JP6686556B2 - Power system - Google Patents

Description

  The present disclosure relates to a power supply system mounted on a vehicle.

  In the parking state, when the state of charge (SOC) of the lithium ion battery is equal to or greater than a predetermined value and the lead battery is not in the fully charged state, the DC-DC converter is controlled to supply power from the lithium ion battery to the lead battery. Is known to reduce the SOC of the lithium-ion battery while keeping the lead battery in a fully charged state (see, for example, Patent Document 1).

Japanese Patent Laid-Open No. 2008-148389

  In recent years, the electric power consumption of the electric load group tends to be relatively high in the parking state. In this respect, in the above-described technique, when the electric power consumption of the electric load group is relatively high in the parked state, the SOC of the lead battery may be lowered, and the lead battery may be deteriorated. On the other hand, if the DC-DC converter is operated in order to cover the power consumption of the electric load group with the electric power from the lithium-ion battery in the parking state, the DC-DC converter operates in a low efficiency region, resulting in poor operation efficiency. There is a risk of becoming.

  Therefore, the disclosed technology provides a power supply system capable of improving the operating efficiency of the DC-DC converter in the parked state while reducing the promotion of deterioration of the lead battery in the parked state.

According to one aspect of the present disclosure, a power supply system mounted on a vehicle,
An electric load group including an electric load that operates in a parked state,
A lead battery electrically connected to the electric load group,
A lithium-ion battery electrically connected to the electrical load group in a parallel relationship to the lead battery,
A DC-DC converter provided between the electric load group and the lead battery and the lithium ion battery;
In the parking state, a first process of operating the DC-DC converter and a second process of stopping the DC-DC converter are selectively executed so as to supply electric power from the lithium ion battery to the electric load group. And a control device for
In the parking state, the control device determines whether or not the power consumption of the electric load group is equal to or more than a first threshold value, and when the power consumption of the electric load group is equal to or more than the first threshold value, 1 process is executed, if the power consumption of the electric load group is not equal to or more than the first threshold value, the second process is executed ,
In the first process, the control device calculates the electric power that can be supplied from the lithium ion battery to the electric load group according to the SOC of the lithium ion battery, and supplies the electric power from the lithium ion battery to the electric load group. There is provided a power supply system that controls the DC-DC converter so that the supplied power is equal to or less than the supplyable power.

  According to the technique of the present disclosure, it is possible to obtain a power supply system capable of improving the operation efficiency of the DC-DC converter in the parked state while reducing the promotion of deterioration of the lead battery in the parked state.

It is a figure which shows the schematic electric circuit structure of the power supply system 1. 3 is a diagram showing a schematic configuration of a control system of the power supply system 1. FIG. It is a figure which shows an example of the relationship of SOC of lithium ion battery 22 memorize | stored as map information, and the electric power which can be supplied. 7 is a flowchart schematically showing an example of processing executed by the control device 70. 5 is an explanatory diagram of efficiency characteristics of the step-up / down converter 30. FIG. It is a figure which shows schematically the electric power supply state using only the lithium ion battery 22. It is a figure which shows schematically the electric power supply state using the lead battery 20 and the lithium ion battery 22. It is a figure which shows schematically the electric power supply state using only the lead battery 20. It is a figure which shows schematically the electric power supply state at the time of charge of the lead battery 20. It is a figure which shows the relationship between the load power consumption and SOC of the lead battery 20 by a comparative example. It is explanatory drawing of the effect by a present Example.

  Hereinafter, each embodiment will be described in detail with reference to the accompanying drawings.

  FIG. 1 is a diagram showing a schematic electric circuit configuration of the power supply system 1. The power supply system 1 is mounted on a vehicle that uses only an engine as a drive source.

  The power supply system 1 includes an electric load group 10, a lead battery 20, a lithium-ion battery 22, and a DC-DC converter 30 (hereinafter, referred to as “buck-boost converter 30”).

  The electric load group 10 includes a plurality of low-voltage electric loads 11 and 12 that are supplied with power from the lead battery 20. In the example shown in FIG. 1, the electric load group 10 includes two electric loads 11 and 12, but may actually include a larger number of electric loads. The electric load group 10 includes electric loads that operate in a parked state. In this embodiment, the electric loads 11 and 12 are assumed to be electric loads that operate in a parked state. For example, the electric load that operates in the parked state may be an electric load related to a security system or an air conditioning system, a defogger, or the like.

