METHOD TO CONTROL AN ACTIVE SHOCK ABSORBER OF A ROAD VEHICLE

Abstract

A method to control an active shock absorber of a road vehicle. The active shock absorber is part of a suspension connecting a frame of the road vehicle to a hub of a wheel and has: a first element, which defines an end of the active shock absorber, a second element, which defines another end of the active shock absorber and is mounted so as to slide relative to the first element; and an actuator, which is configured to generate a force, which is applied between the two elements. The control method comprises the steps of: determining a vertical acceleration of the hub; determining a speed of translation between the two elements of the active shock absorber; determining a target force for the actuator of the active shock absorber based on the vertical acceleration of the hub and based on the speed of translation between the two elements of the active shock absorber; and controlling the actuator (10) of the active shock absorber so as to pursue the target force.

Claims

1) A method to control a road vehicle (1) comprising; a frame (4); at least one wheel (2) provided with a hub (3); and a suspension (5), which connects the frame (4) to the hub (3) of the wheel (2) and is provided with an active shock absorber (6) comprising: a first element (7), which defines an end of the active shock absorber (6), a second element (8), which defines another end of the active shock absorber (6) and is mounted so as to slide relative to the first element (7); and an actuator (10), which is configured to generate a force (F), which is applied between the two elements (7, 8); the control method comprises the steps of: determining a vertical acceleration (a.sub.z) of the hub (3); determining a speed (v) of translation between the two elements (7, 8) of the active shock absorber (6); determining a target force (F.sub.TGT) for the actuator (10) of the active shock absorber (6) based on the vertical acceleration (a.sub.z) of the hub (3) and on the speed (v) of translation between the two elements (7, 8) of the active shock absorber (6); controlling the actuator (10) of the active shock absorber (6) so as to pursue the target force (F.sub.TGT); determining a first contribution (C.sub.1) exclusively based on the sole vertical acceleration (a.sub.z) of the hub (3) and using a first open-loop transfer function (TF.sub.1), which provides the first contribution (C.sub.1) exclusively as a function of the sole vertical acceleration (a.sub.z); determining a second contribution (C.sub.2) exclusively based on the sole speed (v) of translation between the two elements (7, 8) of the active shock absorber (6) and using a second open-loop transfer function (TF.sub.2), which provides the second contribution (C.sub.2) exclusively as a function of the sole translation speed (v); and calculating the target force (F.sub.TGT) by adding the two contributions (C.sub.1, C.sub.2).

2) The control method according to claim 1, wherein the target force (F.sub.TGT) is calculated by only and exclusively adding the two contributions (C.sub.1, C.sub.2).

3) The control method according to claim 1, wherein the second transfer function (TF.sub.2) consists of a map of experimentally determined points.

4) The control method according to claim 1 and comprising the further steps of: establishing a second optimal and desired transfer function (F.sub.2-OPT); experimentally determining a second measured transfer function (TF.sub.2-MSR) by using mechanical stresses of the suspension (5) and by always keeping the second contribution (C.sub.2) at zero, namely always having the target force (F.sub.TGT) coincide with the sole first contribution (C.sub.1); and determining the second transfer function (TF.sub.2-OPT) as difference between the second optimal and desired transfer function (TF.sub.2-OPT) and the second measured transfer function (TF.sub.2-MSR).

5) The control method according to claim 1, wherein the second transfer function (TF.sub.2-OPT) is variable as the frequency varies.

6) The control method according to claim 1, wherein the second transfer function (TF.sub.2-OPT) has a gain having [Ns/m] as unit of measurement and a phase expressed in degrees.

7) The control method according to claim 1, wherein the second open-loop transfer function (TF.sub.2-OPT) entails the second contribution (C.sub.2) being proportional to the speed (v) of translation between the two elements (7, 8) of the active shock absorber (6).

8) The control method according to claim 1, wherein the second open-loop transfer function (TF.sub.2-OPT) entails the second contribution (C.sub.2) increasing as the speed (v) of translation between the two elements (7, 8) of the active shock absorber (6) increases.

