JP2018098947A - Control device of electric vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a control device of an electric vehicle capable of suppressing deterioration or the like of a battery caused by reduction in cell voltage.SOLUTION: A control device of an electric vehicle is configured to: reduce output torque of a traveling motor 3 by using first reduction rate when slip of a driving wheel 5 occurs; and further change reduction rate of the output torque to second reduction rate larger than the first reduction rate, when voltage of a battery 2 drops below a determination threshold value.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a control device that controls an electric vehicle equipped with a traveling motor (electric motor) and a battery that supplies electric power to the traveling motor.

  Conventionally, in an electric vehicle that travels using a travel motor as a power source, when slip occurs on a drive wheel driven by the travel motor, the slip is suppressed by appropriately reducing the output torque output from the travel motor. ing.

  For example, when slip occurs in an electric vehicle, there is one that reduces (torques down) the output torque output from the traveling motor in accordance with the slip rate of the electric vehicle (see, for example, Patent Document 1).

Japanese Patent Laying-Open No. 2006-40968

  By the way, when slip occurs in the drive wheel, the rotation of the traveling motor increases, so that a relatively large current flows through the traveling motor. On the other hand, in a battery that supplies electric power to the traveling motor, the voltage temporarily greatly decreases accordingly. For example, when the battery has a relatively high internal resistance, such as when the battery has deteriorated or when the battery temperature is low, the battery voltage tends to decrease. The battery is composed of a plurality of battery cells, and when a slip occurs in the drive wheel, the voltage (cell voltage) of each battery cell constituting the battery is greatly reduced.

  If the cell voltage is extremely lowered due to the slip of the drive wheel as described above, the battery (battery cell) may be deteriorated, and further, the battery (battery cell) may be damaged. is there. A battery (battery cell) generally has a limited input / output voltage usable range. For example, if the cell voltage falls below the lower limit (lower limit voltage) of the usable range, the battery deteriorates. There is a risk of inviting.

  Further, the decrease in the cell voltage caused by the slip can be suppressed to some extent by reducing the output torque of the traveling motor as described above when the drive wheel slips. However, when the slip amount of the driving wheel is relatively large, there is a possibility that the cell voltage drop cannot be sufficiently suppressed.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a control device for an electric vehicle that can suppress battery deterioration caused by a decrease in cell voltage.

  One aspect of the present invention that solves the above-described problem is a control device that controls an electric vehicle having a traveling motor and a battery that supplies electric power to the traveling motor, and detects an opening degree of an accelerator pedal. An accelerator opening degree detecting means, a motor control means for controlling the output torque of the traveling motor according to the opening degree of the accelerator pedal, and whether or not a slip is generated on a wheel driven by the traveling motor. A slip determination means for determining; and a voltage determination means for determining whether or not the voltage of the battery has dropped below a determination threshold when the slip determination means determines that a slip has occurred. When it is determined by the slip determination means that the slip has occurred, the control means outputs the output torque of the travel motor regardless of the opening of the accelerator pedal. Is reduced at a first reduction rate, and further, when the voltage determination means determines that the voltage of the battery has dropped below the determination threshold value, the output torque reduction rate is made lower than the first reduction rate. The control apparatus for an electric vehicle is characterized by changing to a large second reduction rate.

  Here, the control device includes a deterioration state determination unit that determines a deterioration state of the battery, and the motor control unit may increase the second decrease rate as the degree of deterioration of the battery progresses. preferable.

  Preferably, the control device includes a temperature detection unit that detects a temperature of the battery, and the motor control unit increases the second decrease rate as the temperature of the battery is lower.

  Preferably, the control device includes a deterioration state determination unit that determines a deterioration state of the battery, and the voltage determination unit sets the determination threshold value to a larger value as the degree of deterioration of the battery progresses.

  In addition, the control device includes temperature detection means for detecting the temperature of the battery, and the voltage determination means sets the determination threshold value to a larger value as the temperature of the battery detected by the temperature detection means is lower. Is preferred.

