JP7040367B2 - Power control unit - Google Patents

Description

The present disclosure relates to a technique for supplying electric power to an electric load using a plurality of storage batteries.

Patent Document 1 proposes a technique of using a plurality of storage batteries in a power supply device mounted on a vehicle and supplying electric power to an electric load mounted on the vehicle while using each of these storage batteries properly.

Japanese Patent No. 5488169

The power supply device described in Patent Document 1 includes two storage batteries. In the above power supply device, each storage battery is connected in parallel. Further, each of the storage batteries and the electric load are connected in series, and switches are provided in each of the connection paths, so that these two switches are appropriately short-circuited or opened.

When switching the storage battery that supplies power to the electric load from one of the two storage batteries to the other storage battery, it is desirable that the supply of power to the electric load is not interrupted (hereinafter, also referred to as power supply shortage). .. For example, in a power supply device as described in Patent Document 1, it is considered that power supply loss can be suppressed by switching after the two switches are short-circuited together.

However, in a state where both of the above two switches are short-circuited, there is a possibility that a failure may occur in each switch due to a temperature rise due to an increase in current consumption, and a power supply defect may occur in an electric load due to a switch failure.

One aspect of the present disclosure is to provide a technique capable of suppressing the occurrence of a power supply defect in an electric load when power is supplied to the electric load by using a plurality of storage batteries.

One aspect of the present disclosure is a power supply control device (10) capable of driving an electric load by a plurality of storage batteries. The plurality of storage batteries include a first storage battery (51) and a second storage battery (52). The power supply control device includes a temperature acquisition unit (S10), a switching determination unit (S20), a temperature determination unit (S30, S35), and a storage battery switching unit (S40-S80).

The temperature acquisition unit is a switch that can be switched to either short-circuit or open according to an instruction signal from the power supply control device, and is a first connection switch that short-circuits or opens between the first storage battery and the electric load, a second storage battery, and the like. Acquire the temperature of each of the second connection switches that short-circuit or open between the electrical loads.

The switching determination unit is driving a drive battery, which is a storage battery for driving an electric load, and is not driving an electric load from one of the first storage battery and the second storage battery, which is a storage battery driving the electric load. It is determined whether or not there is a switching request for switching to the other storage battery of the first storage battery and the second storage battery, which is a storage battery. The temperature determination unit determines whether or not the temperature of each of the first connection switch and the second connection switch satisfies a predetermined temperature condition.

When it is determined that there is a switching request and the temperature condition is satisfied, the storage battery switching unit is predetermined with at least an instruction signal, which is a superimposed signal for short-circuiting the first connection switch and short-circuiting the second connection switch. The superimposition period is output, and the switching signal is output after the superimposition signal is output. The storage battery switching unit does not output the superimposed signal and the switching signal when it is determined that the switching request is made and the temperature condition is not satisfied.

The switching signal is an instruction signal, which is a signal for opening between one storage battery and the electric load and short-circuiting between the other storage battery and the electric load.
As described above, the power supply control device outputs a switching signal after outputting a superposed signal when there is a switching request. As a result, when power is supplied to the electric load using a plurality of storage batteries, it is possible to suppress the occurrence of power supply defects in the electric load.

Further, when there is a switching request, the power supply control device switches only when the temperature of the first connection switch and the temperature of the second connection switch satisfy the temperature condition. That is, if the temperature condition is not satisfied, the superimposed signal for switching is not output. For example, by appropriately setting temperature conditions such as the temperature of the first connection switch and the temperature of the second connection switch being less than a predetermined temperature, the first connection switch and the second connection switch fail due to the temperature rise. Is suppressed.

As a result, when power is supplied to the electric load using a plurality of storage batteries, it is possible to suppress the occurrence of power supply defects in the electric load.
In addition, the reference numerals in parentheses described in this column and the scope of claims indicate the correspondence with the specific means described in the embodiment described later as one embodiment, and the technical scope of the present disclosure is defined. It is not limited.

The block diagram which shows the structure of the vehicle power supply system of 1st Embodiment. The flowchart of the switching process of 1st Embodiment. Explanatory drawing explaining the temperature condition of 1st Embodiment. Flowchart of overlap time processing. A timing chart illustrating the operation of the vehicle power supply system of the first embodiment. Explanatory drawing explaining the state of the vehicle power supply system at time t2. Explanatory drawing explaining the overlap state after time t2. Explanatory drawing explaining the state of the vehicle power supply system at time t3. Explanatory drawing explaining the overlap state after time t6. Explanatory drawing explaining the state of the vehicle power supply system at time t7. Explanatory drawing explaining the temperature condition of the modification 1. FIG. The flowchart of the switching process of the modification 1. The figure explaining the connection state in the vehicle power supply system at the time of deceleration operation of the modification 2. FIG. The block diagram which shows the structure of the vehicle power supply system of 2nd Embodiment. The flowchart of the switching process of 2nd Embodiment. A timing chart illustrating the operation of the vehicle power supply system of the second embodiment. Explanatory drawing explaining the state of the vehicle power supply system at time t11. Explanatory drawing explaining the state of the vehicle power supply system at time t13. Explanatory drawing explaining the overlap state after time t15. Explanatory drawing explaining the state of the vehicle power supply system at time t16.

Hereinafter, embodiments of the present disclosure will be described with reference to the drawings.
[1. First Embodiment]
[1-1. Constitution]
[1-1-1. overall structure]
The vehicle power supply system 1 shown in FIG. 1 is a system mounted on a vehicle. The vehicle referred to here travels with an internal combustion engine (hereinafter referred to as an engine) as a drive source.

The vehicle power supply system 1 includes an alternator 41, a starter 33, an in-vehicle electrical component, a first load 31 and a second load 32, a plurality of storage batteries, a first switch 21 (hereinafter referred to as a first switch), and a first switch. A two-connection switch (hereinafter, second switch) 22 and an electronic control device (hereinafter, ECU) 10 are provided. The plurality of storage batteries include a lead storage battery 51 and a lithium storage battery 52.

The starter 33, the first load 31, the second load 32, the lead storage battery 51, and the lithium storage battery 52 are connected in parallel to the alternator 41. The first switch 21 is arranged between the lead storage battery 51 and the second load 32, and the second switch 22 is arranged between the lithium storage battery 52 and the second load 32.

The first switch 21 and the second switch 22 are switches that can be switched to either short circuit or open according to an instruction signal from the ECU 10, respectively. The first switch 21 short-circuits or opens between the lead-acid battery 51 and the second load 32. The second switch 22 short-circuits or opens between the lithium storage battery 52 and the second load 32.

Although not shown, each of the first switch 21 and the second switch 22 is provided with a temperature sensor for measuring the temperature. Each temperature sensor outputs a signal representing the temperature of the first switch 21 and a signal representing the temperature of the second switch 22 to the ECU 10.

The starter 33, the first load 31, and the second load 32 are electrical loads. The starter 33 is a motor for starting the engine. The first load 31 and the second load 32 are in-vehicle electrical components.

