DE102014000288A1 - Three-dimensional object and method for generative production thereof - Google Patents

Abstract

A three-dimensional object (100, 200) with a grid structure (102, 202) is described, which forms a closed lateral surface and is in one piece. Furthermore, a method for the generative production of the three-dimensional object (100, 200) is proposed.

Description

The present invention relates to a three-dimensional object having a mesh structure, wherein the mesh structure forms a closed surface. Furthermore, the invention relates to a method for the generative production of the three-dimensional object.

STATE OF THE ART

Laser sintering is a well-known process for the rapid production of workpieces. A laser beam fuses a pulverulent raw material to a solid workpiece. If a workpiece layer has fused, then a thin powder layer of raw material is applied to it and in turn fused with the laser beam. The workpiece typically grows vertically from layer to layer vertically from a building platform.

From the DE 10 2010 040 261 A1 For example, a laser sintering method for producing a three-dimensional body is known. The body achieves a high elastic modulus through its internal structure. The known body has two flat sections with different lattice structure, which lead to different degrees of deformation of the body when force.

From the EP 2 525 187 A1 is a half-shell-shaped mesh structure known, which serves for the production of a protective helmet.

The object of the invention is to provide a stable body that is easy and inexpensive to produce.

DISCLOSURE OF THE INVENTION

According to the invention therefore a three-dimensional object is provided, which is designed according to claim 1. A method for producing the same is provided in claim 8. The three-dimensional object is further used according to claim 10.

In particular, the three-dimensional object is formed with a grid structure. The grid structure may have a closed lateral surface. Further, it is preferable that the mesh structure is integrally formed.

The grid structure is a structure that may have openings. As a result, the structure is in particular lighter than solid material, which has no openings. Also, the use of an apertured mesh structure is less expensive because less starting material can be used.

A one-piece design of the grid structure preferably includes any type of body without seams, material transitions or other connections such as form-fit, frictional and the like. Another advantage of the integral lattice structure is generally its stability compared to multi-piece bodies. Seams, material transitions and other connections can form weak points where the grid structure fails under load, eg breaks or tears.

The one-piece design of the grid structure also offers the further advantage that no subsequent assembly work, such as screwing, gluing are necessary. The mesh structure is preferably made in one fell swoop as a one-piece body and can be used immediately after manufacture. As a result, the manufacturing costs for the grid structure can be reduced.

It is further preferred that the grid structure encloses a cavity. If the grid structure forms the closed lateral surface, it may already be meant that it encloses a volume or forms a space. The cavity or the volume has the advantage that there no starting material must be used, so it can be saved.

In one embodiment, the grid structure may be egg or spherical. Ball and egg shape are generally already very stable body. If, for example, the grid structure is supported at a first location (eg floating bearing) and acts on a second location opposite the first location a force, this force can advantageously be transmitted to the support by the ball or egg shape.

The grid structure may also include a plurality of webs forming a grid-like network structure. The webs can form the network structure. In a computer-aided construction of the grid structure, for example, a flat two-dimensional initial grid can be started. Such an exit grid has identical square, triangular, n-square, honeycomb or circular openings.

Through a mathematical projection, the output grid is preferably imaged onto the three-dimensional grid network structure. The grid structure can thereby have in particular projected openings in square, triangular, n-corner, honeycomb or circular shape.

Depending on the shape of the openings, a certain direction-dependent force absorption for the three-dimensional object can be provided in an advantageous manner.

By providing openings in the mesh structure, the three-dimensional object can have an advantageous spring action under load.

The use of materials can be reduced through openings. The three-dimensional object can furthermore be produced by means of a generative manufacturing method. The openings allow advantageously the removal of material residues, these can, for. B. easier to fall through the openings. If the grid structure surrounds a cavity or a volume, for example, material residues can fall out of the interior through the openings.

If the webs have a symmetrical cross-sectional area, and in particular if the number of corners of the cross-sectional area is even, the webs thus formed can advantageously transfer force with less directional dependence than about asymmetrical ones.

The generative manufacturing method preferably includes additive manufacturing processes such as selective laser sintering, abbreviated SLS, stereolithography, selective laser melting, fused deposition modeling, laminated object modeling or 3D printing. Plastic or metal powder can be used in particular as starting material for the grid structure. The powder can be fused by a laser along the intended grid structure and thus form the three-dimensional object. Three-dimensional objects made of metal are advantageously electrically conductive and can withstand high temperatures. Made of plastic three-dimensional objects are advantageous light, electrically insulating, heat insulating and inexpensive.

