JP3374752B2 - Drive system vibration suppression device for hybrid vehicle - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for suppressing vibration of a drive system such as a transmission and a drive shaft in a hybrid vehicle, and more particularly to a damper or the like between an internal combustion engine, which is one of the power sources, and the drive system. The present invention relates to a vibration damping device for a hybrid vehicle in which the elastic damping mechanism is interposed.

[0002]

2. Description of the Related Art A hybrid vehicle is a vehicle developed for the purpose of improving fuel consumption and exhaust gas, and generally includes an internal combustion engine such as a gasoline engine and an electric motor as power sources. The internal combustion engine is operated so that the fuel consumption and exhaust gas are the best, and is operated when a driving force that cannot be obtained by an electric motor is required, and in a situation that is disadvantageous to the operation of the internal combustion engine when starting, It is controlled to obtain driving force by an electric motor.

Of these power sources, the electric motor is one that continuously rotates, and therefore does not itself become a source of vibration or noise. On the other hand, the internal combustion engine changes the linear motion associated with the explosion of the fuel into the rotational motion to output the torque, so that the vibration of the entire vehicle may occur due to the operation of the internal combustion engine. Therefore, in order to suppress the vibration due to the fluctuation of the torque output by the internal combustion engine, conventionally, a transmission mechanism such as a clutch provided on the output side of the internal combustion engine is internally provided with an elastic cushioning mechanism such as a damper. The torque fluctuation of the internal combustion engine is mitigated by. Therefore, the changing state of the torque on the input side with respect to the elastic cushioning mechanism and the changing state of the torque on the output side via the elastic cushioning mechanism are different.

By the way, a so-called parallel type hybrid vehicle is known as a hybrid vehicle having an internal combustion engine and an electric motor as power sources. This is a vehicle configured such that each of the internal combustion engine and the electric motor can be connected to a drive system including a transmission, a propeller shaft, and the like. In this type of hybrid vehicle, in order to avoid the influence of torque fluctuations of the internal combustion engine, it is common to connect an electric motor to the output side of an elastic damping mechanism provided on the output side of the internal combustion engine. That is, the electric motor is directly connected to the drive system. Therefore, the state of the torque in the drive system can be changed by the output torque of the electric motor.

A device that corrects the driving sensation caused by a change in the driving torque of the vehicle by utilizing such a function is disclosed in Japanese Patent Laid-Open No. 9-242242.
It is proposed by Japanese Patent Publication No. -106994. That is, the device described in this publication is a device configured to suppress a change in drive torque that accompanies starting of the internal combustion engine during traveling, and torque fluctuations when starting the internal combustion engine with the generator fixed. Is calculated, the output torque of the electric motor is corrected based on the calculation result, and the change in the drive torque of the vehicle is suppressed.

[0006]

In the conventional device described in the above publication, the torque used for starting the internal combustion engine causes a reduction in the driving torque for traveling, so that The output torque of the electric motor is controlled according to the torque for starting, and the drive torque is complemented. In that case, the output torque of the internal combustion engine fluctuates due to repeated explosive combustion, and since the torque fluctuation is changed by an elastic buffer mechanism such as a damper, the motor on the output side of the elastic buffer mechanism. If the torque of 1 is simply added, the torque fluctuation is promoted, and the vibration may become remarkable. At least the inventions described in the above publications do not consider the torque fluctuation of the internal combustion engine and the influence of the elastic shock absorbing mechanism such as the damper, so that the fluctuation of the driving torque and the vibration caused thereby may be large. .

The present invention has been made in view of the above circumstances, and provides an apparatus capable of effectively suppressing vibration in a drive system in a hybrid vehicle equipped with an internal combustion engine and an electric motor as power sources. The purpose is to do.