  The lead battery 20 has a rated voltage of 12 V, for example.

  The lithium-ion battery 22 has a rated voltage of, for example, 24V or 48V. However, the lithium-ion battery 22 may have a rated voltage of 12V.

  The buck-boost converter 30 charges the lithium-ion battery 22 by boosting the voltage generated by the alternator 40 during the boosting operation. During the step-down operation, the step-up / step-down converter 30 steps down the voltage of the lithium-ion battery 22 and outputs it to the low voltage side (lead battery 20 and electric load group 10 side).

  The power supply system 1 further includes a current sensor 201 that detects the charge / discharge current of the lead battery 20, a voltage sensor 202 that detects the voltage of the lead battery, and a current sensor 221 that detects the charge / discharge current of the lithium-ion battery 22. A voltage sensor 222 that detects the voltage of the lithium-ion battery 22 is included. Power supply system 1 further includes a current sensor 301 that detects the output current of buck-boost converter 30, and a voltage sensor 302 that detects the output voltage of buck-boost converter 30. The current sensor 301 and the voltage sensor 302 may be built in the buck-boost converter 30.

  FIG. 2 is a diagram showing a schematic configuration of a control system of the power supply system 1. The power supply system 1 includes a control device 70. The control device 70 is realized by an ECU (Electronic Control Unit) including a microcomputer and an IC (Integrated Circuit). A sensor group 90 and a buck-boost converter 30 are connected to the control device 70. The sensor group 90 includes current sensors 201, 221, 301 and voltage sensors 202, 222, 302.

  The control device 70 includes a battery information acquisition unit 71, a converter activation control unit 72, a power consumption determination unit 74, a suppliable power calculation unit 76, a storage unit 77, a converter control unit 78, and a power generation circuit 79. including. The battery information acquisition unit 71, the converter activation control unit 72, the power consumption determination unit 74, and the available power calculation unit 76 are realized by a microcomputer (that is, the CPU of the microcomputer executes the program stored in the ROM or the like). Will be realized in). The storage unit 77 is realized by a memory such as a flash memory of a microcomputer. The converter control unit 78 is realized by, for example, a microcomputer and a control IC.

  The battery information acquisition unit 71 acquires information indicating the state of the lead battery 20 and information indicating the state of the lithium ion battery 22. The information indicating the state of the lead battery 20 includes current and voltage that can be acquired from the current sensor 201 and the voltage sensor 202. The battery information acquisition unit 71 calculates the SOC of the lead battery 20 based on the information indicating the state of the lead battery 20. When the temperature of the lead battery 20 is used to calculate the SOC of the lead battery 20, the information indicating the state of the lead battery 20 includes the temperature of the lead battery 20.

  Similarly, the information indicating the state of the lithium-ion battery 22 includes current and voltage that can be acquired from the current sensor 301 and the voltage sensor 302. The battery information acquisition unit 71 calculates the SOC of the lithium ion battery 22 based on the information indicating the state of the lithium ion battery 22. Similarly, when other parameters such as the temperature of the lithium ion battery 22 are used to calculate the SOC of the lithium ion battery 22, the information indicating the state of the lithium ion battery 22 includes the temperature of the lead battery 20 and the like. For example, the battery information acquisition unit 71 calculates an integrated current value by integrating based on the current information obtained from the current sensor 301 during parking, and based on the integrated current value and the SOC at the start of parking, the current time is calculated. Calculate SOC. At this time, the battery information acquisition unit 71 may correct the current SOC based on the temperature of the lithium-ion battery 22 and the degree of deterioration (for example, SOH: State Of Health).

  The converter activation control unit 72 activates the buck-boost converter 30 when the buck-boost converter 30 is stopped. Specifically, converter activation control unit 72 activates buck-boost converter 30 by controlling power supply generation circuit 79 to generate drive power. The power supply generation circuit 79 generates a drive power supply (for example, 15V) based on a low voltage system power supply (for example, so-called + B) caused by the lead battery 20, for example. When the driving power is generated, the operating state of the buck-boost converter 30 is established. The control IC of the converter control unit 78 turns on / off the switching element (not shown) of the step-up / down converter 30 based on the drive power generated by the power generation circuit 79.

  The converter activation control unit 72 stops the buck-boost converter 30 in the operating state of the buck-boost converter 30. The converter activation control unit 72 stops the step-up / down converter 30 by stopping the generation of drive power by the power generation circuit 79.

