EP3973433A1

EP3973433A1 - Method and device for predicting and/or reducing the deformation of a multipart assembly

Info

Publication number: EP3973433A1
Application number: EP20718640.4A
Authority: EP
Inventors: Michael Fleischer; Sebastian ROESEL
Original assignee: Bayerische Motoren Werke AG
Current assignee: Bayerische Motoren Werke AG
Priority date: 2019-05-23
Filing date: 2020-04-09
Publication date: 2022-03-30
Also published as: US20220318461A1; CN113543929A; DE102019113805A1; DE102019113805B4; WO2020233900A1

Abstract

The invention relates to a device for predicting and/or reducing deformation of an assembly (110) that is caused during the production of at least one weld seam (203) for connecting a first component (201) and a second component (202) of the assembly (110). The device is designed to determine an FE model (310) of the assembly (110), wherein the FE model (310) comprises a number of FEs (311) for the weld seam (203) and a number of FEs (311) for the first and second components (201, 202). The device is also designed to bring about a spatial contraction of the number of FEs (311) for the weld seam (203), and to determine an effect of the spatial contraction on the number of FEs (311) for the first and/or the second component (201, 202). The device is also designed to predict a spatial deformation of the first component (201) and/or the second component (202) on the basis of the effect on the number of FEs (311) for the first and/or the second component (201, 202).

Description

Method and device for predicting and / or reducing the deformation of a multi-part assembly

The invention relates to a method and a corresponding device that make it possible to predict and / or reduce the geometric distortion of an assembly that consists of several construction parts that are connected to one another via one or more welds.

A vehicle typically has different multi-part assemblies in which at least two components are connected to one another via one or more linear weld seams. For example, a relatively stable structural component for a vehicle can be produced using one or more

Welds are connected to a relatively easily deformable outer skin component, the outer skin component forming the outer shape of the vehicle door. As part of the welding process for connecting the two components, a geometric distortion can be caused, which leads to visible deformations on the outer skin component.

Deformations that arise when creating weld seams are typically only recognized at a relatively late stage in the development of an assembly and / or can only be predicted for the assembly using relatively complex thermomechanically coupled models.

The present document is concerned with the technical task of being able to recognize and / or avoid or reduce deformations that are caused when a multi-part assembly is welded together at an early stage and / or in an efficient manner. The problem is solved by the independent claims. Advantageous embodiments are described, inter alia, in the dependent claims. It is pointed out that additional features of a patent claim dependent on an independent patent claim without the features of the independent patent claim or only in combination with a subset of the features of the independent patent claim can form a separate invention independent of the combination of all features of the independent patent claim which can be made the subject of an independent claim, a divisional application or a subsequent application. This applies equally to the technical teachings described in the description, which can form an invention that is independent of the features of the independent patent claims.

According to one aspect, an apparatus (e.g., a computer and / or a server) for predicting and / or reducing the deformation of a multi-part assembly is described. In particular, the device is designed to predict and / or reduce the deformation of the assembly that is brought about when at least one weld seam is produced to connect a first component and a second component of the assembly. In other words, the device can be designed to predict and / or reduce the deformation of a multi-part assembly caused during a welding process (in particular a laser welding process and / or a tactile and / or remote welding process). The aspects described in this document can generally be applied to welding processes in which a linear and / or elongated weld seam is herge between two components. The device described in this document can be part of a CAD (Computer Aided Design) system.

The first component can have a relatively high rigidity and the second component can have a relatively low rigidity. In other words, the second component can be deformed relatively easily in comparison to the first component his. The second component can for example consist of a relatively thin sheet metal (for example with a thickness or strength of 0.5 cm or less). In one example, the assembly is a door or flap (particularly a door or flap of a vehicle). The first component can form a load-bearing structure of the door or flap and the second component can form an outer skin of the door or flap.

