FR2998244A1 - Method for correcting level of assistance to electric power steering of car, involves detecting dynamics of steering wheel angle, and applying variable gain on base reference current, which depends on dynamics of steering wheel angle - Google Patents

Abstract

The method involves providing assistance force by an electric motor to a steering column according to the speed (74) of a car and a torque (76) applied by a driver on a steering wheel, so as to establish a base reference current (72) for the electric motor. A detection of dynamics of a steering wheel angle (52) is performed, and a variable gain (78) is applied on the base reference current, which depends on the dynamics of the steering wheel angle. The variable gain is multiplied by the base reference current to obtain a final current. An independent claim is also included for a system for monitoring an electric power steering of a car.

Description

The present invention relates to a method for correcting the level of assistance of an electric power steering system for a motor vehicle, as well as a system and a motor vehicle employing the invention. such a correction method. A used motor vehicle power steering system comprises a hydraulic pump which delivers a pressure of assistance on a cylinder connected to the steering rack, depending on the forces applied by the driver on the steering wheel. This type of hydraulic power steering generally gives the driver a feeling of effort on the steering wheel that reproduces fairly faithfully the forces applied to the wheels for their steering. This feeling makes it possible in particular to appreciate in the bends the variations of efforts, in order to allow precise dosing, and to ensure safety as well as comfort. A known type of power steering which is developing today, presented in particular by the document US Pat. No. 4,538,698, comprises an electric motor which applies an assist torque on the steering column, comprising an intensity dependent on the speed of the vehicle as well as the angle of rotation of the steering wheel. In this way the level of assistance is adjusted according to this speed and this angle, in order to give both conditions of control of the vehicle to ensure safety, and good comfort. However, under certain dynamic conditions involving rapid changes in the steering angle, electric power steering systems do not deliver a similar steering-wheel-like feel to hydraulic power steering, which can give the driver an unpleasant impression, and reduce Security.

The present invention is intended to avoid these disadvantages of the prior art. It proposes for this purpose a method of correcting the level of assistance of an electric power steering of a motor vehicle, comprising an electric motor delivering an assistance effort on the steering column depending on the speed of the vehicle and of the torque applied by the driver on the steering wheel, which make it possible to establish a basic current setpoint for this electric motor, characterized in that it realizes a detection of the dynamics of the flying angle, and that it applies a variable gain on the current base setpoint, which depends on this dynamic. An advantage of the correction method according to the invention is that while maintaining an equivalent level of assistance for angle variations with a low dynamic range, it is possible to correct the gain in a particular way for certain wheel steering speeds comprising a 15 higher dynamic, to bring the feeling by the driver with that given by a hydraulic steering. The method of correcting the level of assistance according to the invention may further include one or more of the following features, which may be combined with one another. Advantageously, the correction method multiplies the variable gain by the electric current base setpoint, to obtain a final current setpoint. Advantageously, the method calculates the variable gain from a gain function comprising mappings, which receives the detection of the dynamics of the steering angle as well as information on the speed of the vehicle, to establish from these mappings this gain value. Advantageously, the method subtracts the filtered low-pass filter angle value from the raw fly-angle value given by a sensor to obtain a high-frequency dynamic signal which is centered around a value. angle of 0 °.

The correction method can then filter by a high-pass filter the signal comprising the high-frequency dynamic, to obtain the dynamics of the flying angle. Advantageously, for some dynamics the gain is asymmetrical 5 depending on the direction of the dynamic movement of the steering wheel. In particular, during a dynamic operation of the steering, the method can achieve a variable gain giving an increase in the maximum torque on the steering wheel, and a reduction of the minimum torque. The invention also relates to a control system for an electric power steering, comprising a vehicle speed sensor and a torque sensor on the steering wheel, which send information to a function of calculating the basic setpoint of the current for the electric steering assistance motor, this system comprising a dynamic detection function receiving information from a steering wheel angle sensor, which delivers this dynamic to a gain calculation function comprising mappings, receiving in addition the vehicle speed information, to establish a gain value which is multiplied by the base setpoint to obtain the final current setpoint of the electric motor. The invention furthermore relates to a motor vehicle having an electric power steering which is controlled by an assistance level management system, this vehicle comprising means implementing a correction method of this level of assistance. assistance, comprising any of the preceding features. The invention will be better understood and other features and advantages will emerge more clearly on reading the following description, given by way of example and in a nonlimiting manner with reference to the appended drawings, in which: FIG. 1 is a graph showing a power steering operation simulation protocol, which includes a time-angle angle variation; - Figures 2 and 3 are graphs showing from this protocol and for two different settings, the torque on the steering wheel for hydraulic and electrical power steering; FIG. 4 is a schematic diagram of the operation of the correction method according to the invention; FIG. 5 shows, as a function of time, different angle calculations established by this method; and FIG. 6 shows a power steering system implementing the method according to the invention.