The first load 31 is a general electrical load other than the starter 33 and the second load 32 described later. Specifically, the first load 31 may include a headlight, a wiper such as a front windshield, a fan of an air conditioner, a heater for a defroster of the rear windshield, and the like. Further, the first load 31 may include a drive mechanism such as a power steering and a power window.

The second load 32 is an electric load that requires that the voltage of the supplied power is substantially constant or that the voltage fluctuation is within a predetermined range and is stable. The lead storage battery 51 can be connected to the second load 32 via the first switch 21, and the lithium storage battery 52 can be connected to the second load 32 via the second switch 22. Specifically, the second load 32 may include an in-vehicle navigation device, an in-vehicle audio device, and the like.

The alternator 41 generates electricity by the rotational energy of the crank shaft. The electric power generated by the alternator 41 can be supplied to the starter 33, the first load 31, the second load 32, the lead storage battery 51, and the lithium storage battery 52.

Here, the alternator 41 and the lead storage battery 51 are located on the lead storage battery 51 side of the first switch 21, as shown in FIG. That is, the alternator 41 is a charging device that charges at least the lead-acid battery 51 regardless of whether the first switch 21 and the second switch 22 are open or short-circuited. On the other hand, the lithium storage battery 52 is located on the lithium storage battery 52 side of the first switch 21 and the second switch 22 with respect to the alternator 41. That is, the alternator 41 is a charging device that charges the lithium storage battery 52 only when the first switch 21 and the second switch 22 are short-circuited.

When the engine is stopped and the alternator 41 is not generating power, electric power may be supplied to the starter 33, the first load 31, and the second load 32 from at least one of the lead storage battery 51 and the lithium storage battery 52.

Here, the lead-acid battery 51 supplies electric power to the starter 33 and the first load 31 regardless of whether the first switch 21 and the second switch 22 are open or short-circuited. Further, the lead storage battery 51 supplies electric power to the second load 32 when at least the first switch 21 is short-circuited.

On the other hand, the lithium storage battery 52 supplies electric power to the second load 32 when at least the second switch 22 is short-circuited. Further, the lithium storage battery 52 supplies electric power to the first load 31 and the second load 32 when both the first switch 21 and the second switch 22 are short-circuited.

When the first switch 21 is short-circuited and the second switch 22 is short-circuited, the storage battery having the higher output voltage among the lead storage battery 51 and the lithium storage battery 52 has a lower output voltage among the lead storage battery 51 and the lithium storage battery 52. Power can be supplied in the direction toward the storage battery.

The lead storage battery 51 is a general-purpose storage battery. The storage capacity of the lead storage battery 51 is set to be larger than that of the lithium storage battery 52. In the present embodiment, the output voltage when the lead storage battery 51 is fully charged is set higher than the output voltage when the lithium storage battery 52 is fully charged.

The lithium storage battery 52 is a high-density storage battery having a smaller power loss during charging and discharging, and a higher output density and energy density than the lead storage battery 51. In the lithium storage battery 52, a plurality of battery cells (not shown) are connected in series.

The ECU 10 includes a microcomputer having a CPU 11 and a semiconductor memory (hereinafter, memory 12) such as RAM or ROM. Each function of the ECU 10 is realized by the CPU 11 executing a program stored in the memory 12. When this program is executed, the method corresponding to the program is executed. The ECU 10 may be provided with one microcomputer or may be provided with a plurality of microcomputers.

The method for realizing each function of the ECU 10 is not limited to software, and some or all of the functions may be realized by using one or a plurality of hardware. For example, when the above function is realized by an electronic circuit which is hardware, the electronic circuit may be realized by a digital circuit, an analog circuit, or a combination thereof.

The ECU 10 realizes at least control that enables the second load 32 to be driven by a plurality of storage batteries such as the lead storage battery 51 and the lithium storage battery 52 by executing a switching process described later.

[1-1-2. Power supply to the second load]
In the vehicle power supply system 1, electric power is supplied to the second load 32 by appropriately short-circuiting or opening the first switch 21 and the second switch 22 according to the situation of the vehicle.

For example, it is assumed that only the second switch 22 is short-circuited and the storage battery for driving the second load 32 is the lithium storage battery 52. At this time, when the output voltage or the storage capacity of the lithium storage battery 52 decreases, the second switch 22 is opened and the first switch 21 is short-circuited, so that the lead storage battery 51 becomes a storage battery in which the second load 32 is being driven. , The lithium storage battery 52 becomes a storage battery in which the second load 32 is not being driven.

Here, "driving" means driving an electric load, that is, supplying electric power to the electric load. On the other hand, "non-driving" means that the electric load is not driven, that is, the electric load is not supplied with electric power. The drive battery referred to below means a storage battery that drives a second load 32, which is an electric load.

As described above, the drive battery can be switched from the lithium storage battery 52 to the lead storage battery 51 by opening the second switch 22 and short-circuiting the first switch 21, but it was instantaneous depending on the switching timing. Even so, there is a risk that the power supply to the second load 32 will be defective. A similar problem may occur when the drive battery is switched from the lead storage battery 51 to the lithium storage battery 52.

Therefore, in order to suppress power failure, it is conceivable to switch after passing through a state in which power is supplied to the second load 32 by two storage batteries such as a lead storage battery 51 and a lithium storage battery 52. That is, it is conceivable to switch after passing through the overlap state. The overlapping state means a state in which both the first switch 21 and the second switch 22 are short-circuited. In addition, the overlap time described below means the time in the overlap state.

However, in the overlapped state, the current consumption in the first switch 21 and the second switch 22 increases as compared with the case where only one of the first switch 21 and the second switch 22 is short-circuited.

This is because when the output voltage of the lead storage battery 51 is higher than that of the lithium storage battery 52, the internal resistance of the lithium storage battery 52 increases as an electrical load in addition to the second load 32 when viewed from the lead storage battery 51. If the output voltage of the lithium storage battery 52 is higher than that of the lead storage battery 51, the first load 31, the internal resistance of the lead storage battery 51, and the starter 33 are electrically in addition to the second load 32 when viewed from the lithium storage battery 52. This is because it increases as a heavy load.

Therefore, in the first switch 21 and the second switch 22, the temperature rises, and there is a concern that a failure may occur due to the temperature rise. The failure may be either an open failure or a short circuit failure. In any failure, a power supply defect may occur in the second load 32. The ECU 10 executes the switching process described below in order to switch the drive battery while suppressing such a power failure.

[1-2. process]
[1-2-1. Switching process]
Next, the switching process executed by the ECU 10 will be described with reference to the flowchart of FIG. The switching process is a process for driving the second load 32 by using a plurality of storage batteries such as the lead storage battery 51 and the lithium storage battery 52. The switching process is repeatedly executed in a predetermined switching cycle. The switching cycle may be, for example, about several msec to several hundred msec.

In S10, the ECU 10 acquires the temperature T _SW1 of the first switch 21 and the temperature T _SW2 of the second switch 22, respectively. In addition, the overlap time stored in the memory 12 is acquired. The overlap time is the time when both the first switch 21 and the second switch 22 are short-circuited. The overlap time is counted by an overlap time process, which will be described later, which is a process different from the main switching process, which is executed by the ECU 10. The initial value of the overlap time is 0.