The device is set up to determine and / or provide a finite element (FE) model of the assembly. The FE model includes a set of FEs for the weld seam and a set of FEs for the first and second component. The weld seam can extend linearly between the first component and the second component (e.g. along an edge of the first component and along an edge of the second component). The weld seam can have a length that is significantly (in particular by a factor of 5 or more, 10 or more or 50 or more) greater than the thickness and / or the width of the weld seam. The FE model can describe the full and / or the entire weld seam right at the start of a simulation. The set of FEs for the (entire) weld seam can then comprise a line-shaped series of FEs corresponding to the weld seam. An FE model can thus be provided for the assembly which (already at the beginning of the simulation) has a set of FEs for the entire weld seam between the first component and the second component.

The individual FEs of the FE model typically each have a certain spatial extent (eg as a three-dimensional cuboid or bar). Furthermore, an FE typically includes a mechanical (mathematical) model that describes how a force applied to an edge of the FE affects the spatial expansion of the FE. Adjacent FEs are typically mechanically coupled to one another, so that a change in the spatial expansion of an FE causes a force on a directly adjacent FE, which in turn can cause a change in the spatial expansion of the directly adjacent FE. An FE model can be provided in a basic state in which the first component and the second component have the shape that the first component and the second component had before the welding process, ie before the production of the

Weld seam. In the basic state, the FE model already includes the entire weld seam between the first component and the second component. The FE model for the (entire) weld seam can then have FEs that connect the FEs of the (undeformed) first component with the FEs of the (undeformed) second component. In this case, in the basic state, preferably no forces are brought about by an FE for the weld seam on an FE of the first and / or the second component. This preferably applies to all FEs of the weld seam.

The device can be set up to cause a spatial contraction of the set of FEs for the weld seam. In other words, within the framework of a simulation, the spatial extent of the FEs for the weld seam (in particular along the start of the weld seam) can be reduced. In this case, a spatial contraction can be brought about by a specific contraction factor (in order to ensure that the weld seam, starting from the basic state, has a catch that is reduced by the contraction factor). The contraction factor can be applied to the individual FEs of the set of FEs for the weld. In particular, the spatial contraction can be evenly distributed over the set of FEs for the weld seam.

The device is also set up to determine and / or simulate the effect of the spatial contraction of the amount of FEs for the weld seam on the amount of FEs for the first and / or the second component. The contraction can be brought about gradually (for example on a sequence of time steps) in order to gradually determine and / or simulate the progressive effects (for example on the sequence of time steps). The spatial contraction of the FEs for the weld seam typically brings about forces on individual FEs of the first component and / or the second component. These forces in turn lead to a change in the spatial extent of the individual FEs of the first component and / or of the second component. These changes and / or effects on the individual FEs can be determined in the context of an FE simulation.

Furthermore, the device is set up to predict the spatial deformation of the first component and / or the second component on the basis of the effect on the set of FEs for the first and / or the second component. In particular, one or more points can be predicted at which the first and / or the second component will deform as a result of the production of the at least one weld seam.

The device enables the effects of the production of a weld seam to be predicted in an efficient manner (without using a thermomechanical model and / or without taking into account parameters with respect to the welding process and / or with respect to the welding tool) and, based on this, reduce them . The cost of a multi-part assembly can thus be reduced and the quality of the assembly produced can be increased.

In particular, the device described does not carry out a progressive build-up of the weld seam in order to simulate the production of the weld seam analogously to reality. For an FE simulation from the start of the FE simulation, the device uses an FE model of the assembly that already includes a set of FEs for the entire weld seam. In other words, the amount of FEs for the weld seam can already be used at the beginning of an FE simulation to determine the effect of the spatial contraction on the amount of FEs for the first and / or the second component, the entire weld seam between the first component and the second component describe (as they actually do should be produced). In this way, the complexity of the simulation can be significantly reduced.

