Your search keyword '"Marcel Droß"' showing total 5 results

1. Combined robot-based manufacturing and machining of multi-material components

Author

Ann-Kathrin Reichler, Hans-Werner Hoffmeister, Marcel Droß, Martin David, Max Albergt, and Klaus Dröder

Subjects

Computer science, business.industry, Mechanical Engineering, Plastics extrusion, Process (computing), Mechanical engineering, Modular design, Chip, Structuring, Industrial and Manufacturing Engineering, Computer Science Applications, Machining, Control and Systems Engineering, Robot, Reduction (mathematics), business, Software

Abstract

The growing demand for individualized products is becoming more and more significant and leads to a reduction in batch sizes. In particular, the production of multi-material components for lightweight design presents new challenges to the manufacturing process. This is evident when it comes to the production of individual parts, as today’s processes are characterized by high tool costs and manual operations. The described challenge can be overcome by a robot-based manufacturing cell allowing the use of a novel, modular process chain in which metal parts are mechanically pre-treated, subsequently completed by additive plastic application, and afterwards finalized in a machining step to achieve the required surface qualities and geometries. In order to realize the novel process chain, robot-based solutions for free-form metal sheet processing, increased interlayer bonding strength of plastic, and multi-material machining with integrated chip extraction have to be found. Therefore, this paper presents the first approach of a robot-guided surface structuring end-effector and a concept for a direct extraction hood, which is able to be adapted specifically to the movement of the robot and the part surface, so free-form surfaces can be machined. Based on this, first experimental studies for increasing the interlayer bonding strength of plastic were carried out using an extruder set up to applicate thermoplastics onto metal at high deposition rates. To define the positioning accuracy for a robot-guided structuring process, different point to point movements have been investigated.

Published

2021

2. Finite Element and Finite Volume Modelling of Friction Drilling HSLA Steel under Experimental Comparison

Author

Marcel Droß, Eugen Stockburger, Hendrik Wester, Bernd-Arno Behrens, Klaus Dröder, and André Hürkamp

Subjects

tensile testing, material characterisation, material modelling, friction drilling, high-strength low-alloy steel, Technology, Materials science, engineering.material, Article, General Materials Science, Tensile testing, High-strength low-alloy steel, Microscopy, QC120-168.85, Finite volume method, business.industry, QH201-278.5, Structural engineering, Engineering (General). Civil engineering (General), Finite element method, Material flow, TK1-9971, Descriptive and experimental mechanics, Bushing, engineering, Hardening (metallurgy), Friction drilling, Electrical engineering. Electronics. Nuclear engineering, TA1-2040, business

Abstract

Friction drilling is a widely used process to produce bushings in sheet materials, which are processed further by thread forming to create a connection port. Previous studies focused on the process parameters and did not pay detailed attention to the material flow of the bushing. In order to describe the material behaviour during a friction drilling process realistically, a detailed material characterisation was carried out. Temperature, strain rate, and rolling direction dependent tensile tests were performed. The results were used to parametrise the Johnson–Cook hardening and failure model. With the material data, numerical models of the friction drilling were created using the finite element method in 3D as well as 2D, and the finite volume method in 3D. Furthermore, friction drilling tests were carried out and analysed. The experimental results were compared with the numerical findings to evaluate which modelling method could describe the friction drilling process best. Highest imaging quality to reality was shown by the finite volume method in comparison to the experiments regarding the material flow and the geometry of the bushing.

Published

2021

3. Increased load bearing capacity of mechanically joined FRP/metal joints using a pin structured auxiliary joining element

Author

Per Heyser, Vadim Sartisson, Gerson Meschut, Marcel Droß, and Klaus Dröder

Subjects

Metal, Materials science, Mechanics of Materials, Mechanical Engineering, visual_art, visual_art.visual_art_medium, General Materials Science, Fibre-reinforced plastic, Composite material, Load bearing

