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| United States Patent Application |
20100244333
|
| Kind Code
|
A1
|
|
Bedal; Bryan
; et al.
|
September 30, 2010
|
Apparatus for Three Dimensional Printing Using Imaged Layers
Abstract
A three-dimensional printer adapted to construct three dimensional
objects is disclosed. In an exemplary embodiment, the printer includes a
first surface adapted to receive a bulk layer of sinterable powder, a
polymer such as nylon powder; a radiant energy source, e.g., an
incoherent heat source adapted to focus the heat energy to sinter an
image from the layer of sinterable powder; and a transfer mechanism
adapted to transfer or print the sintered image from the first surface to
the object being assembled while fusing the sintered image to the object
being assembled. The transfer mechanism is preferably adapted to
simultaneously deposit and fuse the sintered image to the object being
assembled. The process of generating an image and transferring it to the
object being assembled is repeated for each cross section until the
assembled object is completed.
| Inventors: |
Bedal; Bryan; (Santa Clarita, CA)
; Schell; Steven E.; (Monrovia, CA)
; Beers; Ross D.; (La Crescenta, CA)
|
| Correspondence Address:
|
3D Systems, Inc.;Attn: Keith A. Roberson
333 Three D Systems Circle
Rock Hill
SC
29730
US
|
| Family ID:
|
34986614
|
| Appl. No.:
|
12/796041
|
| Filed:
|
June 8, 2010 |
Related U.S. Patent Documents
| | | | |
|---|
|
| Application Number | Filing Date | Patent Number |
|---|
| | 11998151 | Nov 28, 2007 | |
| | 12796041 | | |
| | 11890984 | Aug 8, 2007 | |
| | 11998151 | | |
| | 11078894 | Mar 11, 2005 | 7261542 |
| | 11890984 | | |
| | 60554251 | Mar 18, 2004 | |
| | 60872041 | Nov 29, 2006 | |
|
|
| Current U.S. Class: |
264/497 |
| Current CPC Class: |
B29C 67/0077 20130101; B29C 67/0085 20130101; B33Y 40/00 20141201; B33Y 30/00 20141201; B33Y 70/00 20141201; B33Y 10/00 20141201 |
| Class at Publication: |
264/497 |
| International Class: |
B29C 35/08 20060101 B29C035/08 |
Claims
1-11. (canceled)
12. A method of building an object from a plurality of cross sections
with a three-dimensional printer (3DP), the method comprising: dispensing
a layer of sinterable powder; selectively fusing a portion of a layer of
sinterable powder to provide a support structure comprising a
substantially rigid portion that is sintered with an energy density
substantially the same as an energy density used to fuse the sinterable
powder comprising the cross sections of the object; selectively fusing a
portion of a layer of sinterable powder to provide a support structure
comprising an interface portion sintered with less energy than the energy
density used to fuse the sinterable powder comprising the cross sections
of the object; and selectively fusing a portion of a layer of sinterable
powder into a sintered image, the sintered image corresponding to one of
said cross sections of the object, wherein the interface portion of the
support structure is generally provided between the substantially rigid
portion of the support structure and the cross sections of the object.
13. The method of claim 12, wherein the interface portion is selectively
fused directly on the substantially rigid portion, and the cross sections
of the object are selectively fused directly on the interface portion.
14. The method of claim 12, wherein the interface portion is selectively
fused to comprise some unsintered powder.
15. The method of claim 12, wherein the selective fusing is performed
with a focused radiant energy source.
16. The method of claim 12, wherein the selective fusing is performed
with a steerable mirror and laser.
17. The method of claim 12, further comprising receiving a layer of
sinterable powder on a first surface, wherein the selective fusing of at
least one of the substantially rigid portion, the interface portion, and
the cross sections of the object is performed on the first surface.
18. The method of claim 16, further comprising transferring via a
transfer mechanism the selectively fused powder from the first surface to
the object being assembled.
19. The method of claim 12, wherein the selectively fusing of the
interface portion is performed with less energy per unit area per unit
time than the selectively fusing of the layers of sinterable powder
corresponding to the cross sections of the object.
20. The method of claim 12, wherein the selectively fusing of the
interface portion is performed for a shorter period of time than the
selectively fusing of at least one of the substantially rigid portion and
the cross sections of the object.
21. The method of claim 12, wherein the selectively fusing provides the
interface portion of the support structure between the object and the
substantially rigid portion of the support structure.
22. The method of claim 12, wherein selectively fusing the substantially
rigid portion and the interface portion of the support structure fully
supports all projecting and overhanging portions of the object.
Description
CROSS-REFERENCE TO RELATED APPLICATION
[0001] This application is a continuation-in-part of U.S. patent
application Ser. No. 11/890,984, filed Aug. 7, 2007, which is a
continuation of U.S. patent application Ser. No. 11/078,894, filed on
Mar. 11, 2005, now issued U.S. Pat. No. 7,261,542, which claims the
benefit of U.S. Provisional Patent Application Ser. No. 60/554,251 filed
Mar. 18, 2004, entitled "Three Dimensional Printing," each of which is
hereby incorporated by reference herein for all purposes. This
application also claims the benefit of U.S. Provisional Patent
Application Ser. No. 60/872,041, filed Nov. 29, 2006.
TECHNICAL FIELD
[0002] The present invention relates to a system and method for generating
three dimensional objects from a plurality of cross sectional
information. In particular, the invention relates to a system and method
for constructing three dimensional objects using inexpensive sources of
heat and simple motion systems.
BACKGROUND
[0003] Three dimensional (3D) printers and rapid prototyping (RP) systems
are currently used primarily to quickly produce objects and prototype
parts from 3D computer-aided design (CAD) tools. Most RP systems use an
additive, layer-by-layer approach to building parts by joining liquid,
powder, or sheet materials to form physical objects. The data referenced
in order to create the layers is generated from the CAD system using
thin, horizontal cross-sections of the model. The prior art 3D printing
systems that require heat to join the materials together generally employ
high powered lasers and high precision motion systems containing a
multitude of actuators to generate parts; resulting in a 3D printer which
is generally too expensive for the home/hobbyist user or small mechanical
design groups. There is therefore a need for 3D printers and RP systems
that can generate parts on a layer-by-layer basis without a high power
laser or other expensive energy source and with less expensive motion
systems.
SUMMARY
[0004] The invention features a three-dimensional printer (3DP) adapted to
construct three dimensional objects from cross sectional layers of the
object that are formed on one surface, then subsequently adhered to the
stack of previously formed and adhered layers. In the preferred
embodiment, the 3DP includes a first surface adapted to receive a bulk
layer of sinterable powder; a radiant energy source adapted to fuse a
select portion of the layer of sinterable powder to form a sintered
image; and a transfer mechanism adapted to concurrently transfer or print
the sintered image from the first surface to the object being assembled
while fusing the sintered image to the object being assembled. The layer
of sinterable powder is preferably a polymer such as nylon that may be
fused on a roller or drum, for example, with the energy provided by an
incoherent heat source such as a halogen lamp. The transfer mechanism
includes one or more actuators and associated controls adapted to
simultaneously roll and translate the drum across the object being
assembled so as to press and fuse the sintered image to the object. The
transfer mechanism may further include a transfixing heater for heating
the sintered image and the object immediately before the layer is applied
to the object. The process of generating an image and transferring it to
the object being assembled is typically repeated for each cross section
until the assembled object is completed.