Furthermore, the described device typically does not use any data relating to a welding system and / or tool and / or relating to the kinematics of the welding system and / or the welding tool that relate to the real assembly process of the assembly influence. Instead, the effects of the welding process are simulated in an efficient manner (possibly alone) by contraction of the FE model of the entire weld seam between the first component and the second component.

The device can be set up to determine one or more (reference) properties of the first component and / or of the second component. Exemplary (reference) properties are: the material of the first component and / or of the second component, and / or the material thickness of the first component and / or of the second component.

The extent of the contraction to be induced, in particular the contraction factor for the contraction of the weld seam, can then be determined in a precise manner based on the one or more reference properties of the first component and / or of the second component. In particular, the extent of the contraction to be caused can be determined on the basis of predetermined characteristic data, the characteristic data for a plurality of combinations of different one or more reference properties of a first reference component and / or a second reference component each being an extent of the con to be initiated show traction. The characteristic data can, for example, have been determined in advance using (thermomechanical) simulations and / or on the basis of measurements on actual assemblies. By determining the extent of the contraction and / or a contraction factor on the basis of predetermined characteristic data and / or on the basis of (reference) properties of the first and / or the second component, the deformation of the assembly can be predicted in a particularly precise manner and / or be reduced.

The device can be set up to iteratively and / or repeatedly adapt the first and / or the second component (in particular the FE model of the first and / or the second component) (in particular with regard to the shape and / or the used Material). The deformation can then be repeatedly predicted.

Thus, the first component and / or the second component can be adapted iteratively and / or repeatedly in order to produce an assembly with a reduced amount of deformation.

In particular, the device can be set up to repeatedly adapt the FE model of the assembly for the first component and / or for the second component, in order to determine an adapted FE model in each case. In particular, the device can be set up to adapt the geometric shape and / or a material property (e.g. the material thickness) of the first component and / or the second component in order to determine the adapted FE model.

A spatial contraction of the set of FEs for the weld seam of the respectively adapted FE model can then be initiated, and the effect of the spatial contraction on the set of FEs for the first and / or the second component of the adapted FE model can be initiated be determined. Furthermore, the extent of the spatial deformation of the first component and / or of the second component can be determined based on the effect on the set of FEs for the first and / or the second component of the respectively adapted FE model. The repeated adaptation of the FE model can be used to determine an optimized, adapted FE model for which the extent of the spatial deformation of the first component and / or of the second component is smaller than a predetermined deformation threshold value.

Furthermore, the device can be set up to provide design data for the optimized, adapted FE model of the assembly, the design data making it possible to manufacture the first component and / or the second component. In other words, the optimized, adapted FE model can be used to manufacture the first component and / or the second component. In this way, it can be ensured in a reliable manner that the assembly produced by welding the first and second component has a reduced amount of deformation.

According to a further aspect, a (computer-implemented) method for predicting and / or reducing the deformation of an assembly is described, which is brought about when producing at least one weld seam to connect a first component and a second component of the assembly. In particular, the deformation of the (relatively easily deformable) second construction can be partially predicted and / or reduced.

The method comprises providing an FE model of the assembly, the FE model comprising a set of FEs for the weld seam and a set of FEs for the first and second component. The method also includes causing the set of FEs for the weld to contract spatially. The contraction can take place along the longitudinal direction of the weld seam. As an alternative or in addition, the contraction can take place transversely and / or radially to the longitudinal direction of the weld seam. The method further includes simulating the effect of the spatial contraction on the set of FEs for the first and / or the second component. In particular, the effects on the spatial extent of the set of FEs for the first and / or the second component can be determined. In addition, the method comprises predicting the spatial deformation of the first component and / or the second component based on the simulated effect on the set of FEs for the first and / or the second component.

According to a further aspect, a software (SW) program is described. The software program can be set up to be executed on a processor (e.g. on a computer or server) and thereby to execute the method described in this document.

According to a further aspect, a storage medium is described. The storage medium can comprise a SW program which is set up to be executed on a processor and thereby to execute the method described in this document.

