WO2017121539A1 - Method and computer-readable medium for modeling a contact structure - Google Patents

Abstract

The invention relates to a method for modeling a contact structure (6) in the computer-aided construction of a workpiece (100) to be produced in an additive manner. The method has the steps of detecting a construction region (4) for the workpiece (100) to be produced in an additive manner on a model substrate (1'), detecting construction parameters for the workpiece (100') to be produced in an additive manner, and generating at least one geometry for the contact structure (6) in the construction region (4) on the basis of the construction parameters. The at least one geometry is calculated such that a workpiece (100) to be produced in an additive manner on a substrate (1) corresponding to the model substrate (1') can be separated from the substrate (1) by a cutting process. The invention further relates to a computer-readable medium comprising program instructions which can be carried out and which are suitable for allowing a data processing device to carry out the aforementioned steps.

Description

description

METHOD AND COMPUTER READABLE MEDIUM FOR MODELING A CONTACT STRUCTURE

The present invention relates to a process for model-regulation ^¬ a contact structure in the computer-aided construction of a additive workpiece to be produced and a corresponding computer-readable medium, such as a storage medium.

A computer-readable medium and a corresponding method are known, for example, from WO 2015/106020 Al. The additive or generative production of workpieces or components usually takes place directly on the basis of computer-internal data models. The workpiece is preferably prepared by a primary forming process, for example by means pulverbett- based methods and / or constructed, using advantageously can be substantially dispensed with metal-cutting work ^¬ steps. Known methods are particular to ^¬ selective laser melting (SLM: English for "selective laser melting"), selective laser sintering (SLS: English for "Selective Laser Sintering") and electron beam melting (EBM: English for "Electron Beam Melting" ).

To display a component, for example by means of SLM, a powder bed is exposed by means of a laser beam in accordance with a predetermined exposure geometry, wherein the data can be generated from a 3D file. In a first

Step, the workpiece or component is divided into individual layers. In a second step, the tracks or vectors are generated for each layer, which moves off the laser beam. Is a powder layer is exposed, the Component platform is lowered and a new layer of powder is applied by means of ei ^¬ nes slider, for example a rake, and then again exposed to the laser which melts the powder and can solidify. Frequently in the additive Manufacturing the workpiece using common computer-aided designs or CAD (English for "Computer Aided Design") designed and especially in 3D constructions of relevant material parameters often simulated by finite element analysis (FEA).

Furthermore, through CAM technology (English for "Computer Aided Manufacturing") completely dispensed with the use of technical drawings.

Further, in the SLM process often supporting structures must be used to obtained for example overhangs in the workpiece support to a production substrate or on a component ^¬ platform during the manufacturing process and / or the heat me of the laser beam used to melt the powder discharge. On the other hand, it is possible to dispense with support structures for particularly small parts to be manufactured in an additive manner, since heat removal is not such a big problem. Since the workpieces are preferably materially connected by means of the melting process (compare SLM and EBM process) with a component sub ^¬ substrate, the workpieces must be separated by the additive structure by complex mechanical or machining operations again from the substrate. As an alternative to this, it is also possible to resort to breakage structures ("easy-to-break" structures), in which case the workpiece can be separated from the substrate again by breaking or applying force after assembly

Plastics, ceramic workpieces or metallic workpieces such as turbine components, in particular parts in the hot gas path of gas turbines, offers a lot of ^¬ number of advantages in terms of manufacturing and the repair of these workpieces. Of particular importance in connection with the actual additive structure is also the processing or the handling of the design data, the simulation and the modeling of the corresponding construction partial geometry. For example, the modeling of the above-mentioned complicated fracture structures proves to be particularly complicated in CAD design. It is therefore an object of the present invention to provide means by which the stated problems can be solved and a corresponding construction and / or additive production of the workpieces can be improved. This object is achieved by the subject matter of the independent claims to ^¬. Advantageous embodiments are the subject of the dependent claims.

One aspect of the present invention relates to a method for modeling a contact structure or a modeling method in the computer-aided design.

