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| United States Patent Application |
20090179355
|
| Kind Code
|
A1
|
|
Wicker; Ryan
; et al.
|
July 16, 2009
|
METHODS FOR MULTI-MATERIAL STEREOLITHOGRAPHY
Abstract
Methods and systems of stereolithography for building cost-efficient and
time-saving multi-material, multi-functional and multi-colored
prototypes, models and devices configured for intermediate washing and
curing/drying is disclosed including: laser(s), liquid and/or platform
level sensing system(s), controllable optical system(s), moveable
platform(s), elevator platform(s), recoating system(s) and at least one
polymer retaining receptacle. Multiple polymer retaining receptacles may
be arranged in a moveable apparatus, wherein each receptacle is adapted
to actively/passively maintain a uniform, desired level of polymer by
including a recoating device and a material fill/remove system. The
platform is movably accessible to the polymer retaining receptacle(s),
elevator mechanism(s) and washing and curing/drying area(s) which may be
housed in a shielded enclosure(s). The elevator mechanism is configured
to vertically traverse and rotate the platform, thus providing angled
building, washing and curing/drying capabilities. A horizontal traversing
mechanism may be included to facilitate manufacturing between components
of SL cabinet(s) and/or alternative manufacturing technologies.
| Inventors: |
Wicker; Ryan; (El Paso, TX)
; Medina; Francisco; (El Paso, TX)
; Elkins; Christopher; (Redwood City, CA)
|
| Correspondence Address:
|
FULBRIGHT & JAWORSKI L.L.P.
600 CONGRESS AVE., SUITE 2400
AUSTIN
TX
78701
US
|
| Family ID:
|
35731225
|
| Appl. No.:
|
12/389147
|
| Filed:
|
February 19, 2009 |
Related U.S. Patent Documents
| | | | |
|---|
|
| Application Number | Filing Date | Patent Number |
|---|
| | 10903379 | Jul 30, 2004 | |
| | 12389147 | | |
|
|
| Current U.S. Class: |
264/401 |
| Current CPC Class: |
B29C 67/0062 20130101; B29C 67/0066 20130101; B33Y 40/00 20141201; B33Y 70/00 20141201; B33Y 10/00 20141201; B33Y 30/00 20141201 |
| Class at Publication: |
264/401 |
| International Class: |
B29C 35/04 20060101 B29C035/04 |
Claims
1-33. (canceled)
34. A method of multi-material stereolithography comprising the steps of:
solidifying a first polymer into a first desired subject part layer of a
subject part; and solidifying a second polymer on the subject part,
wherein the second polymer is not the same as the first polymer.
35. The method of claim 34, wherein solidifying the second polymer on the
subject part comprises solidifying the second polymer into a second
desired subject part layer of the subject part.
36. The method of claim 35, wherein the first desired subject part layer
and the second desired subject part layer have different thicknesses.
37. The method of claim 34, wherein solidifying the second polymer on the
subject part comprises solidifying the second polymer into the first
desired subject part layer of the subject part.
38. The method of claim 34, further comprising the step of washing the
subject part, wherein the step of washing the subject part is performed
after the step of solidifying the first polymer and before the step of
solidifying the second polymer.
39-40. (canceled)
41. The method of claim 34, further comprising the step of solidifying
the first polymer into a third desired subject part layer of the subject
part.
42. The method of claim 34, wherein the first desired subject part layer
comprises multiple layers.
43-48. (canceled)
49. The method of claim 34, further comprising the step of solidifying
the second polymer into a third desired subject part layer of the subject
part.
50. The method of claim 35, wherein the second desired subject part layer
comprises multiple layers.
51. The method of claim 34, further comprising solidifying a third
polymer on the subject part into a third desired subject part layer,
wherein the third polymer is not the same as the second polymer.
52. The method of claim 51, wherein the third polymer is not the same as
the first polymer.
53-62. (canceled)
63. The method of claim 34, wherein the method further comprises
performing an alternative manufacturing technology on the subject part.
64. The method of claim 63, wherein the alternative manufacturing
technology is selected from the group consisting of: Computer Numerical
Control (CNC) milling apparatuses and tool carousels, Coordinate
Measuring Machine (CMM) probes and other vision measurement systems,
Fused Deposition Modeling (FDM), Selective Laser Sintering (SLS), Layered
Object Manufacturing (LOM) and other RP technologies, micro-machining
systems, micro-jet and other cutting systems such as water jet, laser and
plasma cutting systems, painting apparatuses, ink jets and other fluid
and particle dispensing mechanisms and other pick and place technologies
including robotic materials placement technologies, and any combination
thereof.
65-67. (canceled)
68. The method of claim 34, wherein at least one of the first polymer and
the second polymer is a hydrogel selected from the group consisting of
natural polymers, synthetic polymers and any combinations thereof.
69. The method of claim 34, wherein at least one of the first polymer and
the second polymer is a resin composition selected from the group
consisting of: a radically polymerizable organic compound, a cationically
polymerizable organic compound, a polyether, polyol compound, elastomer
particle and any combination thereof.
70. The method of claim 34, wherein at least one of the first polymer and
the second polymer is selected from the group consisting of
stereolithography resins, curable inks, photopolymer resins, photopolymer
powdered materials and any combination thereof.
71. The method of claim 34, wherein the method further comprises the step
of incorporating an additive into at least one of the first polymer and
the second polymer.
72. The method of claim 71, wherein the additive is selected from the
group consisting of color altering, thermal property altering, electrical
property altering, optical property altering, mechanical property
altering, strength altering, function altering, biofunction altering
additives and any combination thereof.
73. The method of claim 71, wherein the additive is selected from the
group consisting of imbedded devices and imbedded materials, such as
bioactive ingredients and cells, and any combination thereof.
74. The method of claim 34, further comprising the step of using one or
more lasers to solidify a polymer.
75-106. (canceled)
107. A method of multi-material stereolithography comprising the steps
of: solidifying a first material into a first desired subject part layer
of a subject part, wherein the first material comprises a first polymer;
and solidifying a second material on the subject part, wherein: the
second material comprises a second polymer; and the second material is
not the same as the first material.
108. The method of claim 107, wherein solidifying the second material on
the subject part comprises solidifying the second material into a second
desired subject part layer of the subject part.
109. The method of claim 107, wherein solidifying the second material on
the subject part comprises solidifying the second material into the first
desired subject part layer of the subject part.
110. The method of claim 107, wherein the first polymer is not the same
as the second polymer.
111. The method of claim 107, wherein the first polymer is the same as
the second polymer.
Description
BACKGROUND
[0001] The present invention relates to the general field of rapid
prototyping technology, and in particular, to stereolithography methods
and systems.
[0002] Rapid prototyping (RP) technologies, also known as Solid Freeform
Fabrication (SFF), layered manufacturing and other similar technologies
enable the manufacture of complex three-dimensional (3D) parts. RP
technologies, in particular, generally construct parts by building one
layer at a time. RP technologies are commonly used to build parts and
prototypes for use in, for example, the toy, automotive, aircraft and
medical industries. Oftentimes prototypes made by RP technologies aid in
research and development and provide a low cost alternative to
traditional prototyping. In a few cases, RP technologies have been used
in medical applications such as those associated with reconstructive
surgery and tissue engineering (TE).
