Iris Publishers
Continuous Orbital Winding of Thermoplastic FRPs
Authored by Rainer Wallasch
In
order to satisfy the requirements of functionality and energy and material
efficiency, the reduction of moving masses in transportation systems (e.g.
cars, trains, electric vehicles) is of crucial importance. The comparatively
low masses, high specific strength and the opportunity for large-scale production
of fiber-reinforced thermoplastics are showing great potential for industrial
applications. One part of the federal cluster of excellence MERGE Exc1075
“technology fusion for multifunctional lightweight structures”, was focusing on
the development of the novel technological concepts. As a result, a technology
for continuous generation of structural components with convex or concave
surfaces was realized by applying an inverted winding process. For the
validation of this technology, a pilot plant was developed and tested. The
layer structure is realized by welding the fiber reinforced thermoplastic tapes
and pressed on with defined pressure onto the closed winding core. The mandrel
is linearly guided through the rotating winding units and can be made of metal
as durable mold or made of thermoplastic, which remains in the structural
component. Possible mandrel geometries are shown in Figure 1 (rel. [1,3,4]).
The
key objective of the present research and development activities is the process
automation by automated trajectory generation of driving parameters for each
orbital winding unit, which is necessary for the implementation. This
preprocessor is using directly the 3D dataset provided by the CAD system. The
import of the STL-dataset (ASCII Format) is realized with Mathcad interface.
Next, the data preparation is performed, and a curved pathway is calculated.
The guide ways are computed, and the machine datasets derived by the use of an
algorithm for movement kinematics [1]. The validation of the developed software
tool for the orbital winding process is conducted at the pilot plant
State of the Art
The novel process is a
combination of thermoplastic automated tape laying (ATL) and automated tape
winding (ATW) technology. Both processes are mainly using unidirectional fiber
reinforced thermoplastic tapes. The layer structure is realized by the melting
and depositing of the thermoplastic tape. The layers are fused by locally
melting the matrix material with convective heat transfer (hotgas) or radiation
(IR radiation or diode laser). The tapes are supplied on spools with a width of
up to 300 mm and a thickness in the range of 0.12 mm to 1 mm [2].
Thermoplastic tape winding
The fiber-reinforced tape is
pulled off from the coil by the rotation of the winding core and molten in
front of the deposit position. The tape tension and the resulting retraction force
in the tape are used to apply consolidation pressure in the contact area
between layers, thus fusing the winding layers on each other. The winding
process is used to produce rotationally symmetrical closed bodies [2].
Thermoplastic tape placement
A multi-axis system with a tape
placement head is used for direction variable placement of the usually
unidirectional fiberreinforced tapes. The tape placement is typically realized
on planar or curved tools by applying heat for the melting of the tape material
and pressure for consolidation. This process is used to produce large
components or to implement local thickenings as well as reinforcements, usually
designed to be functional and load appropriate. The tape material is conveyed
by the relative movement of the laying unit to the tool surface or by driven
feed rollers. The tape is heated up to melt temperature before it reaches the
drop-off point and is consolidated with the required compaction force of the
pressing unit [2].
Continuous orbital winding (COW)
The aim of the orbital winding
process is to go beyond the state of classical winding of rotational
symmetrical profiles to generate variable cross-sectional profiles. Pre- and
downstream technologies are taken into account for integration into largescale
production concepts and to implement a higher level of value-added chains. For
this purpose, a modular process chain was developed, shown in Figure 2. The
structure of the continuous orbital winding technology also accounts for
further processes, e.g. for functionalization or integration of auxiliary
components in the layer structure [3-5].
The winding concept is derived
from an inverted winding principle. Contrary to the conventional winding
principle, the application unit is rotating around the winding mandrel. The
winding mandrel is solely driven in axial direction.
A special kinematic system was
developed for the orbiting motion of the application unit around the local
profile cross-section. It allows the compaction roller to freely follow even
complex geometries. The basic design of the multi-axis system developed for
this purpose (Figure 3) features a radial and a tangential actuator to follow
the contour as well as a tilting capability to adapt to the local surface.
The
functional principle was validated with the realization of a modular structured
pilot plant. The key components are the winding units (Figure 4) which have
been specifically developed on the basis of the operating principle (Figures 2
& 3). The identical design of the winding units allows for a modular
construction in series (Figure 5).
Methods
In the case of in-line orbital
winding, unidirectional fiber reinforced or also bi-axial prepregs can be
processed into rotationally symmetric (cylindrical parts) and nonsymmetric
nearnet- shape structures and complex structural components. For this
application, the present article describes the functionality of an adequate
offline machine control as preprocessor and simulative functionality tests in
the multibody mechanism tool in the CADsystem Pro-Engineer.
