Rapid manufacturing of parts for wind tunnel testing using polyjet technology.
Udroiu, Razvan ; Dogaru, Florin
1. INTRODUCTION
In the last years, there have been substantial changes in
technology and its requirement. This changing environment created many
new needs and opportunities, which are only possible with the advances
in new materials and their associated manufacturing technology. Some of
these new technologies are RapidX (Udroiu & Ivan, 2008). Under the
umbrella of RapidX there are some specific terms uses in additive
fabrication such as: Rapid Product Development (RPD), Rapid Technology,
Rapid Nanotechnology, Rapid Prototyping (RP), Rapid Tooling (RT) and
Rapid Manufacturing (RM). Additive fabrication refers to a group of
technologies used for building physical models, prototypes, tooling
components and finished parts, all from 3D CAD data or data from 3D
scanning system.
The most popular RP technologies used worldwide are
stereolithography (SL), selective laser sintering (SLS), 3D printing
(3DP) and laminated object manufacturing (LOM). This paper is focused on
3DP technologies that represent 44.3% of all additive systems installed
worldwide at the end of 2005 (Wohlers, 2006). 3D printing technologies
can be divided in the following: inkjet printing, fused deposition
modelling and polyjet (Park, 2008).
Rapid prototypes can be used for design testing. For example, an
aerospace engineer might mount a model airfoil in a wind tunnel to
measure lift and drag forces. This paper presents some research
regarding the rapid manufacturing of products for wind tunnel testing.
2. MODELS FOR WIND TUNNEL TESTING
One of the most interesting and significant applications in the
aerospace, automotive and wind energy sectors is with no doubt the wind
tunnel model of products (aircraft, automotive or wind turbine) that can
be tested before an important investment in manufacturing. The role of
physical prototypes in the all industry sectors is essential.
A wind tunnel model needs to be manufacturing in a short time, with
good surface quality and from materials with good mechanical
characteristics.
Regarding of rapid prototyping applications for wind tunnel testing
there are some researches projects that have used different RP
technologies: stereolithography, selective laser sintering (SLS) etc.
The stereolithography process it was experimented (Landrum, 1997)
to manufacturing a NACA 0012 airfoil section. It was resulted a surface
finish with a noticeable distributed roughness as well as low chordwise
ridges due to resin overcure in at the build layer interfaces. In the
paper (Maheshwaraa et al., 2007) a UAV wing is fabricated using
Duraform(r) Flex material in an SLS machine and postprocessed to remove
unsintered powder. The UAV wing prototype is infiltrated using a mixture
of ST-1040A and ST1040B polyurethane to make the UAV wing air tight.
In order to develop a European tiltrotor in cooperation, the
companies AGUSTA and WESTLAND needed a prototype for wind tunnel
testing. This prototype was been realized at 1:8 scale by the Rapid
Prototyping Department of CRP Technology during the year 2007 (***,
2008), using SLS RP technology and WINDFORM GF materials (a composite
polyamide based material, aluminium and glass filled). Thus it was
possible to complete and test the model in the wind tunnel within a very
short time, with excellent results and with really high-performing
mechanical and aerodynamic properties.
This paper presents a new method for manufacturing aerodynamic
models used in wind tunnel testing, using Polyjet technology by Objet
Geometries.
3. POLYJET APPLICATION: RAPID
FABRICATION OF WIND TUNNEL MODELS
The various CAD packages use a number of different algorithms to
represent solid objects. To establish consistency, the STL format has
been adopted as the standard of the rapid prototyping industry.
First of all, it was designed the NACA airfoil section in
SolidWorks software. A particularity of the 3D model (figure 1) is a
series of small holes (0.8mm) on a high deep (127 mm). These holes are
useful to measure the air pressure on different locations of the wing
during the wind tunnel testing.
[FIGURE 1 OMITTED]
[FIGURE 2 OMITTED]
The basic methodology for all current rapid prototyping techniques
and of course for RP polyjet technology can be summarized in the
following steps as follows:
* Designing of CAD part and then converting it to STL file format;
* Simulating and optimising (orientation of the model on the build
try, material consumption and building time) the RP process. RP software
processes the STL file by creating thin sliced layers of the model;
* Building of the model layer by layer on RP machine;
* Cleaninig and finishing the model.
