JP7110692B2 - Control device - Google Patents

Description

The present disclosure relates to an electric vehicle control device.

Electric vehicles are becoming more popular. An electric vehicle is a vehicle that drives a rotating electrical machine with electric power stored in a storage battery and runs with the driving force of the rotating electrical machine. Such electric vehicles include, for example, electric vehicles that run solely on the driving force of a rotating electrical machine, hybrid vehicles that run on the driving power of both a rotating electrical machine and an internal combustion engine, and the like.

In order to efficiently charge and discharge the storage battery, it is necessary to keep the temperature of the storage battery at an appropriate temperature. Patent Literature 1 listed below describes that when the temperature of the storage battery rises after the start of charging, the charging voltage is limited to a predetermined range or the cooling of the storage battery is started thereafter.

JP 2010-277839 A

The amount of heat generated by the storage battery increases during charging. Therefore, even if countermeasures for suppressing temperature rise are started during charging, it is often difficult to prevent the storage battery from becoming hot. It is also conceivable to continue charging with a smaller charging current, for example, but in this case the time required for charging becomes longer.

An object of the present disclosure is to provide a control device for an electric vehicle that can prevent a storage battery from becoming hot without suppressing a charging current during charging.

A control device according to the present disclosure is a control device (10) for an electric vehicle (EV), and determines whether an opportunity for charging a storage battery (20) mounted on the electric vehicle is imminent. It comprises a charging determination unit (121) and a travel control unit (122) that controls the travel state of the electric vehicle. When the charging determination unit determines that the storage battery is about to be charged, the travel control unit performs heat generation suppression control to bring the vehicle into a travel state in which heat generation in the storage battery is suppressed. The charging determination unit determines whether or not there is an opportunity to charge the storage battery soon, based on the traveling position of the electric vehicle. The charge determination unit determines that the charging of the storage battery is imminent when the distance from the travel position to the chargeable location is below a predetermined distance threshold. The charging determination unit determines a distance threshold based on at least one of the travel distance, the road gradient, the wind speed, the wind direction, and the operation status of the air conditioner mounted on the electric vehicle on the route until the electric vehicle reaches the chargeable place. set.

In such a control device, heat generation in the storage battery is suppressed by the travel control unit performing heat generation suppression control. Such heat generation suppression control is performed when the charge determination unit determines that the opportunity to charge the storage battery is imminent, that is, at a time before the start of charging (for example, when an electric vehicle is running). middle). Therefore, the temperature of the storage battery at the start of charging can be sufficiently lowered in advance while the vehicle is running. After that, the temperature of the storage battery rises with the start of charging, but since the initial temperature is low, the temperature reached is kept low. As a result, it is possible to prevent the storage battery from becoming hot without suppressing the charging current during charging.

According to the present disclosure, there is provided a control device for an electric vehicle that can prevent the storage battery from becoming hot without suppressing the charging current during charging.

FIG. 1 is a diagram schematically showing the overall configuration of a control device according to a first embodiment and an electric vehicle equipped with the control device. FIG. 2 is a diagram showing an example of temperature change of a storage battery. FIG. 3 is a flow chart showing the flow of processing executed by the control device according to the first embodiment. FIG. 4 is a flow chart showing the flow of processing executed by the control device according to the first embodiment. FIG. 5 is a flow chart showing the flow of processing executed by the control device according to the first embodiment. FIG. 6 is a flow chart showing the flow of processing executed by the control device according to the first embodiment. FIG. 7 is a flow chart showing the flow of processing executed by the control device according to the first embodiment. FIG. 8 is a diagram showing an example of changes over time such as actual torque in an electric vehicle. FIG. 9 is a flow chart showing the flow of processing executed by the control device according to the second embodiment.

Hereinafter, this embodiment will be described with reference to the accompanying drawings. In order to facilitate understanding of the description, the same constituent elements in each drawing are denoted by the same reference numerals as much as possible, and overlapping descriptions are omitted.

A control device 10 according to the present embodiment is configured as a device for controlling an electric vehicle EV. Prior to describing the control device 10, the configuration of the electric vehicle EV will be described first with reference to FIG.

The electric vehicle EV is configured as an electric vehicle that drives a motor generator 40 with electric power stored in a storage battery 20 and runs with the driving force of the motor generator 40 . Instead of such a mode, the electric vehicle EV may be configured as a so-called "hybrid vehicle" that can run by the respective driving forces of the motor generator 40 and the internal combustion engine.

The storage battery 20 is a power storage device for storing electric power to be supplied to the motor generator 40 as described above, and is a lithium ion battery in this embodiment. Charging of the storage battery 20 is performed while the electric vehicle EV and a power supply stand (not shown) are connected by a cable. Since electric power is supplied from the storage battery 20 to the motor generator 40 while the electric vehicle EV is running, the amount of electricity stored in the storage battery 20 gradually decreases. However, when the electric vehicle EV decelerates or the like, regenerated electric power generated by the motor generator 40 is supplied to the storage battery 20, so that the amount of electricity stored in the storage battery 20 may increase.

