阅读说明：本技术 分层构建对象的方法及用于执行此类方法的3d打印装置 (Method for hierarchically building objects and 3D printing device for performing such a method ) 是由 安德烈亚斯·J·伯姆 马尔特·科滕 于 2019-07-17 设计创作，主要内容包括：本发明公开了一种在3D打印装置上由至少第一可光硬化树脂和第二可光硬化树脂分层构建对象的方法,以及被构造成执行此类方法的3D打印装置。该3D打印装置具有：构架平台,在该构建平台上能够构建对象；透光性载体,该透光性载体包括多个凹陷部；以及光投影仪,该光投影仪用于穿过载体投影光图案。方法具有以下步骤：(a)部分地构建对象,从而提供处理中对象；(b)用第一可光硬化树脂的第一坯料层涂覆载体的第一表面区域；(c)移动载体,从而将第一坯料层定位在构建平台与光投影仪之间；(d)使处理中对象与第一坯料层接触；(e)用光图案照射第一坯料层,从而用硬化层增补处理中对象；以及(f)将所增补的处理中对象与载体分离。(A method of layerwise building an object from at least a first and a second photocurable resin on a 3D printing device, and a 3D printing device configured to perform such a method. The 3D printing device has: a framework platform on which objects can be built; a light-transmissive carrier including a plurality of recessed portions; and a light projector for projecting the light pattern through the support. The method comprises the following steps: (a) partially building the object, thereby providing an in-process object; (b) coating a first surface region of a carrier with a first green layer of a first photohardenable resin; (c) moving the carrier to position the first layer of billet material between the build platform and the light projector; (d) contacting the subject under treatment with the first green sheet layer; (e) irradiating the first green layer with a light pattern to supplement the object under treatment with a hardened layer; and (f) separating the supplemented in-process object from the carrier.)

1. A method of layerwise building an object, preferably a dental restoration or a dental restoration component, from at least a first and a second light hardenable resin on a 3D printing device, the 3D printing device comprising a build platform on which the object can be built, a light transmissive carrier comprising a plurality of recesses, and a light projector arranged for projecting a light pattern through the carrier towards the build platform, the method comprising the steps of:

(a) partially constructing the object, thereby providing an in-process object;

(b) coating a first surface region of the carrier with a first layer of the first photocurable resin;

(c) positioning the first layer of billet material between the build platform and the light projector;

(d) advancing the build platform toward the carrier, thereby contacting the in-process object with the first billet layer;

(e) irradiating the first green layer with a light pattern to harden the portion irradiated with the pattern, thereby supplementing the object under treatment with a hardened layer; and

(f) retracting the build platform from the carrier, thereby detaching the supplemented in-process object from the carrier.

2. The method of claim 1, further comprising the steps of:

(g) coating a second surface region of the carrier with a second green layer of the second photocurable resin;

(h) positioning the second layer of billet material between the build platform and the light projector;

(i) advancing the build platform toward the carrier, thereby contacting the in-process object with the second green layer;

(j) irradiating the second green layer with a light pattern to harden the portion irradiated by the pattern, thereby supplementing the in-process object with an additional hardened layer; and

(k) retracting the build platform from the carrier, thereby detaching the supplemented in-process object from the carrier.

3. The method of claim 1 or 2, wherein steps (b) and (g) are performed overlapping in time.

4. The method of claim 3, wherein steps (c) - (f) are performed prior to steps (h) - (k).

5. A method according to any one of claims 2 to 4, wherein in steps (d) and (i), the in-process object is positioned relative to the carrier so as to provide a distance between the in-process object and the carrier, wherein the first and second green layers each have a thickness corresponding to the distance.

6. The method according to any one of the preceding claims, further comprising the step of: the carrier is supplied from a feed reel and discharged onto a discharge reel.

7. The method according to any one of the preceding claims, wherein a residual part of the first green layer is formed as a result of separating the supplemented in-process object from the carrier, wherein the method further comprises the following steps: irradiating the residual portion of the first green layer with light to harden the residual portion; and disposing of the hardened residual portion of the first green layer.

8. A 3D printing device for layerwise building up an object, preferably a dental restoration or a dental restoration component, from at least a first and a second photo-hardenable resin, the 3D printing device comprising: a build platform on which the object can be built; a light-transmissive carrier including a plurality of recesses; and a light projector arranged to project a light pattern through the carrier in a direction along a build axis towards the build platform; a first dispenser for coating a first surface region of the carrier with a first layer of the first photocurable resin, wherein the build platform is movable along the build axis, and wherein the carrier is movable transverse to the build axis.

9. The 3D printing device according to claim 8, the 3D printing device being configured to move the build platform and the carrier to a position determined by a computer control.

10. The 3D printing apparatus according to claim 8 or 9, the 3D printing apparatus comprising a second dispenser for coating a second surface region of the carrier with a second layer of the second photocurable resin.

11. The 3D printing device according to any of claims 8 to 10, wherein the light forming the light pattern has a wavelength suitable for hardening the first photo-hardenable resin.