9) The control method according to claim 1, wherein the first transfer function (TF.sub.1) is variable as the frequency varies.

10) The control method according to claim 1 and comprising the further step of estimating the speed (v) of translation between the two elements (7, 8) of the active shock absorber (6) based on a moving speed of the actuator (10) of the active shock absorber (6).

11) The control method according to claim 10 and comprising the further step of estimating the speed (v) of translation between the two elements (7, 8) of the active shock absorber (6) also based on a relative position (p) between the two elements (7, 8) of the active shock absorber (6).

12) The control method according to claim 10 and comprising the further step of estimating the speed (v) of translation between the two elements (7, 8) of the active shock absorber (6) also based on the vertical acceleration (a.sub.z) of the hub (3).

13) The control method according to claim 1 and comprising the further step of estimating the speed (v) of translation between the two elements (7, 8) of the active shock absorber (6) only and exclusively based on a moving speed of the actuator (10) of the active shock absorber (6), on a relative position (p) between the two elements (7, 8) of the active shock absorber (6) and on the vertical acceleration (a.sub.z) of the hub (3).

14) The control method according to claim 1, wherein the active shock absorber (6) comprises a spring (9), which is connected between the two elements (7, 8) and is compressed or expanded when the two elements (7, 8) linearly translate relative to one another.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0009] The invention will now be described with reference to the accompanying drawings showing a non-limiting embodiment thereof, wherein:

[0010] FIG. 1 is a schematic plan view of a road vehicle provided with four active shock absorbers, which are controlled according to the invention;

[0011] FIG. 2 is a schematic view of a suspension of the road vehicle of FIG. 1;

[0012] FIG. 3 is a control diagram implemented in a control unit of the road vehicle of FIG. 1; and

[0013] FIG. 4 is a diagram showing an optimal and desired transfer function and a corresponding measured transfer function.

PREFERRED EMBODIMENTS OF THE INVENTION

[0014] In FIG. 1, reference number 1 indicates, as a whole, a road vehicle provided with two front wheels 2 and with two rear wheels 2.

[0015] The road vehicle 1 is provided with a powertrain system (which is known and is not shown herein), which can comprise an internal combustion engine and/or one or more electric motors and can transmit a motion to the front wheels 2 and/or to the rear wheels 2.

[0016] A hub 3 (schematically shown in FIG. 2) of each wheel 2 is connected to a frame 4 of the road vehicle 1 by means of a suspension 5 (partially shown in FIG. 1), which is provided with an (electronically controlled) active shock absorber 6, which is capable of making autonomous movements (namely, completely independent of the stresses transmitted by the road surface), which are added to the movements caused by the stresses transmitted by the road surface.

[0017] According to FIG. 2, each active shock absorber 6 comprises an element 7, which defines an end of the active shock absorber 6, and an element 8, which defines the other end of the active shock absorber 6 and is mounted so as to slide relative to the element 7 in order to be able to linearly translate relative to the element 7. Each active shock absorber 6 comprises a spring 9, which is connected between the two elements 7 and 8 and is compressed or expanded when the two elements 7 and 8 linearly translate relative to one another. Finally, each active shock absorber 6 comprises an electric actuator 10 (typically, a rotary electric motor), which is configured to have the active shock absorber 6 make autonomous movements (namely, completely independent of the stresses transmitted by the road surface) between the elements 7 and 8, namely is capable of generating a force F, which is applied between the elements 7 and 8. By way of example, the active shock absorbers 6 could be of the type described in patent applications US2008190104A1 and WO2014145215A2.

[0018] Each active shock absorber 6 comprises a position sensor 11 (for example, a potentiometer), which provides the relative position p of the two elements 7 and 8, namely the exact measure of how much the element 8 is translated relative to the element 7. Furthermore, each active shock absorber 6 comprises a position sensor 11 (for example, a rotary encoder), which provides the angular position α of the electric actuator 10. The road vehicle 1 comprises four vertical accelerometers 13, which are mounted on the hubs 3 of the wheels 2, namely are rigidly fixed to the hubs 3 of the wheels 2 in order to move with the hubs 3 of the wheels 2 in an integral manner. Each vertical accelerometer 13 is configured to measure a vertical acceleration a.sub.z of the corresponding hub 3.