The storage battery 20 is provided with a storage battery sensor 21 . The storage battery sensor 21 is composed of a plurality of sensors. These sensors include a sensor for measuring the temperature of storage battery 20 and a sensor for measuring the amount of electricity stored in storage battery 20 . The temperature and the storage amount measured by the storage battery sensor 21 are respectively input to the control device 10 (specifically, the MG-ECU 110 described later).

Motor generator 40 is a rotating electric machine for generating driving force for electric vehicle EV. As described above, the motor-generator 40 can receive power supplied from the storage battery 20 to generate driving force, or can generate regenerative power and supply it to the storage battery 20 for charging. The above operation of motor generator 40 is controlled by control device 10 (specifically, MG-ECU 110).

The electric vehicle EV includes an outside air temperature sensor 30 , a navigation system 50 , and an in-vehicle camera 60 in addition to the storage battery 20 and the motor generator 40 described above.

The outside air temperature sensor 30 is a sensor for measuring the outside air temperature around the electric vehicle EV. The outside temperature measured by outside temperature sensor 30 is input to control device 10 (specifically, MG-ECU 110).

The navigation system 50 is a device that acquires the current position of the electric vehicle EV by GPS and indicates the route along which the electric vehicle EV should travel based on this and map information. The current position of the electric vehicle EV acquired by the navigation system 50 is input to the control device 10 (specifically, a DSS-ECU 120 described later). The information input from the navigation system 50 to the control device 10 includes the slope and distance of the road on which the electric vehicle EV travels.

The vehicle-mounted camera 60 is a CMOS camera for photographing the surroundings of the electric vehicle EV. An image generated by the vehicle-mounted camera 60 is input to the control device 10 (specifically, a DSS-ECU 120 described later). By analyzing the image, the control device 10 can grasp the presence of other vehicles traveling around the electric vehicle, the traveling speed of the other vehicles, and the like.

The electric vehicle EV is provided with a plurality of sensors for detecting the state of the electric vehicle EV and the state of the surroundings, in addition to the outside air temperature sensor 30, the storage battery sensor 21, and the vehicle-mounted camera 60. 1, its illustration is omitted. Measurement results from each sensor are input to the control device 10 .

The configuration of the control device 10 will be described with continued reference to FIG. The control device 10 according to the present embodiment is composed of two control devices consisting of an MG-ECU 110 and a DSS-ECU 120 . Each control device is configured as a computer system having a CPU, ROM, RAM, and the like. The control device 10 performs two-way communication between the MG-ECU 110 and the DSS-ECU 120 while executing processes necessary for controlling the electric vehicle EV. Specific contents of the processing will be described later.

MG-ECU 110 is configured as a device for performing processing necessary for controlling motor generator 40 . MG-ECU 110 adjusts the magnitude of electric power supplied from storage battery 20 to motor generator 40 so that motor generator 40 generates the required driving force. The adjustment is performed by controlling the operation of a power converter (not shown) interposed between storage battery 20 and motor generator 40 .

The MG-ECU 110 can also adjust the generation of regenerative electric power in the motor generator 40 when the electric vehicle EV decelerates, travels downhill, or the like. The adjustment is also performed by controlling the operation of the power converter.

The MG-ECU 110 basically adjusts the driving force and the like of the motor generator 40 based on the driving operation performed by the driver, thereby adjusting the running speed of the electric vehicle EV. In addition, MG-ECU 110 may adjust the driving force of motor generator 40, etc. based on a request from DSS-ECU 120, which will be described below. Therefore, even if the driver performs a driving operation that accelerates the electric vehicle EV, the driving force is limited by the MG-ECU 110, and the electric vehicle EV is accelerated according to the driving operation. There may be cases where it is not broken.

The DSS-ECU 120 automatically performs processing necessary for running the electric vehicle EV (for example, adjustment of running speed, steering, etc.) as necessary to support part of the driving operation by the driver. It is a control device. The electric vehicle EV may be a vehicle capable of such partial automatic operation, or a vehicle capable of completely automatic operation (driving that does not require the driver's operation). may be Further, the vehicle may be a vehicle that normally travels based only on the driving operation of the driver and supports the driving operation only when necessary.

As described above, the DSS-ECU 120 receives various information from the navigation system 50, the vehicle-mounted camera 60, and the like. The DSS-ECU 120 controls part or all of the running of the electric vehicle EV based on the input information. For example, the DSS-ECU 120 automatically stops the electric vehicle EV in order to prevent a collision when the in-vehicle camera 60 confirms that there is another stopped vehicle ahead.

The DSS-ECU 120 includes a charging determination section 121 and a travel control section 122 as functional control blocks.

The charging determination unit 121 is a part that determines whether or not an opportunity to charge the storage battery 20 is imminent. As will be described later, for example, when the amount of electricity stored in the storage battery 20 is below a predetermined value, it is determined that the opportunity to charge the storage battery 20 is imminent. A specific mode of determination by charge determination unit 121 will be described later.

