JP2005102365A - Regenerative control method of motor generator when requesting deceleration of hybrid vehicle - Google Patents

Abstract

An object of the present invention is to achieve efficient energy recovery by regeneration while maintaining a feeling of deceleration required by a driver.
The vehicle speed and the motor generator are set so that the regeneration amount by the motor generator increases at a lower speed based on the shift speed of the multimode manual transmission (MMT) at the time of deceleration request and fuel cut (Yes at Step S10, Yes at Step S11). The target regeneration amount is calculated in consideration of the accelerator opening (step S12), the motor generator is subjected to regeneration control so as to obtain the target regeneration amount, and a pseudo engine brake feeling is generated (step S13). In this case, the actual shift speed of the MMT is not shifted. On the other hand, when the fuel is not cut during deceleration (No at Step S11), the regeneration control of the motor generator is prohibited (Step S14).
[Selection] Figure 1

Description

  The present invention relates to a motor generator regeneration control method when a hybrid vehicle is requested to decelerate. More specifically, the present invention relates to a hybrid vehicle decelerating request that can realize efficient energy recovery by regeneration while maintaining the decelerating feeling required by the driver. The present invention relates to a motor generator regenerative control method.

  In recent years, hybrid vehicles have been developed from the viewpoint of conservation of the global environment and resource saving. The hybrid vehicle includes an engine, a step-variable transmission capable of automatic transmission (hereinafter referred to as MMT (multi-mode manual transmission)), a clutch that connects and disconnects power transmission between the engine and the MMT, and the engine. A motor generator that assists in power generation by output or engine output by battery power, and is configured to be driven by either the engine or the motor generator.

  The motor generator is configured to be capable of taking two operating states: a power running mode that functions as a motor that is a travel drive source, and a regenerative mode that functions as a generator. In the hybrid vehicle configured as described above, the MMT is automatically shifted at the time of shifting, and the clutch is automatically engaged and disengaged. The MMT can be shifted (manual shift) by manually operating the shift lever.

  The driving force by the engine and the driving force by the motor generator are properly used according to the running state, and are controlled so as to increase the driving efficiency. For example, the engine efficiency is poor at low speed (low rotation) or low load such as when starting, so the engine is stopped and the vehicle is driven only by the motor (EV traveling). Is controlled to drive.

  In the hybrid vehicle configured as described above, a technique has been proposed in which the generation of a feeling of deceleration accompanying the disconnection of the clutch is avoided by using a motor generator (electric motor) (see, for example, Patent Document 1).

  As another related technology, if the engine speed is high during braking, the engine brake will act greatly, and the regenerative power obtained by regenerative braking will be reduced accordingly, so the shifting point will be moved to the low speed side during braking. A technique for increasing the regenerative power by lowering the rotational speed of the entire engine has been proposed (see, for example, Patent Document 2).

  In such a manual shift mode in a conventional hybrid vehicle, the driver shifts down by operating a shift lever when descending a slope or immediately before entering a corner to apply a predetermined engine brake.

JP 2000-105240 A Japanese Patent Laid-Open No. 9-9415

However, in the above-described prior art, the engine brake can be simply increased, but the regenerative function of the motor generator at the time of braking, which is one of the hybrid functions, cannot be effectively used, and the energy recovery amount is increased. There was a problem that it was difficult. That is, although the driver can sufficiently obtain the feeling of deceleration required by the engine brake, the amount of energy regeneration is reduced due to the friction loss of the engine, and it is difficult to recover more energy.

  The present invention has been made in view of the above, and provides a motor generator regeneration control method at the time of deceleration request of a hybrid vehicle capable of realizing efficient energy recovery by regeneration while maintaining the deceleration feeling required by the driver. The purpose is to provide.

