WO2019062820A1 - Hybrid electric vehicle and active vibration reduction control method and apparatus therefor - Google Patents

Abstract

A hybrid electric vehicle and an active vibration reduction control method therefor. The method comprises the following steps: when determining, according to an acceleration sensor signal and a crankshaft sensor signal, that a hybrid electric vehicle is in a driving growling working condition, calculating a target current value according to a rotation speed, a vibration period and a vibration amplitude of an engine, and also acquiring a vehicle speed sensor signal of the hybrid electric vehicle; correcting the target current value according to the vehicle speed sensor signal and the rotation speed of the engine, so as to obtain a first corrected current value; and acquiring an ignition coil signal of the engine, and when the engine is in an ignition state, outputting, according to the first corrected current value and the ignition coil signal, a drive signal with a working time to a drive circuit, so as to perform active vibration reduction control on the hybrid electric vehicle. The method can realize the active vibration reduction control of a vehicle in a driving growling working condition, and has a relatively high timeliness. The present invention further relates to an active vibration reduction control apparatus for a hybrid electric vehicle.

Description

Hybrid electric vehicle and active vibration damping control method and device thereof

Cross-reference to related applications

The present application is based on a Chinese patent application filed on Jan. 30, 2017, the entire disclosure of which is hereby incorporated by reference.

Technical field

The present application relates to the field of automobile technology, and in particular to an active vibration damping control method for a hybrid vehicle, an active vibration damping control device for a hybrid vehicle, and a hybrid vehicle having the same.

Background technique

With the advancement of social technology, people's requirements for comfort are getting higher and higher, and ride comfort has become an important indicator to measure the performance of cars. Among them, the main factor affecting ride comfort is car vibration, which causes car vibration. There are many reasons for this, and engine vibration is one of the main reasons worthy of attention. The engine vibration is mainly caused by the combustion in the engine cylinder and the reciprocating motion of the piston. The vibration is transmitted to the frame through the engine suspension system, and then transmitted to the cab, which affects the ride comfort.

In order to improve ride comfort, a reasonable suspension system is required to achieve the purpose of damping vibration.

Summary of the invention

The present application aims to solve at least one of the technical problems in the related art to some extent. To this end, the present application proposes an active vibration damping control method for a hybrid vehicle, which can realize active vibration damping control of the vehicle under driving and roaring conditions, and has high timeliness, and directly obtains vibration reduction using the ignition coil signal. The effective moment of noise makes the action time of the vibration damping control more accurate and the vibration damping effect more effective.

The present application also proposes an active vibration damping control device for a hybrid vehicle.

The present application further proposes a hybrid vehicle.

An embodiment of the present application proposes an active vibration damping control method for a hybrid vehicle, the hybrid vehicle including an active suspension system, the method comprising the steps of: acquiring when the engine of the hybrid vehicle is working An acceleration sensor signal and a crankshaft sensor signal of the hybrid vehicle, and determining, according to the acceleration sensor signal and the crank sensor signal, whether the hybrid vehicle is in a driving booming condition; if the hybrid vehicle is in a driving booming condition, Calculating a rotational speed and a vibration period of the engine according to the crankshaft sensor signal, calculating a vibration amplitude of the engine according to the acceleration sensor signal, and estimating the engine according to the engine speed, a vibration period, and a vibration amplitude. a vibration state, and calculating a target current value according to the vibration state of the engine; acquiring a vehicle speed sensor of the hybrid vehicle when determining whether the hybrid vehicle is in a driving roaming condition according to the acceleration sensor signal and the crank sensor signal a signal; correcting the target current value according to a vehicle speed sensor signal of the hybrid vehicle and a rotational speed of the engine to obtain a first corrected current value; acquiring an ignition coil signal of the engine, and according to ignition of the engine a coil signal determining that the engine is in an ignition state, outputting a driving signal with a working time to a driving circuit operating according to the first corrected current value and the ignition coil signal of the engine; the driving circuit An operating current with an active time is output to the actuator based on the drive signal, and the actuator operates in accordance with the operating current with an active time to perform active damping control of the hybrid vehicle.

According to the active vibration control method of the hybrid vehicle according to the embodiment of the present application, when the engine of the hybrid vehicle is working, it is determined whether the hybrid vehicle is in a driving boom condition according to the acceleration sensor signal and the crank sensor signal, and if so, according to the crankshaft The sensor signal calculates the engine speed and vibration period, and calculates the vibration amplitude of the engine based on the acceleration sensor signal, and then calculates the target current value according to the engine speed, the vibration period, and the vibration amplitude. At the same time, the vehicle speed sensor signal of the hybrid vehicle is obtained. Then, the target current value is corrected based on the vehicle speed sensor signal of the hybrid vehicle and the rotational speed of the engine to obtain a first corrected current value. Finally, the ignition coil signal of the engine is obtained, and when the engine is in the ignition state, the driving signal with the working time is output to the driving circuit according to the first corrected current value and the ignition coil signal, and the driving circuit outputs the working to the actuator according to the driving signal. Current, active vibration control of hybrid vehicles. Therefore, the active vibration reduction control of the vehicle under driving and roaring conditions is realized, and the time is effective, and the effective moment of vibration reduction and noise reduction is directly obtained by using the ignition coil signal, so that the action time of the vibration reduction control is more accurate, and the vibration damping effect is obtained. More effective.

An active vibration damping control apparatus for a hybrid vehicle according to another embodiment of the present application includes: a first acquisition module, wherein the first acquisition module is configured to acquire the hybrid vehicle when the engine of the hybrid vehicle is working The acceleration sensor signal and the crank sensor signal; the first determining module, the first determining module is configured to determine, according to the acceleration sensor signal and the crank sensor signal, whether the hybrid vehicle is in a driving roaming condition; the vibration period computing module, The vibration period calculation module is configured to calculate a rotation speed and a vibration period of the engine according to the crankshaft sensor signal when the hybrid vehicle is in a driving booming condition, and calculate a vibration amplitude of the engine according to the acceleration sensor signal; a state estimation module, configured to estimate a vibration state of the engine according to a rotational speed, a vibration period, and a vibration amplitude of the engine; a target current calculation module, wherein the target current calculation module is configured to be used according to the engine Vibration state calculation target electricity a main control module, configured to acquire a vehicle speed sensor signal of the hybrid vehicle when the first determining module determines whether the hybrid vehicle is in a driving boom condition; the first current correction module The first current correction module is configured to correct the target current value according to a vehicle speed sensor signal of the hybrid vehicle and a rotation speed of the engine to obtain a first correction current value; a second acquisition module, the first The second obtaining module is configured to obtain an ignition coil signal of the engine; the second determining module is configured to determine, according to an ignition coil signal of the engine, whether the engine is in an ignition state; the driving control module and the driving circuit The drive control module is configured to output a driving signal with a working time to the driving circuit according to the first corrected current value and an ignition coil signal of the engine when the engine is in an ignition state, the driving circuit Outputting an operating current with an active time to the actuator according to the driving signal, so that the actuation It operates according to the operating current with a duration of action of the active damping control for the hybrid vehicle.

