JP2006345677A - Vehicle drive unit by motor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the operation efficiency of a vehicle drive unit, namely, the system efficiency as compared with a situation where uniform torque is distributed to a plurality of motors. <P>SOLUTION: The vehicle drive unit by a motor comprises a plurality of drive wheels, a plurality of motors transmitting torque to the plurality of drive wheels respectively, and a motor control means for controlling the plurality of motors to control each drive force of the drive wheels. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a drive device for a vehicle using a motor as a drive force source, such as an electric vehicle, a hybrid electric vehicle, and a fuel cell vehicle.

A motor is used as means for driving a vehicle such as an electric vehicle or a hybrid electric vehicle. In the drive system, for the purpose of reducing energy loss in the power transmission system, the technology of Japanese Patent No. 2790462 equipped with an in-wheel motor, or the technology of attaching the motor to the left and right drive shafts by eliminating the differential gear It has been known.
Japanese Patent No. 2790462

  Considering the motor and inverter provided on each wheel together as a system, the overall system efficiency (hereinafter referred to as system efficiency) is reduced when the vehicle is driven using an operating region where the energy efficiency of the motor or inverter is low. There's a problem. For example, when a vehicle having a motor having energy efficiency characteristics as shown in FIG. 1 is driven at 25 [km / h], the energy efficiency is 0.3 at the operating point A where the motor is operated in a low driving force region. The energy efficiency is 0.65 at the operating point B where the motor is operated in the high driving force region. As described above, even if the vehicle speed is the same, unless the operating point is appropriately selected, the energy efficiency of each motor is lowered, and the system efficiency is also deteriorated. The energy efficiency characteristics in FIG. 1 are shown by converting the motor speed and motor torque into vehicle speed and driving force, respectively.

  In view of these points, an object of the present invention is to improve system efficiency of a vehicle drive device by controlling torque distribution of a plurality of motors.

  In order to solve the above-mentioned problem, the invention according to claim 1 controls drive wheels, a plurality of motors that generate torque transmitted to the drive wheels, and distribution of torques generated by the plurality of motors. Motor control means for controlling the torque distribution of the plurality of motors.

  Thereby, compared with the case where equal torque is distributed to a plurality of motors, the operation efficiency of the vehicle drive device, that is, the system efficiency can be improved. For example, if each of the front and rear drive wheels of the vehicle has a drive motor, the drive motor at the front of the vehicle is used in a torque region where the energy efficiency is very good, and the drive motor at the rear of the vehicle is used in a torque region where the energy efficiency is poor. It becomes possible to use this, and the operation efficiency of the entire vehicle can be improved as compared with the case where all the drive motors of the vehicle are used in a torque region where the energy efficiency is slightly poor.

  The invention described in claim 2 is characterized in that the motor control means controls the torque distribution of the plurality of motors using an inverter connected to at least one of the plurality of motors.

  Thereby, the motor control means can distribute drive torque to a plurality of motors using an inverter. For example, in the case of a vehicle drive device for a four-wheel drive vehicle in which a motor and an inverter are provided for each of the four wheels and the motor control means is a microcomputer, an inverter control signal for driving each motor is output from the microcomputer to each inverter. A motor control signal such as a PWM signal can be output from each inverter to each motor.

  The invention according to claim 3 includes at least one or more clutches provided between the plurality of motors and the drive wheels, and clutch control means for controlling the clutch, wherein the clutch control means The clutch is controlled.

  By disconnecting the clutch, it is possible to eliminate the mechanical loss of the motor when there is no load, so that the operation efficiency of the vehicle drive device can be further improved as compared with the configuration of the first aspect. For example, the no-load state of the motor includes a state where torque is not generated in some motors due to the effect of claim 1, that is, a case where some driving wheels are slave wheels.

  According to a fourth aspect of the present invention, the transmission includes at least one transmission provided between the plurality of motors and driving wheels, and transmission control means for controlling the transmission. The control means controls the transmission.

Thus, by providing the transmission, each motor can be operated in a torque region with good energy efficiency. For example, in a vehicle having six motors on six drive wheels, it is assumed that the operation characteristics of the six motors are different. Since all drive wheels need to rotate at the same number of revolutions, if there are no transmissions and the operating characteristics of the six motors are different, not all motors can always operate in an energy efficient torque range. Absent. However, if the transmission is provided with a transmission between each drive wheel and each motor, the rotational speed of the drive wheel can be adjusted while operating each motor in the torque region where each motor is energy efficient. Can be constant. Thereby, compared with the structure of Claim 1, operational efficiency can be improved further.
The invention according to claim 5 is characterized in that the motor control means controls the torque distribution of the plurality of motors based on at least two or more operation efficiency of the plurality of motors.

  As a result, system efficiency can be improved as compared with the case where uniform torque distribution is performed for all motors.

  The invention described in claim 6 is characterized in that the motor control means controls the torque distribution of the plurality of motors based on the operation efficiency of the whole of the plurality of motors.

  In this way, by considering the system efficiency as the efficiency of the system including all the motors, it is possible to distribute the torque to each motor so as to improve the operation efficiency of the entire system.

  The invention according to claim 7 is characterized in that the motor control means controls the torque distribution of the plurality of motors based on the total operation efficiency of the plurality of motors and the inverter.

  By including not only the motor but also the operating efficiency of the inverter in the system efficiency, the operating efficiency in a wider range can be improved as compared with the configuration of the first aspect.

  According to an eighth aspect of the present invention, the motor control unit controls torque distribution of the plurality of motors based on an operation efficiency obtained by adding the plurality of motors and the inverter, or the clutch control unit The clutch is controlled.

  Thereby, the mechanical loss of the unloaded motor can be eliminated, and the operation efficiency of the entire system can be further improved as compared with the configuration of the seventh aspect.

  According to a ninth aspect of the present invention, the motor control unit controls torque distribution of the plurality of motors based on an operating efficiency obtained by adding the plurality of motors and the inverter, or the transmission control unit. Controls the transmission.

  By controlling the transmission based on the system efficiency, the motor can be operated in a wider operating range. For example, if the transmission is equipped with a continuously variable transmission mechanism such as CVT and this transmission is controlled so as to maximize the system efficiency, the rotational speeds of all the driving wheels are made constant according to the energy characteristics of each motor. However, it is possible to drive the motor in a torque region with the highest energy efficiency.