The running control unit 122 is a part that controls the running state of the electric vehicle EV. The control of the running state performed by the running control unit 122 includes adjustment of the running speed and acceleration of the electric vehicle EV, adjustment of generated regenerative electric power, and the like. A specific aspect of the control will also be described later.

As shown in FIG. 1, in this embodiment, both the charging determination unit 121 and the travel control unit 122 are provided in the DSS-ECU 120. FIG. Alternatively, one or both of the charging determination unit 121 and the travel control unit 122 may be provided in the MG-ECU 110 instead of the DSS-ECU 120 . Further, the measured values of storage battery sensor 21 and outside air temperature sensor 30 may be input to DSS-ECU 120 , and information from navigation system 50 and on-board camera 60 may be input to MG-ECU 110 .

Furthermore, the control device 10 is not configured to be divided into the MG-ECU 110 and the DSS-ECU 120, but is configured as a single control device (ECU) as a whole. and the traveling control unit 122 may be provided. Alternatively, the entire control device 10 may not be mounted on the electric vehicle EV, but may be partially or wholly installed on the cloud. Thus, the specific hardware configuration of the control device 10 is not particularly limited.

A temperature change of the storage battery 20 will be described with reference to FIG. 2 . The horizontal axis of the graph shown in the figure is the travel distance of the electric vehicle EV, and the vertical axis is the temperature of the storage battery 20 . In the example shown in FIG. 2 , charging of the storage battery 20 is performed while the electric vehicle EV is stopped when the traveling distances are D1, D2, and D3.

Generally, it is known that the amount of heat generated in a storage battery increases when the storage battery is charged and discharged, and the amount of heat generated increases particularly during charging. In the example of FIG. 2 as well, when the traveling distances are D1, D2, and D3, the temperature of the storage battery 20 rises relatively significantly due to the heat generated during charging.

When the electric vehicle EV is running (for example, when the running distance is between D1 and D2), the amount of heat generated by the storage battery 20 is relatively small. Therefore, the temperature of the storage battery 20 during running is gradually lowered due to cooling by outside air or the like. Note that FIG. 2 is merely an example, and it is possible that the temperature of the storage battery 20 rises even while the electric vehicle EV is running.

As shown in FIG. 2, the temperature of the storage battery 20 gradually rises as the charging of the storage battery 20 and the running of the electric vehicle EV are repeated. The upper limit value UL shown in the figure is the upper limit value of the temperature range in which the storage battery 20 can operate normally. When the charging of the storage battery 20 is repeated, the temperature of the storage battery 20 eventually exceeds the upper limit value UL, and power cannot be supplied from the storage battery 20 to the motor generator 40. is concerned.

Therefore, in the control device 10 according to the present embodiment, the heat generation of the storage battery 20 is suppressed in advance to lower the temperature during a period before charging of the electric vehicle EV is started. Specifically, the running control unit 122 changes the running state of the electric vehicle EV to a running state that suppresses the heat generation of the storage battery 20, thereby lowering the temperature of the storage battery 20 in advance. .

As a result of such control, charging of the storage battery 20 is started after the temperature of the storage battery 20 has been lowered by the control described above. Therefore, even if charging is repeated as shown in FIG. 2, the temperature of storage battery 20 does not exceed upper limit value UL. In this way, the control for setting the running state of the electric vehicle EV to a running state in which the heat generation of the storage battery 20 is suppressed is hereinafter also referred to as “heat generation suppression control”. Specific aspects of heat generation suppression control will be described later.

A specific flow of processing performed by the control device 10 will be described with reference to FIG. 3 and the like. A series of processes shown in FIG. 3 are processes that are repeatedly executed by the DSS-ECU 120 each time a predetermined control period elapses.

In the first step S01 of the process, the charging determination unit 121 determines whether or not an opportunity to charge the storage battery 20 is imminent. Specific contents of the determination will be described with reference to FIGS. 4 and 5. FIG. The flowcharts shown in FIGS. 4 and 5 respectively show the specific flow of the process performed by the charging determination unit 121 in step S01 of FIG.

In the first step S11 of the process shown in FIG. 4, the traveling distance of the electric vehicle EV is calculated. The “travel distance” referred to here is the expected travel distance that the electric vehicle EV will travel from the current travel position until it reaches the next chargeable location. The “chargeable place” is a place where the electric vehicle EV can stop and charge the storage battery 20, for example, a destination or waypoint where a charging stand is installed. The calculation of the distance traveled in step S11 is performed based on the information on the route input from the navigation system 50. FIG.

In step S12 following step S11, a distance threshold is set. The “distance threshold” is a threshold that is compared with the travel distance calculated in step S11 when the charging determination unit 121 determines whether the opportunity to charge the storage battery 20 is imminent. . If the traveled distance is less than the distance threshold (that is, if the electric vehicle EV will soon reach a place where it can be charged), it is determined that the charging of the storage battery 20 is imminent.