In S20, the ECU 10 determines whether or not there is a switching request. The switching request is a storage battery in which the drive battery is being driven by the second load 32, and the storage battery in which the second load 32 is not being driven from one of the lead storage battery 51 and the lithium storage battery 52. It is a request for switching to the other storage battery of the lead storage battery 51 and the lithium storage battery 52, and is a request for the ECU 10.

In the present embodiment, the ECU 10 is configured to determine whether or not a predetermined switching condition is satisfied, and if it is determined that the switching condition is satisfied, it is determined that there is a switching request. .. When the ECU 10 determines that the switching condition is satisfied, the process shifts to S30, and when it is determined that the switching condition is not satisfied, the ECU 10 ends the switching process.

The switching condition is that the drive battery is a storage battery that is driving the second load 32 and is a storage battery that is not driving an electric load from one of the lithium storage battery 52 and the lithium storage battery 52 and is a lead storage battery. This is a condition for switching to the other storage battery of the 51 and the lithium storage battery 52.

Here, the ECU 10 determines whether or not the switching condition for switching the drive battery from the lithium storage battery 52, which is one storage battery, to the lead storage battery 51, which is the other storage battery, is satisfied. You may.

The switching condition referred to here is the lithium storage battery 52 when only the second switch 22 of the first switch 21 and the second switch 22 is short-circuited and power is supplied to the second load 32 by the lithium storage battery 52. It may include that the output voltage or SOC of the above has changed from within the predetermined appropriate range to outside the appropriate range. SOC is an abbreviation for State of charge and represents the ratio of the actual charge amount to the charge amount at the time of full charge.

Specifically, in the present embodiment, the ECU 10 acquires the output voltage of the lithium storage battery 52. Then, the ECU 10 switches when the output voltage of the lithium storage battery 52 changes from a voltage threshold value equal to or higher than a predetermined voltage value to less than the voltage threshold value, and the drive battery has not been switched since the change. Judge that the conditions are met.

The voltage threshold value (hereinafter, also referred to as an out-of-range threshold value) is stored in the memory 12 in advance. The term that the drive battery is not switched here means that the lithium storage battery 52, which is one of the storage batteries, and the second switch 22 that connects the second load 32 are still short-circuited, that is, they are not open. say.

The ECU 10 calculates the SOC of the lithium storage battery 52, and the SOC of the lithium storage battery 52 changes from the ratio threshold value or more, which is a predetermined ratio, to less than the ratio threshold value, and after the change, the drive battery is switched. If not, it may be determined that the switching condition is satisfied. The ratio threshold value may be stored in the memory 12 in advance.

On the other hand, the ECU 10 determines whether or not the switching condition for switching the drive battery from the lead storage battery 51, which is one storage battery, to the lithium storage battery 52, which is the other storage battery, is satisfied. May be good.

The switching condition referred to here is the lithium storage battery 52 when only the first switch 21 of the first switch 21 and the second switch 22 is short-circuited and power is supplied to the second load 32 by the lead storage battery 51. It may include that the output voltage or SOC of the above has changed from outside the predetermined appropriate range to within the appropriate range.

Specifically, in the present embodiment, the ECU 10 acquires the output voltage of the lithium storage battery 52. Then, the ECU 10 switches when the output voltage of the lithium storage battery 52 changes from less than the voltage threshold value, which is a predetermined voltage value, to the voltage threshold value or more, and the drive battery has not been switched since the change. Judge that the conditions are met.

The voltage threshold value (hereinafter, also referred to as an in-range threshold value) is stored in the memory 12 in advance. The in-range threshold value may be the same value as the out-of-range threshold value, which is the voltage threshold value in the above switching conditions for switching the drive battery from the lithium storage battery 52 to the lead storage battery 51, or may be a different value. The case where the drive battery is not switched here means that the first switch 21 connecting between the lead storage battery 51 and the second load 32, which are one storage battery, is still short-circuited, that is, when it is not open. say.

The ECU 10 calculates the SOC of the lithium storage battery 52, changes the SOC of the lithium storage battery 52 from less than the ratio threshold, which is a predetermined ratio, to more than the ratio threshold, and switches the drive battery after the change. If not, it may be determined that the switching condition is satisfied.

Further, the ECU 10 may determine whether or not the switching condition is satisfied in the main switching process, or may perform the determination in a process different from the main switching process. Further, the ECU 10 may acquire the determination result of whether or not the switching condition is satisfied from another ECU mounted on the vehicle.

In S30, the ECU 10 determines whether or not the temperatures T _SW1 and T _SW2 of the first switch 21 and the second switch 22 satisfy the temperature conditions, respectively. The temperature condition referred to here is a condition that the temperature T _SW1 of the first switch 21 is less than a predetermined temperature threshold value and the temperature T _SW2 of the second switch 22 is less than the temperature threshold value.

The ECU 10 shifts the process to S40 when the temperature condition is satisfied, and shifts the process to S70 when the temperature condition is not satisfied.
In the present embodiment, the temperature threshold value is a predetermined value, is set to the same value for each of the first switch 21 and the second switch 22, and is stored in the memory 12 in advance. However, the temperature threshold value may be set to a different value for each of the first switch 21 and the second switch 22.

As shown in FIG. 3, the temperature threshold SW _TH sets the maximum value H _M of the amount of temperature change that may increase due to a short circuit of both the first switch 21 and the second switch 22 to the first switch 21 or the first switch 22. It is a value subtracted from the allowable maximum temperature SW _M of the second switch 22. The temperature threshold SW _TH can be set by an experiment or the like based on the time when both the first switch 21 and the second switch 22 are short-circuited, the current consumption, and the like.

In S40, the ECU 10 determines whether or not it is in an overlapping state. Here, the ECU 10 shifts the process to S70 if it is already in the overlap state, and shifts the process to S50 if it is not in the overlap state.

In S50, the ECU 10 puts the first switch 21 and the second switch 22 in an overlapping state. Specifically, the ECU 10 outputs an overlap signal to each of the first switch 21 and the second switch 22. The overlap signal is an instruction signal, which is a signal for short-circuiting the first switch 21 and short-circuiting the second switch 22.

As a result, the lead storage battery 51 and the second load 32 are short-circuited, and the lithium storage battery 52 and the second load 32 are short-circuited.
The ECU 10 sets the count request flag in the subsequent S60. The count request flag is a flag that is set while counting the overlap time. The count request flag is reset when the overlap time count is no longer needed, that is, when the overlap time needs to be cleared. Clearing the overlap time means resetting the overlap time to 0. While the count request flag is set, the overlap time continues to be counted in the overlap time process described later.

In S70, the ECU 10 determines whether or not an overlap time of a predetermined length has elapsed. Specifically, when the overlap time is equal to or longer than the predetermined duration threshold value, the ECU 10 determines that the overlap time of the predetermined length has elapsed. The duration threshold can be set, for example, from a few msec to a few hundred msec.

