EP3758920A1 - Device and method for producing 3d shaped parts by means of improved particulate material dosing unit - Google Patents

Abstract

The invention relates to a device for producing 3D shaped parts by means of improved particulate material dosing unit (6).

Description

 Device and method for producing 3D molded parts by means of improved Partikelmaterialdosiereinheit

 The invention relates to an apparatus and a method for producing three-dimensional models by means of layer construction technique.

European Patent EP 0 431 924 B1 describes a method for producing three-dimensional objects from computer data. In this case, a particulate material is applied in a thin layer on a platform and this selectively printed by means of a print head with a binder material. The particle area printed with the binder sticks and solidifies under the influence of the binder and optionally an additional hardener. Subsequently, the platform is lowered by one layer thickness into a structural cylinder and provided with a new layer of particulate material, which is also printed as described above. These steps are repeated until a certain desired height of the object is reached. The printed and solidified areas create a three-dimensional object.

This object made of solidified particulate material is embedded after its completion in loose particulate material and is subsequently freed from it. This is done for example by means of a nipple. The desired objects then remain, which are then removed from the residual powder, e.g. be freed by brushing.

A problem with known methods of 3D printing in which particulate materials are applied is a lump-free material application. The particulate material is placed in a coater (recoater) and applied in layers to the building level. It happens

CONFIRMATION COPY It often happens that the particulate material adheres to larger particles and loses its fluidity or is applied as a particle aggregate on the construction level and thus leads to inaccuracies in the produced 3D-Fromteil or this is completely useless for quality reasons.

Another problem is that the outlet of the coater is partially or / and temporarily closed and then at least for a short time no particulate material passes through the coater opening on the building level. This can lead to voids in the produced 3D molded part as well as inaccuracies in the form precision or / and to disadvantages with regard to the strength or stability of the 3D molded part.

It was therefore an object of the present invention to provide constructive means which allow an improved 3D printing process or at least to improve or avoid the disadvantages of the prior art.

In particular, it was an object of the present invention to provide an apparatus and a method in which it is structurally achieved that particle aggregate formation is reduced or substantially prevented.

Brief summary of the invention

In one aspect, the invention relates to a device suitable for carrying out a method according to the invention for producing 3D parts, the device comprising or comprising at least one application means, such as a dosing body, optionally one or more dosing carrier carriers and optionally one or more leveling agents , at least one filter medium, such as a sieve body.

In another aspect, the invention relates to a method for producing 3D molded parts, wherein particulate building material is applied in a defined layer by means of coaters on a construction field, selectively applying one or more liquids or particulate binder, using a coater comprising an agent or combination of agents that reduces or substantially prevents particulate aggregation.

In a further aspect, the invention relates to an apparatus for producing molded parts comprising a device as described herein.

In a further aspect, the invention relates to a 3D molded part manufactured by means of a device or a method as described herein.

Brief description of the figures

Fig. 1 shows an aspect of an embodiment according to the invention, wherein a powder reservoir wall (4, 4 ') forms a powder material reservoir (17) and further a screen body (1), dosing (2), Dosierkörperträger (3) are shown. The direction of movement (5) of the metering body is indicated by an arrow and this can be controlled in both directions of rotation. The powder reservoir wall (4, 4 ') can form a counter wall (21, 21'). The unit of dosing (2) and Dosierkörperträger (3, 3 ') can also be referred to as dosing.

Fig. 2 shows an aspect of an embodiment according to the invention, wherein the metering body (2) between the powder reservoir wall (4, 4 ') is designed as a horizontally movable doctor blade, which is moved in the direction of arrow (5) via the screen body (1) for particulate material delivery.

3 shows an aspect of an embodiment (6) according to the invention, wherein two drive means (24, 24 ') are arranged below the powder reservoir walls (4, 4'). The dosing bodies (2) move in the direction of the arrow (5) and are connected to a dosing body belt (16).

