JP3823066B2 - Drive device for front and rear wheel drive vehicles - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a drive device for front and rear wheel drive vehicles.
[0002]
[Prior art]
One type of driving device for automobiles is a type of front and rear wheels in which the main driving wheel side which is one of the front and rear wheels is driven by the main driving means, and the sub driving wheel side which is the other of the front and rear wheels is driven by the sub driving means. There are drive devices for wheel drive vehicles. The drive device of this type drives the main drive wheels by the main drive means during normal running to form a single drive running state of the main drive wheels, and the main drive means and By driving the auxiliary drive means, both the front and rear wheels of the vehicle (the main drive wheel and the auxiliary drive wheel) are driven together to form a front and rear wheel drive driving state, an example of which is disclosed in JP-A-2001-253256. Is proposed under the name of “vehicle drive device”.
[0003]
Specifically, the vehicle drive device is such that a front wheel side is driven by an engine as a main drive means and a rear wheel side is driven by an electric motor as a sub drive means. A generator, a low-voltage battery for storing electric power generated by the first generator, and a second generator driven by the engine, supplying electric power generated by the second generator to the electric motor to rear wheels Configured to drive the side.
[0004]
According to the vehicle drive device, a long drive transmission mechanism such as a long drive shaft for transmitting the driving force of the engine to the rear wheel side, which is indispensable in a normal four-wheel drive vehicle, becomes unnecessary. The weight of the vehicle can be reduced and energy can be saved significantly.
[0005]
[Problems to be solved by the invention]
By the way, in this type of drive device, as recognized by the vehicle drive device described above, the drive state on the side of the sub drive wheels by the sub drive means is not limited even when the brake is activated during both front and rear wheel drive travel. It has been continued. In such a front and rear wheel drive vehicle, when such a state occurs, the brake and the sub drive means interfere with each other, impairing the durability of the drive device, causing damage to the sub drive means, and consuming useless energy. Become. The object of the present invention is therefore to address these problems.
[0006]
[Means for Solving the Problems]
The present invention relates to a drive device for a front and rear wheel drive vehicle, and includes a main drive means for driving a main drive wheel side which is one of the front and rear wheels, and a sub drive for driving a sub drive wheel side which is the other of the front and rear wheels. The main drive wheel is driven by the main drive wheel side to form a single drive running state of the main drive wheel, and the main drive wheel drive by the main drive means and the sub drive means are The present invention is intended for application to a drive device for a front and rear wheel drive vehicle that forms a two-wheel drive running state of these two drive wheels by driving the auxiliary drive wheels.
[0007]
  Thus, the drive device for a front and rear wheel drive vehicle according to the present invention includes output control means for controlling the output from the sub drive means to the sub drive wheel side according to the operating state of the brake or the operating operation of the brake. HaveRumoIt is.
[0008]
In the drive device for a front and rear wheel drive vehicle according to the present invention, the output control means is,A control function is provided for stopping the supply of the drive source to the sub drive means when the main drive means is driven when the brake is operated.It is characterized by doing.
[0009]
In the drive device according to the present invention, the main drive means for driving the main drive wheel side which is one of the front and rear wheels, and the electric motor which is the sub drive means for driving the sub drive wheel side which is the other of the front and rear wheels, An electromagnetic clutch for connecting and disconnecting power transmission between the electric motor and the auxiliary drive means is provided, and the main drive wheel is driven by the main drive wheel while the coupling of the electromagnetic clutch is cut off. Both wheels are driven by the drive on the main drive wheel side by the main drive means and the drive on the sub drive wheel side by the sub drive means in a state where the single drive running state is formed and the electromagnetic clutch is coupled. A drive device for a front and rear wheel drive vehicle of a type that forms a drive running state can be applied.
[0010]
  In this case, the output control means is,It can be configured to have a control function for stopping the supply of electric power to the electric motor when the main drive means is driven when the brake is operated, and when the brake is operated while the vehicle is running, the electric motor And a control function for stopping the coupling of the electromagnetic clutch.
[0011]
In these driving devices according to the present invention, the electric motor includes an engine that is the main driving means and a generator that is driven by the engine to generate electric power, and controls electric power generated by the generator. It can be set as the structure which supplies electric power with respect to and drives the same electric motor.