According to the active vibration damping control device of the hybrid vehicle according to the embodiment of the present application, when the engine of the hybrid vehicle is working, it is determined whether the hybrid vehicle is in a driving boom condition according to the acceleration sensor signal and the crank sensor signal, and if so, according to the crankshaft The sensor signal calculates the engine speed and vibration period, and calculates the vibration amplitude of the engine based on the acceleration sensor signal, and then calculates the target current value according to the engine speed, the vibration period, and the vibration amplitude. At the same time, the vehicle speed sensor signal of the hybrid vehicle is obtained. Then, the target current value is corrected based on the vehicle speed sensor signal of the hybrid vehicle and the engine speed to obtain a first corrected current value. Finally, the ignition coil signal of the engine is obtained, and when the engine is in the ignition state, the driving signal with the working time is output to the driving circuit according to the first corrected current value and the ignition coil signal, and the driving circuit outputs the working to the actuator according to the driving signal. Current, active vibration control of hybrid vehicles. Therefore, the active vibration reduction control of the vehicle under driving and roaring conditions is realized, and the time is effective, and the effective moment of vibration reduction and noise reduction is directly obtained by using the ignition coil signal, so that the action time of the vibration reduction control is more accurate, and the vibration damping effect is obtained. More effective.

A further aspect of the present application provides a hybrid vehicle including the above-described active vibration damping control device for a hybrid vehicle.

In the hybrid vehicle of the embodiment of the present application, the active vibration damping control device of the hybrid vehicle described above can realize the active vibration damping control of the vehicle under the driving and roaring condition, and has high timeliness, and the ignition coil signal is directly used. Obtaining the effective moment of vibration and noise reduction makes the action time of the vibration reduction control more accurate and the vibration damping effect more effective.

DRAWINGS

1 is a flowchart of an active vibration damping control method of a hybrid vehicle according to an embodiment of the present application;

2 is a schematic diagram showing a relationship between an ignition coil signal and a target current value of a four-cylinder engine according to an embodiment of the present application;

3 is a flow chart of active vibration damping control corresponding to a first communication cycle (n=1) when a hybrid vehicle is in a booming condition according to an embodiment of the present application;

4 is a flow chart of active damping control corresponding to a second and above communication cycles (n≥2) when the hybrid vehicle is in a booming condition according to an embodiment of the present application;

5 is a block schematic diagram of an active vibration damping control device of a hybrid vehicle according to an embodiment of the present application;

6 is a block diagram showing an active vibration damping control device of a hybrid vehicle according to an embodiment of the present application;

7 is a block schematic diagram of a hybrid vehicle in accordance with an embodiment of the present application.

Detailed ways

The embodiments of the present application are described in detail below, and the examples of the embodiments are illustrated in the drawings, wherein the same or similar reference numerals are used to refer to the same or similar elements or elements having the same or similar functions. The embodiments described below with reference to the accompanying drawings are intended to be illustrative, and are not to be construed as limiting.

This application is based on the inventors' understanding and research on the following issues:

The related art provides an anti-vibration control algorithm for estimating the vibration state of the first cycle of the engine vibration based on the output of the sensor for detecting the rotational variation of the engine, and simultaneously calculating the cycle length and the target current value waveform, and constant The sampling period samples the target current value waveform to obtain a data set of the target current value. When the target current value is output to the drive unit, the cycle length of the third cycle of the engine vibration is estimated based on the predetermined number of crank pulse intervals, and thereby the data set of the obtained target current value is corrected.

The inventor found that the above control algorithm is only for the fuel vehicle and does not involve the vibration reduction control of the hybrid vehicle. Further, the control algorithm estimates the vibration state and the target current value of the third cycle based on the vibration state and the target current value of the first cycle of the engine vibration, etc., and does not have timeliness, and real-time adjustment of the vibration cannot be realized, and Applicable to the relatively special operating conditions of the engine speed.

An active vibration damping control method for a hybrid vehicle, an active vibration damping control device for a hybrid vehicle, and a hybrid vehicle having the same according to an embodiment of the present application will be described below with reference to the accompanying drawings.

1 is a flow chart of an active vibration damping control method of a hybrid vehicle according to an embodiment of the present application. Among them, the hybrid vehicle includes an active suspension system. As shown in FIG. 1, the active vibration damping control method of the hybrid vehicle may include the following steps:

S1. When the engine of the hybrid vehicle is working, the controller of the active suspension system acquires the acceleration sensor signal and the crank sensor signal of the hybrid vehicle, and determines whether the hybrid vehicle is in a roaming condition according to the acceleration sensor signal and the crank sensor signal. .

Among them, the driving roaring condition refers to the roaring of the engine's rotating speed and vibration amplitude due to sudden changes in the engine's current or other state changes during the driving of the vehicle. When the car is in the booming condition, the vibration and noise of the car will suddenly become larger, which is reflected in the abnormal engine speed and vibration. Therefore, the engine speed can be obtained through the crankshaft sensor signal, and the acceleration sensor signal can be obtained at the same time. Obtain the vibration amplitude of the engine, then judge whether the engine speed is in an abnormal state, and judge whether the vibration amplitude is too large. If the rotation speed is abnormal and the vibration amplitude is too large, it is judged that the automobile is in a driving booming condition.

S2, if the hybrid vehicle is in a driving boom condition, the controller of the active suspension system calculates the engine speed and the vibration period according to the crank sensor signal, and calculates the vibration amplitude of the engine according to the acceleration sensor signal, and according to the engine speed and vibration. The period and the vibration amplitude estimate the vibration state of the engine, and calculate the target current value according to the vibration state and the vibration amplitude of the engine. Among them, the vibration state of the engine includes a vibration period and a vibration frequency.

