Patent Application
20230256675
Embodiments of the present invention relate to a method and to an apparatus for producing three-dimensional objects by selectively solidifying a build material applied layer by layer.
DE 10 2017 211 657 A1 discloses an apparatus for additive manufacturing of a component with protective gas guiding means, and a method in this respect. This apparatus comprises a process assistance device having a centre module and a respective outer module aligned with the centre module. The centre module is triggered so as to be able to move above a build platform. The centre module comprises a coater, via which build material is fed from a powder reservoir, with the result that said build material is discharged onto the build platform during the movement of the centre module. A respective protective gas outlet device, the protective gas outlets of which are aligned towards the outer module, is provided on either side of the coater. During the solidification of the build material, a protective gas is discharged through a multiplicity of the protective gas outlets and extracted by suction by the opposite outer module. This outer module in the form of a suction extracting device can be triggered so as to be able to move synchronously with the centre module, while the build material is being solidified by means of a laser beam in the region in between.
WO 2019/115140 A1 furthermore discloses a method and an apparatus for producing three-dimensional objects by selectively solidifying a build material applied layer by layer. This apparatus comprises a receiving device, to which a centre module and, adjacent to each outer end, a respective outer module are fastened in stationary fashion. The centre module comprises a coater and a respective suction extracting device, which is aligned with the outer module. While the laser beam is being fed to a build platform between an outer module and the centre module, a process gas stream from the outer module to the suction extracting device on the centre module is generated. The opposite outer module is cut off from the feed of a process gas stream.
EP 1 137 504 B1 discloses a method and an apparatus for selective laser melting of build material to produce a three-dimensional object. A process gas stream containing argon, which is aligned horizontally and extracted by suction from an intake opening on one side of the process chamber to an outlet opening on the opposite, or left-hand, wall of the process chamber, is generated above a build platform. Feed openings for a helium process gas stream are provided above the build platform and close to a passage window for the laser beam. In a similar way to the process gas stream guided parallel to the build platform, this helium process gas stream is extracted by suction through the one outlet opening in the left-hand wall of the process chamber. The two process gas streams fed into the process chamber are extracted by suction through an outlet opening provided on the process chamber.
EP 3 147 047 A1 furthermore discloses a method and an apparatus for producing three-dimensional objects by selectively solidifying a build material applied layer by layer. In the case of this apparatus, it is provided that, by way of a shared gas supply source, a first process gas stream is fed through a right-hand wall of the process chamber, guided along above the build platform, and removed through an outlet opening on the left-hand process chamber wall. The process gas supply source feeds a second process gas stream from a flow head which is arranged above the build platform and has a multiplicity of outlet openings, through which the second gas stream is fed towards the build platform. This process gas stream introduced into the process chamber through the flow head, together with the first process gas stream, is extracted by suction through the shared opening on the left-hand wall of the process chamber.
Embodiments of the present invention provide a method for producing a three-dimensional object by selectively solidifying a build material applied layer by layer. The method includes, in at least one process chamber, applying the build material layer by layer to a build platform, generating at least one beam for solidifying the build material using a radiation source, feeding the at least one beam to the build material in the build platform using at least one beam guiding element, and generating a primary gas flow along the build platform using a process assistance device. The process assistance device includes a centre module and at least one outer module aligned with the centre module, so that a section over which primary gas flows is formed between the centre module and the at least one outer module. The method further includes generating a secondary gas flow that is aligned onto and fed to the build platform using a feed device above the build platform, so that a section along which the secondary gas flows is created between the feed device and the process assistance device.
Subject matter of the present disclosure will be described in even greater detail below based on the exemplary figures. All features described and/or illustrated herein can be used alone or combined in different combinations. The features and advantages of various embodiments will become apparent by reading the following detailed description with reference to the attached drawings, which illustrate the following:
Embodiments of the present invention provide a method and an apparatus for producing three-dimensional objects by selectively solidifying a build material applied layer by layer, by virtue of which the quality of the three-dimensional object and the process reliability are increased.
