DE102018108145A1 - Method for processing surfaces of components produced by means of 3D printing, and such a machined component - Google Patents

Abstract

The invention relates to a method for processing surfaces (14) of components (10) produced by means of 3D printing as well as to such a processed component (10).
It is envisaged that a method for processing surfaces (14) of 3D printed components (10) is provided. The method comprises the following steps: scanning the surface (14) of the component (10) to be machined by means of a scanning device (12), wherein at least one piece of information is determined, then transmitting the at least one information to a control device. Followed by the steps of processing the at least one information in the control device and providing the recalculated at least one information from the control device to a blasting device (18). The processing of the surface (14) of the component (10) to be machined is performed by means of the blasting device (18), the blasting device (18) being designed to use the at least one processed information as control instruction for at least one parameter of the blasting device (18) ,

Description

The invention relates to a method for processing surfaces of components produced by means of 3D printing as well as to such a machined component.

The surface quality of 3D printing components is a common quality defect and is a criterion for excluding 3D printing as a manufacturing process. The selective structure of the components form the individual "production zones" on the surface. This problem occurs in almost all 3D printing processes. Currently, attempts are being made to counteract this disadvantage by changing the process parameters in 3D printing in such a way that a surface quality can thus be increased. For example, FDM (Fused Deposition Modeling) uses smaller nozzles, and SLS (selective laser sintering) processes use finer powders. Also, an attempt is made to increase the surface quality by a post-processing is completed. Such a post-processing may include, for example, a milling or a vibratory finishing. Such post-processing steps are associated with additional effort or a reduction in productivity.

From the DE 42 41 527 A1 For example, a method for hardening and, if appropriate, smoothing of machine components as well as machine components produced by this method can be taken as known. A surface of a machine component is heated by means of a jet, for example a laser beam, so that diffusion of the carbon from the cemented alleles of the ledeburite or perlite into the soft interlamellar ferrite regions takes place in an edge layer. A targeted selection of the surface to be processed is not provided.

A post-processing by means of high-energy radiation such as by means of laser beams is also from the DE 199 60 797 C1 to be known as known. Here, however, an opening is to be made in a metallic component, so that this method represents a special type of surface treatment.

From the DE 10 2014 217 858 A1 is a surface smoothing of generatively manufactured components and correspondingly manufactured components of a turbomachine to be taken as known. It is envisaged to apply a further smoothing layer to the surface, wherein the smoothing layer is deposited by vapor deposition. The smoothing layer material may be different from the one or more materials of which the component is constructed. A targeted selection of the surface to be processed is not provided.

The invention is based on the object to provide a method with which a targeted processing of 3D-manufactured components is inexpensive possible.

In a preferred embodiment of the invention, it is provided that a method for processing surfaces of 3D-printed components is provided. The method comprises the following steps: scanning the surface of the component to be processed by means of a scanning device, wherein at least one information is determined, sending the at least one information to a control device, processing the at least one information in the control device, providing the processed at least one piece of information from the control device to a jet device. The processing of the surface to be machined of the component is performed by means of the jet device, wherein the jet device is designed to use the at least one processed information as a control instruction for at least one parameter of the jet device. It is thus an inline control of the laser based on the at least one information possible. In this way, it is possible to significantly increase the surface quality of 3D-manufactured components. The process can be carried out very efficiently, so that it is also cost-effective.

Further preferred embodiments of the invention will become apparent from the remaining, mentioned in the dependent claims characteristics.

In a further preferred embodiment of the invention it is provided that the jet device is a laser device. Such a jet device has been found to be particularly suitable.

In addition, in a further preferred embodiment of the invention, it is provided that the scanning device is an optical measuring system. By measuring the surface using such an optical measuring system, it is possible to use the laser specifically to eliminate surface defects. In this way, an efficient process time can be achieved, so that a cost-effective method is made possible. In this case, the optical measuring system detects the surface with high precision and plays the at least one piece of information in the form of data to a control unit or a computer.

Furthermore, it is provided in a further preferred embodiment of the invention that the at least one information determined by the scanning device topographic data to be processed Surface is. The at least one determined information comprises a measurement of the surface of the component to be processed. This can be an optical measurement of the surface. Such data are particularly advantageous for a post-processing step to be performed. In particular, elevations and depressions are thus detected very precisely by the surface of the component.

It is also provided in a further preferred embodiment of the invention that the control device converts the at least one information into a processed information, so that the processed information is provided in the form of an inverse model to the jet device. The control unit or the computer converts the topographic data into an inverse model and transfers it to the laser device. It is thus possible to draw conclusions from the at least one information on the state of the surface, so that a subsequent post-processing step can be carried out very efficiently and inexpensively.

In a further preferred embodiment of the invention, it is provided that the blasting device additionally uses the CAD (computer-aided design) information of the component to be processed for the processing in addition to the at least one refurbished information. The CAD information of the component serves as an additional reference. Thus, an even more targeted processing of the component by means of the laser device is possible, so that the method is even more cost-effective.

In addition, it is provided in a further preferred embodiment of the invention that the processing by means of the jet device comprises a smoothing step of the surface to be machined of the component. The laser smooths the surface, wherein a particularly smooth surface of the component to be machined can be obtained in an advantageous process time, so that a cost-effective method is made possible.

