DE102005039228A1 - Electronic construction device for motor vehicle, automatically modifies two-dimensional object in processing level based on inputs, and modifies three-dimensional body, such that intersection of modified body with level encompasses object - Google Patents

Abstract

The device has a data memory storing a two-dimensional processing level, a two-dimensional object (14), a motor vehicle construction model with a computer operable three-dimensional body (15). The device automatically displays the object in a computer monitor, modifies the object in the level based on inputs, and modifies the body (15), such that intersection of the altered body with the level encompasses the modified object.

Description

The The invention relates to an electronic construction device.

Out DE 10147558 A1 It is known to completely parameterize a computer-available design model and to change it by changing parameters. This allows the design model to adapt quickly to changes.

In DE 10046742 A1 and WO 02/25502 A1 describes a construction system which operates on a uniform database. On this basis, other design systems, such. B. Calculation programs. The object to be constructed is described by means of parameters and relationships between these parameters. These parameters include geometric parameters of geometric objects.

Of the Invention is based on the object, an electronic construction device to provide editing a computer-accessible three-dimensional Design model of an object easier.

The Task is by a construction device with the features of claim 1. advantageous Embodiments are specified in the subclaims.

• – ein rechnerverfügbares Konstruktionsmodell eines Gegenstandes,
• – mindestens eine rechnerverfügbare zweidimensionale Bearbeitungsebene und
• – mindestens ein rechnerverfügbares geometrisches zweidimensionales Objekt

The electronic design device comprises a data memory, at least one input device and a display device. In this data store are

• A computer-available design model of an object,
• At least one computer-accessible two-dimensional processing plane and
• At least one computer-accessible geometric two-dimensional object

• – Darstellen des zweidimensionalen Objekts mit Hilfe der Anzeigevorrichtung,
• – Verändern des zweidimensionalen Objekts in der Bearbeitungsebene abhängig von Eingaben mit dem Eingabegerät und
• – Verändern des Körpers dergestalt, dass die Schnittmenge des veränderten Körpers mit der Bearbeitungsebene das veränderte zweidimensionale Objekt umfasst.

stored. The design model includes a computer-accessible geometric three-dimensional body. The two-dimensional object lies in the working plane. The intersection of the body with the working plane comprises the two-dimensional object. The construction device is designed to automatically carry out the following steps:

• Displaying the two-dimensional object by means of the display device,
• - Modifying the two-dimensional object in the working plane depending on inputs with the input device and
• - Modifying the body such that the intersection of the changed body with the working plane comprises the modified two-dimensional object.

The Invention shows a way to a three-dimensional design model in one plane, namely editing level. Because a display device, z. B. a screen device, has a two-dimensional representation and interaction level, let yourself accurately edit a two-dimensional object on the display device. This does not apply to the three-dimensional body of the design model. Because the construction device can this body only from a certain viewing direction and thus necessarily only incomplete represent.

The The invention further ensures that the design device changes Automatically tracks the two-dimensional object, d. H. the design model with the body automatically to the changed adapted two-dimensional object becomes.

in the The following is an embodiment the invention described in more detail with reference to the accompanying figures. Showing:

1 , an exemplary architecture of a data processing system for performing the method;

2 , Machining levels in the design model;

3 , a simple body and a two-dimensional object;

4 , a body and a two-dimensional object;

5 , the result of a translation movement of an in 4 shown object;

6 , a change of objects in 5 ;

7 , an alternative change of objects in 5 ,

• – einen Datenspeicher 3,
• – eine Recheneinheit 1 zur Durchführung von Berechnungen,
• – eine Anzeigevorrichtung in Form eines Bildschirmgeräts 2, das einen Kathodenstrahl-Bildschirm oder einen Flüssigkristall-Bildschirm umfasst,
• – ein erstes Eingabegerät in Form einer DV-Maus 4, die drei Tasten aufweist,
• – ein zweites Eingabegerät in Form einer Tastatur 5 mit Tasten und
• – eine Graphikkarte 6, die die Eingangssignale für das Bildschirmgerät 2 erzeugt.

1 shows an exemplary architecture of a data processing system, with the aid of which the construction device according to the invention is realized. This data processing system comprises in this example the following components:

• - a data store 3 .
• - one arithmetic unit 1 to perform calculations,
• - A display device in the form of a display device 2 comprising a cathode ray screen or a liquid crystal screen,
• - A first input device in the form of a DV mouse 4 that has three buttons,
• - A second input device in the form of a keyboard 5 with buttons and
• - a graphics card 6 indicating the input signals to the display device 2 generated.

