Artificial neural network-based geometry compensation to improve the printing accuracy of selective laser melting fabricated sub-millimetre overhang trusses

Hong, Richang; Zhang, Lei; Lifton, Joseph; Daynes, Stephen; Wei, Jun; Feih, S.; Lu, Wen Feng

doi:10.1016/j.addma.2020.101594

Cited by 23 publications

(6 citation statements)

References 47 publications

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“…Wang et al [31] discussed the support structures of partial dentures. In the next step of the present study, the same building orientation as that of a clinical clasp [20] without the cylindrical chucking part would be used by developing a geometry compensation methodology [32] for the chucking part.…”

Section: Discussionmentioning

confidence: 99%

Comparison of the fatigue life of pure titanium and titanium alloy clasps manufactured by laser powder bed fusion and its prediction before manufacturing

et al. 2023

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In this study, the fatigue properties of additively manufactured titanium clasps were compared with those of commercially pure titanium (CPTi) and Ti-6Al-4V (Ti64), manufactured using laser powder-bed fusion. Methods: Fourteen specimens of each material were tested under the cyclic condition at 1 Hz with applied maximum strokes ranging from 0.2 to 0.5 mm, using a small stroke fatigue testing machine. A numerical approach using finite element analysis (FEA) was also developed to predict the fatigue life of the clasps. Results: The results showed that although no significant differences were observed between the two materials when a stroke larger than 0.35 mm was applied, CPTi had a better fatigue life under a stroke smaller than 0.33 mm. The distributions of the maximum principal stress in the FEA and the fractured position in the experiment were in good agreement. Conclusions: Using a design of the clasp of the present study, the advantage of the CPTi clasp in its fatigue life under a stroke smaller than 0.33 mm was revealed experimentally. Furthermore, the numerical approach using FEA employing calibrated parameters for the Smith-Watson-Topper method are presented. Under the limitations of the aforementioned clasp design, the establishment of a numerical method enabled us to predict the fatigue life and ensure the quality of the design phase before manufacturing.

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Section: Discussionmentioning

confidence: 99%

Comparison of the fatigue life of pure titanium and titanium alloy clasps manufactured by laser powder bed fusion and its prediction before manufacturing

et al. 2023

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“…In the case of Ruochen's study, a geometric prediction model based on artificial neural network (ANN) was created by collecting extensive data on the overhang angle using a dome-shaped truss lattice structure with various overhang angles applied to predict and complement the shape according to the overhang angle. [19]. Kenneth et al modeled and simulated the heat to solve the heat distortion that occurs in a thin sculpture with an overhang, and based on this, modeled a non-contact heat dissipating sculpture different from the existing supporters [20].…”

Section: Resultsmentioning

confidence: 99%

Selective Laser Melting Process for Sensor Embedding into SUS316L with Heat Dissipative Inner Cavity Design

et al. 2021

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Artificial intelligence and Internet of Things (IoT) technology, which are the core of the 4th industrial revolution, can resolve many problems that optimization of production times in the manufacturing process and reduction of materials required etc. In order to utilize the 4th industrial revolution technology, real-time monitoring technology of metal parts is essential, so technology for embedding sensors and IC chips into parts is essential. Using metal 3d printing technology, it is possible to embed IC chips into metal parts, which was impossible because of the existing high-temperature metal manufacturing process of casting or forging. Here we introduce a novel new method for sensor embedding into SUS316L by hemisphere design to avoid direct laser exposure onto sensors during selective laser melting process. Thermal and microstructural analysis was carried out to characterize the property of inner hemisphere for safe thermal couple embedding into SUS316L.

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“…During the SLM printing process, a laser melts the powder and the liquid metal pool will seep into the powder below, creating an irregular under surface in overhanging regions (Hong, et al 2021). As the metal solidifies and cools, the thermally induced residual stresses tend to lift the part upwards, which can cause permanent deformation of the part and/or a collision with the recoat blade .…”

Section: Configuration A: Supported Structure Under Gravity Loadingmentioning

confidence: 99%

Simultaneous optimisation of support structure regions and part topology for additive manufacturing

Daynes

2022

Struct Multidisc Optim

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Support structures are required to enable the build of additively manufactured parts. The supports reinforce overhanging regions on the part and/or counteract the thermally-induced residual stresses generated during printing. However, the optimal design of the part for its intended use case is decoupled from the design of the support structures in a conventional design for additive manufacturing (DfAM) workflow. In this work, a novel methodology is presented that simultaneously optimises the part topology and its support structure regions. A two-model topology optimisation approach is considered. One model describes the combined part and support structure regions subject to a pseudo-gravity load and a second model describes the part subject to its intended application load cases. A novel load-aligned trunk and branch support structure is generated from the topology optimisation results. Generating the fine support features in a post-processing step avoids the computational expense of topology optimising the intricate supports directly. Thermo-mechanical simulations of a selective laser melting process confirms that this new approach to optimising support structures can reduce manufacturing process-induced deformation when benchmarked against a conventional DfAM workflow.

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Artificial neural network-based geometry compensation to improve the printing accuracy of selective laser melting fabricated sub-millimetre overhang trusses

Cited by 23 publications

References 47 publications

Comparison of the fatigue life of pure titanium and titanium alloy clasps manufactured by laser powder bed fusion and its prediction before manufacturing

Comparison of the fatigue life of pure titanium and titanium alloy clasps manufactured by laser powder bed fusion and its prediction before manufacturing

Selective Laser Melting Process for Sensor Embedding into SUS316L with Heat Dissipative Inner Cavity Design

Simultaneous optimisation of support structure regions and part topology for additive manufacturing

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