JP4130147B2 - Power steering device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a power steering apparatus provided with a flow control valve for preventing energy loss.
[0002]
[Prior art]
As a power steering apparatus provided with a flow control valve for preventing energy loss, there is one already disclosed by the present applicant as Japanese Patent Application Laid-Open No. 2001-260917 (Patent Document 1).
In this conventional apparatus, as shown in FIG. 11, one end of the spool 1 of the flow control valve V faces one pilot chamber 2 and the other end of the spool 1 faces the other pilot chamber 3.
A pump P is always in communication with the one pilot chamber 2 through a pump port 4. The one pilot chamber 2 communicates with the inflow side of the steering valve 9 that controls the power cylinder 8 via the flow path 6 → the variable orifice a → the flow path 7.
[0003]
On the other hand, in the other pilot chamber 3, a spring 5 is interposed and communicated with the inflow side of the steering valve 9 through a flow path 10 and a flow path 7. Therefore, the pilot chambers 2 and 3 communicate with each other through the flow path 6 → the variable orifice a → the flow path 7 → the flow path 10, and the pressure upstream of the variable orifice a is applied to one pilot chamber 2. The downstream pressure acts on the other pilot chamber 3. The opening of the variable orifice a is controlled by a solenoid current command value SI for the solenoid SOL.
[0004]
The spool 1 maintains a position where the acting force of one pilot chamber 2 and the acting force of the other pilot chamber 3 and the spring force of the spring 5 are balanced, but at the balanced position, the opening degree of the tank port 11 is maintained. Is decided.
For example, when the pump P is driven by the operation of a pump drive source 12 such as an engine, pressure oil is supplied to the pump port 4 and a flow is generated in the variable orifice a. When a flow occurs in the variable orifice a in this way, a differential pressure is generated before and after that, and a pressure difference is generated in both pilot chambers 2 and 3 due to this differential pressure. Then, due to this pressure difference, the spool 1 moves from the normal position shown in the figure to the balance position against the spring 5.
[0005]
When the spool 1 moves from the normal position in this way, the opening degree of the tank port 11 increases, but the control flow rate QP guided from the pump P to the steering valve 9 side according to the opening degree of the tank port 11 at this time The distribution ratio with the return flow rate QT returned to the tank T or the pump P is determined. In other words, the control flow rate QP is determined according to the opening degree of the tank port 11.
[0006]
Thus, the fact that the control flow rate QP is controlled according to the opening degree of the tank port 11 ultimately determines the control flow rate QP according to the opening degree of the variable orifice a. This is because the moving position of the spool 1 that determines the opening of the tank port 11 is determined by the pressure difference between the pilot chambers 2 and 3, and this pressure difference is determined by the opening of the variable orifice a.
[0007]
Therefore, in order to control the control flow rate QP according to the vehicle speed and the steering situation, it is only necessary to control the opening of the variable orifice a, that is, the solenoid current command value SI for the solenoid SOL. This is because the opening of the variable orifice a can be arbitrarily controlled from the maximum to the minimum depending on the magnitude of the excitation current of the solenoid SOL.
[0008]
On the other hand, the steering valve 9 to which the control flow rate QP is guided controls the supply amount to the power cylinder 8 in accordance with an input torque (steering torque) of a steering wheel (not shown). For example, if the steering torque is large, the switching amount of the steering valve 9 is increased to increase the supply amount to the power cylinder 8. Conversely, if the steering torque is small, the switching amount of the steering valve 9 is decreased to reduce the power cylinder. The supply amount to 8 is reduced. The power cylinder 8 exhibits a larger assist force as the pressure oil supply amount is larger, and the assist force is smaller as the supply amount is smaller.
Note that the switching amount of the steering torque and the steering valve 9 is set by a torsional reaction force such as a torsion bar (not shown).
[0009]
The required flow rate QM supplied to the power cylinder 8 as described above is controlled by the steering valve 9. The control flow rate QP supplied to the steering valve 9 is controlled by the flow rate control valve V as described above. Has been. Here, if the required flow rate QM required by the power cylinder 8 and the control flow rate QP determined by the flow rate control valve V are made as equal as possible, the energy loss on the pump P side can be kept low. This is because the energy loss on the pump P side is caused by the difference between the control flow rate QP and the required flow rate QM of the power cylinder 8.
Therefore, in order to prevent the energy loss by making the control flow rate QP as close as possible to the required flow rate QM of the power cylinder 8, the opening degree of the variable orifice a is controlled in this conventional example. The opening degree of the variable orifice a is determined by the excitation current for the solenoid SOL as described above, and the controller C described below controls the excitation current.