A constant fixed value may be used as the distance threshold set in step S12, but a different distance threshold may be set depending on the situation. The charging determination unit 121 in the present embodiment determines the traveling distance, road gradient, wind speed, wind direction, and the operation of an air conditioner (not shown) mounted on the electric vehicle EV on the route until the electric vehicle EV reaches the chargeable place. A distance threshold is set based on at least one of the conditions.

Specifically, for example, the longer the travel distance calculated when the electric vehicle EV starts traveling, the larger the distance threshold value is set. As a result, cooling (cooling by heat suppression control) of the storage battery 20 that has become hot due to long-distance running can be started early, and the temperature of the storage battery 20 can be sufficiently lowered by the start of charging. In this case, the setting of the distance threshold in step S12 is performed only once when the electric vehicle EV starts running.

Further, when the road on which the electric vehicle EV travels has a steep uphill slope, the distance threshold is set to a larger value than when the road slope is gentle. When the headwind against the electric vehicle EV has a high wind speed, the distance threshold is set to a larger value than when the wind speed is low or when there is a tailwind. When the air conditioner mounted on the electric vehicle EV is operating, the distance threshold is set to a larger value than when the air conditioner is stopped. By setting the distance threshold as described above, the cooling of the storage battery 20, which becomes hot due to a large power load, can be started early, and the temperature of the storage battery 20 can be sufficiently lowered by the start of charging.

In step S13 following step S12, it is determined whether or not the travel distance calculated in step S11 is below the distance threshold set in step S12. If the traveled distance is less than the distance threshold, the process proceeds to step S14. In step S14, it is determined that the opportunity to charge the storage battery 20 is imminent.

In step S13, when the traveled distance is equal to or greater than the distance threshold, the process proceeds to step S15. In step S15, it is determined that the opportunity to charge the storage battery 20 is not imminent.

A series of processes shown in FIG. 5 are processes executed in parallel with a series of processes shown in FIG. The determination in step S01 of FIG. 3 is made in consideration of both the result of the processing shown in FIG. 4 and the result of the processing shown in FIG.

At the first step S21 in the processing of FIG. The amount of stored electricity may be obtained as a "storage rate" (SOC: State of Charge) that takes a value from 0% to 100%.

In step S22 following step S21, a power storage threshold is set. The “storage threshold” is a threshold that is compared with the storage amount calculated in step S21 when the charging determination unit 121 determines whether the opportunity to charge the storage battery 20 is imminent. . When the amount of stored electricity is below the storage threshold (that is, when charging of the storage battery 20 is required soon), it is determined that the opportunity to charge the storage battery 20 is imminent.

As the power storage threshold set in step S22, a fixed value may always be used, but a different power storage threshold may be set depending on the situation. The charging determination unit 121 in the present embodiment sets the power storage threshold based on at least one of the outside air temperature, the temperature of the storage battery 20, and the amount of power stored in the storage battery 20. FIG.

Specifically, for example, the higher the outside air temperature is, the larger the power storage threshold is set. As a result, it is possible to start cooling the storage battery 20 early and sufficiently reduce the temperature of the storage battery 20 by the start of charging in summer or the like when the temperature of the storage battery 20 tends to rise.

Also, the higher the temperature of the storage battery 20 is, the larger the power storage threshold value is set. As a result, the cooling of the storage battery 20 already at a high temperature can be started early, and the temperature of the storage battery 20 can be sufficiently lowered by the start of charging.

Further, the larger the amount of electricity stored in the storage battery 20 obtained when the electric vehicle EV starts running, the larger the value of the electricity storage threshold is set. This makes it possible to start cooling the storage battery 20 when a predetermined amount of power is consumed. In this case, the setting of the power storage threshold in step S22 is performed only once when the electric vehicle EV starts running.

In step S23 following step S22, it is determined whether or not the amount of stored electricity obtained in step S21 is below the threshold value of stored electricity set in step S22. When the amount of stored electricity is less than the stored electricity threshold, the process proceeds to step S24. In step S14, it is determined that the opportunity to charge the storage battery 20 is imminent.

In step S23, when the amount of stored electricity is equal to or greater than the stored electricity threshold, the process proceeds to step S25. In step S25, it is determined that the opportunity to charge the storage battery 20 is not imminent.

Returning to FIG. 3, the description continues. In step S01, when the process of FIG. 4 proceeds to step S14, or when the process of FIG. Finally, the process proceeds to step S02.

Otherwise, that is, when the process proceeds to step S15 in the process of FIG. 4 and when the process proceeds to step S25 in the process of FIG. is finally performed to end the series of processes shown in FIG. In this case, heat generation suppression control is not performed, and the electric vehicle EV runs normally.

If the determination in step S01 is No while the heat generation suppression control is being performed, the heat generation suppression control is interrupted, and the electric vehicle EV is returned to the normal running state.

The determination in step S01 of FIG. 3 may be made based on the processing results of both FIG. 4 and FIG. may be broken.