[0005] In some embodiments, the 3DP includes a powder applicator adapted
to apply a predetermined quantity of sinterable powder to the drum for
sintering. In the preferred embodiment, the applicator extracts the
sinterable powder from a reservoir and permits the powder to briefly free
fall, thereby separating the particles that may have compacted in the
reservoir and normalizing the density of the particles applied in layer
form to the drum. The powder applicator may further include a blade
which, when placed a select distance from and angle relative to the drum,
produces a layer of sinterable powder with uniform thickness and density
on the drum as the drum is rotated.
[0006] In some embodiments, the drum of the 3DP includes a temperature
regulator and drum heating element adapted to heat the temperature of the
drum at or near the fusing point of the sinterable powder to reduce the
energy required by the radiant energy source to print a sintered image
from the layer of bulk powder on the drum. The 3DP may further include a
first heating element, a second heating element, or both to reduce the
energy required to fuse the sintered image to the object being assembled.
The first heating element, which is incorporated into a platform assembly
on which the object is assembled, for example, is adapted to hold the
object at a first predetermined temperature above the ambient
temperature. The second heating element is preferably a hot pad adapted
to contact and maintain the temperature of the upper surface of the
object being assembled at a second determined temperature until the next
sintered image is applied to the upper surface. The second determined
temperature is less than the inching temperature of the sinterable
powder.
[0007] The 3DP in some embodiments further includes a layer thickness
control processor adapted to regulate the thickness of a sintered image
fused to the object being assembled. The layer thickness control
processor may vary the thickness of the sintered image before or after
transferring to the object being assembled by, for example, varying the
quantity of sinterable powder dispensed by the applicator, regulating the
position of an applicator blade with respect to the drum, regulating the
time and pressure applied by the drum to transfer the sintered image to
the object being assembled, compressing the sintered image after it is
fused to the object being assembled, and removing excess material from
the object being assembled by means of a material removal mechanism.
BRIEF DESCRIPTION OF THE DRAWINGS
[0008] The present invention is illustrated by way of example and not
limitation in the figures of the accompanying drawings, and in which:
[0009] FIGS. 1A-1C are schematic diagrams demonstrating the operation of
the three dimensional printer of the first preferred embodiment of the
present invention;
[0010] FIG. 2 is an isometric view of the three dimensional printer in
accordance with the second preferred embodiment of the present invention;
[0011] FIG. 3 is a cross sectional view of the three dimensional printer
in accordance with the second preferred embodiment of the present
invention;
[0012] FIG. 4 is an isometric view of the drum assembly in accordance with
the second preferred embodiment of the present invention;
[0013] FIG. 5 is a cross sectional view of the sintering assembly in
accordance with the second preferred embodiment of the present invention;
[0014] FIG. 6 is an isometric view of the powder applicator in accordance
with the second preferred embodiment of the present invention;
[0015] FIGS. 7A-7C are schematic diagrams demonstrating the operation of
the powder applicator in accordance with the second preferred embodiment
of the present invention;
[0016] FIGS. 8A-8D are cross sectional isometric views demonstrating the
three dimensional printer forming a sintered image and applying it to the
object under construction in accordance with the second preferred
embodiment of the present invention;
[0017] FIGS. 9A-9E are cross sectional diagrams demonstrating the
formation of an object using a partially sintered support structure in
accordance with an embodiment of the present invention;
[0018] FIGS. 10A-10B are plan views of individual sintered images showing
alternating open hatch patterns in accordance with an embodiment of the
present invention;
[0019] FIG. 10C is plan view of an object being assembled from a plurality
of sintered images having alternating open hatch patterns in accordance
with an embodiment of the present invention;
[0020] FIGS. 11A-11B are perspective views of an object being assembled
within a layer thickness reference wall in accordance with an embodiment
of the present invention;
[0021] FIG. 12 is a z-stage control for regulating the thickness of an
object during assembly, in accordance with an embodiment of the present
invention;
[0022] FIG. 13 is a side view of another embodiment of a three dimensional
printer;
[0023] FIGS. 14A and 14B is a close-up of a brush used to remove powder
from the drum before roll-off, in accordance with one embodiment of the
present invention; and
[0024] FIG. 15 is a perspective view of a portion of support structure
comprising a plurality of hatches and cross hatching, in accordance with
one embodiment of the present invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
[0025] Illustrated in FIGS. 1A-1C is a schematic diagram demonstrating the
operation of the three dimensional printer (3DP) of the first preferred
embodiment. The 3DP 100 is adapted to construct a three dimensional (3D)
part or object from a digital model of the object using a plurality of
layers corresponding to cross sectional layers of the object. In the
preferred embodiment, the cross sectional layers are formed from a powder
whose particles can be sintered, i.e., to be formed into a coherent mass
by heating. The layers of sintered powder referred to as sintered images
are individually generated and sequentially assembled or printed onto a
stack to build the object. Heat is used to fuse particles of the powder
together to form individual layers as well as fuse individual layers
together into the 3D object.
[0026] As illustrated in FIG. 1A, the 3DP 100 preferably includes a layer
processing surface 102, a radiant energy source 104, and a work surface
106. The layer processing surface, e.g., the continuous surface of a
process drum 102 or a planar surface, is adapted to rotate 120 about its
longitudinal axis and pass over the work surface in a translational
motion under the control of a microprocessor (not shown) and transfer or
otherwise deposit the layers of sintered powder onto the work surface.
The work surface is either a build surface on which the first sintered
image is deposited or a preceding sintered image on the object being
assembled. When produced on a layer processing surface separate from the
object being assembled, the sintered image is permitted to express any
distortion due to melting and density changes, for example, before the
sintered image is affixed to the object, thereby reducing internal
stresses that may arise in the object. As described below, production of
the sintered image on the continuous surface of the drum 102 or other
heated layer processing surface does not, in the preferred embodiment,
typically require the energy required to concurrently fuse the image to
the previous layer.
[0027] In the preferred embodiment, the process drum 102 includes a
heating element (not shown) adapted to elevate the temperature of the
outer surface of the drum to a predetermined value near the melting
temperature of the sinterable powder employed. In the preferred
embodiment, the sinterable powder is a crystalline nylon powder and the
temperature to which the outer surface of the drum is raised is
preferably low enough to prevent the powder from fully fusing but high
enough above the ambient temperature of the sinterable powder to reduce
the energy that must be injected to fuse the powder into a sintered image
and subsequently, to weld or otherwise adhere the sintered image to the
object under construction. A uniform layer of sinterable powder 110 is
applied in bulk to drum 102. The sinterable powder, which is made tacky
by the heat of the drum 102, adheres to the drum without the particles of
the layer 110 fusing together. Electrostatic attraction may also be used
in combination with a heated drum or alone with an unheated drum to
releasably or removably adhere sinterable powder to the drum 102.