[0019] According to FIG. 1, the road vehicle 1 comprises a longitudinal accelerometer 14 and a transverse accelerometer 15, which are mounted on the frame 4, namely are rigidly fixed to the frame 4 in order to move with the frame in an integral manner 4, and are configured to measure a longitudinal acceleration a.sub.x and a transverse acceleration a.sub.y of the frame 4 (namely, of the road vehicle 1), respectively. According to a possible embodiment, the two accelerometers 14 and 15 could be integrated in one single sensor (for example, a triple-axis accelerometer), which provides both the longitudinal acceleration a.sub.x and the transverse acceleration a.sub.y.

[0020] The road vehicle 1 comprises an electronic control unit (“ECU”) 16, which, among other things, controls the actuators 10 of the active shock absorbers 6 in the ways described below; from a physical point of view, the control unit 16 can consist of one single device or of several devices, which are separate from one another and communicate through the CAN network of the road vehicle 1. The control unit 16 is connected (directly or indirectly through a BUS network of the road vehicle 1) to the position sensors 11 and 12 and to the accelerometers 13, 14 and 15.

[0021] According to FIG. 3, the control unit 16 implements an estimating block 17, which determines (estimates) a speed v of translation between the two elements 7 and 8 of the active shock absorber 6. According to a preferred embodiment, the estimating block 17 estimates the speed v of translation between the two elements 7 and 8 of the active shock absorber 6 based on a moving speed of the actuator 10 of the active shock absorber 6 (determined by deriving, in the time, the position p of the actuator 10 measured by the position sensor 12), based on the relative position p between the two elements 7 and 8 of the active shock absorber 6 (directly measured by the position sensor 11) and based on the vertical acceleration a.sub.z in the area of the hub 3 (directly measured by the vertical accelerometer 13).

[0022] According to FIG. 3, the control unit 16 implements a control block 18, which, by using an open-loop transfer function TF.sub.1, determines a contribution C.sub.1 exclusively based on the sole vertical acceleration a.sub.z in the area of the hub 3 (directly measured by the vertical accelerometer 13); in other words, the contribution C.sub.1 exclusively depends on the sole vertical acceleration a.sub.z in the area of the hub 3. Furthermore, the control unit 16 implements a control block 19, which, by using an open-loop transfer function TF.sub.2, determines a contribution C.sub.2 exclusively based on the sole speed v of translation between the two elements 7 and 8 of the active shock absorber 6 (provided by the estimating block 17); in other words, the contribution C.sub.2 exclusively depends on the sole speed v of translation between the two elements 7 and 8 of the active shock absorber 6. Finally, the control unit 16 implements an adder block 20, which calculates the target force F.sub.TGT of the actuator 10 by only and exclusively adding the two contributions C.sub.1 and C.sub.2 (it should be pointed out that the two contributions C.sub.1 and C.sub.2 also have a sign and, therefore, their sum is calculated taking into account the sign); namely, the value of the target force F.sub.TGT of the actuator 10 is exclusively determined by the sum of the sole contributions C.sub.1 and C.sub.2.

[0023] Basically, the open-loop transfer function TF.sub.2 entails the force F generated by the actuator 10 (namely, the contribution C.sub.2 of the target force F.sub.TGT of the actuator 10) being substantially proportional to the speed v of translation between the two elements 7 and 8 of the active shock absorber 6; namely, it increases as the speed v of translation between the two elements 7 and 8 of the active shock absorber 6 increases. Indeed, the gain of the transfer function TF.sub.2 is measured in [Ns/m] as, by being multiplied by the speed v of translation (measured in [m/s]), it directly provides the contribution C.sub.2 of the target force F.sub.TGT of the actuator 10 (measured in [N]).