Specifically, when the engine of the hybrid vehicle is operated, the active suspension system (the active suspension system can be used to support the weight of the power unit, suppress the dynamic displacement of the power unit due to the external force of the internal reaction force, and prevent the position from the engine or the like. The vibration force is transmitted to the vehicle body vibration, which is a buffer system.) Acquire the acceleration sensor signal and the crank sensor signal and calculate the engine speed and vibration amplitude, and then determine whether the engine speed and vibration amplitude are within the range of the engine's driving boom. Inside. If the engine speed and vibration amplitude are not within the range of the engine's driving boom, enter other conditions (such as acceleration, deceleration, etc.); if the engine's speed and vibration amplitude are within the engine's driving boom conditions, then The engine speed and vibration period are calculated based on the crankshaft sensor signal, and the vibration amplitude of the engine is calculated based on the acceleration sensor signal.

Wherein, the engine speed is equal to the number of revolutions of the crankshaft per minute; the vibration period of the engine can be calculated according to the number of cylinders of the engine and the engine speed. Taking a four-cylinder engine as an example, the crankshaft rotates two times in each working cycle of the engine. And in each working cycle, four cylinders are fired in sequence according to the sequence, that is, the engine will explode twice per revolution, that is, the engine will vibrate twice per revolution. If the engine speed is 6000r/min, then the engine vibration period It is 1/200 s; the vibration amplitude of the engine can be obtained by sampling the acquired acceleration sensor signal to obtain a discrete signal, and then performing Fourier transform on the discrete signal to convert the time domain signal into a frequency domain signal.

After calculating the engine speed, vibration period and vibration amplitude, the vibration frequency of the engine can be calculated according to the engine speed and vibration period, and then calculated according to the vibration frequency and vibration amplitude of the engine by sampling method or table lookup method. The target current value A can be specifically calculated by using the prior art.

S3. When it is determined that the hybrid vehicle is in a driving boom condition according to the acceleration sensor signal and the crank sensor signal, the controller of the active suspension system acquires the vehicle speed sensor signal of the hybrid vehicle.

S4. The controller of the active suspension system corrects the target current value according to the vehicle speed sensor signal of the hybrid vehicle and the engine speed to obtain the first correction current value.

Specifically, since the vehicle speed of the hybrid vehicle and the engine speed affect the vibration of the engine, the corresponding correction value is obtained by looking up the table according to the current vehicle speed sensor signal of the hybrid vehicle and the engine speed, and then The correction value adjusts the target current value A to obtain the first correction current value A', so that the corrected target current value is more in line with the actual working condition, and is more beneficial to the vibration reduction and noise reduction of the active suspension system. Among them, under normal circumstances, the vehicle speed sensor signal needs to be obtained by the vehicle controller, and the communication cycle of the active suspension system and the vehicle controller is many times larger than the vibration period of the engine, and the change of the crankshaft sensor signal is fast, and the range of variation Large, so in order to make the target current value more consistent with the current vibration state of the engine and save computation time, a pre-processing (ie, steps S1-S2) can be set, the pre-processing function is to continuously acquire the acceleration sensor signal and the crank sensor signal. And calculating the engine speed and vibration period based on the crankshaft sensor signal, and obtaining the vibration amplitude of the engine according to the acceleration sensor signal, and thereby preliminarily determining whether the hybrid vehicle is in a driving booming condition and calculating a target current value A, when When the target current value A and the vibration state of the engine, such as the vibration period and the vibration amplitude, are required, they can be directly utilized, thereby not only saving the calculation time in the working condition determination process and the software flow process, but also the target current value more reflecting the current state. .

According to an embodiment of the present application, when determining whether the hybrid vehicle is in a driving boom condition based on the acceleration sensor signal and the crank sensor signal, the active suspension system also confirms the current communication by communicating with the vehicle controller of the hybrid vehicle. Whether the current working condition of the hybrid vehicle in the cycle is a roaming condition.

That is to say, in order to ensure the accuracy of the working condition judgment, it is also communicated with the vehicle controller of the hybrid vehicle to confirm whether the current working condition is a driving booming condition. If so, the target current value A is corrected based on the vehicle speed sensor signal of the hybrid vehicle and the engine speed to obtain the first corrected current value A'.

Further, FIG. 2 is a schematic diagram showing the relationship between the ignition coil signal and the target current value of the four-cylinder engine according to an embodiment of the present application. As shown in FIG. 2, I-IV represents the ignition coil signals of the four cylinders of the engine; A waveform diagram of the PWM signal required to generate the target current A; a indicates that the active suspension system is in a driving booming condition; b indicates that the active suspension system is in a dormant condition after being judged by d and e in sequence; c indicates that the active suspension system is in turn After d and e judgment, it is in other working conditions; d indicates whether the sensor signal is in the driving roaring condition; e indicates that the communication signal of the communication between the controller of the active suspension system and the vehicle controller determines whether it is in the driving roaming 1; indicates that the active suspension system is in a sleep state; 2 indicates that the active suspension system has two working states after being judged by d, respectively, the active suspension system is in an active state and remains in a sleep state, but only one of them can be selected; 3 indicates that the active suspension system has three working states after being judged by d and e, respectively, which are driving roaring conditions, dormant working conditions and other working conditions, but only Choose which one kind.

Specifically, the active suspension system is normally in a dormant state during the driving of the vehicle. When the active suspension system is in a dormant state, a small current is sent to the active suspension system in advance to enable the active suspension system and the entire vehicle to be controlled. The device communicates to obtain the current working condition and the vehicle speed sensor signal determined by the vehicle controller. At the same time, the active suspension system preprocesses the acceleration sensor signal and the crank sensor signal to obtain the engine speed, the vibration period, and The amplitude of the vibration. Since the communication cycle is many times larger than the vibration period of the engine, the judgment of d in FIG. 2 is first performed, that is, whether the hybrid vehicle is in a driving boom condition according to the signal obtained by the preprocessing, and if so, the system is actively suspended. The set current enters the active state and calculates a target current value A; otherwise, it remains in a sleep state. Subsequently, the judgment of e in FIG. 2 is performed. If the vehicle controller determines that the hybrid vehicle is in a roaming condition at this time, the active suspension system enters a working state, and if it is determined that the hybrid vehicle is in other working conditions at this time, the suspension is actively suspended. Set the system to work in other working conditions; otherwise, the active suspension system will remain dormant. After the active suspension system enters the operating state, the target current value A is corrected based on the vehicle speed sensor signal of the hybrid vehicle and the engine speed to obtain the first corrected current value A'.