[0012]
[Operation and effect of the invention]
The drive device for a front and rear wheel drive vehicle according to the present invention includes output control means for controlling the output from the sub drive means to the sub drive wheel side in accordance with the operating state of the brake or the operating operation of the brake. The following effects are exhibited. In other words, it is possible to prevent the interference between the brake and the sub driving means such as the electric motor and improve the durability of the driving device. Further, it is possible to prevent the drive device from being damaged when the main drive means such as the engine continues to be driven unnecessarily such as emptying, or when the parking brake is operated during traveling such as a severe mean test. In addition, when both front and rear wheel driving is not required, wasteful consumption of energy can be prevented by restricting the driving of auxiliary driving means such as an electric motor.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
The present invention relates to a drive device for a front and rear wheel drive vehicle, and includes a main drive means for driving a main drive wheel side which is one of the front and rear wheels, and a sub drive for driving a sub drive wheel side which is the other of the front and rear wheels. The main drive wheel is driven by the main drive wheel side to form a single drive running state of the main drive wheel, and the main drive wheel drive by the main drive means and the sub drive means are The present invention is intended for application to a drive device for a front and rear wheel drive vehicle that forms a two-wheel drive running state of these two drive wheels by driving the auxiliary drive wheels. There are various types of driving devices for front and rear wheel drive vehicles of this type, and in this embodiment, two types of driving devices shown in FIGS. 1 and 4 developed by the present inventors are exemplified. To do.
[0014]
FIG. 1 schematically shows a first four-wheel drive vehicle 10 configured by mounting the first drive device according to the present invention. The first driving device controls the first driving mechanism 10a that drives the front wheel side that is the main driving wheel, the second driving mechanism 10b that drives the rear wheel side that is the auxiliary driving wheel, and the second driving mechanism 10b. A device 10c is provided.
[0015]
The first drive mechanism 10a includes an engine 11 that is an internal combustion engine and a generator 12 that is a generator. In the first drive mechanism 10a, the driving force of the engine 11 is transmitted to the drive shafts 13d through the transmission 13a, the reduction gear train 13b, and the front differential 13c, and the front wheels 13e are driven by the drive shafts 13d. During this time, the engine 11 drives the generator 12 to generate electric power. The generated electric power is stored in the low voltage battery 14. The low voltage battery 14 is a battery for driving auxiliary equipment, and is, for example, a 12V battery.
[0016]
The second drive mechanism 10 b includes an electric motor 15, a DC-DC converter 16, a high voltage battery 17, and an electromagnetic clutch 18. The high voltage battery 17 is a dedicated battery for driving the electric motor 15 and is, for example, a 36V battery. The electric motor 15 is an electric motor 15 that can selectively output electrical energy and mechanical energy, and as the electric motor 15, other excitation motors, DC motors, brushless motors, and the like are appropriately employed. Can do.
[0017]
In the second drive mechanism 10b, the electric motor 15 is driven by receiving electric power, and the driving force of the electric motor 15 is transmitted to each drive shaft 19c through the reduction gear train 19a, the electromagnetic clutch 18, and the rear differential 19b. The rear wheels 19d are driven by the drive shafts 19c. Further, the electric motor 15 functions as a generator and generates regenerative power when receiving a driving force from the rear wheel 19d side. The generated regenerative power is stored in the high voltage battery 17 via the drive circuit 10c2 constituting the control device 10c.
[0018]
As shown in FIG. 2, the control device 10 c includes a throttle opening sensor S 1, a wheel speed sensor S 2, a brake sensor S 3, a high voltage battery voltage sensor S 4, a switch sensor S 5 for detecting the state of the 4WD switch, and an electric motor 15. It is connected to a motor sensor S6 that detects the rotational state, and includes an MPU (microprocessor) 10c1 and a drive circuit 10c2.
[0019]
The MPU 10c1 has a CPU and a memory for holding a control program and data for controlling the electric motor 15 and the electromagnetic clutch 18. The MPU 10c1 takes in detection signals output from the sensors S1 to S6 via the interface, The state in which the electric motor 15 and the electromagnetic clutch 18 are to be operated is determined, and the command torque for the electric motor 15 and the state in which the electric motor 15 and the electromagnetic clutch 18 are to be operated are used as command signals to the drive circuit 10c2 via the interface. Output.
[0020]
The drive circuit 10c2 controls the driving and power generation of the electric motor 15 based on a command signal from the MPU 10c1, and performs ON / OFF (coupling / disconnection) control of the electromagnetic clutch 18. The control program included in the MPU 10c1 holds an output control program for controlling the output from the electric motor to the rear wheel 19d according to the operating state of the brake or the operating operation of the brake.
