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| United States Patent Application |
20100212584
|
| Kind Code
|
A1
|
|
Ederer; Ingo
; et al.
|
August 26, 2010
|
DEVICE FOR THE LAYER-WISE PRODUCTION OF PATTERNS
Abstract
The instant invention relates to a method for changing characteristics of
a plastic component, wherein a medium is introduced into the plastic
component, which encompasses a porosity and wherein the medium forms a
homogenous compound with the plastic component by at least partially
dissolving the plastic component.
| Inventors: |
Ederer; Ingo; (Geltendorf, DE)
; Hartman; Andreas; (Stadtbergen, DE)
|
| Correspondence Address:
|
DOBRUSIN & THENNISCH PC
29 W LAWRENCE ST, SUITE 210
PONTIAC
MI
48342
US
|
| Assignee: |
Voxeljet Technology GmbH
|
| Family ID:
|
40490140
|
| Appl. No.:
|
12/681957
|
| Filed:
|
October 6, 2008 |
| PCT Filed:
|
October 6, 2008 |
| PCT NO:
|
PCT/DE2008/001603 |
| 371 Date:
|
April 7, 2010 |
| Current U.S. Class: |
118/56 |
| Current CPC Class: |
B29C 67/0081 20130101; B23P 19/04 20130101; B29C 41/02 20130101; B05C 19/04 20130101; B41J 3/4073 20130101; B29C 67/0085 20130101; B21D 53/00 20130101; B05C 13/00 20130101; B28D 1/001 20130101; B05C 11/02 20130101; B05C 15/00 20130101; Y10T 29/49826 20150115; B21D 39/00 20130101; B29C 67/0059 20130101 |
| Class at Publication: |
118/56 |
| International Class: |
B05C 11/02 20060101 B05C011/02 |
Foreign Application Data
| Date | Code | Application Number |
|---|
| Oct 23, 2007 | DE | 10 2007 050 953.9 |
Claims
1. A device for manufacturing patterns in layers, encompassing a
vertically displaceable build platform, a dispensing device for applying
binder material onto the build platform, wherein the device additionally
encompasses a mounting platform, to which all displacement units for the
dispensing device and for the build platform are affixed.
2. The device according to claim 1, wherein a spreader device for
applying fluid is provided.
3. The device according to claim 2, wherein all displacement units of the
spreader device are further affixed to the mounting platform.
4. The device according to claim 1, wherein the dispensing device the
spreader device, or both are further affixed to the mounting plate.
Description
CLAIM OF PRIORITY
[0001] This application is a national phase of PCT application No.
PCT/DE2008/001603, filed Oct. 6, 2008, which claims priority to German
Application No. DE 10 2007 050 953.9, filed Oct. 23, 2007, all of which
are incorporated by reference herein.
FIELD OF THE INVENTION
[0002] The present invention relates to a device for manufacturing
patterns in layers, which encompasses a mounting plate, guides for moving
a spreader device and a drop dispensing system, a vertically displaceable
and exchangeable build platform as well as a material feeding device,
wherein the main elements of the device are mounted to the mounting
platform before it is introduced into a housing and is fixed therein. The
present invention further relates to use of such a device.
BACKGROUND
[0003] Today, the development of components represents new demands on the
producing industry. The increasing time and cost pressure can be
confronted in that new methods, such as rapid prototyping and rapid
tooling are used.
[0004] A method (Object) is thus known, for example, where a polymeric
material, which can be hardened, is applied in the form of liquid
droplets onto a vertically displaceable build platform or workpiece
platform selectively within a contour of the corresponding cross section
of the desired object by means of a displaceable dispensing device and is
hardened by means of UV radiation. The desired component is created layer
by layer by means of repeated application. The object is subsequently
removed from the build platform.
[0005] In the case of another method, a layer of a free-flowing
particulate material is settled in an area on a build table. A binder
material in the form of liquid droplets is then applied onto the layer of
particulate material in a selected partial area by means of a
displaceable dispensing device. Binder material and particulate material
form a solidified structure. Further layers are in each case formed by
repeating the afore-mentioned steps. The solidified structure is then
separated from non-solidified portions of the particulate material.
[0006] Different devices are known to carry out such so-called rapid
prototyping methods, which are known from the state of the art.
[0007] A typical embodiment of a device according to DE0010047614, e.g.,
consists of a welded tube frame supporting adapted guide tracks. Such
frames are joined from a plurality of elements and are set up
extensively. Due to the fact that the joining areas are located around
the frame parts, the component parts must be fully machined all around.