S5. The controller of the active suspension system acquires an ignition coil signal of the engine, and determines that the engine is in an ignition state according to an ignition coil signal of the engine, and outputs a driving signal with a working moment according to the first corrected current value and the ignition coil signal of the engine. An actuator that drives the active suspension system performs a drive circuit for the active suspension system. The working moment is an instantaneous value used to determine the moment of action of the driving signal.

According to an embodiment of the present application, when it is judged that the engine is not in the ignition state according to the ignition coil signal of the engine, the timer is also used to count, and when the timing time reaches the preset time, if the engine is still not in the ignition state, then return Determine if the engine of the hybrid car is working.

Specifically, the ignition coil signal reflects the explosion timing of the cylinder in the engine, and the vibration of the engine is mainly generated by the gas combustion in the cylinder at the ignition timing to push the piston, so the ignition coil signal is used to control the output timing of the first correction current value A′, and the suppression is performed. Vibration is more accurate and effective.

In practical applications, it is possible to obtain an ignition coil signal of the engine by communicating with an electronic control unit of the engine, and determine whether the engine is in an ignition state according to the ignition coil signal. If the engine is not in the ignition state at this time, the waiting state is entered, the timer starts counting, and it is judged whether the timing time exceeds the prescribed time. If the predetermined time is exceeded, the above steps S1-S5 are repeatedly performed; if the specified time is not exceeded, the process is repeated. Step S5. If the engine is in the ignition state at this time, the drive signal with the operating time is output to the drive circuit based on the first corrected current value A' and the ignition coil signal.

Specifically, the corresponding driving signal may be obtained by using pulse width modulation control according to the first modified current value A′ and the vibration period of the engine, and then the driving pulse control signal is generated according to the ignition coil signal, and the pulse control signal is controlled by the pulse. The signal determines the time at which the first corrected current value A' is input to the actuator. When the first correction current value A' is input to the actuator, the actuator adjusts its own electromagnetic induction device according to the working current to realize the up and down movement of the mechanical structure, thereby changing the damping and dynamic stiffness of the active suspension, and realizing the automobile. The vibration and noise reduction function under driving and roaring conditions improves the user's ride comfort.

S6. The driving circuit outputs an operating current with an active time to the actuator according to the driving signal, and the actuator operates according to the working current with the working time to perform active vibration damping control on the hybrid vehicle. The action time refers to the time when the operating current is input to the actuator. The active vibration damping control method of the hybrid vehicle according to the embodiment of the present application can not only realize the active vibration damping control of the hybrid vehicle under the driving roaring condition, but also has high timeliness, the algorithm is more accurate, and the vibration damping effect is more good. At the same time, the effective timing of the vibration reduction and noise reduction control is directly obtained by using the ignition coil signal, so that the action time of the vibration reduction control is more convenient and more accurate, and the vibration damping effect is more effective.

In addition, in practical applications, since the temperature affects the vibration damping effect of the actuator, in order to achieve a better vibration damping effect, the operating temperature of the actuator is also monitored, and the target current value is based on the operating temperature. Make adjustments.

According to an embodiment of the present application, the active vibration damping control method of the hybrid vehicle further includes: detecting an output current of the driving circuit to obtain an operating temperature of the actuator; and correcting the first correction current according to an operating temperature of the actuator The value is adjusted.

Specifically, since the resistance of the coil in the driving circuit increases as the temperature increases, the output current of the driving circuit can be used to calculate the resistance value of the coil, and then the actuator is calculated based on the resistance value. The operating temperature is finally calculated based on the operating temperature, and the first corrected current value A' is adjusted according to the operating state, and the dynamic stiffness of the active suspension is adjusted according to the adjusted current value. Therefore, before the current damping effect is generated, the magnitude of the first correction current value at each moment is adjusted by monitoring the operating temperature of the actuator, thereby eliminating the influence of the temperature on the actuator and achieving the vibration damping effect. Active adjustment to make it have a better damping effect.

After adjusting the dynamic stiffness of the active suspension, if the vibration damping effect is not monitored, it is impossible to judge whether the vibration damping is effective and what kind of vibration damping effect, and if the vibration damping effect can be monitored, and according to the current reduction The vibration effect adjusts the first correction current value of the next communication cycle, and the obtained first correction current value is more reasonable, and the vibration damping effect is better.

According to an embodiment of the present application, the active vibration damping control method of the hybrid vehicle further includes: determining whether the current vibration value of the hybrid vehicle is greater than a preset vibration threshold according to the vibration amplitude of the engine; if the current vibration of the hybrid vehicle If the value is greater than the preset vibration threshold, the first correction current value is secondarily corrected to obtain a second correction current value, so that the actuator adjusts the dynamic stiffness of the active suspension system of the hybrid vehicle according to the second correction current value, Active vibration control for hybrid vehicles. Among them, the preset vibration threshold can be calibrated according to the actual situation.

Specifically, after adjusting the dynamic stiffness of the active suspension, the vibration amplitude of the engine is obtained by the acceleration sensor signal, and the current vibration value of the vehicle can be calculated according to the vibration amplitude, and then compared with the preset vibration threshold. If the vibration value is greater than the preset vibration threshold, the damping effect is not good. At this time, the target current correction signal is output according to the difference between the vibration value and the preset vibration threshold, and the first correction current value is corrected according to the target current correction signal. A' is corrected, and then the dynamic stiffness of the active suspension is adjusted according to the corrected target current value, that is, according to the second corrected current value A", thereby achieving the effect of the closed loop control.