The duration threshold value can be set to such a time that the first switch 21 and the second switch 22 do not fail due to the temperature rise even if the first switch 21 and the second switch 22 are continuously short-circuited by experiments and calculations based on power consumption. The duration threshold is stored in the memory 12 in advance.

The ECU 10 shifts the process to S80 when the overlap time is equal to or longer than the duration threshold value, and ends the switching process when the overlap time is less than the duration threshold value.
The ECU 10 switches the drive battery in S80. That is, the drive battery, which is the storage battery for driving the second load 32, is the storage battery in which the second load 32 is being driven in the state before the overlap, from one of the lithium storage battery 52 and the lithium storage battery 52. , The storage battery in which the electric load is not driven in the state before the overlap is switched to the other storage battery of the lead storage battery 51 and the lithium storage battery 52.

Here, the ECU 10 opens between the lithium storage battery 52 and the second load 32 when the switching condition for switching the drive battery from the lithium storage battery 52 to the lead storage battery 51 is satisfied in the above-mentioned S20, and the lead storage battery 51. And a switching signal for short-circuiting the second load 32 are output.

On the other hand, when the switching condition for switching the drive battery from the lead storage battery 51 to the lithium storage battery 52 is satisfied in the above-mentioned S20, the ECU 10 opens the lead storage battery 51 and the second load 32, and opens the lithium storage battery 52 and the lithium storage battery 52. A switching signal for short-circuiting between the second loads 32 is output.

The ECU 10 resets the count request flag in the subsequent S90. As a result, the overlap time is cleared by the overlap time processing described later.
With the above, the ECU 10 ends the switching process.

[1-2-2. Overlap time processing]
The overlap time processing will be described with reference to the flowchart shown in FIG. The ECU 10 executes the overlap time processing at a predetermined execution cycle. The execution cycle may be, for example, about several msec to several tens of msec.

The ECU 10 determines in S110 whether or not the overlap time is required to be counted. Specifically, the ECU 10 determines that counting is required when the above-mentioned count request flag is set. Here, when counting is required, the ECU 10 shifts the processing to S120, counts up the overlap time, and ends the overlap time processing. On the other hand, when the counting is not required, the ECU 10 clears the overlap time and ends the overlap time process. Clearing the overlap time means setting the overlap time to 0.

[1-2-3. Operation]
The operation of the vehicle power supply system 1 will be described with reference to the time chart shown in FIG. 5 and FIGS. 6-10. In the present embodiment, the output voltage of the lead storage battery 51 is set to 12V when fully charged, and the output voltage of the lithium storage battery 52 is set to about 12V when fully charged. As described above, the output voltage of the lead-acid battery 51 when fully charged is larger than the output voltage of the lithium storage battery 52 when fully charged.

Further, in the present embodiment, in the switching condition for switching the drive battery from the lithium storage battery 52 to the lead storage battery 51, the out-of-range threshold value, which is the voltage threshold value in the switching condition, is set to 11V. Further, in the switching condition for switching the drive battery from the lead storage battery 51 to the lithium storage battery 52, the threshold within the range, which is the voltage threshold in the switching condition, is set to 11.5V. The output voltage and the voltage threshold value are not limited to these, and may be set to arbitrary values.

At time t1, the first switch 21 is open and the second switch 22 is short-circuited. That is, the lithium storage battery 52 is a drive battery. After time t1, the output voltage of the lithium storage battery 52 decreases with the passage of time.

At time t2, as shown in FIG. 6, the output voltage of the lithium storage battery 52 is less than 11V. That is, the output voltage of the lithium storage battery 52 changes from the voltage threshold value or more to the voltage threshold value, and the switching condition for switching the drive battery from the lithium storage battery 52 to the lead storage battery 51 is satisfied. Subsequently, the ECU 10 determines whether or not the temperature condition is satisfied. Here, the ECU 10 specifies that the temperature T _SW1 of the first switch 21 and the temperature T _SW2 of the second switch 22 are each less than the temperature threshold SW _TH .

Therefore, as shown in FIG. 7, the ECU 10 first outputs an instruction signal that puts the first switch 21 and the second switch 22 in an overlapping state. As a result, the lithium storage battery 52 is charged by the lead storage battery 51. Since the lithium storage battery 52 is a storage battery having high charging efficiency, the remaining capacity can be increased and the output voltage can be increased with the passage of time by charging with the lead storage battery 51.

The time t3 represents a time point when the duration threshold value has elapsed from the time t2. At time t3, as shown in FIG. 8, the ECU 10 subsequently opens the lithium storage battery 52 and the second load 32 between the lead storage battery 51 and the second load 32 to the first switch 21 and the second switch 22. The switching signal, which short-circuits, is output. In this way, the drive battery is switched from the lithium storage battery 52 to the lead storage battery 51.

At time t3, the output voltage V _Li of the lithium storage battery 52 is 11.5 V, which is increased from less than the voltage threshold to more than the voltage threshold. That is, after time t3, the switching condition for switching the drive battery from the lead storage battery 51 to the lithium storage battery 52 is satisfied. However, the temperature T _SW1 of the first switch 21 and the temperature T _SW2 of the second switch 22 are each equal to or higher than the temperature threshold value SW _TH , and the temperature condition is not satisfied. Therefore, the ECU 10 does not switch the drive battery.

Even at the following time t4, the temperature condition is not satisfied. Therefore, the ECU 10 does not switch the drive battery. Assuming that the first switch 21 and the second switch 22 are in an overlapping state in order to switch the drive battery at the time t4, as shown by the dotted line in the figure, the time when the duration threshold has elapsed from the time t4. At t5, the temperature T _SW1 of the first switch 21 and the temperature T _SW2 of the second switch 22 may exceed the allowable maximum temperature SW _M.

At time t6, the temperature T _SW1 of the first switch 21 is less than the temperature threshold SW _TH , and the temperature T _SW2 of the second switch 22 is less than the temperature threshold SW _TH , so that the temperature condition is satisfied. That is, the switching condition for switching the drive battery from the lithium storage battery 52 to the lead storage battery 51 is satisfied, and the temperature condition is also satisfied.

Therefore, as shown in FIG. 9, the ECU 10 outputs an instruction signal that puts the first switch 21 and the second switch 22 in an overlapping state.
Subsequently, at time t7 after the duration threshold has elapsed from time t6, the ECU 10 short-circuits the lithium storage battery 52 and the second load 32 to the first switch 21 and the second switch 22, as shown in FIG. Then, a switching signal for opening between the lead storage battery 51 and the second load 32 is output. In this way, the drive battery is switched from the lead storage battery 51 to the lithium storage battery 52.

At time t7, the temperature T _SW1 of the first switch 21 and the temperature T _SW2 of the second switch 22 are each less than the allowable maximum temperature SW _M. In this way, the ECU 10 can switch the drive battery without causing a failure due to a temperature rise in the first switch 21 and the second switch 22.

