TY - JOUR
T1 - Advanced manufacturing concept of a bio-inspired reaction wheel rotor for small- and medium-sized constellation satellites
AU - Kaiser, Nils
AU - Goossens, Nils
AU - Jimenez, Ane
AU - Laraudogoitia, Ignacio
AU - Psarras, Spyridon
AU - Tsantzalis, Stavros
N1 - Publisher Copyright:
© 2023, The Author(s).
PY - 2024/1
Y1 - 2024/1
N2 - The increasing number of constellation satellites requires re-thinking of the design and manufacturing process for reaction wheel rotors. Mass optimisation of reaction wheel rotors leads to cost reduction and performance increase. Those optimisations can be realised by taking ideas from nature. Therefore, design principles of diatoms were screened, abstracted and implemented in an algorithm-based design process. In this way, a bio-inspired rotor was created, which considers launch and in-operation loads, is capable of up to 7500 RPM and shows a compact design with a diameter of 282mm. Regarding mechanical performance, an energy density of 4661Jkg-1 and a mass moment of inertia ratio of 0.7584, which considers the component and an idealized design, could be achieved. Compared to a commercial rotor, this is equivalent to a similar inertia ratio and +85 % energy density, but +44 % mass due to manufacturing restrictions. Based on different boundary conditions, different first natural frequency for launch and operation conditions were obtained (658Hz and 210Hz). The new design was cast from nano-reinforced aluminium alloy (AlSi10Mg + Al2O3) in 3D-printed sand moulds that were produced via binder-jetting process. Thus, a hybrid manufacturing process was used, by combining additive manufacturing and casting. Post-processing of the cast part via turning and milling was performed to compensate distortion and achieve the required surface quality. Preliminary vibration measurements were performed, showing a large need for balancing to achieve low vibration emissions.
AB - The increasing number of constellation satellites requires re-thinking of the design and manufacturing process for reaction wheel rotors. Mass optimisation of reaction wheel rotors leads to cost reduction and performance increase. Those optimisations can be realised by taking ideas from nature. Therefore, design principles of diatoms were screened, abstracted and implemented in an algorithm-based design process. In this way, a bio-inspired rotor was created, which considers launch and in-operation loads, is capable of up to 7500 RPM and shows a compact design with a diameter of 282mm. Regarding mechanical performance, an energy density of 4661Jkg-1 and a mass moment of inertia ratio of 0.7584, which considers the component and an idealized design, could be achieved. Compared to a commercial rotor, this is equivalent to a similar inertia ratio and +85 % energy density, but +44 % mass due to manufacturing restrictions. Based on different boundary conditions, different first natural frequency for launch and operation conditions were obtained (658Hz and 210Hz). The new design was cast from nano-reinforced aluminium alloy (AlSi10Mg + Al2O3) in 3D-printed sand moulds that were produced via binder-jetting process. Thus, a hybrid manufacturing process was used, by combining additive manufacturing and casting. Post-processing of the cast part via turning and milling was performed to compensate distortion and achieve the required surface quality. Preliminary vibration measurements were performed, showing a large need for balancing to achieve low vibration emissions.
KW - Flywheel
KW - Mass reduction
KW - Nano-reinforced aluminium
KW - Optimisation
KW - Sand casting
KW - Vibration tests
UR - http://www.scopus.com/inward/record.url?scp=85151342185&partnerID=8YFLogxK
U2 - 10.1007/s12567-023-00489-w
DO - 10.1007/s12567-023-00489-w
M3 - Article
AN - SCOPUS:85151342185
SN - 1868-2502
VL - 16
SP - 73
EP - 86
JO - CEAS Space Journal
JF - CEAS Space Journal
IS - 1
ER -