Abstract
Ceramics are repeatedly investigated as packaging materials because of their gas tightness, e.g., as hermetic implantable housing. Recent advances also make it possible to print the established aluminum oxide in a Fused Filament Fabrication process, creating new possibilities for manufacturing personalized devices with complex shapes. This study was able to achieve integration of channels with a diameter of 500 µm (pre-sintered) with a nozzle size of 250 µm (layer thickness 100 µm) and even closed hemispheres were printed without support structures. During sintering, the weight-bearing feedstock shrinks by 16.7%, resulting in a relative material density of 96.6%. The well-known challenges of the technology such as surface roughness (Ra = 15–20 µm) and integrated cavities remain. However, it could be shown that the hollow structures in bulk do not represent a mechanical weak point and that the material can be gas-tight (<10−12 mbar s−1). For verification, a volume-free helium leak test device was developed and validated. Finally, platinum coatings with high adhesion examined the functionalization of the ceramic. All the prerequisites for hermetic housings with integrated metal structures are given, with a new level of complexity of ceramic shapes available.
Highlights
Technical ceramics are preferred materials, especially in demanding use cases, such as aerospace components and medical implants
The binder component Low-Density Polyethylene (LDPE) ensured the stability of the green body
In the subsequent sintering process, the technical ceramics are brought into a firm bond
Summary
Technical ceramics are preferred materials, especially in demanding use cases, such as aerospace components and medical implants. In these applications, ceramics are often used instead of polymers to achieve longevity in aggressive environments. Ceramic-based circuit boards [1] or implant housings are of particular interest [2,3]. Both applications benefit from the wide temperature stability and from the electrical properties and low permittivity for gases. Many alumina ceramics are considered biocompatible and biostable and have excellent electrical insulation properties [5]. The subtractive manufacturing process of the substrates limits the possible housing shape, and the screen printing process is only possible on flat surfaces
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