[0010]
A steering angle sensor 14 and a vehicle speed sensor 15 are connected to the controller C. As shown in FIG. 12, the controller C specifies the current command value I1 based on the steering angle detected by the steering angle sensor 14, and also determines the current command value based on the steering angular velocity calculated by differentiating the steering angle. I2 is specified.
The steering angle and the current command value I1 are determined on the basis of a theoretical value in which the relationship between the steering angle and the control flow rate QP is a linear characteristic. Further, the relationship between the steering angular velocity and the current command value I2 is also determined based on a theoretical value in which the relationship between the steering angular velocity and the control flow rate QP is a linear characteristic. However, the current command value I1 and the current command value I2 are both set to output zero unless the steering angle and the steering angular velocity exceed a certain set value. That is, when the steering wheel is in the neutral position or in the vicinity thereof, the current command values I1 and I2 are set to zero to make the neutral vicinity a dead band.
[0011]
Further, the controller C outputs a steering angle current command value I3 and a steering angular velocity current command value I4 based on the detection value of the vehicle speed sensor 15.
The steering angle current command value I3 is set to 1 in the low speed range and to, for example, 0.6 in the maximum speed range. Further, the steering angular velocity current command value I4 is set to 1 in the low speed range and, for example, 0.8 in the maximum speed range. That is, the steering angle current command value controlled in the range of 1 to 0.8 is controlled by the steering angle current command value I3 controlled in the range of 1 to 0.6. It is made larger than I4.
[0012]
The steering angle current command value I3 is multiplied by the steering angle current command value I1. Therefore, the steering angle system current command value I5, which is the multiplication result, becomes smaller as the speed increases. In addition, since the gain of the steering angle current command value I3 is set to be larger than the gain of the steering angular velocity current command value I4, the reduction rate increases as the speed increases. That is, the responsiveness is kept high in the low speed range, and the responsiveness is lowered in the high speed range. The reason why the responsiveness is changed in accordance with the vehicle speed in this way is generally that high responsiveness is not required during high-speed driving, and high responsiveness is generally required in the low speed range. .
[0013]
On the other hand, for the current command value I2 based on the steering angular velocity, the steering angular velocity current command value I6 is output using the steering angular velocity current command value I4 as a limit value. The current command value I6 is also decreased according to the vehicle speed. However, since the gain of the steering angular velocity current command value I4 is smaller than the steering angular current command value I3, the rate of decrease of the current command value I6 is smaller than that of the current command value I5.
The reason why the limit value is set according to the vehicle speed is mainly to prevent the excessive assist force from being exerted during high-speed traveling.
[0014]
The steering angle system current command value I5 and the steering angular velocity system current command value I6 output as described above are compared, and the larger value is adopted.
For example, the steering angle system current command value I5 is usually larger than the steering angle speed system current command value I6 because the steering is hardly operated suddenly at high speed. Therefore, in most cases, the current command value I5 for the steering angle system is selected during high speed traveling. In order to increase the safety and stability of the steering operation at this time, the gain of the current command value I5 is increased. That is, the higher the traveling speed, the higher the ratio of decreasing the control flow rate QP, thereby improving the safety and stability during traveling.
[0015]
On the other hand, when the vehicle is traveling at a low speed, the steering is frequently operated suddenly. In many cases, the steering angular velocity is larger. For this reason, the current command value I6 of the steering angular velocity system is almost selected during low-speed traveling. When the steering angular velocity is large as described above, responsiveness is emphasized.
Therefore, when the vehicle is traveling at low speed, the gain of the current command value I6 of the steering angular velocity system is reduced with reference to the steering angular velocity in order to improve the operability of the steering operation, that is, the responsiveness. In other words, even when the traveling speed is increased to some extent, when the steering is suddenly operated, the control flow rate QP is sufficiently ensured to ensure responsiveness.
[0016]
The standby current command value I7 is added to the current command value I5 or I6 selected as described above. Then, a value obtained by adding the standby current command value I7 is output to the drive device 16 as a solenoid current command value SI.
