JP2020188571A - On-vehicle power control device and on-vehicle power supply device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique capable of setting a setting value used for control related to backup by a more versatile method and with a simpler configuration. SOLUTION: A power control device 1 sets a set value corresponding to a combination of an acquisition unit 45 for acquiring requests from loads 94 to 96 and loads 94 to 96 connected to a plurality of output ports 22 and 23. It has a setting unit 46 and a control unit 44 that controls backup based on the set value set by the setting unit 46. The setting unit 46 sets the set value based on the request acquired by the acquisition unit 45 and the setting information in which the candidate value of the set value is determined for each combination of the loads 94 to 96. [Selection diagram] Fig. 1

Description

The present disclosure relates to an in-vehicle power supply control device and an in-vehicle power supply device.

Patent Document 1 discloses a technique for supplying electric power from a main battery to a load in an in-vehicle system, while backing up with a sub-battery when the electric power supply from the main battery is interrupted. When such technology is installed in a vehicle, control according to the combination of loads to be backed up is required. In addition, the combination of loads to be backed up may differ depending on the vehicle type. Therefore, conventionally, software is developed for each combination of loads to be backed up, semiconductor chips incorporating each software are manufactured, and the corresponding semiconductor chips are mounted on the vehicle to support various vehicle models. Was there.

JP-A-2015-217734

However, if a semiconductor chip is manufactured for each combination of loads as described above, there is a problem that the manufacturing cost and the management cost are increased.

Therefore, the present disclosure provides a technique capable of setting a setting value used for control related to backup by a more versatile method and with a simpler configuration.

The vehicle-mounted power control device, which is one of the disclosures, is
The first power supply unit has a plurality of output ports, a first power supply unit, and a second power supply unit that functions as a backup power source when the power supply from the first power supply unit is interrupted. A power supply used in an in-vehicle power supply system in which power is supplied to each load connected to each of the output ports, and the second power supply unit functions as a backup power supply when the power supply from the first power supply unit is interrupted. It ’s a control device,
The acquisition unit that acquires the request from the load,
A setting unit that sets a setting value corresponding to a combination of the loads connected to the plurality of output ports, and a setting unit.
A control unit that controls backup based on the set value set by the setting unit,
Have,
The setting unit sets the setting value based on the setting information in which the candidate value of the setting value is determined for each combination of the request acquired by the acquisition unit and the load.

The vehicle-mounted power supply device, which is one of the disclosures, is
With the above second power supply unit
The above-mentioned in-vehicle power supply control device and
To be equipped.

FIG. 1 is a circuit diagram conceptually illustrating an in-vehicle power supply control device and an in-vehicle power supply system in which the in-vehicle power supply device of the first embodiment is used. FIG. 2 is a flowchart illustrating a flow of setting processing executed by the vehicle-mounted power supply control device of the first embodiment. FIG. 3 is a flowchart illustrating the flow of the output determination process in the setting process of FIG. FIG. 4 is a flowchart illustrating the flow of the request determination process in the setting process of FIG. FIG. 5 is an explanatory diagram illustrating candidate values of set values corresponding to the combination of the load and the output port.