It should be noted that the methods, devices and systems described in this document can be used both alone and in combination with other methods, devices and systems described in this document. Furthermore, any aspects of the methods, devices and systems described in this document can be combined with one another in a variety of ways. In particular, the features of the claims can be combined with one another in diverse ways.

The invention is described in more detail below with the aid of exemplary embodiments. Show it

FIG. 1 shows an exemplary vehicle with a multi-part assembly;

FIG. 2a shows a multi-part assembly in a front view;

FIG. 2b shows a multi-part assembly in a side view; FIG. 3a shows an exemplary finite element model of a multi-part assembly; FIG. 3b shows an exemplary finite element; and

FIG. 4 shows a flow chart of an exemplary method for predicting and / or avoiding or reducing deformations in the production of a multi-part assembly.

As stated at the beginning, the present document deals with the efficient and early prediction and, if necessary, avoidance or reduction of deformation in the manufacture of a multi-part assembly by means of a welding process. In this context, FIG. 1 shows a vehicle 100 with a vehicle door 110 as an example of a multi-part assembly. Furthermore, FIG. 2a schematically shows a multi-part assembly 110 in a front view (on the surface of the multi-part assembly 110) and FIG. 2b in a side view (on the edge between the different components 201, 202 of the assembly 110). The multi-part assembly 110 can have an area of 0.5 m ² or more, for example.

The assembly 110 comprises a first component 201, e.g. is designed to bring about the mechanical stability of the assembly 110 (at least to a substantial extent). The assembly 110 further comprises a second component 202, e.g. is designed to effect a decorative and / or shaping task of the assembly 110. In the case of a vehicle door as an assembly 110, e.g. the second component 202 form an outer skin of the vehicle door. The first component 201 can be made relatively stiff, while the second component 202 can be relatively easily deformable (e.g. due to the use of a relatively thin sheet metal).

The first component 201 and the second component 202 can be connected to one another at one or more (elongated) edges. For example, the first component 201 and the second component 202 can be tilted and / or pressed together at an edge 204. Alternatively or in addition, the first Component 201 and the second component 202 can be welded to one another at one or more edges by linear welds 203 (for example by using a laser welding method and / or by using a tactile and / or remote welding method). For example, a weld 203 can be arranged on two or more edges of the assembly 110.

The connection of the two components 201, 202 by one or more linear and / or elongated weld seams 203 can lead to tension within the construction group 110, the tension particularly in the second construction part 202 causing deformations. The stresses can in particular be caused by the thermal influences during the production and cooling of the weld seams 203. The stresses and deformations caused thereby can, if necessary, be predicted by specific measurements on prototypes of the component 110 and / or by using complex thermomechanical simulation models.

The individual components 201, 202 of an assembly 110 can be described by a finite element (FE) model 310, as shown by way of example in FIG. 3a Darge. In particular, Fig. 3a shows an FE model 310 for a section of the component 110. The first component 201 and the second component 202 are each described by a set of adjacent finite elements 311, which e.g. each a (three-dimensional) bar or cuboid structure can aufwei sen. In other words, the volume of the individual components 201, 202 can be described by a two- or three-dimensional stringing together of FEs 311.

Each individual FE 311 can (as illustrated in Fig. 3b) a plurality of parameters, in particular of geometric parameters 321, 322 to describe the spatial extent of the FEs 311 and / or of mechanical Para meters 331, 332 to describe mechanical forces and / or voltage gen within FE 311. Furthermore, an FE 311 can comprise a mathematical and / or mechanical model that describes how mechanical forces and / or stresses at the edges of the FE 311 affect the spatial extent of the FE 311 and / or vice versa. Adjacent FEs 311 can interact with one another via adjacent edges.

