JP2008247261A - Suspension control device - Google Patents

Abstract

In a suspension control device that performs semi-active damper control, control accuracy is improved with a simple structure.
A controller 8 calculates a target damping force F based on a sprung acceleration of a vehicle body 2 detected by a sprung acceleration sensor 6 and supplies a control current I to an actuator 7 to adjust a damping force adjusting hydraulic shock absorber. The damping force of the vehicle body 2 is controlled by adjusting the damping force 5. The controller 8 calculates the maximum relative speed V between the sprung and unsprung based on the sprung acceleration, and the damping force-piston of the damping force adjusting hydraulic shock absorber 5 from the maximum relative speed V and the target damping force F. The control current I is determined using the speed-current map. Thereby, the processing load of the controller 8 can be reduced and the control accuracy can be increased.
[Selection] Figure 1

Description

  The present invention relates to a suspension control device for a vehicle such as an automobile that controls a vehicle body by adjusting a damping force of a shock absorber according to a traveling state.

2. Description of the Related Art Conventionally, as described in Patent Document 1, for example, a so-called semi-active damper control type suspension control device that controls a vehicle body by adjusting a damping force of a shock absorber according to a traveling state is known. . The suspension control device described in Patent Document 1 includes a damping force adjusting hydraulic shock absorber (shock absorber) interposed between a spring and an unsprung portion of a vehicle, an actuator for switching the damping force, and upper and lower parts of a vehicle body. A sprung acceleration sensor that detects acceleration and a controller that supplies a control signal to the actuator based on detection by the sprung acceleration sensor. The controller calculates the target damping force from the sprung acceleration of the vehicle body detected by the sprung acceleration sensor based on the so-called skyhook theory, and supplies the control current to the actuator to adjust the damping force adjusting hydraulic shock absorber The damping force of is switched to the target damping force. In this way, the vehicle body can be damped by switching the damping force of the damping force adjusting hydraulic shock absorber according to the running state, and the ride comfort and the handling stability can be improved.
JP 2002-293121 A

  When executing vibration suppression control based on the Skyhook theory described above, unsprung acceleration in addition to sprung acceleration (velocity) is used to determine the vibration state and vibration suppression state of the damping force adjusting hydraulic shock absorber to the vehicle body. (Speed) needs to be monitored. In general, the damping force of the damping force adjustable hydraulic shock absorber depends on the piston speed (relative speed between the sprung and unsprung), so that the actual damping force can be accurately adjusted to the target damping force. It is necessary to monitor the piston speed.

  Piston speed (relative speed between sprung and unsprung) of unsprung acceleration and damping force adjustable hydraulic shock absorber is provided by providing an acceleration sensor under the spring or a stroke sensor between the sprung and unsprung. Can be detected directly. However, the unsprung parts of automobile suspension devices are subject to severe conditions such as severe vibrations caused by running, wind and rain, snow, ice, mud, dust, stepping stones, etc., so that they are easily damaged and ensure reliability. Have difficulty. Further, if an acceleration sensor is provided under the four-wheel spring or a stroke sensor is provided, the processing load of the controller increases due to an increase in the number of sensors and costs increase.

  On the other hand, the unsprung acceleration (velocity) can be calculated and estimated from information such as the sprung acceleration using a known method, for example, an equation of motion of a vibration system. Therefore, in the device described in Patent Document 1, the target damping force is calculated based on the sprung acceleration detected by the sprung acceleration sensor provided on the vehicle body, and a predetermined constant is set for the damping force adjusting hydraulic shock absorber. The control current to the actuator is determined using a damping force-current map representing the relationship between the target damping force and the control current at the piston speed of the piston, and the piston speed estimated based on the sprung acceleration etc. is monitored to determine the piston. By correcting the control current value according to the speed, vibration suppression control of the vehicle body is performed without providing an unsprung acceleration sensor and an unsprung / unsprung stroke sensor. This simplifies the control system, reduces the processing load on the controller, increases reliability, and reduces costs.

