JP2017065652A - Diagnostic device of hybrid vehicle and diagnostic method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To correctly determine running out of gasoline on a hybrid vehicle.SOLUTION: An integrated controller 50 determines that running out of gasoline on an engine 1 occurs, when rotation speed of a motor generator 3 is lowered to less than idling rotation speed of the engine 1 during WSC control, and a differential rotation obtained by subtracting output rotation speed of a second clutch 6 from rotation speed of the motor generator 3, is a negative value.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a technique for determining a lack of gas in a hybrid vehicle.

  Patent Document 1 discloses a hybrid vehicle in which an engine and a motor are disposed in series, a first clutch is disposed between the engine and the motor, and a second clutch is disposed between the motor and the drive wheels.

  In the hybrid vehicle having such a configuration, when the first clutch is released and the second clutch is engaged, the EV mode travels only with the motor. When the first clutch and the second clutch are engaged, the HEV travels with the engine and the motor. It becomes a mode.

  In addition, the WSC (Wet Start Clutch) control that gradually increases the hydraulic pressure supplied to the second clutch at the time of start and gradually engages the second clutch while slipping, makes it possible to smoothly perform without depending on the torque converter. The start is realized.

JP 2010-155590 A

  WSC control cannot be performed correctly if the hydraulic valve control unit malfunctions and there is a MAX pressure failure in which the hydraulic pressure supplied to the second clutch is always maximum. Therefore, when performing WSC control, it is determined whether a MAX pressure failure has occurred. If it is determined that a MAX pressure failure has occurred, WSC control is stopped and appropriate fail-safe control is performed. Need to do.

  Here, if the MAX pressure failure has occurred, the second clutch suddenly engages and the driving wheel that is stopped or rotates at a low speed and the motor are directly connected to each other, and the rotational speed of the motor is reduced, so that The differential rotation (= motor rotation speed−output rotation speed of the second clutch) is reduced. Focusing on this phenomenon, it is conceivable to determine whether or not a MAX pressure failure has occurred based on the rotational speed of the motor and the differential rotation in the second clutch.

  However, even when the engine cannot blow due to a lack of gas (a state in which a sufficient amount of fuel is not supplied to the engine due to a lack of fuel), the rotational speed of the motor is reduced by the engine, and the differential rotation in the second clutch is reduced. In addition, if it is determined whether a MAX failure has occurred based on these parameters, there is a possibility that a gas shortage is erroneously determined as a MAX pressure failure.

  If the correct judgment cannot be made, not only can fail fail control be performed properly, but it may take time to identify the cause of the failure in subsequent repairs, and there is a possibility that non-failed parts will be replaced. It is not preferable.

  The present invention has been made in view of such technical problems, and it is an object of the present invention to correctly determine a lack of gas in a hybrid vehicle.

  According to an aspect of the present invention, an engine and a motor arranged in series, a clutch arranged between the motor and a drive wheel, and a pressure regulating mechanism that regulates the hydraulic pressure supplied to the clutch, A diagnosis apparatus for a hybrid vehicle that performs WSC control for adjusting a hydraulic pressure supplied to the clutch at the time of starting to a hydraulic pressure at which the clutch slips by the pressure adjusting mechanism, wherein a rotational speed of the motor is controlled during the WSC control. If the difference rotation obtained by subtracting the output rotation speed of the clutch from the rotation speed of the motor is negative, it is determined that the engine has run out of gas. A configured diagnostic device is provided.

  Also, a hybrid vehicle diagnosis method corresponding to this is provided.

  According to these aspects, if the rotational speed of the motor falls below the idle rotational speed of the engine during WSC control and the differential rotational speed in the clutch is negative, it is determined that the engine has run out of gas. . As a result, the engine gas shortage can be correctly determined without misidentifying the engine gas shortage as a MAX pressure failure.