[1-3. effect]
According to the first embodiment described in detail above, the following effects are obtained.
(1a) In S40-S80, the ECU 10 outputs an overlap signal for the duration threshold value and continuously for the duration threshold value when it is determined that there is a switching request and the temperature condition is satisfied. After outputting the overlap signal, the switching signal is output. When there is a switching request and it is determined that the temperature condition is not satisfied, the overlap signal and the switching signal are not output. The switching signal is a signal that opens between one of the two storage batteries and the second load 32, and short-circuits between the other storage battery and the second load 32.

As described above, when there is a switching request, the ECU 10 switches only when the temperature of the first switch 21 and the temperature of the second switch 22 satisfy predetermined temperature conditions. At the time of switching, the switching signal is output after the overlap signal is output.

As a result, when power is supplied to the electric load using a plurality of storage batteries, it is possible to suppress the occurrence of a power supply defect in the second load 32 due to the overlap state when the drive batteries are switched.

Further, by appropriately determining the temperature conditions such as being below a predetermined temperature, the overlap signal is not output when the temperature conditions are not satisfied, so that the first switch 21 and the second switch 22 are affected by the temperature rise. Failure is suppressed. As a result, when power is supplied to the electric load using a plurality of storage batteries, it is possible to suppress the occurrence of a power supply defect due to a switch failure in the second load 32 when the drive battery is switched.

(1b) In S30, the ECU 10 may determine whether or not the temperature condition that the temperature of each of the first switch 21 and the second switch 22 is less than the temperature threshold is satisfied. When the temperature of the first switch and the temperature of the second switch are equal to or higher than the temperature threshold value, the overlap signal is not output. By setting the temperature threshold value to an upper limit value to the extent that these switches do not fail, it is possible to prevent these switches from failing due to temperature rise. As a result, the same effect as in (1a) can be obtained.

(1c) In S20, the ECU 10 uses a drive battery, which is a storage battery for driving the second load 32, from one of the lead storage battery 51 and the lithium storage battery 52, which is a storage battery driving the second load 32. It is determined whether or not the switching condition for switching to the other storage battery of the lead storage battery 51 and the lithium storage battery 52, which is a storage battery in which the second load 32 is not being driven, is satisfied, and the switching condition is satisfied. If so, it is determined that there is a request for switching to the ECU 10.

As a result, since it is determined whether or not the switching condition is satisfied by the ECU 10 that executes the switching, the time lag at the time of determination is larger than that in the case where the determination is made by a device other than the ECU 10 and the result is acquired. Can be suppressed.

(1d) In S20, the ECU 10 determines whether or not the switching condition for switching the drive battery from the lithium storage battery 52, which is one storage battery, to the lead storage battery 51, which is the other storage battery, is satisfied, and the switching condition. Is satisfied, it is determined that there is a switching request. After outputting the overlap signal, the ECU 10 outputs a switching signal that opens between the lithium storage battery 52 and the second load 32, which are one storage battery, and short-circuits the lead storage battery 51 and the second load 32, which are the other storage batteries. You may.

As a result, the drive battery can be switched from the lithium storage battery 52 to the lead storage battery 51, and at the time of switching, the same effect as in (1a) can be obtained.
(1e) In S20, the ECU 10 determines whether or not the switching condition for switching the drive battery from the lead storage battery 51, which is one storage battery, to the lithium storage battery 52, which is the other storage battery, is satisfied, and the switching condition is set. If it is satisfied, it is determined that there is a switching request. After outputting the overlap signal, the ECU 10 outputs a switching signal that opens between the lead storage battery 51 and the second load 32, which are one storage battery, and short-circuits the lithium storage battery 52 and the second load 32, which are the other storage batteries. You may.

As a result, the drive battery can be switched from the lead storage battery 51 to the lithium storage battery 52, and at the time of switching, the same effect as in (1a) can be obtained.
(1f) In the vehicle power supply system 1, the lead storage battery 51 is connected to an alternator 41 which is a charging device capable of charging at least the lead storage battery 51.

As a result, the lead-acid battery 51 can be charged by the alternator 41 regardless of the connection state of the first switch 21 and the second switch 22. A first load 31 is connected to the lead storage battery 51. That is, power can be supplied to the first load 31 regardless of the connection state of the first switch 21 and the second switch 22.

(1 g) The output voltage of the lead storage battery 51 is always higher than the output voltage of the lithium storage battery 52. As a result, the lithium storage battery 52 can be charged by the lead storage battery 51 in an overlapping state in which the second load 32 and the lithium storage battery 52 are connected to the lead storage battery 51.

[1-4. Modification example]
A modification of the first embodiment is shown below.
[1-4-1. Modification 1]
As shown in FIG. 11, the ECU 10 estimates the predicted temperature, which is the temperature after the elapse of the duration threshold value of each of the first switch and the second switch 22, based on the temperature of each of the first switch 21 and the second switch 22. It may be configured as follows.

Here, the predicted temperature is calculated by adding the predicted rise value to the current switch temperature. The increase prediction value is a value obtained by calculating the power consumption based on the energization current in each switch and the duration threshold value which is the time during which the energization current flows, and predicting the temperature increase from the power consumption. The energizing current in each switch is based on the difference between the output voltage of the lead storage battery 51 and the output voltage of the lithium storage battery 52, the resistance value at the time of a short circuit in each switch, and the internal resistance of the lead storage battery 51 and the lithium storage battery 52. Can be calculated.

Then, in the ECU 10, the predicted temperature P _SW1 of the first switch 21 is less than the predetermined predicted threshold SW _PTH , and the predicted temperature P _SW2 of the second switch 22 is less than the predetermined predicted threshold SW _PTH . , May be configured to determine whether or not the temperature condition of is satisfied. Here, the prediction threshold SW _PTH can be set to a temperature at least higher than the predicted temperature. For example, the prediction threshold value may be set to a temperature higher than the predicted temperature by a predetermined temperature. The predetermined temperature can be set to a smaller value as the calculation accuracy of the predicted temperature is higher.

The prediction threshold value for the first switch 21 and the prediction threshold value for the second switch 22 may be set to the same value or may be set to different values. In the present embodiment, the prediction threshold value for the first switch 21 and the prediction threshold value for the second switch 22 are set to the same value.

As shown in FIG. 12, the switching process in the first modification differs from that in FIG. 2 in that S25 is added and S30 is replaced with S35.
Specifically, in the switching process, the ECU 10 executes the same process as S10-S20 in FIG. 2 in S10-S20.

In S25, the ECU 10 estimates the predicted temperature P _SW1 of the first switch 21 and the predicted temperature P _SW2 of the second switch 22 based on the temperature of the first switch 21 and the temperature of the second switch 22, respectively.

In S35, the ECU 10 has a temperature condition that the predicted temperature P _SW1 of the first switch 21 is less than the predicted threshold SW _PTH and the predicted temperature P _SW2 of the second switch 22 is less than the predicted threshold SW _PTH . It is judged whether or not the temperature condition is satisfied. The ECU 10 shifts the process to S40 when the temperature condition is satisfied, and shifts the process to S70 when the temperature condition is not satisfied. After S40, the ECU 10 executes the same processing as after S40 in FIG.