[Explanation of Embodiments of the present disclosure]
First, embodiments of the present disclosure will be listed and described.
The vehicle-mounted power control device, which is an example of the present disclosure, is
(1) An acquisition unit that acquires a request from a load, a setting unit that sets a setting value corresponding to a combination of loads connected to a plurality of output ports, and a control related to backup based on the setting value set by the setting unit. It has a control unit for performing the above. Then, the setting unit sets the setting value based on the setting information in which the candidate value of the setting value is determined for each combination of the request and the load acquired by the acquisition unit.
In this way, it is possible to appropriately apply a plurality of types of vehicles, which have different combinations of loads to be mounted and need to set a set value according to the combination of loads to be mounted, as application candidates by a highly versatile method. Moreover, since the acquisition unit can acquire the request from the load and set the set value based on the request acquired in this way, the above effect can be achieved while suppressing the complication of the peripheral circuit of the control unit. Obtainable.
(2) It has a detection unit that detects output states in a plurality of output ports, the request includes information for specifying the type of the load that issued the request, and the setting unit is an output state detected by the detection unit. It is preferable to set the set value based on the request acquired by the acquisition unit and the setting information.
In this way, it is possible to more reliably confirm which load is connected to which output port. Moreover, the type of load can be specified based on the request, and the set value can be set according to the type of load.
(3) The second power supply unit may have a plurality of power storage elements, and the setting unit may set the number of power storage elements as a set value.
In this power supply control device, the number of power storage elements can be set as a set value corresponding to the combination of loads connected to the output port. Therefore, a plurality of types of vehicles having different numbers of power storage elements depending on the combination of loads to be mounted can be appropriately applied as application candidates by a highly versatile method.
(4) It is preferable that the setting unit sets a target value of the charging voltage as a set value, and the control unit performs charging control so that the charging voltage of the second power supply unit becomes the set value.
This power supply control device can set a target value of the charging voltage as a set value corresponding to the combination of loads connected to the output port. Therefore, it is possible to appropriately apply a plurality of types of vehicles having different storage capacities in the second power supply unit according to the combination of loads to be mounted by a highly versatile method as application candidates. Charging control can be performed so that the charging voltage of the second power supply unit becomes an appropriate target value.
(5) The vehicle-mounted power supply control device may include a voltage monitoring unit that monitors the voltage of the conductive path connected between the output port and the load. When each of the plurality of conductive paths is connected to each of the plurality of output ports, each conductive path becomes a path for supplying electric power to each load, and the voltage monitoring unit serves as each conductive path. It may be designed to monitor each voltage of. Then, the setting unit may set a target voltage value of the voltage monitored by the voltage monitoring unit as a set value. Then, the control unit may control the voltage of each of the conductive paths to be a set value by turning on and off the switching elements provided in each of the conductive paths.
This power supply control device can set a target voltage value as a set value corresponding to a combination of loads connected to the output port. Therefore, a plurality of types of vehicles having different target voltage values depending on the combination of loads to be mounted can be appropriately applied as application candidates by a highly versatile method, and the applied vehicles are supplied to the load. Control can be performed so that the voltage value becomes an appropriate voltage value.
(6) The vehicle-mounted power supply control device may include a current monitoring unit that monitors the current of the conductive path connected between the output port and the load. When each of the plurality of conductive paths is connected to each of the plurality of output ports, each conductive path becomes a path for supplying electric power to each load, and the current monitoring unit serves as each conductive path. It may be designed to monitor each current of. Then, the setting unit may set the maximum current value of the current monitored by the current monitoring unit as a set value. Then, the control unit may perform a predetermined protection operation when it is determined that the current value of the conductive path has reached the set value.
This power supply control device can set a target current value as a set value corresponding to a combination of loads connected to the output port. Therefore, a plurality of types of vehicles having different maximum voltage values depending on the combination of loads to be mounted can be appropriately applied as application candidates by a highly versatile method, and the applied vehicles are appropriately determined. The protection operation can be performed based on the maximum current value.

The vehicle-mounted power supply device, which is an example of the present disclosure, includes the above-mentioned second power supply unit and the vehicle-mounted power supply control device according to the above-mentioned (1) to (6).
This vehicle-mounted power supply device has the same effect as the vehicle-mounted power supply control device described in (1) to (6) above.

[Details of Embodiments of the present disclosure]
Specific examples of the vehicle-mounted power supply control device and the vehicle-mounted power supply device of the present disclosure will be described below with reference to the drawings. It should be noted that the present invention is not limited to these examples, and is indicated by the scope of claims, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

The vehicle-mounted power control device and the vehicle-mounted power supply device of the present disclosure will be described with reference to FIGS. 1 to 5. The vehicle-mounted power supply system 100 (hereinafter, also referred to as power supply system 100) shown in FIG. 1 is connected to a plurality of output ports 22, 23 to which a plurality of types of loads 94 to 96 can be connected, and to output ports 22, 23. It includes a first power supply unit 90 that supplies power to loads 94 to 96, and a second power supply unit 92 that functions as a backup power source when the power supply from the first power supply unit 90 is interrupted.