[0021]
The control device 10c performs control to select operating states of the electric motor 15 and the electromagnetic clutch 18 when the 4WD switch is ON. The control device 10c includes a throttle opening sensor S1, a wheel speed sensor S2, a brake sensor S3, a voltage sensor S4 for the high voltage battery, a switch sensor S5 for detecting the state of the 4WD switch, and a motor sensor for detecting the rotational state of the electric motor 15. Based on the signal from S6, a state in which the electric motor 15 should be operated and a state in which the electromagnetic clutch 18 should be operated are determined, and a command torque for the electric motor 15 is calculated. The determination result and the command torque are output as a command signal to the drive circuit 10c2, and the drive circuit 10c2 controls the operation of the electric motor 15 and the electromagnetic clutch 18 based on the command signal.
[0022]
FIG. 3 is a flowchart for executing a control program for controlling the operation of the electric motor 15 and the electromagnetic clutch 18 by the control device 10c. If it is determined in step 101 that the 4WD switch is in the ON state, the microcomputer constituting the control device 10c determines in step 102 that the operating state of the electric motor 15 should be selected. If the microcomputer determines in step 101 that the 4WD switch is in the OFF state, the microcomputer turns off the electromagnetic clutch 18 in step 103 and ends the execution of the control program.
[0023]
In step 102, the microcomputer determines whether or not the electric motor 15 should select the power generation operation. The determination of the power generation control is performed based on the voltage of the high voltage battery 17, the wheel speed, and the operating state of the brake. The voltage of the high voltage battery 17 is less than the predetermined value, the wheel speed is less than the predetermined value, and the brake is in the operating state. If there is, it is determined as power generation control, the program proceeds to step 104, the electromagnetic clutch 18 is turned on at step 104, and the electric motor 15 is controlled to be in a power generation operable state at step 105. Thus, the electric motor 15 is driven by the driving force from the rear wheel 19d side to generate regenerative power. The generated regenerative power is stored in the high voltage battery 17 via the drive circuit 10c2 of the control device 10c, and the voltage of the high voltage battery 17 is increased to a predetermined value or more.
[0024]
If the microcomputer determines in step 102 that the power generation control is not performed, the microcomputer advances the program to step 106, and in step 106, determines whether or not the electric motor 15 should select the drive operation. . The drive control is determined based on signals from a throttle opening sensor, a wheel speed sensor, and the like. When the vehicle is in a low speed state and the throttle opening is equal to or greater than a certain value, it is determined that the drive control is performed, and the program is transferred to step 107. Proceed.
[0025]
In step 107, the microcomputer calculates a motor output torque T based on a method described later as a command torque, turns on the electromagnetic clutch 18 in step 108, and controls the electric motor 15 in a drivable state in step 109. Then, electric power is supplied from the high voltage battery 17 to the electric motor 15 via the drive circuit 10c2 of the control device 10c. As a result, the electric motor 15 is driven, and the rear wheel 19d is driven by the output from the electric motor 15 to bring the vehicle into a four-wheel drive running state.
[0026]
If the microcomputer determines in step 106 that it is not drive control, the microcomputer advances the program to step 110 to turn off the electromagnetic clutch 18, and in step 111, from the high voltage battery 17 to the electric motor. The electric motor 15 is maintained in a non-driven state without supplying power to the power source 15.
[0027]
The microcomputer circulates and executes the above control program based on the flowchart. During this time, the microcomputer reads the detection signal of the brake sensor S3 and performs output control for regulating output torque from the electric motor 15 described later to the rear wheel 19d.
[0028]
Thus, in the front and rear wheel drive vehicle 10 equipped with the drive device, the operation of the control device 10c can smoothly change the vehicle to the four-wheel drive state when necessary, and the drive source of the rear wheel 19d. The power stored in the high-voltage battery 17 can be used as a drive source for driving the electric motor 15 that is the drive means for the rear wheel 19d. The use of a dedicated generator for driving the electric motor 15 is abolished. The high voltage battery 17 can be mounted anywhere in a narrow space of the vehicle, and therefore the mountability of the drive device to the vehicle is very good.