  The power consumption determination unit 74 calculates the power consumption of the electric load group 10 (hereinafter referred to as “load power consumption”). The power consumption determination unit 74 calculates the power supplied from the lead battery 20 to the electric load group 10 (hereinafter, referred to as “first power consumption”) based on the information from the current sensor 201 and the voltage sensor 202. Based on the information from the current sensor 301 and the voltage sensor 302, the electric power supplied from the lithium ion battery 22 to the electric load group 10 (hereinafter, referred to as “second power consumption”) is calculated. Then, the power consumption determination unit 74 calculates the load power consumption by adding the first power consumption and the second power consumption.

  The available power calculation unit 76 calculates the power that can be supplied to the electric load group 10 from the buck-boost converter 30 (hereinafter referred to as “available power”). For example, the available power calculation unit 76 calculates the available power according to the SOC of the lithium-ion battery 22 based on the relationship between the SOC of the lithium-ion battery 22 and the available power as shown in FIG. 3, for example. . In FIG. 3, the horizontal axis shows the available power supply and the vertical axis shows the SOC. Note that the suppliable electric power is set to be lower than the maximum electric power that can be supplied from the lithium ion battery 22 in consideration of the durability of the lithium ion battery 22. The relationship shown in FIG. 3 is derived based on, for example, a test, is mapped, and is stored in the storage unit 77 of the control device 70.

  The storage unit 77 stores map information indicating the relationship as shown in FIG.

  Converter control unit 78 determines the target value of the output voltage of buck-boost converter 30 based on the calculation results from power consumption determination unit 74 and available power calculation unit 76. Then, converter control unit 78 controls the output voltage of buck-boost converter 30 so that the target value of the output voltage is realized. For example, converter control unit 78 generates a drive signal according to the target value by PWM (Pulse Width Modulation) control, and applies the drive signal to the gate of each switching element (not shown) of buck-boost converter 30.

  More specifically, the converter control unit 78 outputs the output of the buck-boost converter 30 when the load power consumption calculated by the power consumption determination unit 74 is less than or equal to the supplyable power calculated by the supplyable power calculation unit 76. The target value of the voltage is determined so that the discharge current of the lead battery 20 becomes zero. That is, converter control unit 78 controls the output voltage of buck-boost converter 30 based on the information obtained from current sensor 201 so that the discharge current of lead battery 20 becomes zero.

  On the other hand, when the load power consumption calculated by the power consumption determination unit 74 exceeds the available power calculated by the available power calculation unit 76, the converter control unit 78 sets the target value of the output voltage of the buck-boost converter 30 to The value is determined such that the available power is supplied. That is, converter control unit 78 controls the output voltage of buck-boost converter 30 so that the product of the current and the voltage that can be obtained from current sensor 301 and voltage sensor 302 matches the determined target value of the output voltage. As a result, the lead battery 20 is discharged. That is, the electric power from the lead battery 20 is consumed.

  Other operations of converter control unit 78 will be described later with reference to FIG.

  The power supply generation circuit 79 is an electric circuit that generates the drive power supply described above. Since the control IC of the converter control unit 78 operates based on the drive power supply as described above, it turns off when the drive power supply is not generated.

  FIG. 4 is a flowchart schematically showing an example of processing executed by the control device 70. FIG. 6A, FIG. 6B, FIG. 7A, and FIG. 7B are explanatory diagrams of the process of FIG. 4, and are diagrams schematically showing a power supply state. In FIG. 6A, FIG. 6B, FIG. 7A, and FIG. 7B, the arrow indicates the supply of electric power, and the arrow schematically indicates a thicker mode as the supplied electric power amount is larger.

  In step S400, the power consumption determination unit 74 determines whether the engine is operating. Whether or not the engine is operating can be determined based on, for example, the voltage of the ignition power supply. Alternatively, whether or not the engine is operating may be determined based on information from an engine ECU (not shown).

In step S402, the power consumption determination unit 74 calculates the load power consumption and determines whether the calculated load power consumption is smaller than a predetermined value W ₁ (an example of the first threshold value). The predetermined value W ₁ is predetermined based on the efficiency characteristic of the buck-boost converter 30 as shown in FIG. 5, for example. In FIG. 5, as an example of efficiency characteristics of the buck-boost converter 30, the horizontal axis represents output power (output voltage × output current), and the vertical axis represents efficiency of the buck-boost converter 30. Generally, the buck-boost converter 30 is inefficient when the output power is small, and the lithium-ion battery 22 consumes unnecessary power. The X region in FIG. 5 shows such a low efficiency region. Therefore, the predetermined value W ₁ is set within the range of electric power larger than that of the region X. In step S402, if the determination result is "YES", the process proceeds to step S404 to perform the low load process, and otherwise, the process proceeds to step S420 to perform the high load process (one example of the first process).