The first power supply unit 90 functions as, for example, a main battery, and is configured as a known in-vehicle battery such as a lithium ion battery. In the first power supply unit 90, the terminal on the high potential side is electrically connected to the first input side conductive path 11, and a predetermined output voltage is applied to the first input side conductive path 11. Further, the terminal on the low potential side of the first power supply unit 90 is electrically connected to a ground unit (not shown).

The second power supply unit 92 functions as, for example, a sub-battery, and is composed of, for example, a plurality of power storage elements 93 (for example, a capacitor). In the second power supply unit 92, the terminal on the high potential side is electrically connected to the second input side conductive path 12, and a predetermined output voltage is applied to the second input side conductive path 12. Further, in the second power supply unit 92, the terminal on the low potential side is electrically connected to a ground unit (not shown).

The first input-side conductive path 11 and the second input-side conductive path 12 are electrically connected via an intermediate conductive path 13, and a voltage converter 24 is provided in the intermediate conductive path 13. The voltage converter 24 is configured as, for example, a step-down DCDC converter, and can input a voltage based on the output voltage of the first power supply unit 90, and at the same time, step down the input voltage and output it to the second power supply unit 92 side. Can be done. The voltage converter 24 may be configured as a step-up DCDC converter or a buck-boost DCDC converter, and may boost the voltage output from the first power supply unit 90 and output it to the second power supply unit 92 side. You may do so. The second power supply unit 92 is charged by inputting the voltage output from the voltage converter 24.

The output ports 22 and 23 are provided corresponding to the loads 94 and the loads 95 and 96, respectively, and the type of load to be connected is predetermined. Specifically, output ports 22A and 23A are provided corresponding to the first load 94, and output ports 22B and 23B are provided corresponding to the second load 95 and the third load 96. The plurality of output ports 22 may be visually distinguishable from each other. Further, the plurality of output ports 23 may be visually distinguishable from each other. For example, the load 94 and the identification code corresponding to the type of the load 95, 96 may be attached to each of the plurality of output ports 22 and 23 so that they can be visually distinguished. Further, the plurality of output ports 22 and 23 may have a structure in which only the corresponding loads 94 and 95, 96 can be connected (a structure in which non-corresponding loads are not connected).

The loads 94 to 96 are each provided with an actuator, an ECU for controlling the actuator, and the like. The first load 94 may be connected to the corresponding output port 22 via the output side conductive path 15. The second load 95 and the third load 96 may be connected to the corresponding output port 23 via the output side conductive path 15. The second load 95 and the third load 96 have an exclusive relationship with each other and cannot be mounted on the vehicle at the same time. The loads 94 to 96 may or may not be mounted depending on the type of vehicle (vehicle type). That is, the vehicle types are a vehicle type (vehicle type A) equipped with both the first load 94 and the second load 95, a vehicle type (vehicle type B) equipped with both the first load 94 and the third load 96, and the first load. Vehicle type with only 94 (vehicle type C), vehicle type with only second load 95 (vehicle type D), vehicle type with only third load 96 (vehicle type E), and any loads 94 to 96 It is classified into a vehicle type that is not installed (vehicle type D).

Each of the plurality of output ports 22 is electrically connected to the first input side conductive path 11 via the main side conductive path 17 provided individually corresponding to each of the output ports 22. Specifically, the output port 22A is electrically connected to the first input-side conductive path 11 via the main-side conductive path 17A, and the output port 22B is electrically connected to the first input-side conductive path 11 via the main-side conductive path 17B. 1 It is electrically connected to the input side conductive path 11.