According to some embodiments, a method for producing three-dimensional objects by selectively solidifying a build material applied layer by layer, in the course of which method a primary gas flow is generated along the build platform by means of a process assistance device, which comprises a centre module and a respective outer module aligned with it, with the result that a section over which primary gas flows is formed between a centre module and at least one outer module, and, in addition to this primary gas flow, a secondary gas flow is introduced into the process chamber and aligned onto the build platform by means of a feed device above the build platform, and a section along which the secondary gas flows is created between the feed device and the process assistance device. This has the advantage of inducing continuous flushing of the process chamber with the secondary flow, with the result that laser-particle interaction is considerably reduced. This enables uniform process conditions, and therefore, by virtue of the combination of the primary gas stream and the secondary gas stream, an improved quality in the build of three-dimensional objects and an increase in process reliability are achieved.
Preferably, it is provided that a primary gas stream is discharged by at least one outer module and a secondary gas stream is discharged by the feed device, and that the primary gas stream and the secondary gas stream are extracted by suction together by the centre module of the process assistance device. This triggering of the centre module to extract the primary gas stream and the secondary gas stream by suction makes it possible to selectively enable solidification of the build material by the beam on either side of the centre module, wherein the centre module is moved correspondingly in relation to the build platform. In addition, improved flushing of the entire process chamber can be enabled in order to guide dirt out of the process chamber.
Advantageously, each outer module discharges a primary gas stream towards the centre module, wherein the fed primary gas stream is extracted by suction by a suction extracting means, which is aligned with each outer module and provided on the centre module. This makes it possible to enable consistent conditions during the solidification of the build material.
During a movement of the centre module above the build platform, it is preferably provided that the two suction extracting devices of the centre module are triggered to extract the primary gas stream and the secondary gas stream by suction. This enables complete extraction of the process chamber volume by suction.
Preferably, the centre module or the at least one outer module are triggered so as to be movable along the build platform. In the process, the distance between the centre module and the at least one outer module can be triggered to remain the same or vary. The centre module and the at least one outer module or the two outer modules can be directly and individually triggered to move. In this case, the outer modules may be formed with feed channels, the length of which is variable and which in particular are telescopic.
In the event of a movement of the centre module into or out of an end position adjacent to the build platform or in the event of a positioning of the centre module in the end position, preferably a constant flow of the primary jet and secondary jet is triggered. This makes it possible to optimize the process time. As an alternative, it may be provided that only that suction extracting device of the centre module that faces the build platform is triggered to extract the primary and secondary jet by suction. In particular when assuming an end position, the centre module can be filled, for example, with build material and the primary gas jet and secondary gas jet can nevertheless be extracted by suction, that is to say that, while a storage container is being filled with build material in the centre module, the build material can continue to be solidified.
Furthermore, it is preferably provided that, in the event of a movement of the centre module into or out of an end position adjacent to the build platform or in the event of a positioning of the centre module in the end position, only that outer module that is opposite and remote from the centre module is triggered to discharge the primary gas stream. This makes it possible to avoid disruptive turbulences, in particular resulting from the delivery of removed build material to overflow containers arranged adjacent to the build platform.
A further advantageous embodiment of the method provides that the two outer modules are at a standstill in a respective end position outside the build platform and the centre module is triggered to move over the build platform. This arrangement enables a more straightforward structural design of the outer modules. As an alternative, it may be provided that the centre module and the at least one outer module, preferably the two outer modules, are triggered to move along the build platform. This makes it possible to produce short paths over which flow passes between the outer module and the centre module. This has the advantage of enabling homogeneity of the section over which flow passes, as a result of which improved extraction of dirt, byproducts or the like by suction is enabled. Advantageously, it may be provided that, during the movement of the centre module and of the at least one outer module, the distance between them is kept constant. As an alternative, it is also possible to trigger a change in distance of the centre module in relation to the outer module.