The computer-aided design can be referred to herein as a CAD and / or CAM method. The construction mentioned herein refers to an additive near, ^¬ alternate workpiece. The contact structure is or is preferably formed so that it acts as a strong connection between the substrate and the workpiece to be produced during manufacture.

In one embodiment, the method is preferably feasible with a data processing device.

The method comprises detecting a construction area for the workpiece to be manufactured additively or its construction on a substrate or model substrate.

The model substrate is preferably a computer-aided constructed and / or modeled substrate which is intended to simulate a real substrate or its properties as accurately as possible, for example by means of FEA. The construction area preferably describes a region of a base area of the workpiece to be produced and / or a corresponding model. The construction area preferably designates the area of the workpiece to be produced additively, which is connected or connected directly to the substrate for the additive construction.

The method further includes detecting design parameters for the workpiece to be additively manufactured.

In one embodiment, the design parameters comprise material information about the materials as well as the material properties of the workpiece to be produced additively and / or of the substrate.

The method further includes creating and / or computing at least one geometry for the contact structure in the design area and depending on the design parameters. Here, the virtual geometry comprise a 3D model and / or other indication that play, a user or a person who carries out the method described can be displayed at ^¬.

The said at least one geometry is calculated in such a way that a workpiece produced additively on a real substrate corresponding to the model substrate can be separated from the substrate by cutting, for example mechanical and / or manual cutting. For this purpose, the contact ^¬ structure, for example, comprise one or more predetermined breaking points.

The at least one geometry of the contact structure is wei ^¬ terhin calculated such that a connection between the substrate and the subsequent additive workpiece to be produced stresses which arise during manufacture, resists, and wherein the user due to the calculation of at least one geometry continues to a signal is warranted if a connection between the substrate and the workpiece to be produced additively, due to the choice of the construction area and / or the design parameters and / or due to the geometry parameters that may have been edited or changed by the user.

Accordingly, after a change or input of the user with regard to the geometry parameters, a renewed modeling of the contact structure may be expediently necessary and carried out by the described method.

The workpiece is preferably constructed on the model substrate, and especially directly on the contact structure.

Said dicing preferably designates manual breaking or otherwise dicing without machining or machining.

By means of the described method, it is advantageously achieved to specify a contact structure which has been modeled automatically, without the need for "manual" modeling, for example individual contact structure elements - piece of the substrate.

A further aspect of the present invention relates to a computer-readable, preferably non-volatile medium or storage medium comprising executable program instructions which are suitable for having a data processing device carry out the following steps:

Detecting a construction area for the additive forth ^¬ presentation end workpiece on the substrate or Modellsub ^¬ strat,

Acquisition of design parameters for the additive to be produced workpiece and Creating at least one geometry for the contact ^¬ structure in the construction area and in dependence of the design parameters, wherein the at least one geometry is calculated such that an on a model corresponding to the substrate substrate additively manufactured ^¬ tes workpiece can be separated by dividing the substrate ,

In one embodiment, the at least one geometry for the contact structure is calculated such that the geometry has a multiplicity of geometric elements for a plurality of contact structure elements of the contact structure. By this configuration, a ^¬ expedient ssige contact structure can be formed particularly advantageous.

In one embodiment, each contact structure element is connected via a contact surface with the substrate and / or the Modellsub ^¬ strats. According to the nomenclature chosen the geometry in the model thus corresponds to the contact structure in the real or physical world and geometry elements corresponding to the structural elements con ^¬ tact. In one embodiment, the contact surfaces are rectangular square, polygonal, circular and / or oval shaped.