In the second step, build orientation is important for several
reasons. First, properties of rapid prototypes can vary from one
coordinate direction to another. In addition, part orientation
determines the amount of time required in building the model. Placing
the shortest dimension in the z direction reduces the number of layers,
thereby shortening build time. In this study case it was be done an
optimisation of the part orientation on the build tray to minimize the
building time and material consumption.
The RP software, in this case Objet Studio (figure 2) and Job
Manager, slices the STL model into a number of layers and generates an
auxiliary structure to support the model during the build.
Objet's PolyJet technology uses two different photopolymer materials for building models: one for the model, and another material
for support (figure 3). Support structure is useful for delicate
features such as overhangs, internal cavities, and thin-walled sections
or complicated geometries, such as undercuts.
[FIGURE 3 OMITTED]
In this case study, we were used EDEN 350 rapid prototyping/
manufacturing machine (figure 4) which is available at Transilvania
University of Brasov, Department of Manufacturing Engineering.
The FullCure materials used by Eden 350 3D printer offer excellent
flexibility, impact strength and transparency, producing durable models
suitable for snap fits and frequent handling. In figure 4 it is
presented a sequence from the 3D printing process.
The great achievement of Objet's PolyJet technology is that it
combines the advantages of two RP methods known so far
(stereolithography and 3D printing), once with the elimination of their
deficiencies. In summary the PolyJet process consists in the steps
presented as follow.
[FIGURE 4 OMITTED]
[FIGURE 5 OMITTED]
The PolyJet jetting head slides back and forth along the Xaxis,
similar to a line printer, depositing a single super-thin layer (16
microns) of photopolymer onto the build tray. Two UV bulbs, located side
by side the jetting bridge, emit UV light and immediately curing and
hardening each layer. This step eliminates the additional post curing
required by other technologies. When the build is finished, a WaterJet
easily removes the support material, leaving a smooth surface.
Using polyjet technology it can be obtained parts with very small
detail such as very thin walls (down to 0.4 mm) and small holes (up to
0.5 mm in diameter). Using other traditional or RP technology it is
difficult to obtain these small details.
The rapid prototypes obtained by polyjet technology can be
machining (milling, drilling, etc), gluing, painting and metal coating.
In this case the two side holes were threaded (figure 5) to allow
assembling the airfoil model within the wind tunnel.
Thus, polyjet technology can allow obtaining of aerodynamic models
that can be tested with good results within wind tunnel.
4. CONCLUSION
This work demonstrates that the polyjet rapid prototyping
technology can be effectively applied for fabricating test models that
can be used in aerodynamic experimental investigations. The models are
built with exceptionally high quality, accuracy and speed.
The next step will be focus on the fabrication of complex models
such as aircraft models, component for automotive industry (spoiler),
wind turbine blade models and so on.
5. REFERENCES
Landrum, B.; Beardt, R. M.; LaSarge P. A. & Sprecken N. (1997).
Evaluation of stereolithography rapid prototyping for low speed airfoil
design, AIAA-1997-719, Aerospace Sciences Meeting and Exhibit, 35th,
American Institute of Aeronautics and Astronautics, Reno, NV, Jan. 6-9
Maheshwaraa, U.; Bourell, D. & Seepersad, C., C. (2007). Design
and freeform fabrication of deployable structures with lattice skins,
Rapid Prototyping Journal, vol. 13, No. 4, pp. 213-225, Emerald Group
Publishing Limited, ISSN: 1355-2546
Park, R. (2008). Utilising PolyJet matrix technology and digital
materials, TCT Magazine, Vol.16, No.3, Rapid News Publications plc, ISSN
1751-0333, UK
Udroiu, R. & Ivan N., V. (2008). Rapid-X Using 3D Printers,
Supliment Of Academic Journal Of Manufacturing Engineering, No.2 /2008,
pp.199-205, ISSN 1583-7904 Romania
Wohlers, T. (2006). Wohlers Report 2006: Executive summary, Rapid
prototyping & manufacturing. State of the industry, TCT Magazine,
Rapid News Publications plc, ISSN 17510333
***, (2008). 1:8 Scale Wind tunnel model of the external fairing of
the European tilt rotor using SLS technology and Windform powders,
Available from: www.crptechnology.com/sito/images/PDF/ cs/Case_Study_
Convertiplano_CRP_ENG.pdf, Accessed on: 2009-05-02