Embodiments of the present invention also provide an apparatus for producing three-dimensional objects by selectively solidifying a build material applied layer by layer, which apparatus comprises a process assistance apparatus having a centre module and a respective outer module aligned with it, with the result that a section over which primary gas flows is formed between the centre module and the at least one outer module to generate a primary gas flow, and a feed device for a secondary gas flow is provided above the build platform, wherein the secondary gas flow is aligned onto the build platform from above by the feed device, and a section along which flow passes is formed between the feed device and the process assistance device. This makes it possible to build up a targeted flow of a primary gas flow and a secondary gas flow through the process chamber, in order to keep the process gas chamber free of dirt, byproducts or the like. In addition, by introducing the secondary gas flow above the build platform, it is possible to efficiently flush the process chamber, as a result of which laser-particle interaction or lengthy dwell times of particles in the process chamber are avoided.
Preferably, it is provided that the centre module has a suction extracting device, which faces the respective outer module and extends at least over the width of the build platform, that is to say in the Y direction. This suction extracting device is preferably in the form of a rotary tube with a continuous suction-extraction opening. This makes it possible for the centre module to enable extraction of the primary gas stream and/or of the secondary gas stream by suction on either side.
Preferably shaft-shaped storage containers for the build material and a coating device between them are arranged between the two suction extracting devices of the centre module of the process assistance device. As a result, a compact arrangement and structure for the centre module can be provided, with the result that at the same time discharging and coating of the discharged build material for the next layer to be solidified is made possible.
Advantageously, each outer module has an outlet nozzle, which is provided on a feed channel for the process gas. The outlet nozzle on the outer module preferably has a polynomial nozzle shape. As a result, the primary gas stream flowing out of the outlet nozzle is accelerated and stabilized, resulting in homogeneity of the process gas flow along the path over which flow passes. Advantageously, the feed channel has a variable length, in particular is telescopic. This makes it possible for the outlet nozzle to be moved above the build platform depending on the position of the centre module.
A beam inlet opening for the beam for solidifying the build material is preferably provided in the process chamber. A feed channel for feeding the secondary gas is preferably aligned on either side of the beam inlet opening. The secondary gas is preferably transferred to the process chamber through a respective feed opening adjoining the beam inlet opening or through a feed opening surrounding the beam inlet opening. This makes it possible to enable central introduction of the secondary gas stream and a uniform application of secondary gas to the process chamber.
It is preferably provided that the length of the process chamber is delimited by mutually opposite wall portions which, proceeding from the feed opening of the feed device, have a respective flow surface, the distance between which flow surfaces progressively decreases towards the build platform. This makes it possible to achieve stabilization of the secondary stream and also homogenization, in particular irrespective of the position of the process assistance device, in particular of a position of the centre module.
Advantageously, proceeding from the smallest distance between the mutually opposite wall portions, the flow surface merges into a widening, which is delimited by a horizontally aligned boundary surface, connected thereto, of the wall portion. As an alternative, the smallest distance between the flow surfaces is reached at those ends of the flow surfaces that point towards the build platform, in particular as far as a horizontally aligned boundary surface connected thereto. The horizontally aligned boundary surface is advantageously aligned above the process assistance device, which is aligned towards the process chamber floor. This makes it possible to achieve further optimization of the secondary gas stream until it impinges on the build platform or is extracted by suction by the centre module.
Preferably, the smallest distance between the flow surfaces of the wall portions of the process chamber is the same as or less, alternatively greater, than the length of the build platform. By virtue of this geometric configuration, a targeted transfer of the secondary jet to the build platform can be enabled.
According to a preferred embodiment of the process chamber, it is provided that, as seen in a side view, the wall portions of the process chamber have a tulip-shaped contour. This makes it possible to achieve a constriction of the secondary jet for flow stabilization.
An advantageous embodiment of the feed opening provides that it is formed by a throughflow element, in particular a flow screen, a perforated plate, a nonwoven or the like. As an alternative or in addition, such a throughflow element can also be provided at the feed opening which widens along the flow surface. Preferably, use can be made of a multilayer filter laminate woven fabric, for example a four-layer filter laminate woven fabric, as a result of which better performance for uniform distribution of the flow by generating a higher pressure difference is enabled. Preferably, such a filter laminate has a mesh width of 10 to 500 µm, particularly preferably 30 to 200 µm, for example 100 µm. Such a flow screen enables uniform distribution of the fed secondary gas, as a result of which the homogenization of the secondary gas stream is promoted.