[0008]

In order to achieve the above-mentioned object, the invention of claim 1 is such that a drive system is connected to the output side of an internal combustion engine through an elastic buffer mechanism, and the drive system thereof is connected. in the vibration damping device of a drive system in a hybrid vehicle in which the motor is coupled to the operating condition detecting means for detecting an operating condition of the internal combustion engine, the vibration characteristics of the driver like on purpose the elastic buffer mechanism of the internal combustion engine detected In the drive system
A vibration state detecting means for detecting a vibration state of the drive system based on a gear ratio of a transmission included therein, and for suppressing the vibration of the drive system based on the detected vibration state of the drive system. And a damping torque calculating means for calculating the output torque of the electric motor.

Therefore, according to the first aspect of the invention, the operating state of the internal combustion engine, which directly causes the vibration, is detected, and the vibration state of the drive system is detected based on the detected operating state. In that case,
Speed ratio of the vibration characteristics and transmission by an elastic buffer mechanism being interposed vibration state of the drive system are taken into account is detected while the internal combustion engine and the drive system. And the output torque of the electric motor acting in the direction of suppressing the vibration of the drive system is
It is calculated based on the vibration state of the drive system. As a result, according to the invention of claim 1, even if the elastic damping mechanism is interposed between the internal combustion engine and the drive system, the vibration state of the drive system can be detected, and in accordance therewith, the electric motor Since the output torque is controlled, the vibration of the drive system can be effectively suppressed.

According to a second aspect of the present invention, there is provided a vibration damping device for a drive system in a hybrid vehicle in which a drive system is connected to an output side of an internal combustion engine via an elastic damping mechanism, and an electric motor is connected to the drive system. A driving state detecting means for detecting a driving state of the internal combustion engine and the electric motor; and a driving state of the detected internal combustion engine, a driving state of the electric motor, and the driving system.
The rotation variation estimating means for estimating the state of the rotation variation of the drive system based on the gear ratio in the transmission and the output torque of the electric motor for suppressing the estimated rotation variation of the drive system. And a damping torque calculation means.

