Additive Manufacturing and Mechanical Performance of Trifurcated Steel Joints for Architecturally Exposed Steel Structures

He, Pengfei; Du, Wenfeng; Wang, Longxuan; Kiran, Ravi; Yang, Mijia

doi:10.3390/ma13081901

Cited by 8 publications

(2 citation statements)

References 28 publications

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“…Another study that examined trifurcated 3D printed 316L steel joints using SLM processing showed that maximal discrepancies were < 5%. [23] As specially the printing axes I and II showed the highest deviations, it might be necessary to avoid printing large solid volumes. During the cooling process, the solid specimens may deform due to their weight.…”

Section: Discussionmentioning

confidence: 99%

Influence of printing procedure and printing axis of dental alloys on dimensional accuracy, surface roughness, and porosity

Berger¹,

Graf²,

Rohr³

2022

APOS

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Objectives: This study aimed to evaluate the printing procedure and printing axis and its influence on the dimensional accuracy, surface roughness, porosity, and strength of 3D-printed dental alloys used in orthodontics prepared using binder jetting (BJ), electron beam melting (EBM), or selective laser melting (SLM). Material and Methods: Specimens with a dimension of 50 mm × 12 mm were produced using BJ, EBM, and SLM techniques of dental alloys and were printed either along the X-, Y-, or Z-axis (n = 8 per group). Specimen dimension was chosen according to the ISO standard 6892-1 for tensile strength test specimens. Surface roughness parameters Sa, Sz, Sq, and Ssk were obtained using a 3D laser microscope and porosities were visualized with scanning electron microscopy (SEM). The specimen surfaces were optically scanned and volumetric deviations from the original stereolithography files were calculated. Afterward, tensile strength was measured. Results: The printing method and printing axis significantly affected surface roughness parameters (P < 0.05). Overall, the lowest surface roughness Sa values were found for BJ (9.1 ± 3.4 µm) followed by SLM (39.8 ± 24.2 µm) and EBM (50.4 ± 6.4 µm). BJ showed the smallest dimensional deviation followed by EBM and SLM. SEM analysis revealed a porous structure of BJ while fewer pores were observed on EBM and SLM samples. The ultimate tensile strength was only determined for BJ (495 ± 6 MPa) and EBM (726 ± 50 MPa) as the strength of SLM superseded the strength of the holder of the universal testing machine. Conclusion: BJ printing provides the highest dimensional accuracy with the smoothest surfaces irrespective of the printing axis. However, the remaining porosities owed to this printing procedure may have decreased the strength of the material.

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Section: Discussionmentioning

confidence: 99%

Influence of printing procedure and printing axis of dental alloys on dimensional accuracy, surface roughness, and porosity

Berger¹,

Graf²,

Rohr³

2022

APOS

View full text Add to dashboard Cite

show abstract

“…Zhou et al [ 21 ] used additive manufacturing technology to prepare 316L stainless steel standard parts and performed tensile property tests. He et al [ 22 ] studied the 3D modeling and printing of tree-like structure joints and verified the mechanical properties of 3D-printed joints through finite element simulation and experimental study. Combining the two aspects, topology optimization is an effective way to realize the optimal design of joints, and additive manufacturing can quickly manufacture high-precision complex joints.…”

Section: Introductionmentioning

confidence: 99%

Innovative Joint for Cable Dome Structure Based on Topology Optimization and Additive Manufacturing

Wang

Zhu

et al. 2021

Materials

Self Cite

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Aiming at the problems of a low material utilization rate and uneven stress distribution of cast-steel support joints in cable dome structures, topology optimization and additive manufacturing methods are used for optimization design and integrated manufacturing. First, the basic principle and calculation process of topology optimization are briefly introduced. Then, the initial model of the support joint is calculated and analyzed by using the universal software ANSYS Workbench 2020R2 and Altair OptiStruct, and the optimized joint is imported into Discovery Live to smooth the surface. The static behaviors of three types of joints (topology-optimized joints, joints after the smoothing treatment, and joints from practical engineering) are compared and analyzed. Finally, the joints are printed by using fused deposition modeling (FDM) technology and laser-based powder bed fusion (LBPBF) technology in additive manufacturing. The results show that the new support joint in the cable dome structure obtained by the topology optimization method has the advantages of a novel shape, a high material utilization rate, and a uniform stress distribution. Additive manufacturing technology can allow the manufacture of complex shape components with high precision and high speed. The combination of topology optimization and additive manufacturing effectively realizes the advanced design and integrated manufacturing of support joints for cable dome structures.

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Novel machine learning approach for shape-finding design of tree-like structures

Zhao

Wang

et al. 2022

Computers & Structures

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Additive Manufacturing and Mechanical Performance of Trifurcated Steel Joints for Architecturally Exposed Steel Structures

Cited by 8 publications

References 28 publications

Influence of printing procedure and printing axis of dental alloys on dimensional accuracy, surface roughness, and porosity

Influence of printing procedure and printing axis of dental alloys on dimensional accuracy, surface roughness, and porosity

Innovative Joint for Cable Dome Structure Based on Topology Optimization and Additive Manufacturing

Novel machine learning approach for shape-finding design of tree-like structures

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