FIG. 1 shows, as a function of the time T expressed in seconds, a flying angle variation 0 for a simulation protocol of a power steering, making it possible to simulate driving forces, and to compare steering wheel torque between a power steering system of the hydraulic type and another of the electric type, so as to try to obtain similar behaviors. From a flywheel angle zero, a rotation of this flywheel giving a constant ramp which starts at 0.5s, to reach after a duration of 1s a bearing angle 01, then a stabilization on this angle of bearing for 1.5s. Then there is a sinusoidal oscillation of the steering wheel angle, having a constant period which is adjusted to obtain different results. FIGS. 2 and 3 show, as a function of time T expressed in seconds, the steering wheel torque C in Nm given by simulations according to the protocol presented above, with for each figure identical parameters so as to obtain comparable results, for a hydraulic direction 10, 20 and for an electrical direction 12, 22. For the electrical direction, the level of assistance is calculated by a method usually used, so as to study the difference in reaction between the two types of power steering, so to see the corrections to bring to get a feeling comparable between them.

FIG. 2 shows simulations carried out with the following parameters, a vehicle speed of 50km / h, a bearing angle θ of 90 °, and a sinusoidal oscillation around this bearing angle of +/- 45 ° with a frequency of 1 Hz.

FIG. 3 similarly shows simulations carried out with the following parameters, a vehicle speed of 120km / h, a bearing angle θ of 37.5 °, and a sinusoidal oscillation around this bearing angle of +/- 20 °. with a frequency of 0.5Hz. It can be seen from these two figures that the levels of torque for level stabilization are slightly different between the two types of assisted steering, which is explained by the settings of the management of assistance which are different. It is also noted that the amplitude of the flying torque during the sinusoidal oscillation is greater for the hydraulic power steering 10, 20, with a greater difference for the higher frequency of 1 Hz. In addition, it exists with the power steering 10, 20 hydraulic torque discontinuities flying during oscillations, forming torque peaks. However, these peaks having very short durations with a high frequency, it is considered that they have very little influence on the feeling of conductor.

In order to try to bring the flying torque curves of the electrical direction 12, 22 closer to those of the hydraulic direction 10, 20, modifications of the gain for this first type of direction have been tried, with the help of current setpoint on the electric assist motor.

Tests conducted for different sinusoidal oscillations have shown that the torque deviation can be slightly reduced during these oscillations, but the level of stabilized bearing torque is strongly modified, which is undesirable. Moreover these tests have shown that for oscillation frequencies ranging between 0.25 and 2Hz, the amplitude of the flying torque is an increasing function of the frequency for the hydraulic direction, whereas for the electrical direction it is a function first decreasing then increasing. It is therefore not possible to apply a simple rule of correction of the gain of the assistance for the electrical direction, which would use for example a linear function dependent on the frequency.

Figures 4 and 5 show a dynamic range detection function 38 of the steering wheel angle 0, established by the assistance level correction method according to the invention. From the detection of the dynamic represented by a frequency, and according to other parameters such as the vehicle speed and the average flywheel angle, the method will then apply a specific value given by a mapping, at the gain which controls the level of assistance from the electrical direction. Detection of the dynamics of the flying angle makes it possible to adjust the gain level precisely according to the particular dynamics, and to distinguish the ducts with a low dynamic so as not to degrade the torque level for the operations in operation. quasi-static. The measurement of the flying angle given by a sensor 30, represented by the curve 40, is delivered directly to a subtraction operator 32 which subtracts from this measurement the value of this angle filtered by a low-pass filter 34, which is represented by the curve 42. The low-pass filter 34 makes it possible to obtain a signal devoid of significant dynamics, and therefore of high frequency. The signal 50 delivered by the subtraction operator 32 then comprises the high frequency dynamic, which is centered around an angle value of 0 °.

The signal 50 delivered by the subtraction operator 32 is then filtered by a high-pass filter 36, which eliminates the low frequency variation of the departure given by the ramp and the stabilization bearing, to obtain a final signal representing only the oscillation. high frequency which is representative of the dynamics of the flying angle 52.