[0003] Stereolithography (SL) is one of the most widely used RP
technologies known in the art. The resolution of SL machines and the
ability of SL to manufacture highly complex 3D objects, make SL ideal for
building both functional and non-functional prototypes. In particular, SL
techniques provide an economical, physical model of objects quickly and
prior to making more expensive finished parts. The models are readily
customizable and changes may be easily implemented.
[0004] SL generally involves a multi-stage process. For example, the first
stage involves designing and inputting a precise mathematical geometric
description of the desired structure's shape into one of many
computer-aided design (CAD) programs and saving the description in the
standard transform language (STL) file format. In the second stage, the
STL file is imported into SL machine-specific software (RP software). The
RP software slices the design into layers and determines the placement of
support structures to hold each cross-section in place while building the
structure layer by layer. By computing build parameters, the RP software
controls the part's fabrication. In the layer preparation stage, the
build parameters for the desired part are translated into machine
language. Finally, the machine language controls the SL machine to build
a desired part and its support structure layer by layer. SL machines
typically focus an ultraviolet (UV) laser onto a cross-section of a
liquid photopolymer resin. The laser, in turn, selectively cures a resin
to form a structure, such as anatomical shapes (i.e., organs and
tissues), layer by layer. Ultimately, the part is cleaned, the support
structure is removed and the part is post-cured (typically exposed to UV)
prior to completion.
[0005] SL technologies known in the art generally include, for example, a
laser, a liquid level sensing system, laser beam optics and controllable
mirror system, a vertically movable platform, single resin retaining
receptacle or vat and a recoating device. During the laser scanning
phase, a series of optics and controllable mirrors raster a UV laser beam
to solidify a photocurable polymer resin. The subject 3D part is first
attached to the platform by building a support structure with the
platform in its topmost position. This step allows for misalignment
between the platform and the surface of the liquid resin--once
constructed, the base support structure is parallel with the surface of
the liquid. When building the subject part simultaneously with its
required support structure and after the laser beam completes a layer,
the platform typically is vertically traversed downward a distance equal
to the build layer thickness. After the platform is vertically traversed
downward and prior to selectively curing the next layer, a recoating
device is typically traversed horizontally across the part that deposits
a uniform layer of liquid polymer across the part. The recoating device
ensures that trapped spaces within the part are filled with liquid resin
(which may be required for future build layers), and is used to maintain
a constant build layer thickness. The process repeats as each layer is
built. Complex-shaped parts are thus manufactured by repeating the
layering process. Once complete, the part is typically raised out of the
liquid polymer, the support structure is removed from the part and the
part is cleaned and then post-cured. The operator may, however, need to
sand, file or use some other finishing technique on the part in order to
provide a specific surface finish to the structure, which may include
painting, plating and/or coating the surface.
[0006] TE techniques, in particular, rely on necessary fluids, growth
factors and cells to perfuse through the pores of a scaffold (a
supporting structural and potentially bioactive framework used in tissue
engineering for directed cell growth). One of the most challenging
problems in TE involves promoting cell in-growth and perfusion to seeded
cells in implanted scaffolds. The diffusion of oxygen and nutrients is
not sufficient to sustain cell viability beyond distances of
approximately 100 microns in the body. TE techniques, therefore, must
retain precise control over the resulting 3D geometry to design favorable
perfusion into a scaffold thus maintaining cell viability. SL
technologies allow direct manufacturing of perfusion promoting
implantable scaffolds. Hydrogels are biocompatible materials that exhibit
favorable perfusion characteristics and are currently used in
photolithographic processes using manual lithographic masking techniques
as well as a variety of other processes. Implantable multi-material
hydrogel constructs, however, are not currently suited for single
material SL machines known in the art.
[0007] Accordingly, improvements in part building technology are desired.
Specifically, there is a need for a low cost, efficient and easy to use
stereolithography system that accommodates multiple building materials or
resins. What is desired is a system that maintains a non-contaminating
and sterile building environment while accommodating intermediate
cleaning and curing between materials and/or resins. For example, when
building biomedical implantable structures and/or devices, it is
imperative to maintain a sterile building environment. It is equally
important that resin or resin residue from one portion of the build does
not contaminate any other resin when building with multiple materials,
and thus, intermediate washing between materials is a critical element of
the desired system. What is also desired is a multiple resin system to
directly manufacture complex multiple-material, functional and
non-functional prototypes and finished devices. What is further desired
is an SL system that accommodates building multiple material, implantable
hydrogel structures and other microstructures. What is still further
desired is an SL system that allows additives, such as color (pigments,
dyes and other color additives known in the art), to incorporate into
resins on a layer by layer basis. Still another desire is to have a
system that allows other resin additives and/or other materials (as in
part embedding or cell seeding) to alter characteristics, such as the
strength, mechanical, optical, thermal, electrical, functional and
biofunctional properties of the resin and/or resulting model on a layer
by layer basis or even within a single layer.
SUMMARY OF THE INVENTION
[0008] The present invention overcomes the aforementioned limitations in
an effective and efficient manner, thus expanding the use of RP in
various applications and improves SL functionality. The present
invention, for example, also provides improvements in vat and platform
exchange, material isolation, material fill/removal, material level
sensing and control, intermediate washing and rinsing, intermediate
post-curing/drying and incorporating material and/or resin additives on a
layer by layer basis or within a single layer. The present invention
provides these improvements while maintaining a sterile and
non-contaminating building environment. For example, when building
multi-material functional and non-functional structures and/or devices,
it is imperative to eliminate the contamination of materials and/or
resins between retaining receptacles. It is further imperative when
building biomedical implantable structures and/or devices to maintain a
sterile building environment.
[0009] The present invention provides, for example, multiple polymer
retaining receptacles or vats in a stacked system, a fixed vat system or
a carousel system, as examples, designed to accommodate multi-material
fabrication of a part. The numerous materials compatible with use in the
present invention include, for example, polymers that are photocurable
using an ultra-violet (UV) light source with a wavelength compatible with
current SL machines. Other suitable polymers and materials are described
herein. In one embodiment of the present invention, each vat is easily
exchangeable and is connected to a pump system. A pump system fills and
removes polymers from individual vats and facilitates the exchange of
materials, if necessary, while maintaining a sterile building
environment.
[0010] The present invention also provides a platform system which
transports the subject part from one area of the SL machine to another or
between two or more SL machines. For example, the platform system may
transport a subject part for intermediate washing and rinsing in the
washing unit and then post-curing/drying (or intermediate curing/drying)
in the curing/drying unit. The intermediate curing capability allows for
any uncured material to be cured and/or dried prior to immersing the
platform with the subject part in the next material, thus, providing
sterile multi-material fabrication on a layer by layer basis or within a
single layer.