The FE model 310 can also include FEs 311 for modeling the one or more weld seams 203 for connecting the first component 201 to the second component 202. The FE model 310 of a weld 203 can e.g. comprise a (possibly one-dimensional) series of FEs 311. The FE model 310 of a weld 203 is connected at a first (longitudinal) edge to the FE model 310 of the first component 201 and at an opposite second (longitudinal) edge to the FE model of the second component 202, in this way that a change in a parameter 321, 322, 331, 332 in an FE 311 of the weld seam 203 can affect a parameter 321, 322, 331, 332 in an FE 311 of the first component 201 and / or the second component 202.

In the basic state of the FE model 310, it may be assumed that the FEs 311 of a weld 203 do not cause any forces and / or stresses 331, 332 on adjacent FEs 311 of the first component 201 and / or the second component 202.

The effects of the welding process on a multi-part assembly 110 can be simulated using the FE model 310 of the assembly 110. In particular, it can be made that the FE model 310 is a

Weld 203 contracts by a certain contraction factor (along the length of weld 203 and / or transversely to weld 203). For this purpose, the spatial extent 321 of the FEs 311 of the FE model 310 of the weld seam 203 (in the longitudinal direction and / or transverse to the longitudinal direction) can be reduced by the determined contraction factor. The contraction factor can be determined in advance by measurements and / or by thermal mechanical simulations. In particular, a first reference component with one or more first reference properties and a second reference component with one or more second reference properties can be connected to one another via at least one weld seam. Examples are reference properties

• the material of a component;

• the thickness or the strength of a component; and

• the modulus of elasticity of a component.

Characteristic data (e.g. in the form of a look-up table) can then be provided, which each indicate the contraction factor to be used for different combinations of first and second reference components. To determine the contraction factor for a specific assembly 110, the reference properties of the first component 201 and the reference properties of the second component 202 can be determined, and the value of the contraction factor can then be determined from the characteristic data using the reference properties.

The contraction of the FEs 311 of the weld 203 causes changes in the parameters 321, 322, 331, 332 of the FEs 311 of the first component 201 and / or the second component 202 based on the FE model 310 of the assembly 110 in the frame can be determined by an FE simulation. In particular, effects on the geometric parameters 321, 322 of the FEs 311 of the first component 201 and / or of the second component 202 and thus deformations of the first component 201 and / or of the second component 202 can be determined.

It can thus be determined on the basis of an FE simulation whether there is a (visible) distortion in the creation of one or more weld seams 203 or a (visible) deformation of the first component 201 and / or of the second component 202 occurs. If this is the case, the first component 201 and / or the second component 202 (in particular the FE model 311 of the first and / or second component 201, 202) can be changed. For example, a material property (for example the material thickness) and / or the shape of the first and / or second component 201, 202 can be adapted. A contraction of the adapted FE model 310 of the one or more weld seams 203 can then be brought about again in order to detect a possible deformation of the assembly 110. This adaptation process can be repeated iteratively.

By iterative adaptation of the FE model 310 of the first and / or the second component 201, 202, an optimized FE model 310 can be determined for which no or no significant (visible) deformations of the weld seam 203 during the contraction of the one or more weld seams 203 first and / or the second component 201, 202 of the FE model 310. The first and / or the second component 201, 202 and the multi-part assembly 110 can then be manufactured in accordance with the determined, optimized FE model 310. In this way, a multi-part assembly 110 with one or more weld seams 203 can be produced in an efficient and reliable manner, which has no deformations (significant and / or visible to the naked eye).