12. The 3D printing device according to claim 11, wherein the wavelength is in a range of 330nm to 450 nm.

13. The 3D printing device according to any of claims 8 to 12, the 3D printing device comprising a feeding spool for providing the carrier and a discharging spool for discharging the carrier.

14. The 3D printing device according to any of claims 8 to 12, wherein the carrier is formed by an endless belt.

15. The 3D printing device according to any of claims 8 to 14, the 3D printing device being based on a stereoscopic illumination type technique.

Technical Field

The present invention relates to a method of layerwise building up an object from a first photocurable resin and optionally a second photocurable resin on a 3D printing device. The invention also relates to a 3D printing apparatus configured to perform such a method. In particular, the present invention relates to a method in which a layer of one or more unhardened photocurable resins is applied to a carrier in the form of a blank layer, which is subsequently positioned between a build platform and a light projector for partially hardening it.

Background

In various technical fields, physical objects or mechanical workpieces are increasingly manufactured by additive manufacturing processes.

Such additive manufacturing processes typically allow an object to be built up in a desired individual shape of the object, by successively adding material to form the shape. Although additive manufacturing processes are widely used in the rapid prototyping industry, the manufacture of end products in many areas remains challenging. Particularly for making dental restorations, it is generally necessary to use materials that are compatible with use in the human body. In addition, dental restorations manufactured by additive manufacturing must exhibit the required mechanical stability and must meet aesthetic expectations, for example relating to chromatic aberration and translucency.

Some additive manufacturing processes are based on hardening photohardenable resins in layers. Photohardenable resins are typically photopolymerizable and harden locally due to exposure to light. A desired three-dimensional object can be constructed by successively adding layers of shapes controlled according to the desired external shape of the object. The object to be constructed is typically prepared by Computer Aided Design (CAD) and provided in the form of a three-dimensional computer model. The computer model of the object is actually cut into layers, each layer having a particular shape generated from the external shape of the object. The shape of such layers is determined by exposing such layers to a light pattern corresponding to the shape of the respective slice.

In many cases, manufacturing is focused on providing objects in a desired shape. Although there are also applications where objects are provided in a desired color, there is still a need for a method and apparatus that allows for the preparation of objects having multiple colors or color gradations. In particular, there remains a need to provide dental restorations by additive manufacturing with a color gradient similar to natural teeth.

WO 2012/053895 a1(DSM) describes an additive manufacturing apparatus comprising a movable foil guiding stage having a contact face, and comprising a pair of upper and lower foil guiding elements on opposite sides of the contact face, the lower foil guiding element defining a foil height position away from the contact face to contact a tangible object by moving the foil guiding stage along the tangible object while keeping the foil stationary relative to the object to guide a foil comprising a layer of liquid to or from the contact face. The energy source is arranged for at least partially solidifying at least a part of the intersecting pattern in the liquid layer arranged on the foil and in contact with the tangible object.

US 2008/0206383 a1(Hull et al) is directed to a solid imaging apparatus and method of use that reduces the amount of uncured solid imaging build material that remains on an intact build object after the solid imaging build process is completed. The amount of uncured build material is reduced by using an uncoated web that removes excess build material from the build object during the build process or a build material ink supply that uses only as much build material as is needed for the manufacture of the build portion.

Disclosure of Invention

The invention relates to a method of layerwise building up an object from at least a first photocurable resin on a 3D printing device. In particular, the invention may relate to a method of layerwise building up an object on a 3D printing device from a first and a second photocurable resin and optionally from a further photocurable resin. The first photocurable resin, the second photocurable resin, and/or the additional photocurable resin may be generally referred to herein as a "photocurable resin".

The 3D printing apparatus comprises a build platform on which the object can be built, a light transmissive carrier and a light projector arranged to project a light pattern through the carrier towards the build platform. The carrier includes a plurality of recesses for receiving the photohardenable resin.

The method comprises the following steps:

(a) partially building the object, thereby providing an in-process object;

(b) coating a first surface region of the carrier with a (preferably contiguous) first layer of a first photocurable resin (composed of it);

(c) positioning a first layer of billet material between a build platform and a light projector;

(d) advancing the build platform toward the carrier, thereby contacting the in-process object with the first green layer;

(e) irradiating the first green layer with a light pattern to harden the pattern-irradiated portion, thereby supplementing the object under treatment with a hardened layer; and

(f) the build platform is retracted from the carrier, thereby separating the supplemented in-process object from the carrier.

The term "part" in step (e) covers one part. Thus, the term "portion" means "one or more portions".

The invention is advantageous because it allows the object to be prepared from layers of different resins. In particular, the invention allows for the preparation of objects having a color and/or translucency gradient. The present invention is also advantageous in that it helps to maximize the throughput of the 3D printing device by preparation of the release layer and hardening of the layer used to build the object.

The presence of the recesses for receiving the photohardenable resin simplifies the coating process. The risk of possible cross-contamination can also be reduced if two photo-hardenable resins are used. The use of recesses may also help to reduce waste of unused photocurable resin, as only the portion of the carrier having the recesses is filled with photocurable resin.

Step (c) may be defined by moving the carrier to position the first layer of the billet between the build platform and the light projector.