The arithmetic unit 1 is via an information forwarding interface with the data store 3 connected. In this data store 3 is a computer-accessible three-dimensional design model 8th an object stored. The article is a motor vehicle in this example. The construction device is used to construct the motor vehicle. The process of designing involves creating and editing the design model 8th ,

The information forwarding interface is a bidirectional, ie the arithmetic unit 1 has both read and write access to the data store 3 with the design model 8th , The design device can therefore be the design model 8th both read and write change.

It is possible that the design model 8th describes a component of a motor vehicle. In contrast, in this embodiment, the design model includes 8th for the motor vehicle, an overall design model for the motor vehicle as a whole as well as various three-dimensional computer-available design models for components of the motor vehicle. Each of these constituent design models functions as a body of the design model within the meaning of the claims. The components include z. As the body, the hood as part of the body, a hydraulic unit in the engine and the wheels with tires. In this example, the constituent design models determine the geometries of the surfaces of the respective constituents, but not z. B. electrical or hydraulic properties of the components or their "inner workings." Also, the overall design model for the motor vehicle as a whole functions in this example as a body of the design model within the meaning of the claims.

In the data store 3 Furthermore, the positions and orientations of these design models are stored with respect to a given three-dimensional coordinate system. So that's in the data store 3 also stored the relative positions of the construction models to each other.

In the data store 3 Furthermore, computer-accessible descriptions of several processing levels are stored. In particular, in the data memory 3 stored the positions of the machining planes with respect to the given three-dimensional coordinate system. As a result, the positions of the machining planes with respect to the design model of the motor vehicle are determined.

The construction device is also preferably designed to edit and modify the computer-accessible descriptions of the processing levels. A user can, for. B. by input with the input devices 3 and 4 Change the position and / or orientation of a working plane in the three-dimensional coordinate system.

In this embodiment, the construction device is used to construct a new variant of a motor vehicle. At the beginning of the design process, there is a data store 3 from stored output design model available. The design model of the variant is constructed step-by-step from this initial design model. Preferably, successive different construction stages are passed through, and thereby the level of maturity achieved is increased stepwise.

In In this example, the construction device u. a. used for the shape of the body and the positions and orientations of Components relative to each other and to determine the body. Especially should the geometric interaction of body including planking with exterior components and interior components of the motor vehicle and if necessary changed become.

2 shows by way of example six processing levels X0, X1, X2, X3, X4 and X5 in a design model 8th of a motor vehicle. The editing levels in this example are all perpendicular to the drawing plane and are parallel to each other.

In In this example, the processing plane X0 is positioned so that the centers of the two front wheels in the working plane X0 is located. The working plane X4 passes through the reference point SRP1, the processing plane X5 through the reference point SRP3. "SRP" means "seat reference point" and sets the position of a seat. The positions of X4 and X5 are through the positions uniquely defined by SRP1 or SRP3. The positions of these two Reference points, in turn, become the center of the left by their distances Front wheel set in the drawing plane.

The design device is configured so that a user can input the values of parameters in a table. This table is with the design model 8th connected and changed the position or shape of geometric objects of the design model 8th , For example, the user may set and change the distances from SRP1 and SRP3 to the center of the left front wheel by entering values in the table.

In the data store 3 Furthermore, several computer-accessible geometric two-dimensional objects are stored. Each two-dimensional object belongs to the intersection of the respective working plane with a design model of a component of the motor vehicle. In the data store 3 is or is stored for each two-dimensional object whose position and orientation on the respective working plane.

In one embodiment, the design device itself generates these two-dimensional objects in response to inputs made by a user to the input devices 4 and 5 performs. In another embodiment, another data processing device generates the machining planes and these two-dimensional objects and presents them to the design device.

For example becomes a two-dimensional object in a working plane generates the following way. Several points of a body, here that is, a constituent design model, are selected. For example, points are selected that are the outer shape feature of the ingredient. These points are at the working level projected. The respective projection axis is z. B. perpendicular at the working level. The projection of the selected points provides several projection points. These projection points function as reference points for the two-dimensional object and are not necessarily in the intersection of body and processing level. The two-dimensional object itself is z. B. as an intersection of body and machining level generated. The body, here a component design model, puts z. For example, determine the geometry of the surface of the component. This intersection is then z. By several lines or curves, which together form a closed curve. Approximated.