When the process proceeds from step S01 to step S02, heat generation suppression control is performed by the travel control unit 122 except for some exceptional cases (described later). Heat generation suppression control will be described with reference to FIG. The flowchart shown in FIG. 6 shows a specific flow of processing performed by the travel control unit 122 in step S02 of FIG.

In the first step S31 in the process of FIG. 6, a process of switching to a state in which the generation of regenerative electric power is prohibited or suppressed is performed as one of the heat generation suppression controls. A state in which the generation of regenerative power is prohibited is a state in which the motor generator 40 does not generate regenerative power at all. A state in which the generation of regenerative electric power is suppressed is a state in which the regenerative electric power is generated with a smaller output than normal or for a shorter period of time than normal. After the process of step S31 is performed, power supply from the motor generator 40 to the storage battery 20 is prohibited or restricted, so that heat generation in the storage battery 20 is suppressed.

In step S32 following step S31, as one of heat generation suppression control, a process of switching to a state in which rapid acceleration of the electric vehicle EV is prohibited or suppressed is performed. The state in which rapid acceleration is prohibited is a state in which the acceleration of the electric vehicle EV is prohibited from exceeding a predetermined value. The state in which sudden acceleration is suppressed is a state in which the acceleration of the electric vehicle EV is allowed to exceed the predetermined value only for a short period of time. Since the current output from storage battery 20 to motor generator 40 is suppressed after the process of step S32 is performed, heat generation in storage battery 20 is further suppressed.

In step S33 subsequent to step S32, as one of heat generation suppression control, a process of switching to a state in which high-speed travel of the electric vehicle EV is prohibited or suppressed is performed. The state in which high-speed travel is prohibited is a state in which the running speed of the electric vehicle EV is prohibited from exceeding a predetermined value. The state in which high-speed travel is suppressed is a state in which the travel speed of the electric vehicle EV is permitted to exceed the predetermined value only for a short period of time. After the process of step S33 is performed, the current output from storage battery 20 to motor generator 40 is also suppressed, so heat generation in storage battery 20 is further suppressed.

As described above, the heat suppression control in the present embodiment includes control for prohibiting or suppressing generation of regenerative electric power in the electric vehicle EV (step S31), and control for prohibiting or suppressing rapid acceleration of the electric vehicle EV (step S31). Step S32) and control for prohibiting or suppressing high-speed driving of the electric vehicle EV (step S33) are included. Alternatively, only some of steps S32, S33, and S34 may be executed instead of all of them.

As described above, in the control device 10 according to the present embodiment, when the charge determination unit 121 determines that the charging of the storage battery 20 is imminent, the travel control unit 122 controls the storage battery 20 It is configured to perform heat generation suppression control to bring about a running state in which heat generation is suppressed at. As a result, the temperature of storage battery 20 can be lowered in advance before electric vehicle EV stops and charging of storage battery 20 is started. Since it is not necessary to suppress the charging current during charging in order to prevent the storage battery 20 from becoming hot, charging can be completed in a short time.

As described with reference to FIG. 4 , the charging determination unit 121 determines whether the charging of the storage battery 20 is imminent based on the traveling position of the electric vehicle EV. Specifically, when the distance from the current travel position to the chargeable location is below a predetermined distance threshold, it is determined that the charging of the storage battery 20 is imminent.

When the electric vehicle EV reaches the chargeable place, the storage battery 20 is charged with a high probability. Therefore, according to the above method, it is possible to accurately determine whether or not the opportunity to charge the storage battery 20 is imminent.

As described with reference to FIG. 5 , the charging determination unit 121 determines whether or not the charging of the storage battery 20 is imminent based on the state of the storage battery 20 . Specifically, when the amount of power stored in the storage battery 20 falls below a predetermined power storage threshold, it is determined that the opportunity to charge the storage battery is imminent. When the amount of stored electricity becomes low, the driver is notified of this by lighting an empty lamp, for example, so there is a high possibility that the storage battery 20 will be charged within a short period of time thereafter. Therefore, according to the above method, it is possible to accurately determine whether or not the opportunity to charge the storage battery 20 is imminent.

By the way, if the heat generation suppression control as described above is always performed when the opportunity to charge the storage battery 20 is imminent, a problem may arise. For example, when the generation of regenerative electric power is prohibited or suppressed, the amount of stored electricity for running the electric vehicle EV may become insufficient. In addition, as the rapid acceleration of the electric vehicle EV is prohibited or suppressed, it may become impossible to avoid the risk of collision with another vehicle. For this reason, the running control unit 122 according to the present embodiment suspends part or all of the heat generation suppression control depending on the state of the electric vehicle EV, and restores the normal running state.

Processing performed for this purpose will be described with reference to FIG. In the series of processes shown in FIG. 7, after the heat generation suppression control is started through the process of FIG. The processing is executed by the traveling control unit 122 each time the period elapses. That is, the processing shown in FIG. 7 is performed in parallel with the processing shown in FIG.

