The concept of additive manufacturing involves solidifying a build material according to a data specifying an object to be formed. In some additive manufacturing systems, the build material is in the form of a powder or liquid and is solidified layer-by-layer to build up the desired object. In powder-based systems, the powder may be heated to a preliminary temperature, selectively treated with a fusing agent based on a cross-section of the object being formed and irradiated to solidify or fuse the build material where the fusing agent was deposited.
The accompanying drawings illustrate various implementations of the principles described herein and are a part of the specification. The illustrated implementations are merely examples and do not limit the scope of the claims.
Throughout the drawings, identical reference numbers designate similar, but not necessarily identical, elements.
As noted above, the concept of additive manufacturing involves solidifying a build material according to a data specifying an object to be formed. In powder-based systems, the powder may be initially pre-heated to a preliminary temperature, selectively treated with a fusing agent (FA) based on a cross-section of the object being formed and irradiated to solidify or fuse the build material where the fusing agent was deposited. After each layer or cross-section of the object has been formed, the excess, unsolidified build material is removed from around the object and recycled.
A variety of different materials can be used as the powdered build material, including plastics or polymers, ceramics and metals. Similarly, a variety of different fusing agents having different characteristics can be selected and used. Different build materials, fusing agents and build material/fusing agent combinations or sets will give the finished object different properties. For example, one material set might result in a structurally stronger object than other materials. A different material set may give more accuracy in fine details or a smoother finish in the finished object.
Thus, the user may want to select a different build material and/or fusing agent depending on what properties are most important in the finished object. However, different build materials and fusing agents may optimally need different parameters in the additive manufacturing system or method that are not readily adjusted in existing platforms. For example, the optimal build material or fusing agent may respond most effectively to a particular band of wavelengths that is different from the wavelengths an additive manufacturing system uses. Additionally, some build materials may be degraded by exposure to some doses of radiation that an additive manufacturing system uses for or is configured to use for a different build material. For these and other reasons, the user may want to control the wavelengths applied by the additive manufacturing system to optimally preheat the build material, fuse the fusing agent or avoid degradation to the build material.
Consequently, the present specification describes, for example, an additive manufacturing device that includes a build platform for supporting successive, stacked layers of an object being formed; a spreader for spreading successive layers of build material on the build platform; a liquid dispenser for selectively dispensing a liquid fusing agent into an uppermost layer of build material in a pattern corresponding to a layer of the object being formed; a carriage for moving the liquid dispenser over the build platform; a first irradiation source having a first wavelength band, the first wavelength band being tuned for absorption by the fusing agent; and a second irradiation source having a second wavelength band disposed above the build platform for heating the successive layers of build material on the build platform. In various examples, the first irradiation source may be on the carriage while the second irradiation source is stationary above the build platform. In other examples, both radiation sources may be stationary above the build platform or both on the carriage above and moving over the build platform. In this system, the first wavelength band does not overlap the second wavelength band. Additionally, in some examples, the second wavelength band has shorter wavelengths or is narrower than the first wavelength band.
This illustrative additive manufacturing device may further include a first plurality of irradiation modules, each module comprising an irradiation source. The carriage includes a socket to receive any of the first plurality of irradiation modules as the first irradiation source. In this example, each of the first plurality of irradiation modules has a wavelength band tuned to a different fusing agent. In some examples, each of the first plurality of irradiation modules comprises a Light Emitting Diode (LED) radiation source.
The additive manufacturing device of this example may further include a second plurality of irradiation modules. In this case, the second irradiation source comprises a socket to receive any of the second plurality of irradiation modules. Each of the second plurality of irradiation modules has a wavelength band tuned to a different build material.
In another example, the present specification describes an additive manufacturing method that includes: selecting one of a plurality of irradiation modules based on a selected module having a wavelength band tuned for absorption by a fusing agent to be used to form an object by additive manufacture; plugging the selected module into a socket over the build platform; supporting successive, stacked layers of the object being formed on the build platform; using a liquid dispenser mounted on the carriage, selectively dispensing the fusing agent into an uppermost layer of build material in a pattern corresponding to a layer of the object being formed; and fusing the build material by exposing the fusing agent to a first wavelength band from a first irradiation source in the selected module.
In still another example, the present specification describes an additive manufacturing device that includes a build platform for supporting successive, stacked layers of an object being formed; a spreader for spreading successive layers of build material on the build platform; a liquid dispenser for selectively dispensing a liquid fusing agent into an uppermost layer of build material in a pattern corresponding to a layer of the object being formed; a plurality of irradiation modules each comprising a radiation source with a wavelength band tuned for absorption by a different fusing agent; a carriage for moving the liquid dispenser over the build platform, wherein the carriage comprises a socket to receive any of the plurality of irradiation modules as a first irradiation source; and a second irradiation source disposed above the build platform for heating the successive layers of build material on the build platform.
