Laminate object manufacturing vs. fused deposition modeling--machine comparison.
Pilipovic, Ana ; Sercer, Mladen ; Stojanovic, Ivan 等
Abstract: Products made by additive manufacturing are increasingly
replacing the products made by classical procedures of polymer
processing. The current market requires the products to be of good
mechanical properties, low prices, and complicated geometry. With the
procedures such as Fused Deposition Modelling and Laminated Object
Manufacturing it is possible to produce a product of relatively low
price and good mechanical properties. In practice it is impossible to
avoid using the products in various atmospheric conditions (e.g. UV
radiation and humid environment) either intentionally or
unintentionally. The UV light, the Sun being its usual source,, and the
average humidity of countries worldwide can vary from 20% to 90%
depending on the weather, day and geographic location. It is therefore
necessary to determine how UV light, after a longer exposure, affects
the final mechanical properties of the products. A comparison of tensile
strength and elasticity module of the test specimens in FDM and LOM procedures has been performed.
Key words: fused deposition modeling--FDM, laminated object
manufacturing, LOM, tensile strength, modulus of elasticity, UV light
1. INTRODUCTION
1.1. Fused deposition modelling (FDM)
Fused deposition modelling (FDM) is a rapid prototyping procedure
which was originally developed at the Advanced Ceramics Research (ACR)
Company in Tucson, Arizona, but was then significantly improved by the
Stratasys Company. The procedure starts from 3D CAD model, which is
sliced by computer software into horizontal layers. The filament (e.g.
polymer or wax) is supplied to the machine through a nozzle, which is
computer-controlled and in one layer it forms the raster of the item in
the respective layer. The material exits the nozzle in liquefied state
and at ambient temperature hardens quickly. The entire system is usually
in a heated environment. After making the first layer, the working bed
is lowered for the thickness of the new layer and the new layer is
extruded (Liou, 2008, Gibson et al., 2010, Pahole et al., 2005). In more
complex prototype geometry, the support structure may be used. In this
case a double extrusion head is used. The thickness of the layer depends
on the nozzle opening, material dosage and the rate of feeding the
material and it usually ranges from 0.18 mm to 0.5 mm (Gibson et al.,
2010, www.alexdenouden.nl). It is possible to extrude also biocompatible and/or biodegradable materials (e.g. polycaprolacton--PCL) and
elastomers and it is possible to simultaneously produce several
prototypes (Pahole et al., 2005, www.dimensionprinting.com). The
mechanical properties depend on the position of the prototype on the
working bed, especially in the direction of z-axis (Liou, 2008, Gibson
et al., 2010; Godec, 2005).
1.2. Laminated Object Manufacturing--LOM
The LOM procedure is used to manufacture a prototype by lamination and laser finishing (cutting) of materials such as paper, polymeric
films and foils, and metal laminates. With polymeric foils better
mechanical properties are achieved than with paper. The sheets are
laminated into solid blocks by adhesion-joining, clamping and ultrasonic
welding. (Liou, 2008, Kunwoo, 1999, Gibson et al., 2010). After a layer
(foil) has been deposited, the laser beam or knife cuts a part of the
material into the form of the finished product. The Company Solido from
Israel, in their laminated object manufacturing procedure use film on
which a layer of glue is applied, which is then cut by a knife into
adequate form. Then, an "anti-glue" layer is applied on
certain places where there is no prototype, i.e. the glue is
neutralized. The next film layer is applied and it is glued to the
previous one and the prototype is manufactured all the way to the final
layer. When the last layer is finished, the excess material is removed
from the prototype manually (Liou, 2008, Kunwoo, 1999, Gibson et al.,
2010, Godec, 2005). The LOM features small shrinkage, low residual
stress and warpage, allows fast manufacturing of big parts, the machines
do not use toxic materials so that no special area is needed, and the
prices of equipment and materials are low in comparison with other RP
procedures (Liou, 2008, Gibson et al., 2010, Cooper, 2001). The
mechanical and thermal properties are non-homogeneous due to the use of
glue between the layers, and during removal of unused material small
parts can be damaged, so that it is not possible to manufacture hollow
parts (Gibson et al., 2010, Pahole et al., 2005, Lim, 2002).
2. COMPARISON OF MACHINES FOR FDM AND LOM PROCEDURE
The Stratasys cheapest model of the device is Dimensional uPrint
from the uPrint family, the price of which is 12000 [euro] upward. The
device is based on the principle of FDM procedure and can make parts of
ABSplusTM material, but only in one colour (Ivory). The characteristics
of the uPrint device are: build size: 203 x 152 x 152 mm, layer
thickness: 0.254 mm, machine size: 635 x 660 x 800 mm, machine mass: 76
kg. (www.dimensionprinting.com).