The 3D printing device preferably has a coating station and an additive manufacturing station. The coating station and the additive manufacturing station are preferably spaced apart from each other in the process flow direction. The process flow direction is the direction in which the carrier moves. Step (b) is preferably performed in a coating station, and steps (d) and (e) are preferably performed in an additive manufacturing station. Thus, the coating may be performed independently of the additive manufacturing. For example, steps (b) and (e) may be performed simultaneously or overlapping each other. Thus, the object can be constructed at a minimized time.

In one embodiment, the method further comprises the steps of:

(g) coating a second surface region of the carrier with a (preferably contiguous) second layer of a second photocurable resin (composed of it);

(h) positioning a second layer of the billet between the build platform and the light projector;

(i) advancing the build platform toward the carrier, thereby contacting the in-process object with the second green layer;

(j) irradiating the second green layer with a light pattern to harden the pattern-irradiated portion, thereby supplementing the object under treatment with an additional hardened layer; and

(k) the build platform is retracted from the carrier, thereby separating the supplemented in-process object from the carrier.

The term "part" in step (j) also covers a part. Thus, the term "portion" means "one or more portions".

Preferably, the build axis is advanceable and retractable along the build axis. The build axis is also the axis along which the objects are built successively.

Step (h) may be defined by moving the carrier to position the second layer of the billet between the build platform and the light projector.

Step (g) is preferably performed in a coating station, and steps (i) and (j) are preferably performed in an additive manufacturing station.

Generally, the method of the present invention can be performed using more than the first and second photocurable resins. The first photocurable resin, the second photocurable resin, and any additional photocurable resin are preferably photopolymerizable resins that include a photoinitiator. The hardening is preferably performed by irradiating the photo-curable resin with light. The photocurable resin may specifically comprise an acylphosphine oxide as photoinitiator. In addition, the photocurable resin may be based on a monomer having a (meth) acrylate moiety as a reactive group. The photo resin may include a filler, a dye, and a colorant.

The wavelength of light suitable for hardening the photocurable resin may be in the range of 450nm to 495nm (blue light) or 330nm to 450nm, preferably 383nm (UV light). The light used in the method of the present invention may be selected according to the photohardenable material used.

Additionally, the first surface region and the second surface region may be spaced apart from each other. In particular, the first surface area and the second surface area may be spaced apart from each other in a dimension of the process flow direction.

Thus, the method may further comprise the steps of:

(l) Coating a third or further surface region of the carrier with a (preferably contiguous) third or further blank layer of a third or further photocurable resin (consisting thereof);

(m) positioning a third or additional layer of the billet between the build platform and the light projector;

(n) advancing the build platform towards the carrier, thereby bringing the in-process object into contact with the third or further blank layer;

(o) irradiating the third or further blank layer with a light pattern to harden the pattern-irradiated portion to supplement the object under treatment with a further hardened layer; and

(p) retracting the build platform from the carrier, thereby detaching the supplemented in-process object from the carrier.

The term "part" in step (o) also covers a part. Thus, the term "portion" means "one or more portions".

Step (m) may be defined by moving the carrier to position the third or further layer of the billet between the build platform and the light projector.

In steps (d), (i) and (n), the build platform is preferably advanced from a position in which the in-process object is not in contact with the first blank layer, the second blank layer, the third or further blank layer, respectively, to a position in which the in-process object is in contact with the first blank layer, the second blank layer, the third or further blank layer, respectively. The position in which the object in the treatment is in contact with the first blank layer, the second blank layer, the third or further blank layer preferably corresponds to the proximal position, and the position in which the object in the treatment is not in contact with the first blank layer, the second blank layer, the third or further blank layer preferably corresponds to the retracted position.

In the proximal position, the subject under treatment may not be in direct contact with the carrier. Steps (f), (k) and (p) preferably result in the subject being positioned in a retracted position during treatment. Thus, in steps (f), (k) and (p), the subject under treatment is preferably positioned from the proximal position to the retracted position.

Preferably, the first and second surface regions (and ultimately the third or further surface region) are offset from one another. In particular, the first and second surface regions (and ultimately the third or further surface region) may be offset from each other in a dimension in the process flow direction.

In one embodiment, steps (b) and (g) are performed overlapping in time or simultaneously.

In addition, steps (b) and (g) may be performed before either of steps (e) or (o).

In one embodiment, steps (c) - (f) are performed before steps (h) - (k).

Preferably, in steps (d), (i) and (n), the in-process object is positioned relative to the carrier so as to provide a distance between the in-process object and the carrier. In one embodiment, the first and second billet layers each have a thickness corresponding to (or substantially corresponding to) the distance. The first and second green layers may also each have a thickness of [ up to 105% ] of this distance. Such an oversize of the first and second green layers may be provided to achieve air-or bubble-free contact between each of the first and second green layers and the object under treatment.

In an optional embodiment, the object under treatment is supplemented by two or more hardened layers arranged side by side in a plane perpendicular to the build axis. The two or more hardened layers may be obtained from different photo-hardenable resins as follows. The photohardenable resins may differ from each other, for example in color and/or translucency, at least at the stage of hardening thereof. In a first process, the first hardened layer can be supplemented to the process object according to method steps (b) to (f). In a second process, the second hardened layer can be supplemented to the process object according to method steps (g) to (k). However, in a second process, the object under treatment is advanced towards the carrier in step (i) such that the first hardened layer is in contact with the carrier. In step (j), the second green layer is hardened at one or more portions other than the first hardened layer.