In step S404, the battery information acquisition unit 71 calculates the SOC of the lithium ion battery 22, and determines whether the calculated SOC of the lithium ion battery 22 is equal to or greater than a predetermined value S ₃ . The predetermined value S ₃ corresponds to, for example, a value obtained by giving a predetermined margin to the lower limit value of the SOC of the lithium ion battery 22 to be secured. If the determination result is "YES", the process proceeds to step S406, and if not, the process proceeds to step S410.

  In step S406, the battery information acquisition unit 71 determines whether or not the lithium ion battery 22 is charging the lead battery 20. Charging from the lithium-ion battery 22 to the lead battery 20 is realized by the process of step S416 described later by the converter control unit 78. Therefore, whether or not the lithium-ion battery 22 is charging the lead battery 20 can be determined based on the information from the converter control unit 78. If the determination result is "YES", the process proceeds to step S408, and if not, the process proceeds to step S412.

In step S408, the battery information acquisition unit 71 calculates the SOC of the lead battery 20 and determines whether the calculated SOC of the lead battery 20 is equal to or greater than a predetermined value S ₂ (an example of a second threshold value). The predetermined value S ₂ is a value corresponding to full charge or a value close thereto. If the determination result is "YES", the process proceeds to step S410, and if not, the process proceeds to step S416.

  In step S410, converter activation control unit 72 establishes the stopped state of buck-boost converter 30 (an example of the second process). For example, the converter activation control unit 72 maintains the stopped state in the stopped state in which the drive power generation circuit 79 does not generate the drive power, and the operation state of the buck-boost converter 30 in which the drive power generation circuit 79 generates the drive power. Then, the operation of the power generation circuit 79 is stopped. FIG. 7A schematically shows a power supply state when the buck-boost converter 30 is in a stopped state. In this case, as shown in FIG. 7A, only the electric power of the lead battery 20 is consumed by the electric load group 10.

In step S412, the battery information acquisition unit 71 calculates the SOC of the lead battery 20 and determines whether the calculated SOC of the lead battery 20 is equal to or less than a predetermined value S ₁ (an example of a third threshold value). The predetermined value S ₁ corresponds to the upper limit value of the SOC range in which the deterioration of the lead battery 20 is promoted, and is smaller than the predetermined value S ₂ . If the determination result is "YES", the process proceeds to step S414, otherwise, the process ends.

  In step S414, converter activation control unit 72 forms the operating state of buck-boost converter 30 (an example of the second process). For example, the converter activation control unit 72 maintains the operating state in the operating state of the step-up / down converter 30 in which the driving power source is activated by the power source generation circuit 79, and the stopped state in which the driving power source is not generated by the power source generation circuit 79. Then, the power generation circuit 79 generates drive power.

  In step S416, converter control unit 78 drives step-up / down converter 30 to charge lead battery 20 from lithium-ion battery 22 (an example of a third process). FIG. 7B schematically shows the power supply state by the process of step S416. In the example shown in FIG. 7B, the electric power of the lithium ion battery 22 is consumed by charging the lead battery 20 and the electric load group 10.

  In step S420, converter activation control unit 72 establishes the operating state of buck-boost converter 30, as in step S414 above.

  In step S422, the battery information acquisition unit 71 calculates the SOC of the lithium ion battery 22.

  In step S424, the available power calculation unit 76 calculates the available power according to the SOC of the lithium-ion battery 22 calculated in step S422 using the relationship shown in FIG. 3, for example, and the load power consumption (step S402). (Calculated in step 1) is less than or equal to the power that can be supplied. If the determination result is "YES", the process proceeds to step S426, and if not, the process proceeds to step S428.

  In step S426, converter control unit 78 determines a value such that discharge current of lead battery 20 becomes 0 based on the information obtained from current sensor 201, and raises or lowers based on the determined target value of the output voltage. The output voltage of the pressure converter 30 is controlled. FIG. 6A schematically shows a power supply state by the process of step S426. In this case, as shown in FIG. 6A, only the electric power of the lithium ion battery 22 is consumed by the electric load group 10.

