JP2008222222A - Driving device and its operation control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent the overheating of a generator motor in a driving device equipped with an automatic transmission, an internal combustion engine and the generator motor. <P>SOLUTION: The driving device 20 is provided with: a CVT 50 for performing a shift between an input shaft 51 and an output shaft 52; an engine 22 equipped with a crankshaft 24 connected to the input shaft 51; and a motor 40 equipped with a rotary shaft 41 connected to the input shaft 51. In this driving device 20, while the engine 22, the motor 40 and the CVT 50 are controlled so that the output shaft 52 can output target power and so that the motor 40 can output target electric power, the transmission gear ratio of the CVT 50 is changed according to the temperature of the motor 40, so that the temperature of the motor 40 can be prevented from exceeding an allowable critical temperature. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a drive device, and relates to an automatic transmission that shifts between an input shaft and a drive shaft, an internal combustion engine that includes an output shaft connected to the input shaft of the automatic transmission, and an input of the automatic transmission. The present invention relates to a driving device including a generator motor including a rotating shaft connected to a shaft. The present invention also relates to an operation control method for such a drive device.

2. Description of the Related Art Conventionally, as this type of drive device, a drive device in which an internal combustion engine, a continuously variable transmission, and a generator motor are connected using a planetary gear has been proposed (for example, see Patent Document 1). In this drive device, an internal combustion engine is connected to the ring gear of the planetary gear, a generator motor is connected to the sun gear, and a transmission is connected to the carrier, so that the operation point differs from the required output required for the drive shaft, but performs the same output. The internal combustion engine is operated and the output from the internal combustion engine is output as a required output to the drive shaft by the rotational speed control of the generator motor and the torque ratio control of the continuously variable transmission. In addition, the drive device includes a clutch that rotates the sun gear, the ring gear, and the carrier as one body. By connecting the clutch, the output shaft of the internal combustion engine and the input shaft of the continuously variable transmission are coupled. The output of the internal combustion engine is output directly to the drive shaft via a shift by a continuously variable transmission, and the secondary motor can be charged by generating a generator motor.
Japanese Patent Laid-Open No. 9-37411

  However, in a state where the output shaft of the internal combustion engine, the rotating shaft of the generator motor, and the input shaft of the continuously variable transmission are connected so as to be integrated, the sum of the target power and the power required for power generation by the generator motor is Although it is the output of the internal combustion engine, the output torque of the internal combustion engine increases because the rotational speed of the internal combustion engine is usually set in consideration of improving fuel efficiency, and the generator motor generates power. The absolute value of the required torque increases. If the absolute value of this torque is large, the current flowing through the generator motor increases, and copper loss occurs in proportion to the square of the current, so the amount of heat generation increases. Since the efficiency of the generator motor decreases as the temperature rises, if such a temperature rise is left unattended, the efficiency of the entire apparatus may be reduced.

  An object of the present invention is to solve the above-described problems, and an object of the present invention is to provide a drive device that can prevent overheating of a generator motor and an operation control method thereof. The applicant is a device that converts the power from the internal combustion engine using two motors and outputs the torque to the drive shaft. When the motor temperature is equal to or higher than a predetermined temperature, the internal combustion engine is used to suppress the temperature rise. A proposal for changing the operating point of an engine has been proposed (Japanese Patent Application No. 9-224316).

The drive device of the present invention that achieves the above-described object is as follows.
An automatic transmission that shifts between an input shaft and a drive shaft, an internal combustion engine that includes an output shaft connected to the input shaft, and a generator motor that includes a rotary shaft connected to the input shaft. A driving device comprising:
While controlling the internal combustion engine, the generator motor and the automatic transmission so that the drive shaft is in a target drive state and the generator motor is in a target operating state, the temperature of the generator motor exceeds a predetermined allowable limit temperature. The gist of the present invention is to provide an operation control means for controlling the gear ratio of the automatic transmission according to the temperature of the generator motor.

  In this drive device, the gear ratio of the automatic transmission is set according to the temperature of the generator motor while controlling the internal combustion engine, the generator motor, and the automatic transmission so that the drive shaft is in the target drive state and the generator motor is in the target operation state. By changing the temperature, the temperature of the generator motor is controlled so as not to exceed a predetermined allowable limit temperature, so that the generator motor can be prevented from being overheated. Here, “drive state” with respect to the drive shaft means a combination of torque and rotation speed, and “operation state” with respect to the generator motor means both states in which the motor is operated as a generator or a motor. “The temperature of the generator motor” is meant to include the temperature of the drive circuit of the generator motor, and is not limited to the temperature of the generator motor itself, and the temperature of the generator motor may be directly detected. However, the temperature of the generator motor may be estimated from another parameter (for example, the coolant temperature of the generator motor, the temperature of the peripheral device of the generator motor, or the temperature of the coolant temperature of the device). In addition, the “allowable limit temperature” is an upper limit temperature determined in consideration of, for example, characteristics of the generator motor, operating efficiency, and the like.

  In the drive device of the present invention, the output shaft of the internal combustion engine can be mechanically connected to the input shaft without slipping, and the rotating shaft of the generator motor slips with respect to the input shaft. Mechanical connection without accompanying is possible, and the operation control means is in a mechanically connected state in which the input shaft of the automatic transmission, the output shaft of the internal combustion engine, and the rotating shaft of the generator motor do not slip. In addition, while controlling the internal combustion engine, the generator motor, and the automatic transmission so that the drive shaft is in a target drive state and the generator motor is in a target operation state, the temperature of the generator motor is a predetermined allowable limit temperature. The transmission ratio of the automatic transmission may be controlled according to the temperature of the generator motor so as not to exceed. During such direct running, that is, when the input shaft of the automatic transmission, the output shaft of the internal combustion engine, and the rotating shaft of the generator motor are mechanically connected without slipping, the operation of the internal combustion engine is controlled by the gear ratio control of the automatic transmission. Although the point can be controlled on the optimum fuel consumption curve, since the generator motor can be prevented from being overheated in such a case, the efficiency of the entire apparatus is not reduced. In addition, “mechanical connection without slipping” means that a mechanical connection without slipping can be performed by operating a connection mechanism such as a clutch or a brake, The present invention is not limited to one in which a mechanical connection without sliding is always made.

  In the driving apparatus according to the present invention, a temperature detection unit that detects a temperature of the generator motor is provided, and the operation control unit is configured to change the gear ratio of the automatic transmission according to the temperature of the generator motor detected by the temperature detection unit. May be controlled.

  In the driving apparatus of the present invention, the operation control means may change a gear ratio of the automatic transmission according to a temperature of the generator motor when the generator motor is in a power generation state. For example, even if a generator motor is driving and assisting an internal combustion engine, the assist time is usually not so long as the generator motor overheats, so there is little risk of overheating, whereas the generator motor generates power. When the battery is charged, it may take a long time to charge, which may cause overheating. Therefore, it is highly necessary to apply the present invention when the generator motor is in the power generation state.

  In the driving apparatus according to the present invention, the operation control means may control the gear ratio of the automatic transmission according to the temperature of the generator motor when the temperature of the generator motor approaches the allowable limit temperature. Of course, the gear ratio of the automatic transmission may be controlled at all times according to the temperature of the generator motor, but when the temperature approaches the allowable limit temperature of the generator motor, the gear ratio of the automatic transmission according to the temperature of the generator motor. Even if this is controlled, overheating of the generator motor can be prevented.