[0017]
Since the standby current command value I7 is added in this way, the solenoid current command value SI is maintained at a predetermined magnitude even when the current command values based on the steering angle, the steering angular velocity, and the vehicle speed are all zero. Yes. Therefore, a predetermined flow rate is always supplied to the steering valve 9 side. From the viewpoint of preventing energy loss, if the required flow rate QM on the power cylinder 8 and steering valve 9 side is zero, it is ideal that the control flow rate QP of the flow control valve V is also zero. That is, setting the control flow rate QP to zero means returning the entire discharge amount of the pump P from the tank port 11 to the pump P or the tank T. And since the flow path which returns from the tank port 11 to the pump P or the tank T is in the main body B and is very short, there is almost no pressure loss. Since there is almost no pressure loss, the driving torque of the pump P can be suppressed to the minimum, which leads to energy saving. From this point of view, when the required flow rate QM is zero, setting the control flow rate QP to zero is advantageous from the viewpoint of preventing energy loss.
[0018]
Nevertheless, the reason why the standby flow rate QS composed of the standby current command value I7 is secured even when the required flow rate QM is zero is as follows.
First, it is for preventing the burn-in of the apparatus. That is, a cooling effect can be expected by circulating the standby flow rate QS to the apparatus.
Second, it is to ensure responsiveness. That is, if the standby flow rate QS is ensured as described above, the time to reach the target control flow rate QP can be shorter than when there is no standby flow rate QS. Since this time difference becomes responsiveness, the responsiveness can be improved by securing the standby flow rate QS.
[0019]
Thirdly, it is also for combating disturbances such as kickback and self-aligning torque. That is, when a drag force due to disturbance, self-aligning torque, or the like acts on the tire, it acts on the rod of the power cylinder 8. If the standby flow rate QS is not ensured, the tire will fluctuate due to the drag due to this disturbance and self-aligning torque. However, if the standby flow rate is secured, the tire will not wobble even if the above-described drag acts. That is, since the pin of the power cylinder 8 is engaged with a pinion or the like for switching the steering valve 9, when the drag acts, the steering valve 9 is also switched, and the standby flow rate QS in a direction against the drag. Will be supplied. Therefore, if the standby flow rate QS is secured, the disturbance due to the kickback and the self-aligning torque can be countered.
[0020]
Next, the operation of this conventional example will be described.
While the vehicle is traveling, a steering angle system current command value I5, which is a product of the solenoid current command value I1 based on the steering angle and the steering angle current command value I3, is output. At the same time, the steering angular velocity system current command value I6 is output. The current command value I6 is obtained by setting the steering angular velocity current command value I4 of the solenoid current command value I2 based on the steering angular velocity as a limit value.
Then, the magnitude of the current command value I5 for the steering angle system and the current command value I6 for the steering angular velocity system is determined, and the standby current command value I7 is added to the larger current command value I5 or I6. The solenoid current command value SI at that time is determined. The solenoid current command value SI is mainly based on the steering angle system current command value I5 when the vehicle is traveling at high speed, and is mainly based on the steering angular velocity system current command value I6 when the vehicle is traveling at low speed.
[0021]
A slit 13 is formed at the tip of the spool 1. The slit 13 allows one pilot chamber 2 and the variable orifice a to communicate with each other even when the spool 1 is in the normal position shown in the figure. That is, even when the spool 1 is in the normal position, the pressure oil supplied from the pump port 4 to the one pilot chamber 2 is supplied to the steering valve 9 via the slit 13 → the flow path 6 → the variable orifice a → the flow path 7. By supplying to the side, prevention of image sticking, prevention of disturbance such as kickback, and responsiveness are ensured.
In the figure, reference numerals 17 and 18 are throttles, and reference numeral 19 is a relief valve.
[0022]
[Patent Document 1]
Japanese Patent Laid-Open No. 2001-260917 (pages 3 to 7, FIGS. 1 and 2)
[0023]
[Problems to be solved by the invention]
In the above-described conventional power steering device, when the steering wheel is stopped in a large steering angle range, a current command value corresponding to the steering angle is output, so that the control flow rate hardly decreases.
However, when the steering wheel is stopped in the small steering angle range as shown in FIG. 13, not only the current command value corresponding to the steering angle is reduced as shown in FIG. 14, but also the steering that has been output until then. Since the current command value of the angular velocity system is almost lost, the current command value is rapidly decreased. When the current command value is suddenly reduced in this way, the control flow rate QP is suddenly reduced. As a result, the required steering torque suddenly increases, and as a result, stable steering cannot be performed or the driver feels uncomfortable. There was a problem.
[0024]
An object of the present invention is to provide a power steering device capable of stable steering even when an input current command value is sharply reduced and not causing a driver to feel uncomfortable.