  According to a tenth aspect of the present invention, the motor control unit controls torque distribution of the plurality of motors based on an operation loss of the plurality of motors as a whole.

  The invention described in claim 11 is characterized in that the motor control means controls torque distribution of the plurality of motors based on an operation loss obtained by adding the plurality of motors and the inverter.

  According to a twelfth aspect of the present invention, the motor control unit controls torque distribution of the plurality of motors based on a total operation loss of the plurality of motors and the inverter, or the clutch control unit includes: The clutch is controlled.

  According to a thirteenth aspect of the present invention, the motor control unit controls torque distribution of the plurality of motors based on an operation loss obtained by adding the plurality of motors and the inverter, or the transmission control unit. Controls the transmission.

  The invention according to claim 14 includes storage means for storing efficiency characteristics of the plurality of motors, and estimation means for estimating operation efficiency of the plurality of motors based on the efficiency characteristics, The means controls torque distribution of the plurality of motors based on the estimation.

  Thereby, the operating efficiency of the vehicle drive device can be improved by a controller using a microcomputer or the like.

  According to a fifteenth aspect of the present invention, a storage means for storing an efficiency characteristic that combines the plurality of motors and the inverter, and an operating efficiency that combines the plurality of motors and the inverter are estimated based on the efficiency characteristics. And estimating means for controlling the torque distribution of the plurality of motors based on the estimation.

  Accordingly, when a plurality of motors and inverters are regarded as a system, the operation efficiency of the entire system can be maximized by a controller using a microcomputer or the like.

  According to a sixteenth aspect of the present invention, a storage means for storing efficiency characteristics combining the plurality of motors and the inverter, and an operating efficiency combining the plurality of motors and the inverter are estimated based on the efficiency characteristics. Estimating means for controlling the torque distribution of the plurality of motors based on the estimation, and the clutch control means controlling the clutch based on the estimation. Features.

  Thus, the motor and clutch can be controlled by a controller using a microcomputer or the like, and the mechanical loss of the no-load motor is eliminated, thereby further improving the operating efficiency of the entire system compared to the configuration of claim 14. be able to.

  According to a seventeenth aspect of the present invention, the storage means for storing the efficiency characteristics of the plurality of motors and the inverter combined, and the operating efficiency of the combination of the plurality of motors and the inverter is estimated based on the efficiency characteristics. And the motor control unit controls torque distribution of the plurality of motors based on the estimation, and the transmission control unit controls the transmission based on the estimation. It is characterized by that.

  Accordingly, the motor and the transmission can be controlled by a controller using a microcomputer or the like. By operating the motor in a torque region with good energy characteristics by the transmission, the entire system can be further compared with the configuration of claim 14. The operating efficiency can be improved.

  The invention according to claim 18 comprises storage means for storing the efficiency characteristics of the plurality of motors, and estimation means for estimating operation losses of the plurality of motors based on the efficiency characteristics, The means controls torque distribution of the plurality of motors based on the estimation.

  According to a nineteenth aspect of the present invention, the storage means for storing the efficiency characteristic of the plurality of motors and the inverter combined, and the operation loss of the combination of the plurality of motors and the inverter are estimated based on the efficiency characteristic. And estimating means for controlling the torque distribution of the plurality of motors based on the estimation.

  According to a twentieth aspect of the present invention, a storage means for storing efficiency characteristics combining the plurality of motors and the inverter, and an operating loss combining the plurality of motors and the inverter are estimated based on the efficiency characteristics. Estimating means for controlling the torque distribution of the plurality of motors based on the estimation, and the clutch control means controlling the clutch based on the estimation. Features.

  According to a twenty-first aspect of the present invention, a storage means for storing an efficiency characteristic that combines the plurality of motors and the inverter, and an operating loss that combines the plurality of motors and the inverter are estimated based on the efficiency characteristics. And the motor control unit controls torque distribution of the plurality of motors based on the estimation, and the transmission control unit controls the transmission based on the estimation. It is characterized by that.

  According to a twenty-second aspect of the present invention, the plurality of motors includes a first group including motors having the same characteristics and a motor having the same characteristics among motors not included in the first group. It comprises the 2nd group comprised, It is characterized by the above-mentioned.

  Normally, some or all of the motors used for driving are often of the same standard, so when determining whether operating efficiency is good by grouping motors with the same characteristics in this way. The amount of computation can be reduced.

  The invention described in claim 23 is characterized in that the motors constituting the first group and the motors constituting the second group have different rated outputs.

  Even if the rated output for each group differs, operating the motor in a torque region with good energy efficiency for each group improves the operating efficiency of the entire system compared to generating uniform torque for all motors. can do.

  The invention described in claim 24 is characterized in that the motors constituting the first group and the motors constituting the second group are different from each other in operating efficiency or operating loss characteristics.

  As described above, even if the operation characteristics are different for each group, the system efficiency can be improved by distributing the torque to each motor based on the operation efficiency of all the motors.

  According to a twenty-fifth aspect of the present invention, the first group includes a motor that drives driving wheels at the front of the vehicle, and the second group includes a motor that drives driving wheels at the rear of the vehicle. To do.

  By grouping the motors at the front and rear of the vehicle in this way, it is possible to reduce the amount of calculation when determining whether or not the operation efficiency is good. For example, in a vehicle in which two front drive wheels are driven by motors of the same characteristics provided in each, and two rear drive wheels are driven by one motor via a drive shaft, It is assumed that two motors at the front of the vehicle are driven, and only one motor at the rear of the vehicle is driven in addition to the front motor only when starting on a slope. When this vehicle starts on a slope in a straight traveling state, the two front motors included in the first croup generate the same torque. Therefore, it is not necessary to consider the energy efficiency of each of the motors included in the first group, and only the energy efficiency of one of the two front motors and the energy efficiency of the motors of the second group should be considered. It ’s fine. As a result, while using three motors, the energy efficiency of the two groups of motors is calculated, so the amount of calculation can be reduced.