  In the driving apparatus of the present invention, the operation control means obtains a target rotational speed of the input shaft according to the temperature of the generator motor when controlling the gear ratio of the automatic transmission according to the temperature of the generator motor. The gear ratio of the automatic transmission may be controlled based on the target rotational speed. In this way, the speed ratio of the automatic transmission can be obtained from the drive shaft speed and the target speed of the input shaft of the automatic transmission. Here, “based on the target rotational speed of the input shaft” includes the case based on a parameter that can be substantially identified with the target rotational speed of the automatic transmission input shaft. Even if it is a parameter other than the rotational speed (for example, the target rotational speed of the internal combustion engine or generator motor or the target torque of the internal combustion engine, generator motor, or automatic transmission input shaft), if the parameter is determined, the automatic transmission input shaft If the number of rotations is determined, the case based on such parameters is also included.

  In the drive device of the present invention, the operation control means controls the gear ratio of the automatic transmission according to the temperature of the generator motor, and when the generator motor outputs the target power, the temperature of the generator motor is high. The target rotational speed of the input shaft may be obtained so that the rotational speed of the generator motor is high and the torque is low, and the gear ratio of the automatic transmission may be controlled based on the target rotational speed. In this way, the higher the temperature of the generator motor, the smaller the absolute torque value of the rotating shaft of the generator motor connected to the input shaft of the automatic transmission, and the heat generation of the generator motor is suppressed.

  In the driving apparatus of the present invention, the operation control means may control a gear ratio of the automatic transmission according to a temperature of the generator motor and a temperature of a cooling medium that cools the generator motor. Since the generator motor is cooled by the cooling medium, in order to prevent overheating of the generator motor more reliably, the gear ratio of the automatic transmission should be controlled in consideration of the temperature of the cooling medium in addition to the temperature of the generator motor. Is preferred. In this case, medium temperature detection means for detecting the temperature of the cooling medium for cooling the generator motor is provided, and the operation control means is configured to adjust the temperature of the generator motor and the temperature of the cooling medium detected by the medium temperature detection means. Accordingly, the gear ratio of the automatic transmission may be controlled. However, an estimated value calculated based on another parameter value may be used as the medium temperature.

  Here, the operation control means controls the speed ratio of the automatic transmission according to the temperature of the generator motor and the temperature of the cooling medium, and the operation control means according to the temperature of the generator motor and the temperature of the cooling medium. The target rotational speed of the input shaft may be obtained and the gear ratio of the automatic transmission may be controlled based on the target rotational speed. In this way, the speed ratio of the automatic transmission can be obtained from the drive shaft speed and the target speed of the input shaft of the automatic transmission. Further, since the gear ratio of the automatic transmission is controlled in consideration of the temperature of the cooling medium in addition to the temperature of the generator motor, overheating of the generator motor can be more reliably prevented.

  Further, when the operation control means changes the gear ratio of the automatic transmission in accordance with the temperature of the generator motor and the temperature of the cooling medium, the temperature of the generator motor is changed when the generator motor outputs target power. The target rotational speed of the input shaft is determined so that the higher the temperature or the higher the temperature of the cooling medium, the higher the rotational speed of the generator motor and the lower the torque, and the transmission ratio of the automatic transmission is controlled based on the target rotational speed. May be. In this way, the higher the temperature of the generator motor, the smaller the absolute torque value of the rotating shaft of the generator motor connected to the input shaft of the automatic transmission, and the heat generation of the generator motor is suppressed. Further, since the gear ratio of the automatic transmission is controlled in consideration of the temperature of the cooling medium in addition to the temperature of the generator motor, overheating of the generator motor can be more reliably prevented.

  In the driving apparatus of the present invention, the operation control means obtains the target rotational speed of the input shaft and controls the gear ratio of the automatic transmission based on the target rotational speed. A guard may be applied so as not to exceed the upper limit target rotational speed obtained from the maximum value of the gear ratio of the automatic transmission and the actual rotational speed of the drive shaft. In this way, it is possible to avoid the target rotational speed of the input shaft from becoming a value that cannot be achieved by the gear ratio control.

  In the driving apparatus of the present invention, the operation control means controls the speed ratio of the automatic transmission so that the temperature of the generator motor does not exceed a predetermined allowable limit temperature, while the speed ratio of the automatic transmission is adjusted. If there is a possibility that the allowable limit temperature may be exceeded only by controlling, the target electric power of the generator motor may be lowered. In this case, even if the gear ratio of the automatic transmission alone does not sufficiently lower the temperature of the generator motor, in that case, the temperature of the generator motor can be further lowered by reducing the target power of the generator motor. The overheating of the generator motor can be prevented more reliably.

Next, another drive device of the present invention that achieves the above-described object is as follows.
An automatic transmission that shifts between an input shaft and a drive shaft, an internal combustion engine that includes an output shaft connected to the input shaft, and a generator motor that includes a rotary shaft connected to the input shaft. A driving device comprising:
Input shaft rotation stopping means for stopping rotation of the input shaft;
Power transmission means for connecting the output shaft of the internal combustion engine and the rotary shaft of the generator motor so that power can be transmitted in a state where the input shaft of the automatic transmission is separated from the output shaft of the internal combustion engine and the rotary shaft of the generator motor. When,
The power transmission means can transmit power between the output shaft of the internal combustion engine and the rotary shaft of the generator motor in a state where the input shaft of the automatic transmission is separated from the output shaft of the internal combustion engine and the rotary shaft of the generator motor. When the input shaft rotation stopping means is connected and rotation of the input shaft is stopped, the internal combustion engine is controlled in accordance with the temperature of the generator motor so that the temperature of the generator motor does not exceed a predetermined allowable limit temperature. And an operation control means for controlling the engine speed.

  In this drive device, the input shaft of the automatic transmission is connected to the output shaft of the internal combustion engine and the rotary shaft of the generator motor in a state where the input shaft of the automatic transmission is separated from the output shaft of the internal combustion engine and the rotary shaft of the generator motor. When the vehicle is parked, it is controlled so that the temperature of the generator motor does not exceed a predetermined allowable limit temperature by changing the rotation speed of the internal combustion engine according to the temperature of the generator motor. Can prevent overheating of the generator motor. Here, “the temperature of the generator motor” and “the allowable limit temperature” are as described above. Further, “controlling the number of revolutions of the internal combustion engine” includes a parameter that substantially changes the number of revolutions of the internal combustion engine, and parameters other than the number of revolutions of the internal combustion engine (for example, the number of revolutions of the generator motor or the internal combustion engine). Even when the torque of the engine or generator motor is changed, such a case is also included if the number of revolutions of the internal combustion engine is uniquely determined if those parameters are determined.

  In the drive device of the present invention, in place of or in addition to the input shaft rotation stop means, there is provided non-drive state control means for making the drive shaft in a non-drive state, and the operation control means is configured to transmit the automatic transmission by the power transmission means. The input shaft of the internal combustion engine is disconnected from the output shaft of the internal combustion engine and the rotating shaft of the generator motor, and the output shaft of the internal combustion engine and the rotating shaft of the generator motor are connected so as to be able to transmit power, and the non-driving state control means The rotational speed of the internal combustion engine is controlled according to the temperature of the generator motor so that the temperature of the generator motor does not exceed a predetermined allowable limit temperature when the drive shaft is in a non-driven state by May be. Also in this case, overheating of the generator motor during parking can be prevented.

  The drive device according to the present invention further comprises temperature detection means for detecting the temperature of the generator motor, and the operation control means controls the rotational speed of the internal combustion engine according to the temperature of the generator motor detected by the temperature detection means. You may control.

  In the driving apparatus of the present invention, the operation control means may control the rotational speed of the internal combustion engine according to the temperature of the generator motor when the automatic transmission is in the P range.

  In the driving apparatus according to the present invention, the operation control means may change the rotational speed of the internal combustion engine according to the temperature of the generator motor when the generator motor is in a power generation state. When the generator motor is in a power generation state, it may take a longer time than when it is in an electric state, so the generator motor is likely to be overheated, and the need to apply the present invention is high.