[0029]
In addition, by adopting the stored power of the high voltage battery 17 instead of a dedicated generator for driving the electric motor 15 as the drive source of the electric motor 15, the configuration of the two-wheel drive vehicle is designed in the configuration of the four-wheel drive vehicle. There is no need to make a significant change, and a dedicated design for a four-wheel drive vehicle in the case of configuring a four-wheel drive vehicle becomes unnecessary. For this reason, the increase in the cost for comprising a four-wheel drive vehicle can be reduced significantly.
[0030]
In the driving apparatus, a low-voltage battery 14 that stores electric power generated by the generator 12 driven by the engine 11 that is the main drive unit is selected as a power source for storing the high-voltage battery 17. 14 is configured to include a DC-DC converter 16 that converts the stored power of 14 into a high voltage and stores it in the high voltage battery 17. Similarly to the high voltage battery 17, the DC-DC converter 16 can be mounted anywhere in a narrow space of the vehicle. Therefore, a good mountability of the drive device on the vehicle is sufficiently ensured.
[0031]
Further, in the driving device, the electric motor 15 capable of selectively converting electrical energy and mechanical energy and outputting as a driving means for the rear wheel 19d is employed as a power source for storing the high voltage battery 17. The electric motor 15 is selected, and the high voltage battery 17 is also stored by the regenerative power generated by the electric motor 15. According to such a configuration, it is possible to effectively use the regenerative power of the electric motor 15 and increase the energy use efficiency.
[0032]
In the driving device, an electromagnetic clutch 18 that intermittently transmits the driving force of the electric motor 15 to the rear wheel 19d side, and a control device 10c that controls each component of the driving device according to the state of the vehicle. It is configured to provide. As a result, the drive device is operated to accurately form the drive state intended for the vehicle, and overall, the energy use efficiency is further enhanced.
[0033]
The drive device is thus a very effective drive device for constructing the four-wheel drive vehicle of the type. However, the control device 10c constituting the drive device is used when the vehicle is driven by four-wheel drive. The output control is performed to restrict the output from the electric motor 15 to the rear wheel 19d side according to the brake operation state or the brake operation operation, and various cases such as when the vehicle falls into the brake operation state during the four-wheel drive traveling, etc. Solve the problem. A detailed description of this point will be described later.
[0034]
FIG. 4 schematically shows a second four-wheel drive vehicle 20 formed by mounting the second drive device according to the present invention. The drive device includes a first drive mechanism 20a that drives the front wheel side, a second drive mechanism 20b that drives the rear wheel side, and a control device 20c that controls the second drive mechanism 20b.
[0035]
The first drive mechanism 20a includes an engine 21 that is an internal combustion engine and a generator 22 that is a generator. In the first drive mechanism 20a, the driving force of the engine 21 is transmitted to the drive shafts 23d through the transmission 23a, the reduction gear train 23b, and the front differential 23c, and the front wheels 23e are driven by the drive shafts 23d. During this time, the engine 21 drives the generator 22 to generate electric power.
[0036]
The second drive mechanism 20 b includes an electric motor 24 and an electromagnetic clutch 25. The electric motor 24 is driven by receiving a high-voltage power supply. When the electric motor 24 is driven when the electromagnetic clutch 25 is ON, the driving force of the electric motor 24 is transmitted to each drive shaft 26c via the reduction gear train 26a, the electromagnetic clutch 25, and the rear differential 26b, and each drive The rear wheel 26d is driven by the shaft 26c.
[0037]
The generator 22 constituting the first drive mechanism 20 a is a generator with variable generation voltage, and is selectively connected to the low voltage battery 28 and the electric motor 24 via a changeover switch 27. The low voltage battery 28 functions to drive various auxiliary machine parts 29 mounted on the vehicle. The changeover operation of the changeover switch 27 is performed via the drive circuit 20c2 of the control device 20c.
[0038]
As shown in FIG. 5, the control device 20 c includes a throttle opening sensor S 1, a wheel speed sensor S 2, a brake sensor S 3, a low voltage battery voltage sensor S 4, a switch sensor S 5 for detecting the state of the 4WD switch, and an electric motor 24. It is connected to a motor sensor S6 for detecting the rotation state, and includes an MPU (microprocessor) 20c1 and a drive circuit 20c2.
