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| United States Patent Application |
20090020919
|
| Kind Code
|
A1
|
|
Marsac; Nicolas
|
January 22, 2009
|
METHOD AND MACHINE FOR PRODUCING THREE-DIMENSIONAL OBJECTS BY MEANS OF
SUCCESSIVE LAYER DEPOSITION
Abstract
Inventive machine allowing the simultaneous fabrication of several
objects by a method of "rapid prototyping" type, by depositing a
succession of layers of heat-fusible fluid.
It chiefly comprises a crossbar (20) carrying two platforms (11) on each
of which an object is fabricated by deposition. Two fixed work stations
are arranged diametrically opposite each other so that the jet (12) of
each of these fixed stations can perform a depositing operation at the
same time as the other jet (12). After each deposit, the crossbar is
rotated 180.degree. to alternate the depositing operations of the two
different materials.
Particular application to prototyping jewellery models.
| Inventors: |
Marsac; Nicolas; (Paris, FR)
|
| Correspondence Address:
|
PEARNE & GORDON LLP
1801 EAST 9TH STREET, SUITE 1200
CLEVELAND
OH
44114-3108
US
|
| Family ID:
|
34778710
|
| Appl. No.:
|
10/597211
|
| Filed:
|
February 4, 2005 |
| PCT Filed:
|
February 4, 2005 |
| PCT NO:
|
PCT/FR05/50068 |
| 371 Date:
|
July 20, 2006 |
| Current U.S. Class: |
264/401 ; 425/130 |
| Current CPC Class: |
B29C 67/0055 20130101; B33Y 30/00 20141201; B33Y 10/00 20141201 |
| Class at Publication: |
264/401 ; 425/130 |
| International Class: |
B29C 35/04 20060101 B29C035/04; B29C 31/10 20060101 B29C031/10 |
Foreign Application Data
| Date | Code | Application Number |
|---|
| Feb 6, 2004 | FR | 0450221 |
Claims
1. Method for producing three-dimensional objects by forming a large
number of successive parallel layers in a first dimension and each
consisting of two heat-fusible modelling materials, the method using the
two following main steps: a first step consisting of the timed supply of
a first modelling material to at least a first jet (12) positioned on a
first fixed working station, and of moving the jet with respect to the
supporting surface along second and third directions perpendicular to the
first direction and over a determined pathway, to deposit drops of
material on the supporting surface; and a second step consisting of
conducting the same operation with a second jet positioned on a second
fixed work station and supplied with a second material over a determined
pathway, this cycle being renewed a sufficient number of times, with
pathways determined in relation to the object, in order to construct the
object. characterized in that the number of fixed work stations is 2.N,
the supporting surface consists of 2.N platforms (11) on each of which
the process is implemented, each of the two 2.N platforms (11) is
alternately moved to lie under at least one of the N first jets (12) to
conduct the first step, then under at least one of the N second jets (12)
to conduct the second step, in order to deposit simultaneously 2.N
deposits of material on the 2.N platforms (11).
2. Method as in claim 1, characterized in that surface shaving of the
last deposited layer is performed after every second operation under a
fixed shaving station with at least one shaver (25, 25A, 25B) mounted
rotatably about a fixed axis perpendicular to a first direction.
3. Machine for producing three-dimensional models by forming a large
number of successive, parallel layers along a first direction and each
formed of two modelling materials on a supporting surface by means of at
least jets (12) each supplied with one of the two materials at fixed work
stations, and mobile with respect to a main carriage (14) along a second
direction perpendicular to the first direction, the main carriage (14)
being mobile with respect to the fixed depositing station along a third
direction perpendicular to the first direction, this machine implementing
the steps of the method according to claim 1, characterized in that the
supporting surface consists of 2.N platforms (11) on each of which the
process is implemented simultaneously, the 2.N platforms (11) being moved
at the same time and alternately under a number N of first depositing
stations each carrying a first jet (12), by means of a mobile secondary
carriage (13) to implement the first step, and under a same number N of
second fixed depositing stations each carrying a second jet (12) by means
of a mobile secondary carriage, to implement the second step in order to
produce 2.N objects simulatenously.
4. Machine as in claim 3, characterized in that it comprises a number N
of fixed surface shaving stations, positioned every second fixed
depositing station between two adjacent depositing stations.
5. Machine as in claim 3, characterized in that the supporting surface is
mounted rotatably about a main axis (A) parallel to the first direction,
the 2.N platforms (11) being spaced at an angle from each other by an
angle pitch of .pi./N, the 2.N depositing stations also being positioned
at an angle of .pi./N.