[0011] One embodiment of the present invention further provides a platform
system which may be rotated during the washing and/or curing/drying
cycles to facilitate angled washing and curing/drying. The platform
provides, for example, the ability to rotate and position itself, within
the washing and curing/drying unit. Because the platform is further
designed to provide a sealed enclosure, overspray from the washing area
and curing/drying unit is eliminated. The platform is further adapted to
rotate at any angle during the building processes. Thus, the present
invention facilitates angled part building, washing, curing and drying
(about a horizontal axis).
[0012] The present invention significantly decreases overall build times
for multiple material applications. Thus, for example, the present
invention has the potential to maintain cell viability and increase
flexibility for 3D complexity required by real tissue generation
applications. The present invention also provides improvements in
implantable complex-shaped, multi-material curable polymer constructs
which may now be directly manufactured for implantation and facilitate TE
for organs and tissues.
[0013] The present invention may be retrofitted into existing
stereolithography technology and aid in the manufacturing of 3D
multi-material functional and non-functional prototypes and devices, or
it can be introduced as a new technology incorporating the inventive
concepts described herein. For example, one embodiment of the SL machine
may include a single vat, an enclosed stationary washing area with a
curing/drying unit, a movable platform, an elevator mechanism with
optional platform rotation mechanism, an optional alternative
manufacturing apparatus and a horizontal traversing unit configured to
access each of the above-listed components of the SL machine.
[0014] As another example, an alternative embodiment of the SL machine may
include two single vats, an enclosed stationary washing area with a
curing/drying unit, a movable platform, an elevator mechanism with
optional platform rotation mechanism, an optional alternative
manufacturing apparatus and a horizontal traversing unit configured to
access each of the above-listed components of the SL machine.
[0015] As yet another example, an alternative embodiment of the SL machine
may include a single rotatable vat apparatus (a vat carousel apparatus),
a stationary washing area with a curing/drying unit, a movable platform,
an elevator mechanism with optional platform rotation mechanism, an
optional alternative manufacturing apparatus and a horizontal traversing
unit configured to access each of the above-listed components of the SL
machine.
[0016] As still another example, an alternative embodiment of the SL
machine may include two rotatable vat apparatuses (vat carousel
apparatuses) separated by an enclosed stationary washing area with a
curing/drying unit, a movable platform, an elevator mechanism with
optional platform rotation mechanism, an optional alternative
manufacturing apparatus and a horizontal traversing unit configured to
access each of the above-listed components of the SL machine.
[0017] As still one more example, an alternative embodiment of an SL
machine may include a rotatable vat apparatus (a vat carousel apparatus),
an enclosed stationary washing area with curing/drying unit, two movable
platforms, optional alternative manufacturing apparatuses and a
dual-sided elevator mechanism with one or more optional platform rotation
mechanisms configured to access each of the above-listed components of
the SL machine.
[0018] The present invention may also aid in designing new
stereolithography applications and thus provides expanded opportunities
for manufacturing multi-material products using RP, while providing a
cost effective and easy to implement system. For example, the present
invention still further provides an SL system that allows additives, such
as color, to incorporate into resins on a layer by layer basis or within
a single layer. Thus, the present invention, for example, facilitates
multi-colored SL. The present invention also accommodates other resin
additives, such as those that alter characteristics relating to the
strength, mechanical, optical, thermal, electrical, functional and/or
biofunctional properties of the resin, on a layer by layer basis or
within a single layer. For example, a given part may be made of a single
material, but have portions of the part constructed with an additive
incorporated into that material. For example, the additive may be rigid,
encapsulated gas or some other material that may or may not be
photocurable with U. The additive may require some other type of curing
mechanism. For example, the additive may be a thermally curable material.
[0019] The present invention also facilitates interfacing with other
manufacturing technologies. For example, manufacturing technologies may
include such technologies as Computer Numerical Control (CNC) machining
and ink jet printing (such as those used to print polymers, curable inks
and/or proteins, as examples). Thus, the given part may be designed to
exhibit different material properties at any given location. The present
invention thus provides endless combinations of multi-material and
multi-colored construction and significant improvements in numerous
applications requiring complex, three-dimensional, functional and
non-functional prototyping or finished products.
[0020] The present invention still further provides methods and systems
for multi-layered and multi-material manufacturing using, for example,
hydrogel solutions in existing SL RP machines. These methods and systems
require software and hardware to, for example: (1) interface with the
existing RP technology; (2) maintain the biocompatibility of the hydrogel
solution; (3) determine the optimum SL machine parameters for
successfully manufacturing hydrogel constructs with or without living
cells and bioactive elements; and (4) develop the processes required for
multi-material construction both within and across build layers. The
present invention will accommodate these needs and provide further
improvements in TE, chemical sensing, biological sensing and numerous
other applications requiring complex, three-dimensional, multi-material,
multi-element and/or multi-color manufacturing. The present invention,
for example, further provides a multi-material SL system that builds
angiogenic structures or roadways between proliferative structures for
use in, for example, guided angiogenesis to restore vascular function.
BRIEF DESCRIPTION OF THE DRAWINGS
[0021] The above and further advantages of the invention may be better
understood by referring to the following description in conjunction with
the accompanying drawings, in which:
[0022] FIG. 1 is an illustration of a prior art SL machine;
[0023] FIG. 2 is an illustration of a prior art SL machine which may serve
as a preferred working environment of a multi-material SL machine of the
present invention;
[0024] FIG. 3A is a perspective view of a preferred UV shielded cabinet, a
preferred rotatable vat apparatus and optional platform rotation
mechanism of an SL machine of the present invention;
[0025] FIG. 3B is a perspective side view of a preferred movable platform
and optional platform rotation mechanism of the present invention;
[0026] FIG. 3C is another perspective view of a preferred movable platform
and optional platform rotation mechanism of the present invention shown
when the movable platform is located in the material vat;
[0027] FIG. 3D is another perspective view of FIG. 3C shown when a
preferred movable platform is located outside the material vat;
[0028] FIG. 4 is a perspective view of an alternative embodiment of a
rotatable vat apparatus of the present invention;
[0029] FIG. 5 is an illustration of the rotational capabilities of a
preferred movable platform and optional platform rotation mechanism of
the present invention;
[0030] FIG. 6A is a perspective view of an alternative embodiment of an SL
machine in accordance with the present invention shown with two single
vats, an enclosed stationary washing area with a curing/drying unit, a
movable platform, an elevator mechanism with an optional platform
rotation mechanism, an optional alternative manufacturing apparatus and a
horizontal traversing unit configured to access each of the above-listed
components of the SL machine;
[0031] FIG. 6B is another perspective view of the alternative embodiment
of FIG. 6A;
[0032] FIG. 7A is a perspective view of an alternative embodiment of an SL
machine in accordance with the present invention shown with a single
rotatable vat apparatus, a stationary washing area with a curing/drying
unit, a movable platform, an elevator mechanism with an optional platform
rotation mechanism, an optional alternative manufacturing apparatus and a
horizontal traversing unit configured to access each of the above-listed
components of the SL machine;
[0033] FIG. 7B is another perspective view of the alternative embodiment
shown in FIG. 7A;
[0034] FIG. 8A is a perspective view of another alternative embodiment of
an SL machine in accordance with the present invention shown with two
rotatable vat apparatuses separated by an enclosed stationary washing
area with a curing/drying unit, a movable platform, an elevator mechanism
with an optional platform rotation mechanism, an optional alternative
manufacturing apparatus and a horizontal traversing unit configured to
access each of the above-listed components of the SL machine;
[0035] FIG. 8B is another perspective view of the alternative embodiment
shown in FIG. 8A;
[0036] FIG. 9A is a perspective view of still another alternative
embodiment of an SL machine in accordance with the present invention
shown with a rotatable vat apparatus, an enclosed stationary washing area
with curing/drying unit, two optional alternative manufacturing
apparatuses and a dual-sided, rotatable elevator mechanism with two
movable platforms, shown with optional platform rotation mechanisms
configured to access each of the above-listed components of the SL
machine;
[0037] FIG. 9B is another perspective view of the alternative embodiment
shown in FIG. 9A;
[0038] FIG. 9C is yet another perspective view of the alternative
embodiment shown in FIG. 9A;
[0039] FIG. 9D is still another perspective view of the alternative
embodiment shown in FIG. 9A; and
[0040] FIG. 10 is a perspective view of a preferred vat material
fill/remove system of the present invention.
