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| United States Patent Application |
20100310698
|
| Kind Code
|
A1
|
|
Klare; Martin
; et al.
|
December 9, 2010
|
DEVICE AND METHOD FOR THE GENERATIVE PRODUCTION OF THREE-DIMENSIONAL
OBJECTS ON THE BASIS OF A MULTIPHASE SYSTEM
Abstract
The invention relates to a device and to a method for the production of a
three-dimensional object by the consecutive layered bonding of a material
that can be bonded by means of electromagnetic radiation, wherein in the
so-called vat an at least n-phase system, where n>2, is present, of
which at least one phase comprises the building material and at least one
other a phase that cannot be mixed with the building material.
| Inventors: |
Klare; Martin; (Dortmund, DE)
; Gischer; Frank; (Menden, DE)
; Brick; Uwe; (Jena, DE)
|
| Correspondence Address:
|
KF ROSS PC
5683 RIVERDALE AVENUE, SUITE 203 BOX 900
BRONX
NY
10471-0900
US
|
| Family ID:
|
40873366
|
| Appl. No.:
|
12/745553
|
| Filed:
|
February 12, 2009 |
| PCT Filed:
|
February 12, 2009 |
| PCT NO:
|
PCT/DE09/00187 |
| 371 Date:
|
June 16, 2010 |
| Current U.S. Class: |
425/174.4 |
| Current CPC Class: |
B29C 35/0805 20130101; B29C 67/0055 20130101; B33Y 30/00 20141201; B29C 2791/005 20130101; B29C 67/0092 20130101 |
| Class at Publication: |
425/174.4 |
| International Class: |
B29C 35/08 20060101 B29C035/08 |
Foreign Application Data
| Date | Code | Application Number |
|---|
| Feb 13, 2008 | DE | 10 2008 009 003.4 |
Claims
1. An apparatus for the production of a three-dimensional object by the
consecutive layered solidification of a material that can be solidified
by electromagnetic radiation, wherein in a vat holds an at least n-phase
system with n.gtoreq.2 of which at least one phase comprises the process
material and at least one other a phase that cannot be mixed with the
process material.
2. The apparatus defined in claim 1, further comprising pump means for
varying the layer thickness of at least one of the phases during the
consumption of the phase that contains the process material.
3. The apparatus defined in claim 1, further comprising: pump means for
varying the layer thickness of at least one of the phases can be during
the consumption of the phase that contains the process material; and an
active or passive system for coating.
4. The apparatus defined in claim 1, further comprising: pump means for
varying the layer thickness of at least one of the phases during the
consumption of the phase that contains the process material and further,
an active or passive system for coating, the auxiliary phase being
transparent to electromagnetic radiation in the spectral range of the
absorption spectrum of the photo initiator, and a radiation source
suitable for the finish curing of the generated object irradiates the
auxiliary phase.
Description
[0001] Described are an apparatus and a method for the production of a
three-dimensional object by the consecutive layered solidification of a
material that can be solidified by electromagnetic radiation, wherein in
a so-called vat holds an at least n-phase system with n.gtoreq.2, of
which at least one phase comprises the process material and at least one
other a phase that cannot be mixed with the process material. Within the
meaning of the invention, "not mixable" means that a defined phase
boundary between at least two of the above-mentioned phases is formed.
Preferably, the layer thickness of the one phases can be varied by a pump
or can be controlled during the consumption of the phase that contains
the process material.
[0002] Different methods for layered structuring of three-dimensional
objects from "radiation-curable" photopolymers, are described in the
literature, see "Generative Fertigungsverfahren" by A. Gebhardt 3. Aufl.
2007 (ISBN 978-3-446-22666-1). By continuous development of methods and
materials, today, generative production methods are not used only for
rapid production of prototypes (rapid prototyping), but increasingly in
the field of rapid production (Klare, Martin; Altmann, Reiner: Rapid
Production in der Horgerateindustrie in: RTejournal-Forum fur Rapid
Technologie, 2. Ausgabe, 2(2005), May 2005, ISSN 1614-0923, URN
urn:nbn:de009-2-1049,
http://www.rtejournal.de/aktuell/archiv/ausgabe2/104).
[0003] Also, in addition to their robustness, specific requirements apply
here with respect to the economic efficiency of the used methods. The
economic efficiency is, among other things, closely connected with the
cost of the process materials and the necessary finishing processes. The
present invention thus provides an apparatus and a method that, in
comparison to the additive-layer production methods known from the prior
art, has essential advantages in particular with respect to the
cost-effective production of three-dimensional objects. For the
generative production of three-dimensional objects from
"radiation-curable" "photopolymers" today, primarily such methods are
used that are based on light exposure by a laser (stereolithography,
hereinafter designated as SLA), by a multi-media projector, a LC-display
(reflexive, transmissive), LED or laser diode array (that is moved
orthogonally to the array and across the layer), or by light valve
technology (MEMS).