6. Machine as in claim 5, characterized in that the number N equals 1,
the angle pitch is 180.degree., the fixed shaving stations being offset
by 90.degree. with respect to the two fixed work stations.
7. Machine as in claim 6, characterized in that the supporting surface is
carried by a crossbar (20) mounted rotatably about the main axis (A) and
carrying two opposite platforms (11).
8. Machine as in claim 7, characterized in that it comprises an angle
encoder (21) located at the base of the crossbar (20).
9. Machine as in claim 8, characterized in that the crossbar (20) is
driven by a motor (22) and a wheel/worm screw driving system (23).
10. Machine as in claim 3, characterized in that the main (14) and
secondary (13) carriages are driven by linear motors.
Description
FIELD OF THE INVENTION
[0001] The invention pertains to the production of objects in three
dimensions by depositing successive layers, and more precisely to models.
It therefore also concerns the area of <<rapid prototyping
>>. It applies, inter alia, to the manufacture of models requiring
high construction accuracy such as models for jewellery, spectacles,
electronic packaging, aeronautics.
PRIOR ART AND PROBLEM RAISED
[0002] In the area of jewellery, it is known to produce models in three
directions using so-called "rapid prototyping" systems. One type of these
systems is based on placing heat-fusible material on a work platform,
mobile along a vertical axis. This type of process consists of depositing
a high number of successive layers, of constant or different thickness,
whose successive surface areas correspond to the gradual forming, along a
vertical axis, of the model to be produced. It is therefore necessary to
define a large number of sections of the object to be produced by making
successive slices of parallel planes, the distance between each section
corresponding to the thickness of one layer. To reconstitute the object
or model, the sections are stacked in sequence one on top of the other.
It is to be noted that it is also known to use computer-aided design or
digitizing tools to implement said process.
[0003] Depending upon methods, the materials used may be heat-setting
liquids such as liquid resins or heat fusible materials such as waxes. It
is noted that a shaving operation on each deposited layer is performed to
calibrate the thickness and regularize the upper surface. A multitude of
layers are thereby deposited on the preceding layer.
[0004] For the model production of objects of sophisticated shapes, it is
known in the jewellery industry to produce a model by means of a large
number of two series of successive layers, each consisting of different
materials. One first material is used to form the final part, a second to
form its support. The support material is removed by dissolving in a bath
once the deposit and solidification of the successive layers are
completed.
[0005] Also, with reference to FIG. 1, from European patent EP 0 715 573,
a device is known for making three-dimensional models by the sequential
formation of a multitude of layers one upon the other by drop depositing
a modelling material. This device comprises: [0006] a platform 1 for
the model to be produced, mobile along a vertical axis; [0007] a first
main carriage 3A mobile along a longitudinal axis, giving support to a
secondary carriage 3B mobile along an axis transverse to the preceding
axis; [0008] two jets 2 depositing drops of the two materials one after
the other, attached to the secondary carriage 3B; [0009] a third "loose"
carriage 3C mobile along the longitudinal axis of the main carriage 3A,
on which the shaver 3D is arranged intended to surface the layers
produced, driven episodically after the depositing of each layer via
action of the main carriage 3A; [0010] control means managing the
positions of the mobile assemblies along the vertical, longitudinal and
transversal axes, and the timed ejection of drops of materials.
[0011] The making of models using this type of device, depositing the two
types of materials one after the other, is relatively long, namely
several hours and even several days. There is therefore a need to
accelerate the manufacture of this type of model.
[0012] The purpose of the invention is therefore to propose a method and a
machine able to produce models quicker.
SUMMARY OF THE INVENTION
[0013] For this purpose, one first main object of the invention is a
method for producing three-dimensional objects by forming a large number
of successive parallel layers, along a first direction, each consisting
of two heat-fusible modelling materials. The method using the two
following main steps: [0014] a first step consisting of the timed
supply of a first modelling material to at least a first jet positioned
on a first fixed work station, and of moving the jet over the surface of
a support platform along second and third directions perpendicular to the
first direction and along a determined pathway, to place drops of
material on the support surface; and [0015] a second step consisting of
conducting the same operation with at least one second jet positioned on
a second fixed work station and supplied with a second material, along
another determined pathway, this cycle being renewed a sufficient number
of times, with pathways determined in relation to the object, in order to
construct the object.
[0016] According to the invention, since the platform consists of 2.N
platforms on each of which the process is implemented, each of the 2.N
platforms is alternately moved under a number N of fixed work stations
each having at least one first jet to perform the first step, then under
a same number N of fixed work stations each having at least one second
jet to conduct the second step, in order simultaneously to achieve 2.N
deposits of material on the 2.N platforms, each platform remaining
separate from the other with respect to its mobility along a vertical
direction.