Therefore, according to the invention of claim 2, torque is input to the drive system from the internal combustion engine and the electric motor,
Rotational fluctuations of the drive system occur depending on the input torque and the characteristics of the elastic damping mechanism. Since the electric motor is connected to the drive system, its drive state represents the rotational state of the drive system, and therefore the drive state of this electric motor and the internal combustion engine.
The rotation fluctuation state of the drive system is estimated based on the state and the gear ratio of the transmission . Since the rotational fluctuation state of the drive system can be estimated in this manner, the output torque of the electric motor is calculated based on the estimation result so as to suppress the vibration of the drive system. Therefore, according to the invention of claim 2, even if the elastic cushioning mechanism is interposed between the internal combustion engine and the drive system,
Since the vibration state of the drive system can be detected and the output torque of the electric motor is controlled accordingly, the vibration of the drive system can be effectively suppressed . Further, in claim 3
The invention is to drive the output side of an internal combustion engine through an elastic buffer mechanism.
The system is connected and the motor is connected to the drive system.
In the vibration damping device of the drive system in the hybrid vehicle,
An operating state detecting means for detecting the operating state of the internal combustion engine,
Based on the detected operating state of the internal combustion engine,
Output torque is transmitted to the drive system via the elastic buffer mechanism.
Vibration state detection for detecting the reached vibration state of the drive system
Based on the means and the detected vibration state of the drive system,
The output of the electric motor for suppressing the vibration of the drive system
A damping torque calculation means for calculating the torque is provided.
It is characterized by. Therefore, in the invention of claim 3,
The internal combustion engine operating condition, which is the direct cause of vibration.
The drive system vibration state is detected based on the
It In that case, an elastic buffer mechanism is provided between the internal combustion engine and the drive system.
Vibrations in the drive system due to the presence of
The state is different from the vibration state in the internal combustion engine.
However, the vibration state detection means determines the vibration state of the drive system.
To detect. Vibration characteristics and transmission by elastic damping mechanism
The transmission gear ratio is added to detect the vibration state of the drive system.
It And acts to suppress the vibration of the drive system
The output torque of the electric motor is calculated based on the vibration state of the drive system.
Will be issued. As a result, according to the invention of claim 3, the internal combustion engine
There is an elastic buffer mechanism between the function and the drive system.
However, the vibration state of the drive system can be detected and
The output torque of the motor is controlled according to this, so the drive
Vibration of the system can be effectively suppressed. And the contract
According to the invention of claim 4, an elastic buffer mechanism is provided on the output side of the internal combustion engine.
Drive system is connected, and an electric motor is connected to the drive system.
To the drive system vibration control system for hybrid vehicles
And detect the driving states of the internal combustion engine and the electric motor.
Drive state detection means, and the detected drive state of the internal combustion engine and
The output torque of the internal combustion engine based on the drive state of the electric motor
Before being transmitted to the drive system via the elastic damping mechanism
Rotational fluctuation estimating means for estimating the state of rotational fluctuation of the drive system
And for suppressing the estimated rotation fluctuation of the drive system,
Damping torque calculating means for calculating the output torque of the electric motor
It is characterized by having. Therefore contract
In the invention of claim 4, an internal combustion engine and an electric motor are provided for the drive system.
Torque is input from the input torque and elastic damping
The rotation of the drive system varies depending on the characteristics of the mechanism. So
Since the electric motor of is connected to the drive system, its drive state
Represents the rotation state of the drive system, and
Fluctuation of the drive system based on the drive state of the engine and the internal combustion engine
The state is estimated. In this way, the rotation fluctuation state of the drive system is estimated.
The drive system based on the estimation results.
The output torque of the motor is calculated to suppress the vibration of
It Therefore, according to the invention of claim 4, the internal combustion engine and the drive
Even if an elastic buffer mechanism is interposed between the dynamic system and
The vibration state of the drive system can be detected and
Since the output torque of the electric motor is controlled in accordance with
The movement can be effectively suppressed.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION Next, the present invention will be described based on a specific example shown in the drawings. First, a power train in a hybrid vehicle that is a target of the present invention will be described. FIG. 4 schematically shows a power train of a so-called parallel hybrid vehicle, in which an output shaft of an internal combustion engine (hereinafter, referred to as an engine) 1 is a damper 2 having an elastic cushioning mechanism.
Is connected to the torque synthesizing / distributing mechanism 3 via. Like the damper in the conventional vehicle clutch, the damper 2 has a configuration in which an elastic body (for example, a coil spring) that expands and contracts in the rotational direction is interposed between a relatively rotatable input side member and an output side member. The input side member is connected to the output shaft of the engine 1, and the output side member is connected to the torque synthesis / distribution mechanism 3.

The torque combining / distributing mechanism 3 is composed of a single pinion type planetary gear mechanism, and its ring gear 4 is connected to the output side member of the damper 2. Further, the sun gear 5 is connected to a rotor 7 of an electric motor (hereinafter referred to as a motor) 6. Further, a carrier 8 holding a pinion gear meshing with the ring gear 4 and the sun gear 5 is connected to a transmission 9. An integrated clutch 10 is provided between the carrier 8 and the ring gear 4.

The transmission 9 is basically of a construction capable of changing the rotational speed ratio between the input member and the output member. The continuously meshed stepped transmission and the transmission ratio are changed steplessly. It is possible to employ a continuously variable transmission that can be used. A drive gear 12 is connected to an output shaft 11 of the transmission 9, and a ring gear 14 of a differential 13 meshes with the drive gear 12. Then, the drive torque is transmitted from the differential 13 to the left and right drive wheels (not shown). Therefore, the transmission system of the power from the above torque combining / distributing mechanism 3 to the drive wheels via the transmission 9 and the differential 13 constitutes the drive system in the present invention.

The engine 1 is configured to electrically control the throttle opening, the ignition timing, the fuel injection amount, etc., and an electronic control unit (E
-ECU) 15 is provided. The motor 6 is, for example, an AC synchronous motor, and is connected to a battery 17 via an inverter 16. Also, the motor 6
Is configured to perform power running to output torque and regeneration to generate power. An electronic control unit (M-ECU) 18 is provided in connection with the inverter 16 for controlling the motor 6 in these operating states. Has been. Further, the transmission 9 is configured to electrically control hydraulic pressure to change a gear ratio by driving a synchronous coupling mechanism (synchronizer), a friction engagement device, or a sheave. Electronic control unit (T-ECU) 1 for
9 is provided. In addition, these electronic control units 1
5, 18 and 19 are connected to each other so that data communication is possible.