  In order to solve the above-described problems and achieve the object, a motor generator regeneration control method at the time of a deceleration request for a hybrid vehicle according to claim 1 of the present invention includes an engine, a stepped transmission capable of automatic transmission, A clutch that performs contact and separation of power transmission between the engine and the stepped transmission; and a motor generator that assists the engine output by power generation by the engine output or battery power, and whichever of the engine and the motor generator In the regenerative control method of the motor generator when the hybrid vehicle configured to be driven by either of them is requested to decelerate, the motor generator is set to a lower speed step based on the shift step of the stepped transmission at the time of the deceleration request and the fuel cut. Calculate the target regeneration amount so that the regeneration amount by Is characterized in carrying out the regeneration control of the motor generator so that the amount of regeneration.

  According to a second aspect of the present invention, there is provided a regeneration control method for a motor generator when a hybrid vehicle is requested to decelerate. In the invention according to the first aspect, the motor generator has a lower instruction shift stage of the stepped transmission. Only the regenerative amount is increased, and the actual gear stage of the stepped transmission is not shifted.

  According to a third aspect of the present invention, there is provided the motor generator regeneration control method according to the third aspect of the present invention, wherein the target regeneration amount of the motor generator includes the vehicle speed and the accelerator opening. It is calculated as follows.

  According to a fourth aspect of the present invention, there is provided a regeneration control method for a motor generator when requesting deceleration of a hybrid vehicle. In the invention according to the first aspect, when the fuel is not cut during the deceleration, the regeneration control of the motor generator is performed. It is characterized by prohibiting.

  According to a fifth aspect of the present invention, there is provided a motor generator regenerative control method according to claim 5 of the present invention, wherein the clutch is disengaged during the deceleration. The regenerative amount of the motor generator is increased or decreased so as to give a feeling of deceleration immediately before the cutting control.

  According to the regenerative control method for a motor generator when requesting deceleration of a hybrid vehicle according to the present invention (Claim 1), the lower the shift stage, the lower the shift stage based on the shift stage when requesting deceleration such as downhill. Since the regeneration amount is increased and the pseudo engine braking feeling is increased, the deceleration feeling and the regeneration amount are increased respectively. As a result, efficient energy recovery by regeneration can be realized while maintaining the feeling of deceleration required by the driver.

Further, according to the regeneration control method for a motor generator at the time of deceleration request of the hybrid vehicle according to the present invention (Claim 2), only the instructed shift speed is instructed to the low speed without changing the actual shift speed of the MMT, and the actual shift The stage is shifted by a normal shift line based on the accelerator opening and the vehicle speed. As a result, the engine brake is not generated, and the deceleration feeling requested by the driver can be ensured only by the pseudo engine brake feeling by the motor generator, so that the regeneration amount can be further increased while maintaining drivability. it can.

  Further, according to the motor generator regeneration control method (claim 3) at the time of deceleration request of the hybrid vehicle according to the present invention, the target regeneration amount of the motor generator can be calculated with high accuracy, and the pseudo-generation generated based on the target regeneration amount can be calculated. This makes it possible to make the engine brake feel closer to the deceleration required by the driver.

  According to the motor generator regenerative control method when claiming deceleration of the hybrid vehicle according to the present invention (Claim 4), when the engine brake does not need to be applied positively, for example, when overtaking acceleration is performed, the motor Generator regeneration can be prohibited. Furthermore, fuel efficiency can be improved by prioritizing engine fuel cut before increasing the vehicle deceleration feeling by the motor generator.

  According to the motor generator regeneration control method (claim 5) at the time of deceleration request of the hybrid vehicle according to the present invention, the engine generator is artificially braked by increasing / decreasing the regeneration amount of the motor generator during deceleration and shifting. A reduction in feeling of deceleration (feeling of torque loss) due to clutch disengagement control at the time of deceleration can be recovered by the motor generator. As a result, a continuous engine braking feeling can be maintained regardless of shift changes, drivability can be improved, and energy can be recovered.

  Hereinafter, an embodiment of a motor generator regeneration control method at the time of a deceleration request of a hybrid vehicle according to the present invention will be described in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

  First, a schematic configuration of a diesel hybrid vehicle that is a front wheel drive vehicle (FF vehicle) will be described with reference to FIG. Here, FIG. 2 is a schematic diagram showing a schematic configuration of the diesel hybrid vehicle. A diesel hybrid vehicle (hybrid vehicle) 10 is provided with a diesel engine (engine) 11 as a travel drive source at the front of the vehicle.