  In the driving apparatus according to the present invention, the operation control means may control the rotational speed of the internal combustion engine according to the temperature of the generator motor when the temperature of the generator motor approaches the allowable limit temperature. Of course, the speed of the internal combustion engine may always be controlled according to the temperature of the generator motor, but when the temperature approaches the allowable limit temperature of the generator motor, the speed of the internal combustion engine is controlled according to the temperature of the generator motor. Even so, overheating of the generator motor can be prevented.

  In the driving apparatus of the present invention, the operation control means controls the number of revolutions of the internal combustion engine in accordance with the temperature of the generator motor, and the higher the temperature of the generator motor is, the higher the temperature of the generator motor is when the generator motor outputs target power. The target rotational speed of the internal combustion engine may be obtained so that the rotational speed of the generator motor is high and the torque is low, and the rotational speed of the internal combustion engine may be controlled to be the target rotational speed. By doing so, the higher the temperature of the generator motor, the smaller the absolute torque value of the rotating shaft of the generator motor connected to the output shaft of the internal combustion engine, and the heat generation of the generator motor is suppressed.

  In the driving apparatus according to the present invention, the operation control means may control the rotational speed of the internal combustion engine in accordance with a temperature of the generator motor and a temperature of a cooling medium that cools the generator motor. Since the generator motor is cooled by the cooling medium, in order to more reliably prevent the generator motor from being overheated, it is necessary to control the rotational speed of the internal combustion engine in consideration of the temperature of the cooling medium in addition to the temperature of the generator motor. preferable. In this case, medium temperature detection means for detecting the temperature of the cooling medium for cooling the generator motor is provided, and the operation control means is configured to adjust the temperature of the generator motor and the temperature of the cooling medium detected by the medium temperature detection means. Accordingly, the rotational speed of the internal combustion engine may be controlled. However, an estimated value calculated based on another parameter value may be used as the medium temperature.

  Here, when the operation control means controls the rotational speed of the internal combustion engine according to the temperature of the generator motor and the temperature of the cooling medium, when the generator motor outputs the target power, The target rotational speed of the internal combustion engine is calculated so that the rotational speed of the generator motor increases and the torque decreases as the temperature of the cooling medium increases, and the rotational speed of the internal combustion engine is controlled to be the target rotational speed. Good. By doing so, the higher the temperature of the generator motor, the smaller the absolute torque value of the rotating shaft of the generator motor connected to the output shaft of the internal combustion engine, and the heat generation of the generator motor is suppressed. Further, since the rotational speed of the internal combustion engine is controlled in consideration of the temperature of the cooling medium in addition to the temperature of the generator motor, overheating of the generator motor can be more reliably prevented.

  In the drive device according to the present invention, the operation control means controls the temperature of the generator motor so as not to exceed a predetermined allowable limit temperature by controlling the rotational speed of the internal combustion engine. If there is a risk of exceeding the allowable limit temperature only by controlling the rotational speed, the target electric power of the generator motor may be lowered. In this case, even if the rotational speed control of the internal combustion engine alone may not sufficiently lower the temperature of the generator motor, in that case, the temperature of the generator motor can be further lowered by reducing the target power of the generator motor. The overheating of the generator motor can be prevented more reliably.

Next, another drive device of the present invention that achieves the above-described object is as follows.
An automatic transmission that shifts between an input shaft and a drive shaft, an internal combustion engine that includes an output shaft connected to the input shaft, and a generator motor that includes a rotary shaft connected to the input shaft. A driving device comprising:
The gist of the invention is that it comprises an operation control means for performing combined control of the internal combustion engine, the generator motor, and the automatic transmission according to the temperature of the generator motor.

  In this drive device, for example, when the internal combustion engine, the generator motor, and the automatic transmission are combined and controlled according to the temperature of the generator motor so that the temperature of the generator motor does not exceed a predetermined allowable limit temperature, The generator motor can be prevented from overheating during parking. Here, “the temperature of the generator motor” and “the allowable limit temperature” are as described above.

  In the drive device of the present invention, the automatic transmission may be a continuously variable transmission. Further, the output shaft of the internal combustion engine and the rotating shaft of the generator motor are each configured to be mechanically connected to the input shaft of the automatic transmission without slippage via a planetary gear mechanism. It may be.

[First Embodiment]
FIG. 1 is a configuration diagram showing an outline of a configuration of an in-vehicle drive device 20 according to an embodiment of the present invention. As shown in the figure, the drive device 20 of the present embodiment includes an engine 22, a planetary gear 30 connected to a crankshaft 24 as an output shaft of the engine 22, a motor 40 capable of generating electricity connected to the planetary gear 30, and a planetary gear. 30 and a CVT 50 as an automatic transmission connected to drive wheels 66a and 66b via a differential gear 64, and a hybrid electronic control unit 70 for controlling the entire apparatus.

  The engine 22 is an internal combustion engine that outputs power using a hydrocarbon fuel such as gasoline or light oil. The crankshaft 24 of the engine 22 generates electric power to be supplied to an auxiliary machine (not shown) and starts the engine 22. A starter motor 26 is attached by a belt 28. Operation control of the engine 22, for example, fuel injection control, ignition control, intake air amount adjustment control, and the like are performed by an engine electronic control unit (hereinafter referred to as engine ECU) 29. The engine ECU 29 communicates with the hybrid electronic control unit 70, controls the operation of the engine 22 by a control signal from the hybrid electronic control unit 70, and, if necessary, transmits data related to the operating state of the engine 22 to the hybrid electronic control. Output to unit 70.

  The planetary gear 30 includes an external gear sun gear 31, an internal gear ring gear 32 disposed concentrically with the sun gear 31, a first pinion gear 33 meshing with the sun gear 31, the first pinion gear 33, the ring gear 32, and the like. A meshing second pinion gear 34, a carrier 35 that holds the first pinion gear 33 and the second pinion gear 34 so as to rotate and revolve freely, and perform differential action with the sun gear 31, the ring gear 32, and the carrier 35 as rotational elements. The crankshaft 24 of the engine 22 is connected to the sun gear 31 of the planetary gear 30, and the rotating shaft 41 of the motor 40 is connected to the carrier 35. The output of the engine 22 is input from the sun gear 31 and the motor 40 is connected via the carrier 35. And output can be exchanged. The carrier 35 can be connected to the input shaft 51 of the CVT 50 by the clutch C1 and the ring gear 32 by the clutch C2. By connecting the clutch C1 and the clutch C2, the sun gear 31, the ring gear 32, and the carrier 35 are connected. The differential by the two rotating elements is prohibited, and the crankshaft 24 of the engine 22, the rotary shaft 41 of the motor 40, and the input shaft 51 of the CVT 50 are made a single rotary body. The planetary gear 30 is also provided with a brake B1 that fixes the ring gear 32 to the case 39 and prohibits its rotation.

  The motor 40 is configured, for example, as a known synchronous generator motor that can be driven as a generator and can be driven as an electric motor, and exchanges electric power with the secondary battery 44 via an inverter 43. The motor 40 is driven and controlled by a motor electronic control unit (hereinafter referred to as a motor ECU) 49. The motor ECU 49 manages signals necessary for driving and controlling the motor 40 and the secondary battery 44. A motor that detects necessary signals, for example, a signal from a rotational position detection sensor 45 that detects the rotational position of the rotor of the motor 40, a phase current applied to the motor 40 detected by a current sensor (not shown), and a temperature of the motor 40. A signal from the temperature sensor 42, a voltage between terminals from a voltage sensor 46 installed between terminals of the secondary battery 44, a charge / discharge current from a current sensor 47 attached to a power line from the secondary battery 44, a secondary The battery temperature or the like from the temperature sensor 48 attached to the battery 44 is input, and the motor ECU 49 switches to the inverter 43. Control signal is output. The motor ECU 49 calculates the remaining capacity (SOC) based on the integrated value of the charge / discharge current detected by the current sensor 47 in order to manage the secondary battery 44. The motor ECU 49 is in communication with the hybrid electronic control unit 70, and controls the drive of the motor 40 by a control signal from the hybrid electronic control unit 70, and the operation state of the motor 40 and the secondary battery 44 as necessary. Is output to the hybrid electronic control unit 70.