[0024] In other words, the contribution C.sub.1 is determined based on the sole vertical acceleration a.sub.z of the hub 3 and using the open-loop transfer function TF.sub.1, which provides the contribution C.sub.1 based on the vertical acceleration a.sub.z; similarly, the contribution C.sub.2 is determined based on the sole speed v of translation between the two elements 7 and 8 of the active shock absorber 6 and using the open-loop transfer function TF.sub.2, which provides the contribution C.sub.2 based on the speed v of translation. Hence, the control unit 16 determines the target force F.sub.TGT based on the vertical acceleration a.sub.z of the hub 3 and based on the speed v of translation between the two elements 7 and 8 of the active shock absorber 6 by exclusively using open-loop transfer functions TF.sub.1 and TF.sub.2.

[0025] Basically, the contribution C.sub.1 determined based on the vertical acceleration a.sub.z constitutes an inertia compensation, whereas the contribution C.sub.2 determined based on the speed v of translation between the two elements 7 and 8 of the active shock absorber 6 constitutes a damping compensation.

[0026] According to a preferred embodiment, the transfer functions TF.sub.1 and TF.sub.2 are variable as the frequency varies (generally, ranging from 0 to 50 Hz) and have a gain and a phase.

[0027] To sum up, the control unit 16 determines the target force F.sub.TGT for the actuator 10 of the active shock absorber 6 based on the vertical acceleration a.sub.z of the hub 3 (directly measured by the vertical accelerometer 13) and based on the speed v of translation between the two elements 7 and 8 of the active shock absorber 6 (provided by the estimating block 17). The control unit 16 controls the actuator 10 of the active shock absorber 6 so as to pursue the target force F.sub.TGT; according to a preferred embodiment, the target force F.sub.TGT determined by the control unit 16 only and exclusively based on the vertical acceleration a.sub.z of the hub 3 and on the speed v of translation between the two elements 7 and 8 of the active shock absorber 6 could be added to other target forces determined in other ways and so as to pursue other targets (as described, for instance, in Italian patent applications 102021000015170 and 102021000015182).

[0028] According to a preferred embodiment, the transfer function TF.sub.2 consists of a map of experimentally determined points. In particular and according to FIG. 4, at first an optimal and desired transfer function TF.sub.2-OPT is established on paper in order to have an optimal and desired damping; subsequently, a measured transfer function TF.sub.2-MSR is experimentally determined by using mechanical stresses of the suspension 5 and by always keeping the second contribution C.sub.2 at zero, namely by always having the target force F.sub.TGT coincide with the sole first contribution C.sub.1. Finally, the transfer function TF.sub.2-OPT is determined as difference between the optimal and desired transfer function TF.sub.2-OPT and the measured transfer function TF.sub.2-MSR.

[0029] The embodiments described herein can be combined with one another, without for this reason going beyond the scope of protection of the invention.

[0030] The control method described above has different advantages.

[0031] First of all, the control method disclosed above optimizes the damping response of the active shock absorber 6 (both in terms of effectiveness of the response and in terms of promptness of the response), though maintaining a hood level of comfort.

[0032] Furthermore, the control method disclosed above is particularly stable and safe as, by operating in open loop, it never risks triggering undesired oscillations.

[0033] Finally, the control method described above is simple and economic to be implemented, for it does not require either a significant calculation ability or a large memory space.

LIST OF THE REFERENCE NUMBERS OF THE FIGURES

[0034] 1 vehicle [0035] 2 wheels [0036] 3 hub [0037] 4 frame [0038] 5 suspension [0039] 6 active shock absorber [0040] 7 element [0041] 8 element [0042] 9 spring [0043] 10 electric actuator [0044] 11 position sensor [0045] 12 position sensor [0046] 13 vertical accelerometer [0047] 14 longitudinal accelerometer [0048] 15 transverse accelerometer [0049] 16 control unit [0050] 17 estimating block [0051] 18 control block [0052] 19 control block [0053] 20 adder block [0054] a.sub.z vertical acceleration [0055] α angular position [0056] p angular position [0057] F force [0058] F.sub.TGT desired force [0059] F.sub.1 transfer function [0060] F.sub.2 transfer function [0061] TF.sub.2-OPT optimal transfer function [0062] TF.sub.2-MSR measured transfer function [0063] C.sub.1 contribution [0064] C.sub.2 contribution