The invention according to claim 26 is configured such that the first group includes a motor that drives the driving wheel on the right side of the front part of the vehicle and a motor that drives the driving wheel on the left side of the rear part of the vehicle.
The second group includes a motor for driving the driving wheel on the left side of the front part of the vehicle and a motor for driving the driving wheel on the right side of the rear part of the vehicle.

  In this way, by grouping motors in diagonal positions with respect to the vehicle, it is determined whether the operation efficiency is good without impairing the function of distributing the torque distribution so that the vehicle can turn more easily. It is possible to reduce the amount of calculation when performing.

  According to a twenty-seventh aspect of the present invention, at least one of the motors is an in-wheel motor.

  By using an in-wheel motor, the measurement accuracy of energy efficiency at the shaft and gear can be increased. As a result, torque distribution to the motor can be determined based on accurate energy efficiency, so that the system efficiency can be further improved as compared with the above-described configurations.

  The invention according to claim 28 is a first drive wheel, a second drive wheel, a first motor for transmitting a drive force to the first drive wheel, and a second for transmitting a drive force to the second drive wheel. A motor and motor control means, wherein the motor control means controls torque output by the first motor and the second motor in order to distribute the driving force to each drive wheel. And

  The invention according to claim 29 has a plurality of drive wheels and a plurality of motors for transmitting torque to each of the plurality of drive wheels, and the plurality of motors are constituted by motors having the same characteristics. The motor is configured by a first group and a second group including motors having the same characteristics among the motors not included in the first group.

  Hereinafter, the best mode for carrying out the present invention will be described using Examples 1 to 6.

[Example 1]
Example 1 will be described with reference to FIGS.

  FIG. 2 shows a configuration of a vehicle drive device including four drive wheels and four motors. The first driving wheel (1-f1) at the left front of the vehicle, the second driving wheel (1-f2) at the right front, the third driving wheel (1-r1) at the left rear, and the fourth driving wheel (1 -R2). Further, a first motor (2-f1) is provided on the vehicle interior side on the axle of the first drive wheel (1-f1), and a second motor (2 is provided on the vehicle interior side on the axle of the second drive wheel (1-f2). -F2), the third motor (2-r1) on the vehicle interior side on the axle of the third drive wheel (1-r1), and the fourth motor on the vehicle interior side on the axle of the fourth drive wheel (1-r2). (2-r2) is installed, and each driving wheel is driven separately by four motors by a motor provided in each driving wheel. The first motor (2-f1) has a first inverter (3-f1) installed inside the vehicle, and the second motor (2-f2) has a second inverter (3-f2) installed inside the vehicle. ), The third motor (2-r1) has a third inverter (3-r1) installed inside the vehicle, and the fourth motor (2-r2) has a fourth inverter (3-r2) installed inside the vehicle. ) Are connected, and all four inverters are controlled by a controller (4) provided inside the vehicle. The controller (4) receives vehicle speed, accelerator signal, and brake signal from various sensors (not shown) and outputs control commands to all four inverters.

  An example of the energy efficiency characteristic of the motor is shown using FIG. It is assumed that all four motors have the characteristics shown in FIG.

  Here, when the vehicle speed and the required driving force in a certain traveling state are expressed by the rotational speed and torque of the motor, Nf1 = Nf2 = Nf3 = Nf4 = N [rpm] (Equation 1) and Tf1 + Tf2 + Tf3 + Tf4 = Ta [Nm] (Equation 2). Where N is the number of rotations required for the motor (hereinafter referred to as required number of rotations), Nf1 is the number of rotations of the first motor (2-f1), Nf2 is the number of rotations of the second motor (2-f2), and Nf3 is The number of rotations of the third motor (2-r1), Nf4 is the number of rotations of the fourth motor (2-r2), Ta is the total torque required for all the motors (hereinafter referred to as total torque), and Tf1 is the first motor (2-f1) output torque, Tf2 is output torque of the second motor (2-f2), Tf3 is output torque of the third motor (2-r1), and Tf4 is output torque of the fourth motor (2-r2). It is.

When the required rotational speed N = 400 and the total torque Ta = 20, when the necessary torque is evenly distributed to the four motors, the torque of each motor is Tf1 = Tf2 = Tf3 = Tf4 = 20/4 = 5 0.0 [Nm] (Formula 3). As a result, the operating points of the four motors become the operating point C in FIG. 3, and the energy efficiency is 0.40. Here, when the system efficiency is defined as a weighted average according to the workload, the system efficiency E = (total output of the system) / (total input of the system). For simplification of description, Tf1 = Tf2 (Equation 4) and Tr1 = Tr2 (Equation 5) so that two front drive wheels and two rear drive wheels have the same torque distribution. The total output of the two front motors is Pf, the total output of the two rear motors is Pr, the total output of the four front and rear motors is Pall, the efficiency of the two front motors is nf, If the efficiency of two motors is nr, the system efficiency can be expressed as E = (Pf + Pr) / (Pf / nf + Pr / nr) (Formula 6). Further, when Equation 6 is transformed, E = Pall / {Dm × Pall / nf + (1−Dm) Pall / nr} (Equation 7), E = 1 / {Dm / nf + (1-Dm) / nr} (Equation 8) is obtained. The system efficiency in the case where the required torque is evenly distributed to the four motors according to Equation 6 to Equation 8 is E = 1 / {0.5 / 0.4 + (1-0.5) /0.4}. = 0.4.

  On the other hand, a case will be described in which the total torque is distributed to each of the four motors so that the system efficiency is maximized, that is, the output torques of the four motors are not the same. FIG. 4 shows the system efficiency E and the torque distribution ratio when the required rotational speed N = 400, the total torque Ta = 20, and the torque distribution ratio Dm to each motor is Dm = (Tf1 + Tf2) / (Tf1 + Tf2 + Tr1 + Tr2) (Equation 9). It is a system efficiency map showing the relationship of Dm. 4, it can be determined that the distribution ratio Dmax that provides the maximum system efficiency Emax in the range of 0 ≦ Dm ≦ 1 is Dmax = 0.23 or Dmax = 0.77. Further, using Equation 6 to Equation 8, the maximum system efficiency can be calculated as Emax = 1 / {0.77 / 0.60 + (1−0.77) /0.36} = 0.52. As described above, when the same required rotational speed and total torque are required, the method of distributing torque to each of the four motors has better system efficiency than the method of distributing torque evenly to the four motors.