DETAILED DESCRIPTION OF THE INVENTION
[0041] While the making and using of various embodiments of the present
invention are discussed in detail below, it should be appreciated that
the present invention provides many applicable inventive concepts that
can be embodied in a wide variety of specific contexts. The specific
embodiments discussed herein are merely illustrative of specific ways to
make and use the invention and do not delimit the scope of the invention.
[0042] A typical prior art SL machine 10, as illustrated in FIG. 1,
generally includes a UV laser beam 12, a liquid level sensing system 14,
optics 16 and controllable mirror system 18, a vertically movable
platform 20 and a resin retaining receptacle or vat 22. The vat 22 houses
a liquid photocurable polymer resin 24 and, generally, the SL machine 10
rasters a UV laser beam 12 across the resin through a series of optics 16
and a controllable mirror system 18. In most designs, the subject
three-dimensional (3D) part 26 is usually first attached to the platform
20 by building a base support structure 28 while the platform 20 is still
in its topmost position. The support structure 28 is usually made up of
fine filaments that support the subject part's 26 overhangs and are
manufactured simultaneously using the same resin 24. Prior art designs
typically incorporate a recoating device, recoating blade or other
sweeping device 29 that sweeps or horizontally translates across the
surface of the liquid after the platform 20 and subject part 26 have been
traversed downward a distance equal to the build layer thickness. Thus,
the recoating device 29 facilitates uniform liquid layers on the surface
of the subject part 26 and eliminates trapped gases or bubbles and/or
trapped volumes left on or underneath the platform 20 and/or the subject
part 26 both before and during the building process.
[0043] Referring still to the prior art SL machine 10 depicted in FIG. 1,
after the SL machine 10 rasters the UV laser beam 12 and completes a
given layer (which also includes waiting a sufficient time for the
reaction to finish after the laser beam has completed its scan), the
platform 20 is vertically traversed downward a distance equal to the
build layer thickness typically between by not limited to 2 and 6 mils or
optionally traversed downward a distance greater than the build layer
thickness in order to dip the subject part 26 into the resin 24 and fill
any internal part cavities. Once dipping the subject part 26 is
completed, if dipping is optionally performed, the platform 20 is then
traversed upward until the platform is located a distance equal to the
build layer thickness from the surface of the resin 24. The build layer
thickness usually depends on the type of build desired. Prior to
beginning a new reaction with the laser 12, a recoating device 29
typically traverses the liquid resin 24 surface as described previously,
and the SL machine 10 waits a prescribed amount of time for the liquid
resin to reach a state of equilibrium (so that essentially all waves and
any other movement of the liquid resin has stopped) prior to starting the
next layer. The process repeats as each layer is built. Complex-shaped
parts are thus manufactured by repeating the layering process. Once
complete, the subject part 26 is typically raised out of the liquid
polymer resin 24, the support structures 28 are removed and the subject
part 26 is cleaned and post-cured, usually in a UV oven (not shown).
However, it should be understood that support structures 28 may be
removed before, during, and/or after the cleaning and curing/drying
processes. Prior art SL machines 10, thus, limit building a subject part
26 to one material or, for example, a liquid photopolymer resin 24. What
is desired is an SL system that readily allows building 3D models from
different materials using the same apparatus and allows sweeping between
layers of multi-material 3D models.
[0044] FIG. 2 depicts a preferred working environment of a multi-material
SL machine 30 of the present invention. A computer 32 preferably controls
the multi-material SL machine 30. A UV laser beam 12 apparatus preferably
solidifies each slice of the model, thus the SL machine 30 builds a
subject part 26 layer by layer in a UV shielded SL cabinet or enclosure
34. Moreover, the SL machine 30 is capable of fabricating layers within
layers, thus facilitating more complex and intricate subject parts 26.
The preferred working environment may be customized to suit a user's
specifications. For example, the working environment may be fitted with
one or more SL cabinets 34 to accommodate certain building requirements.
The multi-material SL machine 30 of the present invention allows for a
multitude of working environment configurations for added user and design
flexibility.
[0045] A perspective view of a UV shielded SL cabinet 34 of a preferred
embodiment of the multi-material SL machine 30 of the present invention
is depicted in FIG. 3A. The UV shielded SL cabinet 34 features a movable
vat apparatus 36 that may be rotated about a vat apparatus axis 38, as
shown, or movable along a horizontal or transverse axis. It should be
understood that the vat apparatus 36 may be configured in one of several
alternative configurations to achieve the same functionality. (See, for
example, FIG. 4). Alternative embodiments for the multi-material SL
machine 30 of the present invention may include, for example, a single
vat system, a stacked vat system or a fixed vat system each capable of
accommodating intermediate washing and/or curing/drying of the subject
part 26, while maintaining a sterile environment. For example, when
building multi-material parts and/or devices, the SL machine 30 of the
present invention should eliminate contamination between materials and/or
resins. In the case of biomedical implants, the present invention further
facilitates a biocompatible environment. It should be understood that
intermediate washing, in most applications, is essential to eliminating
contamination and maintaining a sterile building environment, while
intermediate curing/drying may be an optional requirement to achieve the
same.