As a result, in the modified example 1, the prediction threshold value SW _PTH can be set near the maximum allowable temperature SW _M by improving the estimation accuracy of the predicted temperature. That is, the first switch 21 and the second switch 22 can be put into an overlapping state for a longer period of time.

[1-4-2. Modification 2]
In the vehicle power supply system 1, the alternator 41 may be configured to perform deceleration regeneration in which the lead storage battery 51 and the lithium storage battery 52 are charged by power generation during deceleration of the vehicle.

As shown in FIG. 13, during deceleration operation of the vehicle, both the first switch 21 and the second switch 22 are short-circuited, and the alternator 41 regeneratively charges the lead storage battery 51 and the lithium storage battery 52, and the first load 31 and the second switch 22. 2 Power is supplied to the load 32. Since the lithium storage battery 52 is a storage battery having high charging efficiency, the remaining capacity of the lithium storage battery 52 can be increased by regenerative charging during deceleration operation of the vehicle.

The ECU 10 gives an instruction signal to the first switch 21 and the second switch 22 so that both the first switch 21 and the second switch 22 are short-circuited only when the above-mentioned temperature conditions are satisfied even during the deceleration operation of the vehicle. May be configured to output.

[2. Second Embodiment]
[2-1. Constitution]
Since the basic configuration of the second embodiment is the same as that of the first embodiment, the differences will be described below. It should be noted that the same reference numerals as those in the first embodiment indicate the same configuration, and the preceding description will be referred to.

In this embodiment, as shown in FIG. 14, the vehicle power supply system 2 includes an ISG 42 instead of the alternator 41, and in addition to the first switch 21 and the second switch 22, the third switch 23 and the fourth switch 24 are further provided. It is different from the first embodiment in that it is provided with. ISG is an abbreviation for Integrated Starter Generator.

The lithium storage battery 52 and the first switch 21-4th switch 24 are housed in a housing and integrated to form a switch unit 20. Like the first switch 21 and the second switch 22, the third switch 23 and the fourth switch 24 are switched to either short circuit or open according to the instruction signal from the ECU 10.

The switch unit 20 is provided with a first terminal P1, a second terminal P2, and a third terminal P3 as external terminals. The external terminal is a terminal for connecting the switch unit 20 to the outside of the switch unit 20. A lead storage battery 51, a starter 33, and a first load 31 are connected to the first terminal P1. ISG42 is connected to the second terminal P2. A second load 32 is connected to the third terminal P3.

The ISG 42 has a power generation function of generating electricity by rotating the crank shaft of the engine and a power output function of applying a rotational force to the crank shaft.
Specifically, the ISG 42 has a rotating machine (not shown). The rotary machine is driveably connected to the crank shaft of the engine by a belt or the like, and the rotation shaft of the rotary machine rotates due to the rotation of the crank shaft, and the crank shaft rotates due to the rotation of the rotation shaft of the rotary machine. .. That is, the ISG 42 realizes a power generation function and a power output function by a rotating machine. The ISG 42 may have a function of performing regenerative power generation.

The lead storage battery 51 and the lithium storage battery 52 are connected in parallel to the ISG 42, and the lead storage battery 51 and the lithium storage battery 52 can be charged by the generated power of the ISG 42. The ISG 42 is connected to the lead storage battery 51 via the fourth switch. The ISG 42 is connected to the lithium storage battery 52 via the third switch 23. Further, the ISG 42 can be driven by being supplied with electric power from the lead storage battery 51 and the lithium storage battery 52.

[2-2. process]
[2-2-1. Switching process]
In the switching process of the present embodiment, the lithium storage battery 52 and the lead storage battery 51, whichever has the lower output voltage, is charged by the ISG 42 to reduce the difference between the output voltage of the lead storage battery 51 and the output voltage of the lithium storage battery 52. It differs from the first embodiment in that the drive battery is switched. Specifically, as shown in FIG. 15, in the switching process of the present embodiment, as shown in FIG. 15, a point where S10 is replaced with S15 and S22-S24 are added to the switching process of the first embodiment shown in FIG. It differs in that.

In the switching process of the present embodiment, in S15, the ECU 10 further acquires the output voltage V _Pb of the lead storage battery 51 and the output voltage V _Li of the lithium storage battery 52 in addition to the process of S10 shown in FIG.

In the subsequent S20, the ECU 10 executes the same process as in FIG. However, the ECU 10 shifts the process to S22 when it is determined in S20 that there is a switching request, that is, when it is determined that the switching condition is satisfied.

In S22, the ECU 10 determines whether or not the absolute value of the difference between the output voltage V _Pb of the lead storage battery 51 and the output voltage V _Li of the lithium storage battery 52 is equal to or greater than a predetermined difference threshold value. The ECU 10 shifts the process to S30 when the absolute value of the difference between these output voltages is less than the difference threshold value, and shifts the process to S24 when the absolute value of the difference between these output voltages is equal to or more than the difference threshold value. ..

The difference threshold can be set to a value less than 1V, for example 0.5V. However, the difference is not limited to this, and the difference threshold value can be set to any value. The difference threshold is stored in the memory 12 in advance.

In S24, the ECU 10 uses the ISG 42 to charge the two storage batteries having the lower output voltage for a predetermined time.
Here, in the ECU 10, when the switching condition for switching the drive battery from the lithium storage battery 52 to the lead storage battery 51 is satisfied in S20, the output voltage V _Li of the lithium storage battery 52 is higher than the output voltage V _Pb of the lead storage battery 51. If it is low, an instruction signal for short-circuiting the third switch is output to the switch unit 20, and the lithium storage battery 52 is charged by the ISG 42 for a predetermined time.

On the other hand, in S20, when the switching condition for switching the drive battery from the lead storage battery 51 to the lithium storage battery 52 is satisfied, the output voltage V _Pb of the lead storage battery 51 is lower than the output voltage V _Li of the lithium storage battery 52. In this case, the ISG 42 may be configured to charge the lead-acid battery 51 for a predetermined time by outputting an instruction signal for short-circuiting the fourth switch to the switch unit 20.

After S30, the ECU 10 performs the same processing as after S30 in FIG.
[2-2-2. Operation]
The operation of the vehicle power supply system 2 will be described with reference to the time chart shown in FIG. 16 and FIGS. 17-20. In the present embodiment, the output voltage when the lead storage battery 51 is fully charged and the output voltage when the lithium storage battery 52 is fully charged are set to 12V. Further, the out-of-range threshold value as the voltage threshold value in the switching condition is set to 11V, and the in-range threshold value is set to 12V. The difference threshold is set to 0.5V. The output voltage, voltage threshold value, and difference threshold value at the time of full charge are not limited to these, and can be set to arbitrary values.

At time t11, the first switch 21 is opened, the second switch 22 is short-circuited, the third switch 23 is opened, and the fourth switch 24 is opened. That is, the lithium storage battery 52 is a drive battery. After time t11, the output voltage V _Li of the lithium storage battery 52 decreases with the passage of time.

