Stereolithography build time estimation based on volumetric calculations

Campbell, Ian; Combrinck, Jacques; Beer, Deon de; Barnard, L.J.

doi:10.1108/13552540810907938

Cited by 45 publications

(25 citation statements)

References 5 publications

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“…Stereolithography, selective laser sintering, and similar technologies are limited by how fast the material in use reacts to the energy source. They also require the build platform be recoated with material after each layer is completed, requiring additional time [34]. Direct deposition processes, like fused deposition modeling, are limited by how quickly the material can be extruded from the print head.…”

Section: Process Specific Variablesmentioning

confidence: 99%

Ten challenges in 3D printing

Oropallo

Piegl

2015

Engineering with Computers

319

170

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predominantly in two ways: (1) material is removed from a stock, or (2) material is added to a part in progress that started out as a non-existent entity, e.g., an empty moving table or a box of powder with no part being solidified, depending on the type of manufacturing process being deployed. 3D printing is a technology that adds material to produce the part, and hence, it is also called additive manufacturing. Our notion of printing involves transferring ink to paper, line-by-line until the document is completed. Generalizing this process to 3D would involve transferring material to 3D space layer-by-layer till the object is completed. Since most of the 3D printers manufacture objects layer-by-layer, the term 3D printing struck.Since our 2D printers have become such common, and by-and-large, fairly reliable machines, this may create the impression that going from 2D to 3D is a straightforward task. The third dimension has always posed a challenge to mankind (according to surveys we performed, a significant percentage of people are 3D blind), so much so that we believe that 3D printing will be no exception. The ten challenges below illustrate the rocky road ahead and show that this technology may not be as disruptive, at least in the short term, as the media wants the public to believe. The list is by no means exhaustive and it represents our understanding of and opinion about the technology. We selected what we believed to be the most relevant papers for this review. Challenge 1: shape optimizationOptimization of the design space is made possible with additive manufacturing since the process has the ability to fill the interior part of the object in practically infinite ways. The design space is any area of the model that can be Abstract Three dimensional printing has gained considerable interest lately due to the proliferation of inexpensive devices as well as open source software that drive those devices. Public interest is often followed by media coverage that tends to sensationalize technology. Based on popular articles, the public may create the impression that 3D printing is the Holy Grail; we are going to print everything as one piece, traditional manufacturing is at the brink of collapse, and exotic applications, such as cloning a human body by 3D bio-printing, are just around the corner. The purpose of this paper is to paint a more realistic picture by identifying ten challenges that clearly illustrate the limitations of this technology, which makes it just as vulnerable as anything else that had been touted before as the next game changer.

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Section: Process Specific Variablesmentioning

confidence: 99%

Ten challenges in 3D printing

Oropallo

Piegl

2015

Engineering with Computers

319

170

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“…It is also somewhat restricted by the capability of the additive process. Due to the majority of engineering parts being prismatic or cylindrical (Campbell et al 2008), the iAtractive process is designed primarily for prismatic part production. However, the increasing customer demands lead to a paradigm shift, which stimulates and increases the needs for customised products with complex structures.…”

Section: Discussionmentioning

confidence: 99%

“…existing part with final features, with non-final features, and with both final and non-final features. As the iAtractive process is designed primarily for prismatic part manufacture and the majority of engineering parts are prismatic or cylindrical (Campbell et al 2008), this study is focused on prismatic part manufacture. Therefore, six types of features are considered, which are boss, pocket, hole, slot, step and planar face.…”

Section: Definitions Of Materials Reuse and Classification Of Existingmentioning

confidence: 99%

A novel decision-making logic for hybrid manufacture of prismatic components based on existing parts

2014

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The on-going industrial trend towards high value sustainable manufacturing has led to the emergence of hybrid manufacturing processes. This new generation of processes combines the capabilities of a number of individual manufacturing processes on a single platform. Despite the fact that the drawbacks of individual processes have been significantly reduced, the application of hybrid technology has always been constrained by the capabilities of their constituent processes, in particular the capability to utilise various raw materials in terms of shape and size. This paper introduces a novel concept of hybrid process, which consists of combining additive, subtractive and inspection processes. A feature-based decision-making logic is developed, enabling the hybrid process to reuse existing parts/legacy products. An existing part is first measured for obtaining its geometrical information. Feasible manufacturing strategies are provided and then additive, subtractive and inspection processes are utilised interchangeably to add and/or remove material, transforming the existing part into the final part. This indicates that the iAtractive process is not restricted by raw material geometries. Three identical test parts were manufactured from three existing different shaped parts, demonstrating the efficacy of the proposed hybrid process and the decisionmaking logic in material reuse. New features can be added onto the existing parts and existing features can be removed or further manufactured, giving these parts additional lives, new uses and increased functionality.

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“…Commercially available rapid prototyping software packages contain build time estimation functionality (Campbell et al ), as do the machine software suites sold in bundles with additive systems (Ruffo et al ). Offering a framework for the classification of AM build time estimators, Di Angelo and Di Stefano () argue that the existing approaches can be divided into “detailed‐analysis” methods based on knowledge of the inner workings of AM systems and “parametric” methods informed by data on a set of process characteristics such as layer thickness, hatch distance, and laser scan velocity.…”

Section: Methodsmentioning

confidence: 99%

“…Build time estimation forms the starting point for AM production cost estimation models in the literature (Alexander et al ; Byun and Lee ; Campbell et al ; Ruffo et al ). Ignoring “ill‐structured costs” (Son ) arising from build failure, idleness, and inventory, Ruffo and colleagues () propose an AM costing model viewing the total cost of a build, C Build , as the sum of all direct raw material costs and the indirect costs (equation ).…”

Section: Methodsmentioning

confidence: 99%

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et al. 2012

J of Industrial Ecology

150

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Keywords:digital supply chain energy consumption industrial ecology manufacturing process rapid manufacturing rapid prototyping SummaryThe supply chains found in modern manufacturing are often complex and long. The resulting opacity poses a significant barrier to the measurement and minimization of energy consumption and therefore to the implementation of sustainable manufacturing. The current article investigates whether the adoption of additive manufacturing (AM) technology can be used to reach transparency in terms of energy and financial inputs to manufacturing operations.AM refers to the use of a group of electricity-driven technologies capable of combining materials to manufacture geometrically complex products in a single digitally controlled process step, entirely without molds, dies, or other tooling. The single-step nature affords full measurability with respect to process energy inputs and production costs. However, the parallel character of AM (allowing the contemporaneous production of multiple parts) poses previously unconsidered problems in the estimation of manufacturing resource consumption.This research discusses the implementation of a tool for the estimation of process energy flows and costs occurring in the AM technology variant direct metal laser sintering. It is demonstrated that accurate predictions can be made for the production of a basket of sample parts. Further, it is shown that, unlike conventional processes, the quantity and variety of parts demanded and the resulting ability to fully utilize the available machine capacity have an impact on process efficiency. It is also demonstrated that cost minimization in additive manufacturing may lead to the minimization of process energy consumption, thereby motivating sustainability improvements.

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Stereolithography build time estimation based on volumetric calculations

Cited by 45 publications

References 5 publications

Ten challenges in 3D printing

Ten challenges in 3D printing

A novel decision-making logic for hybrid manufacture of prismatic components based on existing parts

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