  As shown in FIG. 5, the system efficiency map is created in advance for each combination of required rotational speed and total torque in various driving states (vehicle speed, accelerator, brake), and the system efficiency map group includes an internal controller (4). Store in memory.

  The internal processing based on the above description performed by the controller (4) will be described using the flowchart of FIG. In step S61, the driving force or braking force requested by the driver, that is, the required rotational speed N and the total torque Ta are obtained from the vehicle speed, the accelerator signal and the brake signal input to the controller (4). In step S62 following step S61, a system efficiency map that best matches the required rotational speed N and the total torque Ta is extracted from the system efficiency map group shown in FIG. In step S63 following step S62, the distribution ratio Dmax that provides the maximum system efficiency Emax is calculated using the system efficiency map extracted in step S62 in the preceding stage, and the output torque of each motor is determined. In step S64 following step S63, a control command is output to each inverter that controls each motor so that each motor can output the output torque determined in step S63 in the preceding stage.

  As shown in FIG. 3 and FIG. 4, the energy efficiency of each motor is considered compared to the case where the required total torque is evenly distributed to the four motors (Dm = 0.50). Thus, the method of distributing the torque separately can improve the system efficiency of the vehicle drive device.

[Example 2]
A second embodiment will be described with reference to FIGS. The difference in configuration of the second embodiment from the first embodiment is that in this embodiment, torque is distributed so that the system loss composed of the motor and the inverter is minimized. The difference is that torque was distributed to maximize system efficiency. In addition, about the structure equivalent to above-mentioned Example 1, the code | symbol similar to Example 1 is attached | subjected and description in this Example 2 is abbreviate | omitted.

  FIG. 7 shows an example of the energy loss characteristics of the motor and the inverter (the sum of the loss of one motor and the loss of one inverter). Note that the four motors and the four inverters used in this embodiment all have the characteristics shown in FIG.

  It is assumed that the required rotational speed N = 2100 [rpm] and the total torque Ta = 32 [Nm] in a certain running state.

  At this time, when the necessary torque is evenly distributed to the four motors, the torque of each motor is Tf1 = Tf2 = Tf3 = Tf4 = 32/4 = 8.0 [Nm] (Equation 3). As a result, the operating points of the four types of motors become the operating point D in FIG.

  On the other hand, a case will be described in which the total torque is distributed to each of the four motors so that the system loss is minimized, that is, the output torques of the four motors are not the same. In addition, for simplification of description, the two front drive wheels and the two rear drive wheels have the same torque distribution.

  When the torque distribution ratio Dm to each motor is Dm = (Tf1 + Tf2) / (Tf1 + Tf2 + Tr1 + Tr2) (Equation 9), the relationship between the system loss L and the torque distribution ratio Dm in the four motors and the four inverters as a whole A loss map is shown in FIG. The system loss L is expressed as a relative value when the system loss L0 is L0 = 1.0 at the distribution ratio Dm = 0.50 when the output torques of all four motors are equal. In the range of 0 ≦ Dm ≦ 1, the system loss L becomes the minimum value Lmin when Dm = 0.0 or Dm = 1.0. Thereby, compared with the case where the total torque required is equally distributed to the four motors (Dm = 0.50), the method of distributing the torque separately to each motor has less system loss.

  As in the first embodiment, the system loss map is created in advance for each combination of the required rotational speed and total torque in various driving states (vehicle speed, accelerator, brake), and the system loss map group includes an internal part of the controller (4). Store in memory.

  Since the internal processing of the controller (4) calculates a torque distribution ratio with a small system loss L, the processing of step S62 and step S63 in the flowchart of FIG. In the case of the present embodiment, step S61 is the same process as that of the first embodiment, and in step S62, a system loss map to be used is extracted from the necessary rotational speed and the total torque calculated in the preceding step S61. In step S63, the distribution ratio Dmin that provides the minimum system loss Lmin is calculated from the system loss map extracted in step S62 in the preceding stage, and the output torque of each motor is determined. In step S64 following step S63, a control command is output to each inverter that controls each motor so that each motor can output the output torque determined in step S63 in the preceding stage.

  Thus, by changing the torque distribution to each motor, the system loss L of the plurality of motors and the plurality of inverters can be minimized, that is, the system efficiency can be maximized.

  Also, the merit of using system loss and energy loss instead of system efficiency and energy efficiency will be described. The system efficiency of the four motors and the four inverters as a whole can be expressed as E = (Pf1_out + Pf2_out + Pr1_out + Pr2_out) / (Pf1_in + Pf2_in + Pr1_in + Pr2_in) (Equation 10). Where Pf1_out is the output of the first motor, Pf2_out is the output of the second motor, Pr1_out is the output of the third motor, Pr2_out is the output of the fourth motor, Pf1_in is the input to the first inverter, and Pf2_in is the input to the second inverter Input, Pr1_in is an input to the third inverter, and Pr2_in is an input to the fourth inverter.

  Furthermore, the input to each inverter is Pf1_in = Pf1_out / Ef1 (Equation 11), Pf2_in = Pf2_out using the output of each motor and the energy efficiency (Ef1, Ef2, Ef3, Ef4) of each motor and each inverter. / Ef2 (Formula 12), Pr1_in = Pr1_out / Er1 (Formula 13), Pr2_in = Pr2_out / Er2 (Formula 14).

However, when the rotational speed of the motor is 0 [min ⁻¹ ] or when the motor torque is 0 [Nm], the energy efficiency is 0, and therefore the right side of (Expression 11) to (Expression 14) The denominator becomes 0, and the input to the inverter cannot be calculated. Therefore, the system efficiency E of the entire system including each motor and each inverter cannot be obtained.

On the other hand, when energy loss is used, the input to the inverter is Pf1_in = Pf1_out + Lf1 (Equation 15), Pf2_in = Pf2_out + Lf2 (Equation 16) using the motor output and the energy loss between the motor and the inverter. Pr1_in = Pr1_out + Lr1 (Expression 17), Pr2_in = Pr2_out + Lr2 (Expression 18). As shown in (Equation 15) to (Equation 18), the input to the inverter can be calculated even when the motor rotation speed is 0 [min ⁻¹ ] or the motor torque is 0 [Nm]. Thus, the system loss L of the entire system including the motors and the inverters can also be obtained.

