Design synthesis of non-symmetrically loaded high-performance disc brakes: Part 2: Finite element modelling

Abstract

The prediction of the behaviour of wheel-mounted disc brakes is particularly complex due to non-symmetrical heat input, making disc coning during braking inevitable. Furthermore, severe brake applications cause high local temperatures and stresses, resulting in disc material yielding and permanent disc coning. To ensure adequate brake operation, disc coning during braking and permanent disc coning must be kept within acceptable limits. Obviously, excessive hub stresses must also be avoided, to ensure structural integrity throughout expected brake life. In order to predict disc permanent coning, it is necessary to model macro thermal effects, i.e. thermoelastic instability. The paper deals with different finite element (FE) modelling techniques and measurements of disc material properties, establishing efficient methodology for the prediction of wheel-mounted disc performance. The procedure developed is widely based on a standard FE code, with subroutines developed for data preparation, processing and visualization. This approach, combined with the efficiency and robustness of the methodology, is very suitable for industrial use, reducing risks, costs and development time.

Keywords

disc brakes wheel-mounted railways design process thermoelastic instability

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References

Tirovic

Ali

Design synthesis of non-symmetrically loaded high-performance disc brakes. Part 1

Proc. Instn Mech. Engrs, Part F: J. Rail and Rapid Transit, 2001, 215 (F2), 101–109.

Kennedy

F. E.

Ling

F. F.

A thermal, thermoelastic, and wear simulation of a high speed sliding contact problem

Trans. ASME, J. Lubric. Technol., July 1974, 96 (3), 497–507.

Day

A. J.

Energy transformation at the friction interface of a brake. PhD thesis, Loughborough University of Technology, Loughborough, 1983.

Day

A. J.

An analysis of speed, temperature and performance characteristics of automotive drum brakes

Trans. ASME, J. Tribology, 1988, 110, 298–305.

Day

A. J.

Drum brake interface pressure distributions

Proc. Instn Mech. Engrs, Part D: J. Automobile Engineering, 1991, 205 (D2), 127–136.

Day

A. J.

Harding

P. J.R.

Newcomb

T. P.

Combined thermal and mechanical analysis of drum brakes

Proc. Instn Mech. Engrs, Part D: Transport Engineering, 1984, 198 (15), 287–294.

Inoue

Analysis of brake judder caused by thermal deformation of brake disc rotor. In XXI FISISTA Congress, Belgrade, Yugoslavia, 1986, paper 865131.

Kao

T. K.

Richmond

J. W.

Moore

M. W.

The application of predictive techniques to study thermo-elastic instability of brakes. SAE paper 942087, 1994.

Koetniyom

Brooks

P. C.

Barton

D. C.

Finite element prediction of inelastic strain accumulation in castiron brake rotors. In Brakes 2000 Conference, Leeds, 2000.

10.

Tirovic

Development of a wheel-mounted disc brake for a high-speed train

Proc. Instn Mech. Engrs, Part F: J. Rail and Rapid Transit, 1998, 212 (F2), 113–121.

11.

Sarwar

G. A.

Design optimisation of wheel mounted railway brake discs. PhD thesis, Brunel University, 2002.

12.

Newcomb

T. P.

Spurr

R. T.

Braking of Road Vehicles, 1967 (Chapman and Hall, London).

13.

Tirovic

Sarwar

G. A.

Design synthesis of non-symmetrically loaded high-performance disc brakes. Part 3: Verification and optimization

Proc. Instn Mech. Engrs, Part F: J. Rail and Rapid Transit, 2004, 218 (F2), 105–115.

14.

Limpert

Brake Design and Safety, 1999 (Society of Automotive Engineers, Warrendale, Pennsylvania).

15.

Rhee

S. K.

Liu

High temperature wear of asbestos-reinforced friction materials

Wear, 1976, 37, 291–297.

16.

Dufrénoy

Degallaix

Bumbieler

Viet

J. J.

Raison

Mecanismes de fissuration des disques de frein: analyse experimentale et etude numerique. In JEF 2002 Conference Proceedings, Lille, France, 2002, pp. 111–122.