That is to say, after the first correction current value is input to the driving circuit, the vibration damping effect is monitored by the vibration amplitude of the engine, and feedback is performed for the case where the vibration damping effect cannot be satisfied, so as to correct the first correction current value to form Closed loop adjustment ensures the effectiveness of the damping effect, and when the above two methods work together, the damping effect is more obvious and more stable, which can greatly improve the ride comfort. In addition, since the vibration amplitude of the engine is acquired by the acceleration sensor signal, the acceleration sensor not only participates in the determination of the vehicle working condition, but also obtains the vibration amplitude in real time and feeds back to the active suspension system to adjust the target current value, thereby realizing the work. The function of judgment, real-time adjustment and feedback.

Further, according to an embodiment of the present application, when the active suspension system communicates with the vehicle controller of the hybrid vehicle in the next communication cycle to confirm that the current working condition of the hybrid vehicle is still a driving boom condition, Whether the obtained vehicle speed sensor signal and the engine speed change, wherein if a change occurs, the target current value is corrected according to the changed vehicle speed sensor signal and the engine speed to obtain a third correction current value to be in the engine ignition In the state, the driving signal with the working time is output to the driving circuit according to the third corrected current value and the ignition coil signal of the engine; if no change occurs, the operating current output to the actuator is kept unchanged.

Specifically, since the engine vibration changes rapidly, in order to ensure quick and accurate calculation, the communication periods n=1 and n≥2 after switching to the driving booming condition for other conditions are set. When n≥2, if the front and back working conditions have not changed, the actuator is directly controlled by the target current value finally obtained in the previous communication cycle, thereby simplifying the calculation process and ensuring the calculation accuracy; if there is a change, Then, the latest target current value calculated after the preprocessing is called, and the target current value is corrected according to the obtained vehicle speed sensor signal of the hybrid vehicle and the engine speed to obtain the latest first correction current value, that is, the first Three correction current values.

Specifically, after the end of the first communication cycle of the driving booming condition, communication with the vehicle controller is continued to obtain the current working condition information of the automobile. Before the signal to the vehicle controller is acquired, the actuator is always controlled using the target current value finally obtained in the previous communication cycle.

After obtaining the signal of the vehicle controller, it is judged whether the current car is still in the driving boom condition, and if not, the other working conditions are processed; if yes, it is determined whether the hybrid vehicle speed sensor signal and the engine speed are no change. If not, continue to control the actuator using the target current value finally obtained in the previous communication cycle; if so, call the latest target current value calculated by the preprocessing, and the target according to the vehicle speed sensor signal and the engine speed The current value is corrected to obtain a third corrected current value, and then the actuator is controlled according to the third corrected current value. Thereby, the process of calculating each communication cycle is effectively reduced, the calculation amount is simplified, and the calculation accuracy is ensured.

In order to make the present application clear to those skilled in the art, FIG. 3 is a flow chart of active vibration damping control corresponding to the first communication cycle (n=1) when the hybrid vehicle is in a booming condition according to an embodiment of the present application. Figure. As shown in FIG. 3, the active vibration damping control of the hybrid vehicle may include the following steps:

S101: Communicate with the vehicle controller to determine whether the hybrid vehicle is in a booming condition. If yes, go to step S105; if no, go to the other working conditions identified.

S102: Acquire an acceleration sensor signal and a crank sensor signal while communicating with the vehicle controller, thereby acquiring an engine speed, a vibration period, and a vibration amplitude.

S103. Determine whether the hybrid vehicle is in a driving boom condition. If yes, go to step S104; if no, go to the other working conditions identified.

S104. The active suspension system is activated by a preset current, and acquires a target current value A required for driving a booming condition.

S105. Acquire a vehicle speed of the hybrid vehicle and a rotation speed of the engine, and correct A according to the vehicle speed and the rotation speed to obtain a first correction current value A'.

S106. Acquire an ignition coil signal.

S107. Determine whether the ignition coil signal is ON, that is, determine whether the engine is in an ignition state. If yes, go to step S109; if no, go to step S108.

S108. Determine whether the timing signal is ON. If yes, go back to step S101 and step S102; if no, go back to step S107.

S109, performing duty control on the driving circuit to obtain a first corrected current value A'.

S110, the first correction current value A' is input to the drive circuit.

S111, detecting an operating current of the driving circuit.

S112, the first correction current value A' is adjusted according to the operating current.

S113, reading the vibration amplitude of the engine.

S114, judging whether the vibration damping effect meets the condition according to the vibration amplitude of the engine. If yes, the vibration and noise reduction of the communication cycle is ended; if not, step S115 is performed.

S115, the adjusted first corrected current value A' is corrected according to the vibration damping effect to obtain a second corrected current value A".

Further, FIG. 4 is a flow chart of active damping control corresponding to the second and above communication cycles (n≥2) when the hybrid vehicle is in a driving boom condition according to an embodiment of the present application. As shown in FIG. 4, the active vibration damping control of the hybrid vehicle may include the following steps:

S201, communicating with the vehicle controller to determine whether the hybrid vehicle is still in a roaming condition. If yes, go to step S202; if no, go to the other working conditions identified.

S202. Determine whether there is a change in the speed of the hybrid vehicle and the engine speed. If yes, go to step S203; if no, go to step S205.

S203. Acquire a latest target current value A1.

S204, correcting the latest target current value A1 according to the vehicle speed of the hybrid vehicle and the engine speed to obtain a third current correction value A1'.

S205, directly acquiring the second correction current value A".

S206. Acquire an ignition coil signal.

S207. Determine whether the ignition coil signal is ON, that is, determine whether the engine is in an ignition state. If yes, go to step S209; if no, go to step S208.

S208. Determine whether the timing signal is ON. If yes, go back to step S201; if no, go back to step S207.

S209, performing duty control on the driving circuit to obtain a third corrected current value A1' or a second corrected current value A".

S210, the third correction current value A1' or the second correction current value A" is input to the drive circuit.

S211, detecting an operating current of the driving circuit.

S212, adjusting the third correction current value A1' or the second correction current value A" current value according to the operating current.

S213, reading the vibration amplitude of the engine.

S214, judging whether the vibration damping effect meets the condition according to the vibration amplitude of the engine. If yes, the vibration and noise reduction of the communication cycle is ended; if not, step S215 is performed.

S215, correcting the adjusted current value according to the vibration damping effect.