An advantageous embodiment of the feed opening which widens along the flow surface provides that the throughflow element is secured on a line of the smallest distance between the flow surfaces and alternatively or additionally so as to at least partially adjoin the beam inlet opening or to partially surround it. This enables an areal homogenization of the secondary gas flow, in particular over a large surface portion which reaches from the beam inlet opening to the line of the smallest distance between the flow surfaces. In this respect, it should be noted that it is not necessary for there to be only one line of smallest distance between the flow surfaces if the two mutually opposite flow surfaces have parallel planar portions.
Preferably, the widening feed opening is completely covered by the throughflow element. As a result, the secondary gas flow passing completely through the feed opening is areally homogenized.
In the event of the process chamber having a symmetrical design, i.e. with two throughflow elements in a mirror-symmetrical arrangement, secondary gas can be fed to the process chamber in particularly turbulence-free fashion. Usually, it is also the case that fins or further throughflow elements are dispensed with.
Furthermore, it is preferably provided that the feed channels, which supply the feed opening and surround the beam inlet opening, have two baffles, which divide the fed secondary gas in the feed channel into two symmetrical lateral streams and a core stream in between them. Advantageously, in this respect it is provided that the core stream is fed to an end face of the beam inlet opening and the two lateral strands are fed to a side portion of the feed opening that surrounds the beam inlet opening. As a result, uniform filling of the process chamber with secondary gas can be enabled.
Preferably, the two baffles provided in the feed channels are arranged at a distance from one another that corresponds to the width of the beam inlet opening, with the result that the baffles extend along the width of the beam inlet opening and preferably the mutually opposite baffles arranged in the two feed channels each extend over half of the length of the beam inlet opening. This makes it possible to feed the lateral streams to the entire region of the feed opening, which extends laterally around the beam inlet opening in the form of a frame.
Furthermore, to configure the feed opening, it can alternatively be provided that the throughflow element inserted in the feed opening comprises a chamber in which a filter laminate is provided. Such a chamber makes it possible to bring the core stream and the two lateral streams together.
According to a further preferred embodiment, it is provided that an end face of the beam inlet opening has a reverse-stream fin assigned to it. This reverse-stream fin, which is provided on both sides of the beam inlet opening, brings about a horizontal reverse stream of the secondary gas, which is fed from both sides, with the result that these streams meet in the middle of the beam inlet opening and can generate a secondary gas stream directed downstream.
Furthermore, it is preferably provided that at least one flow stabilizer is provided between an end face of the beam inlet opening and the flow surface of the wall portion of the process chamber, which flow stabilizer preferably has a curvature which in particular follows the curvature of the flow surface. This enables turbulence-free feeding of the secondary gas into the process chamber in all positions of the centre module.
Further advantageous embodiments and developments of the present invention will be described and explained in more detail below on the basis of the examples illustrated in the drawings. The features that can be gathered from the description and the drawings can be used individually by themselves or as a plurality in any combination according to embodiments of the invention.
A radiation source 26, which generates a beam 27, in particular a laser beam, is assigned to the process chamber 16 or secured to the process chamber 16. This laser beam is guided along a beam guide 28 and is deflected and directed onto the build platform 17 by a triggerable beam guiding element 29. In the process, the beam 27 enters the process chamber 16 through a beam inlet opening 30. The build material applied to the build platform 17 can be solidified at the impingement point 31 of the beam 27.
The process assistance device 21 comprises a centre module 33 and a respective outer module 34, 35 assigned to the centre module 33. In the embodiment of the process assistance device 21 according to
The centre module 33 comprises two suction extracting devices 41, which have a respective oppositely aligned intake opening 42. A storage container 44 for receiving build material is provided between the suction extracting devices 41. This storage container 44 has at least one opening or a discharge slot pointing towards the process chamber floor 18, with the result that a layer of build material can be discharged by the centre module 33 when it is moving over the build platform 17. A coating device 46 is preferably provided between two storage containers 44 that are arranged adjacent to the suction extracting device 41. Preferably, the storage container 44 which is at the front in the direction of movement of the centre module 33 is filled with build material. The coating device 46 comes next. In particular, the coating device 46 comprises at least one coater lip.