1 is an overall configuration diagram of a hybrid vehicle to which a diagnostic device according to an embodiment of the present invention is applied. It is an example of a mode switching map. It is the flowchart which showed the content of the diagnostic process. It is the time chart which showed a mode when the engine gas shortage generate | occur | produced at the time of start.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

  FIG. 1 is an overall configuration diagram of a hybrid vehicle (hereinafter referred to as a vehicle) 100. The vehicle 100 includes an engine 1, a first clutch 2, a motor generator (hereinafter referred to as MG) 3, a first oil pump 4, a second oil pump 5, a second clutch 6, and a continuously variable transmission. (Hereinafter referred to as CVT) 7, drive wheel 8, and integrated controller 50.

  The engine 1 is an internal combustion engine that uses gasoline, light oil, or the like as fuel, and the rotational speed, torque, and the like are controlled based on a command from the integrated controller 50.

  The first clutch 2 is a normally open hydraulic clutch interposed between the engine 1 and the MG 3. The first clutch 2 is engaged / released by the hydraulic pressure adjusted by the hydraulic control valve unit 71 using the discharge pressure of the first oil pump 4 or the second oil pump 5 as a source pressure based on a command from the integrated controller 50. Is controlled. For example, a dry multi-plate clutch is used as the first clutch 2.

  The MG 3 is a synchronous rotating electrical machine that is arranged in series with the engine 1 and has a permanent magnet embedded in a rotor and a stator coil wound around a stator. The MG 3 is controlled by applying a three-phase alternating current generated by the inverter 9 based on a command from the integrated controller 50. The MG 3 can operate as an electric motor that is rotationally driven by the supply of electric power from the battery 10. Further, when the rotor receives rotational energy from the engine 1 or the drive wheel 8, the MG 3 functions as a generator that generates electromotive force at both ends of the stator coil and can charge the battery 10.

  The first oil pump 4 is a vane pump that operates when the rotation of the MG 3 is transmitted via the belt 4b. The first oil pump 4 sucks up the hydraulic oil stored in the oil pan 72 of the CVT 7 and supplies the hydraulic pressure to the hydraulic control valve unit 71.

  The second oil pump 5 is an electric oil pump that operates by receiving power supplied from the battery 10. The second oil pump 5 is driven when the amount of oil is insufficient with only the first oil pump 4 based on a command from the integrated controller 50, and is stored in the oil pan 72 of the CVT 7 in the same manner as the first oil pump 4. The hydraulic oil is sucked up and the hydraulic pressure is supplied to the hydraulic control valve unit 71.

  The second clutch 6 is interposed between the MG 3, the CVT 7, and the drive wheel 8. The second clutch is controlled to be engaged and disengaged by the hydraulic pressure adjusted by the hydraulic control valve unit 71 using the discharge pressure of the first oil pump 4 or the second oil pump 5 as a source pressure based on a command from the integrated controller 50. Is done. As the second clutch 6, for example, a normally open wet multi-plate clutch is used.

  The CVT 7 is disposed downstream of the MG 3 and can change the speed ratio steplessly according to the vehicle speed, the accelerator opening, and the like. The CVT 7 includes a primary pulley, a secondary pulley, and a belt that spans both pulleys. A primary pulley pressure and a secondary pulley pressure are generated by the hydraulic control valve unit 71 using the discharge pressure from the first oil pump 4 and the second oil pump 5 as a source pressure, and the movable pulley of the primary pulley and the movable pulley of the secondary pulley are generated by the pulley pressure. The gear ratio is changed steplessly by moving the shaft in the axial direction and changing the pulley contact radius of the belt.

  A differential 12 is connected to an output shaft of the CVT 7 via a final reduction gear mechanism (not shown), and a drive wheel 8 is connected to the differential 12 via a drive shaft 13.

  The integrated controller 50 detects a rotation speed sensor 51 that detects the rotation speed of the engine 1, a rotation speed sensor 52 that detects an output rotation speed Nout of the second clutch 6 (= an input rotation speed of the CVT 7), and an accelerator opening degree. Signals from an accelerator opening sensor 53, an inhibitor switch 54 for detecting a select position of the CVT 7 (a state of a select lever or a select switch for switching forward, reverse, neutral and parking), a vehicle speed sensor 55 for detecting a vehicle speed, and the like are input. . The integrated controller 50 performs various controls on the engine 1, MG3 (inverter 9), and CVT 7 based on these input signals. The rotational speed Nmg of MG3 can be obtained from the frequency of the inverter 9 by calculation.