• – Schnitt in X0 durch die Karosserie mit den Parametern Fugenmaß, Werkzeug-Richtung und Blechabstellung,
• – Schnitt in X0 durch die Karosserie mit dem Parameter maximale Rohbaubreite,
• – Schnitt in X0 durch die Karosserie mit dem Parameter Abstand von Fahrbahn bis Unterkante Radausschnitt vorne.

Because in the example of the 1 the intersection of the bodywork design model with the X0 machining plane has many geometric components and parameters are in the data memory 3 several two-dimensional objects are stored, all of which lie in the working plane X0 and belong to the intersection of the body design model with X0. These two-dimensional objects include the following objects:

• - Section in X0 through the body with the parameters joint dimension, tool direction and sheet metal shut-off,
• - section in X0 through the bodywork with the parameter maximum shell width,
• - Section in X0 through the body with the parameter distance from road to lower edge of wheel cutout in front.

The Joint dimension is the adjustable gap between two components. The tool direction is a parameter from the manufacture of the motor vehicle and designated the pulling direction in which the respective component is pulled, in the form of an adjustable angle. The Blechabstellung is a adjustable angle and denotes the parked edges of Parts of the outer skin.

• – Schnitt in X0 durch das Fahrzeug im Sichelmaß 0 Grad, 30 Grad, 50 Grad mit geometrischen Parametern des Dämpferdoms und des Fußgängerschutzes,
• – Schnitt in X0 durch das Fahrzeug mit dem Parameter Abstand Motorhaube zur Hydraulikeinheit,
• – Schnitt in X0 durch das Fahrzeug mit dem Parameter Radius des Auslegungsreifens.

In addition, the working plane X0 has the following two-dimensional objects:

• - Section in X0 by the vehicle in sickle dimension 0 degrees, 30 degrees, 50 degrees with geometric parameters of the damper dome and the pedestrian protection,
• - section in X0 by the vehicle with the parameter distance bonnet to the hydraulic unit,
• - Section in X0 by the vehicle with the parameter radius of the design tire.

The construction device is designed for switching between the processing planes as well as between the two-dimensional objects of a processing plane. For example, the construction device initially shows a representation of the motor vehicle with the processing planes as shown in FIG 1 at. The user selects one of the displayed processing levels. Subsequently, the construction device z. For example, textually, which two-dimensional objects are created in this work plane. The user selects one of the two-dimensional objects offered for selection that lie in the previously selected working plane.

Some These two-dimensional objects are defined by geometric parameters characterized. These geometric parameters include the above in connection with X0 described parameters. A geometric one Parameter of a two-dimensional object describes z. Legs Dimension, a distance, a position or orientation or a Tolerance of the two-dimensional object in the respective working plane. Preferably, a two-dimensional object comprises elementary geometric Objects, e.g. B. curves, Lines or reference points. For example, this is the two-dimensional Object a closed curve with several curves or lines. Parameters of these elementary geometric objects are then as well Parameters of the two-dimensional object.

After selecting a working plane and a two-dimensional object in this working plane, the construction device displays this two-dimensional object. In one embodiment, the display device 2 a representation and interaction level. The construction device displays the two-dimensional object so that the working plane is equal to the plane of representation or parallel to the working plane. Thus, the two-dimensional object in the working plane is also in or parallel to the presentation plane.

Preferably, the construction device generates a local two-dimensional coordinate system for the selected working plane. This coordinate system has an origin that is changeable by the user of the design device. The design device creates a dimension of the two-dimensional object, including its elementary geometric objects, and places that dimension on the display device 2 The dimensions include the geometric parameters and their values relative to the two-dimensional coordinate system, in particular the coordinates of reference points. Furthermore, the dimensions preferably include the coordinates of start and end points of curves and other geometric parameters such. B. curvatures.

The user can change these geometric parameters of the two-dimensional object. In one embodiment, the geometric parameters are associated with a table. This table shows the construction device on the screen device 2 at. The table has one line per parameter. In the first column is z. For example, a name of the geometric object that describes the parameter. In the second column is a name of the parameter and in the third column the current value of this parameter. The user can change a parameter value by entering a new value using the keyboard.

Is possible, that some parameters against direct change by the user are locked. In the table, the current values of this Parameter only displayed. Preferably, such is locked Parameters through a computer-accessible depending provision connected to at least one other parameter. The value of the parameter is by applying this dependency rule automatically calculated.