The centre module 33 is preferably filled with build material in the right and/or left end position 36, 37. In this respect, a metering apparatus 48 can be assigned to the one end position or both end positions 36, 37.
This metering apparatus 48 can be moved along a Y axis (
The overflow container 19 is likewise assigned to the right and the left end position 36, 37, with the result that stripped build material can be removed into the overflow container 19 by the coating device 46 of the centre module 33 when the end position 36, 37 is assumed.
Each outer module 33 is connected to a supply line 52. This supply line 52 is exposed to a primary gas by a pump or primary gas source, which is not illustrated in more detail, with the result that a primary gas flow can be discharged into the process chamber 16 by the outer modules 34.
A feed device 55 for a secondary gas flow into the process chamber 16 is provided above the process chamber 16. This feed device 55 comprises two mutually opposite feed channels 56, which are positioned adjoining the beam inlet opening 30. The secondary gas flows into the process chamber 16 and is fed from above onto the build platform 17 through at least one feed opening 57, which is assigned to or surrounds the beam inlet opening 30.
The process chamber 16 has lateral wall portions 60, which delimit the length of the process chamber 16. These wall portions 60 comprise flow surfaces 62, which extend towards the build platform 17 and constrict a cross-sectional area of the process chamber 16. This provides a distance 61 which corresponds to, or preferably is smaller than, the length of the build platform 17 that extends in the X direction, as illustrated in
Secondary gas is supplied to each feed channel 56 of the feed device 55 by way of a secondary gas source, not illustrated in more detail, through a supply line 52.
With reference to the following
A perforated plate 71 extending over the cross section is preferably provided in the feed channel 56. As a result, it is already possible to achieve a first homogeneous division of the stream of the fed secondary gas. The feed channel 56 leads into the feed opening 57. In the exemplary embodiment, the feed opening 57 is formed by a throughflow element 59, such as a flow screen. This throughflow element 59 can, for example, also be in the form of a perforated plate or a gas-permeable knitted fabric or a multi-layer metal woven fabric or the like. The feed opening 57 completely surrounds the beam inlet opening 30. Thus, the feed opening 57 and the beam inlet opening 30 are in a common plane.
Baffles 72, which subdivide the cross section of the feed channel 56 into a core stream 74 and two external lateral streams 75, extend between the perforated plate 71 in the feed channel 56 and the feed opening 57. These baffles 72 extend along the width of the beam inlet opening 30, each over half of the length of the beam inlet opening 30. At the same time, the feed channel 56 has an upper curved surface 76, in order to feed the lateral streams 75 to the process chamber 16 via the lateral regions of the feed opening 57.
A reverse-stream fin 77 is assigned to each end face of the beam inlet opening 30 at the feed opening 57. This reverse-stream fin 77 is provided at a distance from the beam inlet opening 30 inside the process chamber 16. These reverse-stream fins 77 are aligned virtually horizontally. As a result, a horizontal reverse stream is fed through the feed channels 56 from either side, these horizontal reverse streams meeting in the middle of the beam inlet opening 30 and then creating a secondary gas stream directed downstream. A respective flow stabilizer 78 is provided between an end face of the beam inlet opening 30 and the wall portion 60. Said flow stabilizer preferably has a curvature corresponding to the flow surface 62. This flow stabilizer 78 extends over the entire width of the feed channel 56 or feed opening 57. These flow stabilizers 78 enable a reverse-stream-free and/or directed secondary gas stream in the peripheral region of the process chamber 16 irrespective of the position of the centre module 33.
Preferably, it is provided that the outlet nozzle 38 of the outer modules 34, 35 has an opening cross section which is more than 3 times larger than the intake openings 42 of the suction extracting device 41.
