TY - GEN
T1 - Dynamic correlation of diesel engine exhaust system containing rubber hose using component mode synthesis
AU - Yoon, Taeyoung
AU - Yoon, Seongho
AU - Na, Sungsoo
N1 - Funding Information:
We gratefully acknowledge the financial support of the project by DOOSAN Infracore.
Publisher Copyright:
© Proceedings of 2020 International Congress on Noise Control Engineering, INTER-NOISE 2020. All rights reserved.
PY - 2020/8/23
Y1 - 2020/8/23
N2 - Diesel engine operates on higher temperature and pressure compare to gasoline engine system. Owing to its operating principle, exhaust system of diesel engine contains rubber hoses which are composed of various hyper-elastic materials. First, metal parts of exhaust system are modelled and correlated using modal test. Also, metal and rubber parts are assembled on finite element (FE) and validated through experiments. Furthermore, the non-linearity and hyperelastic properties of rubbers are modelled using various strain energy models from the tensile test of rubbers. Due to non-linear property and comparably small elastic modulus of rubber components, we found out that exhaust assembly consisting rubber appears to have high number of modal densities in general frequency range. This phenomenon increases complexity on FE model and result computational cost. Therefore, we applied component mode synthesis (CMS) on rubber parts to reduce computing time. Moreover, bellows and inside of EGR cooler are simply modelled by shell elements. Reduced models turn up to be highly efficient than original model while solving vibrational problems. The reduced models are validated by vibrational experiments (Natural frequency, mode shape, frequency response function) and we obtained highly correlated FE models.
AB - Diesel engine operates on higher temperature and pressure compare to gasoline engine system. Owing to its operating principle, exhaust system of diesel engine contains rubber hoses which are composed of various hyper-elastic materials. First, metal parts of exhaust system are modelled and correlated using modal test. Also, metal and rubber parts are assembled on finite element (FE) and validated through experiments. Furthermore, the non-linearity and hyperelastic properties of rubbers are modelled using various strain energy models from the tensile test of rubbers. Due to non-linear property and comparably small elastic modulus of rubber components, we found out that exhaust assembly consisting rubber appears to have high number of modal densities in general frequency range. This phenomenon increases complexity on FE model and result computational cost. Therefore, we applied component mode synthesis (CMS) on rubber parts to reduce computing time. Moreover, bellows and inside of EGR cooler are simply modelled by shell elements. Reduced models turn up to be highly efficient than original model while solving vibrational problems. The reduced models are validated by vibrational experiments (Natural frequency, mode shape, frequency response function) and we obtained highly correlated FE models.
UR - http://www.scopus.com/inward/record.url?scp=85101374924&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:85101374924
T3 - Proceedings of 2020 International Congress on Noise Control Engineering, INTER-NOISE 2020
BT - Proceedings of 2020 International Congress on Noise Control Engineering, INTER-NOISE 2020
A2 - Jeon, Jin Yong
PB - Korean Society of Noise and Vibration Engineering
T2 - 49th International Congress and Exposition on Noise Control Engineering, INTER-NOISE 2020
Y2 - 23 August 2020 through 26 August 2020
ER -