[0017] Preferably after every second operation, surface shaving of the
deposited layer is performed under a fixed shaving station with at least
one shaver mounted rotatably about a fixed axis perpendicular to the
first direction.
[0018] A second main object of the invention is therefore a machine to
produce three-dimensional objects by forming a large number of
successive, parallel layers along a first direction, each consisting of
two modelling materials, on a supporting surface and by means of two jets
each supplied with a different material at fixed work stations, and
mobile relative to a main carriage along a second direction perpendicular
to the first direction, the main carriage being mobile with respect to
the fixed depositing station along a third direction perpendicular to the
first direction, this machine implementing the steps of the
above-mentioned method.
[0019] According to the invention, 2.N fixed work stations are used, the
supporting surface consists of 2.N platforms on each of which the process
is simultaneously conducted, the 2.N platforms being moved at the same
time and alternately under a number N of first fixed work stations each
carrying at least one first jet, by means of the mobile secondary
carriage mobile to implement the first step, and under a same number N of
second fixed work stations each carrying at least one second jet, by
means of a mobile secondary carriage to implement the second step, in
order simultaneously to produce 2.N objects.
[0020] Preferably, use is also made of a number N of fixed surface shaving
stations positioned every second fixed work station between two adjacent
work stations.
[0021] The main embodiment of the invention provides that the supporting
surface is mounted rotatably about a main axis parallel to the first
direction, the 2.N platforms being spaced apart at an angle to each other
by an angle pitch of .pi./N, the 2.N fixed work stations also being
spaced apart at an angle of .pi./N.
[0022] One particular embodiment of the inventive machine provides that
N=1, the angle pitch being 180.degree., the fixed shaver station being
offset by 90.degree. with respect to the fixed work stations.
[0023] In this latter embodiment, the supporting surface is advantageously
carried by a crossbar mounted rotatably about the main axis and carrying
the two opposite platforms.
[0024] This assembly is advantageously completed by the use of an angle
encoder positioned at the base of the crossbar.
[0025] This crossbar can advantageously be driven in rotation by an
electric motor and a wheel/worm screw driving system.
[0026] The main and secondary carriages are advantageously driven by
linear motors.
LIST OF FIGURES
[0027] The invention and its different embodiments and advantages will be
better described in the following description accompanied by several
figures, respectively illustrating:
[0028] FIG. 1, a prior art device for producing a three-dimensional model;
[0029] FIG. 2 is an aerial view of a preferred embodiment of the inventive
machine;
[0030] FIGS. 3A, 3B and 3C are three different views of the embodiment in
FIG. 2;
[0031] FIG. 4 is a variant of this same embodiment; and
[0032] FIG. 5 schematically illustrates a possible further development of
the inventive machine.
DETAILED DESCRIPTION OF TWO EMBODIMENTS OF THE INVENTION
[0033] With reference to FIG. 2, a preferred embodiment of the inventive
machine provides that on a frame 10 of the machine, two work platforms 11
are mounted. These platforms are pivot mounted about a main vertical axis
A, so that they can rotate about this axis and take up position
alternately under two work stations symbolized by the two groups of
tooling shown.
[0034] More precisely, a crossbar 20 forming a carrier structure is pivot
mounted about the main axis A.
[0035] An encoder 21 is located underneath the crossbar 20, so as to be
able to command its rotation about the main axis A. This crossbar 20
carries two supports 12 themselves each bearing a work platform 11. The
two supports 12 are mounted mobile in vertical translation, parallel to
the main axis A by means of two respective guide screws 17 and each
driven by a motor 16. This movement allows progressive lowering of each
of the platforms 11 after the depositing of a layer, during the
manufacturing process of each object.
[0036] On each of these platforms 11, an object is therefore to be
constructed by depositing numerous successive layers of two heat-fusible
materials, by means of two jets 12 each positioned on a fixed depositing
station arranged diametrically opposite one another.
[0037] The latter consist of a pair of parallel rails 18 on which a main
carriage 14 is mounted mobile in horizontal translation. The movements of
this carriage therefore follow a second direction perpendicular to the
first direction symbolized by the main axis A which is vertical. On each
of the main carriages 14 a secondary carriage 13 is mounted mobile in
translation and carrying a jet 12. Each secondary carriage 13 is
therefore mobile in horizontal translation along a third direction
perpendicular to the second direction schematized by the main carriages
14. The three directions of movement mentioned are materialized in FIGS.
2, 3A, 3B and 3C by three orthogonal axes Ox, Oy and Oz. The respective
carriages 13 and 14 may be driven by conventional mechanical systems of
belt pulley or stepping motor type, but in the illustrated figure they
are directly driven by linear motors 19A thereby eliminating any
positioning errors due to wear of the components of conventional
mechanical transmission systems. With the use of linear motors, movements
are controlled by linear encoders.