  The CVT 50 includes a primary pulley 53 that can be changed in groove width and connected to an input shaft 51 as an input shaft, a secondary pulley 54 that is also changeable in groove width and connected to an output shaft 52 as a drive shaft, and a primary pulley. 53 and the secondary pulley 54, a belt 55, a first actuator 56 and a second actuator 57 that change the groove widths of the primary pulley 53 and the secondary pulley 54, and the first actuator 56 and the second actuator 57. By changing the groove widths of the primary pulley 53 and the secondary pulley 54, the power of the input shaft 51 is changed steplessly and output to the output shaft 52. Control of the transmission ratio of the CVT 50 is performed by a CVT electronic control unit (hereinafter referred to as CVTECU) 59. The CVTECU 59 receives the rotational speed of the input shaft 51 from the rotational speed sensor 61 attached to the input shaft 51 and the rotational speed of the output shaft 52 from the rotational speed sensor 62 attached to the output shaft 52. A drive signal to the first actuator 56 and the second actuator 57 is output from the CVTECU 59. The CVTECU 59 is in communication with the hybrid electronic control unit 70, controls the transmission ratio of the CVT 50 by a control signal from the hybrid electronic control unit 70, and transmits data regarding the operating state of the CVT 50 as necessary. Output to the control unit 70.

  The hybrid electronic control unit 70 is configured as a microprocessor centered on the CPU 72, and in addition to the CPU 72, a ROM 74 for storing processing programs, a RAM 76 for temporarily storing data, an input / output port and communication not shown. And a port. The hybrid electronic control unit 70 includes a shift position sensor 81 that detects the rotational speed Nin of the input shaft 51 from the rotational speed sensor 61, the rotational speed Nout of the output shaft 52 from the rotational speed sensor 62, and the operating position of the shift lever 80. Shift position SP from the vehicle, accelerator pedal position A from the accelerator pedal position sensor 83 that detects the amount of depression of the accelerator pedal 82, brake pedal position BP from the brake pedal position sensor 85 that detects the amount of depression of the brake pedal 84, vehicle speed sensor A vehicle speed V from 86, an oil temperature from an oil temperature sensor 87 attached to an oil pan containing cooling oil such as each gear, motor 40, CVT 50, and the like are input via an input port. Further, the hybrid electronic control unit 70 outputs a drive signal to the clutch C1 and the clutch C2, a drive signal to the brake B1, and the like via an output port. As described above, the hybrid electronic control unit 70 is connected to the engine ECU 29, the motor ECU 49, and the CVTECU 59 via the communication port, and exchanges various control signals and data with the engine ECU 29, the motor ECU 49, and the CVTECU 59. ing.

  Next, the operation of the drive device 20 of the present embodiment configured as described above, particularly the operation during the direct running where the clutch C1 and the clutch C2 are in the connected state will be described. FIG. 2 is a flowchart showing an example of a control routine executed by the hybrid electronic control unit 70. This routine is executed at a predetermined timing when the vehicle is directly connected and when the secondary battery is being charged (that is, the motor 40 is in a power generation state).

  When this control routine is executed, first, the CPU 72 of the hybrid electronic control unit 70 first detects the accelerator opening A detected by the accelerator pedal position sensor 83, the vehicle speed V detected by the vehicle speed sensor 86, the rotational speed sensor 61, Signals necessary for control such as the rotational speed Nin of the input shaft 51 detected by the rotational speed sensor 62, the rotational speed Nout of the output shaft 52, the remaining capacity (SOC) of the secondary battery 44 calculated by the motor ECU 49 and input by communication. Is executed (step S100). Subsequently, a target power Pd * for driving required for the drive shaft is calculated based on the read accelerator opening A and vehicle speed V (step S110). For calculating the target power Pd *, a relational expression for obtaining the target power Pd * may be obtained by experiments using the accelerator opening A and the vehicle speed V as variables, and the relational expression may be used to calculate the target power Pd *. The relationship between the degree A, the vehicle speed V, and the target power Pd * is obtained by experiments and stored in the ROM 74 in advance as a target power map. When the accelerator opening A and the vehicle speed V are given, the target power stored in the ROM 74 is stored. The corresponding target power Pd * may be derived from the map. Subsequently, the target power Pb * required for the motor 40 is calculated based on the remaining battery charge SOC (step S120). Then, the target engine output Pe * is calculated in consideration of the transmission efficiency and the like in the sum of the target power Pd * and the target power Pb * (step S130).

  Thereafter, the target engine torque Te *, the target input shaft speed Nin *, and the motor torque command Tm * are set according to the target engine output Pe * and the target power Pb * (step S140). That is, the target engine torque Te * and the target engine speed Ne * are calculated so that the fuel efficiency becomes the optimum point among the operating points of the engine 22 that can output the target engine output Pe *, and the direct driving is performed. Therefore, since the crankshaft 24 of the engine 22, the rotation shaft 41 of the motor 40, and the input shaft 51 of the CVT 50 are mechanically connected without slipping, the same value as the target engine speed Ne * is set to the target input shaft rotation of the CVT 50. A value obtained by dividing the target power Pb * of the motor 40 by the target motor rotational speed (= Ne * = Nin *) is set as the torque command Tm * of the motor 40.

  Next, the motor temperature input from the motor temperature sensor 42 and the oil temperature input from the oil temperature sensor 87 are read (step S150), and the correction coefficient VCVT of the target input shaft rotational speed Nin * according to the motor temperature and oil temperature. Is obtained (step S160). Here, since this routine is executed during direct running, the input shaft rotation speed, the motor rotation speed, and the engine rotation speed match. Therefore, when the target input shaft speed Nin * is corrected, the motor speed and the engine speed are also corrected as a result.

  The correction coefficient VCVT can be obtained, for example, as follows. That is, for the motor 40, an upper limit temperature (allowable limit temperature) that can be used is calculated in consideration of the operation efficiency, operation stability, and the like by experiments in advance, and the motor overheat prevention is performed so as not to exceed the allowable limit temperature. The target input shaft rotation speed correction coefficient map is created. FIG. 3 is an example of this map. This map defines the relationship between the motor temperature, the oil temperature (motor cooling medium temperature), and the correction coefficient VCVT. The higher the motor temperature, the larger the correction coefficient VCVT, and the higher the oil temperature. The correction coefficient VCVT is determined to be large. The correction coefficient VCVT is a numerical value of 1 or more. If both the motor temperature and the oil temperature are sufficiently low, the correction coefficient VCVT is set to “1.0” and no substantial correction is performed.