In another optional embodiment, the 3D printing device comprises at least a first multi-resin dispenser, e.g. an inkjet-based dispenser. In this optional embodiment, two or more different photocurable resins may be dispensed so as to coat the first surface region with a first layer of the blank composed of the different photocurable resins. Thus, the 3D printing device is configured for building up objects having a color and/or translucency gradient not only along the build axis but also in two dimensions perpendicular to the build axis.

Such optional embodiments may also include a second multi-resin dispenser and optionally additional multi-resin dispensers to coat a second surface region (or additional surface regions) with a second layer of a second material composed of a different photohardenable resin. Likewise, the photohardenable resins may differ from each other, for example in color and/or translucency, at least at the stage in which they are hardened.

In one embodiment, the carrier is flat and the first and second green layers protrude from the carrier. In particular, the first and second green layers protrude from the carrier in a dimension transverse to the process flow direction. The photohardenable resin is preferably flowable but self-supporting. This means that the shape of the photocurable resin does not significantly change over a period of 60 seconds. Specifically, the photocurable resin is configured such that the thickness of the first green layer, the second green layer, and/or the additional green layer does not vary by more than [ 5% ]overa period of 60 seconds.

In another embodiment, the carrier includes a plurality of recesses for receiving the first photohardenable resin, the second photohardenable resin, and/or any additional photohardenable resins. The recess may be sized to accommodate the entire first billet layer, second billet layer, and/or additional billet layers. Thus, the first, second and/or further blank layers may not protrude from the respective recess and are preferably flush with the surface of the carrier surrounding the recess.

In another embodiment, the method may include the step of stamping the carrier to form a plurality of recesses.

In another embodiment, step (b) may include filling one of the plurality of recesses with a quantity of the first photocurable resin to form the first green layer. Step (g) may include filling another one of the plurality of recesses with some of the second photocurable resin to form a second green layer.

In one embodiment, the method further comprises the step of providing the support from a supply reel. Additionally, the method may include the step of discharging the carrier onto a discharge spool. The discharge carrier may carry at least a portion of the first photocurable resin (or the second photocurable resin or any of the additional photocurable resins). Thus, the method of the present invention may comprise a reel-to-reel process, wherein a first photohardenable resin, a second photohardenable resin and optionally further photohardenable resins are coated on a carrier and subsequently used to build the object.

As a result of the detachment of the supplemented in-process object from the carrier, a residual part of the first green layer can be formed. Specifically, the residual portion is a portion of the first green layer remaining on the carrier after the object in the process is supplemented by using the first green layer. Thus, as a result of the detachment of the supplemented in-process object from the carrier, a residual part of the second or further blank layer can be formed. Such residual portions are portions of the first, second or further blank layer remaining on the carrier after the treatment of the object by supplementation with the first, second or further blank layer. Thus, any processing of the residual photohardenable resin after hardening is facilitated.

In another embodiment, the method comprises the steps of: the remaining portion of the first green layer is irradiated with light to harden the remaining portion. The method may further comprise the steps of: the remaining portions of the second or further blank layer are irradiated with light to harden these remaining portions. Thus, the 3D printing device may have a cleaning station in which any remaining portions of the first, second or further layer are removed from the carrier or are ready to be removed from the carrier.

In another embodiment, the method comprises the steps of: the hardened residual part of the first billet layer is disposed. The step of disposing of the hardening residual of the first green layer may comprise separating the hardening residual from the carrier, for example by bending the carrier. The carrier may be curved, for example, by guiding the carrier over rollers that cause the carrier to deflect.

In one embodiment, the method further comprises the steps of: the carrier is moved to position the remainder of the first billet layer outside the additive manufacturing station (or outside the region between the build platform and the light projector). The method may further comprise the steps of: the carrier is moved so as to position the remainder of the second or further blank layer outside the additive manufacturing station (or outside the region between the build platform and the light projector).

In another aspect, the invention relates to a 3D printing apparatus for layerwise building of an object from at least a first photohardenable resin and optionally a second photohardenable resin. The 3D printing apparatus is preferably configured for performing the method of the present invention, and optionally for performing any of the optional method features as disclosed herein.

In one embodiment, the object is a dental restoration or a dental restoration component. The first photocurable resin, the second photocurable resin, and any additional photocurable resin may (at least after hardening) exhibit a color similar to a color of a natural tooth.

The 3D printing apparatus comprises in particular a build platform on which the object can be built, a light transmissive carrier and a light projector arranged for projecting a light pattern through the carrier towards the build platform in a direction along a build axis. The building axis is preferably arranged transversely to the process flow direction. The build platform is movable along a build axis, and the carrier is movable transverse to the build axis (or along a process flow direction). The 3D printing device may also have a light transmissive (preferably transparent) exposure plate. The light projector is preferably arranged to project the light pattern through the exposure plate towards the build platform in a direction along the build axis. The carrier is preferably guided such that it is supported on the exposure plate. The build platform, Light projector, and exposure panel may constitute a stereoscopic illumination based technology such as Digital Light Processing^TM(DLP) component of an additive manufacturing station.