FIG. 5 is a collinear characteristic diagram of the torque combining / distributing mechanism 3 described above. When the integrated clutch 10 is engaged, the torque synthesizing / distributing mechanism 3 rotates as a whole, so that the sun gear 5, the carrier 8 and the ring gear 4 have the same rotational speed. In this state, if the motor 6 is controlled to be in the power running state and its rotation speed is increased,
The total number of rotations of the torque combining / distributing mechanism 3, that is, the transmission 9
If the motor 6 is regeneratively controlled, the input speed of the transmission 9 will decrease. Further, the integrated clutch 10 is released to release the torque synthesis / distribution mechanism 3.
If the differential operation is performed, the engine speed decreases as the motor speed increases, or the transmission 9
If the input rotation speed of (1) increases and the motor rotation speed decreases, the engine rotation speed increases or the input rotation speed of the transmission 9 decreases.

In the power train of the hybrid vehicle described above, the engine 1 and the motor 6 are connected to the drive system, so that the motor 6 outputs the torque for traveling and the regeneration during braking, and also the engine. The torque is output so as to suppress the torque fluctuation in the drive system due to the torque fluctuation of No. 1. The device of the present invention analyzes the vibration characteristic in the power train and calculates the output torque fluctuation of the motor on the assumption that the motor torque functions to suppress the vibration in the drive system.

FIG. 6 is a model diagram of the vibration characteristics of the power train described above, where TE is the Laplace transform of the engine torque fluctuation signal, TM is the Laplace transform of the motor output torque fluctuation signal, I1 is the moment of inertia of the engine 1, and I21. Is the input side inertia moment of the transmission 9, I22 is the output side inertia moment of the transmission 9, K1 is the elastic coefficient of the damper 2, and
K2 is the elastic coefficient after the transmission 9, C1 is the viscous damping coefficient at the damper 2, and C2 is the viscous damping coefficient after the transmission 9.

Therefore, the Laplace conversion of the engine torque fluctuation signal and the Laplace conversion of the motor output torque fluctuation signal are

[Formula 1] There is a relationship represented by the characteristic formula of.

Here,

[Formula 2] Is. In addition, s is a Laplace operator.

According to the equations 1 and 2, the motor output torque variation can be obtained by detecting the engine torque variation, and the motor output torque is controlled based on the result, so that the drive system Vibration can be prevented or suppressed by the output torque of the motor 6. Specifically, as shown in FIG. 1, the accelerator opening θ
And the ignition signal Ign is read (step 1). As the accelerator opening θ increases, the amount of fuel supplied to the engine 1 increases, and as a result, the engine output increases and the rotation speed increases, so that the number of times the ignition signal is output per unit time increases. The output state of the engine 1 can be known based on the accelerator opening θ and the ignition signal Ign.

The fluctuation of the engine torque is related to the rotational speed and the output torque, and the fluctuation amplitude is also determined according to the fluctuation of the engine torque.
Based on the ignition signal Ign and the ignition signal Ign, the fluctuation amplitude of the engine torque can be obtained. Specifically, the fluctuation amplitude value is obtained from the engine torque fluctuation map (step 2). Then, an engine torque fluctuation signal is derived based on the fluctuation amplitude value (step 3). Further, the gear ratio i set in the transmission 9 is read (step 4).

Since the Laplace transform of the engine torque fluctuation signal and the gear ratio i in the above equations 1 and 2 are variables, and other moments of inertia and elastic coefficients are constants determined mechanically, the engine torque is determined in step 3. By deriving the fluctuation signal and reading the gear ratio i in step 4, the Laplace transform TM of the motor output torque fluctuation signal can be obtained based on the above equations 1 and 2 (step 5). By inverse Laplace transforming the motor torque fluctuation signal thus obtained, a motor fluctuation signal along the time axis can be obtained, and the motor 6 is controlled based on the motor fluctuation signal (step 6). That is, the motor torque is controlled so as to suppress the vibration due to the fluctuation of the engine torque. Specifically, this control is executed by controlling the inverter 16 by the motor electronic control device 18 to drive the motor 6 or perform a regenerative operation.