[0004] The methods are described in a number of patents such as: U.S. Pat.
No. 4,575,330 by C. Hull "Apparatus for production of three-dimensional
objects by stereolithography" and U.S. Pat. No. 4,999,143 by C. Hull et
al "Methods and apparatus for production three-dimensional objects by
stereolithography," in U.S. Pat. No. 5,247,180 A "Stereolithographic
apparatus and method of use," Texas Instruments Inc., in U.S. Pat. No.
005980813 A "Rapid Prototyping using multiple materials," SRI
International, and in DE G 9319405.6 "Vorrichtung zur Herstellung eines
dreidimensionalen Objektes nach dem Prinzip der Photoverfestigung,"
Forschungszentrum Informatik an der Universitat Karlsruhe. According to a
similar method, in DE 29911122 U1 "Vorrichtung zum Herstellen eines
3-dimensionalen Objektes," the company Deltamed claims a use for the
production of three-dimensional components. Furthermore, EP 1250995 [U.S.
Pat. No. 6,716,522] "Vorrichtung zum Herstellen eines dreidimensionalen
Objektes," owned by Envision Technologies, "Rapid-Prototyping-Vorrichtung
and Rapid-Prototyping-Methode" DE 69909136 [U.S. Pat. No. 7,128,866]
owned by DICON AS Lystrup, WO 2001/000390 owned by HAP, Sitec
Industrietechnologie and Deltamed Medizinprodukte, and WO 2005/110722
[U.S. 20050248062] owned by Envisiontec, are of relevance. The technical
differences of the above-mentioned methods can substantially be
characterized by the type of light exposure. In systems that use a laser
for polymerization, the laser beam is moved across the cross-sectional
area that has to be cured. The contours of the cross-sectional area to be
cured can be scanned by the laser beam like a graph. This applies by way
of example to the stereolithography system Viper Pro.RTM. from 3d
Systems. In these systems, the process material in the form of a
low-viscosity resin formulation is contained in a so-called vat. In
commercially available variants, the vats can have a volume of up to 1.2
m.sup.3. The resin quantity necessary for the first filling of a vat,
also designated as initial filling, represents a significant cost factor
when purchasing such a system and accordingly, the consumables can
account for up to 75% of the machine costs. Since the quantity of resin
for the initial fill is independent of the quantities required for the
components, the initial fill represents so-called "dead capital." From an
economic point of view, this is an inhibiting factor and is a
disadvantage, in particular with respect to rapid production processes.
Moreover, over a longer period of time, such resin mixtures can change
their chemical and physical values for example by scattered radiation of
the used laser, mechanical or thermal load, contamination from the
production environment, and for example by incompletely cured material on
the surface of the components to be removed. In some cases, a so-called
"creeping" of the vat, i.e. prepolymerization of the process material
takes place. However, for the above-mentioned reasons, in this manner,
the robustness of the process is significantly limited and either no
components or components with undesired chemical and physical properties
are obtained. Today, in rapid production processes on the basis of
stereolithography, the "initial fill" is thus changed regularly to avoid
a "creeping" of the resin, associated delays in the production process,
and increased costs. In terms of robustness of the production process and
economic efficiency, this is not desirable.
[0005] In contrast to systems on the basis of lasers, in systems based on
mask projection such as, for example the Perfactory.RTM. series from
Envisiontec or the V-Flash from 3d Systems, only complete layers are
exposed to light at once. In case of the Perfactory, for example, a
production platform is immersed from above into the vat, a defined
distance between production platform and bottom is set, and subsequently,
the light exposure is carried out through the bottom of the vat. Between
component and the bottom of the vat, high adhesive forces occur that can
result in the component breaking off the platform or the supporting
structure. Therefore, after exposure to light, the vat is subsequently
detached from the built layer by a tilting movement. With the so-called
V-Flash method, by using the so-called FTI technology, the material is
placed via a film underneath the production platform. Also in this case,
a tilting movement of the production platform is carried out after the
exposure to light. The tilting movement is necessary in both methods to
minimize the peel strength between component and vat bottom or film.
Despite this approach, it is necessary to use a massive supporting
structure, so-called supports, to prevent the generated layer from
detaching from the vat bottom. For the above-mentioned reason, the
support structure must have a stronger bond with the component in
comparison with the stereolithography. Consequently, it is more difficult
to remove the support structure from the component after completion of
the production job. Accordingly, a higher amount of rework is necessary.
However, from an economic point of view, this is not desirable.