[0025]
[Means for Solving the Problems]
The present invention controls a steering valve for controlling a power cylinder, a variable orifice provided upstream of the steering valve, a solenoid for controlling the opening of the variable orifice, and a solenoid current command value SI for driving the solenoid. Controller, a steering state detection sensor connected to the controller and detecting a steering state such as a steering angle and a steering angular velocity, and pressure oil supplied from a pump according to the opening of the variable orifice and the tank Or a flow control valve that distributes to the pump side, and the controller assumes a power steering device that specifies a solenoid current command value SI based on current command values corresponding to various signals from the steering situation detection sensor. To do.
[0026]
The first invention is based on the above invention, and the controller includes a current command value characteristic storage unit, a delay control characteristic storage unit, an execution unit, and a current command value maintaining unit, and the current command value The characteristic storage unit stores the actual current command value Ib based on the steering angular velocity signal from the steering situation detection sensor, the delay control characteristic storage unit stores the reference decrease rate Δa for specifying the reference current command value Ia, and the execution The unit calculates a decrease rate Δb per unit time of the current command value Ib, and compares the calculated decrease rate Δb with the reference decrease rate Δa. When Δa ≧ Δb, the actual current command value Ib And a reference current command value Ia based on the reference reduction rate Δa is output when Δa <Δb, while the current command value maintaining unit outputs the execution unit when the vehicle speed is equal to or lower than a predetermined value. Reference current at that time Maintaining a decree value Ia.
[0027]
The second invention is based on the above invention, and the controller includes a current command value characteristic storage unit, a delay control characteristic storage unit, an execution unit, and a current command value maintaining unit, and the current command value The characteristic storage unit stores the actual current command value Ib based on the steering angular velocity signal from the steering situation detection sensor, the delay control characteristic storage unit stores the reference decrease rate Δa for specifying the reference current command value Ia, and the execution The unit calculates a decrease rate Δb per unit time of the current command value Ib, and compares the calculated decrease rate Δb with the reference decrease rate Δa. When Δa ≧ Δb, the actual current command value Ib outputs, .DELTA.a <while outputting a reference current command value Ia based on the reference reduction rate .DELTA.a when [Delta] b, the current instruction value holding section, when the steering angle is equal to or higher than the predetermined value, the execution unit is output The reference voltage at that time Maintaining the command value Ia.
[0028]
According to the first and second aspects of the invention, when the reference current command value Ia is output or when the output current command value is maintained, the rate of decrease in the supply flow rate to the steering valve is reduced. It can be controlled in the direction to do.
[0029]
DETAILED DESCRIPTION OF THE INVENTION
1 to 5 show a first embodiment of the present invention. Since the configuration other than the controller C shown in FIG. 11 is exactly the same as the conventional example, only the controller C will be described below.
[0030]
As shown in FIG. 1, the controller C specifies the current command value I1 based on the steering angle detected by the steering angle sensor 14, and also determines the current command value I2 based on the steering angular velocity calculated by differentiating the steering angle. Is identified. However, a steering angular velocity sensor may be provided separately, and the current command value I2 may be specified based on the steering angular velocity detected by the steering angular velocity sensor.
The steering angle and the current command value I1 are determined based on a theoretical value in which the relationship between the steering angle and the control flow rate QP is a linear characteristic. Further, the relationship between the steering angular velocity and the current command value I2 is also determined based on a theoretical value in which the relationship between the steering angular velocity and the control flow rate QP is a linear characteristic.
[0031]
Further, the controller C outputs a steering angle current command value I3 and a steering angular velocity current command value I4 based on the detection value of the vehicle speed sensor 15. The current command value I3 decreases when the vehicle speed is zero or in the extremely low speed range, and outputs 1 when the vehicle speed exceeds a certain speed. Further, the current command value I4 is a value larger than 1 when the vehicle speed is zero or in the extremely low speed range, and 1 when the vehicle speed exceeds a certain speed. Of these current command values, the current command value I3 is multiplied by the current command value I1 of the steering angular system, and the current command value I4 is multiplied by the current command value I2 of the steering angular velocity system.
[0032]
The reason why the current command value I3 based on the vehicle speed is multiplied as described above is to prevent energy loss when the vehicle is stopped or in the extremely low speed range with the steering wheel turned off. For example, when entering the garage, the engine may be stopped for a while with the steering wheel turned off. Even in such a case, the current command value I1 corresponding to the steering angle is the solenoid current command value SI. As a result, a wasteful flow rate is supplied to the steering valve 9 side. In order to prevent such waste, the current command value I3 is multiplied to reduce the steering angle system current command value I1 when the vehicle speed is 0 or extremely low.