  In the diesel engine 11, the fuel injection amount is controlled by a common rail fuel injection system (not shown). The diesel engine 11 includes a turbocharger (not shown). Further, the exhaust passage of the diesel engine 11 is provided with an oxidation catalyst (not shown) that oxidizes hydrocarbons (HC) and carbon monoxide (CO) in the exhaust.

  The driving force generated by the diesel engine 11 is transmitted to a front wheel 13 as a main driving wheel via an MMT (automatic variable stepped transmission) 12 and a drive shaft 14.

  The MMT 12 electrically automatically controls the shift operation of the shift stage using an actuator in accordance with the traveling state. That is, no torque converter is mounted.

The MMT 12 can be shifted (manual shift) by manually operating a shift lever (not shown). In the control of the motor generator 17 for generating an engine brake feeling, which will be described later, this manual shift operation (downshift) is assumed.

  The diesel engine 11 is configured such that its fuel injection amount, intake air amount, and the like are controlled in order to output the requested engine torque commanded from the MMT 12. In addition, the diesel hybrid vehicle 10 is provided with a clutch 12a that performs contact / separation of power transmission between the diesel engine 11 and the MMT 12, so that the contact / separation operation is automatically and electrically controlled by an actuator according to the traveling state. It has become.

  Also, a propeller shaft 16 is connected to the transfer 15 that transmits the driving force separately, and a motor generator (MG) 17 integrated with a driving gear device (gear train) is connected to the end of the transfer shaft 15. The rear wheel 18 is configured to be rotated only by the front wheel 13 that is a driving wheel.

  The motor generator 17 is connected via an inverter 19 to a battery 20 that is a chargeable / dischargeable secondary battery. Further, the motor generator 17 is configured to be able to take two operation states, a power running operation mode that functions as a motor that is a travel drive source, and a regenerative operation mode that functions as a generator.

  For example, the motor generator 17 receives power supplied from the battery 20 in the power running operation mode and generates power for driving the drive shaft 14 via the propeller shaft 16. In the regenerative operation mode, the motor generator 17 converts the driving force transmitted from the diesel engine 11 or the drive shaft 14 via the propeller shaft 16 into electric power, and charges the battery 20. Whether the motor generator 17 is operated in the power running mode or the regenerative operation mode is determined in consideration of the state of charge (SOC) of the battery 20.

  The diesel hybrid vehicle 10 configured as described above is basically controlled as follows together with each component by an electronic control unit (ECU) (not shown), and can travel in various states.

  For example, in a relatively low speed state in which the diesel hybrid vehicle 10 starts traveling, the vehicle travels (EV traveling) by powering the motor generator 17 while the diesel engine 11 is stopped. During EV travel, the diesel engine 11 is stopped and the clutch 12a is disengaged.

  Then, when the diesel hybrid vehicle 10 reaches a predetermined speed or load after the start of traveling, the diesel engine 11 is cranked and started using a starter (not shown), and the operation is shifted to the operation using the diesel engine 11.

  During steady operation, the diesel engine 11 is normally operated so as to generate an output substantially equal to the required power of the drive shaft 14. At this time, almost all of the output of the diesel engine 11 is transmitted to the drive shaft 14.

  On the other hand, when the state of charge SOC of the battery 20 has dropped below a predetermined reference value, the diesel engine 11 is operated with an output that exceeds the required power of the drive shaft 14, and a part of the surplus power is a motor. It is regenerated as electric power by the generator 17 and used for charging the battery 20. Further, when the output torque of the diesel engine 11 is insufficient, the insufficient torque is assisted by driving the motor generator 17, and the necessary torque can be ensured.