  In step S428, converter control unit 78 controls the output voltage of buck-boost converter 30 such that the electric power supplied from lithium-ion battery 22 to electric load group 10 matches the available electric power. Specifically, as described above, the converter control unit 78 determines the target value of the output voltage of the step-up / down converter 30 to a value at which the suppliable power is supplied, and sets it to the determined target value of the output voltage. Based on this, the output voltage of the buck-boost converter 30 is controlled. FIG. 6B schematically shows a power supply state by the process of step S428. In this case, as shown in FIG. 6B, the electric power of the lead battery 20 and the lithium ion battery 22 is consumed by the electric load group 10.

  According to the process shown in FIG. 4, in the parking state, the determination result of step S400 is “NO”, and depending on the determination result of step S402, the low load process (steps S404 to S416) or the high load process (step S420). -Step S428) is selectively performed.

  By the way, in recent years, the electric load group 10 mounted on a vehicle may include an electric load that operates in a parking state and consumes relatively high electric power (hereinafter, referred to as “large electric power load”). It is possible. Even when there is no large electric power load, the number of electric loads operating in the parking state is large, and relatively high electric power may be consumed in the parking state. In such a case, the electric power consumption of the electric load group becomes relatively high in the parking state.

  In this regard, the effect of this embodiment will be described with reference to FIGS. 8 and 9. FIG. 8 is a diagram showing the relationship between the load power consumption and the SOC of the lead battery 20 according to the comparative example, the upper side shows the time series of the load power consumption, and the lower side shows the SOC of the lead battery 20 (Pb SOC) time series. Indicates. FIG. 9 is an explanatory diagram of the effect of the present embodiment, showing the time series of the load power consumption in order from the top, the time series of the SOC (Pb SOC) of the lead battery 20, and the SOC (LiB of the lithium ion battery 22. SOC) time series.

In the comparative example, the buck-boost converter 30 is not operated in the parking state. That is, in the comparative example, the buck-boost converter 30 is maintained in the stopped state even when the load power consumption (power consumption of the electric load group 10) in the parking state is relatively high. In the comparative example, when the buck-boost converter 30 is maintained in the stopped state in a state in which the load power consumption (power consumption of the electric load group 10) in the parking state is relatively high, the lead battery 20 is discharged and overdischarge occurs. Degradation of the lead battery 20 due to this is facilitated. For example, in the example shown in FIG. 8, the large power load operates from time t0 to time t1 and the load power consumption is high. Along with this, the SOC of the lead battery 20 greatly decreases from time t0 to time t1, and the SOC of the lead battery 20 falls below a predetermined value S ₁ at time ta. As a result, in the comparative example, deterioration of the lead battery 20 due to over-discharging is facilitated.

  Therefore, when the load power consumption is relatively high in the parking state, operating the step-up / down converter 30 is useful from the viewpoint of reducing the acceleration of deterioration of the lead battery 20.

In this respect, according to the present embodiment, when the load power consumption is equal to or greater than the predetermined value W ₁ in the parking state, the buck-boost converter 30 is activated and the buck-boost converter 30 is controlled (step S426 or step S426). S428). As a result, the acceleration of deterioration of the lead battery 20 can be reduced even when the load power consumption is relatively high in the parking state. For example, in the example shown in FIG. 9, the large power load operates from time t0 to time t1 and the load power consumption is high. Along with this, the buck-boost converter 30 is activated and the buck-boost converter 30 is controlled. In the example shown in FIG. 9, from time t0 to time t1, the load power consumption is entirely covered by the power from the lithium ion battery 22, and the SOC of the lead battery 20 does not decrease. As a result, acceleration of deterioration of the lead battery 20 due to overdischarge is reduced.

Here, the lithium ion battery 22 tends to be deteriorated if left for a long time in a state where the SOC is relatively high. In this regard, according to the present embodiment, when the load power consumption is equal to or higher than the predetermined value W ₁ in the parking state, the buck-boost converter 30 is operated (step S426 or step S428). When the buck-boost converter 30 is operated, the SOC of the lithium-ion battery 22 decreases. This reduces the possibility that the lithium-ion battery 22 will be left in a high SOC state for a long time, and reduces the acceleration of deterioration of the lithium-ion battery 22.

