KR102474523B1 - Vibration control device of vehicle differential gear - Google Patents

Abstract

The present invention relates to a vibration control device of a differential gear for a vehicle, and more particularly, to a vibration control device for a vehicle differential gear for controlling the behavior of a differential gear to prevent vibration in the front and rear directions of a vehicle that may occur when the vehicle starts. .

Description

Vibration control device of vehicle differential gear}

The present invention relates to a vibration control device of a differential gear for a vehicle, and more particularly, to a vibration control device for a vehicle differential gear for controlling the behavior of a differential gear to prevent vibration in the front and rear directions of a vehicle that may occur when the vehicle starts. .

When the accelerator pedal is tipped in, the throttle valve of the engine intake line suddenly opens due to the driver stepping on the accelerator pedal, and the driving torque of the engine rapidly increases. The rapid change in the driving torque generated at this time causes roll vibration of the differential gear, which generates vibration in the forward and backward directions of the vehicle.

Vibration in the front and rear directions of the vehicle deteriorates ride comfort and drivability, thereby adversely affecting the marketability and quality of the vehicle.

In addition, the sudden change in engine driving torque as described above occurs mainly when the vehicle starts.

Registered Patent No. 10-1807055

The present invention has been devised in view of the above points, and the control force for controlling the roll behavior (rotational vibration) of the differential gear according to the rapid fluctuation of the engine driving torque is obtained by using the electronic differential gear mount and having the differential gear. It is an object of the present invention to provide a vibration control device for a differential gear for a vehicle that can control the forward and backward movement of a vehicle by generating an excitation force (reaction force of engine driving torque) in reverse phase.

Accordingly, in the present invention, the longitudinal acceleration sensor for detecting the longitudinal acceleration of the vehicle; An electronic differential gear mount for mounting the rear part of the differential gear to the cross member; and a controller generating a control signal by inverting the signal of the longitudinal acceleration sensor in antiphase when engine driving torque increases due to vehicle start, and driving the differential gear mount by the control signal. A vibration control device for a differential gear is provided.

According to the present invention, when the electronic differential gear mount is driven by the control signal, it may generate a control force for controlling vertical displacement of the rear portion of the differential gear with a constant amplitude. That is, when the electronic differential gear mount is driven by the control signal, the vertical displacement of the rear part of the differential gear according to the reaction force of the engine driving torque is controlled at a constant amplitude.

Specifically, the controller drives the electronic differential gear mount by the control signal when the amplitude of the signal output from the longitudinal acceleration sensor is greater than the set second reference amplitude when the vehicle starts.

Preferably, the controller determines that when the vehicle starts, the amplitude of a first signal output from the longitudinal acceleration sensor is greater than a set first reference amplitude, and the amplitudes of signals output from the longitudinal acceleration sensor after the first signal are greater than the first reference amplitude. If it is greater than the second reference amplitude set to a small value, the electronic differential gear mount is driven by the control signal.

Further, the controller stops the driving of the electronic differential gear mount when the amplitude of the signal output from the longitudinal acceleration sensor after driving the electronic differential gear mount is equal to or less than the second reference amplitude.

In addition, the controller does not drive the electronic differential gear mount when the amplitude of the first signal output from the longitudinal acceleration sensor is equal to or less than the set first reference amplitude, and the amplitude of the first signal output from the longitudinal acceleration sensor is set to the first reference amplitude. If the amplitude of the second signal output from the longitudinal acceleration sensor is equal to or less than the second reference amplitude, the electronic differential gear mount is not driven.

In addition, the controller generates the control signal when the tip of the accelerator pedal for starting the vehicle is tip-in, and the control signal is a signal having the same magnitude as the signal of the longitudinal acceleration sensor and a phase difference of 180 °. used The controller determines whether it is the tip of the accelerator pedal based on the maximum value and rate of change of the accelerator pedal signal. It is determined that the tip-in condition is satisfied.

