EDITOR’S CHOICE
MANUFACTURE OF VEHICLE PARTS
PAILTON
MOVING BEYOND PROTOTYPES
CAN 3D PRINTING BE USED IN THE MANUFACTURE OF SAFETY
CRITICAL VEHICLE PARTS?
In the United States, an epic backyard project
will see the creation of a life-size, functional
Lamborghini Aventador. The car is not
entirely 3D printed, but rather demonstrates
the impressive potential of 3D printing for
the wider vehicle industry. Here, Kostas
Poulios, Principal Design and Development
Engineer at Pailton Engineering, explains
how 3D printing is used in large vehicle
manufacturing and whether this method
could play a role in the production of safety
critical parts.
Outside of novelty projects, like the
Lamborghini example, 3D printing is already
an important part of vehicle production.
From tooling, parts manufacture, design and
prototyping components, the industry is
widely considered a pioneer of integrating
3D printing into processes. However, the
same cannot be said for the production of
safety critical vehicle parts.
Consider the steering system as an example.
Steering systems are put through intense
conditions throughout their lifespan,
particularly when used in large vehicles like
military, utility and HGVs. Each part of the
system, including the drag link assemblies,
steering and suspension ball joints, and
bevel boxes must be able to withstand heavy
shock loads. In an ideal world, these systems
should also be designed to last.
Due to high shock loads, components
for steering systems cannot currently be
manufactured with some of the common
materials used for 3D printing — at least,
not to a useable standard. For instance,
Acrylonitrile Butadiene Styrene (ABS), a
thermoplastic filament which is regularly
used for Fused Deposition Modelling (FDM),
does not provide adequate properties for the
manufacture of steering system parts.
The material provides good levels of strength
and is lightweight but is simply not strong
or durable enough to be used in a steering
application. Instead, ABS modelled parts are
only suitable for rapid prototyping.
An alternative material would be the
option of Metal Matrix Composites (MMC),
a composite with at least two constituent
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PECM Issue 40
materials. When three or more
materials are combined, this is
known as a hybrid composite. This
option provides much higher levels
of strength, as several elements
can be combined to improve the
materials properties and ensure the
part meets its requirements.
For niche steering systems, such as
those used in HGVs, construction
and military vehicles, MMC
can provide designers with an
opportunity to expertly engineer
the metal their part will be made
from, while also reaping the advantages of
3D printing. This includes the potential to
topologically optimise parts to maximise
their strength-to-weight ratio. This is
particularly advantageous when used in
combination with other design tools, such as
Finite Element Analysis (FEA).
MMC printing could be used to manufacture
safety critical parts, like the ones used in a
steering system. However, MMCs require
the use of Selective Laser Sintering (SLS),
the process required to print components
from metal powder. Currently, this method
can be costly and time consuming for
manufacturers to implement, deeming it
unsuitable for large production volumes.
Looking into the future, when SLS 3D
printers become widely available and more
cost effective to use, this may change.
As in every optimised steering system,
whether that be an entire unit or individual
components, any work outside the
conventional manufacturing processes will
be more expensive. An exception to this
rule would be very low production volumes.
However, these cases are usually undertaken
with the intention of larger volume
production in the future.
When considering whether to implement
3D printing into parts production,
manufacturers must understand that the
advantages of that process might not
outweigh the initial cost. This is certainly the
current case for 3D printing for safety critical
parts. However, the method is valuable in
other areas of production.
3D printing is successfully used in the
design phase of safety critical components.
For example, Pailton Engineering uses a
HP DesignJet to create prototype steering
system components from ABS, including ball
pins, drop arms, steering wheels, suspension
joints and forgings.
In these cases, the 3D printed part is not
used for production, but is replaced with a
production equivalent once the design is
finalised.
3D printing is certainly present in vehicle
manufacturing. However, it is not necessarily
suitable for production of safety critical parts.
Instead, Original Equipment Manufacturers
(OEMs) should prioritise using safety critical
part suppliers, like manufacturers of steering
systems, that use the benefits of 3D printing
for prototyping and testing.
At Pailton Engineering, this process provides
our highly skilled design and production
engineers with a visual representation of
steering parts and assemblies.
This helps us to identify issues and
improvements before production begins
to provide customers with a right first-time
solution, every time.
For more information on Pailton
Engineering’s steering systems,
contact the team directly on
+44 (0) 24 7668 0445 or e-mail
[email protected].