  However, when the control current is determined by the damping force-current map at a constant piston speed as described above, the actual damping force depends on the piston speed (relative speed between the sprung and unsprung) in the hydraulic shock absorber. Therefore, accurate damping force control cannot be performed. Also, when calculating and estimating the relative speed between the sprung and unsprung in real time based on the sprung acceleration, it is necessary to adjust and process many parameters that change from moment to moment, which increases the processing load on the controller. At the same time, the error also increases, which may reduce the calculation accuracy.

  The present invention has been made in view of the above points, and an object of the present invention is to provide a suspension control device that can improve control accuracy with a simple structure.

In order to solve the above-described problem, the invention according to claim 1 includes a shock absorber that is interposed between a spring and an unsprung portion of a vehicle and capable of adjusting a damping force, and a spring that detects the sprung acceleration of the vehicle. In a suspension control device comprising acceleration detection means, and a controller that supplies a control signal to the shock absorber based on the sprung acceleration to adjust damping force and execute vibration suppression control of the vehicle body,
The controller includes a maximum relative speed calculating means for calculating a maximum relative speed between the sprung and unsprung based on the sprung acceleration, a damping force relating to the shock absorber, a relative speed between the sprung and unsprung, and a control signal. Control means for supplying the shock absorber to the shock absorber using the map means from the target damping force of the shock absorber calculated based on the sprung acceleration and the maximum relative speed. It is characterized by determining a signal.
A suspension control apparatus according to a second aspect of the present invention is the suspension control device according to the first aspect, wherein the maximum relative speed calculation means is obtained by integrating the sprung absolute speed obtained from the sprung acceleration and the sprung absolute speed. A maximum sprung absolute speed calculating means for calculating the maximum value of the sprung absolute speed from the sprung displacement calculated, and a relative for calculating the maximum relative speed between the sprung and unsprung based on the calculated maximum sprung absolute speed And a speed maximum value calculating means.
The suspension control apparatus according to a third aspect of the present invention is the suspension control device according to the second aspect, wherein the sprung maximum absolute speed calculation means includes the square value of the sprung absolute speed and the sprung displacement to the sprung absolute speed. The sprung maximum absolute velocity is obtained by calculating the positive square root of the sum of the square frequency multiplied by the angular frequency of.
The suspension control device according to a fourth aspect of the present invention is the suspension control device according to the second aspect, wherein the sprung maximum absolute speed calculation means includes the absolute value of the sprung absolute speed and the sprung absolute speed in the sprung displacement. The maximum absolute velocity on the spring is obtained by dividing the sum of the absolute value and the absolute value by multiplying by {square root over (2)}.

According to the suspension control apparatus of the first aspect of the invention, the maximum relative speed calculation unit of the controller calculates the maximum value of the relative speed between the sprung and unsprung portions, so the amount of calculation is small and the processing load is small. In addition, the number of necessary parameters can be reduced and the parameters can be easily adjusted. As a result, the calculation accuracy of the maximum relative speed can be increased. In addition, since the control signal is determined using a map means that represents the correlation between the damping force related to the shock absorber, the relative speed between the sprung and unsprung and the control signal, the sprung and unsprung with respect to the target damping force. An appropriate control signal can be determined according to the relative speed between them, and the accuracy of damping force control can be improved.
According to the suspension control device of the second aspect of the invention, the maximum value of the sprung absolute speed can be calculated from the sprung acceleration by the sprung maximum absolute speed calculating means, and the relative value is calculated from the maximum value of the sprung absolute speed. The maximum relative speed between the sprung and unsprung parts can be calculated by the speed maximum value calculating means.
According to the suspension control apparatus of the third aspect of the invention, the sprung maximum absolute speed is calculated from the angular frequency of the sprung absolute speed, sprung displacement, and sprung absolute speed by the sprung maximum absolute speed calculating means. Can do.
According to the suspension control device of the fourth aspect of the invention, the load on the controller can be reduced by approximately calculating the sprung maximum absolute speed.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.
FIG. 1 shows a schematic configuration of an automobile suspension control apparatus according to the present embodiment. As shown in FIG. 1, the suspension control device 1 includes a suspension spring 4 and a damping force adjusting hydraulic shock absorber 5 (shock absorber, hereinafter referred to as a hydraulic shock absorber) between a vehicle body 2 and each wheel 3 (only one wheel is shown). And the vehicle body 2 is provided with a sprung acceleration sensor 6 for detecting the acceleration in the vertical direction (sprung acceleration), and at least the detection of the sprung acceleration sensor 6 is performed. A controller 8 is provided for inputting a parameter representing the running state of the vehicle including a signal and supplying a control signal to the actuator 7 of the hydraulic shock absorber 5.