Meanwhile, the apparatus for controlling vibration of a differential gear for a vehicle of the present invention configured as described above may further include a low-pass filter for filtering signal noise of the longitudinal acceleration sensor, and the controller controls the longitudinal acceleration passing through the low-pass filter. The control signal may be generated using a signal. At this time, as the control signal, a signal having the same magnitude as the longitudinal acceleration signal passing through the low pass filter and a phase difference of 180° is used.

According to the vibration control device of the differential gear for a vehicle according to the present invention, by reducing the vertical displacement of the rear part of the differential gear mounted on the rear member of the rear cross member, the front part of the differential gear mounted on the front member of the rear cross member and It is possible to equally maintain the amplitude ratio of the vertical displacement between the rear parts of the differential gear, thereby minimizing the movement of the center of roll vibration (rotational vibration) of the differential gear, thereby reducing the forward and backward behavior of the vehicle, In addition, by improving riding comfort and drivability, it is possible to secure marketability and luxury of the vehicle.

1 is a view showing a signal of an accelerator pedal sensor and a vehicle longitudinal acceleration signal when the accelerator pedal is tipped;
2 is a view showing a drive system of a rear wheel drive vehicle;
3 is a view showing the reaction force of the engine driving torque acting on the rear differential gear installed on the rear cross member;
4 is a view showing the vibration characteristics of the rear differential gear when the tip of the accelerator pedal
5 is a configuration diagram showing a vibration control device of a differential gear for a vehicle according to the present invention
6 is a view showing the effect of the vibration control device of the differential gear for a vehicle according to the present invention
7 is a flow chart showing a driving control method of an electronic differential gear mount using a vibration control device for a vehicle differential gear according to the present invention;

In general, when the vehicle starts, the driving torque of the engine rapidly increases as the accelerator pedal tips in, and the longitudinal acceleration value of the vehicle rapidly increases from zero. At this time, in the signal of the longitudinal acceleration sensor that detects the longitudinal acceleration value, the first signal output after 0 has the largest amplitude, and subsequent signals, that is, the second signal, have smaller amplitude than the first signal, and the amplitude gradually decreases. (See Fig. 1).

Meanwhile, the driving system of a rear-wheel drive vehicle has a closed-loop structure as shown in FIG. The roll vibration (rotational vibration) of the differential gear occurs together with the forward-backward vibration (movement). Since the rear differential gear constitutes a closed-loop driving system together with wheels and a body (subframe, etc.) connected to the drive shaft, the behavior of the rear differential gear and the body affect each other, and roll vibration of the rear differential gear Vibration occurs in the forward and backward directions of the vehicle.

In more detail, the rear differential gear 20 is a differential gear device configured to distribute driving force of the same rotational speed or different rotational speeds to the left and right rear wheels, and the rear cross member through the differential gear mounts 21 and 22 (10) (see Fig. 3). The rear cross member 10 is disposed between the left and right rear wheels of the vehicle in the vehicle width direction and configured between the vehicle body and the suspension to support the torsion of the vehicle in the front and rear and left and right directions, and the front front member 11 and the rear rear It consists of a member 12 and a pair of side members 13 therebetween. Also, differential gear mounts 21 and 22 are mounted on both left and right sides of the front member 11 and on both left and right sides of the rear member 12 , respectively. The differential gear mounts 21 and 22 can be divided into a differential gear front mount 21 disposed on the front member 11 and a differential gear rear mount 22 disposed on the rear member 12 . When the rear differential gear 20 is excited by the reaction force of the engine driving torque, the reaction force acts upward on the front mount 21 of the differential gear and the reaction force acts downward on the rear mount 22 of the differential gear ( See the arrows in Figure 3). At this time, forward and backward vibration occurs together with roll vibration of the rear differential gear 20, and accordingly, the center of roll vibration (rotational vibration) of the rear differential gear 20 moves forward and backward (see FIG. 4). The reason is that during roll vibration of the differential gear 20, the amplitude of the vertical displacement of the rear part of the differential gear 20 (the part mounted on the rear member side of the rear cross member) is This is because when a difference (more than a certain value) with the amplitude of the vertical displacement of the part (a part mounted on the front member side of the rear cross member) occurs, the center of the roll vibration moves in the forward and backward directions of the vehicle. When the center of roll vibration of the differential gear 20 moves in the front and rear direction, vibration in the front and rear direction of the vehicle occurs accordingly, and the differential gear 20 vibrates in a soft mode of roll vibration and front and rear vibration. Accordingly, fluctuations in engine driving torque are deteriorated and vehicle behavior is deteriorated through the closed-loop driving system.

