Fast slicing orientation determining and optimizing algorithm for least volumetric error in rapid prototyping

“…Used MOO techniques Optimised objectives Cheng et al (1995) Weighted sum function Part accuracy; build time Lan et al (1997) Self-developed algorithm Surface quality; build time; complexity of support structure Alexander et al (1998) Self-developed algorithm Cost; support volume; contact area with support; surface accuracy McClurkin and Rosen (1998) Self-developed algorithm Build time; accuracy; surface finish Hur and Lee (1998) Genetic algorithm Part accuracy; build time; support structure volume Xu et al (1999) Self-developed algorithm Build cost; build time; building inaccuracy; surface finish Hur et al (2001) Genetic algorithm Build time; surface quality Masood et al (2003) Generic mathematical algorithm Volumetric error Thrimurthulu et al (2004) Genetic algorithm Surface finish; build time Pandey et al 2004Genetic algorithm Surface roughness; build time Kim and Lee (2005) Genetic algorithm Post-processing time and cost Ahn et al (2007) Genetic algorithm Post-machining time Canellidis et al (2009) Genetic algorithm Build time; surface roughness; post-processing time Padhye and Deb (2011) Genetic algorithm and particle swarm algorithm Surface roughness; build time Strano et al (2011) Genetic algorithm Surface roughness; energy consumption Zhang and Li (2013) Genetic algorithm Volumetric error Paul and Anand (2015) Genetic algorithm Cylindricity and flatness errors; support structure volume Ezair et al (2015) Self-developed algorithm Support structure volume Delfs et al (2016) Self-developed algorithm Surface quality; build time Luo and Wang (2016) Principal component analysis Volumetric error Zhang et al (2017) Genetic algorithm Build time; build cost; production quality Brika et al (2017) Genetic algorithm Surface roughness; build time; build cost; yield strength; tensile strength; elongation; vickers hardness; amount of support structure Chowdhury et al (2018) Genetic algorithm Support structure volume; support structure accessibility; surface area contacting support; number of build layers; number of small openings; number of sharp corners; mean cusp height Mi et al (2018) Point clustering algorithm Number of material changes Jaiswal et al (2018) Surrogate model Material error; geometric error Al-...…”

Section: Moo Methodsmentioning

confidence: 99%

“…attributes of build orientations), such as design requirements, build cost, build time, part accuracy, mechanical properties, and thermodynamic properties, to be optimal from an infinite number of theoretical orientations or a certain number of alternative orientations. The methods based on this principle mainly include the methods proposed by Cheng et al (1995), Lan et al (1997), Alexander et al (1998), McClurkin and Rosen (1998), Hur and Lee (1998), Xu et al (1999), Hur et al (2001), Masood et al (2003), Thrimurthulu et al (2004), Pandey et al (2004), Kim and Lee (2005), Ahn et al (2007), Canellidis et al (2009), Padhye and Deb (2011), Strano et al (2011), Zhang and Li (2013), Paul and Anand (2015), Ezair et al (2015), Delfs et al (2016), Luo and Wang (2016), Zhang et al (2017), Brika et al (2017), Chowdhury et al (2018), Mi et al (2018), Jaiswal et al (2018), Al-Ahmari et al (2018), Huang et al (2018), Raju et al (2018), and Golmohammadi and Khodaygan (2019). A brief summarisation of these methods is provided in Table 1.…”

Section: Related Workmentioning

confidence: 99%

Determination of optimal build orientation for additive manufacturing using Muirhead mean and prioritised average operators

Qin

Scott

et al. 2019

J Intell Manuf

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Build orientation determination is one of the essential process planning tasks in additive manufacturing since it has crucial effects on the part quality, post-processing, build time and cost, etc. This paper introduces a method based on fuzzy multiattribute decision making to determine the optimal build orientation from a finite set of alternatives. The determination process includes two major steps. In the first step, attributes that are considered in the determination and heterogeneous relationships of which are firstly identified. A fuzzy decision matrix is then constructed and normalised based on the values of the identified attributes, which are quantified by a set of fuzzy numbers. In the second step, two fuzzy number aggregation operators are developed to aggregate the fuzzy information in the normalised matrix. By comparing the aggregation results, a ranking of all alternative build orientations can then be generated. Two determination examples are used to demonstrate the working process of the proposed method. Qualitative and quantitative comparisons between the proposed method and other methods are carried out to demonstrate its feasibility, effectiveness, and advantages.

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“…Representative examples are the estimation models in Masood, Rattanawong, and Iovenitti (2003), Zhang and Li (2013), and Luo and Wang (2016). In the proposed method, the model in Luo and Wang (2016) is used to estimate the total volumetric error of an LPBF part in a given build orientation O. Firstly, the volumetric error of each facet in the STL model of an LPBF part in O is estimated via geometric analysis. The total volumetric error of the part in O is then obtained by calculating the sum of the volumetric error of all facets.…”

Section: Factor Value Estimationmentioning

confidence: 99%

Automatic determination of part build orientation for laser powder bed fusion

Qin

Shi

et al. 2020

Virtual and Physical Prototyping

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In this paper, an automatic determination method of part build orientation for laser powder bed fusion is presented. This method includes two steps. First, an existing facet clustering-based approach is applied to automatically generate the alternative orientations of a laser powder bed fusion part. Second, support volume, volumetric error, surface roughness, build time and build cost are considered. Their values in each alternative orientation are estimated by certain estimation models. The weights of these factors are determined via pairwise comparison. The weighted sum model is used to calculate a summary value of the factors in each alternative orientation. According to the calculated summary values, an optimal orientation to build the part is generated. To demonstrate the method, a set of part orientation cases are tested, and effectiveness analysis and efficiency and characteristic comparisons are reported. The demonstration results suggest that the proposed method can work for both regular and freeform surface models, produce stable and reasonable results and provide desired efficiency.

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Fast slicing orientation determining and optimizing algorithm for least volumetric error in rapid prototyping

Cited by 22 publications

References 21 publications

Error Analysis: How Precise is Fused Deposition Modeling in Fabrication of Bone Models in Comparison to the Parent Bones?

Error Analysis: How Precise is Fused Deposition Modeling in Fabrication of Bone Models in Comparison to the Parent Bones?

Determination of optimal build orientation for additive manufacturing using Muirhead mean and prioritised average operators

Automatic determination of part build orientation for laser powder bed fusion

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