However, if the current command value I3 is reduced as described above, the responsiveness when starting to turn the steering wheel from the state in which the steering wheel is held is deteriorated. Is multiplied by the current command value I2 of the steering angular velocity system to ensure responsiveness.
[0033]
When the current command value I3 based on the vehicle speed is multiplied, the multiplied current command value (I1 × I3) is multiplied by the current command value I5 set based on the vehicle speed.
In addition, the current command value (I2 × I4) of the steering angular velocity system is subjected to predetermined control by a delay control unit or a current command value maintaining unit. The functions of the delay control unit and the current command value maintaining unit will be described in detail later.
After predetermined control is performed by the delay control unit and the current command value maintaining unit, the current command value is multiplied by a current command value I6 set based on the vehicle speed.
[0034]
As the current command values I5 and I6, 1 is output in the low speed range, and a decimal value of 1 or less is output in the maximum speed range. Therefore, the input value is output as it is in the low speed range, but the output value decreases as the speed increases. That is, the responsiveness is kept high in the low speed range, and the responsiveness is lowered in the high speed range. The reason why the responsiveness is changed in accordance with the vehicle speed in this way is generally that high responsiveness is not required during high-speed driving, and high responsiveness is generally required in the low speed range. .
[0035]
The current command values after the multiplication are output with current command values I7 and I8 set based on the vehicle speed as limit values. That is, when the value after multiplication exceeds the current command values I7 and I8 corresponding to the vehicle speed at that time, the excess is cut and the current command value within the limit value is output. I have to. The limit value based on the vehicle speed is set in this way in order to prevent an excessive assist force from being exerted during high speed traveling.
The current command values I7 and I8 are also decreased according to the vehicle speed, but the gain is set smaller than the gain of the current command values I5 and I6.
[0036]
Next, the steering angle system current command value suppressed within the limit value as described above is compared with the steering angular velocity system current command value, and the larger value is adopted. The larger current command value becomes the basic current command value Id.
When the basic current command value Id is obtained in this way, the standby current command value Is is added to the basic current command value Id. However, instead of adding the standby current command value Is as it is, a value obtained by multiplying the standby current command value Is by the current command value I9 set based on the vehicle speed is added.
[0037]
The current command value I9 based on the vehicle speed is 1 in the low speed range, but gradually decreases as the vehicle speed increases in the medium speed range. Then, the minimum value is kept at the high speed range. Therefore, a value obtained by multiplying the current command value I9 based on the vehicle speed by the current command value Is for standby is output as it is in the low speed range and gradually decreases from the medium speed range to the high speed range. In the high speed range, the minimum value is maintained. If the standby current command value is reduced in the high speed range, waste of the standby flow rate in the high speed range can be prevented.
Even in the high speed range, the value obtained by multiplying the current command value I9 and the current command value Is is set so as not to become zero.
[0038]
When the standby current command value (Is × I9) is added to the basic current command value Id as described above, the added value is output to the drive device 16 (see FIG. 11) as the solenoid current command value SI. Then, the driving device 16 outputs an exciting current corresponding to the solenoid current command value SI to the solenoid SOL.
[0039]
As described above, the solenoid current command value SI is controlled. For example, as shown in FIG. 2, the small steering angle on the right side slightly exceeds the neutral position from the state where the steering wheel is steered to the left side. In the case of the conventional example where there is no delay control, the steering angle system current command value Iθ changes as shown by the solid line in FIG. That is, the steering angle system current command value Iθ gradually decreases as the steering angle decreases, and maintains a constant level when the steering angle reaches a predetermined steering angle. On the other hand, the current command value Ib of the steering angular velocity system maintains a constant value while operating the steering and rapidly decreases when the operation of the steering wheel is stopped. Assuming that the solenoid current command value SI is controlled based on the current command value of the steering angular velocity system, the assist force by the power cylinder 8 rapidly decreases when the operation of the steering wheel is stopped. When the assist force decreases rapidly in this way, the steering or holding torque required to steer or hold the steering wheel increases rapidly as shown by the broken line in FIG. If the steering torque increases rapidly in this way, the steering cannot be reliably performed or the driver feels uncomfortable.
[0040]
Therefore, in order to prevent such an inconvenience, the delay control unit and the current command value maintaining unit exhibit their functions. The delay control unit and the current command value maintaining unit will be described below.