Figure 6 shows a control system for a power steering, implementing the method according to the invention.

A vehicle speed sensor 60 and a torque sensor on the steering wheel 62, respectively send a vehicle speed information 74 and a torque information to the steering wheel 76, to a function of calculating the basic setpoint of the current 64 for the electric motor assistance of the direction. This setpoint calculation function 64 delivers a current base setpoint 72 to a multiplication operator 66. The steering angle sensor 30 sends the information on the angle of the steering wheel 40 to the dynamic detection function 38 described. above, to obtain the dynamics of the steering angle 52 which is delivered to a gain calculation function having maps 68, further receiving the vehicle speed information 74. The gain calculating function 68 sets to from this information received, and maps contained in memory, a variable gain 78 which is delivered to the multiplication operator 66, in order to multiply the basic setpoint 72 by this variable gain to obtain a final current setpoint which is delivered to the power supply system of the electric steering motor 70. Advantageously, the variable gain 78 established by the mapping function 68, represents the gap required for, depending on the conditions particular steering and vehicle operation, restore a feeling on the steering wheel that is close to that given by a power steering of the hydraulic type. In particular, the variable gain can be asymmetrical depending on the direction of the dynamic movement of the steering wheel. In particular with a mean angle of rotation of the flywheel which is positive, when the dynamic detection signal of the flying angle 52 is positive the gain value may be less than 1, and when this signal is negative the gain value may be greater than to 1. An assistance is thus provided comprising an increase in the maximum torque and a reduction in the minimum torque, in order to get as close as possible to the assistance laws given by a hydraulic steering.

Advantageously, the method is implemented by the computer that manages the electric power steering of the vehicle. This is done only with software supplements, from existing components in vehicles equipped with electrical steering, a standardization of torque sensations on the steering wheel compared to a hydraulic steering, which provides safety by giving the driver a consistent driving impressions, as well as comfort. This standardization is all the more important as the electrical directions are developing strongly today, especially for reasons of reducing vehicle consumption.

Claims (9)

CLAIMS1 - Method for correcting the level of assistance of an electric power steering of a motor vehicle, comprising an electric motor delivering an assistance effort on the steering column according to the speed of the vehicle (74) and the torque applied by the driver on the steering wheel (76), which make it possible to establish a basic current setpoint (72) for this electric motor, characterized in that it carries out a detection of the dynamics of the steering wheel angle (52), and that it applies a variable gain (78) to the current base setpoint (72), which depends on this dynamics. 2 - Correction method according to claim 1, characterized in that it multiplies the variable gain (78) by the electric current base setpoint (72), to obtain a final current setpoint. 3 - correction method according to claim 1 or 2, characterized in that it calculates the variable gain (78) from a gain function (68) having maps, which receives the detection of the dynamics of the angle steering wheel (52) and information on the speed of the vehicle (74), to establish from these maps this gain value. 4 - correction method according to any one of the preceding claims, characterized in that it subtracts the value of flying angle (40) filtered by a low-pass filter (34) to the given gross steering angle value by a sensor (30), to obtain a signal comprising the high frequency dynamic (50) which is centered around an angle value of 0 °. 5 - correction method according to claim 4, characterized in that it then filters by a high-pass filter (36) the signal comprising the high-frequency dynamic (50), to obtain the dynamics of the flying angle (52) . 6 - Correction method according to any one of the preceding claims, characterized in that for some dynamics the gain (78) is asymmetrical depending on the direction of the dynamic movement of the steering wheel. 7 - correction method according to claim 6, characterized in that during a dynamic operation of the direction, it achieves a variable gain (78) giving an increase in the maximum torque on the steering wheel, and a reduction of the minimum torque . 8 - Control system for an electric power steering, comprising a vehicle speed sensor (60) and a torque sensor on the steering wheel (62), which send information to a function of calculating the basic setpoint of the current ( 64) for the electric power steering assistance motor, characterized in that it furthermore comprises a dynamic detection function (38) receiving information from a flying angle sensor (30), which delivers this dynamic (52) to a gain calculation function having maps (68), further receiving the vehicle speed information (74), for setting a gain value (78) which is multiplied by the base setpoint ( 64) to obtain the final current setpoint of the electric motor. 9 - A motor vehicle having an electric power steering which is controlled by an assistance level management system, characterized in that it comprises means implementing a correction method of this level of assistance performed according to the invention. any of claims 1 to 7.