In one embodiment, the sum of the surface areas of the contact surfaces by a multiple, for example, the fivefold, tenfold or twentyfold, smaller than a Flächenin ^¬ halt the design area. Through this design it ^¬ enables the contact structure particularly expedient according to the ^¬ trägliche peeling or separating the workpiece from the substrate. In one embodiment, the geometry for the contact ^¬ structure is calculated such that the contact structure elements or their side surfaces each have an angle of greater than or equal to 45 ° with a surface of the substrate and / or the Include model substrates. Preferably, all of the said side surfaces of the contact structure elements form said angle with the substrate surface. In one embodiment, a multiplicity of different geometries are calculated for different contact structures. This embodiment, for example, allows a user to make a choice about the modeled geometries. In one embodiment, the various geometries are subsequently output to a user and / or displayed, that is, after the calculation, whereby the user can choose between the different geometries, for example, depending on the requirement of the workpiece or component.

In one embodiment, the at least one geometry of the contact structure is output after calculating a user and / or displayed, said geometry parameters, such as the example ^¬ example dimensions of the geometric elements and / or the contact structural elements of the user subsequently, that is after the calculation, edited, and / or can be changed.

In one embodiment, in the calculation of the at least one geometry, stresses between the workpiece and the substrate, which arise during production of the workpiece to be produced additively, are calculated by means of a finite element analysis (FEA). In particular, residual stresses can be calculated by means of the mentioned FEA and / or limit values for the area of the contact areas described above can be calculated.

Another aspect of the present invention relates to an additive manufacturing method of a workpiece comprising the method described for modeling the contact structure. The additive manufacturing method further includes computer assisted designing of the additively manufactured workpiece and additive fabrication of the workpiece on the substrate from the modeled contact structure. Furthermore, the additive manufacturing method may include compiling a numerical control program (CAM) after the computer aided design. The additive production of the workpiece can furthermore be carried out with the additive manufacturing method, for example by means of SLM, on the basis of the CAM data.

In one embodiment, after the additive fabrication, the workpiece is separated from the substrate by dicing, or the additive fabrication is separated from the substrate.

In one embodiment, the contact structure is initially, that is, prepared additive prior to the actual manufacture or additive-up construction of the workpiece or after constructing the herzustel ^¬ lumbar workpiece.

In one embodiment, the production of the workpiece preferably takes place directly on the contact structure.

In one embodiment, the method described is a software module for a construction method for the additive production of a workpiece or component. Another aspect of the present invention relates to

Workpiece or component which is manufactured or producible with the described additive manufacturing process.

Embodiments and / or advantages which in the present case relate to the method for modeling and / or the additive manufacturing method can likewise relate to the computer-readable medium and vice versa.

In the exemplary embodiments and figures, the same or equivalent components in each case with the same reference sign ^¬ may be provided. The illustrated elements and their proportions with each other are basically not to be regarded as true to scale, but rather individual elements, be such as layers, components and areas for Besse ^¬ ren illustration and / or better comprehension exaggerated thick or large dimensions. FIG. 1 schematically indicates at least parts of a method for modeling a contact structure in the computer-aided design of a component.

FIG. 2 shows a schematic sectional view of a geometry for a workpiece to be produced additively.

Figure 3 shows a schematic sectional view of a con tact ^¬ structure on a workpiece to be additive.

FIG. 4 shows a flowchart of method steps of the

 Method according to FIG. 1

FIG. 1 shows a plan view of a geometry for a contact structure (compare reference numeral 6 in FIG. 2 or 3). The geometry comprises a large number of geometric elements 2, preferably for modeling, a multiplicity of contact structure elements (cf., reference numeral 7 in FIG. 3) of the contact structure. The square geometry elements 2 have a dimension a. Alternatively, the geometry elements 2 may have a rectangular shape (see FIG. Dashed Li ^¬ nien) also having dimensions a and b. Without this being explicitly marked in the drawings, the Geomet ^¬ RIE and / or the contact structure of additional forms, examples of play have circular, oval or polygonal shapes.

Said contact structure serves to illustrate a method for modeling the contact structure in the computer-aided design of an additively produced workpiece 100 ^λ (see dashed edge and FIGS. 2 and 3). The geometry is surrounded by a construction area 4. The geometry of elements 2 are all arranged in the Konstruktionsbe ^¬ rich. 4 The construction area 4 preferably designates an area on a model substrate 1 ^λ via which the workpiece in the computer-aided design, for example by means of CAD, for a subsequent additive manufacturing process of the workpiece 100 is connected to or produced on a substrate (see reference number 1 in FIG can. The substrate then preferably corresponds to the model substrate 1 ^{λ of} the design or CAD model.