In the first step S41 in the process of FIG. 7, the electric vehicle EV is in danger of collision or the like, and avoiding the danger requires heat generation suppression control (specifically, prohibition of rapid acceleration or high-speed driving or suppression) determines whether or not it is difficult. The determination is made based on at least one of the traveling speed and acceleration of other vehicles traveling around the electric vehicle EV and the relative speed with respect to the electric vehicle EV. The traveling speed of the other vehicle and the like are calculated by analyzing the image acquired by the vehicle-mounted camera 60 .

For example, when another vehicle approaches the electric vehicle EV relatively, the travel control unit 122 determines that the electric vehicle EV is in danger. Furthermore, the travel control unit 122 determines that it is difficult to avoid danger when at least one of the travel speed, acceleration, and relative speed of the other vehicle with respect to the electric vehicle EV exceeds a predetermined threshold. judge.

If it is determined that it is difficult to avoid danger, the process proceeds to step S42. In step S42, a process of permitting at least one of rapid acceleration and high-speed running of the electric vehicle EV is performed. The “permitting process” referred to here is a process in which rapid acceleration or the like of the electric vehicle EV is neither prohibited nor suppressed.

As a result, part of the heat generation suppression control (specifically, one or both of the processes performed in steps S32 and S33 of FIG. 6) is temporarily canceled. As a result, the electric vehicle EV is in a state where it can perform rapid acceleration and high-speed running without restriction, so it is possible to avoid imminent danger.

If it is determined in step S41 that there is no danger or that it is not difficult to avoid the danger, the process proceeds to step S43. In step S43, a process of continuing the heat generation suppression control is performed. It should be noted that if the process of step S42 has already been performed and the rapid acceleration or high-speed running of the electric vehicle EV is temporarily permitted, the state in which these are prohibited or suppressed is restored.

As described above, when it is determined that it is difficult for the electric vehicle EV to avoid danger, the travel control unit 122 permits rapid acceleration and high-speed travel of the electric vehicle EV. This prevents a situation in which danger cannot be avoided by heat generation suppression control. Although both rapid acceleration and high-speed running may be permitted as in the present embodiment, only one of them may be permitted depending on the state of the electric vehicle EV.

After the process of step S42 or step S43 is performed, the process proceeds to step S44. In step S44, it is determined whether or not it is difficult for the electric vehicle EV to reach the chargeable location due to the shortage of the amount of stored electricity. For example, after obtaining the required travel distance from the navigation system 50, if the storage battery 20 does not store an amount of electricity equal to or greater than the amount of electricity stored corresponding to the travel distance, the electric vehicle EV is allowed to reach a chargeable location. is judged to be difficult.

When it is determined that it is difficult for the electric vehicle EV to reach the chargeable place, the process proceeds to step S45. In step S45, a process of permitting generation of regenerative power is performed. The “allowing process” referred to here is a process for making the generation of regenerative power neither prohibited nor suppressed.

As a result, part of the heat generation suppression control (specifically, the process performed in step S31 of FIG. 6) is temporarily canceled. As a result, the electric vehicle EV is in a state where it can generate and charge regenerative electric power without restriction, so that it is possible to solve the shortage of the amount of stored electricity and reach the destination.

If it is determined in step S44 that it is not difficult for the electric vehicle EV to reach the chargeable place, the process proceeds to step S46. In step S46, a process of continuing the heat generation suppression control is performed. If the process of step S45 has already been performed and the generation of regenerative electric power is temporarily permitted, the state in which the generation of regenerative electric power is prohibited or suppressed is restored.

As described above, when the amount of electricity stored in the storage battery 20 is insufficient and it is difficult for the electric vehicle EV to reach the chargeable location, the travel control unit 122 causes the electric vehicle EV to generate regenerative electric power. Allow This prevents a situation in which the amount of stored electricity becomes insufficient due to the heat generation suppression control.

An example of change in the torque of the electric vehicle EV due to heat generation suppression control will be described with reference to FIG. 8 . FIG. 8(A) shows an example of the change over time of the required torque corresponding to the driver's driving operation. It should be noted that the fact that the value of the required torque is negative means that the generation of regenerative electric power is requested.

FIG. 8(B) shows an example of temporal change in torque actually output from motor generator 40 (that is, actual torque). This change in actual torque over time is basically controlled to have the same value as the actual torque shown in FIG. . It should be noted that the fact that the value of the actual torque is negative means that regenerative electric power is being generated.

FIG. 8C shows an example of transition of the determination result in step S01 of FIG. In FIG. 8C, the determination result that the opportunity to charge the storage battery 20 is imminent is indicated as "ON", and it is determined that the opportunity to charge the storage battery 20 is not imminent. Results are shown as "OFF".

FIG. 8D shows an example of transition of the determination result in step S41 of FIG. In FIG. 8D, the determination result that it is difficult to avoid the danger is indicated as "ON", and the determination result that it is not difficult to avoid the danger is indicated as "OFF". ing.