  The diesel hybrid vehicle 10 is also subjected to so-called eco-run (economy & ecology running) control in order to save fuel and reduce exhaust emissions. That is, for example, when the diesel hybrid vehicle 10 stops due to a signal waiting at an intersection or the like, the diesel engine 11 is automatically stopped under a predetermined stop condition, and then the predetermined restart condition (for example, the accelerator pedal is depressed). At a time), the diesel engine 11 is also restarted.

  The above is the basic configuration and basic control operation of the diesel hybrid vehicle 10 according to the present invention.

  Next, a regenerative control method of the motor generator 17 at the time of a deceleration request, which is a main part of the present invention, will be described with reference to FIG. The following regenerative control is performed on the assumption that the state of charge SOC is not a fully charged state in order to protect the battery 20.

  Here, FIG. 1 is a flowchart showing a regeneration control method for the motor generator 17 at the time of a deceleration request according to Embodiment 1 of the present invention. In the figure, the motor generator 17 is abbreviated as MG.

  In the manual shift mode, the driver performs a downshift operation by a manual shift lever operation, for example, on a downhill where the engine brake is to be applied or immediately before entering the corner. Therefore, first, by detecting this downshift operation, it is determined whether or not a deceleration request is being made (step S10).

  If it is not at the time of a deceleration request (No at Step S10), it is not necessary to generate a feeling of deceleration by the motor generator 17, and the control is terminated. On the other hand, if it is a deceleration request time (Yes at Step S10), it is determined whether the actual fuel injection amount is equivalent to zero, that is, whether fuel cut control is being performed (Step S11), and overtaking acceleration is performed. It is determined that this is not a downshift operation.

  If the actual fuel injection amount is equivalent to zero (Yes in step S11), in order to obtain a pseudo engine braking feeling due to regeneration of the motor generator 17 without downshifting the shift stage of the MMT 12, Based on the vehicle speed and the accelerator opening, the target regeneration amount of the motor generator 17 is calculated based on a predetermined map (step S12).

  For example, if the driver decides that he wants to apply the engine brake while the vehicle is running and the accelerator pedal is returned and the downshift operation is performed from the 4th speed to the 3rd speed by operating the shift lever, the corresponding shift stage of the MMT12 is actually downed. An engine brake feeling that would be obtained if the shift stage was downshifted without shifting is obtained by regeneration of the motor generator 17.

  Further, the target regeneration amount is calculated so that the pseudo engine brake feeling needs to be increased as the speed is low, so that the regeneration amount increases as the speed is low based on the shift stage. That is, for example, when the shift stage of the MMT 12 is actually downshifted from the 4th speed to the 2nd speed (instructed shift stage), the obtained engine braking feeling is stronger than when the downshift is performed from the 4th speed to the 3rd speed.

Therefore, even when a pseudo engine braking feeling is generated, the target regeneration amount is set so that the regeneration amount of the motor generator 17 increases as the speed decreases. In addition, the target regeneration amount of the motor generator can be calculated accurately by taking into account the vehicle speed and accelerator opening when calculating the target regeneration amount, and the driver requests a pseudo engine brake feeling generated based on this. It can be closer to the feeling of deceleration.

  Then, regeneration of the motor generator 17 is performed based on the target regeneration amount calculated as described above (step S13). Thus, in the present embodiment, the engine brake is not generated by the friction loss of the diesel engine 11 as in the prior art, but a pseudo engine brake feeling is obtained by the regeneration of the motor generator 17, so that the driver's The required deceleration feeling can be ensured, and the amount of energy recovered can be increased as compared with the case of using the engine brake, and the fuel consumption can be improved.

  On the other hand, even when the deceleration is requested (Yes at Step S10), if the actual fuel injection amount is not equivalent to zero (No at Step S11), the motor generator 17 does not need to generate a feeling of deceleration. Is prohibited (step S14). That is, for example, when overtaking acceleration is performed, it is not necessary to apply the engine brake positively, and therefore regeneration of the motor generator 17 is prohibited.

  In the first embodiment, it is assumed that a pseudo engine brake feeling is obtained only by regenerative control of the motor generator 17 without downshifting the shift stage of the MMT 12, that is, without generating actual engine brakes. However, it is not limited to this.