When SLM process, the workpiece is, for example, material ^¬ positively and / or metallurgically bonded to the substrate.

The multiplicity of geometric elements 2 from FIG. 1 preferably represent a data model for a plurality of contact structure elements 7 (compare reference numeral 7 in FIG. 3) for the contact structure. Each of the contact structure elements 7 is preferably connected via a contact surface 3 to a substrate (cf. FIGS. 2 or 3) ) connected.

Furthermore, a workpiece region 5 is indicated by way of example in FIG. The workpiece area 5 marks a possible dimension or contour of the workpiece to be produced additively

100 ^λ . The construction area 4 is located in the position shown supervision, for example, completely within the Werkstückbe ^¬ Reich 5. Figure 2 shows a schematic sectional or side view of a model example of a construction model of the additive produced workpiece 100 ^λ or the workpiece 100. additive made with reference to FIGS 1 and 2 is, for example, to recognize that the sum of the areas of the contact surfaces 3 from ^¬ preferably by a multiple, for example, five times, ten times, twenty times or is even smaller than the Area of the construction range 4. This allows the special ^¬ that an additive produced work piece ^{¬ λ} 1 can be separated after its preparation or construction easy again from the substrate 1.

Appropriate surface areas or dimensions of the Kontaktflä ^¬ chen one skilled either known or will be apparent to him without an inventive step using a Konstrukti ^¬ onsprogramms and / or a finite element analysis of the standard of the art.

The contact structure 6 is provided for a subsequent, ie after the additive production, simple detachment of the workpiece 100 from the substrate 1. Of the individual geometrical rieelemente 2 and contact structure elements 7 are set breaking ^¬ or breaks defined or provided wel ^¬ che simply manually and / or broken by the action of force, for example, according to the additive preparation and the additive prepared workpiece in order to share, for example, by decomposition , can be easily separated from the substrate 1.

This technique provides at least for relatively small additive produced workpieces, such as burner nozzles of gas turbines, an advantage such that the substrate can be dispensed with consuming zerspa ^¬ designating machining processes for dissolving or separating the factory ^¬ tee 100 at least largely. The contact structure 6 is arranged or modeled on the substrate 1.1 ^λ . The workpiece 100 ^{λ to be produced in part} is arranged or modeled on the substrate 1.1 ^λ and directly on the indicated contact structure 6. The contact structure 6 comprises serrated, toothed or triangular contact structure elements 7. The individual Kon ^¬ clock structural elements 7 have a vertical or vertical side surface and a relatively inclined to a vertical side surface 8. The said inclined side surfaces 8 preferably each include an angle greater than or equal to 45 ° with a surface of the substrate 1.1 ^λ .

Notwithstanding the representations of FIGS. 2 and 3, all side surfaces 8 of the contact structure elements 7 may have an inclination to the vertical.

Such a configuration is particularly advantageous for the additive fabrication of the workpiece 100, 100 as beispielswei- se contact structure elements, which include a smaller angle with the substrate surface, bad, or can hardly be addi tive ^¬ manufactured. The reasons for this can be too poor heat dissipation and / or poor support in the powder bed, for example in the SLM process.

For those areas of the workpiece 100, which - according to the individual geometry of the component - in any case an acute angle, ie an angle equal to or greater than 45 °, with the substrate or its surface, preferably no separate contact structure needs to be ^¬ modeled ,

FIG. 3 shows a schematic sectional or side view of a workpiece 100 which is produced additively on the contact structure 6 or has been or can be produced. Furthermore, the workpiece area 5 is shown in FIG. The workpiece area 5 is the real dimension of the workpiece 100. On the right edge of the workpiece 100 is shown a region thereof for which no contact structure has been modeled, since this area was not intended for direct contact with the substrate 1 , Only those surfaces or parts of the workpiece 100, which are to be connected directly and / or cohesively to the substrate, are provided by the described method with a contact structure or modeled accordingly. By way of example, an angle is again drawn in which, as described above, is preferably also greater than or equal to 45 ° for all contact structure elements 7. FIG. 4 shows a schematic flow diagram of an additive manufacturing method which comprises the described method for modeling the contact structure.