The delay control unit includes a current command value characteristic storage unit, a delay control characteristic storage unit, and an execution unit that executes delay control.
The current command value characteristic storage unit has a function of storing a current command value (I2 × I4) of the steering angular velocity system after multiplication. Hereinafter, the current command value (I2 × I4) of the steering angular velocity system after multiplication is referred to as “actual current command value Ib”.
The delay control characteristic storage unit stores a reference decrease rate Δa. This reference decrease rate Δa is a value for specifying the reference current command value Ia indicated by the one-dot chain line in FIG. 3 and is determined by experiments or the like.
On the other hand, the current command value maintaining unit has a function of maintaining a constant current command value to be output, but the function is turned on and off by a signal from the vehicle speed determination unit. The vehicle speed determination unit determines that the vehicle speed is low when the vehicle speed detected by the vehicle speed sensor is equal to or less than a certain value, and turns on the function of the current command value maintaining unit at this time. Further, when the vehicle speed detected by the vehicle speed sensor exceeds a certain value, it is determined that the vehicle speed is high, and at this time, the function of the current command value maintaining unit is turned off.
[0041]
As shown in FIG. 5, the delay control unit and the current command value maintaining unit configured as described above first capture the reference reduction rate Δa in step 0 and store it in the delay control characteristic storage unit.
Next, in step 1, the actual current command value Ib (t1) at time t1 is detected, and in step 2, the current command value Ib (t1) detected as time t1 is stored.
In step 3, an actual current command value Ib (t2) at time t2 after a predetermined time has elapsed is detected. In step 4, the time t2 and the detected current command value Ib (t2) are stored.
In step 5, the current command value Ib (t1) is compared with the current command value Ib (t2). When the current command value Ib (t2) is smaller, that is, when it is determined that the current command value has decreased, the process proceeds to step 6 to calculate the rate of decrease Δb per unit time of the actual current command value Ib. .
[0042]
In step 7, the vehicle speed is detected, and in step 8, the vehicle speed determination unit determines whether the vehicle speed is low or high. If the vehicle speed determination unit determines that the vehicle speed is high, the process proceeds to step 9 to set a reference reduction rate Δa. When the reference reduction rate Δa is set in this way, in step 10, the reference reduction rate Δa is compared with the actual reduction rate Δb. If it is determined that the reference reduction rate Δa is smaller than the actual reduction rate Δb, the process proceeds to step 11 to output a reference current command value Ia based on the reference reduction rate Δa. When the reference current command value Ia is output in this way, a value larger than the actual current command value Ib is output as shown in FIG. Therefore, as shown in FIG. 4, the sudden increase in the steering torque can be suppressed, so that a sense of discomfort given to the driver can be prevented.
[0043]
In step 12, the reference current command value Ia is compared with the actual current command value Ib (t2). If the reference current command value Ia is larger than the current command value Ib (t2), the vehicle speed is detected in step 13. In step 14, it is determined whether the vehicle speed is high or low. Then, when the speed is high, the process returns to the step 10, and when the reduction rate Δa is smaller than the actual reduction rate Δb, the control is continued with the reference current command value Ia based on the reference reduction rate Δa.
On the other hand, if it is determined at step 14 that the speed is low, the routine proceeds to step 17 where the current command value Ia output at that time is maintained as shown in FIG. If the current command value Ia is maintained in this way, as shown in FIG. 4, the steering torque does not increase any more, so that a sense of incongruity caused by an increase in the steering torque can be prevented more reliably.
[0044]
In step 18, it is determined whether or not the reference current command value Ia that is maintained constant is larger than the actual current command value Ib. When the reference current command value Ia is larger than the actual current command value Ib (t2), the process proceeds to step 16, where t2 is replaced with t1, and Ib (t2) is replaced with Ib (t1). And it returns to step 2 again and repeats the said procedure.
On the other hand, when the current command value Ia maintained constant in step 18 becomes equal to or less than the actual current command value Ib (t2), the actual current command value Ib (t2) is controlled (step 2). 15). Then, the process proceeds to step 16 and returns to step 2 in the same manner as described above.
[0045]
When it is determined in step 5 that the current command value Ib (t2) is larger, the process proceeds to step 15 to output the actual current command value Ib (t2). In such a case, the steering state is shown as being steered from the neutral steering angle, and thus the steering force is in an increasing direction. In such a state, if the current command value Ib is delayed, an excessive increase in the steering force is caused. Will be invited. Therefore, as described above, the actual current command value Ib (t2) is output.
