Your search keyword '"Georgios Mavros"' showing total 4 results

1. A thermo-frictional tyre model including the effect of flash temperature

Author

Georgios Mavros

Subjects

Engineering, business.industry, Mechanical Engineering, 02 engineering and technology, Mechanics, Surface finish, Contact patch, Solver, 021001 nanoscience & nanotechnology, Thermal conduction, 020303 mechanical engineering & transports, 0203 mechanical engineering, Flash (manufacturing), Automotive Engineering, Heat transfer, Tread, 0210 nano-technology, Safety, Risk, Reliability and Quality, business, Envelope (mathematics)

Abstract

A new tyre model is developed that can predict the influence of both macroscopic and local flash temperature on tyre force generation. The model comprises two heat-transfer solvers. A macroscopic solver calculates the 3D temperature distribution across the tread and sidewall at a resolution of a few millimetres. A separate flash-temperature solver calculates the local hot-spot temperature distribution at the macro-asperity tyre-road contact interface at a resolution of micrometres. The two heat-transfer solvers are coupled with a structural model for the calculation of tyre forces and the sliding speed distribution along the contact patch. The sliding speed distribution feeds into the flash-temperature model and the local coefficient of friction is found as a function of sliding speed, flash temperature, normal pressure, road roughness and the complex modulus of rubber. The proposed tyre model is the first to include the effect of a changing macroscopic temperature distribution on the build-up of the local flash temperature. And to account for road-tread conduction at the macro-asperity contact interface. The model is applicable for identifying the friction envelope and optimum temperature range for tyres on roads with known roughness. This is important in motorsport where knowledge of grip offers a competitive advantage.

Published

2018

2. Frictional contact behaviour of the tyre: the effect of tread slip on the in-plane structural deformation and stress field development

Author

Georgios Mavros and Achillefs Tsotras

Subjects

Engineering, business.industry, Mechanical Engineering, Biaxial tensile test, Poison control, Structural engineering, Viscoelasticity, Physics::Fluid Dynamics, Stress field, Contact mechanics, Automotive Engineering, Tread, Safety, Risk, Reliability and Quality, business, Slip (vehicle dynamics), Plane stress

Abstract

The analysis of the in-plane deformation of the tyre in relation to the frictional contact between the road and the tread is a crucial first step in the understanding of its contribution to the longitudinal dynamics of a vehicle. In this work, the physical mechanism of the generation of the two-dimensional contact pressure distribution for a non-rolling tyre is studied. Towards this aim, a physical tyre model is constructed, consisting of an analytical ring under pretension, a non-linear sidewall foundation, and a discretised foundation of viscoelastic elements representing the tread. Tread behaviour is examined first, with focus on the development of shear micro-slip. The tread simulation is enhanced with the combination of radial and tangential tread elements and the benefits of such an approach are identified. Subsequently, the contact of the complete model is examined by implementing an algorithm for transient simulations in the time domain. The effects of the imposed vertical load and sidewall non-linearity on the contact stress and strain fields are identified. The modelling approach is validated by comparison with published experimental results. The physical mechanism that couples the torsional and horizontal/vertical deformations of the carcass with the frictional forces at the tread is identified and discussed in detail. The proposed modelling approach is found appropriate for the description of the development of the two-dimensional contact pressure field as a function of the frictional potential of the contact.

Published

2010

3. The simulation of in-plane tyre modal behaviour: a broad modal range comparison between analytical and discretised modelling approaches

Author

Achillefs Tsotras and Georgios Mavros

Subjects

Engineering, Mathematical model, business.industry, Mechanical Engineering, Modal analysis, System identification, Truss, Poison control, Structural engineering, Vibration, Modal, Automotive Engineering, Safety, Risk, Reliability and Quality, business, Dynamic testing

Abstract

In-plane tyre modal behaviour determines the response of tyres to ride excitations and braking/traction manoeuvres. In many studies, the interest is limited to relatively low frequencies and a detailed investigation into the ability of models to accurately simulate higher-order responses is unnecessary. In cases where an in-plane model is to be used for the generation of the contact deformation and stresses, or where modal reduction methods are implemented, a detailed knowledge of the modal response is desirable. The present work forms a study on the ability of a number of frequently used modelling approaches to generate realistic modal data throughout a wide frequency range. The analytical ring on elastic foundation model is used as a benchmark throughout the paper. Its predictions are compared with those of two discretised models, namely a truss- and a beam-based model. The sensitivity of the ring's response to a number of physical parameters is discussed. The results are used to inform the comparison between the analytical ring and the discretised models, providing explanations for any discrepancies observed. The limited applicability of the truss model is pointed out, while the accuracy of the beam-based model is enhanced by a circumferential inextensible string element. Both the ring and the enhanced beam models are further improved with the addition of a nonlinear string-based sidewall that accounts for the change in sidewall stiffness with inflation pressure. The findings may offer a reference when setting up in-plane models, including the stage of planning modal tests for parameter identification.

Published

2009

4. On the objective assessment and quantification of the transient-handling response of a vehicle

Author

Georgios Mavros

Subjects

Engineering, business.industry, Mechanical Engineering, media_common.quotation_subject, Yaw, Kinematics, Moment of inertia, Impulse (physics), Inertia, Vehicle dynamics, Control theory, Automotive Engineering, Automobile handling, Transient response, Safety, Risk, Reliability and Quality, business, media_common

Abstract

This article suggests a new methodology for the objective assessment and quantification of the response of a vehicle subjected to transient-handling manoeuvres. For this purpose, a non-dimensional measure is defined, namely the normalized yaw impulse. This measure appears in two variations. In its general or dynamic form, it represents the difference between the yaw moment due to the front-tyre forces and the yaw moment due to the rear-tyre forces, divided by the sum of the aforementioned yaw moments. By employing a linear, two-degree-of-freedom bicycle model, it is shown that the general form of the normalized yaw impulse can be written as a function of the steer angle and the forward, lateral and yaw velocities of the vehicle. This form is referred to as the kinematic yaw impulse. It is demonstrated that the combined application of the dynamic and kinematic expressions of the yaw impulse not only facilitates the explicit assessment and quantification of the transient behaviour of a vehicle, but also reveals the influence of parameters such as the yaw moment of inertia, which traditionally leave the steady-state behaviour unaffected.

Published

2007