The user can also change individual geometrical parameters "geometrically", for example with the mouse 4 expose and move a point or other elemental geometric object this. Or he selects a curve or a route and shifts or rotates it. Or he selects a curve and then a point of the curve and moves the point. As a result, the curve changes its course, leaving the start and end points unchanged. The displacement of the point thus causes the curvature of the curve to change.

3 shows an example of a body 30 and a simple two-dimensional object 20 , The body 30 list indicated by dotted lines and curves, the two-dimensional object 20 through solid lines and curves. The two-dimensional object 20 lies in a working plane.

The design device further generates, at the user's request, a dimension of the body design model relative to the given three-dimensional coordinate system. This dimension includes a dimension of the above-described machining planes, which are described in 2 to be shown. In particular, the dimensioning shows the positions of the machining planes relative to reference points of the design model of the body. The design device switches between the predetermined three-dimensional and the local two-dimensional coordinate system as often as desired by the user.

The Design device dimensioned the generated two-dimensional object on request also with respect to Projection points. This dimension in terms of the projection points includes z. B. the distances between points of the two-dimensional Object and projection points.

As described above, the two-dimensional object is the design model 8th connected to the motor vehicle and / or a component of the motor vehicle. The intersection of the design model and the respective working plane comprises the two-dimensional object. For example, the design model for the body determines the shape of the center surface of the body. This middle surface is curved. Furthermore, the design model determines the wall thickness of the body. These two details clearly specify the geometry of the body in this example. The two-dimensional object is equal to the intersection of the central area with the working plane. This intersection has the shape of a curved curve in the viewing plane. This curved curve is associatively connected to the design model in both directions.

First, the design device alters the design model 8th and thus the constituent design models automatically when the two-dimensional object, that is, the curved curve in the working plane, has been changed. The design device alters each design model such that the intersection of the automatically changed design model with the machining plane is equal to the changed two-dimensional object. In particular, the design device automatically changes geometric parameters of the design model that relate to dimensions, distances, or positions of the design model in the working plane according to the changes in the two-dimensional object.

In the present exemplary embodiment, as described above, various two-dimensional objects can be changed in several processing planes. After changing a two-dimensional object, the construction device alters the constructicon model 8th and thus the constituent design models automatically such that each two-dimensional object lies in the intersection of the changed design model with the respective working plane.

To the changed others the construction device automatically the two-dimensional object in the working plane, when the design model has been changed. This change leads the Construction device so by that the intersection of changed Design model and working plane the modified two-dimensional Object includes.

Preferably a user can just as described geometric and others Change parameters of the two-dimensional object, eg. B. by input with an input device. Parameters of the two - dimensional object are with parameters of the linked to a three-dimensional object. A change a parameter of the two-dimensional object causes the Construction device automatically the linked parameter of the three-dimensional Object with changed.

Farther changed the construction device after a change of a two-dimensional object the dimensions described above automatically so that the changed dimensions change the two-dimensional Object described.

4 and 5 explain the automatic change of the body in another example. In this example, the body represents a motor vehicle component 15 , This ingredient 15 includes five sheets 15.1 . 15.2 . 15.3 . 15.4 and 15.5 , Two of these sheets abut each other in an edge. 4 shows five elementary three-dimensional objects on the right 15.1 . 15.2 . 15.3 . 15.4 and 15.5 belonging to the design model for the automotive component. The centers of these five sheets are marked as reference points. 4 shows three reference points 11.2 . 11.4 and 11.6 , Further reference points are defined on the means of the edges, in which two sheets collide. 4 shows three reference points 11.1 . 11.3 . 11.3 ' 11.5 and 11.5 ' on the centers of the edges. The reference point 11.3 belongs to the elementary object 15.2 , the reference point 11.3 'with the same position to the elementary object 15.3 , The reference point 11.5 belongs to the elementary object 15.4 , the reference point 11.5 'with the same position to the elementary object 15.3 ,

The processing level is in the example of 4 the drawing plane. In this example, the intersection is between the body 15 and the working plane equal to the two-dimensional object 14 , This object 14 includes five elementary two-dimensional geometric objects 14.1 . 14.2 . 14.3 . 14.4 and 14.5 which in this example have the form of lines. The midpoint of each line is as a reference point of the two-dimensional object 14 marked. 4 shows the reference points 10.2 . 10.4 and 10.6 ,

Each of these five reference points is with a reference point of the body 15 connected. The reference point 10.2 is with the reference point 11.2 linked, the reference point 10.4 with the reference point 11.4 and the reference point 10.6 with the reference point 11.6 , "Linkage" means: The design device is designed to also shift the associated reference point of an elementary three-dimensional object after each displacement of a reference point of an elementary two-dimensional object, preferably in the same direction and at the same distance.