As shown in
A liquid dispenser 106 is arranged for selectively dispensing a liquid fusing agent into an uppermost layer of build material in a pattern corresponding to a layer of the object being formed. A carriage 108 moves the liquid dispenser 106 over the build platform 102. As the carriage 108 reciprocates back and forth over the build platform 102, the liquid dispenser 106 is able to dispense fusing agent in any pattern on the uppermost layer of build material that corresponds to a cross-section of the object being formed for that layer of build material.
A first irradiation source 110 having a first wavelength band may be disposed on the carriage 108. This irradiation source 110 is operated to irradiate the layer of build material as treated with the fusing agent. The radiation from the irradiation source 110 causes the fusing agent to coalesce or solidify the build material into which the fusing agent has been applied. This may be because the fusing agent absorbs the radiation and generates heat that fuses the treated build material. In other examples. The radiation may trigger a chemical reaction between the fusing agent and the build material to coalesce or fuse the build material. In any case, the first wavelength band is tuned for absorption by the fusing agent.
A second irradiation source 112 having a second wavelength band may be disposed above the build platform 102 for heating the successive layers of build material on the build platform 102. This radiation source 112 is used for generally heating, usually pre-heating, each layer of build material to an optimal temperature for application of the fusing agent from the liquid dispenser 106. Thus, the second irradiation source 112 may be stationary and arranged in a position so as to heat the entire build platform 102.
In this example, the first wavelength band does not overlap the second wavelength band. Additionally, in some examples, the second wavelength band may have shorter wavelengths or be narrower than the first wavelength band. In other examples, the second wavelength band may have longer wavelengths or be broader than the first wavelength band
As shown in
The method next includes plugging 224 the selected module into a socket over a build platform. For example, the module may be configured with prongs and is received by interference fit in a socket of the carriage without needing tools for installation. The module may be latched or otherwise secured to the carriage and will receive power from the carriage to emit the radiation for which it is designed. In some examples, the radiation modules will each include Light Emitting Diodes (LEDs) as a radiation source. The emitted radiation may be in different portions of the electromagnetic spectrum as is best tuned for absorption by a corresponding fusing agent. In some examples, the socket is in the carriage. The first irradiation source may thus be in the carriage and move relative to the build platform. In some examples, the socket is positioned over the build platform in a static location relative to the build platform.
After installation of the selected module, the method 200 includes supporting 226 successive, stacked layers of the object being formed on the build platform and, using a liquid dispenser mounted on the carriage, selectively dispensing 228 the fusing agent into an uppermost layer of build material in a pattern corresponding to a layer of the object being formed, as described above. The method 200 then concludes with fusing 230 the build material by exposing the fusing agent to a first wavelength band from a first irradiation source in the selected module. In this way, the desired object is formed layer-by-layer, as described above.
As shown in
The method 300 also includes selecting 332 an irradiation module from a set of modules based on what build material is being used. In the specific example of
Next, in
The method 300 concludes with heating 336 the build material with the second selected irradiation module. Each irradiation module contains an irradiation source that will, when powered, emit radiation over a particular wavelength band. Thus, the second selected irradiation module is selected to emit a wavelength band that will be particularly effective or tuned to heating the build material being used. This will typically be a pre-heating cycle in which the build material of the uppermost layer on the build platform is heated prior to distributing fusing agent selectively in that build material layer.
Like
As shown in
A liquid dispenser 106 is arranged for selectively dispensing a liquid fusing agent into an uppermost layer of build material in a pattern corresponding to a layer of the object being formed. A carriage 108 moves the liquid dispenser 106 over the build platform 102.
A first irradiation source 110 having a first wavelength band is also disposed on the carriage 108. This irradiation source 110 is operated to irradiate the layer of build material as treated with the fusing agent. A second irradiation source 112 having a second wavelength band is disposed above the build platform 102 for heating the successive layers of build material on the build platform 102.
As shown in
Additionally, the device 500 of
Any of the set of modules 550 can be selected and plugged into a socket of the irradiation source 112, as described above. Each of the irradiation modules in the set 550 includes a radiation source that emits a different wavelength band in the electromagnetic spectrum. As discussed above with regard to
With the ability to change out the irradiation module in the second irradiation source 112, a variety of different build materials can be used. As the build material being used changes, the selected module 542 is changed and installed to match the build material and effectively heat the build material to an optimal temperature to receive the fusing agent. In some examples, the build material includes a fusing agent mixed into the build material. This allows build materials to have additional absorption in a desired radiation band.