  According to the present invention, when the driving wheel slips, each battery cell (cell voltage) can be prevented from being extremely reduced, and the battery (battery cell) resulting from the reduction in the cell voltage can be suppressed. Deterioration and damage can be suppressed.

It is a figure showing a schematic structure of an electric vehicle provided with a control device concerning the present invention. It is the schematic which shows an example of the battery mounted in an electric vehicle. It is a block diagram which shows schematic structure of the control apparatus which concerns on this invention. It is a flowchart of an example of the torque control by the control apparatus which concerns on this invention. It is a figure which compares and shows each change of the accelerator opening degree, output torque, and cell voltage in the torque control which concerns on this invention. It is a figure which compares and shows the other example of each change of the accelerator opening degree, output torque, and cell voltage in the torque control which concerns on this invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. First, the overall configuration of the electric vehicle according to the present embodiment will be described.
As shown in FIG. 1, an electric vehicle 1 according to this embodiment is an electric vehicle (EV), and is a battery 2 that is a rechargeable secondary battery and an electric motor that operates by supplying power from the battery 2. And a traveling motor 3. The travel motor 3 is connected to drive wheels (in this embodiment, front wheels) 5 via an automatic transmission 4, for example.

  Here, as shown in FIG. 2, the battery 2 includes a plurality of battery cell units 7 including a plurality of battery cells 6. Each battery cell 6 is connected in series by a bus bar or the like although not shown. It is connected. The plurality of battery cell units 7 are housed in a housing case 8, and the housing case 8 is closed by a lid member 9.

  The electric vehicle 1 also includes a control unit (ECU) 10 that comprehensively controls various devices mounted on the electric vehicle 1. The control unit 10 includes an input / output device, a storage device (ROM, RAM, etc.), a central processing unit (CPU), a timer counter, and the like, and is based on signals from various sensors provided in the electric vehicle 1. The operation state is grasped, and various devices are comprehensively controlled based on it.

  As shown in FIG. 3, the control unit 10 includes various sensors provided in the electric vehicle 1, for example, an accelerator pedal stroke sensor (accelerator opening detection means) 32 that detects a stroke of the accelerator pedal 31, and a stroke of the brake pedal 33. A brake pedal stroke sensor 34 for detecting the wheel speed, a wheel speed sensor (wheel speed detecting means) 35 for detecting the rotational speed (wheel speed) of the driving wheel (front wheel) 5 of the electric vehicle 1, and the rotational speed of the traveling motor 3. Rotational speed detection sensor 37, battery voltage sensor (battery voltage detection means) 38 for detecting the voltage (total voltage and cell voltage) of the battery 2, battery temperature sensor (battery temperature detection means) 39 for detecting the temperature of the battery 2, etc. Based on the signal from the vehicle, the driving state of the electric vehicle 1 is accurately grasped, and the electric motor including the driving motor 3 is based on the driving state. Comprehensive control of both 1 various devices. In addition, what is necessary is just to employ | adopt existing sensors as said various sensors.

  The control device according to the present embodiment includes the control unit 10 and various sensors such as an accelerator pedal stroke sensor 32, a battery voltage sensor 38, and a battery temperature sensor 39. When slip occurs, the output torque output from the traveling motor 3 is appropriately controlled. Thereby, since the excessive voltage drop of each battery cell 6 which comprises the battery 2 is suppressed, generation | occurrence | production and deterioration of the battery 2 (battery cell 6) can be suppressed.

  Specifically, the control unit 10 includes a motor control unit (motor control unit) 11, a slip determination unit (slip determination unit) 12, a voltage determination unit (voltage determination unit) 13, and a deterioration state determination unit (deterioration state determination unit). 14).