[0046] Still referring to FIG. 3A, the preferred movable vat apparatus 36
may rest on a moveable vat apparatus rotation mechanism 40 affixed to the
UV shielded (or otherwise shielded) SL cabinet 34, as shown, or similarly
anchored to the cabinet 34. The preferred movable vat apparatus 36
contains three vats 22, as shown, or may comprise any number of vats 22,
depending on the user's application or design criteria. The preferred vat
22, or resin retaining receptacle, of the present invention is designed
to be of a dimension suitable to accommodate the movable platform 20. The
movable platform 20, with the aid of one or more elevator mechanisms 42,
raises, lowers and/or vertically traverses the subject part 26 into, for
example, a vat 22 or a washing and curing/drying area 46 (as also shown
in FIG. 5). Thus, as the movable platform 20 positions the subject part
26 to the desired position about or in a given vat 22, the multi-material
SL machine 30 builds the subject part layer by layer or positions the
part to build a layer within a layer. In addition, sweeping or recoating
technologies known in the art and described earlier herein, as well as
other alternative sweeping technologies and/or strategies, may be
employed in accordance with the present invention. For example, in this
particular embodiment, a recoating device 29 is employed to facilitate
uniform liquid layers on the surface and eliminate trapped gases or
bubbles and/or trapped volumes left on or underneath the platform 20
and/or the subject part 26 both before and during the building process.
Thus, the multi-material SL machine 30 of the present invention provides
a system for sweeping between layers of multi-material 3D models.
[0047] The preferred movable platform 20 is generally affixed to the
elevator mechanism 42 by way of a mounting plate 44, a motorized rotation
unit 49 and a platform rotation mechanism 50 as seen in the side
perspective view of FIG. 3B and the angled perspective views of FIGS. 3C
and 3D. The mounting plate 44 is affixed to the elevator mechanism 42 in
such a manner allowing movement in a vertical manner along the length of
the elevator mechanism. Thus, the movable platform 20 may be manipulated
vertically as needed to customize building the subject part 26. The
mounting plate 44 is also affixed to the rotation unit 49. The rotation
unit 49 allows for controlled rotation of the movable platform 20 at any
angle. The platform rotation mechanism 50, in turn, controls the movable
platform 20 and aids in moving the platform as dictated by the rotation
unit 49. Thus, the movable platform 20 may also be manipulated at any
given angle to customize building the subject part 26 and/or clean, dry
and/or post-cure the subject part 26 and platform 20 in the washing and
curing/drying area 46. Accordingly, the multi-material SL machine 30 of
the present invention provides a movable platform 20 configured to allow
for controlled positioning about or in a given vat 22. For example, FIG.
3C illustrates the subject part 26 positioned inside the vat 22, while
FIG. 3D illustrates the subject part positioned outside of the vat. The
movable platform 20 may also be positioned to access any other desired
area of the multi-material SL machine 30 or of other SL machines or
cabinets 34 (shown in FIGS. 6A, 7A, 8A and 9A, as alternative examples).
[0048] As mentioned before, it should be understood that the movable vat
apparatus 36 may be configured in one of several different embodiments.
For example, FIG. 4 depicts an alternative embodiment of a movable vat
apparatus 36. The movable vat apparatus 36 rests on a movable vat
apparatus rotation mechanism 40 and is shown with three vats 22. The
number and design of each vat 22 is customizable according to a specific
application. For example, the vats 22 may be interchangeable and/or
altered in shape or size. Although there may be several other
embodiments, each vat 22, for example, may have a cross-sectional area of
approximately 5 inches by 5 inches and a depth of approximately 3 inches
and is located approximately 6 inches from the top of the movable vat
apparatus rotation mechanism 40. It should be understood, however, that
vats 22 may be configured in size and shape to suit particular
applications and design criteria.
[0049] The preferred movable vat apparatus 36, as shown in FIG. 4, is
capable of rotating about a vat apparatus axis 38. The movable vat
apparatus rotation mechanism 40 may be attached to an axis 38 that
provides rotational movement about an axis or an axis like structure.
Although, the axis support members 48, as shown, connect each individual
vat 22 to the vat apparatus axis 38, it should be understood that the
design of the axis support member 48 may be altered without affecting
functionality. In this particular embodiment, the vats 22 are preferably
located 90 degrees from one another circumferentially (or spaced
adequately apart if situated on a linearly movable structure). Again,
alternative embodiments for the multi-material SL machine 30 of the
present invention may include designs exhibiting a single vat system, a
stacked vat system or a fixed vat system in lieu of the movable vat
apparatus 36 and other design enhancements, as described later, for
example, in conjunction with the description accompanying FIGS. 6A-9D.
[0050] In accordance with the present invention, multi-material
manufacturing, or using more than one curable fluid medium 24 to build
both across and in-between layers, is accomplished by incorporating
intermediate wash, cure and dry cycles that maintain a sterile
environment whereby different media do not contaminate one another. FIG.
5 provides a simplified depiction of the preferred embodiment of the
movable platform 20, elevator mechanism 42, optional platform rotation
mechanism 50, curing/drying units 56 and washing unit 52 of the present
invention.
[0051] To change materials after building with a separate material, the
vats 22 are rotated out of the way so that the elevator mechanism 42 can
be traversed into the washing and curing/drying area 46. Once in the
washing and curing/drying area 46, the movable platform 22 and the
subject part 26, are washed using an appropriate solvent, usually
depending on the application. For example, most preferred applications
require an alcohol rinse. A solvent rinse jet or set of jets 54 deliver
the desired solvent to the subject part 26. Any waste from the washing
unit 52 remains contained within the washing and curing/drying area 46
for proper disposal.
[0052] Optionally, once the subject part 26 is cleaned, UV lamps or other
curing and/or drying devices 56 are used to cure and/or dry any residue
on the subject part. In accordance with the present invention, the
curing/drying device 56 may be selected from one or more of the
following: an ultraviolet light source, a particle bombarder, a chemical
sprayer, a radiation impinger, an ink jet, an oven, a fan, a pump or any
curing/drying device that incorporates convection, conduction and/or
radiation heat transfer and any combinations thereof. In addition, curing
may alternatively be accomplished through other wavelengths of excitation
allowing proper curing as well as other forms of synergistic stimulation
for a curable fluid medium, such as particle bombardment (electron beams
and the like), chemical reactions by spraying materials through a mask or
by ink jets or impinging radiation other than UV light.
[0053] The washing and/or curing/drying cycles may be repeated as required
by the desired design criteria. After the desired washing and/or
curing/drying procedures are complete, the moveable platform 20 is
returned to its initial position or the top of a defined build envelope
(a predetermined physical region encompassing the build space) and is
then ready for immersion in the next build material or curable fluid
medium 24 and/or placed in a location for part embedding or interaction
with an alternative additive and/or subtractive manufacturing technology.
After each layer or fraction of a layer is built, the entire subject part
26 is washed and optionally post-cured/dried. The parameters for the
amount of time required for post-curing/drying, if desired, depends on
the material and is potentially specific to the application with cure/dry
times varying from zero to finite amounts of time. Once the building
process is complete, the operator may need to sand, file or perform some
additional finishing process on the subject part 26 as well as apply a
paint, coating or some other material to the subject part in order to
provide a certain surface finish and surface appearance. The present
invention thus provides an integrated system that accommodates
intermediate multi-material SL manufacturing.
[0054] Now referring to FIG. 5, the optional platform rotation mechanism
50 facilitates angled functionality when necessary, such as angled
building, washing and/or curing/drying. The depiction on the far left in
FIG. 5 illustrates the movable platform 20 in an upright, straight
position. The depiction in the middle illustrates the movable platform 20
in an angled position, while the depiction on the far right illustrates
the movable platform in an inverted position. Thus, the optional platform
rotation mechanism 50 of the present invention provides a movable
platform 20 with a full range of angled functionality.