Accordingly, in the present invention, vibration of the vehicle in the front and rear directions of the vehicle can be prevented by controlling the roll behavior of the differential gear when the tip-in of the accelerator pedal rapidly increases the engine driving torque.

Specifically, in the present invention, by using an electronic differential gear mount, the control force for controlling the roll behavior (rotational vibration) of the differential gear according to the rapid fluctuation of the engine driving torque is the excitation force (reaction force of the engine driving torque) that excites the differential gear. ), it is possible to control the behavior of the differential gear and the front and rear direction of the vehicle.

To this end, in the present invention, two of the four differential gear mounts 21 and 22 mounted on the rear cross member 10 as shown in FIG. 3 are mounted on the rear member 12 of the rear cross member 10. The differential gear 20 ) to maintain the same (constant) amplitude ratio of the vertical displacement of the front and rear parts (or the front and rear members of the rear cross member).

5 is a configuration diagram showing a vibration control device for a differential gear for a vehicle according to the present invention, and FIG. 6 is a diagram showing the effect of the vibration control device for a differential gear for a vehicle according to the present invention.

As shown in FIG. 5, the vibration control device of the differential gear for a vehicle according to the present invention includes an accelerator pedal sensor 1, a longitudinal acceleration sensor 2, an electronic differential gear mount 4, a controller 3, and the like. It can be.

The accelerator pedal sensor 1 is configured to detect a position according to the amount of depression of the accelerator pedal and transmit the detected accelerator pedal signal (accelerator pedal position signal) to the controller (through wired communication of the vehicle). 3) can be sent to.

The longitudinal acceleration sensor 2 is configured to detect and transmit the longitudinal acceleration of the vehicle to the controller 3, and the detected longitudinal acceleration signal may be transmitted to the controller 3 through wired communication of the vehicle.

The electronic differential gear mount 4 is installed between the differential gear 20 and the cross member 10 to mount the differential gear 20 to the cross member 10, by electronic control using a control signal. A drivable differential gear mount is used. The electronic differential gear mount 4 is installed on the rear member 12 to which the rear part of the differential gear 20 of the front member 11 and rear member 12 of the cross member 10 is coupled (see FIG. 3). . A general differential gear mount (for example, a rubber mount or a hydro mount) may be installed on the front member 11, which does not require a separate electronic control.

The electronic differential gear mount 4 is an electronic active mount that can be driven by a control signal (mount control signal) generated from the controller 3, and drives the differential gear 20 by being driven according to the control signal. By offsetting the excitation force (the reaction force of the engine driving torque), the vertical displacement of the rear portion of the differential gear 20 is reduced to a certain amplitude, thereby generating a control force that can be controlled. The excitation force acts in the vertical direction of the vehicle to cause roll vibration of the differential gear 20, and the control force is generated in an opposite phase to the excitation force, thereby reducing the excitation force.

According to an embodiment of the present invention, the electronic differential gear mount 4 is a differential gear rear mount mounted on the rear member 12 of the cross member 10, and the cross member 10 is the left and right rear wheels of a rear wheel drive vehicle. A rear cross member disposed therebetween, and the differential gear 20 is a rear differential gear mounted to the rear cross member via the differential gear rear mount.