  Based on the detection results of the sensors as described above, the motor control unit 11, for example, in addition to the opening degree of the accelerator pedal 31, the rotational speed (wheel speed) of the drive wheels 5 and the rotational speed of the traveling motor 3 Based on the above, the required torque required for the traveling motor 3 is calculated. Then, the motor control unit 11 appropriately controls the traveling motor 3 so that the actual output torque of the traveling motor 3 matches (or approaches) this required torque. That is, the motor control unit 11 controls the output torque of the traveling motor 3 to match the required torque by adjusting the power supplied from the battery 2 to the traveling motor 3.

  The slip determination unit 12 determines whether or not slip has occurred in the drive wheel (front wheel) 5 driven by the traveling motor 3. In the present embodiment, the slip determination unit 12 determines whether or not a predetermined slip has occurred based on the cell voltage of each battery cell 6 detected by the battery voltage sensor 38. Specifically, the slip determination unit 12 sets the voltage (cell voltage) of any of the battery cells 6 constituting the battery 2 to a preset first value on the condition that the opening degree of the accelerator pedal 31 has rapidly increased. It is determined that slip of the drive wheel 5 has occurred when the value falls below the threshold value.

  Even during normal traveling, the voltage of the battery cell 6 decreases as the output torque of the traveling motor 3 increases, but does not decrease to the first threshold value. In other words, the first threshold value is set to such a low value that the cell voltage does not reach even when the output torque of the traveling motor 3 increases during normal traveling.

  Moreover, the determination method of whether the slip generate | occur | produced in the drive wheel 5 is not specifically limited, It does not necessarily need to determine based on a cell voltage. For example, a voltage of a capacitor (not shown) connected to the traveling motor is detected, and when the capacitor voltage is equal to or lower than a predetermined threshold value, it is determined that the drive wheel 5 is slipping. Good. Further, whether or not slip has occurred in the drive wheel 5 is determined by, for example, the difference in the rotational speed between the drive wheel (front wheel) 5 and the driven wheel (rear wheel), the rate of change in the opening degree of the accelerator pedal 31, and the travel motor. It can also be determined based on the rate of change in the number of rotations of 3.

  During normal travel, the motor control unit 11 appropriately controls the output torque of the travel motor 3 according to the opening degree of the accelerator pedal 31 as described above, but is driven by the slip determination unit 12 as described above. When it is determined that the slip of the wheel 5 has occurred, at that time, control is performed to reduce the output torque of the traveling motor 3 at a preset first reduction rate regardless of the opening of the accelerator pedal 31. Do. That is, when the slip determination unit 12 determines that the drive wheel 5 is slipping, the motor control unit 11 performs control to reduce the output torque of the traveling motor 3 with a predetermined gradient. The first rate of decrease is set to a small value that does not impair the drivability of the electric vehicle 1.

  Thereby, the slip which has arisen in the drive wheel 5 can be suppressed, suppressing the deterioration of the drivability of the electric vehicle 1. FIG. Furthermore, it can suppress that the voltage (cell voltage) of the battery 2 falls below the lower limit (lower limit voltage) of the usable range, and deterioration of the battery 2 and occurrence of damage can be suppressed.

  When it is determined by the slip determination unit 12 that the drive wheel 5 has slipped, the voltage determination unit 13 further determines whether or not the cell voltage has decreased to a second threshold that is a determination threshold. To do. Note that the second threshold value is set to a value that is equal to or smaller than the first threshold value and greater than the lower limit (lower limit voltage) of the usable range of the battery cell 6.

  When the voltage determination unit 13 determines that the cell voltage has decreased to the second threshold value or less, the motor control unit 11 sets the output torque reduction rate of the traveling motor 3 to be greater than the first reduction rate. Change to 2 reduction rate. That is, the motor control unit 11 greatly changes the gradient of the output torque of the traveling motor 3 (makes the gradient abrupt).

  Thereby, it can suppress that a cell voltage falls exceeding the minimum of the usable range. Therefore, the deterioration and damage of the battery 2 accompanying the decrease in the cell voltage can be more reliably suppressed.

  By reducing the output torque of the traveling motor 3 at the first reduction rate as described above, the cell voltage reduction can be suppressed to some extent, but when the slip amount of the drive wheel 5 is relatively large, etc. There is a possibility that the decrease in the cell voltage cannot be sufficiently suppressed.