In the above embodiment, the signal existing in the automobile such as the crank sensor, the ignition coil signal, the acceleration sensor, and the vehicle speed sensor is used as the input signal of the vibration damping control, and the signal acquisition is more convenient and effective. Moreover, the effective timing of the vibration reduction and noise reduction control is directly obtained by using the ignition coil signal, so that the action time of the vibration reduction control is more accurate, and the vibration damping effect is more effective. At the same time, the operating current of the driving circuit is taken as the input signal, the target current value is actively adjusted, and the signal of the acceleration sensor is used as a feedback signal, and the target current value is closed-loop adjusted, so that the signal processing is more strict and effective, so that the signal can be better The vibration and noise reduction control is realized to achieve the effects of attenuating vibration and reducing noise, and improving user comfort. Moreover, the entire control makes full use of the communication time with the vehicle controller, which effectively reduces the calculation time after communication, and makes the control more rapid.

In summary, according to the active vibration control method of the hybrid vehicle according to the embodiment of the present application, when the engine of the hybrid vehicle is working, it is determined whether the hybrid vehicle is in a driving boom condition according to the acceleration sensor signal and the crank sensor signal. Yes, the engine speed and vibration period are calculated based on the crankshaft sensor signal, and the vibration amplitude of the engine is calculated based on the acceleration sensor signal, and the target current value is calculated according to the engine speed, the vibration period, and the vibration amplitude. At the same time, the vehicle speed sensor signal of the hybrid vehicle is obtained. Then, the target current value is corrected based on the vehicle speed sensor signal of the hybrid vehicle and the rotational speed of the engine to obtain a first corrected current value. Finally, the ignition coil signal of the engine is obtained, and when the engine is in the ignition state, the driving signal with the working time is output to the driving circuit according to the first corrected current value and the ignition coil signal, and the driving circuit outputs the working to the actuator according to the driving signal. Current, active vibration control of hybrid vehicles. Therefore, the active vibration reduction control of the vehicle under driving and roaring conditions is realized, and the time is effective, and the effective moment of vibration reduction and noise reduction is directly obtained by using the ignition coil signal, so that the action time of the vibration reduction control is more accurate, and the vibration damping effect is obtained. More effective.

FIG. 5 is a block schematic diagram of an active vibration damping control apparatus of a hybrid vehicle according to an embodiment of the present application. As shown in FIG. 5, the active vibration damping control device of the hybrid vehicle includes: a first acquiring module 11, a first determining module 12, a vibration period computing module 13, a vibration state estimating module 14, a target current computing module 15, and a master control The module 16, the first current correction module 17, the second acquisition module 18, the second determination module 19, the drive control module 20, and the drive circuit 21.

The first obtaining module 11 is configured to acquire an acceleration sensor signal and a crank sensor signal of the hybrid vehicle when the engine of the hybrid vehicle is in operation; and the first determining module 12 is configured to determine, according to the acceleration sensor signal and the crank sensor signal, whether the hybrid vehicle is The vibration period calculation module 13 is configured to calculate the engine speed and the vibration period according to the crank sensor signal when the hybrid vehicle is in the driving boom condition, and calculate the vibration amplitude of the engine according to the acceleration sensor signal; the vibration state estimation module 14 is for estimating the vibration state of the engine according to the engine speed, the vibration period, and the vibration amplitude; the target current calculation module 15 is configured to calculate the target current value according to the vibration state of the engine. The main control module 16 is configured to acquire the vehicle speed sensor signal of the hybrid vehicle when the first determining module 12 determines whether the hybrid vehicle is in a driving roaming condition. The first current correction module 17 is configured to correct the target current value according to the vehicle speed sensor signal of the hybrid vehicle and the rotation speed of the engine to obtain a first correction current value; and the second acquisition module 18 is configured to acquire an ignition coil signal of the engine; The second judging module 19 is configured to determine whether the engine is in an ignition state according to an ignition coil signal of the engine; and the driving control module 20 is configured to output a working moment according to the first modified current value and the ignition coil signal of the engine when the engine is in an ignition state. The driving signal is sent to the driving circuit 21, and the driving circuit 21 outputs an operating current with an active time to the actuator 22 according to the driving signal, so that the actuator 22 operates according to the operating current with the active time to actively reduce the hybrid vehicle. Vibration control.

According to an embodiment of the present application, the main control module 16 is further configured to confirm the current communication cycle by communicating with the vehicle controller of the hybrid vehicle when the first determination module 12 determines whether the hybrid vehicle is in a driving boom condition. Whether the current working condition of the hybrid vehicle is a roaming condition.

According to an embodiment of the present application, the second determining module 19 is further configured to perform timing by a timer when determining that the engine is not in an ignition state according to an ignition coil signal of the engine, and when the timing time reaches a preset time, if the engine is still If it is not in the ignition state, it is returned to determine whether the engine of the hybrid vehicle is working by the third judging module (not specifically shown in the drawing).

According to an embodiment of the present application, as shown in FIG. 6, the active vibration damping control device of the hybrid vehicle further includes: a current detecting module 23 and a target current correcting module 24, and the current detecting module 23 is configured to detect the driving circuit 21. The output current is used to obtain the operating temperature of the actuator 22; the target current correction module 24 is configured to adjust the first corrected current value according to the operating temperature of the actuator 22.

According to an embodiment of the present application, as shown in FIG. 6, the active vibration damping control apparatus of the hybrid vehicle further includes: a fourth determining module 25, wherein the fourth determining module 25 is configured to determine the hybrid vehicle according to the vibration amplitude of the engine. Whether the current vibration value is greater than a preset vibration threshold, and correcting the first correction current value by the target current correction module 24 to obtain a second current correction value when the current vibration value of the hybrid vehicle is greater than the preset vibration threshold The actuator 22 adjusts the dynamic stiffness of the active suspension system of the hybrid vehicle according to the second corrected current value to perform active vibration damping control on the hybrid vehicle.

According to an embodiment of the present application, when the main control module 16 communicates with the vehicle controller of the hybrid vehicle in the next communication cycle to confirm that the current working condition of the hybrid vehicle is still a driving roaming condition, the fifth judgment is passed. The module (not specifically shown in the figure) determines whether the acquired vehicle speed sensor signal and the engine speed change, wherein if a change occurs, the first current correction module 17 compares the target speed according to the changed vehicle speed sensor signal and the engine speed. The value is corrected to obtain a third corrected current value, so that the drive control module 20 outputs a drive signal with the working time to the drive circuit 21 according to the third corrected current value and the ignition coil signal of the engine when the engine is in the ignition state; if not occurs; The change is maintained by the target current correction module 24 to maintain the output current to the actuator 22.