  Further, the integrated controller 50 switches between the EV mode and the HEV mode as the operation mode of the vehicle 100 with reference to the mode switching map shown in FIG.

  The EV mode is a mode in which the first clutch 2 is released and the vehicle travels using only MG3 as a drive source. The EV mode is selected when the required driving force is low and the amount of charge of the battery 10 is sufficient.

  The HEV mode is a mode in which the first clutch 2 is engaged and the engine 1 and the MG 3 are used as driving sources. The HEV mode is selected when the required driving force is high or when the charge amount of the battery 10 is insufficient.

  Note that the switching line from the EV mode to the HEV mode is set at a higher vehicle speed side and a larger accelerator opening than the switching line from the HEV mode to the EV mode so that the switching between the EV mode and the HEV mode is not hunting. The

  Further, since the vehicle 100 is not provided with a torque converter, in the WSC region shown in FIG. 2 (the vehicle speed used when starting / decelerating and stopping is a low vehicle speed region of VSP1 or less, VSP1 is, for example, 10 km / h), the integrated controller 50 performs WSC control that starts and stops while slipping the second clutch 6.

  Specifically, when the select position of the CVT 7 is switched from the non-traveling position (N, P, etc.) to the traveling position (D, R, etc.) and the vehicle 100 starts, the integrated controller 50 switches to the second clutch 6. The supplied hydraulic pressure is gradually increased, and the second clutch 6 is gradually engaged while slipping. When the vehicle speed reaches VSP1, the integrated controller 50 completely engages the second clutch 6, and ends the WSC control.

  Further, when the vehicle 100 is traveling at the select position of the CVT 7 at the travel position (D, R, etc.) and the vehicle 100 decelerates and the vehicle speed decreases to VSP1, the integrated controller 50 supplies the second clutch 6. The hydraulic pressure is gradually reduced, and the second clutch 6 is gradually released while slipping. When the vehicle 100 stops, the integrated controller 50 completely releases the second clutch 6 and ends the WSC control.

  By the way, when the MAX pressure failure that maximizes the hydraulic pressure supplied to the second clutch 6 occurs, the second clutch 6 is immediately engaged immediately after the supply of the hydraulic pressure to the second clutch 6 is started. Can not do. For this reason, it is determined by the integrated controller 50 whether or not a MAX pressure failure has occurred, and when it is determined that a MAX pressure failure has occurred, fail-safe control such as torque reduction of the engine 1 is performed. Is preferred.

  However, the MAX pressure failure occurs because the rotation speed Nmg of MG3 has dropped and the differential rotation ΔNc (= rotation speed Nmg of MG3−output rotation speed Nout of the second clutch 6) in the second clutch 6 is reduced accordingly. If it is immediately determined that the engine 1 has occurred, the same phenomenon occurs when the engine 1 is out of gas (a sufficient amount of fuel is not supplied to the engine 1 due to the lack of fuel). There is a possibility that a gas shortage is mistaken as a MAX pressure failure.

  Therefore, the integrated controller 50 performs a diagnosis process described below, and thereby can correctly determine the cause of the decrease in the rotational speed Nmg of the MG 3 and the reduction in the differential rotation ΔNc in the second clutch 6 thereby.

  FIG. 3 is a flowchart showing the contents of the diagnostic process performed by the integrated controller 50. Details of the diagnostic processing performed by the integrated controller 50 will be described with reference to this.

  In step S1, the integrated controller 50 determines whether WSC control at the time of starting is being performed. If the WSC control at the time of starting is being performed, the process proceeds to step S2, and if not, the process ends.