  However, in the present embodiment, when the cell voltage decreases to the second threshold (<first threshold) or less, the output torque decrease rate is changed from the first decrease rate to the second decrease rate. Therefore, for example, even when the slip amount of the drive wheel 5 is relatively large on a low μ road, it is possible to sufficiently suppress a decrease in the cell voltage. In other words, the cell voltage can be restored without being lowered below the lower limit (lower limit voltage) of the usable range. Therefore, deterioration and damage of the battery 2 can be suppressed more reliably.

Such torque control by the control device according to the present embodiment will be further described with reference to FIGS. 4 and 5.
As shown in the flowchart of FIG. 4, during traveling of the electric vehicle 1, it is determined in step S <b> 1 whether or not the cell voltage is equal to or lower than a first threshold, and it is determined that the cell voltage is equal to or lower than the first threshold. If it is (step S1: Yes), then in step S2, the output torque of the traveling motor 3 is reduced at the first reduction rate. Thereafter, in step S3, it is determined whether or not the cell voltage is equal to or lower than a second threshold value (<first threshold value), and if it is determined that the cell voltage is equal to or lower than the second threshold value (step S3: Yes). Then, the reduction rate of the output torque is changed from the first reduction rate to the second reduction rate. That is, the output torque is reduced at a second reduction rate that is larger than the first reduction rate (step S4).

  Thereafter, in step S5, it is determined whether or not the cell voltage is higher than a third threshold that is equal to or higher than the second threshold. In the present embodiment, the third threshold value = the first threshold value. Here, when the cell voltage is lower than the third threshold value (step S5: No), the control for reducing the output torque of the traveling motor 3 at the second reduction rate is continued. On the other hand, when the cell voltage is higher than the third threshold value (step S5: Yes), it is determined that the cell voltage has increased, the control for decreasing the output torque is terminated, and the normal output torque control is performed. Return.

  In step S3, when the cell voltage is larger than the second threshold (step S3: No), the process proceeds to step S5, and it is determined whether or not the cell voltage is higher than the third threshold. Then, when the cell voltage is lower than the third threshold (step S5: No), the control for reducing the output torque of the traveling motor 3 at the first reduction rate is continued. On the other hand, when the cell voltage is higher than the third threshold (step S5: Yes), the control for reducing the output torque is terminated and the control returns to the normal output torque control.

  For example, as shown in FIG. 5, when the accelerator opening increases rapidly at time t1, the output torque of the traveling motor 3 increases rapidly. In addition, the voltage (cell voltage) of the battery 2 decreases as the output torque increases rapidly. When the cell voltage becomes equal to or lower than the first threshold value V1 at time t2, the output torque of the traveling motor 3 is reduced at the first reduction rate (time t2-t3). Thereafter, when the cell voltage becomes equal to or lower than the second threshold value V2 at time t3, the rate of decrease in the output torque of the traveling motor 3 is changed from the first rate of decrease to the second rate of decrease. Thereafter, when the cell voltage recovers and becomes higher than the third threshold value V3, the control for reducing the output torque is terminated, and the control returns to the normal output torque control. For example, in this example, when the output torque is reduced to zero at time t4, the output torque remains zero, and when the cell voltage becomes higher than the third threshold value V3 at time t5, the output torque is reduced. Control is terminated and control returns to normal output torque control.

  Further, as indicated by the dotted line in the figure, after the output torque of the traveling motor 3 starts to decrease at the first decrease rate at time t2, the output torque recovers without decreasing to the second threshold value V2 or less, and the time When it becomes equal to or greater than the third threshold value V3 (in this embodiment, the same value as the first threshold value) at t6, the control for reducing the output torque is terminated and the control returns to the normal output torque control.