The method for modeling the contact structure 6 comprises in a first method step VI the detection of a

Construction area 4 for the additive to be produced ^¬ piece on a model substrate 1 ^λ .

Furthermore, the method for modeling, preferably in a second method step V2, comprises detecting

Construction parameters for the additive to be produced workpiece. The consumption parameters are preferably material ^parameters for the substrate and / or the workpiece 100, 100 ^{λ to be} produced additively. For example, the design parameters include information about the corresponding materials. The design parameters may in particular be the (material-dependent) coefficient of thermal expansion, the thermal conductivity, the heat capacity, the mass density, the modulus of elasticity or further parameters of the substrate 1 and of the workpiece 100, 100 ^λ . Furthermore, the design parameters may include process parameters of any kind.

The method for modeling the contact structure 6 furthermore comprises-in a method step V3-the creation of the described geometry in the design area 4 as a function of the said design parameters. The geometry is preferably calculated such that a on a corresponding model substrate substrate additive manufactured notified workpiece 100 ^λ as indicated above by dividing, ie manual breaking and can be separated subsequently without machine Be ^¬ processing of the substrate 1 preferably. According to the described method for modeling the contact structure 6, a multiplicity of different geometries are calculated for different contact structures 6 and the different geometries are subsequently output or displayed to a user. Preferably, the user can then choose between the different geometries (see method step V4). Preferably, the user may also choose between various geometry parameters which may be output or displayed to the user or a user as part of the computation or modeling of the contact structure 6. For example, the user can edit and / or modify these geometry parameters (compare dimensions a, b in FIG. 1), for example to correspond to individual requirements of the component.

The geometry or the variety of geometries for the contact structure is preferably calculated in such a way within the framework of the method for modeling, that a connection between the substrate and the subsequent additive workpiece to be produced (compare Figure 2) voltages that arise during the herstel ^¬ lung withstand. These voltages can be typical thermo-mechanical stresses, wel ^¬ che occur for example, when SLM process by the large temperature gradients ^¬ (eg. 1000 K / s and more). The tensions arise in particular due to the rapid Aufhei ^¬ zen and the rapid subsequent solidification of the built-up material.

If the said connection is due to an input or selection of the design area, due to the choice of

Design parameters and / or due to the optionally edited by the user or user of the method or changed geometry parameters, can be issued by the described method advantageously a warning to the user (see method step V4). As a result, at least the calculation of the Modeling process or the entire process performed again.

The voltages mentioned are preferably calculated and / or simulated using finite element analysis (FEA). This can be done by means known to those skilled in the prior art. In particular, residual stresses of the component can be calculated, for example, with a lower limit value for the surface area of the contact surfaces 3 by means of FEA (method step V4).

The process steps described under V4, hinted ^¬ tet by dashes in the figure, preferably as advantageous or optional and not necessarily to be considered essential.

The method of modeling further comprises the additive manufacturing method described with reference to method steps V5, V6 and V7:

Process step V5 refers to the computer-aided Kon ^¬ struieren the additive workpiece to be produced, preferably after, under the method for modeling, which has been created at least a geometry for the contact structure 6 and / or calculated. Further comprising additive Her ^¬ approval process, for example. In step V6, the addi ^¬ tive manufacturing the workpiece 100, 100 ^λ on the substrate 1 by means of the modeled contact structure 6. Before additive production of the workpiece 100 100, the contact structure 6 preferably also produced additively.

Furthermore, the additive manufacturing method preferably comprises separating the workpiece and or the component from the substrate by dicing or manual breaking (method step V7).