4 shows an aspect of an embodiment according to the invention, which is designed as a coater (7), wherein a particle material metering unit (6) above (particle material flow direction) of a Leveling unit (8) is mounted. The particulate material is conveyed from the interior (17) of the particulate material dosing unit (6) by means of metering body (2) into the leveling unit interior (20). The distance of the metering body (2) from each other, their dimensions and the enclosed by this and the surface of the Dosierkörperträgers (3) and the screen body (1) volume defines the particle material volume (19). The particulate material is applied to the building level via the metering gap (18) of the leveling unit (8) and leveled.

Fig. 5 shows an aspect of an embodiment according to the invention, wherein a variation of a leveling unit (8 ') is shown together with a particulate metering unit (6). Leveling unit (8 ') is moved together with the particulate metering unit (6) in the direction of arrow (9), while the particulate material is applied to the building level. The leveling unit (8 ') sweeps smoothly and evenly the deposited particle material as it travels, whereby the layer thickness can be adjusted by suitable means.

Fig. 6 shows an aspect of an embodiment according to the invention, wherein different forms of the dosing body (2) as (10), (11), (12) and (13) are shown. The dosing bodies (2 ', 2 ") are each mounted on, connected to, or integral with a dosing carrier carrier, which is designed as dosing body belt (16).

Fig. 7 shows a specific embodiment of the invention, wherein the filter means (1) rotates (in the arrow direction (22), possible in both directions) and the dosing (2) rigid, preferably not movable, is formed. The internal volume of the filter medium (1) represents the particulate material reservoir (23). The application volume is determined by the rotational speed and the mesh size of the filter medium. Detailed description of the invention

According to the invention an object of the application is achieved by a Partikelmaterialdosiereinheit, which is suitable for the layered structure of moldings, comprising a particulate material reservoir, at least one applicator, optionally one or more Dosierkörperträger, optionally one or more leveling agents, and at least one filter means (strainer) ,

According to the invention, an object underlying the application is achieved by a system for producing molded parts, comprising a particle material metering unit as described herein.

According to the invention, an object underlying the application is achieved by a method which uses a particle material metering unit as described herein.

In the following, some terms of the invention are first explained in more detail.

"3D molded parts," molded parts "or" parts "in the sense of the invention are all three-dimensional objects produced by means of the method according to the invention and / or the device according to the invention, which have a dimensional stability.

"Construction space" is the locus where the bed of particulate material grows during the construction process by repeated coating with particulate material or through which the bedding passes on continuous principles.Usually, the construction space is defined by a floor, the building platform, walls and an open deck area. In the case of continuous principles, a conveyor belt and limiting side walls usually exist.The installation space can also be designed by a so-called job box, which represents a unit which can be moved in and out of the device and allows batch production, with a job box after the process has been completed is extended and immediately a new Jobbox can be retracted into the device, so that the production volume and thus the device performance is increased.

As "particulate materials" or "particulate building materials" or "building materials", all materials known for powder-based 3D printing may be used, in particular silicates (eg, sands), carbides, concrete, polymers, ceramics, and metals.The particulate material is preferably dry-free however, a cohesive, cut-resistant powder or a particle-laden liquid may also be used, in which font particle material and powder are used interchangeably.

"Particle Material Application" is the process of producing a defined layer of powder, either on the build platform or on an inclined plane relative to a conveyor belt with continuous principles " called.

For the purposes of the invention, "selective liquid application" can be carried out after each particle material application or, depending on the requirements of the molded article and for optimizing the production of shaped articles, also irregularly, for example several times with respect to a particle material application, whereby a sectional image is printed by the desired body.

As an "apparatus" for carrying out the method according to the invention, any known 3D printing apparatus may be used which includes the required components. Conventional components include coater (recoater), construction field, means for moving the construction field or coater / printhead and / or other components continuous processes, metering devices and heating and irradiation means and other components known to those skilled in the art, which can be used for powder-based 3D printing and selective solidification devices and are therefore not described here. The building material is always applied in a "defined layer" or "layer thickness", which is adjusted individually depending on the building material and process conditions. It is for example 0.05 to 0.5 mm, preferably 0.1 to 0.3 mm.