[0028] Portions of the layer of sinterable powder 110 representing a cross
sectional layer of the object being formed are sintered by a radiant
energy source 104. The energy source 104, preferably a focused heat
source having a focal point 105 on the drum 102, i.e., the continuous
surface of the drum, heats the powder to a temperature sufficient to fuse
the powder. The powder may be fused by partially liquefying the powder or
by fully liquefying the powder which then cools back to a solid at the
roller temperature once the energy source 104 is removed. A sintered
image 112A is formed by moving the heat source 104 relative to the
continuous surface of the drum 102 to trace lines or regions of sintered
powder across the layer of sinterable powder 110. In the preferred
embodiment, the cross sectional layer of the object may take on any
complex configuration by rotating 120 the drum 102 and translating 122
the heat source 104 under the control of the microprocessor. Unsintered
powder continues to adhere to the drum 102 in this illustrative example.
[0029] As illustrated in FIG. 1B, the sintered image--illustrated in the
form of a diamond 112A--is then transferred to the work surface 106 by
simultaneously rotating 124 the drum 102 while translating 126 the drum
across the work surface. As the drum 102 advances across the work surface
106 from its initial position illustrated by dashed lines, the sintered
image 112A detaches from the drum and transfers to the work surface. The
sintered image and the portion of the object receiving the sintered
image, in some embodiments, are exposed to a heat source for transfixing
the sintered image to the object being assembled. A transfixing heater,
such as a fuser lamp (discussed in more detail below), increases the
tackiness of the sintered image and the work surface for purposes of
enhancing the layer-to-layer fusion or welding and ensuring that the
sintered image has a greater adhesion to the work surface than the drum
102. The distance between the translated drum surface 102 and the work
surface 106 is approximately equal to or less than the thickness of the
sintered image 112A. As stated above, the term work surface 106 as used
herein refers to a surface on which the current sintered image is
deposited, which may be the platform of the 3DP 100 or a previous
sintered image layer laid down during the assembly of the 3D object.
[0030] In the preferred embodiment, the sintered image is concurrently
transferred to and fused with the object being assembled. In some
embodiments, however, the sintered image may first be deposited onto the
object and subsequently fused by, for example, a fuser lamp that follows
the drum, a bulk heating process, a hot pad (discussed in more detail
below), or a combination thereof.
[0031] As illustrated in FIG. 1C, the entire sintered image is deposited
onto the work surface 106 once the drum 102 has traversed the length of
the work surface and the drum reached its final position illustrated by
dashed lines. Unsintered powder, left over after the sintered image is
formed, may be removed from the drum 102 before or after transferring the
sintered image to the object, removed from the work surface 106 after
transferring, or retained at the work surface after transfer to provide
support for the subsequent sintered image, particularly overhanging
sections of the next sintered layer deposited onto the object 112B. This
process of producing and depositing a sintered image is repeated for each
cross section of the object being constructed from the model.
[0032] Illustrated in FIGS. 2 and 3 is a 3DP 200 in accordance with the
second preferred embodiment of the invention. Consistent with the first
embodiment, the second embodiment includes a drum assembly 202, a
sintering assembly, a platform assembly, and a microprocessor 250. This
embodiment of the 3DP 200 further includes a sinterable powder applicator
210, a sinterable powder reservoir 212, an object heating element 208,
and means for cleaning the roller and work surface in preparation for the
next sintered image. The drum assembly 202 includes a drum frame 218 and
a process drum 310 adapted to rotate in response to a first actuator,
preferably a stepper motor 220, operably coupled to the drum via one or
more reduction gears 222.
[0033] The drum assembly in this embodiment, also illustrated in FIG. 4,
further includes a second actuator, preferably a stepper, motor 226, to
drive the drum 310 laterally across the length of the work surface
(direction perpendicular to the longitudinal axis of the drum 310)
preferably via a lead screw 224. The drum 310 is preferably a smooth
anodized aluminum drum onto which the sinterable powder is applied. An
anodized aluminum drum provides thermal stability and durability although
other thermally conductive and non-conductive materials may also be used.
In the preferred embodiment, the circumference of the drum 310 is equal
to or greater than the length (direction perpendicular to drum axis) of
object being constructed. In other embodiments, however, the drum may
have a circumference smaller than the length of the working surface if
the steps of applying the powder, imaging the powder, and depositing the
sintered image are performed substantially concurrently as part of a
continuous process. The outer surface of the drum 310 may be coated with
a nonstick surface such as TEFLON, for example, to inhibit the sintered
image or the unsintered powder from unduly adhering to the drum 310, to
minimize heat loss into the drum during imaging, or to enable an electric
field to be employed to aid powder adhesion.
[0034] The drum assembly may also include a temperature regulator (not
shown) and drum heating element--preferably a tubular halogen lamp or
cartridge heater 802, for example, (see FIG. 8A) mounted internal to the
drum 310--adapted to heat the drum 310 to a temperature substantially
near, but lower than, the fusing point of the sinterable powder. In the
preferred embodiment, the sinterable powder is a crystalline nylon powder
and the temperature to which the outer surface of the drum is raised is
between approximately 2 degrees Celsius and 15 degrees Celsius below the
powder's melting point. A higher roller temperature is generally employed
to facilitate relatively rapid sintering of the powder with minimal input
energy from the imaging lamp system, although the 3DP system may be more
susceptible to roller temperature variations and powder temperature
variations that can result in unintentional sintering of powder on the
roller. In contrast, the drum may be held at a lower temperature to
improve sintered image quality, although the sintering process and
overall object production may take longer. In some embodiments, the drum
assembly further includes a transfixing heater 804 (see FIG. 8A) for
heating the outer side of the sintered image immediately before the
sintered image is deposited on the preceding sintered image of the
object. Similarly, in some embodiments the heating element may also heat
the top surface oldie previously deposited sintered image of the object
being formed. The transfixing heater 804--such as a halogen lamp,
tungsten wire heater, or nichrome wire heater, for example--may be
mounted on the assembly housing the drum 310 in proximity to the drum and
the platform assembly or work surface. In order to control the amount of
heat applied to the surfaces to be adhered, the transfixing heater is
preferably further includes an adjustable mask to limit the area of
exposure for each surface.