Each of the plurality of output ports 23 is electrically connected to the second input side conductive path 12 via the sub-side conductive path 18 provided individually corresponding to each of the output ports 23. Specifically, the output port 23A is electrically connected to the second input-side conductive path 12 via the sub-side conductive path 18A, and the output port 23B is connected to the second input-side conductive path 18B via the sub-side conductive path 18B. 2 It is electrically connected to the input side conductive path 12.

One end of each of the plurality of main-side conductive paths 17 is electrically connected to the first input-side conductive path 11, and the other end is electrically connected to different output ports 22. One end of each of the plurality of sub-side conductive paths 18 is electrically connected to the second input-side conductive path 12, and the other end is electrically connected to different output ports 23.

The electric power of the first power supply unit 90 is supplied to the loads 94 to 96 through the first input side conductive path 11, the main side conductive path 17, the output port 22, and the output side conductive path 15. Further, the electric power of the second power supply unit 92 is supplied to the loads 94 to 96 through the second input side conductive path 12, the sub side conductive path 18, the output port 23, and the output side conductive path 15. In the following, in the main side conductive path 17, the first power supply unit 90 side is referred to as an input side, and the output port 22 side is referred to as an output side. Further, in the sub-side conductive path 18, the second power supply unit 92 side is referred to as an input side, and the output port 23 side is referred to as an output side.

The power supply system 100 includes a power supply control device 1. The power supply control device 1 controls so that backup using the second power supply unit 92 is performed when the power supply from the first power supply unit 90 to the loads 94 to 96 is interrupted. The power supply control device 1 includes the plurality of output ports 22 and 23 described above, a plurality of main side conductive paths 17, and a plurality of sub side conductive paths 18. Further, the power supply control device 1 includes main side switching elements 25, 27, sub side switching elements 26, 28, power supply monitoring unit 40, voltage / current monitoring unit 42, control unit 44, request processing unit 48, and the like. The power supply control device 1 constitutes the power supply device 3 together with the second power supply unit 92.

The fuse 30 and the main switching elements 25 and 27 (main side switching elements 25A and 27A and the main side switching elements 25B and 27B) are connected to the plurality of main side conductive paths 17 (main side conductive path 17A and main side conductive path 17B), respectively. ), A current detector 32 and the like are provided.

The main switching element 25 is provided on the output side of the fuse 30. The main switching element 25 is configured as, for example, a relay switch, and when it is turned on, it allows power to be supplied from the first power supply unit 90 to the loads 94 to 96 connected to the output port 22.

The main side switching element 27 is provided on the output side of the main side switching element 25. The main-side switching element 27 is configured as, for example, a relay switch, and changes the output voltage to the output side by performing on / off operation.

The fuse 30 and the sub-side switching elements 26 and 28 (sub-side switching elements 26A and 28A and the sub-side switching elements 26B and 28B) are connected to the plurality of sub-side conductive paths 18 (sub-side conductive paths 18A and sub-side conductive paths 18B), respectively. ), A current detector 32 and the like are provided.

The sub-side switching element 26 is provided on the output side of the fuse 30. The sub-side switching element 26 is configured as, for example, a relay switch, and when it is turned on, it allows power to be supplied from the second power supply unit 92 to the loads 94 to 96 connected to the output port 23.

The sub-side switching element 28 is provided on the output side of the sub-side switching element 26. The sub-side switching element 28 is configured as, for example, a relay switch, and changes the output voltage to the output side by performing on / off operation.

The power supply monitoring unit 40 monitors the output voltage of the first power supply unit 90 and the charging voltage of the second power supply unit 92 (each of the power storage elements 93). The output voltage of the first power supply unit 90 and the charging voltage of the second power supply unit 92 (each of the power storage elements 93) are detected by a voltage detector (not shown). The power supply monitoring unit 40 includes an AD converter and the like, and acquires an analog signal indicating the output voltage of the first power supply unit 90 or the charging voltage of the second power supply unit 92 (each of the power storage elements 93) from the voltage detector. , AD conversion and output to the control unit 44.