Further, when it is determined in step 10 that the reference decrease rate Δa is larger than the actual decrease rate Δb, the process proceeds to step 15 to output the actual current command value Ib (t2). That is, when the current command value is decreasing but not decreasing so rapidly, control is performed with the actual current command value Ib (t2).
[0046]
On the other hand, if it is determined in step 8 that the speed is low, the process proceeds to step 17 where the current command value Ia is maintained at the actual current command value Ib (t2) output at that time. The current command value Ia output at this time corresponds to the actual current command value Ib. Therefore, when the steering wheel is operated at a low speed, the current command value does not decrease at all.
[0047]
As described above, according to the first embodiment, only when the actual current command value Ib is decreasing and it is determined that the decrease rate Δb is larger than the reference decrease rate Δa. The reference current command value Ia based on the reference decrease rate Δa is output. In this way, as shown by the one-dot chain line in FIG. 4, the steering torque required by the driver also decreases gradually, so that the amount of change can be suppressed to be smaller than the steering torque based on the actual current command value Ib. it can. Therefore, it is possible to prevent a sense of incongruity caused by a sudden change in steering torque.
[0048]
In particular, when the vehicle speed is low, since the current command value Ia is maintained at the actual current command value Ib (t2) output at that time, smooth steering during low-speed traveling is possible. On the other hand, when driving at high speed, it can provide a neutral feeling.
[0049]
On the other hand, in the second embodiment shown in FIGS. 6 to 10, the steering angle determination unit controls the on / off switching of the current command value maintaining unit. That is, in the second embodiment, as shown in the control flow of FIG. 10, the procedure from step 1 to step 6 is the same as that of the first embodiment, but in step 7, the steering angle is detected, and the step In 8, the magnitude of the steering angle is determined. Similarly to steps 7 and 8, the steering angle is detected also in step 13, and the magnitude of the steering angle is determined in step 14.
In the second embodiment, the procedure from Step 10 to Step 12 and the procedure of Step 15 and Step 16 are exactly the same as those in the first embodiment.
[0050]
In step 8 and step 14, when it is determined that the steering angle is smaller than a predetermined value, the process proceeds to step 17, and the current command value Ia output at that time is maintained.
On the other hand, if it is determined in step 8 and step 14 that the steering angle is greater than or equal to a predetermined value, the reference current command value Ia is output when the reference decrease rate Δa is smaller than the actual decrease rate Δb, In the opposite case, the actual current command value Ib is output.
According to the second embodiment thus configured, since the increase of the steering torque in the small steering angle region is suppressed, smooth steering can be performed. In addition, in a large rudder angle region, it is possible to give a sharp neutral feeling, so that steering stability is improved.
[0051]
By the way, in the first and second embodiments, the limiters having the current command values I7 and I8 as the limit values are set individually immediately after the current command values I5 and I6 are multiplied as gains. However, the limiters are individually set. Instead of setting, a limiter having a current command value corresponding to the vehicle speed as a limit value may be set uniformly to the value after adding the standby current command value.
Further, instead of individually multiplying the current command values I5 and I6 based on the vehicle speed, the current command value based on the vehicle speed may be uniformly multiplied as the gain after the magnitude determination.
Furthermore, a limiter with the current command value corresponding to the vehicle speed as a limit value may be set uniformly to the value after adding the standby current command value, or the current based on the vehicle speed may be set to the value after the magnitude determination. The command value may be uniformly multiplied as a gain.
[0052]
On the other hand, in the first and second embodiments, the opening of the variable orifice a of the flow control valve V is controlled by the controller C so that the control flow QP is not wasted. This is controlled by adjusting the opening degree of the tank port 11 as shown in FIG. That is, the control flow rate QP is controlled by circulating an unnecessary flow rate of the oil discharged from the pump P to the tank T via the tank port 11. The flow path for guiding the oil discharged from the pump P to the tank port 11 is very short because it is inside the main body B. Accordingly, there is almost no pressure loss in the circulating flow path, and therefore the oil temperature hardly increases. That is, in the first and second embodiments, the flow rate control valve V is configured to circulate a flow rate other than the control flow rate QP to the tank T via the tank port 11, so that an effect of suppressing an increase in the oil temperature is achieved. Can also be obtained.