The casing is then hung on the completely mounted device and thereby does
not have any supporting function.
[0008] A very simple device, which substantially consists of profiled
sheet metal parts, to which simple rod guides are screwed directly, is
known from WO20030160667. At any rate, this embodiment has limitations
with reference to the device accuracy and is thus only suitable for
smaller device dimensions, because the guide deviations do not stand out
so much in that case. However, it has proven to be disadvantageous in the
case of all of the devices known from the state of the art and from
practice that the mounting and adjusting of the system is time-intensive
and expensive.
SUMMARY OF THE INVENTION
[0009] According to the invention, this objective is solved in the case of
a device for manufacturing patterns of the afore-mentioned type in layers
by using a mounting plate, to which all of the process-relevant
positioning units and conveying devices are mounted before the mounting
plate together with the attached devices is introduced into a housing and
is fixed therein.
[0010] For this, the mounting plate encompasses cut-outs for the build
platform, the powder supply and removal as well as for maintenance units
for the drop dispensing apparatus, such as cleaning and capping station,
e.g.
[0011] In addition, the mounting plate encompasses fastening possibilities
for the positioning axes of the drop dispensing unit and the spreader
device as well as for the positioning unit of the build platform.
[0012] The mounting plate is thereby dimensioned in such a manner that,
when being fixed on only a few points, it does not deform or only within
narrow margins, so as to ensure the accuracy in the case of the
application mechanisms.
[0013] This applies in particular for the stress caused by weight of the
attached units and weight of the particulate material on the build
platform during the layering process.
[0014] The mounting platform is thereby embodied as a plane plate, e.g. of
a fully machined aluminum plate.
[0015] The build platform is located in a construction cylinder, which is
advantageously embodied as an exchangeable container. The construction
cylinder contains a build platform, which can be moved in the direction
of the cylinder and which cannot slip out of the construction cylinder in
its lower end position. On its lateral edge facing the wall of the
construction cylinder, the build platform encompasses a seal, which keeps
the applied particulate material from flowing by. To introduce the weight
forces of the exchangeable container and the additional friction forces
caused by the friction between build platform and exchangeable container
wall into the mounting plate in the shortest possible way, a guide for
the exchangeable container is located on the underside of the mounting
plate. The exchangeable container in turn encompasses guide elements on
the two opposite upper ends on the outsides of the construction cylinder.
[0016] Via these guide elements, the exchangeable container can easily be
introduced into the device and is thereby fixed in vertical direction.
Roller guides, e.g., are suitable as guide elements. The rollers can be
arranged on the underside of the mounting platform along the introduction
path of the exchangeable container, e.g. The exchangeable container then
again encompasses a matching guide rail, which engages with the rollers
in a positive manner or encloses them in a positive manner.
[0017] Advantageously, a stop, which defines an end position of the
exchangeable container in the device, is located at the end of the
introduction path. After introduction into the device, the exchangeable
container is fixed by means of a holding device.
[0018] The movement of the build platform takes place via a vertical
hoisting mechanism, which is orthogonally attached to the mounting plate.
The hoisting mechanism can consist of one or a plurality of threaded
spindles, e.g., which are mounted in an intermediate platform so as to be
pivot-mounted in spindle nuts, with said intermediate platform being
located below the build platform. The threaded spindles can be actuated
via a common belt drive and a servomotor.
[0019] When using two or a plurality of simultaneously operating spindles,
an additional guide of the hoisting mechanism can become unnecessary,
because the build platform can be sufficiently fixed in its position with
said spindles and all moments of tilt are sufficiently discharged. The
intermediate platform can then be fastened to the mounting platform via
spacer plates, e.g. In the alternative, the hoisting mechanism can also
be affixed on the side of the exchangeable container and can then be
equipped with guide elements, such as rails comprising guide carriages,
e.g. The build platform in the exchangeable container is then connected
to the hoisting system in a non-positive manner via a coupling element.
This can be, e.g., a pneumatically actuated zero point clamping system,
as it is known from tooling machines. All of the displacement movements
are transferred onto the build platform via the coupling and all forces
and moments acting on the build platform, such as, e.g., frictional
forces of the seal between container wall and platform, densification
forces in response to the layer application and gravitational forces are
in turn guided into the hoisting system by means of the particulate
material. The axes for the movement of the spreader unit and for the drop
dispensing apparatus are mounted on the mounting plate. Axes refer to
combinations of guide system and drive. The guide task can be fulfilled
by rails and carriages, e.g., wherein the carriages comprising
recirculating ball systems rolling on the rail.