FIG. 8(E) shows an example of transition of the determination result in step S44 of FIG. In FIG. 8E, the determination result indicating that it is difficult for the electric vehicle EV to reach the chargeable location is indicated as "ON", and it is not difficult for the electric vehicle EV to reach the chargeable location. The determination result that there is not is indicated as "OFF".

In the example of FIG. 8, the period from time t0 to time t20 is the period during which the electric vehicle EV is running. Time t20 is the time when electric vehicle EV reaches a chargeable location and charging of storage battery 20 is started.

During the period from time t0 to time t20, the required torque changes substantially sinusoidally (Fig. 8(A)). In accordance with this, the actual torque also changes in a substantially similar sinusoidal shape for a while from time t0 (FIG. 8(B)). A dotted line DL1 shown in FIG. 8(B) indicates the same waveform as the required torque shown in FIG. 8(A).

After time t10, it is determined that the opportunity to charge the storage battery 20 is imminent (Fig. 8(C)). Along with this, heat generation suppression control is started at time t10, and after that, rapid acceleration and high-speed running are prohibited. As a result, the actual torque during the period from time t10 to time t20 is suppressed to a value smaller than the required torque except for a part of the period.

After time t10, it is determined that it is difficult to avoid danger during the period from time t11 to time t12 (FIG. 8(D)). Therefore, part of the heat generation suppression control is canceled during this period, and rapid acceleration and high-speed running are permitted. As a result, the actual torque (FIG. 8(B)) in this period again matches the required torque (FIG. 8(A)). After time t12, the heat generation suppression control is restored, so that the actual torque is again suppressed to a value smaller than the required torque (FIG. 8(B)).

After a while from time t12, the value of the required torque becomes negative (Fig. 8(A)). However, since heat generation suppression control is being performed at this time, the actual torque after the value of the required torque becomes negative is 0 (FIG. 8(B)). During the period from time t13 to time t14 in which the value of the required torque is negative, it is determined that it is difficult for the electric vehicle EV to reach the chargeable location (see FIG. 8). (E)). For this reason, part of the heat generation suppression control is canceled during this period, and the generation of regenerative power is permitted. As a result, the actual torque (FIG. 8(B)) in this period again matches the required torque (FIG. 8(A)). After time t14, the heat generation suppression control is restored, and the actual torque is set to 0 again (FIG. 8(B)).

A second embodiment will be described with reference to FIG. This embodiment differs from the first embodiment in the content of the processing performed for the determination in step S01 of FIG. Other points are the same as in the first embodiment.

The flowchart shown in FIG. 9 shows a specific flow of processing performed by the charging determination unit 121 in step S01 of FIG. That is, the processing shown in FIG. 9 is executed in place of the processing shown in FIGS. 4 and 5. FIG.

In the first step S51 of the processing shown in FIG. 9, it is determined whether or not the output of the electric vehicle EV is decreasing. When the amount of electricity stored in the storage battery 20 decreases and the power output from the storage battery 20 decreases, the driving force of the motor generator 40 (driving force of the electric vehicle EV) decreases and the maximum output as specified cannot be obtained. In such a state, it is determined in step S51 that the output of the electric vehicle EV has decreased, and the process proceeds to step S52. In step S52, it is determined that the opportunity to charge the storage battery 20 is imminent. In this case, the process shifts from step S01 to step S02 in FIG.

If it is not determined in step S51 that the output of the electric vehicle EV has decreased, that is, if the motor generator 40 can output the maximum output as specified, the process proceeds to step S53. In step S53, it is determined that the opportunity to charge the storage battery 20 is not imminent. In this case, after step S01 in FIG. 3, the series of processes shown in the figure ends. The heat generation suppression control is not performed (or interrupted), and the electric vehicle EV runs normally.

As described above, the charge determining unit 121 according to the present embodiment determines that when the driving force of the electric vehicle EV is reduced due to the decrease in the output of the storage battery 20, the opportunity to charge the storage battery 20 is imminent. I judge.

A driver who feels that the behavior of the electric vehicle EV has changed (for example, acceleration has deteriorated) is highly likely to start charging the storage battery 20 within a short period of time thereafter. Therefore, according to the above method, it is possible to more accurately determine whether or not the opportunity to charge the storage battery 20 is imminent. Even in such a mode, the same effects as those described in the first embodiment can be obtained.

The present embodiment has been described above with reference to specific examples. However, the present disclosure is not limited to these specific examples. Design modifications to these specific examples by those skilled in the art are also included in the scope of the present disclosure as long as they have the features of the present disclosure. Each element included in each specific example described above and its arrangement, conditions, shape, etc. are not limited to those illustrated and can be changed as appropriate. As long as there is no technical contradiction, the combination of the elements included in the specific examples described above can be changed as appropriate.

