The invention relates to a bearing comprising a fixed or “stationary” ring, a rotary ring, and at least one row of rolling bodies disposed in a raceway that is formed between said rings so as to enable them to rotate relative to each other.
It applies typically to motor vehicle wheel bearings, the stationary ring being secured to the chassis of said vehicle and the wheel being associated with rotary ring.
When it is desired to determine the forces that are applied at the interface between the wheel and the surface on which the wheel is rotating, it is known that it is possible to measure said forces at the tire or at the chassis. Unfortunately, measurement at the tire poses major problems as regards transmitting the signal between the rotary reference frame of the tire and a stationary computation reference frame, it also being necessary for said rotary reference frame to be positioned continuously relative to said stationary reference frame so as to be able to perform the computations. As for measurement at the chassis, it is made difficult by the distribution of the forces between the various members that connect the wheel to said chassis.
Therefore, as proposed in Documents FR-2 839 553 and FR-2 812 356, the stationary ring, which is the first connection member between the wheel and the chassis, is used in particular as a support for determining the forces that are exerted at the interface between the wheel and the surface while the vehicle is moving.
In particular, such forces can be determined by measuring deformations in the stationary ring that are induced by the rolling bodies going past. The amplitude of such deformations is representative of the forces to be determined.
One of the problems that arises with such a force determination strategy is that the deformation signal depends on the speed of rotation. In particular, the quality of measurement at low speed is insufficient and forces can be determined only after measurement of deformations induced by at least two successive passes of rolling bodies.
Therefore, that problem is even more critical when force measurement must be performed in real time or with a delay that is a short as possible, as is necessary for systems for controlling the dynamics of the vehicle, such as, for example, an Antilock Braking System (ABS) or an Electronic Stability Program (ESP).
A particular object of the invention is to remedy this problem by proposing a bearing provided with a system for determining the amplitude of the deformations in the stationary ring, said system being arranged to perform spatial interpolation on the deformation signal so as to have, at any instant and independently of the speed of rotation, a measurement of the deformations and thus be able to determine the forces.
To this end, the invention provides a bearing comprising a stationary ring, a rotary ring, and at least one row of rolling bodies disposed in a raceway which is formed between said rings so as to enable them to rotate relative to each other, said rolling bodies being distributed uniformly in the raceway with an angular spacing λ, said bearing being provided with at least one determination system for determining the amplitude A of the pseudo-sinusoidal deformations of a zone of the stationary ring that are induced during the rotation, said bearing being characterized in that the determination system comprises:
Other objects and advantages of the invention will appear on reading the following description given with reference to the accompanying drawings, in which:
FIGS. 1 to 3 are perspective views of respective ones of three embodiments of a bearing, showing the gauges of four systems for determining the amplitudes of the pseudo-sinusoidal deformations, said gauges being disposed on respective zones of the stationary ring;
The invention relates to a bearing comprising a fixed or “stationary” ring 1, a rotary ring, and at least one row of rolling bodies 2 disposed in a raceway 3 that is formed between said rings so as to enable said rings to rotate relative to each other.
The stationary ring 1 is designed to be associated with a fixed or “stationary” structure and the rotary ring is designed to be associated with a rotary member. In a particular application, the bearing is a motor vehicle wheel bearing, the stationary structure being the chassis of the vehicle, and the rotary member being the wheel.
With reference to FIGS. 1 to 3, such a wheel bearing is described that comprises two rows of balls 2 that are disposed about a common axis in respective raceways 3 provided between the stationary outer ring 1 and the rotary inner ring. In addition, the stationary ring 1 is provided with fastening means for fastening to the chassis, which fastening means are formed by a flange 4 provided with four radial projections 5 in each of which an axial hole 6 is provided for enabling fastening to be achieved by means of bolting.
As shown in
The invention aims to make it possible to determine the amplitude of the deformations of at least one zone 7 of the stationary ring 1 so that it is possible to deduce therefrom the forces that are applied at the interface between the wheel and the surface on which said wheel is rotating.
The balls 2 rolling along the raceway 3 induces compression and relaxation of the stationary ring 1. Thus, during rotation, the stationary ring 1 is subjected to a periodic deformation that can be approximated to a sine wave. In the description below, the term “pseudo-sinusoidal deformations” is used to designate the deformations of the stationary ring 1 during rotation.
Pseudo-sinusoidal deformation is characterized by an amplitude that depends on the loads to which the bearing is subjected and thus to the forces that are applied at the interface, and a frequency that is proportional both to the speed of rotation of the rotary ring and also to the number of balls 2.