The 3D printing apparatus further includes a first dispenser for coating a first surface region of the carrier with a first layer of a first curable resin. In addition, the 3D printing apparatus may include a second dispenser for coating a second surface region of the carrier with a second green layer of a second photocurable resin. The 3D printing apparatus may comprise one or more further dispensers to coat one or more further surface areas of the carrier with one or more further layers of blanks of one or more further photo-hardenable resins. Thus, the 3D printing apparatus is configured for building objects from different photo-hardenable resins, and thus may be configured for building objects from different colors. The first dispenser, the second dispenser and the further dispenser may be arranged within or form a coating station of the 3D printing device.

Each of the first dispenser, the second dispenser, or the additional dispenser may include an inkjet coater or a roll coater. Additionally, the first distributor, the second distributor, or the additional distributor may comprise a can formed from a circumferential wall (e.g., a hollow cylindrical wall). The canister may contain a first photocurable resin, a second photocurable resin, or any additional photocurable resin. The canister preferably has a circumferential seal for sealingly abutting the carrier. Thus, the bottom side of the tank (being the side oriented towards the center of gravity) may be closed by the carrier. The seal is preferably configured such that it can sealingly slide on the carrier. For example, the seal may be formed by a resilient sealing lip. Thus, the carrier can move under the canister when the canister is sealed to the carrier. The first (second or further) photocurable resin is wiped off the carrier from areas outside the recesses by the seal when the carrier is moved. However, any photocurable resin present within the recesses remains within the carrier (specifically, within the recesses). A support structure may be provided to support or urge the carrier against the seal.

In one embodiment, the 3D printing device is configured to move the build platform and the carrier to positions determined by the computer control. In particular, the 3D printing device is preferably configured for moving the build platform by the computer control to different positions along the build axis relative to the carrier and/or relative to the exposure plate.

In addition, the 3D printing device may be configured to move the carrier to different positions by the computer control. In particular, the 3D printing device is preferably configured for moving the carrier relative to the build platform and the exposure plate to different positions transverse to the build axis by the computer control. In other words, the 3D printing device is preferably configured for moving the carrier in a process flow direction relative to the additive manufacturing station by the computer control.

It is noted that while it may be advantageous to move the build platform along the build axis, it is considered equivalent to alternatively or additionally moving the carrier and/or exposing the plate along the build axis. Also, instead of moving the carrier in the process flow direction, the additive manufacturing station may be moved in or against the process flow direction. Therefore, a 3D printing apparatus in which the distance between the build platform and the carrier is adjusted by movement of any other component than the build platform is considered equivalent. And in addition, a 3D printing device in which the carrier is stationary and the additive manufacturing station is moving is also considered to be equivalent.

In one embodiment, the light forming the light pattern comprises or is formed by a wavelength suitable for hardening the first photocurable resin. The wavelength may specifically be in the range of 330nm to 450 nm. The preferred wavelength is 383 nm.

In one embodiment, the 3D printing device comprises a feeding reel for providing the carrier. The 3D printing device may also have a discharge spool for discharging the carrier.

In one embodiment, the carrier is formed from an endless belt.

In another embodiment, the 3D printing device comprises two or more carriers arranged in parallel. Preferably, the carriers are movable parallel to each other. In addition, the 3D printing device may have one carrier forming two or more tracks in a dimension transverse to the process flow direction. This makes it possible to arrange the blank layer not only in the process flow direction but also transversely to the process flow direction.

The 3D printing device may have an additive manufacturing station that is movable transverse to a process flow direction. Thus, the object under treatment can be supplemented by adding a hardened layer from different rails or carriers.

In one embodiment, the 3D printing device is based on stereoscopic lighting type technology, such as Digital Light Processing^TM(DLP)。

In one embodiment, the 3D printing device has a print cartridge that houses a carrier and a coating station. Preferably, the print cartridge is removably secured at the additive manufacturing station. Thus, a print cartridge may be exchanged or exchanged for another print cartridge in the additive manufacturing station. In particular, the print cartridge may comprise at least a first dispenser. Additionally, the print cartridge may comprise a second dispenser and optionally additional dispensers. The print cartridge preferably comprises a mount which holds the first dispenser, the second dispenser and/or further dispenser and the carrier in a predetermined positional relationship with one another. In addition, the base may include a feed reel from which the carrier may be obtained and a discharge reel for discharging the carrier after being used to build the object. The print cartridge may be replaced with the carrier removed from the feed spool and/or with any of the first dispenser, the second dispenser, and/or the additional dispensers being free of the photohardenable resin. Any removed print cartridges may be recycled by refilling the first dispenser, the second dispenser and the further dispenser as required and by exchanging the used carrier for a new carrier. Optionally, the print cartridge may comprise a carrier in the form of a closed belt. In this optional embodiment, the print cartridge (or additive manufacturing station) may include a cleaning station to remove any residual photohardenable resin from the carrier. Recycling of such print cartridges may include exchanging the carrier only if the carrier is worn or according to maintenance cycles. In addition, recycling may include refilling the first dispenser, the second dispenser, and the additional dispenser as needed.