  By the way, the relationship between the power generation amount required for the motor 40, the motor torque, and the motor rotation speed is expressed by power generation amount = motor torque × motor rotation speed. For this reason, when the same power generation amount is obtained, if the motor rotation speed is decreased, the motor torque increases and the heat generation amount increases. However, if the motor rotation speed is increased, the motor torque decreases and the heat generation amount decreases. On the other hand, from the viewpoint of optimizing the fuel consumption of the engine 22, it is preferable to keep the engine speed low. Therefore, during direct running, the motor speed decreases accordingly, and the motor torque increases accordingly. The amount of heat generated increases easily. However, it is not preferable that the motor 40 exceeds the allowable limit temperature due to the heat generated by the motor 40. Therefore, in order to prevent the motor 40 from exceeding the allowable limit temperature, the amount of heat generated by the motor 40 is reduced by increasing the motor rotation speed and reducing the motor torque even if the same power generation amount is obtained. Here, increasing the motor rotation speed is nothing but increasing the input shaft rotation speed and engine rotation speed of the CVT 50 during direct-coupled travel. Therefore, the higher the motor temperature or the oil temperature at which the motor 40 is likely to exceed the allowable limit temperature, the larger the correction coefficient VCVT and the larger the target input shaft speed Nin * of the CVT 50, and the absolute value of the motor torque. The motor heat generation amount is suppressed by making it smaller.

  Now, after calculating the correction coefficient VCVT in this way, a value (Nin * × VCVT) obtained by multiplying the correction coefficient VCVT by the target input shaft speed Nin * obtained in step S140 is set as a new target input shaft speed Nin *. (Step S170). Subsequently, it is determined whether or not the target input shaft rotational speed Nin * is equal to or smaller than a value (Nout × γmax) obtained by multiplying the output shaft rotational speed Nout of the CVT 50 input in step S100 by the maximum value γmax of the transmission ratio of the CVT 50 ( In step S180), if the determination is affirmative, the process proceeds to step S200, and if the determination is negative, the gear ratio control cannot be performed with the target input shaft speed Nin *, so that guard processing is performed with Nout × γmax as the new target input shaft speed Nin *. (Step S190), and then the process proceeds to step S200.

  In step S200, the target engine torque Te * and the torque command Tm * of the motor 40 are corrected in accordance with the corrected target input shaft speed Nin * (step S200). That is, the corrected target input shaft rotational speed Nin * is also a target value of the engine rotational speed and the motor rotational speed during direct running, so that the target engine torque Te * is set to Pe * to obtain the target engine output Pe *. / Nin *, and in order to obtain the target power Pb * of the motor 40, the torque command Tm * of the motor 40 is set to Pb * / Nin *. Thereafter, engine control, CVT gear ratio control, and motor control are performed using the target values Te *, Nin *, and Tm * thus obtained (step S210), and this routine is terminated.

  Specifically, the hybrid electronic control unit 70 controls the engine ECU 29 with the target torque Te *, the CVTECU 59 with the target input shaft speed Nin *, and the motor ECU 49 with the torque command Tm *. Output as. Then, the engine ECU 29 controls the fuel injection amount, ignition timing, intake air amount, etc. of the engine 22 so that the target torque Te * is output from the engine 22, and the input shaft 51 rotates at the target input shaft rotational speed Nin *. The CVTECU 59 controls the gear ratio γ of the CVT 50 according to the output shaft rotational speed Nout, and the motor ECU 49 controls the motor 40 so that the torque of the torque command Tm * is output from the motor 40.

  According to the drive device 20 of the present embodiment described above, the engine 22 is configured so that the output shaft 52 of the CVT 50 serving as the drive shaft outputs the target power Pd * and the motor 40 outputs the target power Pb * during the direct running. While controlling the motor 40 and the CVT 50, the speed of the motor 40 is controlled so as not to exceed a predetermined allowable limit temperature by changing the gear ratio of the CVT 50 according to the temperature of the motor 40. The motor 40 can be prevented from being overheated in a power generation state where the battery is likely to overheat, that is, even during charging of the secondary battery 44. Further, since the gear ratio control of the CVT 50 is performed in consideration of the oil temperature in addition to the temperature of the motor 40, the motor 40 can be more reliably prevented from being heated. Further, as shown in FIG. 3, it is determined that the correction coefficient VCVT is increased as the temperature of the motor 40 is higher or the oil temperature is higher. Therefore, as the temperature is higher, the rotation speed of the input shaft 51 of the CVT 50 is increased. The absolute torque value of the motor 40 connected to the input shaft 51 is reduced, and the heat generation of the motor 40 is suppressed.

  In the driving device 20 of the above-described embodiment, the target input shaft rotational speed Nin * is not substantially corrected until one or both of the motor temperature and the oil temperature exceed a predetermined threshold value. Gear ratio control is performed (correction coefficient VCVT is set to “1.0”), and when the predetermined threshold value is exceeded, the target input shaft speed Nin * is substantially corrected (correction coefficient VCVT). Gear ratio control may be performed. Even in this case, overheating of the motor 40 can be prevented. The motor temperature threshold and the oil temperature threshold may be determined in advance through experiments or the like.

  In the driving device 20 of the above embodiment, the correction coefficient VCVT is calculated according to the motor temperature and the oil temperature in order to more reliably prevent the motor 40 from overheating. However, the correction coefficient VCVT is calculated only according to the motor temperature. Alternatively, the correction coefficient VCVT may be calculated according to only the oil temperature.

  In the drive device 20 of the above-described embodiment, the above-described control routine is executed during charging during direct-coupled travel (during motor power generation). However, the above-described control routine is performed during discharge during direct-coupled travel (motor driving). May be executed.

  In the control routine for direct running that is executed by the drive device 20 of the above embodiment, the target power Pb * of the motor 40 calculated in step S120 is used as it is without correction. However, as shown in the flowchart of FIG. After calculating the target power Pb * of 40, it is determined whether or not the correction coefficient VCVT previously calculated in this control routine is greater than or equal to a predetermined value α (step S121). If the correction coefficient VCVT is less than the predetermined value α, In particular, assuming that it is not necessary to correct the target power Pb *, the charge amount correction coefficient Vchg is set to “1.0” (step S123), and then the process proceeds to step S129. On the other hand, if the correction coefficient VCVT is greater than or equal to the predetermined value α There is a possibility that the temperature of the motor 40 may not be sufficiently lowered only by the gear ratio control based on the target input shaft speed Nin *. Therefore, the motor temperature input from the motor temperature sensor 42 and the oil temperature input from the oil temperature sensor 87 are read (step S125), and the charge amount correction coefficient Vchg (<1. 0) is obtained (step S127), and then the process proceeds to step S129. Here, the charge amount correction coefficient Vchg can be obtained, for example, as follows. That is, in order to obtain the same power generation amount for the motor 40 in advance, even if the target input shaft rotation speed Nin * is increased and the motor torque is decreased to reduce the heat generation amount of the motor 40, the allowable temperature limit may be exceeded. In this case, the correction coefficient VCVT is set to a predetermined value α, while a charge amount correction coefficient map for preventing motor overheating is generated so that the motor 40 does not exceed the allowable limit temperature in that case. To do. FIG. 5 is an example of this map. This map defines the relationship between the motor temperature, the oil temperature (motor cooling medium temperature), and the charge amount correction coefficient Vchg. The higher the motor temperature, the smaller the charge amount correction coefficient Vchg. It is determined that the charge amount correction coefficient Vchg decreases as the oil temperature increases. In step S129, a value obtained by multiplying the target power Pb * by the charge amount correction coefficient Vchg is set as a new target power Pb *, and then the processing after step S130 already described is executed. If the correction coefficient VCVT is less than the predetermined value α, the charge amount correction coefficient Vchg is “1.0”, so that no substantial correction is performed. According to the above control routine, even if the temperature ratio of the CVT 50 alone does not sufficiently lower the temperature of the motor 40, in that case, the temperature of the motor 40 is further lowered by reducing the target power Pb * of the motor 40. Therefore, overheating of the motor 40 can be prevented more reliably.