Although the description is given with reference to a wheel bearing comprising two rows of balls 2 for which the amplitudes of the deformations are determined independently, said description is directly transposable by the person skilled in the art to some other type of bearing and/or to some other application in which it is desired to determine the amplitude of the pseudo-sinusoidal deformations of at least one zone 7 of the stationary ring 1.
In accordance with the invention, the bearing is provided with at least one system for determining the amplitude A of the pseudo-sinusoidal deformations of a zone 7 of the stationary ring 1 that are induced during the rotation, said system comprising four strain gauges 8.
Each of the gauges 8 is suitable for delivering a signal as a function of the deformation to which it is subjected. As shown in FIGS. 1 to 3, the gauges 8 are distributed uniformly over the zone 7 along a line that extends in the general direction of the rotation.
The determination system further comprises a measurement device 9 for measuring four signals Vi, each of which is a function of the time variations of the signal emitted by a respective one of the gauges 8 during the rotation, said device being suitable, by combining the four signals Vi, for forming two signals SIN and COS of the same angle and of the same amplitude, said amplitude being a function of A.
From said two signals SIN and COS, it is possible, via a computation device 10 formed, for example, by a processor, to deduce the amplitude A by computing the expression SIN2+COS2.
Thus, since the amplitude is computed independently of the speed of rotation, it is possible to overcome, in particular, the problems of delay or of quality that are inherent to temporal determination of the deformations.
With reference to FIGS. 4 to 6, a description follows of first and second embodiments of a determination system of the invention, in which the gauges 8 are based on resistive elements, in particular piezoresistive or magnetostrictive elements, so that each of them has an electrical resistance Ri that varies as a function of the deformations to which said strain 8 is subjected. In particular, each of the gauges 8 can comprise either a single resistor, or a block of a plurality of resistors that are combined to obtain an averaged resistance that is representative of the resistance at the position of the block, which means of a single resistance.
In the two embodiments shown, the measurement device 9 comprises a current loop circuit between the four gauges 8. The circuit further comprises four differential amplifiers 11 having adjustable gain Gi. In addition, the measurement device 9 can further comprise a signal filter stage (not shown).
The measurement device 9 thus delivers at the outputs of the amplifiers 11, the following signals:
Vi=G1×(R01+ΔR1 sin(ωt))i
V2=G2×(R02+ΔR2 sin(ωt+φ))i
V3=G3×(R03+ΔR3 sin(ωt+2φ))i
V4=G4×(R04+ΔR4 sin(ωt+3φ))i
where R0i are the resistances at rest of the resistors Ri, ΔRi are the variations in the resistances of the gauges 8, ω=2π/T (T is the time period), φ is the spatial phase shift between the gauges 8, and i is the current in the loop.
The sinusoidal nature (relative to time) of the sampled function is used to simplify the following computations, but is in no way limiting. This hypothesis assumes that the bearing is rotating at constant speed (ω constant).
In the embodiment shown in
V1−V2=[(G1R01−G2R02)+G1ΔR1 sin(ωt)−G2ΔR2 sin(ωt+φ)]×i (1)
V3−V4=[(G3R03−G4R04)+G3ΔR3 sin(ωt+2φ)−G4ΔR4 sin(ωt+3φ)]×i (2)
By adjusting the output gains Gi so that: G1=G2=G3=G4=G, by setting the resistances at rest of the resistors such that: R01=R02=R03=R04, and, by assuming that ΔR1=ΔR2=ΔR3=ΔR4=ΔR, the differences (1) and (2) become:
V1−V2=[GΔR[sin(ωt)−sin(ωt+φ)]]×i (3)
V3−V4=[GΔR[sin(ωt+2φ)−sin(ωt+3φ)]]×i (4)
In particular, equality for the values of ΔRi can be obtained when the gauges 8 are equidistant from the raceway.
In the particular case when φ=π/2, i.e. when the gauges 8 are spaced apart by a distance equal to λ/4, the differences (3) and (4) can be written:
V1−V2=[√{square root over (2)}GΔR cos(ωt+π/4)]×i
V3−V4=[√{square root over (2)}GΔR sin(ωt+π/4)]×i
Therefore, in this particular case, the measurement device 9 shown in
Thus, by computing the expression SIN2+COS2, it is possible to obtain:
[√{square root over (2)}GΔR]2×i2
thereby making it possible, at the output of the computation device 10, to obtain, as a function of time, the amplitude A which is a function of ΔR.