  In step S2, the integrated controller 50 determines whether the rotational speed Nmg of MG3 is lower than the drop determination value Ndrp. The drop determination value Ndrp is a threshold value for determining that the MG 3 has dropped to a rotation speed lower than the idle rotation speed of the engine 1, and is a value slightly smaller than the idle rotation speed (for example, the idle rotation speed is 900 rpm). If there is, it is set to 700 rpm). If it is determined that the rotation speed Nmg of MG3 is lower than the drop determination value Ndrp, the integrated controller 50 advances the process to step S3, and otherwise ends the process.

  In step S <b> 3, the integrated controller 50 determines whether the differential rotation ΔNc in the second clutch 6 is positive or negative.

  Here, if the engine 1 can no longer blow due to the lack of gas, the rotational speed Nmg of the MG 3 is lowered by the engine 1, so the rotational speed Nmg of the MG 3 is lower than the output rotational speed Nout of the second clutch 6, The differential rotation ΔNc becomes negative. On the other hand, if the MAX pressure failure occurs, the rotation speed Nmg of the MG 3 is reduced by directly connecting the MG 3 to the stopped or low-speed driving wheel via the second clutch 6. The rotational speed Nmg of MG3 is higher than the output rotational speed Nout, and the differential rotation ΔNc becomes positive.

  For this reason, the integrated controller 50 determines that there is a possibility that the engine 1 is out of gas when the differential rotation ΔNc is negative, and proceeds with the process to step S4. It is determined that there is, and the process proceeds to step S9.

  When the process proceeds to step S4, the integrated controller 50 counts up the first timer.

  In step S5, the integrated controller 50 determines whether the value of the first timer exceeds the gas shortage determination threshold value NGth1, and if so, proceeds to step S6 to determine that the engine 1 has run out of gas. To do. When the value of the first timer does not exceed the gas shortage determination threshold value NGth1, the integrated controller 50 returns the process to step S2, and repeats the processes after step S2.

  Even if it is determined that the differential rotation ΔNc is negative, it is not immediately determined that the engine 1 has run out of gas, and it is determined that the engine 1 has run out of gas only after the value of the first timer exceeds the gas shortage determination threshold NGth1. The reason for doing so is to eliminate the influence of a temporary abnormal value of the sensor or the like and to increase the determination accuracy.

  Then, the integrated controller 50 releases the first clutch 2 as fail-safe control when the engine 1 runs out of gas (step S7), and fixes the vehicle travel mode to the EV mode until refueling thereafter (step S7). S8).

  On the other hand, when the process proceeds to step S9, the integrated controller 50 counts up the second timer.

  In step S10, the integrated controller 50 determines whether the value of the second timer exceeds the MAX pressure failure determination threshold NGth2, and if so, proceeds to step S11 to determine that a MAX pressure failure has occurred. . If the value of the second timer does not exceed the MAX pressure failure determination threshold value NGth2, the integrated controller 50 returns the process to step S2, and repeats the processes after step S2.

  Even if the differential rotation ΔNc is determined to be positive, it is not immediately determined that a MAX pressure failure has occurred, and it is determined that a MAX pressure failure has not occurred until the value of the second timer exceeds the MAX pressure failure determination threshold NGth2. The reason for this is to eliminate the influence of a temporary abnormal value or the like of the sensor and improve the determination accuracy.

  Then, the integrated controller 50 performs torque-down control of the engine 1 as fail-safe control when the MAX pressure failure occurs (step S12). As the fail-safe control when the MAX pressure failure occurs, the first clutch 2 and the second clutch 6 may be released instead of the torque-down control of the engine 1.

  Then, the effect by performing the said diagnostic process is demonstrated.

  FIG. 4 is a time chart showing a situation when the engine 1 has run out of gas when starting.

  When starting, WSC control is performed. When the engine 1 runs out of gas during WSC control, the engine 1 that does not blow up lowers the rotational speed Nmg of the MG 3 (time t1 to time t1).