The controller 3 may be one of the controllers provided in the vehicle, and is configured to generate a control signal for controlling the electronic differential gear mount 4. The controller 3 transmits the control signal when the engine drive torque increases due to vehicle start, specifically when the engine drive torque rapidly and excessively increases, such as when an accelerator pedal is tipped for vehicle start. By generating and driving the electronic differential gear mount 4 by the generated control signal, it is possible to control the vertical displacement of the rear part of the differential gear 20 according to the reaction force of the engine driving torque with a constant amplitude (FIG. 6 Reference).

The controller 3 can determine the change/increase of the engine driving torque and the tip of the accelerator pedal based on the signal of the accelerator pedal sensor 1 detected in real time, and in particular, the maximum value and change rate of the accelerator pedal signal. Based on this, it is possible to determine whether the accelerator pedal is tipped. Specifically, the controller 3 determines that the accelerator pedal tip condition is satisfied when the maximum value of the accelerator pedal signal is greater than or equal to a set reference value and the change rate of the accelerator pedal signal is greater than or equal to the set reference change rate. The reference value and the reference rate of change may be set to values by which it can be determined that tip-in of the accelerator pedal has occurred when the vehicle starts.

The controller 3 generates a control signal based on the signal of the longitudinal acceleration sensor 2, and in particular generates a control signal by inverting the signal (longitudinal acceleration signal) of the longitudinal acceleration sensor 2 in an antiphase. At this time, in order to remove the noise component (high frequency component) included in the longitudinal acceleration signal, before generating the control signal, a low pass filter 5 filtering the longitudinal acceleration signal in a certain frequency band may be used (Fig. see 5). Accordingly, the controller 3 may generate the control signal by referring to the longitudinal acceleration signal that has passed through the low pass filter 5 as a reference signal and inverting the phase of the reference signal by 180°.

In addition, when the amplitude of the signal output from the longitudinal acceleration sensor 2 is greater than the set second reference amplitude when the vehicle starts, the controller 3 drives the electronic differential gear mount by the control signal to generate the reaction force of the engine driving torque. By controlling the up and down displacement of the rear part of the differential gear 20 according to the above, the amplitude fluctuation of the up and down displacement is reduced so that the up and down displacement of the differential gear 20 is controlled at a constant amplitude. To this end, the controller 3 compares the signal output from the longitudinal acceleration sensor 2 (or the first longitudinal acceleration signal that has passed through the low-pass filter) with the second reference amplitude when the accelerator pedal is tipped, and the signal is determined as the second reference amplitude. If it is greater than the amplitude, the electronic differential gear mount 4 can be driven by the control signal. Here, the second reference amplitude is set as an amplitude reference value of vibration that passengers cannot feel. That is, if the amplitude of the longitudinal acceleration signal is equal to or less than the second reference amplitude, it may be determined that the passenger does not feel the vibration caused by the longitudinal acceleration signal.

However, the first signal output from the longitudinal acceleration sensor 2 when the tip of the accelerator pedal has the largest amplitude, and in this case, the first signal output from the longitudinal acceleration sensor 2 has a certain value higher than the second reference amplitude. It exceeds the first reference amplitude set to a large value. Therefore, the controller 3 sets the first reference amplitude (specifically, the first signal of the sine wave that has passed through the low-pass filter) of the sine wave output from the longitudinal acceleration sensor 2 when the vehicle starts. For example, if it is less than 0.1g), it is determined that the vibration of the amplitude felt by the passenger does not occur, and the signal of the longitudinal acceleration sensor 2 is not monitored and the electronic differential gear mount 4 is not driven. At this time, the first reference amplitude is set as an amplitude reference value of vibration that passengers can feel.

In addition, even if the amplitude of the first signal is greater than the set first reference amplitude, the controller 3 operates the electronic differential gear mount 4 when the amplitude of the second signal output from the longitudinal acceleration sensor is less than or equal to the second reference amplitude. don't drive

therefore, The controller 3 sets a first reference amplitude (for example, 0.1g) in which the amplitude of the first signal of the sine wave output from the longitudinal acceleration sensor 2 (or the first longitudinal acceleration signal that has passed through the low-pass filter) is set. and the amplitudes of the signals output from the longitudinal acceleration sensor 2 after the first signal (ie, the second signal, the third signal, ...) are set to a value smaller (about 40%) than the first reference amplitude. If it is greater than the second reference amplitude (eg, 0.06g), it is preferable to drive the electronic differential gear mount 4 by the control signal.