Example 3
Embodiment 3 will be described with reference to FIGS. 9 to 11. The difference in configuration of the third embodiment from the first embodiment is that in this embodiment, a clutch is added between each motor and each drive wheel, and a control function of each clutch is added to the controller (4). This is the point. In addition, about the structure equivalent to each above-mentioned Example, the code | symbol similar to each Example is attached | subjected and description in this Example 3 is abbreviate | omitted.

  FIG. 9 shows a configuration according to the third embodiment of the present invention. A first clutch (5-f1) is added between the first motor (2-f1) and the first drive wheel (1-f1). A second clutch (5-f2) is added between the second motor (2-f2) and the second drive wheel (1-f2). A third clutch (5-r1) is added between the third motor (2-r1) and the third drive wheel (1-r1). A fourth clutch (5-r2) is added between the fourth motor (2-r2) and the fourth drive wheel (1-r2). These clutches are provided with actuators, and the actuators connect or disconnect the clutch plates according to connection / disconnection commands output from the controller (4). Each motor has the energy loss characteristics (sum of motor loss and inverter loss) of the motor and inverter shown in FIG.

  It is assumed that the required rotational speed N = 2100 [rpm] and the total torque Ta = 32 [Nm] in a certain running state.

  At this time, when there is no clutch and the necessary torque is evenly distributed to the four motors, the torque of each motor is Tf1 = Tf2 = Tf3 = Tf4 = 32/4 = 8.0 [Nm] (Formula 3) It becomes. As a result, the operating points of the four types of motors become the operating point D in FIG.

  On the other hand, when each clutch is connected or disconnected by the actuator of each clutch so that system loss is minimized, and the total torque is distributed to each of the four motors, that is, when the output torques of the four motors are not the same. explain. In the following, for simplification of description, the two front drive wheels and the two rear drive wheels have the same torque distribution, and the two clutches between the front drive wheel and the motor are the same. The state (connected or disconnected) and the two clutches between the rear drive wheel and the motor are also in the same state (connected or disconnected).

  FIG. 10 shows the relationship between the system loss L and the torque distribution ratio Dm when the torque distribution ratio Dm to each motor is Dm = (Tf1 + Tf2) / (Tf1 + Tf2 + Tr1 + Tr2) (Equation 9). Note that the system loss L of the four motors and the four inverters in FIG. 10 is relative to 1.0 when 1.0 is 1.0 when there is no clutch and an equal torque is distributed to the four wheels (Dm = 0.50). Represented by value. As can be seen from FIG. 10, when all the clutches are connected, the energy loss L is minimum at L1 when Dm = 0.0 or Dm = 1.0 in the range of 0 ≦ Dm ≦ 1.

  On the other hand, when the front wheel side two clutches are connected and the rear wheel side two clutches are disconnected, or when the front wheel side two clutches are disconnected and the rear wheel side two clutches are connected, The system loss L is minimum at L2. As shown in FIG. 10, the energy loss L2 is smaller than the system loss L1. As a result, compared with the case where the total required torque is evenly distributed to the four motors (Dm = 0.50), the method of distributing the torque separately to each motor using the clutch is a system loss. Less is.

  FIG. 11 shows a processing procedure of the controller (4). In step S111, the driving force or braking force requested by the driver, that is, the required rotational speed N and the total torque Ta are obtained from the vehicle speed, the accelerator signal and the brake signal input to the controller (4). In step S112 following step S111, four motors when the torque distribution to the four motors is changed and the states of the four clutches are changed at the same time using the system loss map used in FIG. And the system loss L of the four inverters as a whole is estimated. Assuming that there are three types of torque distribution, the types of energy loss to be estimated are torque distribution types (3 types) × clutch state (24 types) = 72 types. In step S113 following step S112, the distribution ratio Dmin and the four-wheel clutch state that are the minimum system loss Lmin when the combination of the distribution ratio Dm calculated in the previous step S112 and the clutch state is executed are calculated. Determine the output torque of the motor. In step S114 following step S113, a control command is output to each inverter that controls each motor so that each motor can output the output torque determined in the previous step S113, and a connection / disconnection command is issued to the actuator of each clutch. Output.

  With the above configuration, based on the system loss characteristics of the entire system consisting of four motors and four inverters, the clutch is connected or disconnected to minimize the system loss, and the torque is distributed to each motor. System efficiency can be improved as compared with a method in which torque is evenly distributed to all motors. And the structure of a present Example can improve system efficiency further compared with the structure which does not have a clutch like Example 2. FIG.

  Further, in addition to the above-described configuration, if a function of disconnecting the clutch when the motor does not generate a driving force is used, loss such as friction caused by the motor can be reduced, and system efficiency can be further improved.

Example 4
Embodiment 4 will be described with reference to FIGS. The difference in the configuration of the fourth embodiment from the first embodiment is that a transmission is added between each motor and each driving wheel in this embodiment, and the control function of each transmission is added to the controller (4). This is the point that was added. In addition, about the structure equivalent to each above-mentioned Example, the code | symbol similar to each Example is attached | subjected, and the description in this Example 4 is abbreviate | omitted.

  FIG. 12 shows the configuration of the fourth embodiment. A first transmission (6-f1) is added between the first motor (2-f1) and the first drive wheel (1-f1). A second transmission (6-f2) is added between the second motor (2-f2) and the second drive wheel (1-f2). A third transmission (6-r1) is added between the third motor (2-r1) and the third drive wheel (1-r1). A fourth transmission (6-r2) is added between the fourth motor (2-r2) and the fourth drive wheel (1-r2). These transmissions are controlled by a shift command output by the controller (4), and are two-stage shifts of a Lo gear with a large reduction ratio and a Hi gear with a small reduction ratio. Each motor and each inverter has the energy loss characteristics (sum of motor loss and inverter loss) of the motor and inverter shown in FIG.

  It is assumed that the required rotational speed N = 2100 [rpm] and the total torque Ta = 32 [Nm] in a certain running state.

  At this time, when there is no transmission and the necessary torque is evenly distributed to the four motors, the torque of each motor is Tf1 = Tf2 = Tf3 = Tf4 = 32/4 = 8.0 [Nm] (Formula 3 ) As a result, the operating points of the four types of motors become the operating point D in FIG.