It is also provided in a further preferred embodiment of the invention that the machining comprises a smoothing step, wherein in the smoothing step at least one elevation in the surface to be processed is removed from the component. For example, the laser smooths the surface such that bumps are removed and pits are maintained. This leads to a particularly smooth surface of the component to be machined with an advantageous process time, so that a cost-effective method is made possible. The proposed smoothing step can also be referred to as a polishing step or laser polishing. By laser polishing, the surface quality in 3D printing can be reworked and a significant increase can be achieved. The use of laser polishing for the post-processing of 3D printing components leads to a particularly smooth surface of the component to be machined. The method may also be referred to as laser polishing of 3D printing components in a specific embodiment.

It is also provided in a further preferred embodiment of the invention that the method steps are performed automatically by the method, wherein an automation device is provided, so that the component is aligned in each case for the respective processing step. A complete linking and automation is conceivable with the presented method, so that an even more cost-effective method is made possible. The scanning device or the optical measuring system can also be in the form of a scanner. The laser device can also be referred to only briefly as a laser. The scanner and the laser can be designed so that it is possible to measure and rework the component in a layer of several pages. As a result, a rotation of the component and a reworking can be avoided. In addition to a continuous principle with a moving component, it is also conceivable to move the laser and the scanner around the component. It is also conceivable to move the component with a robot under the laser and the scanner.

Finally, it is provided in a further preferred embodiment of the invention that a 3D-printed manufactured component is provided which has a post-processed surface, wherein such a component is produced by the method according to claims 1 to 9. Such a component can be produced inexpensively with a high surface quality.

In general, the presented process can reduce costs and at the same time achieve higher quality. In particular, the laser offers more freedom. Also, a higher accuracy in post-processing is possible. In addition, the method is universal and applicable to any component geometry. So it is a cost-effective and reproducible process, which is also fully automated. There are no waste of production resources. The use of the method is not limited to the automotive industry. Rather, this method can be used for example in medicine, aviation or in the consumer goods industry or the like. 3D printing will increasingly find application in production vehicles over the next few years. Thus, the method is relevant for all imaginable vehicles in the automotive industry.

The various embodiments of the invention mentioned in this application are, unless otherwise stated in the individual case, advantageously combinable with each other.

The invention will be explained in more detail in exemplary embodiments with reference to the accompanying drawing, the processing stations of the method in a schematic side view.

1 shows a component with reference to the image plane on the left 10 which extends below a scanning device 12 located. The component 10 has a substantially wavy surface 14 which is to be processed in the following step. The waves shown are only representative of a generally uneven surface 14 shown. The way the bumps can have any shape. The scanning device 12 For example, in one variant, it may be an optical measuring system, for example a scanner, which is designed for optical measurement of the surface 14 perform. The scanning step and the scanning beams used 16 are shown schematically. The scanning device 12 sends the determined data via a computer not shown in detail or a control unit to a blasting device 18 , An arrow between the scanner 12 and the jet device 18 indicates this process. The blasting device 18 For example, it can be a laser. Below the blasting device 18 is the component 10 to recognize, with a machined area 20 already subjected to a smoothing step. This smoothing step was carried out by means of the schematically illustrated laser beam 22 that of the blasting device 18 in the direction of the component 10 was sent, executed or produced. An arrow below the plane of the component 10 indicates in which direction the component 10 must be conveyed, so that a sampling and sending of the determined data and the associated steps ultimately the smoothing step can follow. Below the level of the component 10 is also an automation device 24 which may also be a robot, for example, to recognize which component 10 align and transport for the respective process step.

LIST OF REFERENCE NUMBERS

10

component

12

scanning

14

surface

16

scanning

18

ray device

20

machined area

22

laser beam

24

automation device

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 4241527 A1 [0003]
• DE 19960797 C1 [0004]
• DE 102014217858 A1 [0005]

Claims (10)

Method for processing surfaces (14) of components produced by 3D printing (10), comprising the following steps: • scanning the surface (14) of the component (10) to be machined by means of a scanning device (12), wherein at least one information is determined becomes; Sending the at least one information to a control device; Processing the at least one information in the control device; Providing the processed at least one piece of information from the control device to a blasting device (18), characterized in that the processing of the surface (14) of the component (10) to be machined is carried out by means of the blasting device (18), wherein the blasting device (18) is designed to use the at least one processed information as a control instruction for at least one parameter of the jet device (18). Method according to Claim 1 wherein the blasting device (18) is a laser device. Method according to Claim 1 and 2 wherein the scanning device (12) is an optical measuring system. Method according to one of the preceding claims, wherein the at least one information determined by the scanning device (12) is topographic data of the surface (14) to be processed. Method according to one of the preceding claims, wherein the control device converts the at least one information into a processed information, so that the processed information in the form of an inverse model to the jet device (18) is provided. Method according to one of the preceding claims, wherein the blasting device (18) in addition to the at least one processed information additionally uses the CAD information from the component to be machined (10) for processing. Method according to one of the preceding claims, wherein the processing by means of the jet device (18) comprises a smoothing step of the surface (14) of the component (10) to be processed. Method according to Claim 7 wherein the machining comprises a smoothing step, wherein in the smoothing step, at least one protrusion in the surface to be processed (14) is removed from the component (10). Method according to one of the preceding claims, wherein the method steps are performed automatically by the method, wherein an automation device (24) is provided, so that the component (10) is aligned in each case for the respective processing step. 3D printed manufactured component (10) with a reworked surface (14), which by means of the method according to Claims 1 to 9 is made.

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