[0020] The drop dispensing apparatus is typically moved across the build
field in a meander-style during the layering process. This movement is
reached by means of a system of axes, which are aligned orthogonally to
one another. Due to the dimension of the build field, a pair of axes to
be arranged along the opposite sides of the build field is usually
necessary to support a further axis as connection.
[0021] The movement requires a most constant speed across the long
displacement distance (X-axis) and accurate positioning across the short
displacement distance (Y-axis). To minimize masses moved and wear of the
axes, it proves to be advantageous for the individual axis to form the
X-axis and for the pair of axes to serve as Y-axis.
[0022] In the process, the drop dispensing apparatus preferably operates
only in the area of constant speed in response to movement across the
X-axis, so as to locally meter the drops accurately onto the build field.
The drops are thus released here conform to impulses of a measuring unit
system attached to the X-axis. A belt drive axis, providing an even run,
can be used as movement system. Alternatively a threaded spindle axis be
used. Due to the better positioning in this case, a linear measuring
system is not necessary and can be replaced by an encoder mounted to the
motor. Last but not least, a linear drive, as it is increasingly found in
tooling machines, can also be used. The Y-axis, however, must position
accurately, which requires a threaded spindle drive or a linear drive.
[0023] The spreader apparatus, however, needs to be moved across the
construction field at a speed, as constant as possible, while releasing
particulate material onto the build platform. Belt drives as well as
threaded spindle drives as well as linear drives are suitable for this
kind of movement.
[0024] The axes arrangement for the spreader apparatus may not collide
with the axes for the drop dispensing apparatus. Due to the size of the
build field and to reduce moment loading onto an axis, it is likely to
use a pair of axes, which is arranged parallel to the Y-axis of the drop
dispensing apparatus.
[0025] To simplify the apparatus, it is possible to have no separate pair
of axes for the spreader apparatus and using the Y-axis pair for the drop
dispensing apparatus as well as for the spreader apparatus simultaneously
instead. This takes place by mounting the spreader device onto the guide
carriages of the Y-axis next to the X-axis.
[0026] A feeder mechanism for refilling the spreader apparatus with
particulate material is located at the end of the displacement distance.
This material feed preferably takes place by means of a conveying system,
which is operated from a particulate material reservoir below the
mounting platform or outside of the device. In addition, a further
particulate material reservoir is available below the mounting platform
for excess particulate material, which is pushed above the edge of the
build platform by means of the spreader unit. This particulate quantity
is preferably discharged through an ejection slit in the mounting
platform when the spreader unit moves across it.
[0027] A further ejection slit is located on the opposite side of the
construction field at the beginning of the travel of the spreader device.
[0028] The device can be closed by means of a casing. For safety reasons,
there is a need for a hood, which protects the user from particulate
dusts and process vapors and which prevents accidental contact to moving
parts, in particular in the processing room above the mounting platform.
This hood should be movable in such a manner so as to allow the best
possible access to the elements of the device during standstill. A flap
mechanism, which makes it possible to open the hood, is suitable for this
purpose. The flap mechanism can be affixed directly to the mounting
platform. A seal introduced into the mounting platform further shields
the processing room from the environment.
[0029] To further shield the processing room from the underside of the
mounting platform, the introduction path for the exchangeable container
can be covered by a housing. A door arranged at the beginning of the
introduction path closes the introduction path during the process.
[0030] When the mounting platform is dimensioned to be sufficiently large
so as to cover the outer edge of a casing located there below, the
processing room can thus be sealed sufficiently towards the bottom.
[0031] The casing below the mounting platform can be embodied in such a
manner that it simultaneously functions as a rack and supports the
mounting platform. In an advantageous embodiment, the casing consists of
a single component, which encloses the device, e.g. of profiled and
welded sheet metal parts, which accommodates the mounting platform.
[0032] Component assemblies, such as control cabinet, fluid and compressed
air supply, can be accommodated in a space-saving manner in the enclosed
room below the mounting platform.
[0033] Due to the embodiment of the mounting platform as a plane plate,
the effort for orienting the pair of axes to one another is minimized.