An assembly 100 can thus be virtually modeled in the initial state (by means of a CAD nominal geometry) before the one or more weld seams 203 are produced. Only the components or parts 201, 202 of the assembly 100 and not those of the system and / or tool components involved in the process are modeled. All weld seams 203 are part of the model 310 (for example, each as a line in the model 310). Data relating to the tools and / or the systems for creating the weld seams 203 are not used. A weld seam 203 can be modeled with finite elements 311 with material data relating to properties of the material of the weld seam 203. To simulate the welding process, the one or more weld seams 203 are mechanically shrunk by a percentage (ie by a contraction factor) in their length (without using heat sources and / or reducing heat). In the context of the simulation, a percentage, temporally distributed, volume shrinkage can be carried out. The shrinkage can be applied in a distributed manner along the elongated extension of a weld seam 203. Such an FE simulation can be used to qualitatively and quantitatively assess the susceptibility of the assembly 110 with regard to the formation of dents and / or with regard to breakdown problems. Furthermore, risk assessments for deformations that can arise from other influences can be carried out.

4 shows a flowchart of an exemplary (computer-implemented) method 400 for predicting and / or reducing the deformation of an assembly 110 which, when producing at least one (linear) weld seam 203 for connecting a first component 201 and a second component 202 the assembly 110 is effected. The weld 203 can e.g. be produced by means of a welding tool, in particular using a laser welding process and / or by using a tactile and / or remote welding process. The method 400 can be carried out by a computer and / or server (e.g. using an FE simulation software program and / or a CAD (Computer Aided Design) software program).

The method 400 includes providing 401 an FE model 310 of the assembly 110, the FE model 310 comprising a set of FEs 311 for the weld seam 203 and at least a set of FEs 311 for the first and second components 201, 202 . The set of FEs 311 for the weld seam 203 can comprise a line-shaped sequence of FEs 311. The FEs 311 of the weld seam 203 can each be connected to at least one FE 311 of the first component 201 and an FE 311 of the second component 202, in particular such that a deformation (in particular a contraction) of an FE 311 of the weld 203 causes a tension and / or a force in an FE 311 of the first component 201 and / or of the second component 202 is effected.

In addition, the method 400 includes causing 402 a spatial contraction of the set of FEs 311 for the weld seam 203. The contraction can take place along the linear expansion of the weld seam 203. In particular, it can be caused that the length of the weld seam 203 is reduced by a certain contraction factor. The reduction in the length of the weld seam 203 can be (evenly) distributed over the individual FEs 311 for the weld seam 203.

The method 400 further comprises simulating 403 the effect of the spatial contraction of the set of FEs 311 for the weld seam 203 on the set of FEs 311 for the first and / or the second component 201, 202. In particular, it can be simulated (by means of an FE Simulation program) which voltages 331, 332 and / or which spatial changes 321, 322 are caused in the individual FEs 311 of the first component 201 and / or of the second component 202.

In addition, the method 400 includes predicting and / or predicting 404 the spatial deformation of the first component 201 and / or the second component 202 on the basis of the simulated effect on the set of FEs 311 for the first and / or the second component 201, 202 .

Using the method 400 described, a prediction can be made in an efficient manner (even without using a model of the welding system and / or the welding process) as to how the welding process will affect the deformation of a multi-part assembly 110. Furthermore can By iterative and / or repeated adaptation of the FE model 310 of the assembly 110, an FE model 310 can be determined in which the contraction of the weld 203 leads to a reduced deformation of the first and / or the second component 201, 202. The first and / or the second component 201, 202 can then be manufactured on the basis of the adapted FE model 310, so that an assembly 101 with reduced deformations can be manufactured.

The present invention is not restricted to the exemplary embodiments shown. In particular, it should be noted that the description and the figures are only intended to illustrate the principle of the proposed methods, devices and systems.

Claims

Expectations

1) Device for predicting and / or reducing a deformation of an assembly (110) which is brought about when at least one weld seam (203) is produced to connect a first component (201) and a second component (202) of the assembly (110); wherein the device is set up

- A finite element, short FE, model (310) of the assembly (110) to determine and / or provide; wherein the FE model (310) comprises a set of FEs (311) for the weld seam (203) and a set of FEs (311) for the first and second component (201, 202);

- to cause a spatial contraction of the set of FEs (311) for the weld seam (203);

- to determine an effect of the spatial contraction on the set of FEs (311) for the first and / or the second component (201, 202); and

- to predict a spatial deformation of the first component (201) and / or the second component (202) based on the effect on the set of FEs (311) for the first and / or the second component (201, 202).