  On the other hand, a case will be described in which the reduction ratio of the transmission is determined so as to minimize the system loss, and the total torque is allocated to each of the four motors, that is, the output torques of the four motors are not the same. Here, for simplification of explanation, it is assumed that the two front drive wheels and the two rear drive wheels have the same torque distribution, and two transmissions between the front drive wheels and the motor. Are in the same state (Hi or Lo), and the two transmissions between the rear drive wheels and the motor are in the same state (Hi or Lo).

  FIG. 13 is a system loss map showing the relationship between the system loss L and the torque distribution ratio Dm when the torque distribution ratio Dm to each motor is Dm = (Tf1 + Tf2) / (Tf1 + Tf2 + Tr1 + Tr2) (formula 9). The system loss L in FIG. 13 is expressed as a relative value when the system loss is 1.0 when there is no transmission and equal torque is distributed to the four wheels (Dm = 0.50).

  When the reduction ratio of all the transmissions is Lo, the system loss L is minimum at L4 when Dm = 0.0 or Dm = 1.0 in the range of 0 ≦ Dm ≦ 1. Further, when the reduction ratio of all the transmissions is Hi, the system loss L is minimum at L5 when Dm = 0.0 or Dm = 1.0 in the range of 0 ≦ Dm ≦ 1.

  On the other hand, when the reduction ratio of the two transmissions on the front wheel side is Lo and the reduction ratio of the two transmissions on the rear wheel side is Hi, and the reduction ratio of the two transmissions on the front wheel side is Hi and the rear wheel side When the reduction ratio of the two transmissions is Lo, the system loss L is minimum at L6. In addition, as shown in FIG. 13, compared with the case where there is no transmission and all the reduction ratios are Lo, the structure provided with the transmission can reduce the system loss by shifting.

  The internal processing of the controller (4) will be described using the flowchart of FIG. In step S141, the driving force or braking force requested by the driver, that is, the necessary rotational speed N and the total torque Ta are obtained from the vehicle speed, the accelerator signal and the brake signal input to the controller (4). In step S142 subsequent to step S141, the system loss when the torque distribution to the four motors and the reduction ratios (Hi or Lo) of the four transmissions are changed using the system loss map used in FIG. Estimate L. In step S143 following step S142, a distribution ratio Dmin that is the minimum system loss Lmin when the motor is driven with the distribution ratio Dm calculated in the previous step S142 and the transmission reduction ratio is calculated, and the output of each motor is calculated. Determine the torque and reduction ratio of each transmission. In step S144 following step S143, a control command is output to each inverter that controls each motor so that each motor can output the output torque determined in step S143, and a shift command is output to each transmission.

  With the above configuration, the first embodiment is configured by distributing torque to each motor in combination with a reduction ratio that minimizes system loss based on the system loss characteristics of a system including four motors and four inverters. System efficiency can be further improved.

Example 5
Example 5 will be described with reference to FIGS. 15 and 16. The difference in configuration of the fifth embodiment from the first embodiment is that in this embodiment, the front motor group consisting of the first motor (2-f1) and the second motor (2-f2) and the first inverter. Energy efficiency characteristics combining the front inverter group consisting of (3-f1) and the second inverter (3-f2), and the rear motor consisting of the third motor (2-r1) and the fourth motor (2-r2) The energy efficiency characteristics of the rear inverter group consisting of the group, the third inverter (3-r1) and the fourth inverter (3-r2) are different, but in Example 1, all the motors and inverters have the same energy efficiency characteristics. It differs in having had. In addition, about the structure equivalent to each above-mentioned Example, the code | symbol similar to each Example is attached | subjected and description in this Example 5 is abbreviate | omitted.

  The configuration of this embodiment is the same as that of FIG. 2 used in the first embodiment. However, the front motor group and the front inverter group have the energy efficiency characteristics of the motor and the inverter shown in FIG. Further, the rear motor group and the rear inverter group have the energy efficiency characteristics of the motor and the inverter shown in FIG. That is, the total characteristics of the motor and the inverter are different between the front part and the rear part.

  It is assumed that the required rotational speed N = 3500 [rpm] and the total torque Ta = 100 [Nm] in a certain running state.

  At this time, the torque required for the entire four motors is Tf1 + Tf2 + Tf3 + Tf4 = 100 [Nm] (Equation 17). Thereby, the first motor (2-f1) and the second motor (2-f2) of the front motor group are connected to the third motor (2-r1) of the rear motor group and the operation line P shown in FIG. The fourth motor (2-r2) operates on the operating line Q shown in FIG. 15 at an operating point that satisfies the condition of (Equation 17). It is assumed that the rear motor group has a characteristic that energy efficiency is better in a high rotation region than the front motor group.

  FIG. 16 shows the system efficiency when the torque distribution is changed between the front motor group and the rear motor group based on the system efficiency when the required torque is evenly distributed to the four motors (1.0). Expressed as an efficiency map. According to FIG. 16, in the range of 0 ≦ Dm ≦ 1, the system efficiency E is maximum when Dm = 0.8.

  Thus, even in a system in which motors having different energy characteristics are combined, a system efficiency map of the entire system is created from the energy characteristics of each motor, and torque is distributed to four motors based on this system efficiency map. Thus, the same effects as those of the first embodiment can be obtained.

Example 6
The difference in configuration of the sixth embodiment from the above-described embodiments is that in the present embodiment, each motor is an in-wheel motor, and the driving torque of each motor is directly transmitted to the tire. In addition, about the structure equivalent to each above-mentioned Example, the code | symbol similar to each Example is attached | subjected, and description in this Example 6 is abbreviate | omitted.

  The in-wheel type motor in this embodiment is converted into energy transmission efficiency or rotational energy of the shaft or gear in the calculation performed by the controller (4), compared to the method of transmitting via the shaft or gear. There is no need to consider energy. In particular, the energy transmission efficiency of the shaft and gear varies greatly depending on the number of rotations and the transmission torque, and furthermore, there are variations in individual differences, making it difficult to estimate accurately. Therefore, the in-wheel type is improved in controllability by reducing these error factors, and as a result, the effect of improving the system efficiency is increased.