It should be noted that, in the details not disclosed in the active vibration damping control device of the hybrid vehicle of the embodiment of the present application, please refer to the details disclosed in the active vibration damping control method of the hybrid vehicle of the embodiment of the present application. Let me repeat.

According to the active vibration damping control device of the hybrid vehicle according to the embodiment of the present application, when the engine of the hybrid vehicle is working, it is determined whether the hybrid vehicle is in a driving boom condition according to the acceleration sensor signal and the crank sensor signal, and if so, according to the crankshaft The sensor signal calculates the engine speed and vibration period, and calculates the vibration amplitude of the engine based on the acceleration sensor signal, and then calculates the target current value according to the engine speed, the vibration period, and the vibration amplitude. At the same time, the vehicle speed sensor signal of the hybrid vehicle is obtained. Then, the target current value is corrected based on the vehicle speed sensor signal of the hybrid vehicle and the engine speed to obtain a first corrected current value. Finally, the ignition coil signal of the engine is obtained, and when the engine is in the ignition state, the driving signal with the working time is output to the driving circuit according to the first corrected current value and the ignition coil signal, and the driving circuit outputs the working to the actuator according to the driving signal. Current, active vibration control of hybrid vehicles. Therefore, the active vibration reduction control of the vehicle under driving and roaring conditions is realized, and the time is effective, and the effective moment of vibration reduction and noise reduction is directly obtained by using the ignition coil signal, so that the action time of the vibration reduction control is more accurate, and the vibration damping effect is obtained. More effective.

7 is a block schematic diagram of a hybrid vehicle in accordance with an embodiment of the present application. As shown in FIG. 7, the automobile 1000 includes the above-described active vibration damping control device 100 of a hybrid vehicle.

According to the hybrid vehicle of the embodiment of the present application, the active vibration damping control device of the hybrid vehicle described above can realize the active vibration damping control of the vehicle under the driving and roaring condition, has high timeliness, and directly uses the ignition coil signal. Obtaining the effective moment of vibration and noise reduction makes the action time of the vibration reduction control more accurate and the vibration damping effect more effective.

In the description of the present application, it is to be understood that the terms "center", "longitudinal", "transverse", "length", "width", "thickness", "upper", "lower", "front", " After, "Left", "Right", "Vertical", "Horizontal", "Top", "Bottom", "Inside", "Outside", "Clockwise", "Counterclockwise", "Axial", The orientation or positional relationship of the indications of "radial", "circumferential", etc., is based on the orientation or positional relationship shown in the drawings, and is merely for convenience of description of the present application and simplified description, and does not indicate or imply the indicated device or component. It must be constructed and operated in a particular orientation, and is therefore not to be construed as limiting.

Moreover, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, features defining "first" and "second" may include at least one of the features, either explicitly or implicitly. In the description of the present application, the meaning of "a plurality" is at least two, such as two, three, etc., unless specifically defined otherwise.

In the present application, the terms "installation", "connected", "connected", "fixed" and the like shall be understood broadly, and may be either a fixed connection or a detachable connection, unless otherwise explicitly stated and defined. , or integrated; can be mechanical or electrical connection; can be directly connected, or indirectly connected through an intermediate medium, can be the internal communication of two elements or the interaction of two elements, unless otherwise specified Limited. For those skilled in the art, the specific meanings of the above terms in the present application can be understood on a case-by-case basis.

In the present application, the first feature "on" or "below" the second feature may be the direct contact of the first and second features, or the first and second features are indirectly through the intermediate medium, unless otherwise explicitly stated and defined. contact. Moreover, the first feature "above", "above" and "above" the second feature may be that the first feature is directly above or above the second feature, or merely that the first feature level is higher than the second feature. The first feature "below", "below" and "below" the second feature may be that the first feature is directly below or obliquely below the second feature, or merely that the first feature level is less than the second feature.

In the description of the present specification, the description with reference to the terms "one embodiment", "some embodiments", "example", "specific example", or "some examples" and the like means a specific feature described in connection with the embodiment or example. A structure, material or feature is included in at least one embodiment or example of the application. In the present specification, the schematic representation of the above terms is not necessarily directed to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in a suitable manner in any one or more embodiments or examples. In addition, various embodiments or examples described in the specification and features of various embodiments or examples may be combined and combined without departing from the scope of the invention.

While the embodiments of the present application have been shown and described above, it is understood that the above-described embodiments are illustrative and are not to be construed as limiting the scope of the present application. The embodiments are subject to variations, modifications, substitutions and variations.

Claims (13)

1. An active vibration damping control method for a hybrid vehicle, characterized in that the hybrid vehicle comprises an active suspension system, the method comprising the following steps:

   The controller of the active suspension system acquires an acceleration sensor signal and a crank sensor signal of the hybrid vehicle, and determines the hybrid vehicle based on the acceleration sensor signal and the crank sensor signal when the engine of the hybrid vehicle is operating Whether it is in a roaring situation;

   If the hybrid vehicle is in a driving booming condition, the controller of the active suspension system calculates a rotational speed and a vibration period of the engine based on the crank sensor signal, and calculates the engine based on the acceleration sensor signal a vibration amplitude, and estimating a vibration state of the engine according to the engine speed, a vibration period, and a vibration amplitude, and calculating a target current value according to the vibration state and the vibration amplitude of the engine;

   The controller of the active suspension system acquires a vehicle speed sensor signal of the hybrid vehicle when determining that the hybrid vehicle is in a driving booming condition according to the acceleration sensor signal and the crank sensor signal;

   The controller of the active suspension system corrects the target current value according to a vehicle speed sensor signal of the hybrid vehicle and a rotational speed of the engine to obtain a first corrected current value;

   a controller of the active suspension system acquires an ignition coil signal of the engine, and determines, according to an ignition coil signal of the engine, that the engine is in an ignition state, according to the first corrected current value and ignition of the engine The coil signal outputs a drive circuit with a drive signal at a working time to an active suspension system that operates an actuator that drives the active suspension system;

