Digital cellular solid pressure vessels: A novel approach for human habitation in space

Cellucci, Daniel; Jenett, Benjamin; Cheung, Kenneth C.

doi:10.1109/aero.2017.7943936

Cited by 3 publications

(3 citation statements)

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“…These modular building block based structures are intended U.S. Government work not protected by U.S. copyright to enable relatively simple robotic assembly of low massdensity structures with the capability to be disassembled and reassembled into varying configurations. These structures are envisioned to have broad utility, including as the primary structure for various applications including kilometer scale telescope arrays [1], large space habitats [2], spacecraft structures, or even as adaptable emergency ground structures.…”

Section: Introductionmentioning

confidence: 99%

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Geometry Systems for Lattice-Based Reconfigurable Space Structures

Ochalek

Jenett

Formoso

et al. 2019

2019 IEEE Aerospace Conference

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We describe analytical methods for the design of the discrete elements of ultralight lattice structures. This modular, building block strategy allows for relatively simple element manufacturing, as well as relatively simple robotic assembly of low mass density structures on orbit, with potential for disassembly and reassembly into highly varying and large structures. This method also results in a structure that is easily navigable by relatively small mobile robots. The geometry of the cell can allow for high packing efficiency to minimize wasted payload volume while maximizing structural performance and constructability. We describe the effect of geometry choices on the final system mechanical properties and automated robotic constructability of a final system. Geometric properties considered include number of attachments per voxel, number of attachments per coefficient of volume, and effects of vertex, edge, and face connectivity of the unit cell. Mechanical properties considered include strength scaling, modulus scaling, and packing efficiency of the lattice. Automated constructibility metrics include volume allowance for an end-effector, strut clearance angle for an endeffector, and packing efficiency. These metrics were applied to six lattice unit cell geometries: cube, cuboctahedron, octahedron, octet, rhombic dodecahedron, and truncated octahedron. A case study is presented to determine the most suitable lattice system for a specific set of strength and modulus scaling requirements while optimizing for ease of robotic assembly.

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Section: Introductionmentioning

confidence: 99%

“…Scaling factor was estimated due to the connectivity of the unit cell[23] 2. Scaling factor was experimentally determined by Gregg et al[6] 3.…”

mentioning

confidence: 99%

Geometry Systems for Lattice-Based Reconfigurable Space Structures

Ochalek

Jenett

Formoso

et al. 2019

2019 IEEE Aerospace Conference

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“…Cellular structures are also employed as structural parts in planes [68,69], space vehicles [70], sports equipment [71], etc. This is due to their superior strength to weight ratio which offers the required structural strength and stiffness while at the same time being lightweight.…”

Section: Applications Of Cellular Structuresmentioning

confidence: 99%

Optimization of 3D printable cellular array structures for cushioning

Jalil¹

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Chou Siaw Meng and Associate Professor Tai Kang. Their invaluable advice and patience throughout his candidature were truly appreciated. The author would also like to extend his appreciation to Professor Chua Chee Kai for opening the opportunity in pursuing his research in Singapore Centre for 3D Printing (SC3DP). Secondly, the author would like to thank the undergraduate and master students he mentored for their Final Year Projects (FYP), Undergraduate Research Experience on Campus (URECA) and master's dissertation projects for their help in the experiments and analyses providing valuable information to the author. The author is also grateful to fellow researcher in SC3DP, Ahmad Anwar for his companionship and support throughout the entire journey. The author also would like to thank other researchers who have helped along the way.

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Development and Robustness Characterization of a Digital Material Assembly System

Formoso

Trinh

et al. 2018

Procedia Manufacturing

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Digital cellular solid pressure vessels: A novel approach for human habitation in space

Cited by 3 publications

References 10 publications

Geometry Systems for Lattice-Based Reconfigurable Space Structures

Geometry Systems for Lattice-Based Reconfigurable Space Structures

Optimization of 3D printable cellular array structures for cushioning

Development and Robustness Characterization of a Digital Material Assembly System

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