  As described above, according to the control device for an electric vehicle according to the present embodiment, when the drive wheel 5 slips, the voltage (cell voltage) of each battery cell 6 is set to the lower limit voltage Vm within the usable range. It is possible to suppress excessively lowering, and it is possible to suppress deterioration and damage of the battery 2 (battery cell 6) due to the decrease in the cell voltage.

  In the present embodiment, the example in which the second threshold is set to a value smaller than the first threshold has been described. However, the second threshold may match the first threshold. In this case, as shown in FIG. 6, when the cell voltage becomes equal to or lower than the second threshold value V2 (= first threshold value V1) at time t2, the output torque of the traveling motor 3 is reduced at the second reduction rate. (Time t2-t4). Thereafter, when the output torque is reduced to zero at time t4, the output torque is maintained at zero, and when the cell voltage becomes higher than the third threshold value V3 at time t5, the control for reducing the output torque is ended. Return to normal output torque control.

  In the present embodiment, the voltage determination unit 13 determines whether or not the cell voltage has decreased to the second threshold value or less based on the detection result of the battery voltage sensor 38. It may be performed based on the parameters. When the slip of the drive wheel 5 occurs and the cell voltage decreases, the wheel speed increases rapidly. For this reason, it can also be determined (estimated) whether or not the cell voltage has decreased from the wheel speed to the second threshold value or less. That is, when the wheel speed increases beyond the first wheel speed that is the determination threshold, it may be determined (estimated) that the cell voltage has decreased below the second threshold. The determination as to whether or not the cell voltage has dropped below the second threshold is made based on, for example, the rate of change of the accelerator opening that can also be used for slip determination and the rate of change of the rotational speed of the traveling motor. It may be.

  In addition, the second threshold value that is the determination threshold value of the output torque may be set in advance in consideration of the characteristics of the battery 2 and the like, but in this embodiment, the voltage determination unit 13 determines the deterioration state determination unit 14 It is set based on the result.

  The deterioration state determination unit 14 calculates the state of health (SOH) of the battery based on the current full charge capacity (Ah) of the battery 2 and the initial full charge capacity (Ah) of the battery 2 ( The deterioration state of the battery 2 is determined according to the calculated SOH value (see the following formula (1)). That is, the deterioration state determination unit 14 determines that the deterioration of the battery 2 is advanced as the SOH value is smaller. The SOH is appropriately calculated when the battery 2 is charged, and the result is stored.

  SOH = (current full charge capacity / initial full charge capacity) × 100 (1)

  The voltage determination unit 13 sets the second threshold within the above range (below the first threshold) as the degree of deterioration of the battery 2 determined by the deterioration state determination unit 14 progresses (the value of SOH decreases). Moreover, it is set to a larger value at the lower limit (lower limit voltage) of the usable range of the battery cell 6. Furthermore, in this embodiment, the voltage determination part 13 sets a 2nd threshold value to a larger value within the said range, so that the temperature of the battery 2 is low based on the detection result of the battery temperature sensor 39. FIG.

  As the deterioration of the battery 2 progresses and the temperature of the battery 2 decreases, the cell voltage tends to decrease greatly when a slip occurs. That is, as the deterioration of the battery 2 progresses and the temperature of the battery 2 decreases, the cell voltage decreases beyond the lower limit (lower limit voltage) of the usable range (for example, the range of 2V to 4V). The possibility increases.

  Therefore, the second threshold is set to a larger value within the above range as the deterioration of the battery 2 progresses and the temperature of the battery 2 decreases. As a result, the rate of decrease in the output torque of the traveling motor 3 is changed from the first rate of decrease to the second rate of decrease at an earlier stage after the occurrence of the slip. Therefore, it can suppress more reliably that cell voltage falls exceeding the lower limit of the usable range.

  On the other hand, when the battery 2 is not deteriorated or when the temperature of the battery 2 is relatively high, the second threshold value is set to a lower value. For this reason, when the output torque of the traveling motor 3 is reduced, the period of the first reduction rate becomes longer, so that drivability can be maintained better.