[0035] The sintering assembly in the second preferred embodiment, also
illustrated in FIG. 5. includes a housing 232 and frame 338 supporting an
incoherent energy source 330 whose energy is focused on or in proximity
to the drum 310 via a reflector 230 or lens to provide a small area of
concentrated heat. The heat source 330 is preferably a halogen lamp with
an axial filament whose long axis coincides with the focal axis of
symmetry. The halogen lamp is available from Sylvania of Danvers, Mass.,
although any of a number of other heat sources may be used including
tungsten bulbs and arc lamps. As illustrated in the cross sectional view
of FIG. 3, the reflector 230 possesses a substantially elliptical cross
section for purposes of optimizing the concentration of energy from the
heat source 330. A suitable reflector 230 is available from Melles Griot
of Carlsbad, Calif., part #02 REM 001. In some embodiments, the sintering
assembly further includes a mask 502 with an adjustable aperture or
plurality of selectable apertures for further controlling the spot size
of the focal point which may be varied between approximately 10 and 200
mils in the second preferred embodiment. The design of the mask 502 may
also include a parabolic surface of revolution, for example, a Winston
cone, that further concentrates the energy from the heat source 330 to
produce a smaller spot, thus minimizing the power consumption and
obviating the need--in this embodiment--for a laser energy source. In
some embodiments, the sintering assembly further includes a shutter 504
interposed between the heat source 330 and drum 310 for effectively
interrupting the energy beam. In embodiments where the aperture size can
be selected and dynamically changed, the rate at which the heat source
moves across the powder can be varied during construction of a sintered
image or object to compensate for the changes in power incident at the
focus. The heat source 330 is preferably adapted to move co-parallel
relative to the axis of the drum 310 by means of an actuator, e.g., a
stepper motor 236, and a lead screw 234.
[0036] In some alternative embodiments, the sintering assembly employs a
laser or laser diode matched to an absorption band of the sinterable
powder layer as a heat source. The sintering assembly may further include
a steerable or rotating mirror in a fixed position that is adapted to aim
the laser heat on the drum 310, thereby obviating the need to sweep the
sintering assembly over the drum 310 and reducing the number of high
precision actuators.
[0037] The platform assembly in the second preferred embodiment includes a
horizontal build surface on which the first sintered layer is deposited
and the complete object assembled. In the preferred embodiment, the build
surface 240 incorporates a heating pad 241A (discussed below) into the
build surface on which the object is constructed from printed sintered
images. The height of the build surface 240 is adjusted relative to the
drum 310 by means of a scissor lift 206 including two cross arms 242, a
lead screw 244 with left handed and right handed threads on either end,
and an actuator, preferably a stepper motor 246. Rotation of the lead
screw 244 causes the two cross arms 242 to rotate toward or away from
each other depending on the direction of rotation, thereby enabling the
build surface 240 to ascend or descend, respectively. In some
embodiments, the build surface 240 is adapted to rotate in the horizontal
plane with respect to the scissor lift 206, thereby allowing the build
surface 240 to be rotated to a random angle preceding the deposition of
each sintered image to prevent the accumulation of repetitive errors or
artifacts which, if uncorrected, may result in vertical non-uniformities
or nonlinearities in the assembled object. One skilled in the art will
appreciate that the orientation of the sintered image produced on the
drum 310 should reflect the same angular rotation as the build surface
240.
[0038] For each sintered image deposited, the height of the build surface
240 relative to the drum 310 is adjusted such that the top of the object
being constructed is lower than the drum 310 by a distance substantially
equal to the thickness of a sintered image applied to the object. In this
embodiment, the platform is lowered after each image is applied to the
object, but, in another embodiment the height of the drum could be
adjusted upward to compensate for the thickness of the object as the
object is assembled. In some embodiments, the build surface 240 is the
bottom of a object build vat having side walls (not shown) that contain
both the object and the unsintered powder remaining after printing of
sintered images, thereby providing a foundational support for portions of
subsequent sintered images that have no object immediately below them.
[0039] The actuation of the stepper motors employed in the drum assembly,
the sinter assembly, and the platform assembly are preferably
cooperatively controlled by the microprocessor 250 adapted to
concurrently rotate the drum 310 and translate the sinter assembly to
deposit each of the plurality of cross-sections from which the object is
constructed.
[0040] In some embodiments, the 3DP further includes a sinterable powder
applicator to apply powder to the drum 310 and one or more sinterable
powder reservoirs 212 used to collect unsintered powder recovered from
the drum 310 and unsintered powder recovered from the work surface.
Referring to FIGS. 2-3 and FIG. 6, the powder applicator 600 of this
embodiment includes a sinterable powder bin 210 from which sinterable
powder is dispensed and applied to the drum 310 using, for example, a
powder conveyor belt 314 and pulleys 312. As demonstrated by the powder
applicator schematics in FIGS. 7A-7C showing the formation of a
sinterable powder layer, sinterable powder 710 is drawn from bin 210 as
the pulleys 312 are turned and the belt 314 advanced. An agitator (not
shown) in or attached to the bin 210 may be employed to enhance the
transfer of powder. The volume of sinterable powder dispensed by the belt
314 is preferably precisely controlled by the adjustable gate 702 and the
gap thereunder. As the powder falls off of the conveyor belt to the
cavity above the applicator blade, the powder density is normalized to
ensure uniform and repeatable density as the powder is applied to the
drum regardless of how the powder was compacted in the powder bin. The
dispensed powder 712 accumulates against the drum 310 and a layer control
blade 706 used to regulate the thickness and uniformity of the powder
applied to the drum 310. The cavity 708 created between the blade 706 and
drum 310 is preferably wedge-shaped with a relatively wide upper gap to
properly draw powder and a narrower lower gap to spread the powder
uniformly across the width of the drum 310--and preferably compact the
powder to the proper density--as the drum is turned. The thickness of the
sintered layer produced is preferably between 5 and 20 mils thick
depending on the vertical resolution of the object required. As discussed
above, the resulting layer 714 of sinterable powder adheres to the drum
310 due to the inherent tackiness induced by the heating lamp 802
therein.
[0041] In the preferred embodiment, the sinterable powder is a crystalline
plastic powder such as Nylon #12 having an average particle size of 60
microns although this is subject to variation depending on the 3D
printing requirements and the manufacturing method, for example. In some
embodiments, the sinterable powder includes a distribution of two or more
particle sizes, namely a first set of relatively large particles and a
second set of relatively small particles where the diameter of the
smaller particles is selected to substantially fill the inter-particle
voids present between the larger particles, thereby increasing the
density of the sintered powder and reducing the shrinkage of the object.
[0042] The distribution of particle sizes, referred to herein as a modal
distribution, may include a plurality of nominal particle size, each
being successively smaller, to provide maximal powder density.
[0043] In the alternative to Nylon #12, various other sinterable materials
may also be employed including Nylon #11, Acrylate Butadiene Styrene
(ABS), Polystyrene and other powders with a similar particle size. The
sinterable powder may further include a radiation absorbent agent or dye
that increases the effective absorptivity, which is substantially
symmetric to the emissivity, of the powder in the wavelength band of
radiation emitted by the heat source. For example when the heat source is
visible light black or grey coloring agents may be employed to increase
the powder's energy absorption, thereby increasing the rate at which the
powder may be sintered and the object assembled. The radiation absorbent
agent may also allow lower power incoherent energy sources including
lamps as well as coherent energy sources including laser and laser diodes
to be used as a sintering radiation source. In other embodiments using a
laser or laser diode, the dye may be absorptive primarily in the narrow
emission hand of the laser.