  That is, the shift stage of the MMT 12 is actually downshifted to generate a predetermined amount of engine brake, and a pseudo engine brake feeling is generated in combination with the regenerative control of the motor generator 17, so that a smooth deceleration feeling as a whole is obtained. You may control so that it may be obtained.

  For example, if the driver requested a downshift from the 4th speed to the 2nd speed due to the shifting operation, the actual downshift of the MMT12 shift stage was from the 4th speed to the 3rd speed, and the downshift was from the 3rd speed to the 2nd speed. The engine brake feeling that is likely to be obtained in this case is generated in a pseudo manner by regeneration of the motor generator 17, so that the overall control is performed so that it is felt that the engine is decelerated from the fourth speed to the second speed only by the engine brake. Thereby, energy recovery by regeneration can be performed to some extent while maintaining the deceleration feeling required by the driver.

  Further, in the first embodiment, in step S11, it is determined whether or not it is desired to apply the engine brake based on whether or not the actual fuel injection amount is equivalent to zero, that is, whether or not the fuel cut is performed. However, the present invention is not limited to this. For example, it may be determined by the accelerator opening or the fuel injection amount during idling.

  Moreover, in the said Example 1, although demonstrated as what applies this invention to the diesel hybrid vehicle 10 carrying the diesel engine 11, it is not limited to this, You may apply to the hybrid vehicle carrying a gasoline engine. .

  FIG. 3 is a flowchart showing a regeneration control method for the motor generator 17 at the time of a deceleration request according to Embodiment 2 of the present invention.

  First, by detecting this downshift operation, it is determined whether or not a deceleration request is being made (step S20).

  If it is not at the time of a deceleration request (No at Step S20), it is not necessary to generate a feeling of deceleration by the motor generator 17, and the control is terminated. On the other hand, if it is the time of deceleration request (Yes at Step S20), it is determined whether or not the actual fuel injection amount is equivalent to zero, that is, whether or not fuel cut control is performed (Step S21), and overtaking acceleration is performed. It is determined that this is not a downshift operation.

  If the actual fuel injection amount is equivalent to zero (Yes at Step S21), it is determined whether or not the current regeneration amount of the motor generator 17 exceeds a predetermined regeneration amount MGmax_1 (Step S22). The predetermined regeneration amount MGmax_1 is, as shown in FIG. 4, the motor generator 17 required to obtain a deceleration feeling corresponding to the engine braking force at the current shift stage from the maximum regenerative force that can be generated by the motor generator 17. This is the value obtained by subtracting the amount of regeneration. Here, FIG. 4 is a schematic diagram showing a concept of a predetermined regeneration amount MGmax_1.

  In other words, in step S22, it is determined whether or not the deceleration requested by the driver can be obtained only by regeneration of the motor generator 17. If the current regeneration amount of the motor generator 17 does not exceed the predetermined regeneration amount MGmax_1 (No at Step S22), it can be determined that the deceleration feeling requested by the driver can be obtained only by the regeneration of the motor generator 17, so the next step S23 and subsequent steps are executed.

  That is, in order to obtain a pseudo engine braking feeling due to regeneration of the motor generator 17 without downshifting the shift stage of the MMT 12, the current shift stage, vehicle speed, and accelerator opening are used based on a predetermined map. A target regeneration amount of the motor generator 17 is calculated (step S23).

  For example, if the driver decides that he wants to apply the engine brake while the vehicle is running and the accelerator pedal is returned and the downshift operation is performed from the 4th speed to the 3rd speed by operating the shift lever, the corresponding shift stage of the MMT12 is actually downed. An engine brake feeling that would be obtained if the shift stage was downshifted without shifting is obtained by regeneration of the motor generator 17.

  Further, the target regeneration amount is calculated so that the pseudo engine brake feeling needs to be increased as the speed is low, so that the regeneration amount increases as the speed is low based on the shift stage. Then, regeneration of the motor generator 17 is performed based on the calculated value of the target regeneration amount (step S24).