The print cartridge may have a first interface configured to mate with a corresponding second interface of the additive manufacturing station. For example, a number of print cartridges may have a standardized first interface for mating with a second interface of an additive manufacturing station.

Drawings

Fig. 1 is a side view illustrating a 3D printing apparatus described herein;

FIG. 2 is a top view of the device shown in FIG. 1;

FIG. 3 is a side view illustrating another 3D printing device described herein;

FIG. 4 is a top view illustrating another 3D printing device described herein; and is

Fig. 5 is a partial side view illustrating a portion of yet another 3D printing device described herein.

Detailed Description

Fig. 1 shows a 3D printing apparatus 1 for building an object by additive manufacturing. An in-process object 100 (a partially constructed but not yet fully constructed object) is shown. The 3D printing apparatus 1 is configured to perform the method described herein. The illustrated apparatus 1 comprises an additive manufacturing station 10 based on so-called Digital Light Processing (DLP) technology. This technique uses a back-illuminated light transmissive (preferably transparent) exposure plate 11 and a build platform 12 between which an object can be built. The method of the present invention is not limited to DLP but may be used with other additive manufacturing processes or devices based on photohardenable resins as appropriate. In particular, other stereolithography processes or devices may be used with the present invention.

The build platform 12 is movable relative to the exposure plate 11 along a build axis a. The build platform 12 holds or secures the object or in-process object 100 during build. The 3D printing apparatus 1 is provided with a light-transmissive (preferably transparent) carrier 20. The carrier 20 is movable through a gap that may be left between the exposure plate 11 and the build platform 12. The carrier 20 is movable transversely to the building axis a and is preferably arranged directly on the exposure plate 11. The 3D printing apparatus 1 has a gripper bar 21 arranged to hold the carrier 20 down on the exposure plate 11. The clamping bar 21 is movable. Accordingly, the clamping bar 21 may be retracted from the exposure plate 11 to allow the carrier 20 to move. Alternatively, the clamping bar 21 may be moved toward the exposure plate 11 to hold the carrier 20 down on the exposure plate 11.

The illustrated 3D printing apparatus 1 is configured for building objects in layers from photo-hardening resin. Each layer is produced because the photocurable resin hardens in a predetermined gap provided between the carrier 20 and the build platform 12. The gap is provided by positioning the build platform 12 accordingly. The light projector 40 projects a (two-dimensional) light pattern through the exposure plate 11 and carrier 20 towards the build platform 12 and thus hardens those portions of the photocurable resin that are exposed to the light pattern (while the portions outside the light pattern remain unhardened). The hardened resin forms a layer which is then pulled away from the carrier by the build platform 12, thereby forming a new gap between the layer and the carrier 20. The new gap so formed is used to create a new layer, etc.

In this example, the light projector 40 is a digital light projector such that the light pattern emitted from the light projector 40 may be controlled by a computer. Typically, the light pattern is determined by the computer control based on a three-dimensional representation or model of the object to be built. The three-dimensional representation may be generated, for example, on a CAD system (e.g., a dental CAD system that allows for the design of dental restorations or dental restoration components). Typically, the three-dimensional representation is cut into virtual slices of uniform thickness having a two-dimensional contour corresponding to the external shape of the three-dimensional representation it is cut.

The light projector 40 is configured to project light in a corresponding two-dimensional pattern. The light pattern may be based on a matrix of a plurality of pixels arranged in a regular pattern, like for example a checkerboard. The light projector 40 is configured so that each pixel of the pattern can be illuminated or remain dark. The resolution of the light pattern adjacent to the carrier 20 determines the accuracy with which the object can be built in a dimension perpendicular to the build axis a. Control of the light pattern may be provided by a so-called Digital Micromirror Device (DMD). The DMD includes a plurality of individually rotatable small mirrors that can be oriented to deflect light from a light beam toward an exposed plate to generate light pixels or away from the exposed plate to generate dark pixels. The skilled person will recognise other techniques for light projection. For example, the light projector may be based on LCD (liquid crystal display) projection technology. The light pattern may also be based on a movable light beam, e.g. a laser beam. In this technique, the pattern may or may not be based on a matrix of pixels.

The light for light projection includes light in a wavelength range required or suitable for hardening the photocurable resin, in an example UV light in a wavelength range of about 330nm to about 450nm, in particular 383 nm.

The 3D printing apparatus 1 has a plurality of dispensers 30, of which a first dispenser 30a, a second dispenser 30b and a third dispenser 30c are shown by way of example. Although only three dispensers 30 are shown and described below, additional dispensers having the same features as disclosed for the three dispensers shown may be provided.

Specifically, the first dispenser 30a, the second dispenser 30b, and the third dispenser 30c are preferably configured to dispense a first photo-curable resin, a second photo-curable resin, and a third photo-curable resin, respectively. The first photocurable resin, the second photocurable resin, and the third photocurable resin may be different from each other, for example, at least in terms of color and/or translucency at a stage after they are cured. Each of the first dispenser 30a, the second dispenser 30b, and the third dispenser 30c may be based on a printing or coating technique, such as inkjet, roll coating, screen printing, or gravure printing.