[0044] In some embodiments, the 3DP 200 is adapted to produce one or more
sintered images from a sinterable powder including metal, for example.
One exemplary product is distributed under the trade name METAL MATRIX
PLASTIC by Hi-Temp Structures of Gardena, Calif.
[0045] In the second preferred embodiment illustrated in FIG. 3, the 3DP
200 further includes one or more object heating elements, preferably
including a first heating pad 241A and a second heating pad 241B
rotatably affixed to the platform assembly. The first heating pad 241A
contacts the bottom side of the object under construction. The second
heating pad 241B (discussed in more detail below) is generally placed in
proximity to or in contact with the upper side of the object (not shown).
Together or individually, the first heating pad 241A and a second heating
pad 241B elevate the temperature of the object for purposes of enhancing
the bond between the next sintered image and the object and reducing
temperature gradients in the part, therefore inhibiting internal stresses
that may induce dimensional inaccuracies in the object.
[0046] The mechanical operations by which the 3DP 200 forms a sintered
image and applies it to the object under construction is illustrated in
FIGS. 8A-8D which are cross-sectional views drawn in perspective.
Referring to FIG. 8A, sinterable powder sufficient for a single sintered
layer is dispensed in bulk to the drum 310 which resides in its home
position in proximity to the bin 210. The drum 310 is rotated and the
newly applied sinterable powder is formed into a layer as the drum is
turned. The cartridge heater 802 and transfixing heater 804 are clearly
visible in the several views of FIGS. 8A-8D.
[0047] The Referring to FIG. 8B, the drum 310 in this embodiment advances
to a position coinciding with the focal point of the lamp assembly and
portions of the powder layer are sintered to form one or more solid
portions reflective of the associated model cross section. The focal spot
may be swept over the drum surface in accordance with a raster pattern or
in accordance with model vector data, for example, depending on the
digital format of the model cross sectional data. In the preferred
embodiment, a raster sequence and patterns are used to minimize internal
stresses within an imaged layer.
[0048] Referring to FIG. 8C, the drum 310 with the sintered image is
rotated while being driven to the right in this illustration moving it
over the top of the platform. The gap between the drum 310 and the work
surface is less than or equal to the thickness of the sintered
image--preferably substantially equal to the thickness of the sintered
image--and the drum rotated such that the sintered image being deposited
on the work surface is stationary with respect to the work surface to
prevent slippage or displacement of the object under construction. When
the gap between the drum 310 and the work surface is less than the
thickness of the sintered image, the pressure exerted on the sintered
image may improve the fusion between the image and object as well as
increase the density of the object.
[0049] In some embodiments, the 3DP 200 further includes a layer thickness
control processor, which may be embodied in the microprocessor 250 or a
separate processor, that dynamically controls the thickness of the object
being constructed as the sintered image is applied to the object. The
layer thickness control processor preferably detects the thickness of the
entire object or one or more sintered images as the object is being built
and, using feedback, changes the thickness of the sinterable powder
applied to the drum 310 or alters the pressure used to weld a sintered
image to the object. The pressure may be controlled, for example, by
altering the interference gap between the drum 310 and work surface so
that translation of the drum across the work surface induces pressure
that enhances the weld between the sintered image and object. In other
embodiments, the layer thickness control processor controls the time and
temperature of the pressure applied between the drum and object to
achieve the desired layer density and to ensure bonding. In particular,
the layer thickness control processor is adapted to vary the speed and
temperature with which the drum 310 is translated across the work surface
between image layers to normalize the image thickness and provide optimal
bond quality. The transfixing heater 804 is preferably enabled as the
drum 310 traverses the length of the work surface.
[0050] At the distended drum position to the right of the platform
illustrated in FIG. 8D, a scraper 354 or brush, for example, is placed in
contact with the drum 310 while the drum is turned against the scraper to
remove any remaining powder or debris. The angle between the scraper 354
and the drum 310 is preferably between 0 and 45 degrees and the rate at
which the drum is turned is preferably between 10 and 100 inches per
minute. In some embodiments, the 3DP 200 further includes a powder
reservoir (not shown) to collect the powder or debris removed by the
scraper 354. In the alternative, an electric field and corona wire with a
high potential difference with respect to the drum 310 may also be used
to remove excess powder from the drum.
[0051] The drum 310 is returned to its home position, the work surface
cleaned to remove excess unsintered powder, the build platform lowered by
the scissor lift 206 to compensate for the thickness of the newly applied
sintered image, the heating pad reapplied to the object under
construction, and the process described above repeated until the object
is completed. In the second preferred embodiment, the means for cleaning
or otherwise preparing the work surface includes a retractable rotary
brush 352 incorporated into the drum assembly so that it may track the
drum 310 as it traverses the work surface. In the preferred embodiment,
the brush 352 is distended below the drum 310 before returning to its
home position to left in the example illustrations of FIGS. 8A-8D, and a
cylindrical brush head makes contact with the object and rotates
clockwise to clear away loose powder from the work surface or to level
the unsintered powder to the level of the newly deposited sintered image.
The retractable rotary brush 352 assumes a retracted configuration as the
drum passes left to right, as illustrated, depositing a sintered image so
as to avoid disturbing the newly deposited image before it has cooled
sufficiently.
[0052] In some other embodiments, the material removal mechanism for
cleaning the work surface includes a vacuum, a conductor for drawing
powder off the work surface using electrostatic attraction, a
non-retractable brush, a blower for providing high velocity air, or a
combination thereof. A non-retractable brush connected to the drum 310
may have a brush head, for example, adapted to maintain an interference
with the work surface in order to sweep the work surface immediately
after the image is transferred. In still other embodiments, the 3D
printer further includes object cooling means for directing air, for
example over the object to accelerate the rate at which a newly deposited
sintered image is cooled, thereby allowing the object to be cleaned by a
brush 352 immediately before and after the image is deposited, i.e., as
the drum 310 traverses the work surface to the left and to the right.
[0053] As discussed above, the 3DP 200 in some embodiments includes a
second heating pad 241B and corresponding support frame 208 rotatably
attached to the drum assembly. The second heating pad 241B, also referred
to as a "hot pad," is adapted to elevate and or maintain the temperature
of the upper side of the object until the next sintered image is applied.
As shown in FIGS. 8D and 8A, the pad 241B and frame 208 rotate up to
provide clearance for the drum 310 as an image is deposited onto the
object and then rotate back down to a point where it is in contact with
the object as the drum 310 returns to its home position and the work
surface is cleaned of unsintered powder. When in contact with the object,
the second heating pad 241B raises the upper surface of the object to
within several degrees of its melting point. This serves to reduce the
amount of energy that must be added to weld the next sintered image to
the object, to enhance the bond between the next sintered image and the
object, and to preserve the dimensional uniformity of the upper surface
of the object which is prone to dimensional distortion from internal
stresses caused by temperature gradients.