The voltage / current monitoring unit 42 detects the output states of the plurality of output ports 22 and 23. Specifically, the voltage / current monitoring unit 42 monitors the voltage and current of each of the plurality of main-side conductive paths 17, and also monitors the voltage and current of each of the plurality of sub-side conductive paths 18. The voltage of the plurality of main side conductive paths 17 and the voltage of the plurality of sub side conductive paths 18 are detected by voltage detectors (not shown), respectively. The current of the main side conductive path 17 and the current of the sub side conductive path 18 are detected by the current detector 32, respectively. The voltage / current monitoring unit 42 includes an AD converter or the like, and when it acquires an analog signal indicating a detection value of a voltage detector or a current detector 32 (not shown), it performs AD conversion and outputs it to the control unit 44. The voltage / current monitoring unit 42 corresponds to an example of the detection unit. Further, the voltage / current monitoring unit 42 corresponds to an example of the voltage monitoring unit and also corresponds to an example of the current monitoring unit.

The control unit 44 is configured to include, for example, a microcontroller or the like, and includes an arithmetic unit such as a CPU, a storage unit such as a ROM or RAM, and a drive unit such as a driver. The control unit 44 includes an acquisition unit 45 that acquires a request from the load. The control unit 44 of the loads 94 to 96 connected to the plurality of output ports 22 based on the request acquired by the acquisition unit 45 and the information in which the candidate values of the set values are determined for each combination of the loads 94 to 96. A setting unit 46 for setting a setting value corresponding to the combination is provided. The setting unit 46 determines a combination of loads 94 to 96 connected to the plurality of output ports 22, and stores the setting value corresponding to the combination. Then, when the predetermined execution condition is satisfied, the control unit 44 reads out the set value stored in the setting unit 46, and controls the backup based on the set value.

The control unit 44 can specify the output voltage of the first power supply unit 90 and the charging voltage of the second power supply unit 92 (each of the power storage elements 93) based on the signal input from the power supply monitoring unit 40. Further, the control unit 44 can specify the voltage value and the current value of the main side conductive path 17 and the voltage value and the current value of the sub side conductive path 18 based on the signal input from the voltage and current monitoring unit 42. Can be done.

The control unit 44 may drive the voltage converter 24 by the drive unit. By driving the voltage converter 24, the control unit 44 steps down the voltage input to the voltage converter 24 from the first power supply unit 90 side and outputs it to the second power supply unit 92 side to output the voltage to the second power supply unit 92 side. Charge control can be performed to charge the 92. The charge control corresponds to an example of "control related to backup".

When a predetermined charging start condition is satisfied, the control unit 44 drives the voltage converter 24 to start charging the second power supply unit 92. The charging start condition is, for example, that the ignition switch is switched from the off state to the on state. The voltage of the second power supply unit 92 is held at a predetermined standby voltage when the ignition switch is off, and charging is started when the ignition switch is switched to the on state. After the start of charging, the control unit 44 stops driving the voltage converter 24 and ends charging of the second power supply unit 92 when a predetermined charging end condition is satisfied. The charging end condition is, for example, that the charging voltage of the second power supply unit 92 has reached a target value (hereinafter, also referred to as a charging target value). Since this charging target value differs depending on the vehicle type (combination of the loads 94 to 96 to be mounted), the charging target value corresponding to the vehicle type is set by the setting process described later.

The control unit 44 uses the second power supply unit 92 to perform backup when the power supply from the first power supply unit 90 is interrupted. The control unit 44 backs up so that the output voltage (voltage of the sub-side conductive path 18) with respect to the loads 94 to 96 becomes a predetermined target voltage value. Since this target voltage value differs depending on the vehicle type (combination of the loads 94 to 96 to be mounted), the target voltage value corresponding to the vehicle type is set by the setting process described later.

Further, the control unit 44 performs a predetermined protection operation when the current value (current value of the sub-side conductive path 18) flowing through the loads 94 to 96 exceeds a predetermined maximum current value during backup. The predetermined protection operation is, for example, turning off the sub-side switching element 28. As a result, the current flowing through the loads 94 to 96 is cut off, and a large current can be prevented from flowing through the loads 94 to 96. Since the maximum current value differs depending on the vehicle type (combination of loads 94 to 96 to be mounted), the maximum current value corresponding to the vehicle type is set by the setting process described later.