At time t12, as shown in FIG. 17, the output voltage V _Li of the lithium storage battery 52 is less than 11 V. That is, the output voltage V _Li of the lithium storage battery 52 changes from the out-of-range threshold value or more to the out-of-range threshold value, and before the switching of the drive battery is executed, the drive battery is switched from the lithium storage battery 52 to the lead storage battery 51. The switching condition is satisfied. Here, in the present embodiment, the ECU 10 determines that the absolute value of the difference between the output voltage of the lithium storage battery 52 and the output voltage of the lead storage battery 51 is equal to or greater than the difference threshold value.

As shown in FIG. 18, the ECU 10 further short-circuits the third switch at time t13. That is, at time t13, the first switch 21 is short-circuited, the second switch 22 is short-circuited, the third switch 23 is short-circuited, and the fourth switch 24 is opened. As a result, the ECU 10 charges the lithium storage battery 52 for a predetermined time by the ISG 42.

Time t14 is after a predetermined time has elapsed from time t13. The ECU 10 opens the third switch and ends the charging of the lithium storage battery 52 by the ISG 42. That is, at this point, the connection state is the same as in FIG. As shown in FIG. 16, at this point, the absolute value of the difference between the output voltage of the lithium storage battery 52 and the output voltage of the lead storage battery 51 is less than the difference threshold value.

At time t15, the ECU 10 determines whether or not the temperature condition is satisfied. Here, the ECU 10 specifies that the temperature T _SW1 of the first switch 21 and the temperature T _SW2 of the second switch 22 are each less than the temperature threshold SW _TH . Therefore, the ECU 10 first outputs an instruction signal to the switch unit 20 to put the first switch 21 and the second switch 22 in an overlapping state.

That is, as shown in FIG. 19, the first switch 21 is short-circuited, the second switch 22 is short-circuited, the third switch 23 is opened, and the fourth switch 24 is opened. As a result, the first switch 21 and the second switch 22 are put into an overlapping state, and the lithium storage battery 52 is charged by the lead storage battery 51. Since the lithium storage battery 52 is a storage battery having high charging efficiency, the remaining capacity can be increased and the output voltage can be increased with the passage of time by charging with the lead storage battery 51.

The time t16 represents a time point when the duration threshold value has elapsed from the time t15. At time t16, as shown in FIG. 20, the ECU 10 opens the second switch 22 provided between the lithium storage battery 52 and the second load 32 in the switch unit 20, and between the lead storage battery 51 and the second load 32. A switching signal for short-circuiting the provided first switch 21 is output. As a result, the drive battery is switched from the lithium storage battery 52 to the lead storage battery 51.

The ECU 10 may be configured to charge the lithium storage battery 52, which is not driving the second load 32, by the ISG 42 when the drive battery is switched from the lithium storage battery 52 to the lead storage battery 51. That is, as shown in FIG. 20, the first switch 21 may be short-circuited, the second switch 22 may be opened, the third switch 23 may be short-circuited, and the fourth switch 24 may be opened.

As a result, while the second load 32 is being driven by the lead storage battery 51, the lithium storage battery 52 can be charged so as to approach the voltage value at the time of full charge.
[2-3. effect]
According to the second embodiment described in detail above, the effects (1a)-(1b) and (1d) of the above-mentioned first embodiment can be obtained, and further, the following effects can be obtained.

(2a) The lead storage battery 51 is connected to an ISG 42 capable of charging at least one of the lead storage battery 51 and the lithium storage battery 52 via a fourth switch 24 that can be switched to either short circuit or open according to an instruction signal from the ECU 10. Ru. The lithium storage battery 52 is connected to the ISG 42 via a third switch 23 that switches to either short circuit or open according to an instruction signal from the ECU 10.

As a result, the lead storage battery 51 and the lithium storage battery 52 can be charged at an appropriate timing by the ISG 42.
(2b) When it is determined that the switching condition is satisfied, the ECU 10 determines whether or not the absolute value of the difference between the output voltage of the lead storage battery 51 and the output voltage of the lithium storage battery 52 is equal to or higher than a predetermined difference threshold value. It may be configured to determine. When the absolute value of these differences is equal to or greater than the difference threshold value, the ECU 10 short-circuits the switch unit 20 between the lead storage battery 51 and the lithium storage battery 52, whichever has the lower output voltage, and the ISG 42 for a predetermined period. It may be configured to output an instruction signal. That is, the ECU 10 may be configured to short-circuit the switch connected to the storage battery having a low output voltage among the fourth switch 24 and the third switch 23.

Then, after outputting the instruction signal for a predetermined period, the ECU 10 determines whether or not the temperature condition is satisfied, and if the temperature condition is satisfied, switches the drive battery through the overlap state. May be configured in.

As a result, by charging with the ISG 42, the drive battery is switched after reducing the voltage difference between the lead storage battery 51 and the lithium storage battery 52, so that it is possible to suppress the flow of an excessive current in the overlapped state. can. Further, by setting the overlap state, it is not necessary to charge the storage battery having the lower output voltage, so that the overlap time can be shortened.

(2c) When the ECU 10 outputs the switching signal, the switching signal of the lead storage battery 51 and the lithium storage battery 52 is output to the switch unit 20 together with the switching signal, so that the second load 32 is not being driven. The storage battery may be configured to output an instruction signal so as to be charged by the ISG 42. That is, the ECU 10 may be configured to short-circuit the switch connected to the storage battery in which the second load 32 of the fourth switch 24 and the third switch 23 is not being driven. The instruction signal may be continuously output until the output voltage of the non-driving storage battery becomes equal to or higher than the range threshold value.

As a result, the drive battery can be switched and the non-drive storage battery can be newly charged. Further, this eliminates the need to newly charge the non-driving storage battery by setting the overlap state, so that the overlap time can be shortened. Further, by charging in this way, the output voltage of the newly non-driving storage battery can be set to the threshold value within the range or more, and the charged non-driving storage battery can be newly switched as the drive battery.

(2d) The ECU 10 has a difference between the output voltage of the lead storage battery 51 and the output voltage of the lithium storage battery 52, particularly when it is determined that the switching condition for switching the drive battery from the lithium storage battery 52 to the lead storage battery 51 is satisfied. May be configured to determine whether or not is greater than or equal to a predetermined difference threshold. When these differences are equal to or greater than the difference threshold value, the ECU 10 sends an instruction signal to the switch unit 20 to short-circuit the third switch 23, which is a switch provided between the lithium storage battery 52 and the ISG 42, for a predetermined period of time. It may be configured to output.

Further, when the ECU 10 outputs a switching signal, the switch unit 20 receives a switching signal for switching the drive battery from the lithium storage battery 52 to the lead storage battery 51, and the lithium storage battery 52 that is not driving the second load 32. It may be configured to output an instruction signal that short-circuits the third switch 23 so that it is charged by the ISG 42. The instruction signal may be continuously output until the output voltage of the non-driving storage battery becomes equal to or higher than the range threshold value.

As a result, the effects of (2b) and (2c) can be obtained when the drive battery is switched from the lithium storage battery 52 to the lead storage battery 51.
[2-4. Modification example]
A modification of the second embodiment is shown below.