The lines (elementary two-dimensional objects) 14.1 and 14.2 touch each other at the point 10.1 , which is also a reference point of the two-dimensional object 14 is and with the reference point 11.1 of the body 15 is linked. The lines 14.2 and 14.3 touch each other in the reference points 10.3 and 10.3 '. The reference point 10.3 of the object 14 belongs to the elementary object 14.2 , the reference point 10.3 'to the elementary object 14.3 , Accordingly, the reference points 10.3 . 10.3 ' 10.5 and 10.5 ' of the two-dimensional object 14 with the reference points 11.3 . 11.3 ' 11.5 and 11.5 ' of the body 15 connected.

Every elementary two-dimensional object 14.1 . 14.2 . 14.3 , ... has a wall thickness as a parameter. Every elementary three-dimensional object 15.1 . 15.2 . 15.3 , ... has a wall thickness as a parameter. Each wall thickness and wall thickness can be changed independently of any other wall thickness. The wall thickness of the object 14.1 is with the wall thickness of the object 15.1 linked, the wall thickness of the object 14.2 with the wall thickness of the object 15.2 , the wall thickness of the object 14.3 with the wall thickness of the object 15.3 and so on. When a user changes the wall thickness of the object 14.3 changes, the construction device automatically changes the wall thickness of the object 15.3 preferably by reducing the wall thickness of 15.3 to the same value as the wall thickness of 14.3 puts.

5 shows the result of a translational movement. A user moves the line (the elementary two-dimensional object) 14.3 to the left. This will be the reference points 10.3 ' 10.4 and 10.5 ' with postponed. The construction device automatically shifts the reference points 11.3 ' 11.4 and 11.5 ' of the elementary object 15.3 in the same direction and by the same amount. The object 15.3 is then also shifted, in such a way that the three shifted reference points 11.3 ' 11.4 and 11.5 ' in the moved object 15.3 lie.

6 shows a change of objects in 5 , The user extends the object 14.3 in both directions. The angle between the objects 14.2 and 14.3 remains unchanged, also the angle between the objects 14.4 and 14.3 , The construction device changes the object 14.2 automatically so that the changed object 14.2 and the extended object 14.3 in the same position reference points 10.3 and 10.3 ' touch. Accordingly, the construction device changes the object changed 14.4 automatically so that the changed object 14.4 and the extended object 14.3 in the same position reference points 10.5 and 10.5 ' touch.

The construction device automatically changes the positions of the corresponding reference points 11.3 . 11.3 ' 11.5 and 11.5 ' , Furthermore, the construction device changes the three-dimensional object 15.2 , automatically so that the reference points 11.1 . 11.2 and 11.3 in the changed object 15.2 lie on a line. It changes the three-dimensional object 15.3 automatically so that the reference points 11.3 ' 11.4 and 11.5 ' in the changed object 15.3 lie. It changes the three-dimensional object 15.4 automatically so that the reference points 11.5 and 11.6 in the changed object 15.4 lie.

7 shows an alternative change of the objects in 5 , The user leaves the object 14.3 unchanged. For that he changes the angle between the objects 14.2 and 14.3 , also the angle between the objects 14.4 and 14.3 , The reference points 10.2 and 10.6 hike to the left.

The construction device in turn automatically changes the positions of the corresponding reference points 11.3 . 11.3 ' 11.5 and 11.5 ' , Furthermore, the construction device changes the three-dimensional object 15.2 , automatically so that the reference points 11.1 . 11.2 and 11.3 in the changed object 15.2 lie. It changes the three-dimensional object 15.3 automatically so that the reference points 11.3 ' 11.4 and 11.5 ' in the changed object 15.3 lie on a line. It changes the three-dimensional object 15.4 automatically so that the reference points 11.5 and 11.6 in the changed object 15.4 lie. List of used reference signs and symbols