[0024] Here will be described the relationship between the present invention and the specific examples, the above steps 1 Functions means, claim
1 and corresponds to the operating state detecting means of claim 3, also functionally means step 2, claims 1 and corresponds to a vibration <br/> dynamic state detector of claim 3, further Step 5 of the machine Noble hand
The step corresponds to the damping torque calculation means in claims 1 and 3 .

Therefore, according to the above-mentioned device of the present invention, even if the output torque of the engine 1 oscillates due to the combustion of fuel and this is transmitted to the drive system through the damper 2, the vibration of the drive system is Since the state is obtained by the above calculation and the motor torque is transmitted to the drive system so as to damp or cancel the vibration, the vibration in the drive system can be effectively prevented or suppressed. In particular, in the above device, since the motor torque is controlled based on the overall vibration characteristics including the damper, even if the vibration in the drive system is different from the engine torque fluctuation, the vibration in the drive system can be effectively prevented or Can be suppressed.

Next, another example of the present invention will be described. As described above, in the hybrid vehicle targeted by the present invention, the motor 6 is connected to the drive system that is connected to the engine 1 via the damper 2. Therefore, the state of vibration of the drive system driven by the engine torque via the damper 2 can be detected as torque fluctuation of the output shaft of the motor 6. Although not shown in particular, the motor 6 is generally equipped with a sensor capable of detecting the rotation state of a resolver or the like with high accuracy. Therefore, an existing sensor attached to the motor 6 is used to drive the motor 6. It is possible to detect the rotation angle and angular velocity of the. Therefore, in the device according to the present invention, the motor 6 can detect the rotation state and the vibration state of the drive system and control the motor 6 to suppress the vibration.

That is, the state of rotation x in the drive system is estimated based on the estimated angles ωE, ωM and the estimated angular velocities θE, θM of the outputs of the engine 1 and the motor 6.

[Formula 3]

If this is expressed in the differential form,

[Formula 4] Becomes Here, f (estimation error) is f (estimation error) = f (measured value-estimated value), and therefore f (estimation error) =-h1 (? M-? M ')-h2 (? M-
ωM ') can be obtained. Note that θM 'and ωM' are
The measured values, h1 and h2, are predetermined constants.

Therefore, the rotational state x of the drive system can be obtained by solving the above equation 4 in real time. Then, by setting TE to a known value, the correlation between the motor torque and the rotation state x of the drive system can be obtained. Therefore, the motor torque should be suppressed based on the rotation state of the drive system. You can obtain TM. For example, TE is calculated as TE = g1θE + g2θM + g3ωE + g4ωM (where g1, g2, g3, and g4 are constants),
Feedback control proportional to the rotation angle and the angular velocity is performed to set the motor torque so as to suppress the drive system signal.

If the above control example is shown by a flow chart,
It is as shown in FIG. That is, first, θM 'and ωM' are read to calculate f (estimation error) (step 1
1). Then, TE is calculated (step 12). Further, the gear ratio i is read (step 13). Then, the motor output torque is calculated from the motor output torque fluctuation signal TM based on these values and the equation 4 (step 1).
5).

In determining the motor torque, the feedback amount may be changed according to the operating states of the engine 1 and the motor 6. For example, when the angular velocity ωM of the motor 6 is less than or equal to a predetermined reference value, TE = g11 · θE + g12 · θM + g13 · ωE + g14 · ωM, and the angular velocity ωM of the motor 6 exceeds a predetermined reference value. If so, the motor output torque may be calculated as TE = g15θE + g16θM + g17ωE + g18ωM. Note that the above g11, g12, ... G18 are predetermined constants.

