A CFD-DEM-Wear Coupling Method for Stone Chip Resistance of Automotive Coatings with a Rigid Connection Particle Method for Non-Spherical Particles

Qian, J.; Zou, Chenqi; Miao, Zhuang; Chen, Shun Hua; Tsubokura, Makoto

doi:10.32604/cmes.2022.020738

Cited by 3 publications

(2 citation statements)

References 50 publications

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“…In powder technology, simulations with non-spherical particles have been performed for several years [ 13 ], i.e., an abstraction as shown in Figure 1 , Figure 2 , Figure 3 and Figure 4 would not be necessary. In tribology, on the other hand, the particle shapes are composed of spherical basic shapes [ 28 , 29 ] since computer technology still reaches its limits due to the more complex elastic-plastic impact processes and fracture mechanics. Whether the approaches outlined will be pursued further in the automotive industry as originally planned is unclear as a result of the transformation toward electromobility.…”

Section: Discussionmentioning

confidence: 99%

Development and Production of Artificial Test Swarf to Examine Wear Behavior of Running Engine Components—Part 2: Experimentally Derived Designs

Brag,

Piotter,

Plewa

et al. 2023

Materials

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In subtractive manufacturing processes, swarf, burrs or other residues are produced, which can impair the function of a tribological system (e.g., journal bearings). To prevent premature engine damage, cleanliness requirements are defined for production processes. Damaging particle tests are an experimental approach for validating these defined cleanliness requirements. This methodical approach is not yet widely used. For one, the test setup must be developed and proven for the respective application. For another, in order to carry out the tests in a systematic manner, defined test particles with properties similar to those of the contaminants encountered in reality are required. In the second part of the paper, the process chain for manufacturing artificial test swarf by micro powder injection molding (MicroPIM) is described. The size and shape of the swarf were derived from real swarf via several abstraction processes. Although certain design guidelines for MicroPIM parts could not be taken into account, the targeted manufacturing tolerances were achieved in most cases. During demolding, it became apparent that the higher ejection forces of the free-formed geometries must be taken more into account in the design of the mold. The experiments on the test setup also revealed that the artificial test swarf was unexpectedly brittle and was therefore ground up in the bearing gap without causing any substantial damage to the bearing. Thus, the artificial test swarf in its current sintered state is not a suitable substitute for micromilled swarf. However, MicroPIM could still be used to manufacture test particles in applications involving lower mechanical forces.

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Section: Discussionmentioning

confidence: 99%

Development and Production of Artificial Test Swarf to Examine Wear Behavior of Running Engine Components—Part 2: Experimentally Derived Designs

Brag,

Piotter,

Plewa

et al. 2023

Materials

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“…In consideration of experimental methods being of poor repeatability and high cost, numerical methods have become an attractive tool for investigating the impact problem. Many studies regarding the multi-particle impact test have been conducted [12][13][14][15]. With regard to the single-impact test, Toi et al [16,17] established an elasto-viscoplastic-damage constitutive model and evaluated the impact resistance of automotive coatings in combination with a non-coupled analysis method.…”

Section: Introductionmentioning

confidence: 99%

Single-Impact Failure of Multi-Layered Automotive Coatings: A Finite Element-Based Study

et al. 2023

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Automotive coatings are a multi-layered polymer composite structure whose impact resistance is closely related to the appearance and safety of a vehicle. Since experimental methods are of high cost and poor repeatability, in our work, a finite element model is developed for the single-impact failure of automotive coatings. In this model, a multi-mechanism damage model and a large deformation cohesive zone model are employed to account for the polymer-ply and interlaminar failures of the coating, and some rate-dependent material models are adopted to capture the effect of impact velocity. The simulated results indicate that the proposed model can reproduce the failure patterns of automotive coatings well. In addition, the impact failure mechanisms of the coating are revealed. Numerical findings show that both brittle and ductile failures are found in the coating and there are three stages for the propagation of the delamination crack. Finally, we numerically investigate the effects of primer mechanical properties, i.e., Young’s modulus, yield strength, and re-hardening modulus, on the impact resistance of automotive coatings. Our work is helpful to the design of coating, which can improve the impact resistance of automotive coatings.

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Failure Assessment of Electronics Component under Gravel Bombardment Test in Automotive Electronics

Hande¹,

Wójcik²

2023

SAE Technical Paper Series

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<div class="section abstract"><div class="htmlview paragraph">Exposing sensors to environment without any physical protection introduces risk of failure due to collision with small hard objects like stones. This type of interaction is tested during product validation by usage of gravel bombardment procedures, originally designed for evaluating resistance of surface coating to chipping by gravel impact. While useful for practitioners, this procedure is difficult to be used during product design and virtual validation since it does not provide statistical measures regarding gravel size, mass or velocity distribution of moving gravels. Consequently, computer simulation must assume certain properties of impactors. The following simulation methodology evaluates risks associated with gravel bombardment test. It is based on impact force transmission through interconnects belonging to big and/or critical electronic components.</div></div>

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A CFD-DEM-Wear Coupling Method for Stone Chip Resistance of Automotive Coatings with a Rigid Connection Particle Method for Non-Spherical Particles

Cited by 3 publications

References 50 publications

Development and Production of Artificial Test Swarf to Examine Wear Behavior of Running Engine Components—Part 2: Experimentally Derived Designs

Development and Production of Artificial Test Swarf to Examine Wear Behavior of Running Engine Components—Part 2: Experimentally Derived Designs

Single-Impact Failure of Multi-Layered Automotive Coatings: A Finite Element-Based Study

Failure Assessment of Electronics Component under Gravel Bombardment Test in Automotive Electronics

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