[0038] It is therefore easy to understand that each jet 12 can be moved
over a surface parallel to its respective platform 11 located below it,
along the second and third directions, so that it can criss-cross the
entire surface area represented by its corresponding platform 11. Only
one jet 12 is shown, but several jets 12 can be mounted on a secondary
carriage 13 forming a print head.
[0039] According to the inventive method, it is therefore possible to
construct an object such as a model simultaneously on each of platforms
11, by means of the two jets 12 each simultaneously depositing a layer of
heat-fusible material such as wax. One of the two jets 12 deposits a
first material, e.g. a wax intended to form a final model, whilst the
other jet 12 deposits a second material, here another wax, intended to
form a support for the first material throughout the complete
construction of the model.
[0040] Therefore, part of a layer with modelling wax is deposited on a
first platform 11, while on the other platform 11 another part of the
layer is deposited with the support wax. When each layer is completed,
the platforms 11 are exchanged with respect to the jets 12, by rotating
the crossbar 20.
[0041] It is useful to surface the layers of material deposited by one of
the two jets. For this purpose a surface shaving station is provided on
the frame 10. A shaver 25 is rotatably mounted on a fixed axis, rotating
horizontally with respect to the frame. Its length is equal to the radial
side of each platform 11, so that it can shave a surface area equivalent
to the entire surface area of each platform as the latter rotates about
the main axis A. This shaver is mounted at a height that is adjusted to
shave each layer that is to be shaved after being deposited. The shaver
25 is driven in rotation by an ordinary motor 26. The direction of
rotation of the crossbar 20 must take into account that the platform 11
on which only one of the materials has been deposited circulates opposite
the shaver and therefore does not undergo shaving, solely the platform on
which the two materials have been deposited being exposed to surfacing.
[0042] FIG. 3A is a front view of the machine shown FIG. 2. It reproduces
the main elements of the machine structure, namely the frame 10, crossbar
20 and the two supports 12 mounted thereupon. Three motors are also
shown, namely motor 16 driving the guide screw 17 to lift and lower the
supports 12, the motor 22 driving the wheel/worm screw system to rotate
the crossbar, and motor 26 driving the shaver 25.
[0043] FIG. 3B is a side view of this assembly. It shows the support 12,
motor 16 driving the guide screw 17 upwards and downwards, the motor 22
driving the crossbar 20 and the motor 26 driving the shaver 25. It can be
seen in this FIG. 3B that this shaver 25 is of sufficient length to cover
the entire radial side of a support 12.
[0044] FIG. 3C is an overhead view of this assembly. It clearly shows the
position of the shaver 25 and its driving motor 26 with respect to the
position of the platforms 11 in work position. In this FIG. 3C, the fixed
work stations are schematized by the two jets 12.
[0045] FIG. 4 shows a variant of embodiment of this machine in that,
instead of a single shaver 25 as shown in the preceding figures, two
shavers 25A and 25B are provided. These are positioned alongside each
other to perform a surface shaving operation in two depth passes. It can
be contemplated for example that the pass depth provided for a surface
shaving operation is too deep to be made by a single shaver for a given
material. The two shavers 25A and 25B are then positioned at different
heights corresponding to the depth of the pass made by the first shaver.
It is to be noted that the number of shavers is not limited to two as in
the example illustrated FIG. 4.
[0046] With reference to FIG. 5, the number of platforms 11 can be an even
number, greater than 2. In other words the number of platforms used
following the inventive principle is 2.N. It is therefore possible to
manufacture 2.N objects or models at the same time. FIG. 5 shows six
platforms 11 (2.N where N=3) offset at an angle of 60.degree. from one
another (.pi./N where N=3). Conjointly three shavers 25 have been
positioned offset from each other at an angle of 120.degree., each
positioned between two groups of two adjacent platforms 11. It can
therefore be generally understood that after two operations to deposit
successive layers at two fixed work stations, surface shaving can be
performed.
[0047] The two embodiments described in this description are based on a
machine comprising a crossbar that is rotatably mounted and supports 2.N
platforms, the machine frame comprising a number 2.N of fixed work
stations. It is possible to consider that the platforms 11 could be moved
via conveying devices over a closed continuous pathway, irrespective of
the form of the pathway.
[0048] It can therefore be easily understood that with the inventive
machine and method, it is possible to fabricate a number 2.N of objects
simultaneously in a time equivalent to the fabrication time of one object
with a prior art machine such as described with reference to FIG. 1.
* * * * *