When the electronic differential gear mount 4 is driven by the control signal, the vertical displacement of the rear part of the differential gear 20 according to the reaction force of the engine driving torque is controlled while gradually maintaining a constant amplitude. At this time, the control signal is a signal having the same magnitude as the longitudinal acceleration signal (specifically, the longitudinal acceleration signal passing through the low-pass filter) and a phase difference of 180°.

Therefore, the controller 3 controls the amplitude of the longitudinal acceleration signal by driving the electronic differential gear mount 4 to be equal to or less than the second reference amplitude (set to a value smaller than the first reference amplitude), the differential gear 20 It is determined that the amplitude of the vertical displacement of ) is maintained constant, and the driving of the electronic differential gear mount 4 is stopped. Specifically, the controller 3 controls the amplitude of signals output from the longitudinal acceleration sensor 2 after the second signal (ie, the third signal, the fourth signal, ...) to drive the electronic differential gear mount 4. is reduced by, and when it is less than the second reference amplitude, the driving of the electronic differential gear mount 4 is stopped. In other words, the controller 3 operates the electronic differential gear mount 4 until the amplitude value of the signal output from the longitudinal acceleration sensor 2 after the second signal becomes equal to or less than the second reference amplitude.

In this way, when a control force is generated in the reverse phase of the excitation force that excites the differential gear 20 using the electronic differential gear mount 4, the vertical displacement of the rear portion of the differential gear 20 that needs to control the vertical displacement with a constant amplitude It is possible to keep the amplitude of the constant at the same level as the front part of the differential gear 20, and accordingly, it is possible to minimize the movement of the center of the roll vibration (rotational vibration) of the differential gear 20 in the front and rear directions of the vehicle. As a result, it is possible to prevent the front-back movement of the vehicle according to the front-back movement of the differential gear 20 (see FIG. 6).

For reference, reference numeral 6 in FIG. 5 denotes a signal amplifier. The signal amplifier 6 is configured to amplify and output a control signal transmitted from the controller 3 to the electronic differential gear mount 4.

Meanwhile, in FIG. 3, reference numeral P denotes a propeller shaft that transmits torque to the differential gear, and reference numeral D denotes a drive shaft that receives torque from the differential gear.

Here, referring to FIG. 7 , a driving control process of the electronic differential gear mount 4 using the vibration control device of the differential gear for a vehicle according to the present invention will be described as an example.

As shown in FIG. 7 , first, it is determined whether the accelerator pedal is the tip of the accelerator pedal by using the accelerator pedal signal (S10). Whether the tip of the accelerator pedal is the tip may be determined based on the maximum value and change rate of the accelerator pedal signal.

If it is determined that the condition of the tip of the accelerator pedal is satisfied, the noise signal of the high frequency component is removed from the signal of the longitudinal acceleration sensor 2 (S12).

Next, the amplitude value of the first longitudinal acceleration signal from which noise has been removed is compared with the first reference amplitude (S14). Compare with the reference amplitude (S16).

When the amplitude value of the second longitudinal acceleration signal is greater than the second reference amplitude, the electronic differential gear mount is driven (S18). In other words, when the amplitude value of the first longitudinal acceleration signal is greater than the first reference amplitude and the amplitude value of the second longitudinal acceleration signal is greater than the second reference amplitude, the roll vibration of the differential gear 20 is accompanied by the tip of the accelerator pedal. It is determined that forward and backward vibration may occur, and the roll vibration of the differential gear 20 is controlled by operating the electronic differential gear mount 4 to prevent forward and backward vibration of the vehicle due to the forward and backward vibration of the differential gear 20. do. By the operation of the electronic differential gear mount 4, a control force having the same magnitude as the vibration component of the rear end of the differential gear 20 and the opposite phase is generated, and as a result, the vibration of the rear end of the differential gear 20 is insulated. .