[Second Embodiment]
Since the configuration of the present embodiment is the same as that of the first embodiment, the description thereof is omitted, and here, the operation when the shift lever 80 is set to the P range will be described. At this time, the input shaft 51 of the CVT 50 is prohibited from rotating when the ring gear 32 is fixed to the case 39 by the brake B1, and is separated from the carrier 35 by the clutch C1. It is separated from the rotating shaft 41 of the motor 40. Further, the crankshaft 24 of the engine 22 and the rotating shaft 41 of the motor 40 are connected to each other through a sun gear 31 and first and second pinion gears 33 and 34 so as to be able to transmit power. Note that the clutch C2 may be either connected or not connected.

  FIG. 6 is a flowchart showing an example of a control routine executed by the hybrid electronic control unit 70. This routine is executed at every predetermined timing if the shift position SP from the shift position sensor 81 is in the P range. When this control routine is executed, the CPU 72 of the hybrid electronic control unit 70 first reads a signal necessary for control, such as the remaining capacity (SOC) of the secondary battery 44 calculated by the motor ECU 49 and input by communication. Is executed (step S300). Subsequently, the target power Pb * required for the motor is calculated based on the remaining battery charge SOC (step S310). Then, target engine output Pe * is calculated in consideration of transmission efficiency and the like for target power Pb * (step S320), and the fuel efficiency is the optimum point among the operating points of engine 22 that can output this target engine output Pe *. The target torque Te * and the target engine speed Ne * of the engine 22 are calculated so as to become (step S330).

  Next, the motor temperature input from the motor temperature sensor 42 and the oil temperature input from the oil temperature sensor 87 are read (step S340), and the correction coefficient VNET for the target engine speed Ne * is set according to the motor temperature and oil temperature. Obtained (step S350). The correction coefficient VNET can be obtained as follows, for example. That is, for the motor 40, an upper limit temperature (allowable limit temperature) that can be used in consideration of operation efficiency, operation stability, and the like is obtained in advance through experiments and the like, and the motor overheat prevention is performed so as not to exceed the allowable limit temperature. The target engine speed correction coefficient map is created. FIG. 7 is an example of this map. This map defines the relationship between motor temperature, oil temperature (motor coolant temperature), and correction coefficient VNET. The higher the motor temperature, the larger the correction coefficient VNET, and the higher the oil temperature. The correction coefficient VNET is determined so as to increase. The correction coefficient VNET is a numerical value equal to or greater than 1. If both the motor temperature and the oil temperature are sufficiently low, the correction coefficient VNET is set to “1.0” and no substantial correction is performed.

  By the way, as already described in the first embodiment, when the same power generation amount is obtained, if the motor rotational speed is decreased, the motor torque increases and the heat generation amount increases. However, if the motor rotational speed is increased, the motor torque decreases. The calorific value is reduced. On the other hand, from the viewpoint of optimizing the fuel consumption of the engine 22, it is preferable to keep the engine speed in the P range small. Accordingly, the motor speed is also reduced, and the motor torque is increased accordingly, and the motor heat is generated. The amount tends to increase. However, it is not preferable that the motor 40 exceeds the allowable limit temperature due to the heat generated by the motor 40. Therefore, in order to prevent the motor 40 from exceeding the allowable limit temperature, the amount of heat generated by the motor 40 is reduced by increasing the motor rotation speed and reducing the motor torque even if the same power generation amount is obtained. Here, increasing the motor speed is nothing but increasing the engine speed in the P range. Accordingly, the higher the motor temperature or oil temperature at which the motor 40 is likely to exceed the allowable limit temperature, the larger the correction coefficient VNET is set, the larger the target engine speed Ne * is set, and the motor torque is reduced to reduce the motor heat generation amount. It suppresses.

  Now, after calculating the correction coefficient VNET in this way, a value (Ne * × VNET) obtained by multiplying the correction coefficient VNET by the target engine speed Ne * obtained in step S330 is set as a new target engine speed Ne * (step). S360). Subsequently, the target engine torque Te * for obtaining the target engine output Pe * is calculated from the target engine speed Ne *, and the sun gear 31 and the first and second pinion gears 33 and 34 are calculated from the target engine speed Ne *. The target motor speed Nm * is calculated based on the gear ratio of the motor 40, and the torque command Tm * of the motor 40 is calculated from the target motor speed Nm * and the target power Pb * (step S370). Thereafter, engine control and motor control are performed using the target values Te * and Tm * thus obtained (step S380), and this routine is terminated. In this routine, the torque of the motor 40 is controlled to become the torque command Tm *, and as a result, the engine speed is controlled to become the target engine speed Ne *.

  According to the drive device 20 of the present embodiment described above, power can be transmitted between the crankshaft 24 and the rotary shaft 41 in a state where the input shaft 51 of the CVT 50 is disconnected from the crankshaft 24 of the engine 22 and the rotary shaft 41 of the motor 40. When the rotation of the input shaft 51 is stopped, the temperature of the motor 40 is controlled so as not to exceed a predetermined allowable limit temperature by changing the engine speed according to the temperature of the motor 40. Therefore, overheating of the motor 40 can be prevented even when the motor 40 is in a power generation state where the motor 40 is likely to be overheated during parking, for example, when the secondary battery 44 is being charged. Further, since the engine speed is controlled in consideration of the oil temperature in addition to the temperature of the motor 40, the motor 40 can be more reliably prevented from being heated. Further, as shown in FIG. 7, the correction coefficient VNET is determined to increase as the temperature of the motor 40 increases or as the oil temperature increases. Therefore, the engine speed increases as these temperatures increase, and the crankshaft 24 of the engine 22 increases. The absolute value of the torque of the rotating shaft 41 of the motor 40 connected to is reduced, and the heat generation of the motor 40 is suppressed.

  In the driving device 20 of the above-described embodiment, the target engine speed Ne * is not substantially corrected (correction coefficient) until one or both of the motor temperature and the oil temperature exceed a predetermined threshold value. Control is performed with VNET set to “1.0”, and the target engine speed Ne * is substantially corrected when the predetermined threshold value is exceeded (the correction coefficient VNET is set to> 1.0). ) Control may be performed. Even in this case, overheating of the motor 40 can be prevented. The motor temperature threshold and the oil temperature threshold may be determined in advance through experiments or the like.

  In the driving device 20 of the above embodiment, the correction coefficient VNET is calculated according to the motor temperature and the oil temperature in order to more reliably prevent the motor 40 from overheating. However, the correction coefficient VNET is calculated only according to the motor temperature. Alternatively, the correction coefficient VNET may be calculated according to only the oil temperature.

  In the control routine in the P range executed by the drive device 20 of the above embodiment, the target power Pb * of the motor 40 calculated in step S310 is used as it is without correction. However, as shown in the flowchart of FIG. After calculating the target power Pb * of 40, it is determined whether or not the correction coefficient VNET previously calculated in the control routine in the P range is equal to or greater than a predetermined value β (step S311), and the correction coefficient VNET is a predetermined value. If it is less than β, it is considered that there is no need to correct the target power Pb * in particular, the charge amount correction coefficient Vchg is set to “1.0” (step S313), and then the process proceeds to step S319, while the correction coefficient VNET is a predetermined value. If it is equal to or greater than β, it is considered that there is a possibility that the temperature of the motor 40 may not be sufficiently lowered only by the engine speed control. The motor temperature input from 42 and the oil temperature input from the oil temperature sensor 87 are read (step S315), and the charge amount correction coefficient Vchg (<1.0) is obtained according to the motor temperature and oil temperature (step S317). ), And then proceeds to step S319. Here, the charge amount correction coefficient Vchg and the predetermined value β can be obtained in the same manner as the charge amount correction coefficient Vchg and the predetermined value α already described as the modification of the first embodiment, and the charge amount for preventing motor overheating is obtained. For example, the correction coefficient map similar to that shown in FIG. 5 can be used. In step S319, a value obtained by multiplying the target power Pb * by the charge amount correction coefficient Vchg is set as a new target power Pb *. Thereafter, the processing after step S320 described above is executed. If the correction coefficient VNET is less than the predetermined value β, the charge amount correction coefficient Vchg is “1.0”, so that no substantial correction is performed. According to the above control routine, even if the engine speed control alone does not sufficiently lower the temperature of the motor 40, in that case, the temperature of the motor 40 is further lowered by reducing the target power Pb * of the motor 40. Therefore, overheating of the motor 40 can be prevented more reliably.