[2-4-1. Modification 3]
In the third modification, the ECU 10 may be configured to execute the same switching process as in the first embodiment. That is, the ECU 10 may be configured to perform control for short-circuiting and opening the first switch 21 and the second switch 22 in the switch unit 20 as in the first embodiment.

[2-4-2. Modification 4]
In the modified example 4, the ECU 10 may be configured to determine whether or not the temperature condition is satisfied based on the temperature condition shown in the modified example 1.

[3. Other embodiments]
Although the embodiments of the present disclosure have been described above, the present disclosure is not limited to the above-described embodiments, and can be variously modified and implemented.

(3a) In the above embodiment, the ECU 10 is configured to determine that there is a switching request when the switching condition is satisfied, but the present invention is not limited to this. The switching request may be output from another ECU mounted on the vehicle. That is, the other ECU may be configured to determine whether or not the switching condition is satisfied, and may be configured to output a switching request to the ECU 10 when the switching condition is satisfied.

Then, the ECU 10 may be configured to acquire a switching request output from another ECU, and may be configured to determine that there is a switching request when the switching request is acquired.
(3b) A plurality of functions possessed by one component in the above embodiment may be realized by a plurality of components, or one function possessed by one component may be realized by a plurality of components. .. Further, a plurality of functions possessed by the plurality of components may be realized by one component, or one function realized by the plurality of components may be realized by one component. Further, a part of the configuration of the above embodiment may be omitted. Further, at least a part of the configuration of the above embodiment may be added or replaced with the configuration of the other above embodiment. It should be noted that all aspects included in the technical idea specified from the wording described in the claims are embodiments of the present disclosure.

(3c) The present disclosure is disclosed in various forms such as a program for operating the vehicle power supply system 1, 2, ECU 10, and ECU 10 described above, a non-changeable actual recording medium such as a semiconductor memory in which this program is recorded, and a switching method. It can also be realized.

The ECU 10 corresponds to the power supply control device, the lead storage battery 51 corresponds to the first storage battery, the lithium storage battery 52 corresponds to the first storage battery, the first switch 21 corresponds to the first connection switch, and the second. The switch 22 corresponds to the second connection switch, the third switch 23 corresponds to the second charging switch, and the fourth switch 24 corresponds to the first charging switch. Further, the second load 32 corresponds to an electric load.

Further, S10 corresponds to the processing as the temperature acquisition unit, S20 corresponds to the processing as the switching determination unit, S25 corresponds to the processing as the temperature estimation unit, and S30 and S35 correspond to the processing as the temperature determination unit. do. Further, S40-S80 corresponds to the processing as the storage battery switching unit.

Further, the overlap signal corresponds to the superimposed signal, and the duration threshold value corresponds to the superimposed time.

10 ECU, 21 1st switch, 22 2nd switch 22, 23 2nd charging switch 23, 24 1st charging switch 24, 32 2nd load, 51 lead storage battery, 52 lithium storage battery.

Claims (8)

A power supply control device (10) capable of driving an electric load by a plurality of storage batteries.
The plurality of storage batteries include a first storage battery (51) and a second storage battery (52).
The power supply control device is
A switch that can be switched to either short-circuit or open according to an instruction signal from the power supply control device, the first connection switch that short-circuits or opens between the first storage battery and the electric load, the second storage battery, and the electric load. A temperature acquisition unit (S10) that acquires the respective temperatures of the second connection switch that short-circuits or opens the space, and
A drive battery that is a storage battery that drives the electric load is a storage battery that is driving the electric load and is not driving the electric load from one of the first storage battery and the second storage battery. The switching determination unit (S20) for determining whether or not there is a switching request for switching to the other storage battery of the first storage battery and the second storage battery, and the like.
A temperature determination unit (S30, S35) for determining whether or not the temperature of each of the first connection switch and the second connection switch satisfies a predetermined temperature condition, and
When there is a changeover request and it is determined that the temperature condition is satisfied, at least a superposed signal for short-circuiting the first connection switch and short-circuiting the second connection switch is predetermined as the instruction signal. The superimposition period is output, and the switching signal is output after the superimposition signal is output. When it is determined that the switching request is made and the temperature condition is not satisfied, the superimposition signal and the switching signal are not output. , Storage battery switching unit (S40-S80),
Equipped with
The switching signal is a power supply control device which is an instruction signal and is a signal for opening between the one storage battery and the electric load and short-circuiting between the other storage battery and the electric load. The power supply control device according to claim 1.
The temperature determination unit (S30) determines whether or not the temperature condition that the temperature of each of the first connection switch and the second connection switch is less than a predetermined temperature threshold is satisfied. Power control device to judge. The power supply control device according to claim 1.
A temperature estimation unit (S25) that estimates the predicted temperature, which is the temperature after the overlap period of each of the first connection switch and the second connection switch, based on the temperatures of the first connection switch and the second connection switch. )
Further prepare
Whether or not the temperature determination unit (S35) satisfies the temperature condition that the predicted temperature of each of the first connection switch and the second connection switch is less than a predetermined prediction threshold value. A power control device that determines whether or not. The power supply control device according to any one of claims 1 to 3.
The switching determination unit uses the drive battery, which is a storage battery for driving the electric load, from one of the first storage battery and the second storage battery, which is a storage battery driving the electric load, to obtain the electric load. Is a non-driving storage battery, and it is determined whether or not the switching condition for switching to the other storage battery of the first storage battery and the second storage battery is satisfied, and when the switching condition is satisfied, the switching is performed. A power control device that determines that there is a request. The power supply control device according to claim 4.
The switching determination unit satisfies the switching condition for switching the drive battery from the second storage battery, which is the one storage battery, to the first storage battery, which is the other storage battery. Judge whether or not,
When it is determined that the switching condition is satisfied and the temperature condition is satisfied, the storage battery switching unit outputs the superposed signal and then outputs the switching signal, which is the second storage battery. A power supply control device that opens between the storage battery and the electric load and outputs a switching signal that short-circuits between the first storage battery, which is the other storage battery, and the electric load. The power supply control device according to claim 4 or 5.
The switching determination unit satisfies the switching condition for switching the drive battery from the first storage battery, which is the one storage battery, to the second storage battery, which is the other storage battery. Judge whether or not,
When it is determined that the switching condition is satisfied and the temperature condition is satisfied, the storage battery switching unit outputs the superimposed signal, and then the switching signal is the first storage battery. A power supply control device that opens between the storage battery and the electric load and outputs a switching signal that short-circuits between the second storage battery, which is the other storage battery, and the electric load. The power supply control device according to any one of claims 1 to 6.
The first storage battery is a power supply control device connected to a charging device capable of charging at least the first storage battery. The power supply control device according to any one of claims 1 to 7.
The first storage battery is a first charging switch (a first charging switch) that can be switched to a charging device capable of charging at least one of the first storage battery and the second storage battery, either short-circuited or opened according to an instruction signal from the power supply control device. 24) is connected, and the second storage battery is connected to the charging device via a second charging switch (23) that switches to either short circuit or open according to an instruction signal from the power supply control device. Power control device.

Images