[0055] The SL machine 30 of the present invention may optionally
incorporate alternative manufacturing apparatuses 62 (as illustrated, for
example, in FIG. 6A) that further aid in the manufacturing of prototypes
and/or functional models. These alternative manufacturing apparatuses 62
may include additive and subtractive manufacturing technologies known in
the art as well as quality control and inspection technologies known in
the art including, for example, Computer Numerical Control (CNC) milling
apparatuses and tool carousels, Coordinate Measuring Machine (CMM) probes
and other vision measurement systems known in the art, Fused Deposition
Modeling (FDM), Selective Laser Sintering (SLS), Layered Object
Manufacturing (LOM) and other RP technologies known in the art,
micro-machining systems, micro-jet and other cutting systems such as
water jet, laser and plasma cutting systems known in the art, painting
apparatuses, ink jets and other fluid and particle dispensing mechanisms
and/or other pick and place technologies including robotic materials
placement technologies. Thus, SL machines 30 in accordance with the
present invention are versatile, multifunctional apparatuses that
accommodate complex, multi-material manufacturing.
[0056] As mentioned earlier, alternative embodiments for the
multi-material SL machine 30 of the present invention may include designs
exhibiting a single vat system, a stacked vat system or a fixed vat
system in lieu of the movable vat apparatus 36. An SL machine 30 in
accordance with the present invention may also include designs that
incorporate a horizontal traversing unit 58, as depicted for example in
FIG. 6A. The horizontal traversing unit 58 transports the subject part 26
from one area of the SL machine 30 to another or between different SL
cabinets 34. In order to further maintain the integrity of each area, the
SL machine 30 may optionally include, for example, shielded chamber walls
60 (identified but not completely shown) between each area.
[0057] As an example, FIG. 6A depicts an alternative embodiment of an SL
machine 30 in accordance with the present invention that may incorporate,
inter alia, two single vats 22, an enclosed stationary washing and
curing/drying area 46 (with various optional curing/drying units 56), a
movable platform 20, an elevator mechanism 42 with optional rotation
mechanism 50, an optional alternative manufacturing apparatus 62 and a
horizontal traversing unit 58 configured to access each of the
above-listed components of the multi-material SL machine 30. In this
embodiment, the SL machine 30 has the ability to horizontally traverse
the elevator mechanism 42 (and thus the platform 20) to different SL
cabinets 34 by using the horizontal translation mechanism 58. The SL
machine 30 therefore is capable of transporting the platform 20 between
the different vats 22, while maintaining the ability to accomplish
intermediate washing and/or curing/drying, as also depicted in another
perspective view in FIG. 6B. In addition, as described earlier, the SL
machine 30 of the present invention may incorporate an optional platform
rotation mechanism 50 to facilitate angled part building, washing, curing
and drying.
[0058] Still referring to FIGS. 6A and 6B, the washing and curing/drying
area 46 may optionally be contained with enclosure 64. A retractable
entrance 66 allows the elevator mechanism 42 and hence the platform 20 to
be fully enclosed within an enclosure 64, when desired. In order to
further maintain the integrity of each area, the multi-material SL
machine 30 may optionally include shielded chamber walls 60 between each
area (identified but not completely shown). It should be understood that
the number and types of vats 22, washing and curing/drying area 46,
horizontal translation mechanisms 58, alternative manufacturing
apparatuses 62 and other multi-material SL machine 30 elements may be
customized to suit any application and/or design criteria. Thus, the SL
machine 30 in this example maintains a sterile, non-contaminating
building environment, while facilitating an increased number of building
materials. Accordingly, the SL machine 30 depicted in FIGS. 6A and 6B
facilitates the manufacture of complex, multi-material prototypes and
functional models.
[0059] Referring now to FIGS. 7A and 7B, another embodiment of a
multi-material SL machine 30 in accordance with the present invention may
include, inter alia, with a single rotatable vat apparatus 36, a
stationary washing and curing/drying area 46 (with an optional
curing/drying unit--not shown), a movable platform 20, an elevator
mechanism 42 with an optional platform rotation mechanism 50, an optional
alternative manufacturing apparatus 62 and a horizontal traversing unit
58 configured to access each of the above-listed components of the SL
machine 30. In this embodiment, the multi-material SL machine 30 has the
ability to horizontally traverse the elevator mechanism 42 (and thus the
platform 20) between the different SL cabinets 34, by using the
horizontal translation mechanism 58. Thus, the SL machine 30 maintains
the ability to accomplish intermediate washing and curing/drying, if
desired. In addition, as described earlier, the SL machine 30 depicted in
FIGS. 7A and 7B, incorporates an optional platform rotation mechanism 50
to facilitate angled part building, washing, curing and drying.
[0060] As described earlier in the previous example, an alternative
embodiment of the multi-material SL machine 30 depicted in FIGS. 7A and
7B, may also optionally include shielded chamber walls 60 (identified but
not completely shown) between each area in order to further maintain the
integrity of each area. Alternatively, although not depicted in FIG. 7A
or 7B, the washing and curing/drying area 46 may be contained within an
enclosure (not shown) with a retractable entrance (not shown) allowing
the elevator mechanism 42 and hence the platform 20 to be fully contained
within enclosure, when desired. It should be understood that the number
and types of vat apparatuses 36, washing and curing/drying area 46,
horizontal translation mechanisms 58, alternative manufacturing
apparatuses 62 and other multi-material SL machine 30 elements may be
customized to suit any application and/or design criteria. Thus, the SL
machine 30 in this embodiment also maintains a sterile, non-contaminating
building environment, while facilitating an increased number of building
materials. Accordingly, the SL machine 30 depicted in FIGS. 7A and 7B
also facilitates the manufacture of complex, multi-material prototypes
and functional models and further incorporates SL systems known in the
art to accomplish multi-material stereolithography by separating the
machines with an intermediate wash, cure and dry chamber.
[0061] Now referring to FIGS. 8A and 8B, still another embodiment of a
multi-material SL machine 30 in accordance with the present invention,
may include, inter alia, two rotatable vat apparatuses 36 separated by an
enclosed stationary washing and curing/drying area 46, a movable platform
20, an elevator mechanism 42 with an optional platform rotation mechanism
50, an optional alternative manufacturing apparatus 62 and a horizontal
traversing unit 58 configured to access each of the above-listed
components of the SL machine. In this embodiment, the SL machine 30 has
the ability to horizontally traverse the elevator mechanism 42 (and thus
the platform 20) between vat apparatuses 36 and other processing areas
that are housed in different cabinets 34, by using the horizontal
translation mechanism 58. Thus, the multi-material SL machine 30
maintains the ability to accomplish intermediate washing and
curing/drying. In addition, as described earlier, the SL machine 30 of
the present invention may incorporate an optional platform rotation
mechanism 50 to facilitate angled part building, washing, curing and
drying.