  Similarly, when the engine 1 runs out of gas or when the MAX pressure failure occurs, the rotation speed Nmg of the MG 3 drops and the differential rotation ΔNc of the second clutch 6 decreases. For example, when the rotation speed Nmg of MG3 falls below the output rotation speed Nout of the second clutch 6, the first timer starts counting up (time t2), and when the value of the first timer exceeds the gas shortage determination threshold value NGth1, It is determined that 1 out of gas has occurred (time t3).

  In this example, a drop in the rotational speed Nmg of MG3 occurs between times t1 and t2, and a period in which the differential rotation ΔNc is positive occurs intermittently, and the second timer counts in response to this period. It is assumed that the value of the second timer does not exceed the MAX pressure failure determination threshold value NGth2 (not shown).

  Thus, in the present embodiment, when the rotational speed Nmg of MG3 falls below the idle rotational speed of the engine 1 during WSC control and the differential rotational speed ΔNc is negative, the engine 1 is out of gas. Therefore, the out-of-gassing of the engine 1 is not misidentified as a MAX pressure failure, and the out-of-gassing of the engine 1 can be correctly determined (effects corresponding to claims 1, 3, and 5). ).

  Further, since the engine 1 is determined to have run out of gas when the cumulative value of the time during which the differential rotation ΔNc is negative (the value of the first timer) exceeds the out-of-gas judgment threshold, Even if there is no out of gas due to an abnormal value or the like, it is not determined that there is no gas, and high determination accuracy can be realized. The same applies to the determination of the MAX pressure failure (effect corresponding to claims 2 and 4).

  The embodiment of the present invention has been described above, but the above embodiment is merely a part of an application example of the present invention, and the technical scope of the present invention is limited to the specific configuration of the above embodiment. is not.

DESCRIPTION OF SYMBOLS 1 Engine 2 1st clutch 3 Motor generator 4 1st oil pump 5 2nd oil pump 6 2nd clutch 8 Drive wheel 50 Integrated controller (diagnosis apparatus)
71 Hydraulic control valve unit 100 Hybrid vehicle

Claims (5)

The engine and motor arranged in series, a clutch arranged between the motor and the drive wheel, and a pressure regulating mechanism that regulates the hydraulic pressure supplied to the clutch, the hydraulic pressure supplied to the clutch when starting A hybrid vehicle diagnostic apparatus that performs WSC control to regulate the hydraulic pressure at which the clutch slips by the pressure regulating mechanism,
When the rotational speed of the motor falls below the idle rotational speed of the engine during the WSC control and the differential rotational speed obtained by subtracting the output rotational speed of the clutch from the rotational speed of the motor is negative, the engine It is determined that a lack of gas has occurred.
A diagnostic apparatus configured as described above. The diagnostic device according to claim 1,
When the cumulative value of the time during which the differential rotation is negative exceeds a gas shortage determination threshold, it is determined that the engine has run out of gas.
The diagnostic device is further configured as described above. The diagnostic device according to claim 1 or 2,
If the rotational speed of the motor falls below the idle rotational speed of the engine during the WSC control and the differential rotational speed is positive, a MAX pressure failure that maximizes the hydraulic pressure supplied to the clutch occurs. It is determined that
The diagnostic device is further configured as described above. The diagnostic device according to claim 3,
When the cumulative value of the time during which the differential rotation is positive exceeds the MAX pressure failure threshold, it is determined that the MAX pressure failure has occurred.
The diagnostic device is further configured as described above. The engine and motor arranged in series, a clutch arranged between the motor and the drive wheel, and a pressure regulating mechanism that regulates the hydraulic pressure supplied to the clutch, the hydraulic pressure supplied to the clutch when starting A hybrid vehicle diagnostic method for performing WSC control to regulate the hydraulic pressure at which the clutch slips by the pressure regulating mechanism,
When the rotational speed of the motor falls below the idle rotational speed of the engine during the WSC control and the differential rotational speed obtained by subtracting the output rotational speed of the clutch from the rotational speed of the motor is negative, the engine It is determined that a lack of gas has occurred.
A diagnostic method characterized by the above.

Images