[0039]
The MPU 20c1 includes a CPU and a memory for holding a control program and data for controlling the generator 22, the electromagnetic clutch 25, and the changeover switch 27. The detection signals output from the sensors S1 to S6 are sent via the interface. The state in which the generator 22, the electric motor 24, the electromagnetic clutch 25, and the changeover switch 27 are to be operated is determined, and the state in which the generator 22, the electric motor 24, the electromagnetic clutch 25, and the changeover switch 27 are to be operated is used as a command signal. Output to the drive circuit 20c2 via the interface. The drive circuit 20c2 controls the switching operation of the changeover switch 27 based on the command signal from the MPU 20c1, controls the power generated by the generator 22, controls the drive of the electric motor 24, and turns on the electromagnetic clutch 25. Perform OFF control. The control program of the MPU 20c1 holds an output control program that controls the output of the electric motor in accordance with the operating state of the brake or the operating operation of the brake, like the first drive device.
[0040]
That is, the control device 20c controls the success or failure of the four-wheel drive state, the control function that controls the power generated by the generator 22, the control function that controls the drive of the electric motor 24, and the control that regulates the output of the electric motor 24. It has a function.
[0041]
The microcomputer constituting the control device 20c determines whether or not the four-wheel drive state should be selected when the 4WD switch is turned on. When it is determined whether the switch 27 is in a state in which the switch state can be selected, and when it is determined that the switch 27 is in a state in which the switch state can be selected, the switch 27 is switched and the electromagnetic clutch The generator 22 is connected to the electric motor 24 by switching the power generation state of the generator 22 from the low voltage side to the high voltage side.
[0042]
Thus, the generator 22 supplies high-voltage power to the electric motor 24 and drives the electric motor 24 to form the vehicle in a four-wheel drive state. Whether the four-wheel drive state should be selected by the microcomputer is determined by the throttle opening sensor S1, the wheel speed sensor S2, the brake sensor S3, the voltage sensor S4 of the low voltage battery, and the switch for detecting the state of the 4WD switch. Based on the detection signal from the sensor S5, the four-wheel drive state is formed when a sufficient amount of charge remains in the low-voltage battery 28, such as when the vehicle starts, accelerates, or travels at a low speed.
[0043]
The microcomputer constituting the control device 20c executes the above control program based on the flowchart shown in FIG. In step 121, the microcomputer monitors the remaining amount of stored power in the low voltage battery 28. If the microcomputer determines that the remaining amount of stored power is less than the predetermined value A, the microcomputer advances the program to step 122. If it is determined that the remaining amount of power is greater than or equal to the predetermined value A, the program proceeds to step 123.
[0044]
In step 122, the microcomputer monitors the current consumption of power on the low voltage side. If the consumption is less than the predetermined value B, the microcomputer advances the program to step 123. If so, the program proceeds to step 124. Thereby, the connection relationship between the generator 22 and the low voltage battery 28 and the auxiliary machine component 29 is maintained, and the generator 22 continues to supply the low voltage power to the low voltage battery 28 and the auxiliary machine component 29.
[0045]
In step 123, the microcomputer determines whether or not the vehicle is in a state where four-wheel drive is to be performed. If the microcomputer determines that the vehicle is not in a state where four-wheel drive is to be performed, the microcomputer advances the program to step 124. Thereby, the connection relationship between the generator 22 and the low voltage battery 28 and the auxiliary machine component 29 is maintained, and the generator 22 continues to supply the low voltage power to the low voltage battery 28 and the auxiliary machine component 29.
[0046]
If the microcomputer determines in step 123 that the vehicle is in a state of four-wheel drive, the microcomputer advances the program to step 125. In step 125, the microcomputer calculates a motor output torque T based on a method described later to calculate a command torque, turns on the electromagnetic clutch 25 in step 126, and switches the changeover switch 27 to the electric motor 24 side. And the generator 22 is switched to the high voltage power generation side. As a result, the electric motor 24 is driven by the supply of high-voltage power from the generator 22 to form the vehicle in a four-wheel drive state.
[0047]
The microcomputer circulates and executes the above control program based on the flowchart. During this time, the microcomputer reads the output signal of the brake sensor S3 and performs output control for regulating the output torque of the electric motor 24 described later.
[0048]
As described above, in the drive device, the vehicle can be smoothly formed in the four-wheel drive state when necessary by the operation of the control device 20c. However, in the drive device, the engine 21 which is the main drive means is used. As a generator that generates electric power by driving, a generator 22 with variable generation voltage is adopted instead of the conventional generator, and the generator 22 is a low-voltage battery 28 on the conventional low-voltage system auxiliary side and auxiliary parts. 29 and the high-voltage electric motor 24 can be selectively connected. Thus, in the driving apparatus, the electric motor 24 can be driven by the generator 22 to drive the rear wheel 26d side, and the vehicle can be formed in a four-wheel drive state by the electric power of the generator 22.