Control of the winding process
and calculation of the trajectory
For the automated control of the
machine system and process monitoring it is necessary to automate an upstream
motion control system. The aim was to use the CAD based component contour. The
resolution of this task is preceded by the development of a formalism, which
includes the following essential steps:
• Creation/Development of a
CAD-based STL-file in ASCII format with a sufficiently accurate resolution → Creation/Designing
a surface model
• Mathcad interface for reading
the data and creation of the surface model derivation of the triangulated
surfaces
• Design of the winding path as
the guide way
• Illustration of the kinematic
model in the Mathcad
•
Implementation of the inversion of the inverse kinematics to compute
The detailed procedure for data
preparation: and determination of drive parameters is described below STL File-
Import The data set in a stl component model describes the shape of the
component surface with triangular areas or facets. For each surface element
three vertices are assigned, and a normal direction is defined by a vector. The
latter determines the material side and the outside of the part as well. The
specification of the corner points and the normal vector results from three
coordinates relative to the defined reference coordinate system. For the
formalism to treat the data, the ASCII variant of the STL format is used
(Figure 6), which can be generated and read by almost all commercial CAD
systems. In the next section the treatment of the triangular geometry and the
path planning will be described. Both steps were performed using the PTC
Mathcad calculation software.
The
requirements for the STL in ASCII format of the winding profile are
specifically defined. For example, the imported reference coordinate system
must correspond to the machine system. The component longitudinal axis is
described by the y-axis of the coordinate system. The CAD part, the stl-format
and the imported model are shown in Figure 7.
Calculation
of the path: After Data import of the point and vector coordinates grouped into
triangles, a scan of the complete triangle mesh is performed. Figure 8 shows
the contact curve that arises when the consolidation roller is driven once completely
over a constantly shaped winding core [1]. Here, the slope of the curve
corresponds to an uninterrupted winding of the tape (Figure 8).
The feed of the core per
revolution of the laying head equals the actual width of the tape, reduced by
twice the amount of overlap.
• Curve ascends helically along
the longitudinal axis of the winding mandrel
• Calculation of the
intersections → equidistant on the work piece surface
Design of the Guide Way
V360° = B-2u (1)
The calculation of the contour
points Pi of an intersection calculation between the triangular surface and an
ascending ray performing a screw motion. As the ray displaces a unit of length
ΔV in takes place by means the Y direction (looking at Figure 7), its direction
(initially parallel to the X axis) rotates about the Y axis with the angular
step Δ ϕ. The constant ratio
can be interpreted as the screw
pitch.
The intersection calculation is
performed for each triangle until the current triangle of the surface is found.
In the next step, the cutting problem between plane and line has to be solved.
Multiple solutions are eliminated by considering the positive beam direction
and the boundaries of the triangles.
With regard to the later
integration into the control, there was the additional requirement to
distribute the points equally spaced on the core surface. This is achieved
numerically up to the accuracy ε by first estimating the angular stepΔ ϕ
The deviation from the actual
length is less than 0.1% and is neglected due to the elasticity of the
material. The spatial curve itself can now be examined in particular for its
curvature behavior, since, for example, falling below the roller radius in the
case of concave sections can lead to impacts and connection errors [1,6].
Choice of winding angle: In
addition to the laying strategy described above, other variants are possible.
Beyond from the tape laying with overlap area, a free winding angle of the tape
with feeds V360° > B can be selected, since the corresponding movement
possibilities are provided for the laying unit. This is important, if different
winding angles are to be modeled during the production program.
Motion control
Determination of the drive
position: The result of the previous chapter’s calculation is a coordinate list
of the points Pi consisting of equally spaced points of the contact curve of
the roller center on the winding mandrel surface. This coordinate list is
supplemented by associated infeed positions Vi of the winding mandrel and the
angular position HZi of the main rotor. The following describes the inclusion
of this curve in the machine concept for motion control.
First, the points
To estimate the curve normal,
the tangent direction is calculated numerically and rotated by the specified
rotational matrix by 90° around the longitudinal axis of the winding core
(y-axis). The mechatronic axes shown in Figure 4 – have to be positioned in
such a manner, that the roller takes the calculated position Ri at the end of
the kinematic chain.
For this purpose, the inverse
kinematics function
for the backwards transformation
of the position coordinates x of the roller into the axis coordinates q of the
drives was created. It should be noted that the angular position of the main
rotor HR changes uniformly (constant speed) and is thus already fixed.
Integration in the motion
control: The diagrams in Figure 9 show typical axis positions during the
revolution for a reference profile – the result of the inverse kinematics
function Eq. (7). The diagram of the perpendicular orientation shows the
limitation of the slewing angle at the consolidation mechanism in the range
between –45° ≤ θ ≤ 45°.
The drives are controlled by a
master-slave coupling of all single-axis drives to a common master by
‘electronic cam function’. As a first implementation, the infeed of the winding
mandrel V to the master axis was determined all diagrams in Figure 9 refer to V
in the abscissa. Alternatively, it is envisaged to use the length of the
contact contour as a secondary virtual master for the process control. This
would have the decisive advantage in terms of process control, as it is
possible to directly calculate the already used strip length and to control the
laying speed of the tape as a motion control axis. In the course of the determination
of the characteristic curve in the laying process, this will be a decisive step
to eliminate all nonlinearities on the laying process by means of software,
which are caused on the one hand by the kinematics and on the other hand by the
core contour.
