.css-1xsl8rf{width:100%;display:-webkit-box;display:-webkit-flex;display:-ms-flexbox;display:flex;-webkit-align-items:center;-webkit-box-align:center;-ms-flex-align:center;align-items:center;position:relative;overflow:hidden;background:var(--alert-bg);-webkit-padding-start:var(--chakra-space-4);padding-inline-start:var(--chakra-space-4);-webkit-padding-end:var(--chakra-space-4);padding-inline-end:var(--chakra-space-4);padding-top:var(--chakra-space-1);padding-bottom:var(--chakra-space-1);--alert-fg:var(--chakra-colors-orange-600);--alert-bg:var(--chakra-colors-orange-100);font-weight:var(--chakra-fontWeights-semibold);padding-left:var(--chakra-space-4);}.chakra-ui-dark .css-1xsl8rf:not([data-theme]),[data-theme=dark] .css-1xsl8rf:not([data-theme]),.css-1xsl8rf[data-theme=dark]{--alert-fg:var(--chakra-colors-orange-200);--alert-bg:rgba(251, 211, 141, 0.16);}@media screen and (min-width: 48em){.css-1xsl8rf{padding-left:var(--chakra-space-8);}}Bitte aktivieren Sie Javascript um alle Funktionen nutzen zu können und ihre Nutzererfahrung zu verbessern.

Short Talk
ST 21

Surface and Infill optimization of binder based 3D-printed (FGF) biodegradable Mg-0.6Ca-alloy implant prototypes

Termin

Datum: 14.09.2023

Zeit: 12:45 – 13:00

Redezeit: 10 Min.

Diskussionszeit: 5 Min.

Ort / Stream:

Lecture hall 7

Session

Additive Manufacturing

Thema

Implant associated

Mitwirkende

Martin Wolff (Geesthacht, DE), H. Lüneburg (Geesthacht, DE), M. W. Rackel (Geesthacht, DE), E. Nidadawolu (Geesthacht, DE), T. Ebel (Geesthacht, DE), Prof. Dr. Regine Willumeit-Römer (Geesthacht, DE)

Abstract

Abstract text (incl. figure legends and references)

Introduction

Fused Granular Fabrication (FGF) is a binder based 3D-printing technique which enable manufacturing of complex shaped parts, even with hollow infill structure at dense shell or scaffold like strut structures (Fig. 1).

Figure 1: 3D-printed Mg-alloy scaffold.

For the 3D-printing process, feedstock granules made from spherical metal powder and polymer binder components are needed. Identical feedstock is used for Metal Injection Molding (MIM) a near net shape industrial mass production technique.

Objectives

Aim of this investigation is the optimization of the 3D-printed surface morphology and the infill quality of the dense matrix of a 3D-printed implant. Both is in need for optimal performance of bone implants which are placed close to tendons and ligaments – smooth surface roughness and homogeneous metal morphology. The MIM processing was used as a reference route within this study.

Materials & Methods

Spherical Mg- and Mg-10Ca-powder of particle size below 45 µm as well as polymer binder components (wax, stearic acid, PPcoPE) were used for the feedstock preparation in a planetary mixer. The 3D-printing was performed using an AIM3D ExAM255 machine. Sintering was done using a hot wall furnace (MUT, RRO350-900). All details of processing and sintering are publishes elsewhere [1].

Results

As shown in Fig. 2a, optimization of printing parameters using a 0.3 mm nozzle at 0.09 mm layer high and 6 mm/s printing speed results in significant enhancement of the specimens surface quality and density (see x-ray in Figure 2b).

Fig. 2

Conclusion

It could be demonstrated that binder based 3D-printing technique is able to produce parts with smooth surface roughness and a pore free matrix, obtaining no delamination or density differences using fine powder, thin printing nozzle and minimum layer highness. Further investigations will focus on additional electro- and laser-polishing.

Reference

1 Wolff, M. et al, 2016, MIM of Magnesium and Its Alloys, Metals, 6, 118.