  Thus, when the feeling of deceleration requested by the driver can be obtained only by regeneration of the motor generator 17, the engine brake is not generated by the friction loss of the diesel engine 11 as in the prior art, but by the regeneration of the motor generator 17. Because the engine feels like a pseudo engine brake, it can secure the feeling of deceleration required by the driver and can increase the amount of energy recovered compared to using the engine brake, improving fuel economy. can do.

  On the other hand, if the current regeneration amount of motor generator 17 exceeds predetermined regeneration amount MGmax_1 (Yes in step S22), it can be determined that the deceleration feeling requested by the driver cannot be obtained only by regeneration of motor generator 17. Then, the regenerative amount of the motor generator 17 is adjusted so as to give a feeling of vehicle deceleration immediately before, and a pseudo engine brake feeling is generated, and an actual shift downshift is performed by the MMT 12 (step S25). Is generated. This actual shift shifts based on a shift line map determined in advance by the accelerator opening and the vehicle speed.

  The clutch 12a is disengaged during the actual downshift by the MMT 12. At this time, a sense of torque loss (torque shock) can be suppressed by assist control (regeneration amount decreases) by the motor generator 17. Further, when the clutch 12a is engaged, a regenerative amount of the motor generator 17 is adjusted so that a vehicle deceleration feeling just before the clutch 12a is disengaged to generate a pseudo engine braking feeling.

  Next, it is determined whether or not the shift down of the MMT 12 is completed (step S26). If the clutch 12a is engaged and the shift down is completed (Yes in step S26), the regeneration amount of the motor generator 17 is set to the previous time. (Step S27). If the downshift is not completed (No at step S26), the process waits until it is completed.

  By controlling in this way, a feeling of deceleration requested by the driver can be obtained by the engine brake generated after the clutch 12a is engaged and the regeneration by the motor generator 17, and this feeling of deceleration is obtained by disengaging the clutch 12a. Since the vehicle is adjusted so as to almost coincide with the immediately preceding vehicle deceleration feeling, it is smooth and drivability can be improved.

  Even when a deceleration request is made (Yes at Step S20), if the actual fuel injection amount is not equivalent to zero (No at Step S21), it is considered that the driver is performing a downshift operation for overtaking acceleration, for example. In such a case, it is not always necessary to apply the engine brake positively, and therefore it is not necessary to generate a pseudo engine brake feeling by the regeneration of the motor generator 17.

  However, even during overtaking acceleration, the driver is less likely to feel uncomfortable when there is a predetermined feeling of deceleration felt during normal downshifting, and this feeling of deceleration is reproduced as a simulated engine braking feeling due to regeneration of the motor generator 17. If it can be generated smoothly, energy can be recovered without impairing drivability.

  Therefore, after step S28, during overtaking acceleration, the regenerative amount of the motor generator 17 is adjusted so as to give a feeling of vehicle deceleration immediately before, and a pseudo engine brake feeling is generated, and downshift of actual shift by the MMT 12 is performed. (Step S28), an actual engine brake is generated. This actual shift shifts based on a shift line map determined in advance by the accelerator opening and the vehicle speed.

  The clutch 12a is disengaged during the actual downshift by the MMT 12. At this time, a sense of torque loss (torque shock) can be suppressed by assist control (regeneration amount decreases) by the motor generator 17. Further, when the clutch 12a is engaged, a regenerative amount of the motor generator 17 is adjusted so that a vehicle deceleration feeling just before the clutch 12a is disengaged to generate a pseudo engine braking feeling.

  Next, it is determined whether or not the shift down of the MMT 12 is completed (step S29). If the clutch 12a is engaged and the shift down is completed (Yes in step S29), the regeneration amount of the motor generator 17 is set to the previous time. (Step S30). If the downshift is not completed (No at step S29), the process waits until it is completed.

  By controlling in this way, a feeling of deceleration requested by the driver can be obtained by the engine brake generated after the clutch 12a is engaged and the regeneration by the motor generator 17, and this feeling of deceleration is obtained by disengaging the clutch 12a. Since the vehicle is adjusted so as to almost coincide with the immediately preceding vehicle deceleration feeling, it is smooth and drivability can be improved.