2) Device according to claim 1, wherein

- The weld seam (203) extends linearly between the first component (201) and the second component (202); and

- The set of FEs (311) for the weld seam (203) comprises a line-like sequence of FEs (311) corresponding to the weld seam (203).

3) Device according to one of the preceding claims, wherein the Vorrich device is set up

a spatial contraction to cause a contraction factor; and - to apply the contraction factor to individual FEs (311) of the set of FEs (311) for the weld seam (203); and or

- to distribute the spatial contraction evenly over the set of FEs (311) for the weld seam (203).

4) Device according to one of the preceding claims, wherein the Vorrich device is set up

- to determine one or more reference properties of the first component (201) and / or of the second component (202); and

- An extent of the contraction to be induced, in particular a contraction factor for the contraction of the weld seam (203), based on the one or more reference properties of the first component

(201) and / or the second component (202) to be determined.

5) Device according to claim 4, wherein the one or more reference properties comprise

- A material of the first component (201) and / or of the second component

(202); and or

- A material thickness of the first component (201) and / or of the second component (202).

6) Device according to one of claims 4 to 5, wherein

the device is set up to determine the extent of the contraction to be induced on the basis of predetermined characteristic data; and

- The characteristics for a variety of combinations of different chen one or more reference properties of a first reference component and / or a second reference component each indicate an extent of the contraction to be induced.

7) Device according to one of the preceding claims, wherein the Vorrich device is set up repeatedly, - adapt the FE model (310) of the assembly (110) for the first component (201) and / or for the second component (202) in order to determine an adapted FE model (310);

- to cause a spatial contraction of the set of FEs (311) for the weld seam (203) of the adapted FE model (310);

- to determine an effect of the spatial contraction on the set of FEs (311) for the first and / or the second component (201, 202) of the adapted FE model (310); and

- On the basis of the effect on the set of FEs (311) for the first and / or the second component (201, 202) of the adapted FE model (310), an extent of the spatial deformation of the first component (201) and / or the determine the second component (202);

in order to determine an optimized, adapted FE model (310) for which the extent of the spatial deformation of the first component (201) and / or of the second component (202) is less than a predetermined deformation threshold value.

8) The device according to claim 7, wherein the device is set up to provide construction data for the optimized, adapted FE model (310) of the assembly (110), which requires the manufacture of the first component (201) and / or the second component (202) enable.

9) Device according to one of claims 7 to 8, wherein the device is directed to adapt a geometric shape and / or a material property of the first component (201) and / or of the second component (202) in order to use the adapted FE model ( 310).

10) Device according to one of the preceding claims, wherein the set of FEs (311) for the weld seam (203) already at the beginning of an FE simulation to determine the effect of the spatial contraction on the set of FEs (311) for the first and / or the second component (201, 202) die entire weld seam (203) between the first component (201) and the second component (202) describes.

11) Method (400) for predicting and / or reducing a deformation of an assembly (110) that occurs when at least one weld seam (203) is produced to connect a first component (201) and a second component (202) of the assembly (110 ) is effected; wherein the method (400) comprises,

- Providing (401) a finite element, FE for short, model (310) of the assembly (110); wherein the FE model (310) comprises a set of FEs (311) for the weld seam (203) and a set of FEs (311) for the first and second component (201, 202);

- causing (402) a spatial contraction of the set of FEs (311) for the weld seam (203);

- Simulating (403) an effect of the spatial contraction on the set of FEs (311) for the first and / or the second component

(201, 202); and

- Predicting (404) a spatial deformation of the first component (201) and / or the second component (202) on the basis of the simulated effect on the set of FEs (311) for the first and / or the second component (201, 202) .