  Further, when the load power consumption is relatively low in the parking state, not operating the buck-boost converter 30 is useful from the viewpoint of reducing the use of the buck-boost converter 30 in the low efficiency region (region X in FIG. 5). Becomes

In this respect, according to the present embodiment, when the load power consumption is not equal to or more than the predetermined value W ₁ in the parking state, except when a specific condition is satisfied (when the condition for executing step S416 is satisfied). The buck-boost converter 30 is stopped (step S410). As a result, it is possible to prevent the buck-boost converter 30 from being used in a low-efficiency region when the load power consumption is relatively low in the parking state. That is, it is possible to improve the operation efficiency of the DC-DC converter in the parked state. For example, in the example shown in FIG. 9, the high power load is stopped from time t1 to time t2, and only dark current is generated. Note that, from time t1 to time t2, the SOC of the lead battery 20 slightly decreases by the amount of the dark current flowing, but the SOC of the lead battery 20 is the predetermined value S ₁ or more. Along with this, the buck-boost converter 30 is stopped from time t1 to time t2. This can prevent the buck-boost converter 30 from being used in a low efficiency region.

  In this way, according to the present embodiment, it is possible to reduce the promotion of deterioration of the lead battery 20 in the parked state while improving the operating efficiency of the step-up / down converter 30 in the parked state.

Further, according to the present embodiment, when the load power consumption is equal to or more than the predetermined value W ₁ in the parking state, the lithium ion battery 22 to the electric load group 10 are selected according to the relationship between the load power consumption and the available power supply. The buck-boost converter 30 is controlled so that the power supplied to the power supply does not exceed the power that can be supplied (steps S426 and S428). As a result, it is possible to prevent the durability of the lithium-ion battery 22 from being deteriorated due to the consumption of electric power that exceeds the supplyable electric power from the lithium-ion battery 22.

Further, according to the present embodiment, when the load power consumption is equal to or greater than the predetermined value W ₁ in the parking state, and the power supplied from the lithium ion battery 22 to the electric load group 10 does not exceed the available power supply. Controls the buck-boost converter 30 so that the discharge current of the lead battery 20 becomes zero (step S426). As a result, unnecessary discharge from the lead battery 20 can be prevented, and a decrease in the SOC of the lead battery 20 can be prevented.

Further, according to the present embodiment, when the load power consumption is not equal to or more than the predetermined value W ₁ in the parked state and the SOC of the lead battery 20 is equal to or less than the predetermined value S ₁ , the lead battery 20 is charged. (Step S416). As a result, the acceleration of deterioration of the lead battery 20 due to the SOC of the lead battery 20 falling below the predetermined value S ₁ can be reduced. In the example shown in FIG. 9, from the time t1 to the time t2, the SOC of the lead battery 20 slightly decreases as much as the dark current flows. Then, when the SOC of the lead battery 20 becomes equal to or lower than the predetermined value S ₁ at time t2, the buck-boost converter 30 operates and the lithium ion battery 22 charges the lead battery 20. This charging is stopped at time t3 when the SOC of the lead battery 20 becomes S ₂ or more.

  Further, according to the present embodiment, the power consumption determination unit 74 determines the second power consumption that is consumed from the lithium-ion battery 22 via the buck-boost converter 30 based on the information from the current sensor 301 and the voltage sensor 302. calculate. As a result, it is possible to calculate the load power consumption with high accuracy that reflects a slight power loss that occurs in the buck-boost converter 30. However, in the modification, the power consumption determination unit 74 may calculate the second power consumption based on the information from the current sensor 221 and the voltage sensor 222 instead of the information from the current sensor 301 and the voltage sensor 302. Good.

  Although the respective embodiments have been described in detail above, the present invention is not limited to the specific embodiments, and various modifications and changes can be made within the scope of the claims. Further, it is possible to combine all or a plurality of the constituent elements of the above-described embodiments.

For example, in the example shown in FIG. 4, the high-load process (step S420~ step S428) may be that the SOC of the lithium ion battery 22 is executed only when a predetermined value _{S 3} or more.

Further, in the example shown in FIG. 4, it is determined whether or not the load power consumption is equal to or greater than the predetermined value W ₁ based on the load power consumption calculated by the power consumption determination unit 74, but the present invention is not limited to this. . For example, whether or not the load power consumption is equal to or greater than the predetermined value W ₁ may be determined based on whether or not a predetermined large power load is operating. In this case, when the predetermined large power load is operating, it is determined that the load power consumption is equal to or larger than the predetermined value W ₁ . Then, the process of step S426 or step S428 may be selectively executed according to the attribute of a predetermined large power load that is operating (for example, rated power consumption).