[0049]
Further, in the driving apparatus, a generator 22 having a variable generation voltage is employed instead of a conventional generator as a generator that generates power by being driven by an engine 21 that is a main driving means, and the generator 22 is Since the electric motor 24 is used as a driving source, a dedicated generator for driving the electric motor 24 and other driving means dedicated to the electric motor are not necessary. Therefore, the mountability of the drive device on the vehicle is very good.
[0050]
In addition, since the drive device is configured by adopting the generator 22 with variable power generation voltage as a generator that generates power by being driven by the engine 21 that is the main drive means, the drive device is employed. Thus, when a four-wheel drive vehicle is configured, it is not necessary to significantly change the configuration of the two-wheel drive vehicle, and a dedicated design of the four-wheel drive vehicle when configuring a four-wheel drive vehicle can be omitted.
[0051]
For this reason, the increase in the cost for comprising a four-wheel drive vehicle can be reduced significantly. Moreover, since the drive device itself does not require the addition of new expensive parts, the increase in cost for configuring the four-wheel drive vehicle can be further greatly reduced.
[0052]
In the drive device, when the vehicle is required to be in a four-wheel drive state, for example, power is supplied from the generator 22 to the electric motor 24 for a short period of time such as when the vehicle starts or travels at a low speed. The power to the low-voltage auxiliary component 29 side is supplied from the conventional low-voltage battery 27. In this case, the required power to the low-voltage auxiliary component 29 side is temporarily provided. Can be deficient.
[0053]
In the drive device, assuming this case, when the required power to the low-voltage auxiliary machine component 29 side is temporarily insufficient, the generator 22 is connected to the high-voltage electric motor 24. A control device 20c having a control function to be stopped is employed. Thereby, the formation of the four-wheel drive state of the vehicle can be temporarily interrupted to make up for the shortage of required power to the low-voltage auxiliary equipment side.
[0054]
Thus, in each of the drive units constituting each of the above-described four-wheel drive vehicles 10 and 20, when the four-wheel drive state is formed, the control unit calculates the command torque based on the method shown in the flowchart of FIG. Do. If it is determined that the four-wheel drive state is formed, the microcomputer constituting the control device executes a program for calculating the designated torque, reads the detection signal from the wheel speed sensor in step 131, At 132, the front-rear wheel speed difference ΔN is calculated based on the detection signal.
[0055]
Next, in step 133, the microcomputer reads the detection signals from the throttle sensor and other sensors, calculates the output torque T in step 134, and outputs this as a command torque to the drive circuit of the control device. At 135, the current applied to the electric motor is controlled corresponding to the command torque.
[0056]
In calculating the output torque, the throttle sensitive torque T1 to be applied to the electric motor is determined from the relationship between the throttle opening and the throttle sensitive torque shown in FIG. ), The ΔN-sensitive torque T2 applied to the electric motor is calculated from the relationship between the front-rear wheel speed difference ΔN and the ΔN-sensitive torque, and the sum of the throttle sensitive torque T1 and the ΔN-sensitive torque T2 (T1 + T2). ) Is a command torque T.
[0057]
The control device that constitutes each drive device executes the above control program, predicts when a brake operation state occurs or occurs during the four-wheel drive traveling of the vehicle, and uses an electric motor corresponding to them. An output control program for restricting output (output torque) to the rear wheel side is executed. 9 to 12 show flowcharts for executing the four types of output control programs, respectively.
[0058]
The flowchart shown in FIG. 9 shows that the torque output from the electric motor to the rear wheel side is set to a predetermined value when a parking brake or a brake (sometimes referred to collectively as a brake) is activated while the vehicle is traveling on four wheels. The output control program to be controlled is executed.
[0059]
In step 201, the microcomputer determines the operating state of the brake. If the microcomputer determines that the brake is in an inoperative state, the microcomputer ends the execution of the program. If the microcomputer determines that the brake is in an operating state, In step 202, the magnitude of the torque value T of the command torque and the set specified torque value T0 are determined.
[0060]
If it is determined in step 202 that the torque value T of the command torque is less than the specified torque value T0, the microcomputer ends the execution of the program, and the torque value T of the command torque is equal to or greater than the specified torque value T0. If it is determined that there is, in step 203, the current applied to the electric motor is controlled so that the output torque from the electric motor to the rear wheel side is equal to or less than the specified torque value T0, and the execution of the program is completed. To do.