  The hydraulic shock absorber 5 is configured such that a piston, to which a piston rod is connected, is slidably fitted in a cylinder in which oil is sealed, and oil generated by sliding of the piston in the cylinder against expansion and contraction of the piston rod. The flow of the liquid is controlled by a damping force generation mechanism including an orifice and a disk valve to generate a damping force. Further, a damping force adjusting mechanism for adjusting the damping force and an actuator 7 for operating the damping force adjusting mechanism are provided. A damping force corresponding to the piston speed can be generated, and the damping force can be adjusted according to the control current to the actuator 7. FIG. 4 shows a damping force-piston speed-current map M (map means) representing the mutual relationship among the damping force of the hydraulic shock absorber 5, the piston speed, and the control current to the actuator 7.

  The hydraulic shock absorber 5 may be another type of shock absorber as long as it has the characteristics shown in FIG. Further, the hydraulic shock absorber 5 can be set to have a damping force characteristic that is opposite between the expansion side and the contraction side of the piston rod, that is, a combination in which the expansion side is hard and the contraction side is soft, and the extension side is soft and the contraction side is hard. It may be used. In this case, when the damping force is calculated by the controller 8 based on the Skyhook theory as will be described later, the vertical speed of the unsprung portion is monitored, and the sprung portion and the unsprung portion are either in the vibrating state or in the damping state. It is not necessary to determine whether there is any, and the processing load on the controller 8 can be reduced.

  As shown in FIG. 2, the controller 8 is a microprocessor-based control circuit, and includes an integration circuit 9, a damping force calculation unit 10, a maximum relative speed calculation unit 11 (maximum relative speed calculation unit), and a control current calculation unit 12. I have. The integration circuit 9 calculates the sprung absolute speed A by integrating the vertical acceleration of the vehicle body 2 (sprung) detected by the sprung acceleration sensor 6 (here, the sprung absolute speed is one point in space). The vertical speed on the spring with reference to. The damping force calculation unit 10 calculates the target damping force F from the sprung absolute velocity A calculated by the integration circuit 9, and calculates the target damping force F based on the above-described skyhook theory, for example.

  As shown in FIG. 3, the maximum relative speed calculating unit 11 further integrates the sprung absolute speed A calculated by the integrating circuit 9 of the controller 8 to calculate the sprung displacement, and calculates by the integrating circuit 13. Is multiplied by the angular frequency ω to calculate a sprung absolute velocity B (the same amplitude and a phase of 90 ° (π / 2) differing from the original sprung absolute velocity A). And a sprung maximum absolute speed calculating unit 15 (a sprung maximum absolute speed calculating means) that calculates a sprung maximum absolute speed (maximum value of the absolute speed in one cycle) from the sprung absolute speed A and the sprung absolute speed B. Based on the maximum sprung absolute speed calculated by the sprung maximum absolute speed calculator 15, the maximum relative speed V for calculating the maximum relative speed V between the sprung and unsprung (maximum value of the relative speed in one cycle) is calculated. Value calculation unit 16 (relative speed And a maximum value calculating means). The angular frequency ω is ω = 2πf. Here, the frequency f of the sprung absolute speed may be actually counted, but the vehicle body 2 (sprung mass m) and the suspension spring 4 (spring) It can also be obtained as the natural frequency of a one-degree-of-freedom vibration system consisting of a constant k).

The sprung maximum absolute speed calculation unit 15 calculates √ (A ² + B ² ) from the sprung absolute speed A and the sprung absolute speed B to obtain the sprung maximum absolute speed. At this time, the maximum sprung absolute velocity can be approximately calculated by calculating (| A | + | B |) / √2. Thereby, the processing load of the controller 8 can be reduced.