  The embodiment of the present invention has been described above, but the present invention is not limited to the embodiment as described above, and can be implemented in various forms without departing from the gist of the present invention. Of course.

It is a block diagram which shows the outline of a structure of the vehicle-mounted drive device 20 which is 1st Embodiment. 3 is a flowchart showing an example of a control routine executed by a hybrid electronic control unit 70. It is explanatory drawing which shows an example of a target input shaft rotation speed correction coefficient map. It is a flowchart which shows an example of the control routine of the modification of 1st Embodiment. It is explanatory drawing which shows an example of a charge amount correction coefficient map. It is a flowchart which shows an example of the control routine of 2nd Embodiment. It is explanatory drawing which shows an example of a target engine speed correction coefficient map. It is a flowchart which shows an example of the control routine of the modification of 2nd Embodiment.

Explanation of symbols

  20 drive unit, 22 engine, 24 crankshaft, 26 starter motor, 28 belt, 29 engine electronic control unit (engine ECU), 30 planetary gear, 31 sun gear, 32 ring gear, 33 first pinion gear, 34 second pinion gear, 35 carrier , 39 Case, 40 Motor, 41 Rotating shaft, 42 Motor temperature sensor, 43 Inverter, 44 Secondary battery, 45 Rotation position detection sensor, 46 Voltage sensor, 47 Current sensor, 48 Temperature sensor, 49 Motor electronic control unit (Motor ECU), 50 CVT, 51 input shaft, 52 output shaft, 53 primary pulley, 54 secondary pulley, 55 belt, 56 first actuator, 57 second actuator, 59 C Electronic control unit for VT (CVTECU), 61, 62 Speed sensor, 64 Differential gear, 66a, 66b Driving wheel, 70 Hybrid electronic control unit, 72 CPU, 74 ROM, 76 RAM, 80 Shift lever, 81 Shift position sensor , 82 Accelerator pedal, 83 Accelerator pedal position sensor, 84 Brake pedal, 85 Brake pedal position sensor, 86 Vehicle speed sensor, 87 Oil temperature sensor, C1, C2 clutch, B1 brake.

Claims (33)