Abstract

Due to their excellent mechanical properties, fiber-reinforced plastics are increasingly being used in technical lightweight products. The multi-material design of fiber-reinforced plastic and metal leads to great lightweight constructions because the potential of the materials can be efficiently used for the specific field of application. This restricts conventional thermal joining technologies and shows the demand for cost-effective and efficient mechanical and adhesive joining technologies. This paper depicts the development of a new type of auxiliary joining element with integrated pin structures whose purpose is to increase the load-bearing capacity of mechanically joined fiber-reinforced plastic/metal combinations. In addition, the hole area of the fiber-reinforced plastic can be relieved in this way by transferring the operating loads into the laminate via the pin structures. In addition to experimental studies of the application methodology, the quasi-static and dynamic load-bearing capacity will be investigated. This paper presents detailed information about the development of the new auxiliary joining element and the characteristics of the joints, including corrosion effects generated by a corrosion camber.

Published

2019

4. Scalable Process Chain for Flexible Production of Metal-Plastic Lightweight Structures

Author

Georg Mahlfeld, Ann-Kathrin Reichler, Marcel Droß, Klaus Dröder, and Roman Gerbers

Subjects

Flexibility (engineering), 0209 industrial biotechnology, Computer science, business.industry, Process (computing), 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, 020901 industrial engineering & automation, Machining, visual_art, Component (UML), visual_art.visual_art_medium, General Earth and Planetary Sciences, Production (economics), Injection moulding, Sheet metal, Process engineering, business, Interlocking, 0105 earth and related environmental sciences, General Environmental Science

Abstract

The demand for customised products leads to an increasing diversity of variants and batch sizes in production. Therefore, established high volume production technologies have become less profitable. This loss results primarily from high product-specific investments in mould-based manufacturing systems such as injection moulding and sheet metal forming whose amortisation is challenged by smaller batch sizes. The increasing number of components in multi-material design, especially from metal and plastics, calls for flexible production technologies. This paper introduces a new robot-based process chain for metal-plastic parts to close the existing gap between manual production of small batches and mould-based high volume production. The idea is to combine surface treatments with additive and subtractive manufacturing processes in a single workspace implementing an incremental process chain to realise a scalable production system. This will increase the manufacturing flexibility for customised products and reduce the cost per unit. As a first step in the process chain, the surface of a pre-produced metal part is structured for mechanical interlocking and high strength joining. Subsequently, an additive process is used to directly apply a plastic section onto the pre-structured metal part, thus producing a hybrid component. Finally, the hybrid component is machined to add individual holes or pockets and to finish the surface of the additively manufactured area. This paper presents a scalable process chain for metal-plastic components as well as concepts for its technological implementation. Furthermore, first experimental results from the fabrication of a metal-plastic part using additive and conventional processes are presented.

Published

2019

5. Improved Adhesion Strength of Metal Textile Composites by Surface Texturing Using TIG Arc or CW Laser Process

Author

M. Hertel, Marcel Droß, Marén Gültner, Marius Lammers, Uwe Füssel, Jörg Hermsdorf, Anna Große, and Martin Lohse

Subjects

Materials science, 010308 nuclear & particles physics, Mechanical Engineering, Gas tungsten arc welding, Metallurgy, 030206 dentistry, Cw laser, 01 natural sciences, Arc (geometry), Metal, Adhesion strength, 03 medical and health sciences, 0302 clinical medicine, Mechanics of Materials, visual_art, Scientific method, 0103 physical sciences, visual_art.visual_art_medium, General Materials Science, Textile composite, Composite material

Abstract

Within the framework of the bilateral CORNET projects MeTexCom and MeTexCom2, new approaches were developed and tested to improve the adhesion strength of metal textile composites, with a focus on the targeted roughening of aluminum surfaces and the development of new acoustically insulating nonwovens. The metal textile composites were produced by melting thermoplastic components of the textile composites without a separately applied adhesive.For improved adhesion strength between metal and textile, roughness was generated on the metal surface by means of a novel arc treatment by an anodic polarized TIG process or a cw (continuous wave) fiber laser process. On the one hand, the goal was to produce uniformly rough, untercut surface structures in micro-and nanodimension by means of a highly dynamic arcing process. On the other hand, a similar approach was pursued with the cw laser method by using a single-mode as well as a multi-mode laser.

Published

2017