The relative speed maximum value calculation unit 16 calculates the maximum relative speed V between the sprung and unsprung from the sprung maximum absolute speed calculated by the sprung maximum absolute speed calculating unit 15 as follows. For simplicity, ignoring the damping force of the hydraulic shock absorber 5 and assuming a one-degree-of-freedom vibration system composed of the vehicle body 2 (sprung mass m) and the suspension spring 4 (spring constant k), the sprung acceleration x ″ When the relative displacement (x ₀ −x) between the sprung and unsprung parts is established, the following relationship (1) (equation of motion) is established.
mx ″ = k (x ₀ −x) (1)
Assuming that the vibration is a sine wave vibration, x ″ = ωx ′ and x ′ = ωx. Therefore, the following equation (2) can be derived from the equation (1).
| X ₀ ′ −x ′ | = | x ′ | mω ² / k (2)

Then, from the equation (2), the maximum relative speed V (relative speed between the sprung and unsprung (x ₀ ′)) from the maximum sprung absolute speed (maximum value of x ′) calculated by the sprung maximum absolute speed calculating unit 15. -The maximum value of x ') is obtained. Here, as described above, the angular frequency ω is ω = 2πf, and the frequency f of the sprung absolute speed may be actually counted, but the vehicle body 2 (sprung mass m) and the suspension spring 4 (spring) It can also be obtained as the natural frequency of a one-degree-of-freedom vibration system consisting of a constant k).

Further, the maximum relative velocity V between the sprung and unsprung portions can be calculated as follows. For simplicity, ignoring the spring force of the suspension spring 4 and assuming a one-degree-of-freedom vibration system including the vehicle body 2 (sprung mass m) and the hydraulic shock absorber 5 (damping coefficient c), the following equation (3) (Equation of motion) relationship is established.
mx ″ = c (x ₀ −x) (3)
If the vibration is a sine wave vibration, x ″ = ωx ′ and x ′ = ωx, and therefore the following equation (4) can be derived from the equation (3).
| X ₀ ′ −x ′ | = | x ′ | mω / c (4)
Or | x ₀ ′ −x ′ | = | x ′ | mω / 2ζ√mk (4) ′
However, the damping ratio ζ = c / 2√mk.

From the equation (4) (or (4) ′), the maximum relative velocity V (between the sprung and unsprung) is calculated from the maximum sprung absolute velocity (the maximum value of x ′) calculated by the sprung maximum velocity calculating unit 15. Relative velocity (the maximum value of x ₀ '-x') is determined.

  At this time, the maximum relative speed V is obtained by the above equation (2) in the vicinity of the natural frequency (for example, about 1 Hz) on the spring where the influence of the spring force of the suspension spring 4 is large, and the damping force of the hydraulic shock absorber 5 In the vicinity of the unsprung natural frequency (for example, about 10 Hz) that is greatly affected by the above, it may be obtained by the equation (4) (or (4) ′).

  The control current calculation unit 12 stores in advance a damping force-piston speed-current map M representing the mutual relationship between the damping force of the hydraulic shock absorber 5 shown in FIG. 4, the piston speed, and the control current to the actuator 7. Using this damping force-piston speed-current map M, the target damping force F calculated by the damping force calculation unit 10 and the maximum relative speed V between the sprung and unsprung calculated by the maximum relative speed estimation unit 11 (hydraulic buffering) The control current I (control signal) to be supplied to the actuator 7 in order to generate the target damping force F by the hydraulic shock absorber 4 is determined from the piston speed of the compressor 5.

  As described above, the controller 8 calculates the control current I to be supplied to the actuator 7 of the hydraulic shock absorber 5 from the vertical acceleration (sprung acceleration) of the vehicle body 2 detected by the sprung acceleration sensor 6, and controls the control current I. A current I is supplied to the actuator 7 to control the damping force of the hydraulic shock absorber 5.