In some of the subsequent figures, filled areas under the emission curves exemplify approximate energy absorbed by the polymer build material powder and the respective fusing agent. These curves are used to estimate selectivity defined as the ratio of areas defined by the absorption curves and the respective emission curves. Change of the irradiation flux (dimmer or brighter irradiation) and change of the fusing agent concentration may impact these values. In addition, in the areas where fusing agent is present, both the absorption of fusing and of the polymer powder needs to be accounted separately.
The selectivity can be increased by separating powder heating done with an overhead tungsten-halogen lamp (3000K) lamp from the powder melting accomplished with a shorter wavelength narrow-band source mounted on the carriage and emitting in the range where polymer powder's absorption is minimal (approximate range between 600 nm and 340 nm to 500 nm depending on the selected polymer).
Further gains can be achieved when using fusing agent specifically matching the narrow-band emission. Use of visible mono-color irradiation source may produce colored parts, as shown in
Choice of narrow band irradiation source and the corresponding FA may also depend on the printed polymer. For example, violet and near UV narrow-band fusing sources cannot be used when printing Thermoplastic Polyurethane (TPU) or titanium dioxide doped PA12 (PA12/TiO2) due to excessive powder absorption in this range (
Accordingly,
In one option, if the powder UV absorption is too weak an additional low-density FA matching the power heating narrow-band source may be applied to the regions remaining unfused, as shown in
In case when a broad IR emitting source (QTH) is employed heating rate of the powder can be increased by dry blending appropriate IR absorbing additive or selective printing IR absorbing ink like, for example, carbon black. Table 2 shows examples of dry blended commercial IR absorbers.
Described examples demonstrate multiple choices available when powder heating (with an overhead lamp) is separated from powder fusing (primarily with a lamp mounted on the moveable carriage). Full advantage of this solution becomes available when the described lamps are standardized in the form of easily replaceable modules, described above.
Fortunately, the LEDs arrays described can be easily packaged into thin, rectangular shapes matching space allowed for presently used MJF printer lamps. In addition, the proposed arrays emitting at different wavelength can be powered with the same low voltage power supply making switching between different modules simple.
In one example, the LED array includes two types of LEDs having different wavelengths. The two types of LEDs may be arranged in a checkerboard pattern in the LED array. In some examples, the second irradiation source and the first irradiation source are both housed in a selected module. The first irradiation source and second irradiation source may be two separate arrays or a single integrated array having LEDs of both frequencies. An integrated array may provide uniformity advantages over two separate arrays. Using two separate arrays in a single module may allow the arrays to be individually replaced. Accordingly, there are advantages to both approaches.
Thus, the proposed printer design can be easily reconfigured when changing printed polymer material by simply unplugging and removing radiation modules and replacing them with the modules matching printing requirement of the new polymer material (plus loading the appropriate fusing agents). It is also possible that a similar advantage can be realized when switching between different printed objects made of the same material. For example, one could consider the case of a high-volume production when all objects within print run are the same. Objects printed within the first run may not require high selectivity, but cost would need to be low, while objects printed in the second run may have details where high selectivity is needed, and cost is of lesser concern. This requirement may be addressed by selecting radiation sources and corresponding FAs appropriately satisfying needs of each runs and quickly switching them after the first run is completed.
Fusing experiments using UV sources and respective narrow-band fusing agents has shown that irradiation flux of about 5 W/cm 2 to 15 W/cm 2 lasting less than a second is sufficient to achieve complete melting of all presently considered polymers (PA12, PA12+additives, PA11, TPA=polyamide thermoplastic elastomer, TPU, PP). LEDs arrays (mostly GaN-based devices emitting wavelengths below 580 nm) are capable of satisfying and/or exceeding the needed radiation intensity.
The irradiation source 110 includes an irradiation module 442 that is one of a set 440 of multiple irradiation modules. Any of the set of modules 440 can be selected and plugged into a socket. Each of the irradiation modules in the set 440 includes a radiation source that emits a different wavelength band in the electromagnetic spectrum. As discussed above with regard to
The second irradiation source 112 similarly includes multiple modules in a set of modules 550. The second irradiation source may be selected from the set of modules 550 and installed above the build platform 102. The second irradiation source 112 provides heating of the build material. As discussed above, this heating may be augmented by inclusion of a fusing agent, either mixed in the build material or applied to the build material using the liquid dispenser 106. The second irradiation source 112 is selected from the set of modules 550 based on the build material and associated fusing agent, if any, used for heating the build material. In this example, there is no irradiation source 110112 on the carriage 108.
The preceding description has been presented only to illustrate and describe examples of the principles described. This description is not intended to be exhaustive or to limit these principles to any precise form disclosed. Many modifications and variations are possible in light of the above teaching.
Filing Document | Filing Date | Country | Kind |
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PCT/US2020/055967 | 10/16/2020 | WO |