[0061]
Thereby, interference of an electric motor and a brake can be prevented, and durability of a drive device can be improved. The microcomputer circulates and executes the control program based on the flowchart.
[0062]
The flowchart shown in FIG. 10 executes an output control program for stopping the supply of electric power to the electric motor and maintaining the electric motor in a non-driven state when the engine is idled during braking.
[0063]
In step 210, the microcomputer determines the operating state of the brake. If the microcomputer determines that the brake is not operating, the microcomputer advances the program to step 211 to continue normal drive control of the electric motor. If it is determined that the brake is in an operating state, it is determined in step 212 whether or not the throttle opening is within a set maximum allowable value C that forms a four-wheel drive state.
[0064]
If the microcomputer determines in step 212 that the throttle opening is within the set maximum allowable value C that forms the four-wheel drive state, the microcomputer executes the normal drive control of the electric motor in step 211. If it is determined that the throttle opening is equal to or greater than the set maximum allowable value C that forms the four-wheel drive state, the program proceeds to step 213, and this state is set in step 213. It is determined whether or not a certain time has passed.
[0065]
If the microcomputer determines in step 213 that the throttle opening is equal to or greater than the set maximum allowable value C that forms the four-wheel drive state, the routine proceeds to step 214. Thus, it is determined that the engine is idle, the supply of electric power to the electric motor is stopped, the electric motor is maintained in the non-driven state, and the execution of the program is terminated.
[0066]
Thereby, the control device can stop the supply of electric power that continues to be supplied to the electric motor due to continuous engine blow-off and prevent damage to the electric motor due to temperature rise, baking, etc. .
[0067]
The flowchart shown in FIG. 11 executes an output control program that stops torque output from the electric motor to the rear wheel when the parking brake is applied.
[0068]
In step 221, the microcomputer determines the operating state of the parking brake. If the microcomputer determines that the parking brake is not applied, the microcomputer terminates the execution of the program and determines that the parking brake is applied. Advances the program to step 222.
[0069]
If the microcomputer determines in step 222 that the vehicle speed is less than the set specified speed D, the microcomputer ends the execution of the program. If the microcomputer determines that the vehicle speed is equal to or higher than the set specified speed D, The program proceeds to step 223. In step 223, the coupling of the electromagnetic clutch is cut off (OFF), and the supply of electric power to the electric motor is stopped to stop the electric motor.
[0070]
As a result, it is possible to protect the drive device when the parking brake is pulled during traveling such as a severe mean test. The microcomputer circulates and executes the control program based on the flowchart.
[0071]
The flowchart shown in FIG. 12 executes an output control program for stopping the operation of the second drive mechanism on the rear wheel drive side when the parking brake is applied and the four-wheel drive traveling is unnecessary.
[0072]
When the microcomputer determines in step 231 that the parking brake is operating and determines that the parking brake is not applied, the microcomputer terminates the execution of the program and determines that the parking brake is applied. Advances the program to step 232.
[0073]
The microcomputer determines the vehicle speed in step 232, and if the vehicle speed is determined not to be zero, the microcomputer ends the execution of the program. If the microcomputer determines that the vehicle speed is zero, the program proceeds to step 233. At 233, the throttle opening is determined. If the microcomputer determines in step 233 that the throttle opening is not zero, the microcomputer ends the execution of the program. If the microcomputer determines that the throttle opening is zero, the microcomputer proceeds to step 234 and proceeds to step 234. Then, it is determined whether or not a certain period of time has elapsed since the stop state of the vehicle.
[0074]
If the microcomputer determines in step 234 that the fixed time has not elapsed since the set stop state of the vehicle, the microcomputer ends the execution of the program, and the predetermined time after the stop state of the vehicle has elapsed. If it is determined that the program is present, the program proceeds to step 235. In step 235, the microcomputer cuts off the coupling of the electromagnetic clutch (OFF), stops the supply of electric power to the electric motor, and stops the electric motor.
[0075]
Thereby, the operation of the second drive mechanism on the rear wheel drive side when the parking brake is pulled and the four-wheel drive traveling is unnecessary can be maintained in a stopped state, and wasteful energy consumption is prevented, The fuel consumption can be improved. The microcomputer circulates and executes the control program based on the flowchart.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of a first four-wheel drive vehicle configured by mounting a first drive device according to the present invention.