[Other Examples]
In the above-described fifth embodiment, the rear motor group is configured by motors having high energy efficiency in the high rotation region as compared with the front motor group. However, the front motor group is configured by motors having high energy efficiency in the high torque region as compared with the rear motor group. Even if it comprises, the effect similar to Example 5 can be show | played.

  In the fifth embodiment, the first motor (2-f1) and the second motor (2-f2) have the same characteristics, and the third motor (2-r1) and the fourth motor (2-r2) have the same characteristics. However, it is not necessary for the front motor or the rear motor to have the same characteristics. For example, all four motors may have different characteristics, and the first motor (2-f1) and the third motor (2-r1) have the same characteristics, and the second motor (2-f2). The fourth motor (2-r2) may have the same characteristics.

  In the above-described fifth embodiment, the torque is distributed to each motor using the energy efficiency and the system efficiency. However, even if the energy loss and the system loss are used as in the above-described second embodiment, the same effect as in the fifth embodiment is achieved. An effect can be obtained.

  In each of the foregoing embodiments, the number of motors and inverters is four, but the number of motors and inverters is not limited to this. For example, two wheels at the rear of the vehicle body may be used as slave wheels and motors may be provided at the two front wheels. Similarly, the number of clutches and transmissions is not limited to the numbers used in the above-described embodiments. The number of motors and inverters, motors and clutches, and motors and transmissions may not be the same. For example, in a configuration in which the power of one motor is transmitted to the left and right wheels by the drive shaft, the present invention can be implemented even if a left and right wheel and a drive shaft are provided with separate clutches.

  In the above-described fourth embodiment, the number of transmission stages is two, but the number of stages is not limited to this. For example, in the system efficiency map of the two-stage shift shown in FIG. 13, the system loss due to the combination of each gear is represented by four curves, but when the three-stage shift is achieved, each gear is represented by nine curves. Therefore, the system loss can be calculated and can be implemented.

  In the first embodiment and the second embodiment, the energy efficiency or energy loss of the motor or the motor and the inverter is used to maximize the system efficiency or the system loss of the whole motor or the system including the whole motor and the whole inverter. The torque distribution that minimizes the calculation has been calculated, but the energy efficiency or energy loss to be used is not limited to the motor and the inverter. For example, based on the energy efficiency or energy loss of the motor and transmission, all motors and all transmissions may be used as a system, and torque distribution may be determined from the system efficiency or system loss.

  In each of the above-described embodiments, the torque distribution is determined from the system efficiency or system loss including all motors connected to the drive wheels. However, the system efficiency or system loss including all motors may not be used. For example, a motor is provided for each of the four wheels, and the torque of these motors can be controlled separately. However, the two front motors are used during normal driving, and the front motor 2 is used only when starting on a slope. Suppose that there is a vehicle that uses two motors in addition to the rear motor. Since the two rear motors are hardly used, the system efficiency can be sufficiently improved even by adjusting only the torque distribution of the two front motors.

  In each of the embodiments described above, the number of drive wheels is four, but the number of drive wheels is not limited to this because the present invention can be applied if the number of motors is two or more.

  In each of the above-described embodiments, the driving force is allocated so that the system efficiency is maximized or the system loss is minimized. However, it is only necessary to allocate the driving efficiency so that the system efficiency is good or the system loss is small. For example, consider a case where a mechanical burden is placed on each component when the driving force is distributed so as to maximize the system efficiency. At this time, in order to prevent an excessive mechanical burden, the driving force may be distributed so that the system efficiency is slightly less than the maximum value.

It is a figure showing the energy efficiency characteristic which converted the motor rotation speed and the motor torque into the vehicle speed and the driving force, respectively. It is a figure showing the structure of the whole vehicle drive device used in Example 1. FIG. It is a figure which shows the energy efficiency of the motor single-piece | unit used in Example 1. FIG. It is a system efficiency map of the system which consists of four motors when the required rotation speed N = 400 and total torque Ta = 20 used in Example 1. 2 is a system efficiency map group including a plurality of system efficiency maps used in the first embodiment. It is a flowchart showing the internal process of the controller (4) used in Example 1. FIG. It is a figure which shows the sum of the energy loss of the motor used in Example 2, and an inverter. FIG. 10 is a system loss map of a system including four motors and four inverters when a necessary rotation speed N = 2100 and a total torque Ta = 32 used in the second embodiment. It is a figure showing the structure of the whole vehicle drive device used in Example 3. FIG. It is a system loss map in each clutch state of the system which consists of four motors and four inverters when required rotational speed N = 2100 used in Example 3 and total torque Ta = 32. It is a flowchart showing the internal process of the controller (4) used in Example 3. FIG. FIG. 10 is a diagram illustrating a configuration of an entire vehicle drive device used in a fourth embodiment. FIG. 10 is a system loss map in a shift state of each transmission of a system including four motors and four inverters when a necessary rotation speed N = 2100 and a total torque Ta = 32 used in the fourth embodiment. It is a flowchart showing the internal process of the controller (4) used in Example 4. FIG. It is a figure which shows the sum of the energy efficiency of the motor and inverter used in Example 5. FIG. FIG. 10 is a system efficiency map of a system including four motors and four inverters when the required rotational speed N = 3500 and the total torque Ta = 100 used in the fifth embodiment.

