Your search keyword '"Mungyu Jeong"' showing total 6 results

1. Crash Analysis of Aluminum/CFRP Hybrid Adhesive Joint Parts Using Adhesive Modeling Technique Based on the Fracture Mechanics

Author

Young Cheol Kim, Soon Ho Yoon, Geunsu Joo, Hong-Kyu Jang, Ji-Hoon Kim, Mungyu Jeong, and Ji Hoon Kim

Subjects

structural adhesive, carbon-fiber-reinforced plastic (CFRP), fracture toughness, crash simulation, cohesive zone model, tiebreak contact, Organic chemistry, QD241-441

Abstract

This study describes the numerical simulation results of aluminum/carbon-fiber-reinforced plastic (CFRP) hybrid joint parts using the explicit finite-element solver LS-DYNA, with a focus on capturing the failure behavior of composite laminates as well as the adhesive capacity of the aluminum–composite interface. In this study, two types of adhesive modeling techniques were investigated: a tiebreak contact condition and a cohesive zone model. Adhesive modeling techniques have been adopted as a widely commercialized model of structural adhesives to simulate adhesive failure based on fracture mechanics. CFRP was studied with numerical simulations utilizing LS-DYNA MAT54 to analyze the crash capability of aluminum/CFRP. To evaluate the simulation model, the results were compared with the force–displacement curve from numerical analysis and experimental results. A parametric study was conducted to evaluate the effect of different fracture toughness values used by designers to predict crash capability and adhesive failure of aluminum/CFRP parts.

Published

2021

2. Glass-fiber mat/PA6 composite tubes subjected to dynamic axial crush loading—Experimental evaluation and high fidelity modeling of failure phenomena

Author

Holger Böhm, Jonas Richter, Jinbong Kim, Geunsu Joo, Hong-Kyu Jang, Mungyu Jeong, Andreas Hornig, and Maik Gude

Subjects

Ceramics and Composites, Civil and Structural Engineering

Published

2023

3. A Practical Axial Crush Simulation of Glass-Fiber MAT/PA6 Composite Tubes for Application of an Energy Absorber in Automobiles

Author

Jin-Bong Kim, Youngchul Kim, H. Böhm, Jonas Richter, Geunsu Joo, and Mungyu Jeong

Subjects

Materials science, Computer simulation, business.industry, Drop tests, Automotive Engineering, Glass fiber, Composite number, Calibration, Structural engineering, business, Failure mode and effects analysis, Energy (signal processing), Parametric statistics

Abstract

This paper is concerned with numerical simulation utilizing LS-DYNA MAT54 for axial crush of glass-fiber mat/PA6 composite tubes. The crush simulation aims at reproducing the crush energy absorption capability measured from dynamic drop tests. The adopted MAT54 has a merit as a widely commercialized model of composite materials to simulate a progressive failure mode. Parameters of MAT54 are calibrated to reduce difference of the crush energy absorption capability between experiment and simulation on the basis of parametric studies. The calibration is performed for major parameters considering effect of energy absorption and stability of crush simulation first, and other parameters are determined by a trial and error method. In order to evaluate the calibrated parameters of MAT54, results are compared for specific energy absorption and crush depths measured from simulation and experiment. Consequently, the presented simulation shows good agreements with experiments, and its applicability is verified under various impact speed and impactor mass conditions.

Published

2021

4. A Study on The Design Methodology of Hybrid Joints for The Multi-material Carbody Parts

Author

Woo-Kyoung Lee, Min-Gwan Bae, Soon Ho Yoon, Min-Gyu Kang, and Mungyu Jeong

Subjects

Computer science, Automotive Engineering, Multi material, Mechanical engineering, Design methods

Published

2020

5. Crash Analysis of Aluminum/CFRP Hybrid Adhesive Joint Parts Using Adhesive Modeling Technique Based on the Fracture Mechanics

Author

Ji Hoon Kim, Soon Ho Yoon, Young Cheol Kim, Mungyu Jeong, Jihoon Kim, Geunsu Joo, and Hong-Kyu Jang

Subjects

cohesive zone model, Materials science, Polymers and Plastics, Computer simulation, Crash simulation, business.industry, structural adhesive, Organic chemistry, Fracture mechanics, General Chemistry, Structural engineering, Composite laminates, Article, fracture toughness, tiebreak contact, carbon-fiber-reinforced plastic (CFRP), Cohesive zone model, Fracture toughness, QD241-441, crash simulation, Adhesive, business, Joint (geology)

Abstract

This study describes the numerical simulation results of aluminum/carbon-fiber-reinforced plastic (CFRP) hybrid joint parts using the explicit finite-element solver LS-DYNA, with a focus on capturing the failure behavior of composite laminates as well as the adhesive capacity of the aluminum–composite interface. In this study, two types of adhesive modeling techniques were investigated: a tiebreak contact condition and a cohesive zone model. Adhesive modeling techniques have been adopted as a widely commercialized model of structural adhesives to simulate adhesive failure based on fracture mechanics. CFRP was studied with numerical simulations utilizing LS-DYNA MAT54 to analyze the crash capability of aluminum/CFRP. To evaluate the simulation model, the results were compared with the force–displacement curve from numerical analysis and experimental results. A parametric study was conducted to evaluate the effect of different fracture toughness values used by designers to predict crash capability and adhesive failure of aluminum/CFRP parts.

Published

2021

6. Experimental investigation into static and dynamic axial crush of composite tubes of glass-fiber mat/PA6 laminates

Author

H. Böhm, Jonas Richter, Jin-Bong Kim, Niels Modler, and Mungyu Jeong

Subjects

Lamina, Materials science, Mechanical Engineering, Hydraulic test, Composite number, Glass fiber, Bend radius, Crash, Laminar flow, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Industrial and Manufacturing Engineering, 0104 chemical sciences, Mechanics of Materials, Ceramics and Composites, Crashworthiness, Composite material, 0210 nano-technology

Abstract

In this paper, the results are present of an experimental investigation into quasi-static and dynamic crushing responses and crashworthiness characteristics of round-hat-shaped crash tubes made with glass long-fiber-mat/PA6 laminates of around 45 vol%. These characteristics were explored using a high-dynamic hydraulic test machine. The crash tubes failed by the progressive splaying mode except for some tubes in the quasi-static tests, which failed by the mid-length collapse mode. The specific energy absorption (SEA, 42.0 J/g) in the quasi-static tests increased to around 52 J/g in the dynamic tests. The increased energy absorption at the higher test speed was analyzed through the microscopic behavior of the small bending radius of the splayed laminar bundles and fragmentation of the lamina bundles. The drop-tower tests show that the dependency of the performance of the crash tubes on the test speed appears only at relatively low speed (1 m/s in the limited tests reported in this paper), but the performance becomes relatively steady at much higher impact speeds. The impactor mass and tube length had almost no effect on the crash characteristics of the mean crushing load, SEA, and peak load.

Published

2020