you move a hardpoint, ADAMS/Car moves the joint location to the position you specify. The actual connections at the hardpoints are modeled as ideal joints with specified degrees of freedom or bushings with 6 degrees of freedom and joint stiffnesses. The FSAE and Mini-Baja frames have no role in defining hardpoint locations. Hardpoints mounted to the frame are all connected to a rigid chassis. The image of the frame has no structural role in ADAMS/Car. Common abbreviations found while modifying the suspension are found below. hp[lr] hardpoint left or right arb anti roll bar lca lower control arm prod push rod uca upper control arm Control Arm Hardpoints The suspension control arm geometry defines suspension properties such as roll center, motion ratio and camber profile. With ADAMS/Car you can adjust the control arm geometry by adjusting hardpoints and then simulate wheel travel to determine the kinematics for the new geometry. The FSAE model has independent suspensions front and rear. The Mini-Baja model has independent front suspension and an independent or rear swing arm suspension. To modify the control arm of an open suspension subsystem click Adjust>Hardpoint>Table and the Hardpoint Modification Table will appear. Warning: Remember to change your working directory before you begin this lesson. If you do not, Adams may not work correctly. Also remember to move everything you wish to keep from the working directory before you log off. See the Opening Files tutorial for more information.
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Version 1.0 6/18/2008 1
Adams/Car Tutorial
Modifying Suspension Hardpoints
Overview
In ADAMS/Car hardpoints are the building blocks for larger components. The hardpoints are
essentially the joint locations for the parts of the vehicle. In ADAMS/Car you will move
suspension hardpoints to change suspension kinematics, steering hardpoints to change steering
characteristics, etc. For example, you can move the outer steering tierod connection to the
upright to adjust Ackermann steering. When you move a hardpoint, ADAMS/Car moves the
joint location to the position you specify. The actual connections at the hardpoints are modeled
as ideal joints with specified degrees of freedom or bushings with 6 degrees of freedom and joint
stiffnesses.
The FSAE and Mini-Baja frames have no role in defining hardpoint locations. Hardpoints
mounted to the frame are all connected to a rigid chassis. The image of the frame has no
structural role in ADAMS/Car.
Common abbreviations found while modifying the suspension are found below.
hp[lr] hardpoint left or right
arb anti roll bar
lca lower control arm
prod push rod
uca upper control arm
Control Arm Hardpoints
The suspension control arm geometry defines suspension properties such as roll center, motion
ratio and camber profile. With ADAMS/Car you can adjust the control arm geometry by
adjusting hardpoints and then simulate wheel travel to determine the kinematics for the new
geometry. The FSAE model has independent suspensions front and rear. The Mini-Baja model
has independent front suspension and an independent or rear swing arm suspension. To modify
the control arm of an open suspension subsystem click Adjust>Hardpoint>Table and the
Hardpoint Modification Table will appear.
Warning: Remember to change your working directory before you begin this lesson. If you do not,
Adams may not work correctly. Also remember to move everything you wish to keep from the working
directory before you log off. See the Opening Files tutorial for more information.
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Below are the hardpoint tables for the FSAE and Mini-Baja front suspensions with the upper and
lower control arm hardpoints highlighted.
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Mini-Baja Swing Arm
The swing arm found on the Mini-Baja can not be simulated by its self. A full vehicle assembly
must be opened to simulate swing arm motion.
Pushrod, Bellcrank & Shock Hardpoints (FSAE)
When modifying the bell crank placement on the FSAE model you must enter the position of the
joint connection to the chassis (hpl_bellcrank_pivot) and a point to define the rotation axis
(hpl_bellcrank_pivot_orient). The other points defining the bell crank are the pushrod, anti-roll
bar and shock connections (hpl_prod_to bellcrank and hpl_shock_to_bellcrank). The
connection of the pushrod to the upright is hpl_prod_outer. The shock connection to the chassis
is hpl_shock_to_chassis. If you wish to design a pullrod suspension converting the pushrod
system is simply a matter of changing the geometry of the components. The image of the
bellcrank is defined by the positions of the bellcrank pivot, pushrod location, and anti-roll bar.
When these connections move the image of the bellcrank will update.
The Mini-Baja has a simpler suspension design and the shocks mount directly to the
control/swingarm and chassis. The shock is modeled with two hardpoints; one to the control
arm or swing arm and one to the chassis.