Claims (22)

electronic construction device with - a data memory ( 3 ) - a display device ( 2 ) and - at least one input device ( 4 . 5 ), whereby in the data memory ( 3 ) - a computer-available design model ( 8th ) of an object, - at least one computer-accessible two-dimensional processing plane (X0, X1, ...) and - at least one computer-accessible geometric two-dimensional object ( 14 ) are stored, the design model ( 8th ) a computer-accessible geometric three-dimensional body ( 15 ), wherein - the two-dimensional object ( 14 ) lies in the working plane (X0, X1, ...) and - the intersection of the body ( 15 ) with the working plane (X0, X1, ...) the two-dimensional object ( 14 ) and wherein the construction device is designed to automatically carry out the following steps: - displaying the two-dimensional object ( 14 ) using the display device ( 2 ), - changing the two-dimensional object ( 14 ) in the working plane (X0, X1, ...) depending on inputs with the input device ( 4 . 5 ) and - changing the body ( 15 ) in such a way that the intersection of the changed body ( 15 ) with the working plane (X0, X1,...) the changed two-dimensional object ( 14 ). Construction device according to claim 1, characterized in that the construction device - for positioning the working plane (X0, X1, ...) relative to the construction model ( 8th ) depending on inputs with the input device ( 4 . 5 ) and - for automatically generating the two-dimensional object ( 14 ) in the positioned working plane (X0, X1, ...) such that the intersection of the body ( 15 ) with the working plane (X0, X1, ...) the two-dimensional object ( 14 ) is configured. Construction device according to claim 1 or claim 2, characterized in that in the data memory, a computer-available three-dimensional coordinate system is stored and the construction device - for positioning and orienting the design model ( 8th ) and the working plane (X0, X1, ...) in the coordinate system depending on inputs with the input device ( 4 . 5 ) and - to dimension the two-dimensional object ( 14 ) is configured with respect to the coordinate system. Construction device according to claim 3, characterized in that the construction device is designed such that a dimension that can be generated by the construction device - a decomposition of the two-dimensional object ( 14 ) into several elementary geometric two-dimensional objects ( 14.1 . 14.2 , ...) and dimensions of each of these elementary geometric objects ( 14.1 . 14.2 , ...) and - selected points ( 10.1 . 10.2 , ...) of the two-dimensional object ( 14 ) and their positions in the three-dimensional coordinate system. Construction device according to claim 4, characterized in that the construction device for modifying an elementary geometric object ( 14.1 . 14.2 , ...) depending on inputs with the input device ( 4 . 5 ) is configured. Construction device according to one of claims 1 to 5, characterized in that the construction device - for generating a two-dimensional coordinate system in the working plane (X0, X1, ...) - for positioning the two-dimensional object ( 14 ) relative to the two-dimensional coordinate system depending on inputs with the input device ( 4 . 5 ) and - to dimension the two-dimensional object ( 14 ) with respect to the two-dimensional coordinate system is designed. Construction device according to claim 6, characterized in that the construction device - for changing a parameter of the dimensioning in dependence on inputs with the input device ( 4 . 5 ) and - for changing the two-dimensional object ( 14 ) in the working plane (X0, X1, ...) in such a way that the changed two-dimensional object ( 14 ) to the changed parameter of the dimension fits, is designed. Construction device according to claim 6 or claim 7, characterized in that the construction device is designed such that a dimension that can be generated by the construction device - a decomposition of the two-dimensional object ( 14 ) into several elementary geometric two-dimensional objects ( 14.1 . 14.2 , ...) and dimensions of each of these elementary geometric objects ( 14.1 . 14.2 , ...) and - selected points ( 10.1 . 10.2 , ...) of the two-dimensional object ( 14 ) and their positions in the two-dimensional coordinate system. Construction device according to one of claims 1 to 8, characterized in that - the body ( 8th ) is a computer-accessible design model of a component of the object and describes the surface of this component. Construction device according to claim 9, characterized in that - the body ( 8th ) comprises a plane or curved surface which identifies the geometry of the component, and - the design device is designed such that it supports the two-dimensional object ( 14 ) as an intersection of the characterizing surface with the machining plane (X0, X1, ...). Construction device according to claim 10, thereby marked that - the Geometry of the component by the identifying surface as well through a wall thickness is fixed and - the Construction model a determination of the wall thickness includes. Construction device according to claim 11, characterized in that the two-dimensional object ( 14 ) as a parameter has its wall thickness, the parameter wall thickness by inputs with the input device ( 4 . 