[0054] In some embodiments, the second heating pad 241B also cooperates
with a pressure sensing mechanism (not shown) and the layer thickness
control processor (discussed above) to apply a determined heat and
pressure to the top of the previously formed object with the deposition
of each layer during the three dimensional printing process. The
thickness of the newly deposited sintered image may be reduced by raising
the build surface 240 on which the object is constructed to compress the
top layer of the object against the second heating pad 241B with a
determined force. The object is generally held against the second heating
pad 241B during the formation of the next layer, which is enough time for
the curl forces to relax and or the layer thickness adjusted. As one
skilled in the art will appreciate, the pressure sensing mechanism may
also be used to dynamically control the drum to object gap, that is, the
pressure sensing mechanism is used to determined the actual height of the
object and therefore the distance that the build platform must be lowered
to achieve the optimum gap before application of the next sintered layer.
[0055] Instead of the scissor lift 206, the platform assembly in another
embodiment shown in FIG. 12 includes a horizontal build surface 1210
mounted to a lift 1220 that generally translates downward as the object
is assembled on the build surface. The lift is a linear motion system
including a high-torque stepper motor or other actuator, a drive system
including one or more belts and pulleys, and processor for determining
the proper force to apply between the build platform and the roller
during layer transfer. The height of the build surface 1210 is adjusted
downward relative to the drum 310 as one or more pulleys traverse one or
more belts under the power of a stepper motor (not shown) and step down
gear 1222. The set of pulleys includes a first pulley 1230 and a second
pulley 1240 which engage a belt 1250 that is held in dynamic tension
between its two attachment points 1252A, 1252B. When one or more of the
pulleys 1230, 1240 are made to rotate, the first pulley 1230 crawls along
the belt 1240 away from the upper attachment point 1252A while the second
pulley 1240 crawls along the belt 1250 toward the lower attachment point
1252B. The pulleys 1230, 1240 and belt 1250--in combination with
additional pulleys and belts 1254, 1256, 1258--cooperate to support the
four corners of the build surface 1210 and apply a uniform force in the
vertical direction as the platform ascends and descends. The path
traversed by the platform is further constrained by the guides 1260
(including linear ball hearings) and hardened steel shafts 1262. As can
be seen, the build platform 1210 can also be raised by merely reversing
the direction that the pulleys 1230, 1240 rotate. The preferred
embodiment further includes variable-current control circuitry, such as a
chopper drive, for each of the motor coils to vary the upward or downward
force applied by the lift. One or more optical encoders (not shown) may
be used to sense the vertical position of the build surface 1210 for
purposes of calculating any change in the force needed.
[0056] For each sintered image deposited, the height of the build surface
240 relative to the drum 310 is adjusted such that the top of the object
being constructed is lower than the drum 310 by a distance substantially
equal to the thickness of a sintered image applied to the object. In this
embodiment, the precise height of the build surface 1210 is dynamically
changed as the sintered image is deposited on the object in order to
achieve a pressure sufficient to laminate the image layer to the part
without squishing the image out from under the drum. The pressure, force
per unit area of image, is made substantially uniform across the entire
surface of an image being deposited on the object. The amount of force
required to achieve the desired pressure is based on the geometry of the
image, i.e., the area of direct contact between the drum and the part
and/or support being pressed onto the object at any given instant in
time. In general, the net force (neglecting friction) applied between the
build surface 1210 and the drum is proportional to the width of the
image. For example, the build surface 1210 is made to press the object
against the image on the drum with twice the force where the width of the
image is twice as large, thereby achieving a constant pressure across the
two sections of the image.
[0057] In the preferred embodiment, an instantaneous force needed to
achieve a predetermined pressure is computed for a plurality of segments
of each image. The segments of the image correspond to strips spaced at a
predetermined distance apart (e.g., 1 millimeter) in the direction of
image roll-off. The lift 1220 is then driven upward (or downward) to
achieve the necessary force when then roller coincides with the
corresponding segment of the image. The force applied to the lift when
the roller is between segments of the image is determined by linear
interpolation, for example.
[0058] In the preferred embodiment, the requisite force between the object
and image is applied by a stepper motor with an encoder mounted thereto.
The encoder in the preferred embodiment has resolution sufficient to
resolve three or more positions of the motor within a single step of the
motor. An encoder configured to resolve 4000 "clicks" per revolution, for
example, can resolve 80 positions per step of a motor having 50 4-step
cycles per revolution.
[0059] The stepper motor is driven by two motor current signals provided
to a pair of coils that are 90 degrees out of phase. The motor currents
can be used to drive the motor to any angle within a cycle. When the
motor currents correspond to an angle different from the motor's rotor
angle, a resultant force is applied to the motor. The resultant force is
generally proportional to the motor currents applied (i.e., more current
produces more force). To drive the lift 1220 with the requisite force in
the vertical direction, the motor currents are continually adjusted to
specify a "driving angle" that is the sum of the actual rotor angle and a
fixed offset in the direction the force is to be applied. The subsequent
force exerted by the motor is then varied by varying the amount of
current applied to the coils at the drive angle.
[0060] In some embodiments, the 3DP 200 includes a layer processing
surface other than a processing drum 310 to form an individual sintered
layer. The layer processing surface may be, for example, a planar surface
on which the sintered layer is formed before being pressed or otherwise
stamped onto the work surface on the platform assembly.
[0061] In some embodiments, the drum 310 and sinterable powder bin 210 are
provided as a removable and replaceable unit to enable the user to easily
remove and replace or repair the unit. The sinterable powder bin 210 is
preferably a sealed or tamper resistant container analogous to toner
cartridges.
[0062] In a third preferred embodiment of the 3DP, the object is
constructed from sintered images that are sintered in the build vat in
which the object is constructed. The 3DP may further include a second vat
(not shown), namely a powder vat the supplies powder to the assembly vat
to build the object. Both vats are also heated to a temperature just
below the melting point of the powder to, for example, reduce the amount
of energy needed to melt the powder.
[0063] The height of the work surface in the build vat is held
substantially level with the height of the powder in the powder vat to
facilitate the distribution of powder to the build vat. In the preferred
embodiment, the build vat is made to descend and the powder vat made to
ascend in proportion to one another. The height of each of the vats is
preferably controlled by a separate scissor lift operably coupled to a
microprocessor. A powder roller is used to move a layer of powder from
the powder vat to the build vat and distribute it with uniform thickness
and density. The powder layers deposited in the build vat are
approximately 5-20 mils in thickness. In the third preferred embodiment,
the roller is attached to the same sinter assembly to take advantage of
the existing actuators, although it may also be mounted to a separate
control mechanism.