[0006] Moreover, the three-dimensional objects generated by the
above-mentioned generative production methods must be cleaned after the
production process and removal of the support structure with a solvent
and subsequently finish-cured in a separate postexposure source. In terms
of a cost-efficient total process, it is further desirable, if
applicable, to eliminate these steps or to integrate them into the
machine concept. It is the object of the present invention to provide an
apparatus and a method for the production of three-dimensional objects by
the consecutive layered solidification of a material that can be
solidified by electromagnetic radiation where the disadvantages with
respect to robustness and economic efficiency of the methods according to
the prior art are minimized or non-existent. This is achieved according
to the invention in that in a vat holds an at least n-phase system with
n.gtoreq.2 of which at least one phase comprises the process material and
at least one other a phase that cannot be mixed with the process
material. The object is solved by an apparatus according to FIG. 1 or 2.
Preferred developments of the apparatus and the method according to the
invention are described in the dependent claims.
[0007] The apparatus and the method according to the invention allow one
to reduce the required amount of process material in the generative
production system to a minimum. Further, it is not necessary during the
production process to separate an exposed layer from a substrate such as,
for example, a vat bottom or a film. Thus, the above-mentioned adhesive
forces can be avoided. Consequently, the claimed apparatus and the
claimed method result in a more robust generative production process that
requires less rework and is ultimately more cost-efficient, and that can
be used in particular preferably in the field of rapid prototyping.
[0008] An embodiment according to the invention is illustrated in FIG. 1
for a two-phase system. The apparatus consists of a radiation source 1
that can be for example a laser or an image-projection system. Other
energy supply sources within the meaning of the invention are explicitly
not excluded. The production platform 5 is located on a movable holder 2
and, during the production process, can be moved within the vat 6
layer-by-layer and in a controlled manner 9. The phase comprising the
process material 8 can be dosed by a pump 3. It is possible here to add,
during the production process, an excess of process material, that is, an
amount of process material higher than the amount for one layer, or only
the amount that is necessary for one layer. In a preferred embodiment,
the process material can be pumped out after production so that the
generated object is in an auxiliary phase 7. In a particularly preferred
embodiment, then, the object can be finish-cured by an appropriate
radiation source 4. Compared to the prior art, this is to be considered
as being very advantageous because by lowering the component into a phase
that cannot be mixed with the process material, the excessive process
material is transported from the component or the auxiliary phase into
the process-material phase. Accordingly, in rapid production, a cleaning
step for the components can thus be eliminated. Moreover, the generated
component is cured in a phase without supplying oxygen. Thus, the curing
is inhibition-free. This is in particular of advantage for the production
of medical products, the curing of which is based in most cases on a
radical polymerization.
[0009] A further embodiment according to the invention is illustrated in
FIG. 2 for a two-phase system in which the process material phase 7 can
be dosed with a pump 8 into the vat 4 and the auxiliary phase 6 with a
pump 5. The apparatus comprises further a radiation source 1 that can be,
for example a laser or an image projection system. Other energy supply
sources within the meaning of the invention are explicitly not excluded.
[0010] Here, the production platform is fixed. During the production
process, a controller 9 doses the liquid level with the pumps. For
example, by adding the volume of one layer of auxiliary phase 2, a
projection plane of process material is provided that is elevated by one
layer. By calculating the exposure parameter with respect to gain and
focus, the next layer can then be polymerized by the radiation source 1.
It is possible here to add, during the production process, an excess of
process material, that is, an amount of process material higher than the
amount for one layer, or only the amount that is necessary for one layer.
In a preferred embodiment, the process material can be pumped out after
production so that the generated object is in an auxiliary phase 6. In a
particularly preferred embodiment, then, the object can be finish-cured
by an appropriate radiation source 3. Compared to the prior art, this is
to be considered as being very advantageous because by lowering the
component into a phase that cannot be mixed with the process material,
the excessive process material is transported from the component or the
auxiliary phase into the process material phase. Accordingly, in rapid
production, a cleaning step for the components can thus be eliminated.
Moreover, the generated component is cured in a phase without oxygen
supply. Thus, the curing is inhibition-free. This is in particular of
advantage for the production of medical products, the curing of which is
based in most cases on a radical polymerization.
[0011] Within the meaning of the invention, it is further not excluded for
the embodiments that an active or passive coating system, as it is known
to a person skilled in the art, is used.
[0012] Within the meaning of the invention, the term not mixable is to be
understood as a practice-related interpretation. That is, between at
least two phases, there is a zone of mixing ratios that results in the
formation of a layering of two liquid phases.
[0013] Such an example for a two-phase system is shown in table 1.
TABLE-US-00001
TABLE 1
example 1
Components Components
Process material phase Auxiliary phase
88.8% m/m (Octahydro-4,7-methano-1H- 86% 1,2,3-propanetriol
indenediyl)bis(methylene) diacrylate
10% m/m TEGDMA, 2,2'- 14% H.sub.2O
ethylenedioxydiethyl dimethacrylate
1% m/m camphorquinone
0.2% camphorquinone
Other systems with n.gtoreq.2 phases are explicitly not excluded
according to the invention.
[0014] In particular, the liquid phases can have different densities so
that the phases can be layered on top of each other due to the density
difference.
* * * * *