Only the parallelism of the axes must be checked. Simple stops of the
axes can be introduced into the mounting plate by means of alignment pins
and can provide for the correct position of the axes at least on one
side. In response to a sufficient dimensioning of the mounting platform,
the casing at the accommodation of the mounting platform must not be
machined, which considerably reduces the production costs. To fasten the
mounting plate, only vertically displaceable fastening elements must then
be used at different locations, to adjust the distance of the mounting
platform to the casing.
[0034] To simplify the mounting of the device, all attachment parts can be
mounted, adjusted and wired to the mounting plate while placed outside of
the casing. Preferably, this takes place on a separate simple mounting
rack. The accessibility is thereby better than in the fully assembled
state in the casing.
[0035] A preferred embodiment will be described below by means of the
drawings.
[0036] It is thus objective of the present invention to provide a device
for manufacturing patterns in layers, which is as accurate as possible,
easy to mount and yet cost-effective to make.
[0037] Accordingly, pursuant to a first aspect of the present invention,
there is contemplated a device for manufacturing patterns in layers,
encompassing a vertically displaceable build platform, a dispensing
device for applying binder material onto the build platform, wherein the
device additionally encompasses a mounting platform, to which all
displacement units for the dispensing device and for the build platform
are affixed.
[0038] The first aspect of the present invention may be further
characterized by one or any combination of the features described herein,
such as a spreader device for applying fluid is provided; all
displacement units of the spreader device are further affixed to the
mounting platform; the dispensing device and/or the spreader device are
further affixed to the mounting plate.
DESCRIPTION OF THE DRAWINGS
[0039] FIG. 1 shows an embodiment of the device as a tube frame (state of
the art).
[0040] FIG. 2 shows a diagonal view onto the partially mounted mounting
platform.
[0041] FIG. 3 shows a front view of the mounting platform comprising
attached axes.
[0042] FIGS. 4a-4c shows the introduction of the mounting platform into
the casing.
[0043] FIG. 5 shows the mounted device in the diagonal view.
DETAILED DESCRIPTION OF THE INVENTION
[0044] FIG. 1 shows a device for three-dimensional printing according to
the state of the art without an attached casing. The surrounding tube
frame 21, which supports the individual guides for the elements like
spreader device 4, X-axis 7 and Z-axis 5 as well as the material feeder
10, is clearly visible.
[0045] FIG. 2 shows the mounting platform according to the present
invention comprising the attachment parts. The Y-axis pair 22 is fixed to
the opposite sides of the edge of the construction field 23. The print
head 28 is mounted to the print head axis 7, which in turn is attached to
the Y-axis 22. The spreader device 4 is also guided on the Y-axis. The
material feeder 10 is located in the front part of the mounting platform.
The cleaning station 24 for the print head 28 can be seen in the front
area. Next to it is the capping station 25, which closes the print head
during standstill and which thus prevents a drying or soiling of the
print head 28.
[0046] The Z-axis 26 is mounted below the mounting platform. The
introduction room for the non-illustrated exchangeable container is
shielded by means of the casing 27.
[0047] FIG. 3 shows the mounting platform 21 comprising the attachment
parts in side view. In this position, the exchangeable container 2 can be
seen, which is introduced via the guide 30 at the mounting platform
underside so as to be displaceable only in horizontal direction up to the
position below the construction field cut-out and is then held in
position via the catch 29. In this embodiment, the Z-axis 26 consists of
four simultaneously driven threaded spindles, which are supported in the
intermediate platform 28. It is fixed to the mounting platform 22 via the
mounting plates 27.
[0048] FIG. 4 shows the mounting process of the preassembled mounting
platform 22 in the image sequence a to c into the casing 40. The
attachment parts such as Y-axis 22, material feeder 10 and Z-axis 26,
e.g., are mounted to the mounting platform (FIG. 4a), while said mounting
platform rests on an auxiliary frame 30, which allows for the best
possible accessibility. Subsequently (FIG. 4b), the preassembled mounting
platform is lifted into the provided casing 40, e.g. from the auxiliary
frame 30 by means of crane splices 50. Finally (FIG. 4c), the mounting
platform is connected to the casing by means of screwing and the
non-illustrated cap 41 is placed thereon.
[0049] FIG. 5 then shows the completely mounted device comprising casing
40, mounting platform 21 and cap 41. Doors 42 to cover the introduction
space for the exchangeable container 2 are located below the mounting
platform 21.
* * * * *