10: Control Device 20: Storage Battery 121: Charge Determination Unit 122: Driving Control Unit EV: Electric Vehicle

Claims (10)

A control device (10) for an electric vehicle (EV),
a charge determination unit (121) that determines whether or not an opportunity for charging a storage battery (20) mounted on the electric vehicle is imminent;
A running control unit (122) that controls the running state of the electric vehicle,
When the charging determination unit determines that the opportunity to charge the storage battery is imminent,
The running control unit performs heat generation suppression control to set the running state such that heat generation in the storage battery is suppressed,
The charging determination unit determines whether an opportunity for charging the storage battery is imminent based on the traveling position of the electric vehicle,
The charging determination unit determines that an opportunity for charging the storage battery is imminent when the distance from the travel position to the chargeable location is less than a predetermined distance threshold,
The charge determination unit determines at least one of a traveling distance, a road gradient, a wind speed, a wind direction, and an operating condition of an air conditioner mounted on the electric vehicle on a route until the electric vehicle reaches the chargeable place. a controller for setting the distance threshold based on A control device (10) for an electric vehicle (EV),
a charge determination unit (121) that determines whether or not an opportunity for charging a storage battery (20) mounted on the electric vehicle is imminent;
A running control unit (122) that controls the running state of the electric vehicle,
When the charging determination unit determines that the opportunity to charge the storage battery is imminent,
The running control unit performs heat generation suppression control to set the running state such that heat generation in the storage battery is suppressed,
The charging determination unit determines whether an opportunity to charge the storage battery is imminent based on the state of the storage battery ,
The charge determination unit determines that the storage battery will soon be charged when the driving force of the electric vehicle decreases as the output of the storage battery decreases . A control device (10) for an electric vehicle (EV),
a charge determination unit (121) that determines whether or not an opportunity for charging a storage battery (20) mounted on the electric vehicle is imminent;
A running control unit (122) that controls the running state of the electric vehicle,
When the charging determination unit determines that the opportunity to charge the storage battery is imminent,
The running control unit performs heat generation suppression control to set the running state such that heat generation in the storage battery is suppressed,
The charging determination unit determines whether an opportunity to charge the storage battery is imminent based on the state of the storage battery,
The charging determination unit determines that an opportunity to charge the storage battery is imminent when the amount of electricity stored in the storage battery is below a predetermined storage threshold , and
The charge determination unit is a control device that sets the power storage threshold value based on at least one of an outside air temperature, a temperature of the storage battery, and a power storage amount of the power storage amount . The heat generation suppression control includes:
4. The control device according to any one of claims 1 to 3 , including control for prohibiting or suppressing generation of regenerative electric power in said electric vehicle. The heat generation suppression control includes:
4. The control device according to any one of claims 1 to 3 , including control for prohibiting or suppressing rapid acceleration of the electric vehicle. The heat generation suppression control includes:
4. The control device according to any one of claims 1 to 3 , including control for prohibiting or suppressing high-speed travel of the electric vehicle. A control device (10) for an electric vehicle (EV),
a charge determination unit (121) that determines whether or not an opportunity for charging a storage battery (20) mounted on the electric vehicle is imminent;
A running control unit (122) that controls the running state of the electric vehicle,
When the charging determination unit determines that the opportunity to charge the storage battery is imminent,
The running control unit performs heat generation suppression control to set the running state such that heat generation in the storage battery is suppressed,
The heat generation suppression control includes:
including control to prohibit or suppress generation of regenerative power in the electric vehicle;
When the amount of electricity stored in the storage battery is insufficient and it is difficult for the electric vehicle to reach a chargeable location, the travel control unit permits the electric vehicle to generate regenerative electric power. controller . A control device (10) for an electric vehicle (EV),
a charge determination unit (121) that determines whether or not an opportunity for charging a storage battery (20) mounted on the electric vehicle is imminent;
A running control unit (122) that controls the running state of the electric vehicle,
When the charging determination unit determines that the opportunity to charge the storage battery is imminent,
The running control unit performs heat generation suppression control to set the running state such that heat generation in the storage battery is suppressed,
The heat generation suppression control includes:
including control to prohibit or suppress rapid acceleration of the electric vehicle;
The control device, wherein the travel control unit permits rapid acceleration of the electric vehicle when it is determined that it is difficult for the electric vehicle to avoid danger. A control device (10) for an electric vehicle (EV),
a charge determination unit (121) that determines whether or not an opportunity for charging a storage battery (20) mounted on the electric vehicle is imminent;
A running control unit (122) that controls the running state of the electric vehicle,
When the charging determination unit determines that the opportunity to charge the storage battery is imminent,
The running control unit performs heat generation suppression control to set the running state such that heat generation in the storage battery is suppressed,
The heat generation suppression control includes:
including control to prohibit or suppress high-speed driving of the electric vehicle,
The control device, wherein the travel control unit permits the electric vehicle to travel at high speed when it is determined that it is difficult for the electric vehicle to avoid danger. Determining whether it is difficult for the electric vehicle to avoid danger is based on at least one of a traveling speed, an acceleration, and a relative speed to the electric vehicle of another vehicle traveling around the electric vehicle. 10. A controller according to claim 8 or 9 , wherein

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