An automatic transmission that shifts between an input shaft and a drive shaft, an internal combustion engine that includes an output shaft connected to the input shaft, and a generator motor that includes a rotary shaft connected to the input shaft. A driving device comprising:
While controlling the internal combustion engine, the generator motor and the automatic transmission so that the drive shaft is in a target drive state and the generator motor is in a target operating state, the temperature of the generator motor exceeds a predetermined allowable limit temperature. A drive device comprising an operation control means for controlling a gear ratio of the automatic transmission in accordance with a temperature of the generator motor so as not to exist. The drive device according to claim 1,
The output shaft of the internal combustion engine can be mechanically connected to the input shaft without slipping,
The rotating shaft of the generator motor can be mechanically connected to the input shaft without slipping,
The operation control means is configured such that when the input shaft of the automatic transmission, the output shaft of the internal combustion engine, and the rotating shaft of the generator motor are in a mechanical connection state without slipping, the drive shaft is in a target drive state. While controlling the internal combustion engine, the generator motor, and the automatic transmission so that the generator motor is in a target operating state, the temperature of the generator motor is controlled according to the temperature of the generator motor so as not to exceed a predetermined allowable limit temperature. A drive unit for controlling a gear ratio of the automatic transmission. The drive device according to claim 1 or 2,
Comprising temperature detection means for detecting the temperature of the generator motor;
The operation control means controls the gear ratio of the automatic transmission according to the temperature of the generator motor detected by the temperature detection means.   The drive device according to any one of claims 1 to 3, wherein the operation control unit controls a gear ratio of the automatic transmission according to a temperature of the generator motor when the generator motor is in a power generation state.   The said operation control means controls the gear ratio of the said automatic transmission according to the temperature of the said generator motor, when the temperature of the said generator motor approaches the said allowable limit temperature. Drive device.   The operation control means obtains a target rotational speed of the input shaft according to the temperature of the generator motor when controlling the gear ratio of the automatic transmission according to the temperature of the generator motor, based on the target rotational speed. The drive device according to claim 1, wherein the drive ratio of the automatic transmission is controlled.   When the operation control means controls the gear ratio of the automatic transmission according to the temperature of the generator motor, the rotation speed of the generator motor increases as the temperature of the generator motor increases in outputting the target power to the generator motor. The drive device according to any one of claims 1 to 6, wherein a target rotational speed of the input shaft is obtained so that the torque is high and the torque is low, and the speed ratio of the automatic transmission is controlled based on the target rotational speed.   The drive device according to any one of claims 1 to 7, wherein the operation control unit controls a gear ratio of the automatic transmission according to a temperature of the generator motor and a temperature of a cooling medium that cools the generator motor. The drive device according to claim 8, wherein
A medium temperature detecting means for detecting a temperature of a cooling medium for cooling the generator motor;
The driving control unit controls a gear ratio of the automatic transmission according to a temperature of the generator motor and a temperature of the cooling medium detected by the medium temperature detecting unit.   The operation control means controls the gear ratio of the automatic transmission according to the temperature of the generator motor and the temperature of the cooling medium, and controls the input shaft according to the temperature of the generator motor and the temperature of the cooling medium. The drive device according to claim 8 or 9, wherein a target rotational speed is obtained and a gear ratio of the automatic transmission is controlled based on the target rotational speed.   When the operation control means controls the gear ratio of the automatic transmission according to the temperature of the generator motor and the temperature of the cooling medium, the higher the temperature of the generator motor when the target electric power is output to the generator motor Alternatively, the target rotational speed of the input shaft is obtained so that the rotational speed of the generator motor increases and the torque decreases as the temperature of the cooling medium increases, and the transmission ratio of the automatic transmission is controlled based on the target rotational speed. The drive device in any one of 8-10.   When the operation control means obtains the target rotational speed of the input shaft and controls the gear ratio of the automatic transmission based on the target rotational speed, the target rotational speed of the input shaft is equal to the speed ratio of the automatic transmission. The drive device according to claim 6, 7, 10, or 11, wherein a guard is applied so as not to exceed an upper limit target rotational speed obtained from a maximum value and an actual rotational speed of the drive shaft.   The operation control means controls the speed ratio of the automatic transmission so that the temperature of the generator motor does not exceed a predetermined allowable limit temperature, while the control limit means only controls the speed ratio of the automatic transmission. The drive device according to any one of claims 1 to 12, wherein the target electric power of the generator motor is lowered if there is a risk of exceeding the temperature. An automatic transmission that shifts between an input shaft and a drive shaft, an internal combustion engine that includes an output shaft connected to the input shaft, and a generator motor that includes a rotary shaft connected to the input shaft. A driving device comprising:
Input shaft rotation stopping means for stopping rotation of the input shaft;
Power transmission means for connecting the output shaft of the internal combustion engine and the rotary shaft of the generator motor so that power can be transmitted in a state where the input shaft of the automatic transmission is separated from the output shaft of the internal combustion engine and the rotary shaft of the generator motor. When,
The power transmission means can transmit power between the output shaft of the internal combustion engine and the rotary shaft of the generator motor in a state where the input shaft of the automatic transmission is separated from the output shaft of the internal combustion engine and the rotary shaft of the generator motor. When the input shaft rotation stopping means is connected and rotation of the input shaft is stopped, the internal combustion engine is controlled in accordance with the temperature of the generator motor so that the temperature of the generator motor does not exceed a predetermined allowable limit temperature. A drive device comprising: an operation control means for controlling the rotational speed of the engine. An automatic transmission that shifts between an input shaft and a drive shaft, an internal combustion engine that includes an output shaft connected to the input shaft, and a generator motor that includes a rotary shaft connected to the input shaft. A driving device comprising:
Non-driving state control means for bringing the driving shaft into a non-driving state;
Power transmission means for connecting the output shaft of the internal combustion engine and the rotary shaft of the generator motor so that power can be transmitted in a state where the input shaft of the automatic transmission is separated from the output shaft of the internal combustion engine and the rotary shaft of the generator motor. When,
The power transmission means can transmit power between the output shaft of the internal combustion engine and the rotary shaft of the generator motor in a state where the input shaft of the automatic transmission is separated from the output shaft of the internal combustion engine and the rotary shaft of the generator motor. The internal combustion engine is connected according to the temperature of the generator motor so that the temperature of the generator motor does not exceed a predetermined allowable limit temperature when the drive shaft is in the non-drive state by the non-drive state control means And a driving control means for controlling the rotation speed of the driving device. The drive device according to claim 14 or 15,
Comprising temperature detection means for detecting the temperature of the generator motor;
The operation control means controls the rotational speed of the internal combustion engine according to the temperature of the generator motor detected by the temperature detection means.   The drive device according to any one of claims 14 to 16, wherein the operation control means controls the rotational speed of the internal combustion engine according to the temperature of the generator motor when the automatic transmission is in a P range.   The drive device according to any one of claims 14 to 17, wherein the operation control means controls the rotational speed of the internal combustion engine according to a temperature of the generator motor when the generator motor is in a power generation state.   The drive according to any one of claims 14 to 18, wherein the operation control means controls the rotational speed of the internal combustion engine according to the temperature of the generator motor when the temperature of the generator motor approaches the allowable limit temperature. apparatus.   When the operation control means controls the rotational speed of the internal combustion engine according to the temperature of the generator motor, the rotational speed of the generator motor increases as the temperature of the generator motor increases when the generator motor outputs target power. The drive device according to any one of claims 14 to 19, wherein a target rotational speed of the internal combustion engine is obtained so that the torque is high and low, and the rotational speed of the internal combustion engine is controlled so as to be the target rotational speed.   The drive device according to any one of claims 14 to 20, wherein the operation control means controls the rotational speed of the internal combustion engine in accordance with a temperature of the generator motor and a temperature of a cooling medium that cools the generator motor. The drive device according to claim 21, wherein
A medium temperature detecting means for detecting a temperature of a cooling medium for cooling the generator motor;
The operation control means controls the rotational speed of the internal combustion engine in accordance with the temperature of the generator motor and the temperature of the cooling medium detected by the medium temperature detection means.   The operation control means controls the temperature of the generator motor or the cooling medium when the generator motor outputs target power when controlling the rotational speed of the internal combustion engine according to the temperature of the generator motor and the temperature of the cooling medium. 23. The rotational speed of the internal combustion engine is controlled so that the target rotational speed of the internal combustion engine is obtained so that the rotational speed of the generator motor increases and the torque decreases as the temperature of the engine increases. Drive device.   The operation control means controls the rotational speed of the internal combustion engine so that the temperature of the generator motor does not exceed a predetermined allowable limit temperature, while only controlling the rotational speed of the internal combustion engine sets the allowable limit temperature. The drive device according to any one of claims 14 to 23, wherein if there is a risk of exceeding, the target electric power of the generator motor is lowered. An automatic transmission that shifts between an input shaft and a drive shaft, an internal combustion engine that includes an output shaft connected to the input shaft, and a generator motor that includes a rotary shaft connected to the input shaft. A driving device comprising:
A drive device comprising: an operation control unit that performs combined control of the internal combustion engine, the generator motor, and the automatic transmission according to the temperature of the generator motor so that the temperature of the generator motor does not exceed a predetermined allowable limit temperature. An automatic transmission that shifts between an input shaft and a drive shaft, an internal combustion engine that includes an output shaft connected to the input shaft, and a generator motor that includes a rotary shaft connected to the input shaft. A driving device comprising:
A drive apparatus comprising: an operation control unit that performs combined control of the internal combustion engine, the generator motor, and the automatic transmission according to the temperature of the generator motor.   The drive device according to any one of claims 1 to 26, wherein the automatic transmission is a continuously variable transmission.   The output shaft of the internal combustion engine and the rotating shaft of the generator motor are each configured to be mechanically connected to the input shaft of the automatic transmission without slippage via a planetary gear mechanism. The drive device according to any one of claims 1 to 27. An automatic transmission that shifts between an input shaft and a drive shaft, an internal combustion engine that includes an output shaft connected to the input shaft, and a generator motor that includes a rotary shaft connected to the input shaft. An operation control method for a drive device, comprising:
While controlling the internal combustion engine, the generator motor and the automatic transmission so that the drive shaft is in a target drive state and the generator motor is in a target operating state, the temperature of the generator motor exceeds a predetermined allowable limit temperature. An operation control method for a driving device that controls a gear ratio of the automatic transmission in accordance with a temperature of the generator motor so as not to exist. An automatic transmission that shifts between an input shaft and a drive shaft, an internal combustion engine that includes an output shaft connected to the input shaft, and a generator motor that includes a rotary shaft connected to the input shaft. An operation control method for a drive device, comprising:
The input shaft of the automatic transmission is connected to the output shaft of the internal combustion engine and the rotary shaft of the generator motor in a state where the input shaft of the automatic transmission is separated from the output shaft of the internal combustion engine and the rotary shaft of the generator motor. When the rotation of the shaft is stopped, the rotational speed of the internal combustion engine is controlled according to the temperature of the generator motor so that the temperature of the generator motor does not exceed a predetermined allowable limit temperature. Method. An automatic transmission that shifts between an input shaft and a drive shaft, an internal combustion engine that includes an output shaft connected to the input shaft, and a generator motor that includes a rotary shaft connected to the input shaft. An operation control method for a drive device, comprising:
The output shaft of the internal combustion engine and the rotary shaft of the generator motor are connected so as to be able to transmit power while the input shaft of the automatic transmission is separated from the output shaft of the internal combustion engine and the rotary shaft of the generator motor, and the drive An operation control method for a drive device that controls the rotational speed of the internal combustion engine according to the temperature of the generator motor so that the temperature of the generator motor does not exceed a predetermined allowable limit temperature when the shaft is in a non-driven state . An automatic transmission that shifts between an input shaft and a drive shaft, an internal combustion engine that includes an output shaft connected to the input shaft, and a generator motor that includes a rotary shaft connected to the input shaft. An operation control method for a drive device, comprising:
An operation control method for a driving device, wherein the internal combustion engine, the generator motor, and the automatic transmission are combinedly controlled according to the temperature of the generator motor so that the temperature of the generator motor does not exceed a predetermined allowable limit temperature. An automatic transmission that shifts between an input shaft and a drive shaft, an internal combustion engine that includes an output shaft connected to the input shaft, and a generator motor that includes a rotary shaft connected to the input shaft. An operation control method for a drive device, comprising:
An operation control method for a drive device that performs combined control of the internal combustion engine, the generator motor, and the automatic transmission according to the temperature of the generator motor.

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