With reference to
For this purpose, the measurement device 9 further comprises two stages of differential amplifiers 11, the first stage being analogous to the amplifier stage of the first embodiment of
The second stage comprises two differential amplifiers 11 that are shown respectively in
U=[(V1−V2)−(V3−V4)]; and
V=[(V1−V3)−(V4-V2)]
i.e., on the basis of the relationships (3) and (4):
We thus have U=SIN and V=COS, so that, as explained above, we can obtain the amplitude A that is a function of ΔR by computing the expression SIN2+COS2 in the computation device 10.
It should be noted that, if φ is different from π/2, the amplitudes of the signals U and V are different. In order to equalize said amplitudes, it is possible to make provision for at least one differential amplifier 11 of the second stage to have adjustable gain. In particular, the gain of the amplifier 11 forming the signal U can be adjusted to:
In a variant of the embodiment shown in
U=[(V1-V2)−(V3-V4)]; and
V=2(V2-V3)
This variant is particularly suitable for the case when the amplitudes of the signals Vi cannot be considered to be identical, i.e. when the gauges do not detect a sine wave of the same amplitude A. Assuming a linear load distribution between the four gauges 8, the signals Vi can be written:
Vi=(G1R01+(A+3a)sin(ωt))i
V2=(G2R02+(A+a)sin(ωt+φ))i
V3=(G3R03+(A−a)sin(ωt+2φ))i
V4=(G4R04+(A−3a)sin(ωt+3φ))i
where a is the linear variation in the amplitude A to be measured.
Assuming that φ=π/2 in order to simplify the computations, although the solution in this variant is also applicable to any value of φ, the following are obtained:
We thus have U=SIN and V=COS and the square root of the expression SIN2+COS2 is equal to:
Therefore, a limited development of the first order (a<<A) gives us 2√2A×i and thus the amplitude A which is the amplitude induced at the center of the zone in which the gauges 8 are distributed.
With this particular configuration of the gauges 8, the following relationship can be written:
ΔR2=k ΔR1, where k>1 since R1 is further away from the raceway than R2 and thus the signal from the deformation of R1 will be smaller than the signal from R2.
And, because of the symmetry in the configuration of the gauges 8 in the deformation zone 7, we have:
ΔR3=k ΔR4=ΔR2=k ΔR1
Furthermore, the gains are adjusted so that G1ΔR1=G2ΔR2=G3ΔR3=G4ΔR4.
Therefore, with the preceding relationship, we have:
G1=kG2=G4=kG3
In this particular configuration, the resistances at rest of the resistors must thus be such that:
R02=kR01;
R03=kR04; and
R02=R03.
Therefore, in the configuration of the gauges 8 of
In the general case when the gauges 8 are located on the cylindrical periphery of the outer ring 1, the gauge-to-raceway distances are all equal so that k=1. Therefore, in all cases, the gains are equal and the resistances at rest of the resistors must also be equal.
With reference to
Although the above-described gauges 8 are based on resistive elements, other gauges 8, e.g. sensors chosen from surface acoustic wave sensors and magnetic field sensors can be used in the context of the invention providing that they deliver signals that are functions of deformations. In particular, magnetic field sensors can be based on sensitive elements of the following types: magneto-resistance, giant magneto-resistance, Hall effect, tunnel-effect magneto-resistance, and magnetostrictive layers.
In the embodiment shown, the gauges 8 are screen printed in a thick layer on the substrate 12, e.g. made of a ceramic. In particular, a technology of the hybrid type makes it possible to integrate the measurement device 9 and the computation device 10 on the substrate 12 (see embodiment of
The deformation zone 7 is machined so that it is substantially plane and so that it extends above the two rows of balls 12. In this embodiment, the gauges 8 are not equidistant from the raceway 3 so that the amplitude of the deformation measured is a function of the gauge 8 in question (see
In the embodiment shown in
In the embodiment shown in
In particular, the gauges 8 are disposed on the outside periphery of the stationary ring 1, substantially facing each of the raceways 3 so as to increase the intensity of the signals to be measured. Thus, the substrate 12 carrying the gauges 8 makes it possible to determine the amplitude of the deformations induced respectively by essentially one row of balls 2, in the same axial plane.
The bearing can be provided with at least three (eight in the embodiment shown in
Number | Date | Country | Kind |
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040768 | May 2004 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FR05/01108 | 5/3/2005 | WO | 9/12/2007 |