The three-dimensional object can obtain an advantageous stability by the choice of the starting material and / or the generative manufacturing method and / or the aforementioned shapes, such as closed shell surface, enclose cavity, egg or spherical shape, webs. If the three-dimensional object is subjected to a compressive force, it can optimally transfer it. If the compressive force on the three-dimensional object is increased, it can elastically spring in and transmit the compressive force in a damped manner. If the force on the three-dimensional object is increased beyond a certain limit, the three-dimensional object deforms irreversibly, but does not fail, but can transmit an even greater compressive force. Although the three-dimensional object fails, it has an advantageous self-reinforcing effect that can transmit higher compressive forces than comparable conventional bodies.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the invention will be explained in more detail with reference to the drawings and the description below. Show it:

1 an embodiment of the three-dimensional object according to the invention,

2 a further embodiment of the three-dimensional object according to the invention,

3 a lattice network structure of a further embodiment of the three-dimensional object according to the invention,

4 another view of the grid structure and

5 a pressure force-displacement diagram of a loaded embodiment of the inventive three-dimensional object.

EMBODIMENTS OF THE INVENTION

In the 1 is a three-dimensional object 100 shown. The three-dimensional object 100 includes a grid structure 102 , The grid structure 102 surrounds a cavity 104 coat-like. The grid structure 102 and thus the three-dimensional object 100 are spherical. The grid structure 102 has several bars 106 on, the several triangular openings 108 form. The pattern of triangular openings 108 forms a grid-like network structure.

The three-dimensional object 100 also has poles 110 on. The closer the openings 108 at the poles 110 lie, the smaller they are.

As starting material for the three-dimensional object 100 Plastic was used.

In the 2 is another three-dimensional object 200 shown. The three-dimensional object 200 is egg-shaped and has a longitudinal diameter, for example, a measure of 70 mm.

In the 3 is a section of a grid structure 202 of the three-dimensional object 200 shown. The grid structure 202 has square openings 204 and in-between footbridges 206 on. In the 4 is a cross section of the grid structure 202 shown. The bridges 206 have a circular cross-section.

In the 5 is shown a compression force-displacement diagram. There is a curve 500 again, in which a standard compressive force F on two opposite points of the three-dimensional object 200 acts. The three-dimensional object 200 is stored loose. About an increasing force curve F is the three-dimensional object 200 initially elastically deformed and thereby compressed to, for example, up to 60 mm, which corresponds to a compression around the path L of 10 mm. Starting from a first load point 502 At a pressing force F of more than 350 N and a path L of> 10 mm, the three-dimensional object deforms 200 irreversible. In the process, segments of the three-dimensional object fold 200 inside. The three-dimensional object 200 fails however at the first load point 502 not, but can transmit the further increasing compressive force F. At the second load point 504 the compressive force F reaches a maximum value of 600 N. The three-dimensional object 200 is compressed by a total of 55 mm, ie about 78%. Only when reaching the second load point 502 fails the grid structure 202 , the three-dimensional object 200 can from the load point 502 transfer no significant pressure force more.

The improvement in compressive force transfer is independent of the exact dimensions and compressions of the three-dimensional object 200 , referred to as a self-reinforcing effect. These effects are created by the shape of an egg or ball, by the formation as a coat-like mesh structure, the webs, the openings and a one-piece production by means of laser sintering.

The three-dimensional objects 100 . 200 can be used for crash helmets, protective helmets, bumpers, motor vehicle crash barges, safety clothing protectors or safety shoes.

QUOTES INCLUDE IN THE DESCRIPTION

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

Cited patent literature

• DE 102010040261 A1 [0003]
• EP 2525187 A1 [0004]

Claims (6)

Three-dimensional object ( 100 ; 200 ) with a grid structure ( 102 ; 202 ), whereby the grid structure ( 102 ; 202 ) a closed lateral surface is characterized in that the grid structure ( 102 ; 202 ) is integral. Three-dimensional object ( 100 ; 200 ) according to claim 1, characterized in that the grid structure ( 102 ; 202 ) a cavity ( 104 ) encloses. Three-dimensional object ( 100 ; 200 ) according to claim 1 or 2, characterized in that the grid structure ( 102 ; 202 ) Is formed egg- or spherical. Three-dimensional object ( 100 ; 200 ) according to one of the preceding claims, characterized in that the grid structure ( 102 ; 202 ) several webs ( 106 ; 206 ) having a grid-like network structure ( 102 ; 202 ) form. Three-dimensional object ( 100 ; 200 ) according to one of the preceding claims, characterized in that the grid structure ( 102 ; 202 ) projected openings ( 108 ; 204 ) in square, triangular, n-corner, honeycomb or circular shape. Three-dimensional object ( 100 ; 200 ) according to claim 4 or 5, characterized in that

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