Anti-Roll Bar Hardpoints (FSAE)
The hardpoints of the anti-roll bar geometry is modified using the fsae_front_arb subsystem with
the exception of the connection to the bell crank (hpl_ arblink_to_bellcrank) which is modified
on the fsae_front_susp subsystem. The anti-roll bar bushing mount (hpl_arb_bushing_mount) is
listed in the fsae_front_susp subsystem but cannot be modified there. You will need to move the
hardpoint hpl_arb_bushing to coincide with the anti-roll bar system to insure the system works
properly. Having hardpoints hpl_arb_bushing and hpl_arb_bend at the same point works well.
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Steering Hardpoints
In the FSAE steering system the steering rack placement is defined by the location of the inner
tierods found on the front suspension subsystem. When the inner tierod positons move the rack
moves with them. The pinion and rack do no have to coincide to work properly. ADAMS uses
input and output communicators to relay the displacement information. The model has two
joints between the steering wheel and pinion, and can be placed with creating an angle between
intermediate shafts.
hpl_arb_bend
hpl_arb_middle
hpl_arb_bushing
hpl_droplink_to_arb
hpl_arblink_to_bellcrank
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The Mini-Baja steering shaft must be straight from the pinion (hps_pinion_pivot) to the steering
wheel center (hps_steering_wheel_center). Between the pinion and steering wheel center are
two intermediate points (hps_intermediate_shaft_forward and
hps_intermediate_shaft_rearward). You will need to move these points to create a straight
steering shaft from the steering wheel to the pinion. The shaft must be straight in order for the
steering to work properly. In the template the pinion and rack are coincident. This does not have
to be the case. You could move the steering rack and inner tierods forward and leave the pinion
Steering intermediate
joints
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and steering shaft in its original position. There does not have to be a visible connection between
the pinion and the rack.
hps_intermediate_shaft_forward
hps_intermediate_shaft_rearward
Pinion and rack are
coincident in template
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Modifying the FSAE Front Suspension
Obtain and save the FSAE template. Open ADAMS/Car and add the database to the session by
clicking Tools>Database Management>Add to Session. Navigate to the location you have
saved the FSAE template to add.
Open the FSAE front suspension assembly by clicking File>Open>Assembly. Navigate to the
FSAE assemblies.tbl folder and select fsae_front_with_steer.
The default units for the FSAE model are millimeter, kilogram, and newtons. Change the units
to inches, pounds mass, and pounds force by going to Settings>Units.
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Click the IPS button at the bottom of the window to change the units. Click OK.
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From the menu select Modify> Adjust> Table.
The Hardpoint Modification Table will appear. Click the arrow in the top center to see the
subsystems that have hardpoints that you can adjust. Notice the front suspension, steering, and
anti-roll bar subsystems make up this assembly and have hardpoints you can modify. The origin
for the assembly is at an arbitrary location. Placement of the hardpoints will need to be made
relative to other hardpoints in the suspension.
Subsystems
Hardpoints to show
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At the bottom left of the Hardpoint Modification Table you have the option to view the left,
right, or both sides of the vehicle. If left or right is selected then you will be entering changes for
that side of the vehicle but changing both sides symmetrically. To modify the hardpoints for the
front suspension make sure fsae_front_susp is selected and simply enter a new value for the
loc_x, loc_y, or loc_z positions. Then click OK or Apply to make the changes.
Six points determine the control arm geometry at one wheel. For the upper and lower control
arms there are outer, front and rear hardpoint locations. The names for theses hardpoints are
hpl_lca_front, hpl_lca_outer, hpl_lca_rear, hpl_uca_front, hpl_uca_outer, and hpl_uca_rear.
New position values can be entered into the table.
Looking at the model space, notice the coordinate axes at the bottom left-hand corner of the
window has the positive x-direction towards the rear and the positive y-direction towards the
right from the driver’s perspective. Obtain a front view of the assembly by right clicking on the
workspace and selecting Front. With the Hardpoint Modification Table open change the loc_y
values for hpl_uca_front and hpl_uca_rear from -7.876 to -12 and click Apply. Notice that the
inboard upper control arm connections have been moved outward from the center of the vehicle
thus shortening them.
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Now adjust the outboard lower control arm connection changing both the kingpin and caster
angles. Reduce the kingpin angle by making the loc_y value for hpl_lca_outer -26 and observe
the change in kingpin. Now obtain a side view of the assembly by holding “r” + left mouse
button to rotate. Change the loc_x position for hpl_lca_outer to -23, click Apply and observe the
increase in caster angle.
The pushrod, bellcrank, and shock parts in the template are not planar at the design position and
the pivot orient is not perpendicular to the face of the bellcrank. Make the following changes to
the system to create a planar system with a perpendicular pivot orient. When done making
changes click Apply. Rotate the system to confirm the pushrod, bellcrank, and shock are planar.