Explanation of symbols

1-f1 1st drive wheel 1-f2 2nd drive wheel 1-r1 3rd drive wheel 1-r2 4th drive wheel 2-f1 1st motor 2-f2 2nd motor 2-r1 3rd motor 2-r2 1st 4-motor 3-f1 first inverter 3-f2 second inverter 3-r1 third inverter 3-r2 fourth inverter 4 controller 5-f1 first clutch 5-f2 second clutch 5-r1 third clutch 5-r2 first 4 clutch 6-f1 1st transmission 6-f2 2nd transmission 6-r1 3rd transmission 6-r2 4th transmission

Claims (29)

A plurality of drive wheels;
A plurality of motors for transmitting torque to each of the plurality of drive wheels;
A vehicle drive device comprising: motor control means for controlling the plurality of motors in order to control the drive force of each of the drive wheels. 2. The vehicle drive device according to claim 1, wherein the motor control means controls torque distribution of the plurality of motors using an inverter connected to at least one of the plurality of motors. At least one clutch provided between the plurality of motors and drive wheels;
Clutch control means for controlling the clutch,
The vehicle drive apparatus according to claim 2, wherein the clutch control unit controls the clutch. At least one transmission provided between the plurality of motors and drive wheels;
Transmission control means for controlling the transmission,
The vehicle drive apparatus according to claim 2, wherein the transmission control unit controls the transmission. 5. The vehicle drive according to claim 1, wherein the motor control unit controls torque distribution of the plurality of motors based on an operation efficiency of at least two of the plurality of motors. apparatus. The vehicle drive apparatus according to claim 1, wherein the motor control unit controls torque distribution of the plurality of motors based on an operation efficiency of the plurality of motors as a whole. The vehicle drive device according to claim 2, wherein the motor control unit controls torque distribution of the plurality of motors based on a total operation efficiency of the plurality of motors and the inverter. The motor control means controls the torque distribution of the plurality of motors based on the total operating efficiency of the plurality of motors and the inverter, or the clutch control means controls the clutch. The vehicle drive device according to claim 3. Based on the total operating efficiency of the plurality of motors and the inverter, the motor control means controls torque distribution of the plurality of motors, or the transmission control means controls the transmission. The vehicle drive device according to claim 4, wherein The vehicle drive apparatus according to claim 1, wherein the motor control unit controls torque distribution of the plurality of motors based on an operation loss of the plurality of motors as a whole. The vehicle drive device according to claim 2, wherein the motor control unit controls torque distribution of the plurality of motors based on a total operation loss of the plurality of motors and the inverter. The motor control means controls the torque distribution of the plurality of motors based on the total operating loss of the plurality of motors and the inverter, or the clutch control means controls the clutch. The vehicle drive device according to claim 3. The motor control means controls the torque distribution of the plurality of motors based on the total operating loss of the plurality of motors and the inverter, or the transmission control means controls the transmission. The vehicle drive device according to claim 4, wherein Storage means for storing efficiency characteristics of the plurality of motors;
An estimation means for estimating the operation efficiency of the plurality of motors based on the efficiency characteristics;
The vehicle drive device according to claim 5, wherein the motor control unit controls torque distribution of the plurality of motors based on the estimation. Storage means for storing efficiency characteristics combining the plurality of motors and the inverter;
An estimation means for estimating an operation efficiency of the plurality of motors and the inverter based on the efficiency characteristics;
8. The vehicle drive apparatus according to claim 2, wherein the motor control unit controls torque distribution of the plurality of motors based on the estimation. Storage means for storing efficiency characteristics combining the plurality of motors and the inverter;
An estimation means for estimating an operation efficiency of the plurality of motors and the inverter based on the efficiency characteristics;
The motor control means controls torque distribution of the plurality of motors based on the estimation,
9. The vehicle drive device according to claim 8, wherein the clutch control means controls the clutch based on the estimation. Storage means for storing efficiency characteristics combining the plurality of motors and the inverter;
An estimation means for estimating an operation efficiency of the plurality of motors and the inverter based on the efficiency characteristics;
The motor control means controls torque distribution of the plurality of motors based on the estimation,
The vehicle drive apparatus according to claim 9, wherein the transmission control unit controls the transmission based on the estimation. Storage means for storing efficiency characteristics of the plurality of motors;
An estimation means for estimating an operating loss of the plurality of motors based on the efficiency characteristics;
11. The vehicle drive device according to claim 5, wherein the motor control unit controls torque distribution of the plurality of motors based on the estimation. Storage means for storing efficiency characteristics combining the plurality of motors and the inverter;
An estimation means for estimating an operation loss of the plurality of motors and the inverter based on the efficiency characteristics;
The vehicle drive device according to claim 2, wherein the motor control unit controls torque distribution of the plurality of motors based on the estimation. Storage means for storing efficiency characteristics combining the plurality of motors and the inverter;
An estimation means for estimating an operation loss of the plurality of motors and the inverter based on the efficiency characteristics;
The motor control means controls torque distribution of the plurality of motors based on the estimation,
The vehicle drive device according to claim 12, wherein the clutch control means controls the clutch based on the estimation. Storage means for storing efficiency characteristics combining the plurality of motors and the inverter;
An estimation means for estimating an operation loss of the plurality of motors and the inverter based on the efficiency characteristics;
The motor control means controls torque distribution of the plurality of motors based on the estimation,
The vehicle drive device according to claim 13, wherein the transmission control unit controls the transmission based on the estimation. The plurality of motors includes a first group including motors having the same characteristics;
The vehicle according to any one of claims 1 to 21, wherein the vehicle includes a second group including motors having the same characteristics among motors not included in the first group. Drive device. 23. The vehicle drive device according to claim 22, wherein the motor constituting the first group and the motor constituting the second group have different rated outputs. 24. The vehicle drive device according to claim 22, wherein the motor constituting the first group and the motor constituting the second group have different operating efficiency or operating loss characteristics. The first group is composed of motors that drive driving wheels at the front of the vehicle,
The vehicle drive apparatus according to any one of claims 22 to 24, wherein the second group includes a motor that drives drive wheels at a rear portion of the vehicle. The first group includes a motor that drives a drive wheel on the right side of the front part of the vehicle and a motor that drives a drive wheel on the left side of the rear part of the vehicle.
The said 2nd group is comprised by the motor which drives the driving wheel of the vehicle front left side, and the motor which drives the driving wheel of the vehicle rear right side, The one of Claim 22 to 24 characterized by the above-mentioned. Vehicle drive device. 27. The vehicle drive device according to claim 1, wherein at least one of the motors is an in-wheel motor. A first drive wheel;
A second drive wheel,
A first motor for transmitting a driving force to the first driving wheel;
A second motor for transmitting a driving force to the second driving wheel;
Motor control means,
The motor control unit controls a torque output by the first motor and the second motor in order to distribute a driving force to each driving wheel. A plurality of drive wheels;
Having a plurality of motors for transmitting torque to each of the plurality of drive wheels;
The plurality of motors includes a first group including motors having the same characteristics;
A vehicle drive device comprising a second group composed of motors having the same characteristics among motors not included in the first group.

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