FIG. 2 is a schematic configuration diagram of a control device constituting the drive device.
FIG. 3 is a flowchart for executing a control program included in the control device;
FIG. 4 is a schematic configuration diagram of a second four-wheel drive vehicle configured by mounting a second drive device according to the present invention.
FIG. 5 is a schematic configuration diagram of a control device configuring the drive device.
FIG. 6 is a flowchart for executing a control program included in the control device;
FIG. 7 is a flowchart showing a method of calculating a command torque performed by the control device of each drive device according to the present invention.
FIG. 8 is a graph (a) showing the relationship between a preset throttle sensitive torque T1 and a throttle opening as a basis for calculating the command torque, and front and rear wheel rotation differences ΔN and ΔN sensitive torque; It is a graph (b) which shows the relationship of T2.
FIG. 9 is a flowchart for executing an output control program according to an example of the control apparatus according to the present invention.
FIG. 10 is a flowchart for executing an output control program according to another example of the control apparatus according to the present invention.
FIG. 11 is a flowchart for executing an output control program according to another example of the control apparatus according to the present invention.
FIG. 12 is a flowchart for executing an output control program according to another example of the control apparatus according to the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10,20 ... Four-wheel drive vehicle, 10a, 20a ... 1st drive mechanism, 10b, 20b ... 2nd drive mechanism, 10c, 20c ... Control apparatus, 11, 21 ... Engine, 12, 22 ... Generator, 13a, 23a ... Transmission, 13b, 23b ... Reduction gear train, 13c, 23c ... Front differential, 13e, 23e ... Front wheels, 14, 28 ... Low voltage battery, 15, 24 ... Electric motor, 16 ... DC-DC converter, 17 ... High voltage battery 18, 25 ... Electromagnetic clutch, 19a, 26a ... Reduction gear train, 19b, 26b ... Rear differential, 19c, 26c ... Drive shaft, 19d, 26d ... Rear wheel, 27 ... Changeover switch, 29 ... Auxiliary equipment parts.

Claims (5)

A main drive means for driving the main drive wheel side which is one of the front and rear wheels, and a sub drive means for driving the sub drive wheel side which is the other of the front and rear wheels, by driving the main drive wheel side by the main drive means The single drive running state of the main drive wheel is formed, and the two drive wheels are driven by the main drive means on the main drive wheel side and the sub drive means on the auxiliary drive wheel side. a driving apparatus for a front and rear wheel drive vehicle of the type that forms a comprises an output control means for controlling the output to the auxiliary drive wheel side from the auxiliary drive means according to the operation the operation of the operating state or the brake of the brake a driving device for the front rear wheel drive vehicle Ru Tei, said output control means has a control function of stopping the supply of the driving source to the secondary drive means when said main drive means during operation of the brake is driven Before and after characterized Drive for drive vehicle. 2. The drive device for a front and rear wheel drive vehicle according to claim 1 , wherein the sub drive means constituting the drive device is an electric motor, and the power transmission connection between the electric motor and the sub drive means is intermittent. The main drive wheel is driven on the main drive wheel side in a state where the electromagnetic clutch is disconnected, and the single drive running state of the main drive wheel is formed, and the electromagnetic clutch is coupled. For both front and rear wheel drive vehicles, the driving state of the two driving wheels is formed by the driving of the main driving wheels by the main driving means and the driving of the auxiliary driving wheels by the sub driving means . Drive device. 3. The drive device for a front and rear wheel drive vehicle according to claim 2 , wherein the output control means constituting the drive device stops supplying electric power to the electric motor when the main drive means is driven during brake operation. A drive device for a front and rear wheel drive vehicle characterized by having a control function for 4. A drive device for a front and rear wheel drive vehicle according to claim 3, wherein the output control means constituting the drive device stops supplying electric power to the electric motor when a brake is actuated while the vehicle is running. A drive device for a front-rear wheel drive vehicle having a control function for cutting off the coupling of the electromagnetic clutch . It is a drive device for front-and-rear wheel drive vehicles as described in any one of Claims 1-4, The main drive means which comprises the said drive device is an engine, It drives with the same engine and generates electric power. A drive device for a front and rear wheel drive vehicle , comprising a generator, controlling electric power generated by the generator and supplying electric power to the electric motor to drive the electric motor .

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