[0062] Just as in the other embodiments, the multi-material SL machine 30
depicted in FIGS. 8A and 8B, may also optionally include shielded chamber
walls 60 (identified but not completely shown) between each area in order
to further maintain the integrity of each area. The washing and
curing/drying area 46 may be contained within an enclosure 64 equipped
with a retractable entrance 66 which allows the elevator mechanism 42 and
hence the platform 20 to be fully contained within the enclosure, when
desired. It should be understood that the number and types of vat
apparatuses 36, washing and curing/drying area 46, horizontal translation
mechanisms 58, alternative manufacturing apparatuses 62 and other
multi-material SL machine 30 elements may be customized to suit any
application and/or design criteria. Thus, the multi-material SL machine
30 in this embodiment also maintains a sterile, non-contaminating
building environment, while facilitating an increased number of building
materials. Accordingly, the SL machine 30 depicted in FIGS. 8A and 8B
also facilitates the manufacture of complex, multi-material prototypes
and functional models and accomplishes multi-material stereolithography
by separating the machines with an intermediate washing and curing/drying
area 46.
[0063] The multi-material SL machine 30 of the present invention may also
incorporate other traversing mechanisms that transport the platform 20
and subsequently the subject part 26 to different areas of the SL
machine. For example, the multi-material SL machine 30 may incorporate a
dual-sided elevator mechanism 64, as depicted, in FIGS. 9A, 9B and 9C
attached to an elevator mechanism rotation mechanism 66 thus transporting
platforms 20 to different areas of the SL machine 30. Thus, the
multi-material SL machine 30 has the ability to transport a subject part
26 from one area to another in a space saving and time efficient manner.
In this particular embodiment, two platforms 20 are utilized to increase
build efficiencies and reduce overall build times. It should be
understood, however, that the SL machine 30 may be designed with any
number of platforms 20.
[0064] For example, an SL machine 30 in accordance with the present
invention may incorporate, inter alia, a vat apparatus 36, a stationary
washing and curing/drying area 46 and a dual sided elevator mechanism 64
housed in a single SL cabinet 34, as depicted in FIG. 9A. In this
embodiment, the SL machine 30 has the ability to rotatably traverse the
elevator mechanism 42 (and thus platform 20) between vat apparatus 36 and
the washing and curing/drying area 46, thus maintaining the ability to
conduct intermediate washing and curing/drying, as also depicted in FIGS.
9B and 9C. Each platform 20 is optionally connected to an elevator
mechanism 42 with optional platform rotation mechanisms 50. In addition,
as described earlier, the SL machine 30 of the present invention may
incorporate an optional platform rotation mechanism 50 to facilitate
angled part building, washing, curing and drying. In order to further
maintain the integrity of each area, the SL machine 30 may optionally
include shielded chamber walls 60 (identified but not completely shown)
between each area.
[0065] It should be understood that the number and types of vat
apparatuses 36, washing and curing/drying area 46, dual sided elevator
mechanisms 64, alternative manufacturing apparatuses 62 and other SL
machine 30 elements may be customized to suit any application and/or
design criteria, including building more complex apparatuses optionally
configured with horizontally traversing mechanisms 58 (not shown). Thus,
the multi-material SL machine 30 in this embodiment also maintains a
sterile building environment, while facilitating an increased number of
building materials and multiple methods of manufacturing. Accordingly,
the multi-material SL machine 30 depicted in FIGS. 9A-9D facilitates the
customizable manufacture of complex, multi-material prototypes and
functional models.
[0066] Just as in other embodiments, the multi-material SL machine 30
depicted in FIGS. 9A-9D may also optionally include shielded chamber
walls 60 (identified but not completely shown) between each area in order
to further maintain the integrity of each area. The washing and
curing/drying area 46 may be contained within an enclosure 64 equipped
with a retractable entrance 66 which allows the dual sided elevator
mechanism 68 and hence the platform 20 to be fully contained within the
enclosure, when desired. The dual sided elevator mechanism 68 is adapted
to rotate about a vertical axis, as illustrated, Thus, the dual sided
elevator mechanism 68 allows, for example, a platform to be traversed
from one side of the dual sided mechanism to the other side. It should be
understood that the number and types of vat apparatuses 36, washing and
curing/drying area 46, dual sided elevator mechanisms 68, alternative
manufacturing apparatuses 62 and other multi-material SL machine 30
elements may be customized to suit any application and/or design
criteria. Thus, the multi-material SL machine 30 in this embodiment also
maintains a sterile, non-contaminating building environment, while
facilitating an increased number of building materials. Accordingly, the
multi-material SL machine 30 depicted in FIGS. 9A-9D also facilitates the
manufacture of complex, multi-material prototypes and functional models
and further incorporates SL systems known in the art to accomplish
multi-material stereolithography by separating the machines with an
intermediate washing and curing/drying area 46.
[0067] As described earlier, as each layer is built, the subject part 26
can be raised and/or lowered into a curable fluid medium 24 contained in
the vat 22. It is not only important to control the height of the subject
part 26, but also to control the level of curable fluid medium 24 in each
vat 22. The present invention may utilize any one of a number of methods
known in the art for vat fill and liquid level control in each vat 22.
The preferred embodiment incorporates a vat material fill/remove system
70 (as depicted in FIG. 10) or other pumps or pump systems known in the
art to fill and/or remove fluid media 24 from the vats 22. The pump 51
preferably allows isolation of the curable fluid medium 24 from the
moving parts of the vat apparatus 36 and provides a means for
mechanically adding and removing precise quantities of fluid from/to a
vat 22.
[0068] For example, in a preferred embodiment depicted in FIG. 10, each
vat 22 may incorporate a vat material fill/remove system 70. A preferred
vat material fill/remove system 70 maintains a constant liquid level
within an associated vat 22 by continuously pumping liquid into the vat
through a pump 51. A vat material fill/remove system 70 utilizes, for
example, a peristaltic pump 51 that isolates the fluid media 24 from
mechanical pump parts. Using the preferred vat material fill/remove
system 70, precise liquid levels can be controlled, without using the
overfill drain vat chamber 74 (as described later herein), by filling and
removing precise amounts of fluid media 24 by using only a pump known in
the art. The preferred controlled delivery amount and preferred vat 22
cross-section described earlier herein may yield a minimum build layer
thickness of, but not limited to, approximately 0.5 mil.
[0069] In accordance with the preferred embodiment of a vat material
fill/remove system 70 depicted in FIG. 10, each vat 22 is configured to
comprise at least two fluid media retaining chambers, the main vat
chamber 72 and an overfill vat chamber 74. The main vat chamber 72 is
configured such that a platform 20 (not shown in FIG. 10) of a given
multi-material SL machine 30 fits within it. The volume of the main vat
chamber 72 may be adjusted by repositioning a leveling gate 76.
Preferably, the leveling gate 76 may be repositioned by traversing the
leveling gate in a vertical manner. It should be understood, however,
that the leveling gate 76 may be traversed in any direction such as to
alter the volume of the main vat chamber 72 after repositioning.
