Distinctive behaviors of mesh force and transmission error in mesh stiffness model of spur planetary gear system considering elastic ring gear

The structural compliance of annular ring gear can significantly influence the quasi-static and dynamic performance of an epicyclic gear set. As powertrain components are continually being optimized to their design limits, this influence becomes prominent and can no longer be ignored. The current paper will study the impact of ring gear compliance on the dynamic response of epicyclic gear sets, in fixed ring kinematic configuration. To achieve this objective the current study will incorporate a finite element based ring gear formulation into the three-dimensional planetary load distribution model of Ryali and Talbot [1]. The proposed model employs a modified simplex algorithm to iteratively solve for the elastic gear mesh contacts in conjunction with a numerical integration scheme, which enables it to inherently capture the influence of several component and system level design variations. The developed formulation is used to conduct parametric studies involving different planetary gear designs, ring gear fixtures (bolted vs. splined), and operating conditions (quasi-static, dynamic). In the case of a splined ring gear fixture, an external splined tooth contact model is developed, which will be used to validate the model against the quasi-static experiments of Ligata et al. [2]. The discussed results demonstrate the fidelity of the developed model, thus making it an excellent tool for the design and analysis of planetary gears with thin annular ring gears.

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Numerical Simulation of Drive Cycles for Formula Electric Vehicle Comparative Powerflow Analysis

Rodrigues,

Silveira

2024

SAE Technical Paper Series

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<div class="section abstract"><div class="htmlview paragraph">This paper proposes a theoretical drive cycle for the competition, considering the battery pack project under design. The vehicle has a non-reversible, double-stage gear train, created without a dynamic investigation. To evaluate the effect on performance, several ratios were analyzed. Dynamic model uses Eksergian’s Equation of Motion to evaluate car equivalent mass (generalized inertia), and external forces acting on the vehicle. The circuit is divided into key locations where the driver is likely to accelerate or brake, based on a predicted behavior. MATLAB ODE Solver executed the numerical integration, evaluating time forward coordinates, creating the drive cycle. Linear gear train results provided data as boundary conditions for a second round of simulations performed with epicyclic gear trains. Model is updated to include their nonlinearity by differential algebraic equation employment with Lagrange multipliers. All data undergoes evaluation to ascertain the mechanical and electrical power requirements. Subsequent analysis aims to comprehend the peak electrical current and energy storage demands of the battery pack, ensuring the car performs in competition as simulated. Whereas reference gear train ratio returns a good time frame, its energy usage surpasses competition rules. Other implemented ratios demonstrated whether an improvement in time frame or an improvement in energy usage. Upgrading one downgrades the other, for instance, speed reduction of 6.0:1 needs 60% more time for a lap than the fastest, but has the lowest energy usage. This behavior justifies epicyclic gear train investigation. Comparison of both models indicate enough evidence that car performance improves with epicyclic gear train appliance. Epicyclic gear train enhances power flow while improving energy management. It can be up to 16 seconds faster (Np=3 v3) than the reference train (9.0:1) and uses nearly the same amount of energy as 6.0:1 ratio.</div></div>

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Distinctive behaviors of mesh force and transmission error in mesh stiffness model of spur planetary gear system considering elastic ring gear

Cited by 3 publications

References 46 publications

A novel energy-based numerical method for solving planet load sharing model considering elastic ring gear

A novel energy-based numerical method for solving planet load sharing model considering elastic ring gear

Influence of Fixed Ring Gear Structural Compliance on the Quasi-Static and Dynamic Response of Epicyclic Gear Sets

Numerical Simulation of Drive Cycles for Formula Electric Vehicle Comparative Powerflow Analysis

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