[0053]
【The invention's effect】
According to the first and second inventions, even when the input current command value of the steering angular velocity system is suddenly reduced, the rapid fluctuation of the output current command value is reduced by applying the delay control. Therefore, the reduction rate of the supply flow rate to the steering valve can be controlled to be reduced. Therefore, it is possible to prevent inconveniences such as unstable steering or an uncomfortable feeling due to a sudden decrease in the required steering torque.
[0054]
In addition, when the vehicle speed becomes low or when the steering angle becomes small, the current command value output at that time is maintained, so that steering at a low speed or in a small steering angle region can be performed smoothly. In addition, it is possible to improve the steering stability when traveling at a high speed or in a large rudder angle region.
[Brief description of the drawings]
FIG. 1 is a control block diagram of a controller C of a first embodiment.
FIG. 2 is an explanatory diagram showing a relationship between a steering angle and time.
FIG. 3 is an explanatory diagram showing a relationship between a current command value and time.
FIG. 4 is an explanatory diagram showing a relationship between required steering torque and time.
FIG. 5 is a control flowchart of the controller C of the first embodiment.
FIG. 6 is a control block diagram of a controller C of the second embodiment.
FIG. 7 is an explanatory diagram showing a relationship between a steering angle and time.
FIG. 8 is an explanatory diagram showing a relationship between a current command value and time.
FIG. 9 is an explanatory diagram showing a relationship between required steering torque and time.
FIG. 10 is a control flowchart of the controller C of the second embodiment.
FIG. 11 is an overall view of a conventional apparatus.
12 is a control block diagram of a conventional controller C. FIG.
FIG. 13 is an explanatory diagram showing a relationship between a conventional steering angle and time.
FIG. 14 is an explanatory diagram showing a relationship between a current command value and time in the related art.
[Explanation of symbols]
V Flow control valve P Pump SOL Solenoid T Tank a Variable orifice 8 Power cylinder 9 Steering valve C Controller 14 Steering angle sensor 15 Vehicle speed sensor SI Solenoid current command value Is Current command value for standby

Claims (2)

A steering valve for controlling the power cylinder, a variable orifice provided on the upstream side of the steering valve, a solenoid for controlling the opening of the variable orifice, a controller for controlling a solenoid current command value SI for driving the solenoid, A steering situation detection sensor that detects a steering situation such as a steering angle and a steering angular velocity and is connected to the controller, and pressure oil supplied from the pump is supplied to the steering valve side and the tank or pump side according to the opening of the variable orifice. In a power steering apparatus in which the controller specifies a solenoid current command value based on current command values corresponding to various signals from the steering situation detection sensor, the controller A command value characteristic storage unit, a delay control characteristic storage unit, The current command value characteristic storage unit stores the actual current command value Ib based on the steering angular velocity signal from the steering situation detection sensor, and the delay control characteristic storage unit serves as a reference. A reference decrease rate Δa for specifying the current command value Ia is stored, and the execution unit calculates a decrease rate Δb per unit time of the current command value Ib, and the magnitude of the calculated decrease rate Δb and the reference decrease rate Δa The current command value Ib is output when Δa ≧ Δb, and the reference current command value Ia based on the reference decrease rate Δa is output when Δa <Δb. The power steering device is characterized in that the reference current command value Ia output by the execution unit is maintained when the vehicle speed is equal to or lower than a predetermined value. A steering valve for controlling the power cylinder, a variable orifice provided on the upstream side of the steering valve, a solenoid for controlling the opening of the variable orifice, a controller for controlling a solenoid current command value SI for driving the solenoid, A steering situation detection sensor that detects a steering situation such as a steering angle and a steering angular velocity and is connected to the controller, and pressure oil supplied from the pump is supplied to the steering valve side and the tank or pump side according to the opening of the variable orifice. In a power steering apparatus in which the controller specifies a solenoid current command value based on current command values corresponding to various signals from the steering situation detection sensor, the controller A command value characteristic storage unit, a delay control characteristic storage unit, The current command value characteristic storage unit stores the actual current command value Ib based on the steering angular velocity signal from the steering situation detection sensor, and the delay control characteristic storage unit serves as a reference. A reference decrease rate Δa for specifying the current command value Ia is stored, and the execution unit calculates a decrease rate Δb per unit time of the current command value Ib, and the magnitude of the calculated decrease rate Δb and the reference decrease rate Δa The current command value Ib is output when Δa ≧ Δb, and the reference current command value Ia based on the reference decrease rate Δa is output when Δa <Δb. The power steering device is characterized in that when the steering angle is equal to or greater than a predetermined value , the reference current command value Ia output by the execution unit is maintained at that time .

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