   The driving circuit outputs an operating current with an active time to the actuator according to the driving signal, and the actuator operates according to the working current with an active time to actively activate the hybrid vehicle Vibration reduction control.
2. The active vibration damping control method for a hybrid vehicle according to claim 1, wherein said active suspension is determined when said hybrid vehicle is in a driving boom condition based on said acceleration sensor signal and said crank sensor signal The placement system also communicates with the vehicle controller of the hybrid vehicle to confirm whether the current operating condition of the hybrid vehicle during the current communication cycle is the driving booming condition.
3. The active vibration damping control method for a hybrid vehicle according to claim 1 or 2, wherein when it is judged that the engine is not in an ignition state based on an ignition coil signal of the engine, timing is also performed by a timer, and When the chronograph time reaches the preset time, if the engine is still not in the ignition state, it is returned to determine whether the engine of the hybrid vehicle is working.
4. The active vibration damping control method for a hybrid vehicle according to any one of claims 1 to 3, further comprising:

   Detecting an output current of the driving circuit to obtain an operating temperature of the actuator;

   The first correction current value is adjusted according to an operating temperature of the actuator.
5. The active vibration damping control method for a hybrid vehicle according to any one of claims 1 to 4, further comprising:

   Determining, according to the vibration amplitude of the engine, whether a current vibration value of the hybrid vehicle is greater than a preset vibration threshold;

   If the current vibration value of the hybrid vehicle is greater than a preset vibration threshold, performing a second correction on the first correction current value to obtain a second correction current value, so that the actuator is based on the second correction current The value adjusts the dynamic stiffness of the active suspension system of the hybrid vehicle to perform active vibration damping control of the hybrid vehicle.
6. An active vibration damping control method for a hybrid vehicle according to any one of claims 2 to 5, wherein said active suspension system passes through a vehicle controller of said hybrid vehicle in a next communication cycle When it is determined that the current operating condition of the hybrid vehicle is still the driving booming condition, determining whether the acquired vehicle speed sensor signal and the engine speed change, wherein

   If a change occurs, correcting the target current value according to the changed vehicle speed sensor signal and the engine speed to obtain a third correction current value, according to the third when the engine is in an ignition state Correcting a current value and an ignition coil signal of the engine to output a driving signal with a working time to the driving circuit;

   If no change has occurred, the operating current output to the actuator is kept constant.
7. An active vibration damping control device for a hybrid vehicle, comprising:

   a first acquisition module, configured to acquire an acceleration sensor signal and a crank sensor signal of the hybrid vehicle when the engine of the hybrid vehicle is in operation;

   a first determining module, configured to determine, according to the acceleration sensor signal and the crank sensor signal, whether the hybrid vehicle is in a driving roaming condition;

   a vibration period calculation module, configured to calculate a rotation speed and a vibration period of the engine according to the crank sensor signal when the hybrid vehicle is in a driving boom condition, and calculate a calculation according to the acceleration sensor signal The vibration amplitude of the engine;

   a vibration state estimation module, configured to estimate a vibration state of the engine according to a rotation speed, a vibration period, and a vibration amplitude of the engine;

   a target current calculation module, wherein the target current calculation module is configured to calculate a target current value according to the vibration state of the engine;

   a main control module, configured to acquire a vehicle speed sensor signal of the hybrid vehicle when the first determining module determines whether the hybrid vehicle is in a driving roaming condition;

   a first current correction module, configured to correct the target current value according to a vehicle speed sensor signal of the hybrid vehicle and a rotation speed of the engine to obtain a first correction current value;

   a second acquisition module, configured to acquire an ignition coil signal of the engine;

   a second determining module, configured to determine, according to an ignition coil signal of the engine, whether the engine is in an ignition state;

   Driving a control module and a driving circuit, the driving control module is configured to output a driving signal with a working time to the driving according to the first correction current value and the ignition coil signal of the engine when the engine is in an ignition state a circuit, the drive circuit outputs an operating current with an active time to the actuator according to the driving signal, so that the actuator operates according to the working current with a working time to perform the hybrid vehicle Active damping control.
8. The active vibration damping control device for a hybrid vehicle according to claim 7, wherein the main control module is further configured to: when the first determining module determines whether the hybrid vehicle is in a driving booming condition, Communicating with the vehicle controller of the hybrid vehicle to confirm whether the current operating condition of the hybrid vehicle during the current communication cycle is the driving booming condition.
9. The active vibration damping control apparatus for a hybrid vehicle according to claim 7 or 8, wherein the second determining module is further configured to determine that the engine is not in an ignition state according to an ignition coil signal of the engine And counting by the timer, and when the timing time reaches the preset time, if the engine is still not in the ignition state, returning to the third determination module to determine whether the engine of the hybrid vehicle is working.
10. The active vibration damping control apparatus for a hybrid vehicle according to any one of claims 7-9, further comprising:

    a current detecting module, configured to detect an output current of the driving circuit to obtain an operating temperature of the actuator;

    a target current correction module, wherein the target current correction module is configured to adjust the first correction current value according to an operating temperature of the actuator.
11. The active vibration damping control apparatus for a hybrid vehicle according to any one of claims 7 to 10, further comprising:

    a fourth determining module, configured to determine, according to the vibration amplitude of the engine, whether a current vibration value of the hybrid vehicle is greater than a preset vibration threshold, and a current vibration value of the hybrid vehicle is greater than a pre- The first correction current value is corrected by the target current correction module to obtain a second current correction value when the vibration threshold is set, so that the actuator adjusts the hybrid vehicle according to the second correction current value. The dynamic stiffness of the active suspension system is used to actively control the hybrid vehicle.
12. An active vibration damping control apparatus for a hybrid vehicle according to any one of claims 7-11, wherein when said main control module passes through a vehicle controller of said hybrid vehicle in a next communication cycle When it is confirmed that the current operating condition of the hybrid vehicle is still in the driving booming condition, the fifth determining module determines whether the acquired vehicle speed sensor signal and the engine speed change, wherein

    If the change occurs, the first current correction module corrects the target current value according to the changed vehicle speed sensor signal and the engine speed to obtain a third correction current value, so that the drive control module is Outputting a driving signal with a working time to the driving circuit according to the third modified current value and the ignition coil signal of the engine when the engine is in an ignition state;

    If no change has occurred, the operating current of the output to the actuator is kept constant by the target current correction module.
13. A hybrid vehicle characterized by comprising an active vibration damping control device for a hybrid vehicle according to any one of claims 7-12.

Images