[0032] Here, to describe the relationship between the present invention and the above embodiment, the function means of the above steps 11,請
Corresponds to the drive motion state detecting means Motomeko 2 and claim 4, also the function means in step 12, claims 2 and
Corresponds to the fourth rotational fluctuation estimation means further <br/> function means in step 14 corresponds to the damping torque calculating means according to claim 2 and claim 4.

By the way, the power train system described above is
The amount of torsion of the damper may change depending on the engine torque and the motor torque, and the characteristics as a whole may change. Therefore, it is conceivable that the vibration characteristics of the entire system change as the motor torque is changed to suppress the vibration, and as a result, the entire system becomes unstable. In consideration of such instability of the control system, it is also possible to design a control device based on the H-infinity (H∞) control theory to suppress the drive system.

FIG. 3 is a block diagram schematically showing the control system of the above-mentioned power train.
To the drive shaft torque TDS, that is, the transfer function of the output torque TDS from the differential 13 is P
(s) and the drive shaft upper limit torque is W (s),

[Formula 5] Find the controller K (s) that is The method for that purpose is the same as the general H infinity controller design method. By using such a controller, the motor torque is controlled so as to suppress the vibration of the drive system, and as a result, the vibration of the drive system can be prevented or reduced.

In the above description, as an example of the elastic cushioning mechanism, the one in which the coil springs are arranged in the circumferential direction is shown, but the elastic cushioning mechanism mounted on the hybrid vehicle to which the present invention is directed. In essence, it suffices that it acts so as to reduce the change in the torque or the rotational speed. Further, the operating state of the internal combustion engine in the present invention,
In addition to the throttle opening and the ignition signal, the state may be indicated by other parameters related to the output torque such as the rotation speed, the cooling water temperature, and the intake air amount. Further, in the above-mentioned example, an example in which the engine torque fluctuation map is used to detect the vibration state of the drive system has been shown. However, when the vibration state of the drive system is detected based on the engine torque or the drive state of the internal combustion engine Alternatively, the vibration state of the drive system may be detected by another method such as calculating the vibration state without using the map. Further, in the above example, an example of a hybrid vehicle having a configuration in which a motor is connected to a drive system via a torque combining / distributing mechanism including a single pinion type planetary gear mechanism has been shown, but the configuration of the hybrid vehicle to which the present invention is applied is However, the present invention is not limited to the above example.

[0036]

According to the present invention as described above, according to the present invention, even if the elastic buffer mechanism are interposed between the internal combustion engine and the drive system, vibration of the driving state and the elastic buffer mechanism for an internal combustion engine
Since the vibration state of the drive system is detected based on the dynamic characteristics and the gear ratio , and the output torque of the electric motor is controlled based on the detected vibration state, the vibration of the drive system can be effectively suppressed or prevented. .

[0037] According to the invention of claim 2, the preparative <br/> Torque and speed ratio of the motor thus detects the state of oscillation of the drive system, and controls the motor torque based on the detection result, Vibration of the drive system can be effectively suppressed or prevented. Especially in the invention of claim 2, the operation state of the electric motor
And because the vibration state of the drive system is detected based on the gear ratio, it is possible to detect the vibration state of the drive system by the sensor that is usually attached to the electric motor. There are practical effects such as the number of parts to be used can be reduced . Further claims
According to the invention of 3, the elastic cushion is provided between the internal combustion engine and the drive system.
Even if the mechanism is interposed, the vibration of the drive system after the elastic shock absorbing mechanism is
Dynamic state based on the drive state of the internal combustion engine, and
The output torque of the motor is controlled based on the vibration state detected by
Control, effectively suppress or prevent drive system vibration
can do. And according to the invention of claim 4,
The state of vibration of the drive system after the elastic shock absorber is monitored by the torque of the motor.
The motor torque based on the detection result.
Control the vibration of the drive system effectively.
Can be prevented. Particularly, in the invention of claim 4,
Detect the vibration state of the drive system based on the operating state of the motive
Therefore, it is usually driven by the sensor attached to the electric motor.
Since it becomes possible to detect the vibration state of the dynamic system,
Higher accuracy and fewer additional parts to install
There are practical effects such as being able to.