[0064] The sinter assembly preferably includes an inexpensive incoherent
energy source adapted to provide focused heat to sinter the uppermost
layer of powder in the build vat. The heat source preferably includes an
elliptical reflector and or a Winston cone. As with the second
embodiment, the sinter assembly may further use a mask with a hole for
controlling the spot size of the beam, and a shutter for interrupting the
beam. An example spot size in this example is approximately 30-70 mils.
In contrast to the second embodiment, the focal point coincides with the
upper most layer of sinterable powder in the build vat and the sintered
image created by sweeping the sinter assembly across the width and length
of the build vat in accordance with the associated cross-sectional layer
of the model.
[0065] Illustrated in FIG. 9A-9E are cross sectional diagrams
demonstrating the formation of an object using a partially sintered
support structure. A partially sintered support structure as used herein
refers to a laminar structure that is built of sinterable powder
concurrently with the object being assembled to provide structural
support, during assembly, for portions of the object that project or
overhang with respect to the preceding layer of sintered powder. The
partially sintered support structure may be used in the present invention
and other rapid prototyping application where unimaged sinterable powder
is removed from the work surface after the imaged layer is transferred to
the previous layer of the object being assembled. A support structure
generally comprises two portions including (1) a substantially rigid
portion that is sintered with the same energy density as the object being
assembled and (2) an interface portion sintered with less energy than the
object to provide a detachable boundary between the rigid portion and
object.
[0066] Referring to an exemplary structure and object, shown in cross
section FIG. 9A, the support structure 900 being assembled comprises a
plurality of layers 901-905 of sintered powder which may include one or
more layers 901-902 deposited before the first layer of the object. The
third sintered image layer 903 is produced with a substantially rigid
portion 920 as well as an interface portion 930 in proximity to the first
sintered image layer 951 of the object being assembled. The fourth
sintered image layer 904 is produced with a substantially rigid portion
921 and an interface portion 931 adjacent to the first sintered image
layer 951 of the object. The fifth sintered image layer 905 includes a
substantially rigid portion 922, an interface portion 932 as well as the
first sintered image layer 951 of the object. The base layers 901-902 and
substantially rigid portion 920-922 are fused with the same energy per
unit area per unit time as the object being assembled including the first
sintered image layer 951.
[0067] The interface portions 930-932 are fused with the less energy per
unit area per unit time than the layers of the object. In the preferred
embodiment, the interface portions 930-932 are sintered by subjecting
sinterable powder in the region of the interface to the radiant energy
source for a shorter period of time than the regions of the object and
rigid portions. The radiant energy source may be made to traverse the
drum and draw, i.e., sinter, the region of the interface at a rate that
is 40 to 100 percent faster than the regions associated with the object,
for example, thereby making the interface portion weaker than the part
and support structure. In general, the particles of sinterable powder
associated with the interface portion are fused to a lesser degree than
the particles of the object or rigid portion, thereby giving rise to a
difference in density that makes the interface relatively weak
structurally.
[0068] Referring to the cross section of FIG. 9B, the additional layers of
the object and of the support structure 900 are concurrently imaged and
transferred. The completed support structure 900 includes base layers
901-902, rigid portions 920-924, as well as interface portions 930-935.
As illustrated, the rigid portions 920-924 and interface portions 930-935
are adapted to conform to the contours of the object being assembled,
which is a sphere in the present example. In particular, the layers of
the support structure 900 enable a layer of the object to be effectively
transferred with little or no distortion even where the layer being
transferred projects beyond or is cantilevered with respect to the
preceding object layers, which is true of each of the object layers
951-956. Thereafter, the remaining layers 957-958 of the object are
printed and transferred to the object being assembled (sec FIG. 9C), the
completed object 950 separated from the support structure 900 at a
boundary defined by the interface portion 931-936 (see FIG. 9D), and the
interface portion removed to reveal the completed object 950 (see FIG.
9E).
[0069] Referring to FIGS. 10A-10C, the object 950 of FIG. 9A-9E may be
constructed from layers having optimized border and fill patterns to
increase the build speed, reduce internal stresses that lead to
dimensional inaccuracies, and make the part less brittle, i.e., more
durable. In particular, the region within the border 106 of the sintered
image 1000 is generated from a plurality of parallel sections of rigidly
fused sintered powder 1002 separated by sections of unsintered powder
1004. The succeeding sintered image 1010 may have a border 1016 and an
open fill pattern including parallel sections of rigidly fused sintered
powder 1012 and sections of unsintered powder 1014 having an orientation
rotated by 90 degrees with respect to the preceding layer. In the
preferred embodiment, each of the parallel sections of rigidly fused
sintered powder 1002 forming the till pattern are preferably generated by
selecting an aperture for the heat source to produce the largest spot
size possible that the particular area of the image being sintered will
allow. This will significantly reduce the time required to produce the
image and therefore the object. The width and spacing of the parallel
sections of rigidly fused sintered powder 1002, 1012 and the width of the
borders 1004, 1014, may be determined by the feature size and geometry.
For example, a smaller feature may require a smaller spot size for the
border and fill, while the border and fill of a larger feature may be
generated with a larger spot size alone. Similarly, a smaller spot size
may be used to generate a small object while a large spot size is used to
generate a large object. The border and fill patterns may also be further
optimized for speed, strength, cooling, or to produce vias 1022 that
allow unsintered powder to be evacuated from the object being assembled
1020 or after the build is completed.
[0070] Illustrated in FIGS. 11A-11B is a layer thickness reference (LTR)
wall 1110 used to accurately deposit and correct the height of the object
being assembled. The wall 1110 is built layer by layer concurrently with
the object 950 and is made from fully fused sintered powder. The height
of the upper surface 1112, 1122 of the wall 1110 having a consistent
geometry, is generally more uniform than the height of the object, which
may become non-planar if minor errors in layer thickness are permitted to
accumulate. The upper surface 1112 of the wall 1110 may therefore be used
as a guide for a material removal mechanism, preferably a scraper blade
1120, also referred to as a doctor blade, that is passed across the
object 950 to shave or otherwise remove high spots, thereby yielding a
uniformly planar surface 1102 at a predetermined height. The subsequent
sintered image 1104 and wall layer 1122 is then deposited and the scraper
blade 1120 passed over the upper surface 1106 again to correct any
non-uniformities. The process may be repeated for each layer of the
object being assembled. Although the scraper blade 1120 requires as few
as one or two sides of the wall 1110 parallel to the direction of travel,
a wall that fully encircles the object being assemble further serves to
retain unsintered powder for purposes of providing underlying support for
subsequent sintered images.
[0071] In some embodiments of the present invention, unsintered or
partially sintered powder is removed from the drum using a brush, for
example, before the sintered image is rolled onto the object being
assembled. This may be necessary to prevent the unsintered powder, which
is less dense than sintered powder, from the being applied to the object
where it can build up at a relatively fast rate and interfere with the
bonding of subsequent image layers. Referring to the side view in FIG.