The present invention further comprises a computerles ^¬ bares medium such as a storage medium, such as a Hard disk and / or another data memory comprising executable program instructions, which are suitable, a data processing device (not explicitly marked here) the described steps, that is, the described ^¬ capturing the design area 4 and the design parameters and creating the at least egg nen geometry, to have carried out.

Claims

claims 1. A method for modeling a contact structure (6) in the computer-aided construction of a additive herzu- alternate workpiece (100), said method comprising the ^¬ follow the steps of: Detecting a construction area (4) for the workpiece (100) to be produced additively on a model substrate (1), Detection of design ^parameters for the additive to be produced workpiece (100 ^λ ) and Create at least a geometry for the contact ^¬ structure (6) in the construction area (4) and as a function of the design parameters, the Minim ^¬ least a geometry is calculated such that on a model substrate (1 ^λ) corresponding substrate ( workpiece additive prepared 1) (100) by cutting of the substrate (1) can be separated with the Any artwork least a geometry of the contact structure (6) in such a way be ^¬ calculated is that a connection between the substrate (1) and the subsequent workpiece (100) to be produced in an additive manner and with the user being warned of a signal due to the calculation of the at least one geometry when a connection is made between the substrate (1) and the workpiece to be produced thereon ( 100 ^λ ) the resulting during the additive manufacturing voltages due to the choice of the construction area (4) and / or Konstrukti on parameters does not withstand. 2. The method of claim 1, wherein said at least one geo ^¬ geometry for the contact structure (6) is calculated such that the geometry comprises a plurality of primitives (2) for a plurality of contact structure elements (7) of the contact structure (6), and wherein each contact structure element (7) via a contact surface (3) with the substrate (1) is connected. 3. The method of claim 2, wherein the contact surfaces (3) are rectangular, square, polygonal, circular and / or oval shaped. 4. The method of claim 2 or 3, wherein the sum of the surface areas of the contact surfaces (3) is smaller by a multiple than an area of the construction area (4). 5. The method according to any one of claims 2 to 4, wherein the at least one geometry for the contact structure (6) is calculated in such a way that the contact structure elements (7) each enclose an angle () of greater than or equal to 45 ° with a surface of the substrate (1). A method according to any one of the preceding claims, wherein a plurality of different geometries are calculated for different contact structures (6) and the different geometries are subsequently output to a user, and wherein the user can choose between the different geometries. 7. The method according to any one of the preceding claims, wherein the at least one geometry of the contact structure (6) is output after calculation to a user and wherein geometry parameters can be edited by the user subsequently. 8. The method according to any one of the preceding claims, wherein in the calculation of the at least one geometry voltages which occur during manufacture of the additive to be produced workpiece (100 ^λ ), are calculated by means of a finite element analysis. 9. The method according to any one of the preceding claims, wherein the design ^parameters material information of the additive to be produced workpiece (100 ^λ ) and material information of the substrate (1). 10. An additive manufacturing method of a workpiece (100), comprising the method of modeling according to one of the preceding claims, further comprising the following steps: computer-aided design of the additive to be produced ^¬ lenden workpiece (100 ^λ ), additive manufacturing the workpiece (100) on the sub strate ^¬ based on the modeled contact structure (6). 11. The additive manufacturing method according to claim 10, wherein after the additive production, the workpiece is separated from the substrate by dicing. 12. An additive manufacturing method according to claim 10 or 11, wherein the contact structure (6) is first produced additively and the preparation of the workpiece (100, 100 ^λ ) on the contact structure (6). To allow to perform the following steps 13. The computer-readable medium comprising executable program instructions ^¬ suitable data processing device ^¬: Detecting a construction area (4) for the additive-to-be-fabricated workpiece (100 ^λ ) on a model substrate (1 ^λ ), Detection of design ^parameters for the additive to be produced workpiece (100 ^λ ) and Creating at least one geometry for the contact structure (6) in the construction area (4) and depending on the design ^parameters , wherein the at least one geometry is calculated such that a substrate (1) corresponding to the model substrate (1 ^λ ) is made additive Workpiece (100) can be separated by dicing from the substrate (1).