Welf‐Guntram Drossel scite author profile

In this work, we use laser powder bed fusion (LPBF) to produce Nd-Fe-B magnets. A suitable process window is developed, which allows to fabricate isotropic samples with outstanding magnetic performance. The sample quality is mainly defined by the energy input during LPBF and sintering or delamination occurs, if the process parameter are improperly adjusted. Magnetic and structural properties become better as energy input increases, until the material-specific limit for processability has been reached. Magnets with coercivity of 886 kA/m (µ 0 H c = 1.1 T) and maximum energy product of 63 kJ/m 3 can be produced from Nd-lean commercial powder without any post treatment. Thereby, our samples represent the new benchmark for permanent magnets produced by additive manufacturing. On the example of coercivity, the impact of laser power, scan velocity and hatch spacing is discussed. It is shown that coercivity can be sufficiently well described by a simple phenomenological model.

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Smart3 – Smart Materials for Smart Applications

Drossel

Kunze

Bucht

et al. 2015

Procedia CIRP

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Validation of density–elasticity relationships for finite element modeling of human pelvic bone by modal analysis

Scholz

Hoffmann

Sachsen

et al. 2013

Journal of Biomechanics

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Resource and Energy Efficiency in Machining Using High-Performance and Hybrid Processes

et al. 2012

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Gathering of Process Data through Numerical Simulation for the Application of Machine Learning Prognosis Algorithms

Jäckel

Falk

Georgi

et al. 2020

Procedia Manufacturing

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Generation of functional surfaces by using a simulation tool for surface prediction and micro structuring of cold-working steel with ultrasonic vibration assisted face milling

Börner

Winkler

Junge

et al. 2018

Journal of Materials Processing Technology

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The effect of stent graft oversizing on radial forces considering nitinol wire behavior and vessel characteristics

Senf

Sachsen²,

Neugebauer

et al. 2014

Medical Engineering & Physics

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Novel concept of a modular hip implant could contribute to less implant failure in THA: a hypothesis

et al. 2018

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BackgroundThe modularity in total hip arthroplasty (THA) allows orthopaedic surgeons for an exact reconstruction of hip biomechanical parameters especially in revision and tumor arthroplasty. Modular structured femoral stems using taper junctions showed increased implant breakage in the recent past.Presentation of the hypothesisWe hypothesize that a novel modular stem-neck-interface leads to less implant breakage compared to conventional femoral stems.Testing of the hypothesisFor this purpose, a novel modular femoral stem for THA was to design and manufacture. Therefore, three different variants of interface mechanisms were developed that enable a simple connection between the stem and the neck modules and allow for intra-operatively adjustment. Three prototypes A, B and C were manufactured and subsequently dynamic fatigue (ISO 7206–6) and body donor tested.Implication of the hypothesisModularity in THA is mainly applied in THA as well as in revision and tumor arthroplasty. Modular implants are barely used because of the high risk of breakage. Another risks in this context are taper fretting, corrosion and disconnection. With the novel design, it should be possible to detach the stem and neck module intra-operatively to adapt the anatomical situation. The novel coupling mechanism of the rotating interface seems to be the most suitable for a secure stem-neck connection and is characterized by good intraoperative handling.

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