According to fig. 2, for example, the first photocurable resin 200, the second photocurable resin 300, and the third photocurable resin 400 are dispensed from the first dispenser 30a, the second dispenser 30b, and the third dispenser 30c, respectively. First, second, and third photocurable resins 200, 300, and 400 are dispensed on carrier 20 at an area outside additive manufacturing station 10 and then positioned in additive manufacturing station 10. Although not shown, any of the first photocurable resin 200, the second photocurable resin 300, and the third photocurable resin 400 (or one or more additional photocurable resins) may be selectively dispensed, either individually or in any order, as desired. For example, instead of dispensing the first photocurable resin 200, the second photocurable resin 300, and the third photocurable resin 400 in a consecutive order, only one of the first photocurable resin 200, the second photocurable resin 300, and the third photocurable resin 400 may be dispensed. In addition, any one of the first photocurable resin 200, the second photocurable resin 300, and the third photocurable resin 400 may be dispensed a plurality of times in succession before another one of the first photocurable resin 200, the second photocurable resin 300, and the third photocurable resin 400 is dispensed individually or dispensed a plurality of times in succession. The photohardenable resin so dispensed (selected from the first photohardenable resin 200, the second photohardenable resin 300, and the third photohardenable resin 400, and optionally one or more additional photohardenable resins in any order) is then moved between the build platform 12 (shown in fig. 1) and the exposure plate 11 (shown in fig. 1) to harden and thus supplement the treating object 100 with additional hardened layers.

The dispensed photohardenable resin is continuously moved between the build platform 12 and the exposure plate 11 by means of a carrier 20 in which it is used to build the object. To move the carrier 20 with the dispensed photohardenable resin disposed thereon, the build platform 12 is positioned at a retracted position away from the carrier 20 to allow the hardenable resin to move into the additive manufacturing station 10 without colliding with the build platform 12. For example, to move the carrier 20 with the second photocurable resin 300 disposed thereon into the additive manufacturing station 10, the build platform 12 is positioned a distance from the exposure plate 11 that is greater than the thickness of the combination of the second photocurable resin 300 and the carrier. Once the second photocurable resin 300 is positioned between the build platform 12 and the exposure plate 11, the build platform 12 is further positioned toward the exposure plate 11. Specifically, once the second photocurable resin 300 is positioned between the build platform 12 and the exposure plate 11, the build platform 12 is positioned at a predetermined distance from the exposure plate 11 at which the in-process object 100 is in contact with the second photocurable resin 300. At this position, the in-process object 100 is not in contact with the carrier 20, so that the second photocurable resin 300 fills the gap between the carrier 20 and the in-process object 100.

Then, at least a portion of the second light-curable resin 300 is cured using the light projector 40 (see fig. 1) to form a cured layer of the object 100 under supplement processing. The build platform 12 is then retracted to the retracted position and the same steps are repeated for the first photocurable resin 200.

Some of the photohardenable resin may reside on the carrier 20 after any portion of the photohardenable resin is hardened, as shown by way of example for the third photohardenable resin 400'. Any resident photohardenable resin may be disposed of with the carrier 20 after being used to build the object.

As shown, the (different and/or identical) photocurable resins are distributed at a predetermined uniform spacing relative to each other. The carrier 20 may position each dispensed photohardenable resin into the additive manufacturing station 10 according to the spacing.

With the 3D printing apparatus 1 and with the method, an object can be built by providing (or "stacking") a plurality of layers in sequence. The 3D printing apparatus and method of the present invention are particularly suitable for producing hardened layers of the same and/or different properties in any desired sequence. For example, if the photocurable resin is configured to exhibit different colors (at least when cured), an object having a particular color gradient in a dimension along the build axis a may be built.

The layers typically have the same or a predetermined uniform thickness (i.e., along build axis a), but may be individually two-dimensionally shaped in a dimension transverse to the thickness based on different light patterns. However, the object may be built by providing a plurality of layers having different thicknesses. Thus, three-dimensional objects having a variety of different shapes and color gradations can be constructed using the 3D printing apparatus and the method of the present invention.

The 3D printing apparatus 1 has a feeding reel 22 from which the carrier can be supplied. In addition, the 3D printing device 1 has a discharge reel 23 to collect the carrier 20 (eventually with the hardenable resin residing thereon) after being used to build several objects. The carrier 20 may be disposable. For example, the discharge reel 23 may be disposed of after being used to build several objects.

Fig. 3 shows a 3D printing apparatus 1, which corresponds to the 3D printing apparatus shown in fig. 1, except that the carrier in this example is formed by an endless belt. In addition, the 3D printing apparatus 1 has a cleaning station 50.

The 3D printing apparatus 1 is configured for building an object by additive manufacturing, and in particular for performing the method of the present invention. An in-process object 100 is also shown. The illustrated 3D printing apparatus 1 comprises a Digital Light Processing (DLP) based additive manufacturing station 10 as described above.