For the purposes of the invention, a "particulate material dosing unit" comprises suitable means for obtaining a uniform particulate material for application from the coater, for example one or more dosing bodies, which are either made with a filter medium or in particular as a sieve body or sieve For example, one or more dosing bodies combined with one or more dosing carrier carriers, which may also be combined with a filter medium, may be used alone or in the latter combination also passing dosing bodies on a surface (the may also be referred to as a mating surface) in order to break up possible particle aggregates and to apply a uniform particle material with uniform flowability to the building surface with the surface of the Dosierkörperträgers and the mating surface between the dosing on the one hand a volume (three-dimensional gap) forms and on the other hand preferably shear forces can be generated which allow the breaking of particle aggregates, whereby substantially uniform and flowable particulate material is obtained for application to the building level. It can also be followed by a filter means of this arrangement. Preferably, the filter means improves the disruption and homogenization of the particulate material. The "particulate material dosing unit" can be followed by a leveling unit, wherein the leveling unit is a roller or blade or / and a blade is connected downstream of the particulate material reservoir / coater.

A "coating agent" within the meaning of the invention is an agent that facilitates the particle material application and / or a uniform Supporting and distributing the particulate material supported. The "coating agent" may be a dosing body or a squeegee or a conductive agent or dosage form, preferably wherein the conductive agent is a baffle, preferably wherein the squeegee or the conductive agent consists of or comprises a plastic or a metal.

A "leveling unit" within the meaning of the invention may be one or more blades or one or more rollers or one or more wipers or other suitable means.

A "filter medium" in the sense of the invention is a screen body in the form of, for example, a grid or perforated plate or filter fabric, through which the particulate material is conveyed to the building level prior to application.

For the purposes of the invention, a "dosing body" may have different characteristics and be adapted advantageously to other parts of the device A "dosing body" may be round, oval, angular, with a round or pointed tip and executed either individually or in several coupled or independent parts his. A "dosing" can be moved directly or via one or more Dosierkörperträger.

A "dosing body carrier" in the sense of the invention can serve to move or to move one or more dosing bodies.The dosing bodies can be mounted directly on the "dosing body carrier" or controlled and / or moved by further means through the "dosing body carrier" of "Dosierkörperträger" and dosing can be done with suitable means, eg by gluing or welding (see also FIGS. 3, 4, 6).

A "powder reservoir" within the meaning of the invention is constructed or / and limited by one or more powder reservoir walls The "powder reservoir" can also be formed by the internal volume of the filter medium (see, for example, Fig. 7, reference numeral (23)). In this "powder reservoir" can according to the invention one or more Dosing body alone or together with one or more Dosierkörperträgern and one or more filter media are.

A "direction of movement of the dosing" in the context of the invention refers to the movement, by means of which the particulate material is conveyed to the building level and possibly existing particle aggregates are broken and the particulate material is again substantially uniform flowable.

A "particulate material dosing unit" in the sense of the invention may in itself be designed as a coater (recoater), for example in combination with a leveling unit, or filling a coater (recoater) if it is connected upstream of it.

The aspects of the invention are described below.

The invention relates to a device, a system and a method.

With the help of the device, system and method of the invention could surprisingly very advantageous process results can be achieved and high quality components are obtained.

It has been possible and has been achieved particularly advantageously that particle material aggregates are broken up and the applied particulate material can be applied substantially uniformly and flowable to the building level.

With the device, system and method according to the invention, the problems or disadvantages of the prior art described above are at least reduced or substantially or completely avoided.

The invention relates in one aspect to a particulate metering unit which is suitable for the layered construction of moldings comprising a particulate material reservoir, at least one applicator, optionally one or more Dosierkörperträger, optionally one or more leveling agents, and at least one filter means (screen body). In one aspect, the particulate material metering unit is characterized by at least one metering body and one or more filter media (screen body). This makes it possible advantageously to obtain homogeneous particulate material without agglomerates and applied to the construction level.

