An Efficient and Versatile Means for Assembling and Manufacturing Systems in Space

Dorsey, John T.; Doggett, William R.; Hafley, Robert A.; Komendera, Erik; Correll, Nikolaus; King, Bruce D.

doi:10.2514/6.2012-5115

Cited by 22 publications

(11 citation statements)

References 12 publications

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“…2,3 This "erectables" approach involves launching prefabricated strut components and using astronaut labor or telerobotic systems to connect them together to form truss support structures for large-aperture telescopes. Figure 2 shows examples of prototype components developed by the LaRC efforts, and Figure 3 show a large truss frame for a parabolic reflector assembled in the lab using this erectable technology.…”

Section: Prior Work On On-orbit Assembly and Fabricationmentioning

confidence: 99%

TRUSSELATOR: On-Orbit Fabrication of High-Performance Composite Truss Structures

Hoyt

Cushing

Slostad

et al. 2014

AIAA SPACE 2014 Conference and Exposition

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The Trusselator program is investigating the value proposition and technical feasibility of fabricating composite truss structures on-orbit to enable construction of high-power solar arrays, high-gain antennas, and other large spacecraft components. In the Phase I effort, we developed a number of conceptual approaches to constructing large solar arrays, identified approaches that could minimize the complexity of the system required to implement them, and performed structural analyses of the top candidates. These analyses indicate that onorbit fabrication could enable structural mass fraction reductions of 2-5X for many-meter trusses with respect to state-of-the-art deployable mast technologies. To validate technical feasibility, we developed a detailed design for a prototype Trusselator device capable of processing Carbon Fiber/thermoplastic tape feedstock to form long continuous lengths of composite truss. We constructed a prototype, and successfully demonstrated fabrication of multi-meter lengths of truss. We then performed mechanical testing of the truss samples that demonstrated that the truss samples achieve a higher 'bending stiffness efficiency' than flight-heritage deployable truss technologies.Moreover, this superior result was accomplished using 'standard modulus' carbon fiber materials, and integration of highmodulus carbon fiber and optimization of the process is projected to enable further ordersof-magnitude improvement in structural efficiency. This structural efficiency reduces the launch mass, launch cost, and stowed volume of support structures for solar arrays, antennas, and other spacecraft components. Future work on the Trusselator will focus on minimizing its size, weight, and power as well as demonstrating reliable operation in the thermal-vac environment.

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Section: Prior Work On On-orbit Assembly and Fabricationmentioning

confidence: 99%

TRUSSELATOR: On-Orbit Fabrication of High-Performance Composite Truss Structures

Hoyt

Cushing

Slostad

et al. 2014

AIAA SPACE 2014 Conference and Exposition

View full text Add to dashboard Cite

show abstract

“…Onboard sensors must also handle a stark distinction between sunlit 3 N is distinct from the part count due to intermediate steps. 4 To distinguish the experimental LRM and DM from the concepts presented earlier, they will be referred to as the LSMS and IPJR. and shaded components, which was not simulated in the laboratory.…”

Section: Solar Array Assembly Experimentsmentioning

confidence: 99%

“…In recent years, Langley Research Center has developed assembly methods to address some of these challenges [4] by distributing long reach manipulation tasks and precise positioning tasks between specialized agents, employing Simultaneous Localization and Mapping (SLAM) in the assembly workspace, using sequencing algorithms, and detecting and correcting errors. In [5], a heterogeneous team consisting of a long reach manipulator (LRM) and a dexterous manipulator (DM) collaborated to assemble and weld a flat truss made of titanium stock, which required the LRM and DM to collaborate in retrieving struts and nodes from a canister, the DM to position the nodes precisely, and the LRM to weld the struts and nodes together.…”

Section: Introductionmentioning

confidence: 99%

Structure assembly by a heterogeneous team of robots using state estimation, generalized joints, and mobile parallel manipulators

Komendera

Adhikari

Glassner

et al. 2017

2017 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

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Autonomous robotic assembly by mobile field robots has seen significant advances in recent decades, yet practicality remains elusive. Identified challenges include better use of state estimation to and reasoning with uncertainty, spreading out tasks to specialized robots, and implementing representative joining methods. This paper proposes replacing 1) self-correcting mechanical linkages with generalized joints for improved applicability, 2) assembly serial manipulators with parallel manipulators for higher precision and stability, and 3) all-in-one robots with a heterogeneous team of specialized robots for agent simplicity. This paper then describes a general assembly algorithm utilizing state estimation. Finally, these concepts are tested in the context of solar array assembly, requiring a team of robots to assemble, bond, and deploy a set of solar panel mockups to a backbone truss to an accuracy not built into the parts. This paper presents the results of these tests.1 E. E. Komendera is with the Structural Mechanics and Concepts Branch,

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“…Robotic assembly of truss structures has typically taken the form of multi-degree of freedom (DOF) industrial robot arms that place discrete truss segments into larger structural configurations [6]. In order to increase attainable build volume, linear stages are built for the arm to translate around the structure it builds.…”

Section: Figure 2 Coordinate Frames Of Major Links and Their Offsetmentioning

confidence: 99%

Relative Robots: Scaling Automated Assembly of Discrete Cellular Lattices

Carney

Jenett

2016

Volume 2: Materials; Biomanufacturing; Properties, Applications and Systems; Sustainable Manufacturing

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We propose metrics for evaluating the performance of robotically assembled discrete cellular lattice structures (referred to as digital materials) by defining a set of tools used to evaluate how the assembly system impacts the achievable performance objective of relative stiffness. We show that mass-specific stiffness can be described by the dependencies E*(γ, D(n, f, RA)), where E* is specific modulus, γ is lattice topology, and the allowable acceptance of the joint interface, D, is defined by an error budget analysis that incorporates the scale of the structure, and/or number of discrete components assembled, n, the type of robotic assembler, RA, and the static error contributions due to tolerance stack-up in the specified assembler structural loop, and the dynamic error limitations of the assembler operating at specified assembly rates, f. We refer to three primary physical robotic construction system topologies defined by the relationship between their configuration workspace, and the global configuration space: global robotic assembler (GR), mobile robotic assembler (MR), and relative robotic assemblers (RR), each exhibiting varying sensitivity to static, and dynamic error accumulation. Results of this analysis inform an iterative machine design process where final desired material performance is used to define robotic assembly system design parameters.

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An Efficient and Versatile Means for Assembling and Manufacturing Systems in Space

Cited by 22 publications

References 12 publications

TRUSSELATOR: On-Orbit Fabrication of High-Performance Composite Truss Structures

TRUSSELATOR: On-Orbit Fabrication of High-Performance Composite Truss Structures

Structure assembly by a heterogeneous team of robots using state estimation, generalized joints, and mobile parallel manipulators

Relative Robots: Scaling Automated Assembly of Discrete Cellular Lattices

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