The electronic differential gear mount 4 is operated until the signal amplitude after the second longitudinal acceleration signal is equal to or less than the second reference amplitude. When the amplitude of the longitudinal acceleration signal after the second longitudinal acceleration signal becomes equal to or less than the second reference amplitude, the driving of the electronic differential gear mount 4 is stopped.

Since the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited to the above-described embodiments, and various modifications and modifications of those skilled in the art using the basic concept of the present invention defined in the following claims Improvements are also included in the scope of the present invention.

1: Accelerator pedal sensor
2: longitudinal acceleration sensor
3 : Controller
4 : Electronic differential gear mount
5: low pass filter
10: (rear) cross member
11 : front member
12 : rear member
13 : side member
20: (rear) differential gear
21 : differential gear front mount
22 : differential gear rear mount

Claims (14)

a longitudinal acceleration sensor that detects a longitudinal acceleration of the vehicle;
An electronic differential gear mount for mounting the rear part of the differential gear to the cross member;
A controller generating a control signal by inverting the signal of the longitudinal acceleration sensor in antiphase when the engine driving torque increases due to vehicle start, and driving the differential gear mount by the control signal;
The controller determines that the amplitude of the first signal output from the longitudinal acceleration sensor is greater than the set first reference amplitude when the vehicle starts, and the amplitudes of signals output from the longitudinal acceleration sensor after the first signal are smaller than the first reference amplitude. Vibration control device of a differential gear for a vehicle, characterized in that for driving the electronic differential gear mount by the control signal when it is greater than the set second reference amplitude.
The method of claim 1,
The electronic differential gear mount generates a control force for controlling the vertical displacement of the rear portion of the differential gear with a constant amplitude when driven by the control signal.
delete delete The method of claim 1,
Wherein the controller stops driving of the electronic differential gear mount when the amplitude of the signal output from the longitudinal acceleration sensor after driving the electronic differential gear mount is equal to or less than the second reference amplitude Vibration control device of a vehicle differential gear.
The method of claim 1,
Wherein the controller does not drive the electronic differential gear mount when the amplitude of the first signal output from the longitudinal acceleration sensor is equal to or less than the set first reference amplitude.
The method of claim 1,
The controller does not drive the electronic differential gear mount when the amplitude of the second signal output from the longitudinal acceleration sensor is less than or equal to the second reference amplitude, even if the amplitude of the first signal output from the longitudinal acceleration sensor is greater than the set first reference amplitude. Vibration control device of a differential gear for a vehicle, characterized in that.
The method of claim 1,
The controller is a vibration control device of a differential gear for a vehicle, characterized in that for generating the control signal when the tip of the accelerator pedal for starting the vehicle.
The method of claim 1,
The control signal is a signal having the same magnitude as the signal of the longitudinal acceleration sensor and a phase difference of 180 °.
The method of claim 8,
Wherein the controller determines whether the accelerator pedal is the tip of the accelerator pedal based on the maximum value and rate of change of the accelerator pedal signal.
The method of claim 10,
The controller determines that the tip condition of the accelerator pedal is satisfied when the maximum value of the accelerator pedal signal is greater than the set reference value and the change rate of the accelerator pedal signal is greater than the set reference change rate. Vibration control device for a vehicle differential gear, characterized in that.
The method of claim 1,
Further comprising a low-pass filter for filtering signal noise of the longitudinal acceleration sensor, wherein the controller generates the control signal using the longitudinal acceleration signal that has passed through the low-pass filter. Vibration control of a differential gear for a vehicle, characterized in that Device.
The method of claim 12,
The control signal is a signal having the same magnitude as the longitudinal acceleration signal passing through the low pass filter and a phase difference of 180 °.
The method of claim 1,
The cross member is a rear cross member disposed between the left and right rear wheels of a rear wheel drive vehicle, and the differential gear is a rear differential gear mounted on the rear cross member.

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