5 ) and the construction device determines the determination of the wall thickness in the design model ( 8th ) depending on changes in the thickness of the two-dimensional object ( 14 ) changed. Construction device according to one of claims 1 to 12, characterized in that the construction device - for generating a reference point (SRP1, SRP3) depending on inputs with the input device ( 4 . 5 ) and - for positioning the working plane (X0, X1, ...) relative to the reference point (SRP1, SRP3) in response to inputs with the input device ( 4 . 5 ) is configured. Construction device according to claim 13, thereby marked that the construction device for positioning the working plane (X0, X1, ...) relative to the reference point (SRP1, SRP3) dependent on from an enterable distance between working plane (X0, X1, ...) and reference point (SRP1, SRP3) is configured. Construction device according to claim 13 or claim 14, characterized in that the construction device - for selecting and marking a point of the design model ( 8th ) depending on inputs with the input device ( 4 . 5 ) and - designed to generate the marked point as a reference point (SRP1, SRP3). Construction device according to one of claims 1 to 15, characterized in that the construction device is designed so that when the change of the two-dimensional object ( 14 ) comprises a first translational movement, the change of the body ( 15 ) comprises a second translation movement in the same direction and over the same distance as the first translation movement. Construction device according to one of claims 1 to 16, characterized in that the construction device is designed so that when the change of the two-dimensional object ( 14 ) comprises a first rotational movement, the change of the body ( 15 ) comprises a second rotational movement in the same rotational direction and by the same rotational angle as the first rotational movement. Construction device according to one of claims 1 to 17, characterized in that the display device ( 2 ) has a representation plane and the construction device is designed such that it the processing plane (X0, X1, ...) together with the two-dimensional object ( 14 ) in the display plane of the display device ( 2 ). Construction device according to one of claims 1 to 18, characterized in that in the data memory ( 3 ) at least two different two-dimensional objects are stored, both in such a way in the working plane (X0, X1, ...) are that the intersection of the body ( 15 ) with the working plane (X0, X1, ...) comprises both objects, and the design device is designed such that each of the two objects in the working plane (X0, X1,. 4 . 5 ) is selectable. Construction device according to one of claims 1 to 19, characterized in that the design model comprises a first and a second computer-accessible geometric three-dimensional body, in the data memory ( 3 ) are stored a first and a second computer-available geometric two-dimensional object, both of which are in the working plane (X0, X1, ...), that - the intersection of the first body with the processing plane, the first object and - the intersection of the second body with the processing plane comprises the second object, and the design device is designed so that each of the two objects in the working plane (X0, X1, ...) by means of the input device ( 4 . 5 ) is selectable. Construction device according to one of claims 1 to 20, characterized in that the two-dimensional object ( 14 ) a first and a second elementary two-dimensional object ( 14.1 . 14.2 , ...), the body ( 15 ) a first and a second elementary three-dimensional object ( 15.1 . 15.2 , ...), the intersection of the first elementary three-dimensional object ( 15. 2 ) with the working plane (X0, X1,...) the first elementary two-dimensional object ( 14.2 ), the intersection of the second elementary three-dimensional object ( 15.3 ) with the working plane (X0, X1, ...) the second elementary two-dimensional object ( 14.3 ) and the construction device is designed to automatically carry out the following steps: - changing the first elementary two-dimensional object ( 14.2 ) depending on inputs with the input device ( 4 . 5 ), - changing the second elementary two-dimensional object ( 14.3 ) depending on the change of the first elementary two-dimensional object ( 14.2 ), - changing the first three-dimensional object ( 15.2 ) in such a way that the intersection of the changed three-dimensional object ( 15.2 ) with the processing plane (X0, X1,...) the modified first elementary two-dimensional object ( 14.2 ), and - changing the second three-dimensional object ( 15.3 ) in such a way that the intersection of the changed three-dimensional object ( 15.3 ) with the processing plane (X0, X1,...) the modified second elementary two-dimensional object ( 14.3 ). Construction device according to claim 21, characterized in that the first elementary two-dimensional object ( 14.2 ) and the second elementary two-dimensional object ( 14.3 ) in at least one point ( 10.3 ) and the construction device for automatically changing the second elementary two-dimensional object ( 14.3 ) such that the changed first elementary two-dimensional object ( 14.2 ) and the modified second elementary two-dimensional object ( 14.3 ) in at least one point ( 10.3 ), is configured.