The test specimens made by LOM procedure are made of PVC film. The
test bodies in LOM procedures are made on the SD 300 Pro machine,
produced by Solido, is a machine which can produce transparent
prototypes of PVC film, has small dimensions, and is practical for use
in offices. The price of the basic model Solido SD 300 Pro with the
basic set of materials is approximately C 11000. The characteristics of
the SD 300 Pro machine are: precision: 0.1 mm (in axis), layer
thickness: 0.168 mm, working area: 160 x 210 x 135 mm, machine size: 465
x 770 x 420 mm, machine mass: 45 kg (www.solido3d.com).
The printers have similar working volumes and price, which makes
them favourable for small companies. They belong to the class of
personal printers, which means that in service there is no
health-harmful impact on the environment, and the installation is
simple. The characteristic of both machines is the making of products of
smaller dimensions with recyclable material.
3. EXPERIMENTAL PART
To determine the mechanical properties, the tension tester
"Messphysik Beta 50 - 5" was used. The control unit was EDC 100, of maximal load force of 50kN. To determine the extension
properties the test specimen was fixed by the tester jaws and extended
with force F, at speed v = 5 mm/min, as defined by ISO 527:1993
standard.
The test specimens were produced in the working space of the
machine in the xy plane, of maximum height of 4 mm. The test included
the tensile stress and the module of elasticity of the test specimens
made by FDM and LOM procedure after natural exposure to UV light after
120 days and laboratory exposure to UV light after 42 days. According to
ASTM D3-424 standard, 1 hour of laboratory testing in the UV chamber
corresponds to 24 hours of natural exposure to UV light in Europe. Then,
the comparison was made with the test specimens that had not been
exposed to the light sources. The UV chamber model was SOLARBOX 1500e,
manufactured by ERICHSEN.
In the FDM procedure the acrylonitrile/butadiene/styrene (ABS)
material was used in the form of a wire, and in the LOM procedure
poly(vinyl-chloride) (PVC) sheet was used.
The comparison of the procedures (Fig. 1) shows that the tensile
strength in the test specimens made by the LOM procedure is better.
Also, after exposure to light, the adhesive between the layers was
additionally reinforced, thus increasing the tensile strength. In the
FDM procedure the strength is decreased, and it is half the amount of
the strength of test specimens made by the LOM procedure.
[FIGURE 1 OMITTED]
From the diagram in Fig. 2 the module of elasticity may be noted
which in the LOM procedure, after laboratory exposure to light
increases, while with natural ageing the module inexplicably decreases.
[FIGURE 2 OMITTED]
4. CONCLUSION
The limitation of this paper is in performing the comparison using
only one machine in each process and one type of material. However, the
choice is limited to the most popular pair of machines for FDM and LOM
processes and to the commonly used polymers.
Both printers have acceptable prices and give products of good
properties. In the LOM procedure, i.e. Solido, one should take into
consideration the reduction of mechanical properties in z direction and
the problems of removing the support material, which is sometimes
impossible to remove. Before the production itself, the geometrical
complexity of the product has to be analysed and the decision made about
its orientation and position, as well as of the direction of peeling
cuts. In the LOM procedure, one of the negative characteristics is the
impossibility of recycling of the PVC sheets with the additions of
adhesive between the layers.
The FDM procedure in the test machine is limited by the choice of
the material and the roughness important for the FDM technology. The
removal of the supporting material has been solved by simple dissolution
in water solution, but this system raises the price of the machine
itself.
By comparing the carried out tests it may be concluded that the
tensile properties are significantly lower than in products made by
classical procedure of polymer processing. However, today's market
requires output of products in the shortest time possible, which gives
additive technologies additional advantage. The exposure to various
atmospheric influences (UV radiation) results in the reduction of the
properties in the FDM procedure, whereas in the LOM procedure these
properties are improved, which is the reason for the solidification of
the adhesive layer between the laminates.
5. ACKNOWLEDGEMENT
This work is part of the research included in the project
Increasing Efficiency in Polymeric Products and Processing Development,
which is part of the program Rapid Production -From Vision to Reality
supported by the Ministry of Science, Education and Sports of the
Republic of Croatia. The authors would like to thank the Ministry for
the financing of this project. The work of the last author is also
partly financed by the European Union - European Social Funds.
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*** (2011) http://www.alexdenouden.nl, Accessed on: 2011-03-19
*** (2011) www.dimensionprinting.com, Accessed on: 2011-07-15
*** (2011)http://www.solido3d.com, Accessed on: 2011-07-15