13, the three dimensional printer 1300 employs the powder removal brush
1320 to remove all of the unimaged powder from the drum 310 after the
powder is sintered into an image but before that image is rolled off from
the drum, without removing any of the sintered image.
[0072] The powder removal brush 1320 must be able to withstand high
temperatures and resist against wear. In the preferred embodiment, the
powder removal brush 1320 includes carbon fiber bristles that are stiff
enough to brush away the unimaged powder while soft enough to pass over
the image without removing it from the drum. The diameter of the brush is
about 1.75 inches with a twisted-wire core. The carbon fiber bristles are
0.00028 inches in diameter with an unsupported length of almost 0.875
inches, thereby making each bristle extremely flexible and able to bend
as it contacts the drum.
[0073] To accomplish this brushing, the brush 1320 may be turned with
respect to the drum 310, the drum turned with respect to the brush, or a
combination thereof. In the preferred embodiment, the drum and the brush
are both rotated so their relative tangential speed is greater than the
speed of either the brush or the drum. The relative speed and the
interference between the brush fibers and the drum may be adjusted to
finely tune the amount of unimaged powder that is removed. In the
preferred embodiment, the relative speed between the drum and brush is
set to 18.5 inches per second. The interference between the bristles and
the drum is set between 0.030 and 0.090 inches.
[0074] An exemplary mechanism 1400 for implementing brush before roll-off
(BBR) is shown in FIGS. 14A and 14B. The BBR mechanism includes a frame
1410 in which the powder removal brush 1320 is mounted and a cam 1420 for
driving the brush against the drum 310. Before the layer of powder on the
drum is sintered, the cam 1420 resides in a position that holds the brush
1320 away from the drum (see FIG. 14A). After the image is sintered, the
cam 1430 rotates about 180 degrees which pushes against a compliant
support 1430 to rotate the frame 1410 about the pivot 1412 until the
brush makes the proper interference with the drum (see FIG. 14B). The
brush and/or drum may then be rotated to selectively remove any
unsintered powder away from the sintered image on the drum. A threaded
mount 1432 may be used to manually set or adjust the position of the
compliant support, thereby controlling the amount of interference between
the brush 1320 and drum 310. The BBR mechanism may further include one or
more shields 1450 around the brush to contain the unsintered powder
removed from the drum and direct that powder to a waste bin (not shown).
[0075] Using the BBR mechanism, the three dimensional printer can be
configured to brush off unsintered powder from the drum to prevent the
detrimental impact of powder accumulation. In one embodiment, the
unsintered powder is removed from the drum from every N.sup.th layer of
the object being assembled, thereby compensating for the relatively fast
rate of build-up compared to the sintered material. If unsintered powder
is retained to construct a support for the object, for example, the
unsintered powder may be removed from the drum every 10.sup.th image.
This is particularly advantageous where the density of the sintered
powder is 60-90% that of the unsintered powder, thereby allowing the 10
layers of sintered material to "catch up" and vertically align with the 9
layers of unsintered support. This results in supports that are easier to
remove and objects having layers that are better welded together.
[0076] The strength of the powder supports assembled underneath and around
the periphery of an object may be enhanced using a support structure
including a combination of sintered sections, partially sintered
sections, or a combination thereof. This type of support, shown in FIG.
15 for example, comprises a plurality of sintered line segments 1510,
1520 aligned parallel in the direction 1590 of layer roll-off. The line
segments of the pattern, namely a hatch pattern, are separated by a
distance just large enough to prevent the line segments from fusing
together. This pattern is repeated across in width of the layer of
support structure in the horizontal direction perpendicular to the
roll-off direction. The pattern is also repeated in the vertical
direction 1592 for a predetermined number of layers, the sintered line
segments of each layer being stacked directly on top of the preceding
layer to form vertical walls 1530 or walls biased on a diagonal. Each
wall 1530 may be segmented with a gap 1580 in the lateral direction
parallel to the roll-off direction to yield a maximum length of one inch,
for example, to facilitate removal of the support from the object after
final assembly. One skilled in the art will appreciate that the vertical
walls 1530 is one of a plurality of sintered support patterns that may be
used including columns, honeycomb, or fractal, for example.
[0077] After the predetermined number of layers are stacked to form walls,
one or more cross hatch line segments 1540 are formed in the layers of
the support structure to link the walls 1530 together. The vertical
pattern of parallel line segments and cross hatching may be repeated as
needed until the underlying support or lateral support for the object is
completed.
[0078] In some embodiments, the sintered line segments that are stacked to
form walls are generated from sequential layers of images formed on the
drum. That is, a wall formed from 10 line segments is generated from the
line segments of 10 consecutive images. To enhance the removability of
the support structure, however, one or more of the walls in some other
embodiments are formed by skipping one or more layers of line segments.
That is, a wall formed from 10 line segments may be generated by line
segments of 11 or more non-consecutive images, e.g., line segments from
layers 1-5 and layers 7-11 with no contribution from layer 6. While the
object is generated from the combination of each of the 11 or more
images, select layers that might otherwise form the walls are removed in
order to prevent the support structure from building up at a rate greater
than the object.
[0079] The width of the walls and the cross hatches is approximately 0.080
inches in the preferred embodiment. The energy with which the line
segments are formed may fully sinter or partially sinter the powder for
the supports depending on the support strength, rigidity, and
removability required. The strength is required to overcome the
compressive pressures of the drum during layer roll-off as well as the
tensile forces of the curl forces generated by internal stresses in the
imaged part, which are caused by temperature gradients in the part.
[0080] Another technique to enhance the ability of a support removal
entails sintering a border around the support structure where the support
extends further in the lateral direction that the object. In the
preferred embodiment, the support structure follows the general contour
of the object being assembled but with an additional lateral offset that
increases the footprint of the support structure over that of the
footprint of the object. The support structure may further include an
outer contour line that encloses the entire support structure. To prevent
the support border from becoming too strong or rigid, the border may be
intermediately segmented in both the horizontal direction as well as the
vertical direction. The support structure may further include an inner
contour line that is in proximity to but offset from the outer contour
line of the part at that layer. The nominal distance between the
support's inner contour line and the object's outer contour line
preferably ranges between 5 mils and 25 mils. A distance of 5 mils is
effective at firmly holding the object within the support structure,
while a distance of 25 enables the support to be broken away from the
object with ease. In some embodiments, distance between the object and
individual walls of the support structure may alternate between 5 mils
and 25 mils from one wall to the next adjacent wall in order to achieve a
combination of firm support and easy support removal. Similarly, the
distance between the object and walls of the support structure may
alternate between 5 mils and 25 mils between successive layers as well.
[0081] Although the description above contains many specifications, these
should not be construed as limiting the scope of the invention but as
merely providing illustrations of some of the presently preferred
embodiments of this invention.
[0082] Therefore, the invention has been disclosed by way of example and
not limitation, and reference should be made to the following claims to
determine the scope of the present invention.
* * * * *