[Brief description of drawings]

FIG. 1 is a flow chart for explaining a control example implemented by the device of the present invention, in which a vibration state of a drive system is detected based on a drive state of an engine, and a vibration is controlled by a motor. It is a flow chart for explaining.

FIG. 2 is a flow chart for explaining another control example implemented by the device of the present invention, in which a vibration state of a drive system is detected based on a motor torque and a vibration is controlled by the motor. It is a flow chart for explaining.

FIG. 3 is a block diagram schematically showing a control system of a hybrid vehicle that is a target of the present invention.

FIG. 4 is a diagram schematically showing an example of a power train for a hybrid vehicle that is a target of the present invention.

FIG. 5 is a collinear characteristic diagram of the torque combining and distributing mechanism.

FIG. 6 is a model diagram of vibration characteristics of the power train shown in FIG.

[Explanation of symbols]

1 ... Engine, 2 ... Damper, 6 ... Motor, 9 ...
Transmission, 15 ... Electronic control device for engine, 18 ... Electronic control device for motor, 19 ... Electronic control device for transmission.

Front page continued (51) Int.Cl. ⁷ identification code FI F02D 29/02 F02D 29/02 D 29/06 29/06 G (58) Fields investigated (Int.Cl. ⁷ , DB name) B60K 6 / 02-6/04 B60L 11/02-11/14 F02D 29/02-29/06

Claims (4)

(57) [Claims] 1. A vibration damping device for a drive system in a hybrid vehicle, wherein a drive system is connected to an output side of the internal combustion engine via an elastic cushioning mechanism, and an electric motor is connected to the drive system, the operating state of the internal combustion engine. operating condition detecting means for detecting a vibration of the driving-shaped on purpose the elastic buffer mechanism of the internal combustion engine detected
A vibration state detection unit that detects a vibration state of the drive system based on dynamic characteristics and a gear ratio of a transmission included in the drive system, and a vibration state detection unit that detects the vibration state of the drive system. And a damping torque calculating means for calculating the output torque of the electric motor for suppressing the vibration of the driving system. 2. A vibration damping device for a drive system in a hybrid vehicle, wherein a drive system is connected to an output side of the internal combustion engine via an elastic cushioning mechanism, and an electric motor is connected to the drive system. driving state detecting means for detecting a driving state, the drive state of the detected internal combustion engine and an electric motor drive state before
Rotational fluctuation estimating means for estimating the state of rotational fluctuation of the drive system based on the speed ratio of the transmission included in the drive system, and output of the electric motor for suppressing the estimated rotational fluctuation of the drive system. A vibration damping device for a drive system in a hybrid vehicle, comprising: a vibration damping torque calculating means for calculating a torque. 3. An elastic buffer mechanism is provided on the output side of the internal combustion engine.
Drive system is connected, and the motor is connected to the drive system.
In the vibration damping device of the drive system in a hybrid vehicle
And an operating state detecting means for detecting the operating state of the internal combustion engine.
Based on the detected operating state of the internal combustion engine,
Output torque is transmitted to the drive system via the elastic buffer mechanism.
Vibration state detection for detecting the reached vibration state of the drive system
And its drive based on the detected vibration state of the drive system.
Calculate the output torque of the electric motor of the order was to suppress the vibration of the system
And a damping torque calculation means for outputting
Drive system damping device for hybrid vehicles. 4. An elastic buffer mechanism is provided on the output side of the internal combustion engine.
Drive system is connected, and the motor is connected to the drive system.
In the vibration damping device of the drive system in a hybrid vehicle
Te, drive like for detecting the driving state of the internal combustion engine and an electric motor
State detection means, and the detected driving state of the internal combustion engine and the driving state of the electric motor
Based on the output torque of the internal combustion engine,
Of rotational fluctuation of the drive system transmitted to the drive system via
Rotation fluctuation estimating means for estimating the state, and the electric motor for suppressing the estimated rotation fluctuation of the drive system.
And a damping torque calculation means for calculating the output torque of the machine
Drive in hybrid vehicle characterized by
Vibration control system.