1 Power Supply System 10 Electric Load Group 11 Electric Load 12 Electric Load 20 Lead Battery 22 Lithium Ion Battery 30 Buck-Boost Converter 40 Alternator 70 Control Device 71 Battery Information Acquisition Unit 72 Converter Activation Control Unit 74 Power Consumption Determination Unit 76 Suppliable Power Calculation Unit 77 storage unit 78 converter control unit 79 power supply generation circuit 90 sensor group 201 current sensor 202 voltage sensor 221 current sensor 222 voltage sensor 301 current sensor 302 voltage sensor

Claims (6)

A power supply system installed in a vehicle,
An electric load group including an electric load that operates in a parked state,
A lead battery electrically connected to the electric load group,
A lithium-ion battery electrically connected to the electrical load group in a parallel relationship to the lead battery,
A DC-DC converter provided between the electric load group and the lead battery and the lithium ion battery;
In the parking state, a first process of operating the DC-DC converter and a second process of stopping the DC-DC converter are selectively executed so as to supply electric power from the lithium ion battery to the electric load group. And a control device for
In the parking state, the control device determines whether or not the power consumption of the electric load group is equal to or more than a first threshold value, and when the power consumption of the electric load group is equal to or more than the first threshold value, 1 process is executed, if the power consumption of the electric load group is not equal to or more than the first threshold value, the second process is executed ,
In the first process, the control device calculates the electric power that can be supplied from the lithium ion battery to the electric load group according to the SOC of the lithium ion battery, and supplies the electric power from the lithium ion battery to the electric load group. A power supply system that controls the DC-DC converter so that the supplied power is equal to or less than the supplyable power. Further comprising a current sensor for detecting a charge / discharge current of the lead battery,
In the first process, the control device controls the DC-DC so that the discharge current detected by the current sensor becomes 0 when the power that can be supplied is equal to or higher than the power consumption of the electric load group. controlling the converter, the power system of claim 1. In the first process, when the electric power that can be supplied is not more than the electric power consumption of the electric load group, the control device determines that the electric power supplied from the lithium ion battery to the electric load group is the electric power that can be supplied. as matched controls the DC-DC converter, the power supply system according to claim 1 or 2. In a parking state, the control device operates the DC-DC converter to charge the lead battery with the first process, the second process, and the electric power supplied from the lithium-ion battery. And selectively
In the parking state, the control device executes the second process when the power consumption of the electric load group is not equal to or higher than the first threshold value and the SOC of the lead battery is equal to or higher than a second threshold value,
In the parking state, when the power consumption of the electric load group is not equal to or higher than the first threshold value and the SOC of the lead battery is equal to or lower than a third threshold value that is smaller than the second threshold value, The power supply system according to any one of claims 1 to 3 , which executes a third process. A first current sensor for detecting a charge / discharge current of the lead battery;
A first voltage sensor for detecting the voltage of the lead battery;
A second current sensor for detecting an output current of the DC-DC converter on the electric load group side;
A second voltage sensor for detecting an output voltage of the DC-DC converter on the side of the electric load group;
The control device calculates the power consumption of the electric load group based on the detection results of the first current sensor, the first voltage sensor, the second current sensor, and the second voltage sensor. The power supply system according to any one of 1 to 4 . A power supply system installed in a vehicle,
An electric load group including an electric load that operates in a parked state,
A lead battery electrically connected to the electric load group,
A lithium-ion battery electrically connected to the electrical load group in a parallel relationship to the lead battery,
A DC-DC converter provided between the electric load group and the lead battery and the lithium ion battery;
In the parking state, a first state in which the DC-DC converter is operated and a second state in which the DC-DC converter is stopped are selectively formed so as to supply electric power from the lithium-ion battery to the electric load group. And a control device for
In the parking state, the control device determines whether the power consumption of the electric load group is equal to or more than a first threshold value, and when the power consumption of the electric load group is equal to or more than the first threshold value, 1 state is formed, and if the power consumption of the electric load group is not greater than or equal to the first threshold value, the second state is formed ,
In the first state, the control device calculates the power that can be supplied from the lithium ion battery to the electric load group according to the SOC of the lithium ion battery, and supplies the electric power from the lithium ion battery to the electric load group. A power supply system that controls the DC-DC converter so that the supplied power is equal to or less than the supplyable power.

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