Lateral Angular Co-Extrusion: Geometrical and Mechanical Properties of Compound Profiles

Thürer, Susanne Elisabeth; Peddinghaus, Julius; Heimes, Norman; Bayram, Ferdi Caner; Bal, Burak; Uhe, Johanna; Behrens, Bernd‐Arno; Maier, Hans Jürgen; Klose, Christian

doi:10.3390/met10091162

Cited by 11 publications

(25 citation statements)

References 15 publications

(25 reference statements)

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“…The workpieces were fabricated by machining, fitted together with a tolerance H7/g6 for a diameter of 44 mm (clearance fit) without metallurgical bonding, and subsequently formed to the final geometry. The steel thickness investigated in this work was chosen by analogy with the coextrusion process, which produces hybrid workpieces with initial bonds for further investigation, in order to be able to make a comparison [ 20 ].…”

Section: Methodsmentioning

confidence: 99%

Challenges in the Forging of Steel-Aluminum Bearing Bushings

et al. 2021

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The current study introduces a method for manufacturing steel–aluminum bearing bushings by compound forging. To study the process, cylindrical bimetal workpieces consisting of steel AISI 4820 (1.7147, 20MnCr5) in the internal diameter and aluminum 6082 (3.2315, AlSi1MgMn) in the external diameter were used. The forming of compounds consisting of dissimilar materials is challenging due to their different thermophysical and mechanical properties. The specific heating concept discussed in this article was developed in order to achieve sufficient formability for both materials simultaneously. By means of tailored heating, the bimetal workpieces were successfully formed to a bearing bushing geometry using two different strategies with different heating durations. A metallurgical bond without any forging defects, e.g., gaps and cracks, was observed in areas of high deformation. The steel–aluminum interface was subsequently examined by optical microscopy, scanning electron microscopy (SEM) and energy dispersive spectroscopy (EDS). It was found that the examined forming process, which utilized steel–aluminum workpieces having no metallurgical bond prior to forming, led to the formation of insular intermetallic phases along the joining zone with a maximum thickness of approximately 5–7 µm. The results of the EDS analysis indicated a prevailing FexAly phase in the resulting intermetallic layer.

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Section: Methodsmentioning

confidence: 99%

Challenges in the Forging of Steel-Aluminum Bearing Bushings

et al. 2021

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“…• Conventional billets: This variant is based on the use of mono-material billets without reinforcement, as these are Fig. 1 Schematic Tailored Forming process chain for the demonstrator component of the hybrid bearing bushing, starting with a Lateral Angular Co-Extrusion (LACE) process for the manufacture of the bi-metal semi-finished products and subsequent forming into the aluminum/steel bulk metal component by die forging; according to [5] commonly used in industrial extrusion approaches. The reinforcing element is thus, introduced into the forming zone from the outside and, unlike the matrix material, not deformed plastically [11].…”

Section: Manufacturing Of Hybrid Workpieces By Co-extrusionmentioning

confidence: 99%

“…Recent investigations by Thürer et al employing a new tool design at near-industrial scale as well as 20MnCr5 steel tubes as reinforcing elements have already shown that sufficiently coaxial aluminum-steel hollow profiles featuring reinforcement contents of both 14 vol% and 34 vol% can be successfully achieved. In addition, shear strengths of up to 58 MPa ± 15 MPa were determined on sample segments that included the joining zone, which indicated the presence of a metallurgical bond by adhesion of aluminum to the steel [5]. For the planned subsequent die forging step within the Tailored Forming process chain (compare schematic process chain in Fig.…”

Section: Manufacturing Of Hybrid Workpieces By Co-extrusionmentioning

confidence: 99%

“…Since the LACE process is used to encase a rigid reinforcement with a light metal, a mandrel component was designed, which is held in the tool by three support arms, arranged at an angle of 120° to each other. The procedure for this specific LACE process has been described recently by Thürer et al [5] and Fig. 2b shows four steps of the simulated material flow of the aluminum.…”

Section: Lace Process For the Production Of Hybrid Hollow Profilesmentioning

confidence: 99%

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Process chain for the manufacture of hybrid bearing bushings

Thürer

Chugreeva

Heimes

et al. 2021

Prod. Eng. Res. Devel.

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The current study presents a novel Tailored Forming process chain developed for the production of hybrid bearing bushings. In a first step, semi-finished products in the form of locally reinforced hollow profiles were produced using a new co-extrusion process. For this purpose, a modular tool concept was developed in which a steel tube made of a case-hardening steel, either C15 (AISI 1015) or 20MnCr5 (AISI 5120), is fed laterally into the tool. Inside the welding chamber, the steel tube is joined with the extruded aluminum alloy EN AW-6082. In the second step, sections from the compound profiles were formed into hybrid bearing bushings by die forging. In order to set the required forming temperatures for each material—aluminum and steel—simultaneously, a tailored heating strategy was developed, which enabled successful die forging of the hybrid workpiece to the desired bearing bushing geometry. Using either of the case-hardening steels in combination with aluminum, this novel process chain made it possible to produce intact hybrid bearing bushings, which showed both macroscopically and microscopically intimate material contact inside the compound zone.

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“…The required materials are joined to hollow steel-aluminium profiles by a co-extrusion process. After the joining, there is a metallurgical bond without intermetallic phase in the interface zone [23]. The presented work considers a strategy for setting the required temperature gradient in the above-described workpieces before the forging process.…”

Section: Bearing Bushingmentioning

confidence: 99%

A design concept of active cooling for tailored forming workpieces during induction heating

Ince

Chugreeva

Böhm

et al. 2021

Prod. Eng. Res. Devel.

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The demand for lightweight construction is constantly increasing. One approach to meet this challenge is the development of hybrid components made of dissimilar materials. The use of the hybrid construction method for bulk components has a high potential for weight reduction and increased functionality. However, forming workpieces consisting of dissimilar materials requires specific temperature profiles for achieving sufficient formability. This paper deals with the development of a specific heating and cooling strategy to generate an inhomogeneous temperature distribution in hybrid workpieces. Firstly, the heating process boundaries with regard to temperature parameters required for a successful forming are experimentally defined. Secondly, a design based on the obtained cooling strategy is developed. Next a modelling embedded within an electro-thermal framework provides the basis for a numerical determination of admissible cooling rates to fulfil the temperature constraint. Here, the authors illustrate an algorithmic approach for the optimisation of cooling parameters towards an effective minimum, required for applicable forming processes of tailored forming.

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Lateral Angular Co-Extrusion: Geometrical and Mechanical Properties of Compound Profiles

Cited by 11 publications

References 15 publications

Challenges in the Forging of Steel-Aluminum Bearing Bushings

Challenges in the Forging of Steel-Aluminum Bearing Bushings

Process chain for the manufacture of hybrid bearing bushings

A design concept of active cooling for tailored forming workpieces during induction heating

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