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Calculation of tooth pair stiffness by finite element analysis for the multibody simulation of flexible gear pairs with helical teeth and flank modifications

Publikation: Beiträge in ZeitschriftenZeitschriftenaufsätzeForschungbegutachtet

Standard

Calculation of tooth pair stiffness by finite element analysis for the multibody simulation of flexible gear pairs with helical teeth and flank modifications. / Andary, Faysal; Heinzel, Christine; Wischmann, Stefan et al.
in: Multibody System Dynamics, Jahrgang 59, Nr. 4, 12.2023, S. 395-428.

Publikation: Beiträge in ZeitschriftenZeitschriftenaufsätzeForschungbegutachtet

Harvard

Andary, F, Heinzel, C, Wischmann, S, Berroth, J & Jacobs, G 2023, 'Calculation of tooth pair stiffness by finite element analysis for the multibody simulation of flexible gear pairs with helical teeth and flank modifications', Multibody System Dynamics, Jg. 59, Nr. 4, S. 395-428. https://doi.org/10.1007/s11044-023-09926-4

APA

Andary, F., Heinzel, C., Wischmann, S., Berroth, J., & Jacobs, G. (2023). Calculation of tooth pair stiffness by finite element analysis for the multibody simulation of flexible gear pairs with helical teeth and flank modifications. Multibody System Dynamics, 59(4), 395-428. https://doi.org/10.1007/s11044-023-09926-4

Vancouver

Andary F, Heinzel C, Wischmann S, Berroth J, Jacobs G. Calculation of tooth pair stiffness by finite element analysis for the multibody simulation of flexible gear pairs with helical teeth and flank modifications. Multibody System Dynamics. 2023 Dez;59(4):395-428. doi: 10.1007/s11044-023-09926-4

Bibtex

@article{abad92573df54e60a9a9baefb0583767,
title = "Calculation of tooth pair stiffness by finite element analysis for the multibody simulation of flexible gear pairs with helical teeth and flank modifications",
abstract = "Optimizing the acoustic behavior – often referred to as Noise, Vibration, Harshness (NVH) – of drive train components, such as gearboxes, is paramount during the development process. NVH simulation models allow reducing the number of time-consuming and expensive iterations with physical prototypes during the development. These models therefore need to adequately depict the NVH behavior, which is defined by excitation, transfer behavior, and sound radiation. One main excitation source in drive train systems is meshing gear pairs because of the varying mesh stiffness. Although numerous approaches exist for calculating the stiffness of meshing gears, accurately incorporating the varying gear mesh stiffness into NVH system models remains challenging. This study investigates the possibility of modeling gear mesh excitations in system simulation by precalculating the meshing stiffness for individual contact pairs instead of a total gear mesh stiffness. The proposed method can account for variability in contact length due to changes in the gear stage state parameters (e.g., transmission ratio and center distance), which is common in system models with flexible shafts and bearings. With the presented approach, it is also possible to correctly distribute the meshing forces over the meshing tooth pairs, which improves the prediction of the excitation behavior. The method is demonstrated on an example gear pair, verified numerically, and compared to widely adopted methods from state-of-the-art tools and industry norms. The simulation results show good accuracy compared to traditional approaches with the added benefit of accounting for flexible system components by decoupling the positions of the contact pairs.",
keywords = "Dynamic behavior, Elastic bodies, Finite element analysis, Gear mesh stiffness, Multibody simulation",
author = "Faysal Andary and Christine Heinzel and Stefan Wischmann and Joerg Berroth and Georg Jacobs",
note = "Publisher Copyright: {\textcopyright} 2023, The Author(s), under exclusive licence to Springer Nature B.V.",
year = "2023",
month = dec,
doi = "10.1007/s11044-023-09926-4",
language = "English",
volume = "59",
pages = "395--428",
journal = "Multibody System Dynamics",
issn = "1384-5640",
publisher = "Springer Netherlands",
number = "4",

}

RIS

TY - JOUR

T1 - Calculation of tooth pair stiffness by finite element analysis for the multibody simulation of flexible gear pairs with helical teeth and flank modifications

AU - Andary, Faysal

AU - Heinzel, Christine

AU - Wischmann, Stefan

AU - Berroth, Joerg

AU - Jacobs, Georg

N1 - Publisher Copyright: © 2023, The Author(s), under exclusive licence to Springer Nature B.V.

PY - 2023/12

Y1 - 2023/12

N2 - Optimizing the acoustic behavior – often referred to as Noise, Vibration, Harshness (NVH) – of drive train components, such as gearboxes, is paramount during the development process. NVH simulation models allow reducing the number of time-consuming and expensive iterations with physical prototypes during the development. These models therefore need to adequately depict the NVH behavior, which is defined by excitation, transfer behavior, and sound radiation. One main excitation source in drive train systems is meshing gear pairs because of the varying mesh stiffness. Although numerous approaches exist for calculating the stiffness of meshing gears, accurately incorporating the varying gear mesh stiffness into NVH system models remains challenging. This study investigates the possibility of modeling gear mesh excitations in system simulation by precalculating the meshing stiffness for individual contact pairs instead of a total gear mesh stiffness. The proposed method can account for variability in contact length due to changes in the gear stage state parameters (e.g., transmission ratio and center distance), which is common in system models with flexible shafts and bearings. With the presented approach, it is also possible to correctly distribute the meshing forces over the meshing tooth pairs, which improves the prediction of the excitation behavior. The method is demonstrated on an example gear pair, verified numerically, and compared to widely adopted methods from state-of-the-art tools and industry norms. The simulation results show good accuracy compared to traditional approaches with the added benefit of accounting for flexible system components by decoupling the positions of the contact pairs.

AB - Optimizing the acoustic behavior – often referred to as Noise, Vibration, Harshness (NVH) – of drive train components, such as gearboxes, is paramount during the development process. NVH simulation models allow reducing the number of time-consuming and expensive iterations with physical prototypes during the development. These models therefore need to adequately depict the NVH behavior, which is defined by excitation, transfer behavior, and sound radiation. One main excitation source in drive train systems is meshing gear pairs because of the varying mesh stiffness. Although numerous approaches exist for calculating the stiffness of meshing gears, accurately incorporating the varying gear mesh stiffness into NVH system models remains challenging. This study investigates the possibility of modeling gear mesh excitations in system simulation by precalculating the meshing stiffness for individual contact pairs instead of a total gear mesh stiffness. The proposed method can account for variability in contact length due to changes in the gear stage state parameters (e.g., transmission ratio and center distance), which is common in system models with flexible shafts and bearings. With the presented approach, it is also possible to correctly distribute the meshing forces over the meshing tooth pairs, which improves the prediction of the excitation behavior. The method is demonstrated on an example gear pair, verified numerically, and compared to widely adopted methods from state-of-the-art tools and industry norms. The simulation results show good accuracy compared to traditional approaches with the added benefit of accounting for flexible system components by decoupling the positions of the contact pairs.

KW - Dynamic behavior

KW - Elastic bodies

KW - Finite element analysis

KW - Gear mesh stiffness

KW - Multibody simulation

UR - http://www.scopus.com/inward/record.url?scp=85165257863&partnerID=8YFLogxK

U2 - 10.1007/s11044-023-09926-4

DO - 10.1007/s11044-023-09926-4

M3 - Journal articles

AN - SCOPUS:85165257863

VL - 59

SP - 395

EP - 428

JO - Multibody System Dynamics

JF - Multibody System Dynamics

SN - 1384-5640

IS - 4

ER -

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