  As described above, in the present embodiment, the voltage determination unit 13 sets the second threshold based on the deterioration degree of the battery 2 determined by the deterioration state determination unit 14 and the temperature of the battery 2, Furthermore, the second threshold value may be set based on information such as the outside air temperature or weather of the place where the electric vehicle 1 is traveling.

  Further, the motor control unit 11 may appropriately change the second reduction rate of the output torque based on the determination result of the above-described deterioration state determination unit 14 and information such as the outside air temperature and the weather. For example, as the degree of deterioration of the battery 2 progresses, the second reduction rate of the output torque may be increased (increased), and the battery voltage may be restored earlier. Furthermore, similarly to the case of the second reduction rate, the motor control unit 11 may increase the first reduction rate of the output torque as the degree of deterioration of the battery 2 progresses. Although it is preferable to change the first reduction rate together with the second reduction rate, only the first reduction rate may be changed.

Although one embodiment of the present invention has been described above, the present invention is not limited to the above-described embodiment.
For example, in the above-described embodiment, the present invention has been described by exemplifying an electric vehicle (EV) including a traveling motor as an example of the electric vehicle. However, the present invention can be applied to various electric vehicles. . The present invention can also be applied to, for example, a hybrid vehicle including an engine (internal combustion engine) as a drive device together with a traveling motor.

DESCRIPTION OF SYMBOLS 1 Electric vehicle 2 Battery 3 Driving motor 4 Automatic transmission 5 Drive wheel 6 Battery cell 7 Battery cell unit 8 Housing case 9 Cover member 10 Control part 11 Motor control part (motor control means)
12 Slip determination unit (slip determination means)
13 Voltage determination unit (voltage determination means)
14 Deterioration state determination unit (deterioration state determination means)
31 accelerator pedal 32 accelerator pedal stroke sensor (accelerator opening detection means)
33 Brake pedal 34 Brake pedal stroke sensor 37 Revolution detection sensor 38 Battery voltage sensor (battery voltage detection means)
39 Battery temperature sensor (battery temperature detection means)

Claims (5)

A control device that controls an electric vehicle having a traveling motor and a battery that supplies electric power to the traveling motor,
An accelerator opening detecting means for detecting the opening of the accelerator pedal;
Motor control means for controlling the output torque of the traveling motor in accordance with the opening of the accelerator pedal;
Slip determination means for determining whether or not a slip is generated on a wheel driven by the traveling motor;
Voltage determination means for determining whether or not the voltage of the battery has decreased to a determination threshold value or less when it is determined by the slip determination means that slip has occurred,
The motor control means includes
When it is determined that slip has occurred by the slip determination means, the output torque of the travel motor is decreased at a first decrease rate regardless of the opening of the accelerator pedal,
Further, when it is determined by the voltage determination means that the voltage of the battery has decreased below the determination threshold value, the decrease rate of the output torque is changed to a second decrease rate that is larger than the first decrease rate. A control device for an electric vehicle. In the control apparatus of the electric vehicle according to claim 1,
A deterioration state determining means for determining a deterioration state of the battery;
The motor control device according to claim 1, wherein the motor control unit increases the second reduction rate as the degree of deterioration of the battery progresses. In the control apparatus of the electric vehicle according to claim 1 or 2,
Temperature detecting means for detecting the temperature of the battery;
The said motor control means increases the said 2nd fall rate, so that the temperature of the said battery is low, The control apparatus of the electric vehicle characterized by the above-mentioned. In the control apparatus of the electric vehicle as described in any one of Claim 1 to 3,
A deterioration state determining means for determining a deterioration state of the battery;
The said voltage determination means sets the said determination threshold value to a large value, so that the deterioration degree of the said battery progresses, The control apparatus of the electric vehicle characterized by the above-mentioned. In the control apparatus of the electric vehicle as described in any one of Claim 1 to 4,
Temperature detecting means for detecting the temperature of the battery;
The control device for an electric vehicle, wherein the voltage determination unit sets the determination threshold to a larger value as the temperature of the battery detected by the temperature detection unit is lower.