The build platform 12 is movable relative to the exposure plate 11 along a build axis a. The build platform 12 holds or secures the object or in-process object 100 during build. The 3D printing apparatus 1 has a light-transmissive (preferably transparent) carrier 20, which in this example is formed as an endless belt. The deflection rollers 24 help to guide the carrier 20 during movement.

The carrier 20 is movable transversely to the building axis a and is preferably arranged directly on the exposure plate 11. The 3D printing apparatus 1 has a movable gripper bar 21 arranged to hold the carrier 20 down on the exposure plate 11.

The light projector 40 is arranged for projecting a (two-dimensional) light pattern through the exposure plate 11 and the carrier 20 towards the build platform 12. In this example, the light projector 40 is a digital light projector such that the light pattern emitted from the light projector 40 may be controlled by a computer. The light for light projection includes light in a wavelength range required or suitable for hardening the photocurable resin, in an example UV light in a wavelength range of about 330nm to about 450nm, in particular 383 nm.

The 3D printing apparatus 1 also has a plurality of dispensers 30. Specifically, a first dispenser 30a, a second dispenser 30b, and a third dispenser 30c are shown by way of example. The first dispenser 30a, the second dispenser 30b, and the third dispenser 30c are preferably configured to dispense a first photo-curable resin, a second photo-curable resin, and a third photo-curable resin, respectively, as illustrated in fig. 1.

The cleaning station 50 in this example is formed by a light source that can emit light suitable for hardening the light-hardenable resin. In particular, the light source is configured to emit UV light in the wavelength range of about 330nm to about 450nm, in particular 383 nm. Thus, the cleaning station 50 hardens any residual photocurable resin on the carrier. The hardened (and thus rigid) residual resin is separated from the carrier 20 as it moves over the deflection rollers. The hardened residual resin may be collected in the container 51 and disposed of later. Thus, the carrier 20 may be used to continuously coat a layer of the blank thereon, supplement the object under treatment with a hardened layer obtained from the layer of the blank, and remove any residual photocurable resin from the carrier.

Fig. 4 shows a 3D printing apparatus 1, which may correspond to the example of fig. 1 or 2, but has a plurality of carriers 20a, 20b, 20c instead of only one carrier. In this example, the first carrier 20a, the second carrier 20b and the third carrier 20c are arranged side by side. The first, second and third carriers 20a, 20b, 20c are movable parallel to each other in a direction transverse to the build axis (process flow direction indicated by the arrow labelled "M"). In an example, the first dispenser 30a, the second dispenser 30b, and the third dispenser 30c are arranged along a dimension transverse to the process flow direction M. Accordingly, each of the first, second, and third carriers 20a, 20b, and 20c may be coated with a first photo-curable resin, a second photo-curable resin, and a third photo-curable resin, respectively. Specifically, a first surface region of the first carrier 20a may be coated with a first blank layer of a first photocurable resin, a second surface region of the second carrier 20b may be coated with a second blank layer of a second photocurable resin, and a third surface region of the third carrier 20c may be coated with a third blank layer of a third photocurable resin. The additive manufacturing station 10 (as described in the context of fig. 1, 2 and 3) is movably arranged for movement in a dimension transverse to the process flow direction M. Thus, the additive manufacturing station 10 may be selectively positioned to the first, second, or third blank layers to supplement the in-process object with a hardened layer obtained from any of the first, second, or third blank layers. It is noted that instead of a plurality of carriers one common carrier forming a plurality of tracks may equally be used.

In this example, the first, second and third carriers have a plurality of recesses 25 for holding the photo-hardenable resin, as illustrated in fig. 5.

Fig. 5 shows a part of the 3D printing apparatus 1 with a carrier 20, which can be used with the embodiment shown in any of fig. 1 to 4. The carrier 20 has a plurality of recesses 25 (one of which is shown in this view). The recess 25 is provided for receiving the photo-hardenable resin therein. The recesses 25 may be particularly useful for receiving low viscosity photohardenable resins that would otherwise be distributed in an uncontrolled manner on the carrier. The 3D printing device 1 may have an imprint station (not shown) to imprint the carrier 20 to provide the recesses 25.

The 3D printing apparatus 1 has a tank 60, which in this example is formed by a circumferential wall 61 (e.g. a hollow cylindrical wall). A first photocurable resin 63 (or another photocurable resin) is provided in the tank 60. The canister 60 also has a circumferential seal 62 that sealingly abuts the carrier 20. The seal 62 is configured such that it can sealingly slide on the carrier 20. Thus, the carrier 20 may move under the canister 60 when the canister 60 is sealed to the carrier 20. When the carrier 20 moves, the first photocurable resin 63 is wiped off from the region outside the recess 25 of the carrier 20 by the sealing member 62. However, any photocurable resin present within the recess 25 is flush with the surface of the carrier 20 adjacent the seal 62. Accordingly, the recess 25 of the carrier 20 may be completely filled with the first photocurable resin. The carrier 20 may then be moved to position the recess 25 filled with the photohardenable resin between the build platform of the additive manufacturing station and the light projector. A support structure 64 may be provided to support the carrier 20 against the seal 62.