In step S23 in the second embodiment, a pseudo engine brake feeling is obtained only by regenerative control of the motor generator 17 without downshifting the shift stage of the MMT 12, that is, without generating an actual engine brake. However, the present invention is not limited to this.

  That is, the shift stage of the MMT 12 is actually downshifted to generate a predetermined amount of engine brake, and a pseudo engine brake feeling is generated in combination with the regenerative control of the motor generator 17, so that a smooth deceleration feeling as a whole is obtained. You may control so that it may be obtained.

  For example, if the driver requested a downshift from the 4th speed to the 2nd speed due to the shifting operation, the actual downshift of the MMT12 shift stage was from the 4th speed to the 3rd speed, and the downshift was from the 3rd speed to the 2nd speed. The engine brake feeling that is likely to be obtained in this case is generated in a pseudo manner by regeneration of the motor generator 17, so that the overall control is performed so that it is felt that the engine is decelerated from the fourth speed to the second speed only by the engine brake. Thereby, energy recovery by regeneration can be performed to some extent while maintaining the deceleration feeling required by the driver.

  Further, in the second embodiment, in step S21, it is determined whether or not it is desired to apply the engine brake based on whether or not the actual fuel injection amount is equivalent to zero, that is, whether or not the fuel cut is performed. However, the present invention is not limited to this. For example, it may be determined by the accelerator opening or the fuel injection amount during idling.

  As described above, the regenerative control method of the motor generator at the time of deceleration request of the hybrid vehicle according to the present invention is useful for a hybrid vehicle that can realize efficient energy recovery by regeneration while maintaining the deceleration feeling requested by the driver. is there.

It is a flowchart which shows the regeneration control method of the motor generator at the time of the deceleration request | requirement based on Example 1 of this invention. It is a mimetic diagram showing a schematic structure of a diesel hybrid vehicle. It is a flowchart which shows the regeneration control method of the motor generator at the time of the deceleration request | requirement based on Example 2 of this invention. It is a schematic diagram which shows the concept of predetermined | prescribed regeneration amount MGmax_1.

Explanation of symbols

10 Diesel hybrid vehicle (hybrid vehicle)
11 Diesel engine (engine)
12 MMT (Stepped transmission with automatic transmission)
12a Clutch 17 Motor generator 20 Battery

Claims (5)

An engine, a stepped transmission capable of automatic transmission, a clutch for connecting and separating power transmission between the engine and the stepped transmission, and a motor for assisting the engine output by power generation by the engine output or battery power In the regeneration control method of the motor generator at the time of a deceleration request of a hybrid vehicle configured to be driven by either one of the engine and the motor generator,
Based on the shift stage of the stepped transmission at the time of deceleration request and at the time of fuel cut, a target regeneration amount is calculated so that the regeneration amount by the motor generator increases at a lower speed stage, and the motor is set so as to be the target regeneration amount. A regenerative control method for a motor generator at the time of a deceleration request of a hybrid vehicle, wherein the regenerative control of the generator is performed.   2. The hybrid vehicle according to claim 1, wherein the instruction shift stage of the stepped transmission increases only the regeneration amount of the motor generator as the speed shifts at a lower speed, and the actual shift stage of the stepped transmission is not shifted. Regenerative control method for motor generator when requesting deceleration.   The motor generator regeneration control method according to claim 1, wherein the target regeneration amount of the motor generator is calculated in consideration of a vehicle speed and an accelerator opening.   The method for regenerative control of a motor generator at the time of a deceleration request for a hybrid vehicle according to claim 1, wherein when the fuel is not cut during the deceleration, regenerative control of the motor generator is prohibited.   2. The regenerative amount of the motor generator is increased or decreased so as to give a feeling of deceleration immediately before the disconnection control when the control for disconnecting the clutch is performed during the deceleration. A method for regenerative control of a motor generator when a deceleration of a hybrid vehicle is requested.

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