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31-01-2021 | Production Process | Issue 2/2021 Open Access

Production Engineering 2/2021

Introduction to tailored forming

Journal:
Production Engineering > Issue 2/2021
Authors:
B.-A. Behrens, J. Uhe
Important notes

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1 State of the art

Over the last decades, lightweight construction has gained more and more importance in order to reduce weight and carbon emission as well as to save resources and meet governmental environment regulations. Consequent lightweight construction is a compelling necessity to further increase the efficiency of technical components and at the same time it represents the key to realising new technologies, such as electrical and hybrid vehicles. One way to reduce weight is to replace steel with high-strength steels, realise structural lightweight design or use light metals such as aluminium or magnesium. Additionally, increasing requirements on technical components due to locally varying mechanical and thermal loads in combination with downsizing lead to the demand for high-performance components with locally adapted properties. Mono-material components often feature limited qualities according to their respective material properties. To face this difficulty, the combination of different materials using hybrid components becomes more and more important.
Components with locally adapted properties, which are produced using tailored semi-finished products, are already state of the art in sheet metal forming. For tailored welded blanks, blanks with different sheet thicknesses or steel grades are first joined by laser welding and afterwards formed by press hardening. By using two different steels, areas with tensile strengths of over 1500 MPa and areas with significantly lower tensile strengths of approx. 600 MPa can be realised in a B-pillar [ 1].
Hybrid bulk metal parts are currently mainly produced by joining different materials either during or after the forming process. Suitable processes for joining by forming in bulk metal forming are for example compound forging [ 2], impact extrusion [ 3] or co-extrusion [ 4].
Only few studies on the forming of hybrid semi-finished workpieces in bulk metal forming exist so far. Domblesky et al. investigated the feasibility of welded preforms in forging. They stated that friction-welded preforms offer the potential to be used in bulk forming applications, but that further work is needed to develop the respective processes and methods [ 5]. Foydl et al. investigated the process chain of extrusion and subsequent die forging to produce steel-reinforced aluminium parts. It has been shown that it is generally possible to forge co-extruded profiles with a tight fit of the two materials. Hereby, only the matrix material was formed. Embedding elements with sharp edges and high degrees of deformation may lead to cracks in the aluminium matrix [ 6].

2 Vision and scope of the CRC 1153: tailored forming

As a consistent further development and transfer of the findings from sheet metal forming, the development of Tailored Forming process chains for bulk metal forming is carried out in the Collaborative Research Center (CRC) 1153. In addition to Leibniz Universität Hannover (LUH), Laserzentrum Hannover (LZH), Institut für integrierte Produktion Hannover (IPH) and the Technische Informationsbibliothek (TIB) take part in the CRC, resulting in 18 scientific research projects of 12 different institutes. Speaker of the CRC is Prof. Bernd-Arno Behrens, director of the Institut für Umformtechnik und Umformmaschinen (Forming Technology and Machines, IFUM) at the LUH.
The aim of the CRC 1153 is to realise new process chains to manufacture load-adjusted hybrid solid components by using joined semi-finished workpieces. The advantages of these novel process chains are the locally adapted properties due to the combination of appropriate materials, the use of geometrically simple semi-finished workpieces as well as the possibility to influence the joining zone geometrically and thermo-mechanically during the forming process.
Thus, the production of complex components better suited for the local requirements of different structural and functional areas than monomaterial parts becomes possible. The schematic novel process chain of the CRC 1153 is shown in Fig.  1 using a hybrid shaft as an exemplary component. First, the two different materials are joined. In the next step, the hybrid semi-finished product is formed. Heat treatment and finishing steps are carried out subsequently. Finally, the service life and quality of the component are investigated. Parallel to this, the design of Tailored Forming components as well as the material characterisation and simulation of the individual process steps is performed.
The benefits of combining different materials within one component are either the possible weight reduction or the reduction of expensive and limited alloying elements. For this purpose, the materials are arranged coaxially or serially, employing the material combinations aluminium-steel, steel-steel and aluminium-titanium. The research results of the CRC 1153 lead to the production of different demonstrator components, indicating the applicability and the potential of Tailored Forming technology. Some of the demonstrator components and corresponding semi-finished workpieces are shown in Fig.  2.
In order to realise the planned research work from the semi-finished workpiece to the finished component within the process chain, the CRC 1153 is structured in three project areas, mirroring the main research topics of the CRC, see Fig.  3. Due to the combination of different materials, a large number of research topics arises regarding joining processes, the formability and heating of hybrid semi-finished workpieces, their machining and handling. The investigations on the joining and forming of hybrid semi-finished workpieces are accompanied by various investigations regarding their design and quality control.
The research focus of project area A is on the geometrical design and manufacture of hybrid semi-finished workpieces by means of different joining processes. Here, both, the selection and conditioning of suitable material combinations and the development of the corresponding joining and heat treatment technologies are of great importance. The joining processes, co-extrusion, ultrasonic-assisted laser welding, deposition welding and friction welding are applied and modified to manufacture hybrid semi-finished workpieces within the CRC 1153. Special attention is paid to the production of a joining zone which can be further processed by forming without failure. In addition to the joining processes, locally adapted heat treatment is the focus of the project area.
The further processing of hybrid semi-finished workpieces to the final component by forming and machining with simultaneous preservation or improvement of the joining-zone properties is the main challenge of the research projects within project area B. Here, the design and development of different forming processes like cross-wedge rolling, die forging or impact extrusion as well as the machining processes take place. The possibilities and limits of shaping by means of forming and machining processes are investigated and extended while acquiring process-relevant characteristic data. To establish sustainable research data management according to the FAIR principles (Findable, Accessible, Interoperable, Re-usable) and to optimise the data flow along the process chains between the subprojects of the CRC 1153, a research data management system is developed in a separate sub-project.
From the metal-forming perspective, controlled material flow plays a central role, taking into account different flow properties of the respective material combination as well as the joining quality. In case of forming different materials at the same time, special attention must be paid to the inhomogeneous heating of hybrid semi-finished workpieces. In order to ensure inhomogeneous heating and process-oriented handling of the components, close cooperation with Project Area C is maintained. Forming and subsequent machining processes have to be adapted specifically to the hybrid semi-finished products generated in project area A. Intensive cooperation and continuous adaptation and optimisation of the respective processes are required to achieve adequate component quality. In the field of machining, new approaches to the automatic detection of joining zones and the targeted adjustment of residual stresses are being developed. The research work in project area A is supported by process-accompanying simulations and by the use of different test methods for the evaluation of the manufacturing quality from project area C.
Project area C is divided into the two main fields of process design and process development for the analysis and quality assurance of individual production steps along the entire process chain. Here, process design includes both, modeling of the respective tools as well as numerical analysis of the flow behaviour of the material combinations and the joining zone geometry. Furthermore, the development of numerical models and methods for the analysis of fundamental questions in the field of structural design, macro and microstructure simulation, damage prediction and lifetime analysis are other focuses of this project area. The experimental verification and validation of the models created is carried out in cooperation with the subprojects of project areas A and B, enabling predictions and conclusions regarding specific phenomena in the production process. For this purpose, standardised as well as specifically developed test methods are used. Thus, measuring methods for the non-destructive characterisation and monitoring of production quality from the hybrid semi-finished product to the usable component are developed. In addition, new general design and construction guidelines are to be developed and defined with regard to future application fields of hybrid components.

Acknowledgements

The results presented in this paper were obtained within the Collaborative Research Centre 1153 “Process chain to produce hybrid high performance components by Tailored Forming”, funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation)—252662854. The authors would like to thank the German Research Foundation for the financial support of this project.
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