Design and development of an active roll control suspension

Hickson, Luke R.

January 1996

No description available.

629.049

Ground transport systems

The mechanics of the steered wheels of a road vehicle

Kurt-Elli, H.

January 1982

Modern road vehicle suspension and steering systems may generally be classed as multi-loop spatial mechanisms, designed with links constrained and interconnected in such a manner as to attempt a preferred and prescribed motion of the steered wheels with regard to the inputs to the system. The mechanism incorporates elastic and damping elements and is terminated to the ground surface via the tyres. The complete system may be modelled as a multi-body system with spatial kinematics. This work demonstrates an analysis and simulation of the mechanics of a double wishbone/rack and pinion suspension and steering system modelled as a multi-body system. A 3-dimensional Newton-Euler based approach employing vector and matrix notation is used in deriving the coupled set of non-linear equations of motion, and these together with the kinematic equations of constraint are cast in state space form, and numerical solutions sought using a digital computer. The kinematic equations are derived from the velocity loop equations for the model, and deal with the so-called redundant degrees-of-freedom arising in models of this type in a completely general manner. The tyre, shock absorber, main spring, and steering gear are modelled from empirical data. A feature of the work is that the complete set of equations need not be excessively manipulated manually, and that use of a set of specially written computer program routines allows a numerical formulation of the equations in the machine, enabling the main program to be written from inspection of the 'raw' equations. Large displacements and therefore changes of geometry are considered, with the provision for partial numerical linearization of the geometric aspects if required. The kinematic behaviour of the model is also described. A supporting experimental programme of work with a vehicle on a rolling drum rig has been conducted in parallel to the simulation work. And results indicate good correlation between theory and experiment at low frequencies of vibration.

629.049

Ground transport systems

The reduction of structural acoustic coupling in car bodies

Richards, T. L.

January 1982

The nature of sound in cars is discussed in the light of previous experimental and theoretical work, and the major contributions to interior noise are identified. The acoustic field inside a vibrating structure is analysed theoretically in terms of the acoustic cavity modes and the structural modes, and it is shown that'reduction of structural-acoustic coupling could reduce the response for a wide variety of force inputs. Finite element analyses of prismatic acoustic cavities and two-dimensinal ring structures are described and these are combined in a simple theoretical model of ring-mode excitation of sound. By stiffening selected structural elements, the structural-acoustic coupling, and hence the acoustic response, are reduced.

629.049

Ground transport systems

Design and synthesis of active and passive vehicle suspensions

Wang, Fucheng

January 2001

No description available.

629

Ground transport systems

Analysis of car body structures

Page, Laurence J.

January 1982

The requirement to develop lighter vehicle structures arose as a result of the rapidly rising price of oil. The weight of a vehicle makes a considerable contribution to the power required to propel it and therefore the quantity of fuel used. The work presented here is an investigation into the analysis of the components of a vehicle structure, with the aim of obtaining a greater understanding of their behaviour. This knowledge is then applicable to the design of lighter structures made from an assembly of the components studied.

629.049

Ground transport systems

Analysis of disc brake squeal using the finite element method

Mohd Ripin, Zaidi Bin

January 1995

The problem o f disc brake squeal has been examined by developing a finite element model of the coupled pad-disc system , conducting complex eigenvalue analysis and associating unstable modes with potential squeal problem areas. A key issue in this process is the representation of the contact pressure distribution at the frictional interface between the disc and the pad. Non-linear contact analysis using the finite element model of the pad revealed that contact is only partial at the pad-disc interface and that the contact pressure distribution depends on the friction coefficient, Young’s modulus of the friction material and the way the applied pressure is distributed on the pad backplate. A new method is proposed in which interface contact stiffness is related to brake line pressure using a statistical approach based on the measured surface properties of the interface. Complex eigenvalue analysis of the coupled pad-disc system has shown that unstable modes exist within different ranges of contact stiffness thereby providing an explanation of the effect of varying line pressure on squeal. The two most unstable modes from the analysis show good correlation with experimental squeal results. The coupled model is then used for parametric studies the results of which indicate that high coefficient of friction and uniform contact pressure distribution increase instability whilst a trailing edge biased pressure distribution and a high support stiffness at the pad backplate reduce it. Limiting the disc symmetry by introducing equispaced slots was shown to be effective in reducing instabilities involving diametral modes of the disc with the same order of symmetry only Other modes were stabilised by increasing the rigidity of the pad. The overall results suggest that either the pad or the disc can be mainly responsible for the instability depending on the mode thus unifying the different approaches to disc brake squeal and enabling the most appropriate component to be targeted for squeal abatement purposes.

629.049

Ground transport systems

The performance of vehicle suspensions fitted with controllable dampers

Firth, Gregory R.

January 1991

First, techniques for modelling the vehicle and road surface are discussed, and the standard linear and nonlinear analysis methods are reviewed. Then, using the quarter car model and a single idealised road surface, a brief analysis of the passive and active suspensions, including full and limited state feedback schemes, is presented. The performance in terms of ride comfort, road holding ability and suspension travel for both systems is established, providing a yardstick against which the controllable damper systems can be compared. Three suspensions fitted with controllable dampers are then analysed. In order of increasing complexity these are; a three-state adaptive system, a two-state switcliable system, and a continuously variable system. After a performance comparison of the ideal system, the practical limitations present in real hardware are included in the damper model. Their effect on performance is quantified and realistic response targets are set. The model is then extended to a two dimensional “bicycle” model, which enables control laws to be generated which take into account the correlation between front and rear wheel inputs. Using these laws to drive the active and continuously variable damper system, the advantages of a correlated law are identified. The accelerations and suspension displacements of a passively suspended production vehicle are measured during actual runs over three roads of varying roughness. These are used to estimate the surface roughness properties of the roads. Using this range of typical conditions, the idea of system adaptation is then considered. The performance of each controllable damper system lies between that of the active and conventional passive systems. The continuously variable system generally offers the best ride comfort, but worthwhile improvements are also possible with the two-state switchable system. The adaptive system offers only marginal improvements for the conditions considered.

629.049

Ground transport systems

Design study of optimal material and energy usage for transport

West, J.

January 1980

No description available.

629.049

Ground transport systems

Active suspension applied to railway trains

Pratt, Ian

January 1996

There has been an impetus in recent years to increase railway train speeds and reduce journey times. As train speeds have increased, other problems have manifested themselves, in particular the consequent deterioration in ride quality at these higher operating speeds. Improvement in suspension design is one option which can circumvent this problem. Suspension design for a modem high-speed train has hitherto been a heuristic procedure directed towards optimising the passive components of the suspension. Performance limits are now being reached with passive suspensions due to the inherent trade-offs which need to be made in the design process. Active suspension, which eases this inherent trade-off, has received a great deal of interest in both academia and industry over recent years. A number of theoretical and experimental studies have highlighted the potential benefits of active suspension technology. Theoretical studies have concentrated on using simple vehicle models and although providing the initial impetus to active suspension they have not given the industry full confidence in them. In contrast, experimental studies have highlighted a number of problems, most notably the significant effect actuators can have on the overall performance.

629.049

Ground transport systems

Characterisation and functional reconstruction of a neutral amino acid transport system

Lynch, A. M.

January 1987

No description available.

572

Amino acid transport systems