In this embodiment, it is provided that the process assistance device 21 has two outer modules 34, 35 triggered so as to be able to move. In this respect, the feed channels 56 preferably have a telescopic form, with the result that the outlet nozzles 38 can be moved relative to the build platform 17. The triggering of the outer modules 34, 35 to be able to move relative to the movement of the centre module 33 has the advantage that the section over which flow passes between the outlet nozzle 38 and the suction extracting device 41 can be kept short. This makes it possible to maintain the homogeneity of the primary gas stream along the section over which flow passes, as a result of which improved extraction by suction can be achieved. In the illustration of
Also while the centre module 33 is being moved into an end position 36, 37 or into the end position 36, 37, such as the left end position 36 for example, the primary gas stream and/or the secondary gas stream is maintained. Preferably, a constant flow of the entire process gas cycle is provided.
A respective flow surface 62 extends from the feed opening 57 towards the centre module 33 and the build platform 17 (not illustrated). In this example, the flow surfaces 62 are each formed by three planar portions and the smallest distance 61 is formed by the lower ends of the flow surfaces 62. In this case, the smallest distance 61 is greater than the length of the build platform 17 that extends in the x direction. The smallest distance 61 could, however, also be the same as or smaller than the length of the build platform 17 that extends in the x direction. As an alternative, the flow surfaces 62 could have a form similar to the previous exemplary embodiments. A respective horizontally aligned boundary surface 63 is connected to the ends of the flow surfaces 62. The feed opening 57 through which the secondary gas flow is fed therefore widens along the flow surface 62.
In this exemplary embodiment, a throughflow element 59 is secured along the two feed openings 57 that widen in this way, in order to form particularly homogeneous secondary gas flows. In this case, the throughflow element 59 is secured to the feed opening 57, preferably adjacent to the beam inlet opening 30, and to the ends of the flow surfaces 62, i.e. along the line of the smallest distance 61 from the respective other flow surface 62, on the same side of the beam inlet opening 30. In this respect, the widening feed opening 57 is completely covered by the throughflow element 59, with the result that each secondary gas stream must pass through the throughflow element 59 and is thereby homogenized.
In this respect, the throughflow elements 59 are adjacent to the beam inlet opening 30 and vertical in relation to this beam inlet opening 30, in order as a result to create a secondary gas stream which is locally horizontal and thus parallel to the beam inlet opening. By contrast, the angle of the throughflow elements 59 along the line of the smallest distance 61 differs in each case in such a way that that side of the throughflow element 59 that is opposite to the feed channel 56 is inclined towards the centre module 33 and the build platform 17.
In this exemplary embodiment, the throughflow elements 59 are formed by two planar portions. In this case, it comprises a filter laminate, which has a mesh width between 10 and 500 µm, preferably between 30 and 200 µm, for example 100 µm.
While subject matter of the present disclosure has been illustrated and described in detail in the drawings and foregoing description, such illustration and description are to be considered illustrative or exemplary and not restrictive. Any statement made herein characterizing the invention is also to be considered illustrative or exemplary and not restrictive as the invention is defined by the claims. It will be understood that changes and modifications may be made, by those of ordinary skill in the art, within the scope of the following claims, which may include any combination of features from different embodiments described above.
The terms used in the claims should be construed to have the broadest reasonable interpretation consistent with the foregoing description. For example, the use of the article “a” or “the” in introducing an element should not be interpreted as being exclusive of a plurality of elements. Likewise, the recitation of “or” should be interpreted as being inclusive, such that the recitation of “A or B” is not exclusive of “A and B,” unless it is clear from the context or the foregoing description that only one of A and B is intended. Further, the recitation of “at least one of A, B and C” should be interpreted as one or more of a group of elements consisting of A, B and C, and should not be interpreted as requiring at least one of each of the listed elements A, B and C, regardless of whether A, B and C are related as categories or otherwise. Moreover, the recitation of “A, B and/or C” or “at least one of A, B or C” should be interpreted as including any singular entity from the listed elements, e.g., A, any subset from the listed elements, e.g., A and B, or the entire list of elements A, B and C.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2020 129 413.1 | Nov 2020 | DE | national |
This application is a continuation of International Application No. PCT/EP2021/080818 (WO 2022/096669 A1), filed on Nov. 5, 2021, and claims benefit to German Patent Application No. DE 10 2020 129 413.1, filed on Nov. 9, 2020. The aforementioned applications are hereby incorporated by reference herein.
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/EP2021/080818 | Nov 2021 | WO |
| Child | 18308693 | US |