[0070] A peristaltic pump (or any pump known in the art) 51 supplies and
removes fluid media 24 (not shown) from the main vat chamber 72 in a
controlled manner via a bidirectional main building area supply tube 78.
Thus, the vat material fill/remove system 70 maintains constant levels of
fluid media 24 within the main vat chamber 72. It should be understood,
however, that the pump system 51 can also be utilized to precisely
control the liquid level within the vat system by filling/removing
precise amounts of fluid from the vat 22. Thus, optionally eliminating
the need for the overfill drain chamber 74. It should also be further
understood that liquid level sensing systems such as the laser level
sensing system 14 currently employed in SL systems known in the art can
also be employed here (as later described herein).
[0071] When employed, the optional overfill vat chamber 74 is adjacent to
the main vat chamber 72 and collects fluid media 24 from the main vat
chamber, when fluid media levels are in excess of the height of the
leveling gate 76. As fluid media 24 collects in the overfill vat chamber
74, the fluid media is transported to the material reservoir 80 (via a
unidirectional overfill tube 82) for recycling. The material reservoir
80, in turn, supplies the peristaltic pump 51 and vice versa, via a
bidirectional reservoir tube 84. The vat material fill/remove system 70
in accordance with the multi-material SL machine 30 of the present
invention, thus maintains, for example, a constant level of fluid media
24 in the main vat chamber 72, prevents fluid media 24 overflow from the
main vat chamber and aids in conserving fluid media. The vat material
fill/remove system 70, thus, fosters a sterilized system and easily
increases multi-material capability.
[0072] There are several alternative liquid level sensing systems that may
be employed to sustain an appropriate liquid level in each vat 22. Laser
level sensing systems 14 known in the art, for example, may be utilized
for liquid level sensing. Alternatively, various other level sensing
systems may be utilized for platform 20 level sensing. Various level
sensing and/or contact or non-contact displacement measurement systems
such as eddy current displacement systems, confocal chromatic
displacement measurement systems, lineal variable displacement
transducers, proximity switches and others known in the art could be
employed individually or in combination to provide accurate displacement
measurements of the liquid level and/or the platform 20. Such level
sensing systems will help improve build tolerances. The pump or pump
system 51 described earlier herein could be incorporated with the level
sensing system to precisely control the liquid level (or the platform 20
level), as required. It can be appreciated that any or all of these
alternative approaches may be combined for a particular application or
for use in customized systems.
[0073] The present invention accordingly provides for SL processing to
form multi-material parts. The materials may be rigid, semi-rigid, liquid
(may be encapsulated liquid) or gas (trapped gases). There are numerous
examples of curable fluid media 24 suitable for use with the present
invention. Examples of curable fluid media 24 or materials that may be
incorporated in curable fluid media 24 include SL resins known in the
art, hydrogels, bioactive ingredients, cells, imbedded devices or
materials, photopolymer resins and powdered materials. Some types of
powdered materials may be converted from a fluid-like medium to a
cohesive cross-section by processes, such as melting and solidification.
[0074] Hydrogels are examples of a curable fluid medium and may be, for
example, a natural polymer, synthetic polymer or some combination
thereof. Natural polymer hydrogels include polymers such as anionic
polymers (for example, hyaluronic acid, alginic acid, pectin,
carrageenan, chondroitin sulfate, dextran sulfate), cationic polymers
(for example, chitosan and polylysine), amphipathic polymers (such as
collagen, gelatin, carboxymethyl chitin and fibrin) and neutral polymers
(for example, dextran, agarose and pullulan) and their derivatives.
[0075] Synthetic polymer hydrogels, on the other hand, include, for
example, polymers such as polyesters: poly(ethylene glycol)-poly(lactic
acid)-poly(ethylene glycol); poly(ethylene
glycol)-poly(lactic-co-glycolic acid)-poly(ethylene glycol);
poly(ethylene glycol)-polycaprolactone-poly(ethylene glycol); poly(lactic
acid)-poly(ethylene glycol)-poly(lactic acid); poly(hydroxyl butyrate);
poly(propylene fumerate-co-ethylene glycol).+-.acrylate end groups; and
poly(poly(ethylene glycol)/poly(butylene oxide)terephthalate).
[0076] Synthetic polymer hydrogels may include, for example, other
polymers such as: poly(ethylene glycol)-bis-(poly(lactic acid)-acrylate);
poly(ethylene glycol).+-.cyclodextrins; poly(ethylene
glycol)-g-poly(acrylamide-co-Vamine); polyacrylamide; poly(N-isopropyl
acrylamide-co-acrylic acid); poly(N-isopropyl acrylamide-co-ethyl
methacrylate); poly(vinyl acetate)/poly(vinyl alcohol); poly(N-vinyl
pyrrolidone); poly(methyl methacrylate-co-hydroxyethyl methacrylate);
poly(acrylonitrile-co-allyl sulfonate);
poly(biscarboxy-phenoxy-phosphazene); and poly(glucosylethyl
methacrylate-sulfate).
[0077] Combinations of natural and synthetic polymer hydrogels may include
polymers such as poly(polyethylene glycol-co-peptides), alginate
g-(polyethylene oxide-polypropylene oxide-polyethylene oxide),
poly(polylactic-co-glycolic acid-co-serine), collagen-acrylate,
alginate-acrylate, poly(hydroxyethly methacyrlate-g-peptide),
poly(hydroxyethyl methacyrlate/Matrigel.RTM.) and hyraluronic
acid-g-N-isopropyl acrylamide).
[0078] Yet other examples of curable fluid media 24 include, for example:
(1) radically polyinerizable organic compounds (such as urethane,
(meth)acrylate, oligester (meth)acrylate, epoxy (meth)acrylate, thiol
compound, ene compound and photosensitive polyimide); (2) cationically
polymerizable organic compounds (such as an epoxy compound, cyclic ether
compound, cyclic lactone compound, cyclic acetal compound, clycle
thioesther compound, spiro orthoester compound and vinyl ether compound);
(3) radically polymerizable organic compound and a catonically
polymerizable organic compound; and (4) radically polymerizable organic
compound (an ethylenically unsaturated monomer), a polyether, polyol
compound and elastomer particles.
[0079] Moreover, also in accordance with the present invention,
multi-colored manufacturing is accomplished by mixing pigments, paints,
dyes and/or other color media into the curable fluid medium 24, thereby
facilitating the manufacture of multi-colored prototypes and models.
Similarly, other materials may, optionally, be mixed into the fluid
medium 24 to alter the strength, thermal, mechanical, optical,
electrical, functional and/or biofunctional properties thereby
facilitating the manufacture of multi-functional, multi-material,
multi-colored, multi-element and/or implantable prototypes, models and
finished products. The present invention thus facilitates using SL
technology to aid in manufacturing of parts in an endless number of
materials and colors. The present invention also facilitates manipulating
certain materials to exhibit altered properties at select locations
during the building stage.
[0080] Although preferred embodiments of the present invention have been
described in detail, it will be understood by those skilled in the art
that various modifications can be made therein without departing from the
spirit and scope of the invention as set forth in the appended claims.
* * * * *