In one aspect, the particulate material dosing unit is characterized by at least one dosing body and optionally one or more Dosierkörperträger and optionally at least one counter wall. With this combination, particle material agglomerates can advantageously be broken up and essentially homogeneous particle material applied and high-quality 3D molded parts obtained. Shearing forces between dosing carrier body, dosing body and counterwall help break up particulate agglomerates and homogenize the particulate matter.

Further embodiments of the device according to the invention are designed as follows.

In the case of a particulate material metering unit according to the invention, the particulate material reservoir can be designed in such a way that the filter medium or filters are attached to its underside in the material flow direction. The particle material metering unit according to the invention can have a coating agent which is designed as a metering body or a doctor blade or a guide means. The device may also comprise at least one dosing body and further a conducting agent, e.g. have a baffle, or a squeegee. These components may consist of or comprise a plastic or a metal.

In one aspect, the particulate material dosing unit may comprise one or two dosing bodies or dosing carrier carriers, preferably in combination as a dosing roller, wherein the dosing body or dosing carrier carriers are configured, for example, as circular, elliptical, prismatic and / or brushing, or constitute a dosing roller. Furthermore, the particulate material metering unit according to the invention may have a plurality of dosing bodies, preferably 4 to 20 dosing bodies, in combination with a dosing carrier as dosing roller, or dosing bodies mounted on a dosing carrier body, wherein the dosing carrier is moved by the drive means or the drive means, preferably wherein the dosing carrier carriers are configured as a roller or straps.

A particle material metering unit according to the invention can have a volume between two metering bodies (and the corresponding boundaries by metering body carrier and counterwall, or the internal volume of the filter means) of 1 to 3000 cm ³ , preferably 15 to 1000 cm ³ .

A particulate material metering unit according to the invention may comprise a leveling agent, wherein the leveling agent or levels consist of or comprise a roller or / and a blade.

A particle material metering unit according to the invention may comprise a filter medium, the filter medium being upstream or downstream of the metering body or bodies, preferably wherein the filter medium is connected downstream of the metering roll (s) with respect to the material flow direction. The filter medium can also form an interior in which the particle material to be applied is located or introduced into it. This can be done continuously or step by step.

In a particulate metering unit according to the invention, the filter medium or filters may consist of or have a mesh, preferably a wire mesh, a woven fabric and / or a perforated sheet, and preferably a passage width (mesh size) for the particulate material, eg a mesh width, of 10 to 2500 μm , preferably 50-500 pm and the perforated plate preferably have a pitch of 1-10, preferably 1-8 mm. In a further aspect, the invention relates to a plant for producing moldings comprising a particulate material metering unit as described herein.

The invention relates in one aspect to a method for producing molded parts, comprising the steps of: applying particulate material with a particulate dosing unit as described herein, wherein the amount of the particulate material by means of relative speed of the dosing or to the filter medium and / or by means of dosing and / or the Dosierkörperausführung is controlled and a construction field is run over with the Partikelmaterialdosiereinheit and when passing a particle material layer is applied or the construction field is moved, solidifying selected areas by suitable means, repeating these steps until the desired moldings or are constructed and optionally performing another Processing steps on the molded parts thus produced.

A constant amount of particulate material can be applied by means of the particulate material dosing unit whose volume can be determined by the design selection of the dosing bodies.

By means of the method according to the invention, a substantially agglomerate-free particulate material can be applied by means of the particulate material dosing unit.

The method of the invention can use various material systems, e.g. a material system comprising a high fines content powder material, preferably having a mean grain size of <250pm.

The invention also relates to a method for producing molded parts, comprising the steps of applying particles of particulate material with a particulate material dosing unit as described herein or filling a coater (recoater) with a particulate material dosing unit as described herein. A further aspect of the invention is a 3D molded part which has been produced by means of a device or method according to the invention.

example

The invention is illustrated below by way of example, which is not intended to be limiting.