Next, the flow of damping force control of the hydraulic shock absorber 5 by the controller 8 will be described with reference to FIG.
Referring to FIG. 5, when a current is supplied to controller 8, the control system is initialized in step S <b> 1 and the process proceeds to step 2. In step 2, the elapse of the control cycle is determined, and when the control cycle elapses, the process proceeds to step S3. In step 3, the control amount (control current I) calculated in the previous control cycle is supplied to the actuator 7 to switch the damping force of the hydraulic shock absorber 5, and the process proceeds to step S4. In step S4, necessary signals are output from other output ports (not shown), and the process proceeds to step S5. In step S5, detection signals from various sensors including the sprung acceleration sensor 6 are input, and the process proceeds to step S6. In step S6, the control current I is calculated from the sprung acceleration by the above-described calculation process, and the routine is terminated.

  In this way, the damping force of the hydraulic shock absorber 5 is reduced to the target damping based on the sprung acceleration detected by the sprung acceleration sensor 6 without providing the unsprung acceleration sensor and the sprung / unsprung stroke sensor. The vibration control of the vehicle body is executed by switching to the force F. This eliminates the need for an unsprung acceleration sensor that is easily damaged, reduces the number of sensors, increases reliability, reduces the processing load on the controller 8, and reduces the manufacturing cost.

  At this time, the maximum relative speed calculation unit 11 of the controller 8 calculates only the maximum value V of the relative speed between the sprung and unsprung, and does not calculate all the relative speeds in real time. As a result, the processing load on the controller 8 can be reduced. In addition, the number of necessary parameters is small, and the adjustment of the parameters is easy. As a result, the calculation and estimation accuracy of the maximum relative speed V can be improved.

  Since the control current I is determined using the damping force-piston speed-current map M representing the mutual relationship between the damping force, the piston speed and the control current to the actuator 7 for the hydraulic shock absorber 5, The appropriate control current I can be determined according to the relative speed (piston speed) between the sprung and unsprung parts, and the accuracy of damping force control can be improved.

1 is a circuit diagram showing a schematic configuration of a suspension control device according to an embodiment of the present invention. It is a block diagram which shows schematic structure of the controller of the suspension control apparatus shown in FIG. It is a block diagram which shows schematic structure of the maximum relative speed estimation part of the controller shown in FIG. It is a graph of the damping force-piston speed-current map of the damping force adjustment type hydraulic shock absorber of the suspension control device shown in FIG. 3 is a flowchart showing a main routine of control by the controller shown in FIG.

Explanation of symbols

  1 suspension control device, 2 vehicle body (on spring), 3 wheels (under spring), 5 damping force adjustable hydraulic shock absorber (shock absorber), 6 on-spring acceleration sensor, 8 controller, 11 maximum relative speed calculator (maximum relative) Speed calculation means), M damping force-piston speed-current map (map means)

Claims (4)

A shock absorber that is interposed between a sprung portion and a sprung portion of the vehicle and can adjust a damping force, a sprung acceleration detecting means that detects a sprung acceleration of the vehicle, and the shock absorber is controlled based on the sprung acceleration. In a suspension control device including a controller that supplies a signal and adjusts damping force to execute damping control of the vehicle body,
The controller includes a maximum relative speed calculating means for calculating a maximum relative speed between the sprung and unsprung based on the sprung acceleration, a damping force relating to the shock absorber, a relative speed between the sprung and unsprung, and a control signal. Control means for supplying the shock absorber to the shock absorber using the map means from the target damping force of the shock absorber calculated based on the sprung acceleration and the maximum relative speed. A suspension controller characterized by determining a signal. The maximum relative velocity calculation means calculates the maximum value of the absolute value on the spring from the absolute value on the spring and the displacement on the spring obtained by integrating the absolute velocity on the spring. 2. The speed calculating means and a relative speed maximum value calculating means for calculating a maximum relative speed between the sprung and unsprung based on the calculated maximum sprung absolute speed. Suspension control device. The sprung maximum absolute speed calculation means calculates a positive square root of the sum of the square value of the sprung absolute speed and the square value of the sprung displacement multiplied by the angular frequency of the sprung absolute speed. The suspension control device according to claim 2, wherein the maximum sprung absolute velocity is obtained. The sprung maximum absolute speed calculation means divides the sum of the absolute value of the sprung absolute speed and the absolute value of the sprung displacement multiplied by the angular frequency of the sprung absolute speed by √2. The suspension control device according to claim 2, wherein the maximum sprung absolute velocity is obtained.

Images