Simulative tests: The generated
drive data should be tested on the multibody simulation model in prior to the
data transfer into the machine control of the pilot plant. For this purpose,
the respective parameters of the drive axes are exported directly as several
.grt files from the preprocessor and imported into the multi body system. With
the subsequent kinematic simulation, both the general movement and the movement
along the trajectory are checked. Characteristic parameters of the higher-order
motion functions are examined as well. Figure 10 shows significant positions of
the movement of the MBS model during the simulation of the orbital motion.
For the shown CAD model, the
contour of the winding core was integrated in order to be able to perform a
collision check in addition to checking the consistency of the drive
parameters.
Validation of the COW Process
Preparation of experimental
procedure
For the process, validation of
the COW technology and the drive parameters determined by the preprocessor, a
permanent mold for the winding mandrel was developed (Figure 11). This was
modularly designed using a frame construction (similar to aircraft construction),
later manufactured and assembled from sheet metal and plates. This design
allows the demolding of the wound structural component. For the appropriate
handling within the pilot plant system, the winding mandrel was set on an
aluminum carrier with dimensions 100 x 100 mm², which is necessary for
positioning and guiding of the core passage. The essential crosssection
dimensions of the core contour are shown in Figure 11. The predetermined shape
was designed in a way, that the mechanical properties can also be obtained from
test specimen in order to verify the process. For the demonstration of the
winding process of cylindrical parts the TAHYA liner for a CPV was used.
Experimental Procedure
At the beginning of the research
program, the driving parameters were tested and validated with the real
mechatronic system during the initial operations. Therefore, the datasets for
the movement, generated from the 3D-part (see 3.1), were saved in the excel
xls-format and imported into the machine control system via Ethernet interface.
In the next step, the drive parameters were assessed by traversing the contour
in set-up mode and then tested with the winding mandrel installed.
After the successful initial
operations, feasibility studies were carried out regarding the processing of
PP-GF 60 tapes for the square profile and the PA6-GF and PA6-CF tapes for the
cylindrical parts, which were applied in a single layer without gaps. In the
following layer, the deposition was overlapping with half tape width. For
carrying out the experiments for validation of the process, the winding core
was tempered in a temperature range of 90° C ... 110° C. In addition, the
following essential parameters have been applied for the tape placement:
• Placement speed: ca: 1,5 … 6
m/min
• Consolidation force: 120 … 160
N
• Hot air temperature: 350 …
480° C IR-Heater 8 x 100 … 800W
• Tape width: up to 40 mm.
In this case, it can be shown
that the determined drive parameters can be processed, and the characteristic
processing map of the machine can be studied. In particular, the thermal
process management in conjunction with the installation speed and the contact
pressure of the tape deserves further and special attention. After successful processing
and specification of the required core temperature, feasibility studies were
carried out to process the FRPs.
For processing, parameters had
to be adjusted, for example, for the energy input (deposition speed or hot air
temperature) in order to melt thicker tape (tape thickness up to 0.4 mm) for
the welding process.
The studies show that there is
not enough heating power for processing. In a further step within the COW-Pilot
plant was improved and optimized for the winding process of CPVs within the
Horizon 2020 project TAHYA.
Therefore, the hot air heating
system was replaced by an IRHeating system (shown in Figure 1 and Figure 12
right). In addition, the liner guidance was new designed and installed in order
to be able to wind liners with a length up to 5 m.
Results, evaluation and
discussion
The wound structural parts were
left on the winding mandrel for cooling after the winding process and then
removed from the mold. At visual inspection it was seen that the layers at
component’s ends have not been completely consolidated. This can be explained
by the stabilization of the process parameters at the beginning of the laying
process. The components obtained after trimming off the ends are shown in
Figure 13. The specimens have the contour of the shape of the winding core.
This provides the verification of the closed technology chain at the pilot
stage.
The knowledge of processing
speed, temperature regime and contact force technology map may enable strategies
to dynamically control them based on the position of the roller on the core
perimeter.
Summary and Outlook
The present work deals with the
extension of the already developed and researched technological principle of
orbital winding and the associated installed system. The aim is to provide the
closed development chain from the designed structural component over the
conversion into a surface model up to the machine control and finished part. In
addition, the aim is to study simulate the values determined simulatively in
the CAD system and with the pilot plant system. For this, an automated
calculation tool was developed for orbital winding, which uses the generic
component geometry of the wound body. This is a kind of pre-processor for
automated system control, which generates the winding path on the surface based
on the CAD data and derives the drive parameters of the individual actuators
for the kinematic system. The determined drive parameters are tested on the
machine system of the pilot plant and validated together with the process
technology during the production of test specimens.
First of all, standard
commercial unidirectional fiber-reinforced tapes were processed tape was
studied. The processing of unidirectional was successfully accomplished. The
determined data records are thus classified as sufficiently accurate for the
processing process. Finally, knowing the technology map of processing speed,
temperature regime, and contact force will also allow strategies to dynamically
control them based on the position of the roller on the core circumference.
Furthermore,
previous limitations to the shape of the winding core are to be eliminated- so
the stl processing with profiles of variable cross section axis coordinates can
be realized. It is planned to test the implementation on the machine, as an
online change of the electronic cam must be carried out after each revolution.
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