From Structural Optimization Results to Parametric CAD Modeling—Automated, Skeletonization-Based Truss Recognition

Polak, Jan; Nowak, Michał

doi:10.3390/app13095670

Cited by 2 publications

(1 citation statement)

References 27 publications

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“…The third group of wear reduction includes designs that affect changes in the organic wear abrasion through design optimisation and analysis using DEM [16]. Researchers address aspects related to structural optimisation using CAD environments [16][17][18]. Structural optimisation also affects organic wear by preventing hard organic particles from directly accessing the mating parts.…”

Section: Introductionmentioning

confidence: 99%

Use of Heat-Applied Coatings to Reduce Wear on Agricultural Machinery Components

Romek,

Selech,

Ulbrich

2024

Materials

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This article presents the effect of the conditions of abrasive compounds on the wear of samples made by different methods. The 28MnB5 steel was used, which is intended for agricultural components, to which two arc and laser coatings were applied. The study included the analysis of microstructure, microhardness, roughness, and tribological experiments on a dedicated stand. The arc coating was found to significantly improve the tribological properties compared to the samples without the coating. Varied wear results were obtained for the laser coating depending on the parameters of the abrasive compound. Studies of the surface roughness of the samples showed that the concentration and pH of the abrasives have a significant effect on the changes in the surface parameters after the tribological tests. The results of the tribological experiments indicated that wear resistance for some of the abrasive mass conditions was improved by the application of heat-applied coatings. In addition, it was found that the power consumption on the stand was the highest for abrasive mass conditions of a 10% moisture content and a pH of 10. For these test conditions, the mass loss was four times higher than for the parameter with W0% and pH7. The energy consumption of the stand was 60 kWh lower for this variant than for the parameter with W10% and pH10. The results of the study have important practical applications that can help in the selection of materials for agricultural machinery components, depending on the abrasive mass conditions.

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Section: Introductionmentioning

confidence: 99%

Use of Heat-Applied Coatings to Reduce Wear on Agricultural Machinery Components

Romek,

Selech,

Ulbrich

2024

Materials

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Shape Optimization of Structures by Biological Growth Method

Bocko,

Delyová,

Kostka

et al. 2024

Applied Sciences

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Structural element shape optimization based on the biological growth method is increasingly used nowadays. This method consists of two main methods: topological optimization (soft kill option—SKO) and shape optimization (computer-aided optimization—CAO). This paper presents the solution procedures for both shape optimization and topological optimization. In applying these methods, first of all, a certain stress norm must be established, where the most appropriate and most used criterion is the equivalent stress according to von Mises. The application of the mentioned optimization methods is illustrated by several examples. The aim was to compare the change in volume or mass and the maximum stress of the structural elements between the different designs: the initial design, the design after topological optimization, and the design after shape optimization.

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From Structural Optimization Results to Parametric CAD Modeling—Automated, Skeletonization-Based Truss Recognition

Cited by 2 publications

References 27 publications

Use of Heat-Applied Coatings to Reduce Wear on Agricultural Machinery Components

Use of Heat-Applied Coatings to Reduce Wear on Agricultural Machinery Components

Shape Optimization of Structures by Biological Growth Method

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