In one embodiment, the invention is illustrated as a coater fill with the particulate dosing unit as shown in FIG. A Radialdosiereinheit according to the invention is also seen separately in Figure 1. The powder material feed takes place in such a way that six (6) circular dosing bodies are mounted on a round dosing carrier. In this case, a filter medium was used whose Siebmaschenweite of 250pm was selected. The dosage is carried out in e.g. controlled manner, wherein the speed of the metering roller is set to 150 to 200 U / min. A certain speed can be at 180 rpm.

For example, it is possible to process ceramic powder (zirconium oxide D 45pm) as well as other powder materials with corresponding grain sizes.

LIST OF REFERENCE NUMBERS

Claims

claims

A particulate material dosing unit suitable for the layered construction of moldings, comprising a particulate material reservoir, at least one application means, one or more leveling agents, and at least one filter medium.

 2. particulate material metering unit according to claim 1, wherein the particulate material reservoir is designed so that the filter or the filter means are mounted on the underside in the material flow direction or act as a particulate material reservoir itself or / and

 wherein the application means is at least one dosing or at least one dosing on a Dosierkörperträger or is a conductive agent, preferably wherein the conductive agent is a baffle, preferably the conductive means consists of or comprises a plastic or a metal.

 3. particulate material metering unit according to one of claims 1 to 2, wherein the particulate material metering unit one or two

Dosing or Dosierkörperträger having, preferably in combination as a metering, wherein the or the metering or Dosierkörperträger are configured as a circular, elliptical, prism shape and / or brushing.

 4. particulate material metering unit according to one of claims 1 to 3, wherein a plurality of dosing, preferably 4 to 20

Dosing body, in combination with a Dosierkörperträger as Dosing roller are configured, or are mounted on a Dosierkörperträger dosing, wherein the Dosierkörperträger is moved by the one or more drive means, preferably wherein the Dosierkörperträger are configured as a roller or belt.

5. particulate material metering unit according to one of claims 1 to 4, wherein the volume between two Dosierkörpern from 1 to 3000 cm ³ , preferably 15 to 1000 cm ³ is and / or

 wherein the leveling means or consist of or comprise a roller and / or a blade and / or

 wherein the filter means of the application means or upstream or downstream, preferably wherein the filter means of the metering rollers or is connected downstream with respect to the material flow direction.

 6. particulate material metering unit according to one of claims 1 to 5, wherein the one or more filter means consist of or comprise a mesh, preferably a wire mesh, a fabric and / or a perforated plate and preferably a passage width

(Mesh size) for the particulate matter, e.g. a mesh size of 10 to 2500 pm, preferably 50-500 pm and the perforated plate preferably has a pitch of 1-10, preferably 1-8 mm.

 7. Plant for producing molded parts comprising a Partikelmaterialdosiereinheit according to any one of claims 1 to 6.

8. A method for producing molded parts, comprising

Steps: Orders of particulate material with a

Particulate material metering unit according to one of claims 1 to 6, wherein the amount of the particulate material by means of relative speed of the or the dosing to the Filter means and / or controlled by Dosierkörperanordnung and / or Dosierkörperausführung and a construction field is run over with the Partikelmaterialdosiereinheit and when passing a particulate material layer is applied or the construction field is moved, solidification of selected areas by suitable means or the construction field is moved, repeating these steps to the desired molding or parts are constructed and optionally carrying out further processing steps on the molded parts thus produced.

 9. A method for producing molded parts, comprising the

Steps: Orders of particulate material with a

Particulate material dosing unit according to one of claims 1 to 6 or filling of a coater (recoater) with a particulate material dosing unit according to one of claims 1 to 8.

10. The method of claim 9, wherein a constant amount of particulate material is applied by means of the particulate material dosing unit and / or

 wherein a substantially agglomerate-free particulate material is applied by means of the particulate material dosing unit and / or

 wherein a material system, e.g. a high fines powder material is used which preferably has a mean particle size of <250pm.