The request processing unit 48 is configured as a part of, for example, a microcontroller or the like. The request processing unit 48 may have a hardware configuration different from that of the control unit 44. Each request from the loads 94 to 96 connected to the output ports 22 and 23 is input to the request processing unit 48. Each request contains information that identifies the type of load 94-96 that outputs each request. The request processing unit 48 inputs a combination of requests from the loads 94 to 96 (information specifying the loads 94 to 96 that issued the request) to the control unit 44 via the common route 19.

Next, the flow of the setting process executed by the control unit 44 will be described.
The control unit 44 executes the setting process shown in FIG. 2 when a predetermined setting start condition is satisfied. The setting start condition is, for example, that the power supply control device 1 (power supply device 3) is assembled to the vehicle and activated. That is, it was started with the loads 94 to 96 corresponding to the vehicle type connected. When the setting start condition is satisfied, the control unit 44 performs the output determination process shown in FIG. 3 in step S101.

In the output determination process shown in FIG. 3, the control unit 44 first switches all the main side switching elements 25 and 27 to the ON state in step S201. After that, in step S202, the current of each main side conductive path 17 is monitored for a predetermined time. Then, in step S203, it is determined whether or not the current value of the main-side conductive path 17A exceeds a predetermined threshold value within the predetermined time.

As a result of the determination in step S203, when it is determined that the current value of the main side conductive path 17A exceeds a predetermined threshold value, a current is flowing through the main side conductive path 17A (a load is connected to the output port 22). ) Is determined. Then, in step S204, it is determined whether or not the current value of the main-side conductive path 17B exceeds the predetermined threshold value within the predetermined time.

As a result of the determination in step S204, when it is determined that the current value of the main side conductive path 17B exceeds a predetermined threshold value, a current is flowing through the main side conductive path 17B (a load is connected to the output port 23). ) Is determined. Then, in step S205, it is determined that "both output ports 22 and 23 have a load".

As a result of the determination in step S204, when it is determined that the current value of the main side conductive path 17B does not exceed a predetermined threshold value, no current is flowing through the main side conductive path 17B (a load is applied to the output port 22). It is determined that it is not connected). Then, in step S206, it is determined that "there is a load only on the output port 22".

On the other hand, as a result of the determination in step S203, when it is determined that the current value of the main side conductive path 17A does not exceed a predetermined threshold value, no current is flowing through the main side conductive path 17A (to the output port 22). The load is not connected). Then, in step S207, it is determined whether or not the current value of the main-side conductive path 17B exceeds the predetermined threshold value within the predetermined time.

As a result of the determination in step S207, when it is determined that the current value of the main side conductive path 17B exceeds a predetermined threshold value, a current is flowing through the main side conductive path 17B (a load is connected to the output port 23). ) Is determined. Then, in step S208, it is determined that "there is a load only on the output port 23".

As a result of the determination in step S207, when it is determined that the current value of the main side conductive path 17B does not exceed a predetermined threshold value, no current is flowing through the main side conductive path 17B (a load is applied to the output port 23). It is determined that it is not connected). Then, in step S209, it is determined that "there is no load on both the output ports 22 and 23".

When the output determination process shown in FIG. 3 is completed, the control unit 44 performs step S102 (request determination process shown in FIG. 4) of FIG. In the request determination process, first, in step S301, the control unit 44 monitors whether the request signal from the load is sent for a predetermined time. Then, in step S302, it is determined whether or not the request 1 has been acquired within the predetermined time. Here, the request 1 is a request signal transmitted from the ECU of the first load 94, and is, for example, a signal for issuing a command to supply electric power from the second power supply unit 92 to drive an actuator or the like. The control unit 44 determines whether or not the request 1 from the first load 94 has been acquired by the acquisition unit 45. If it is determined that the request 1 has been acquired as a result of the determination in step S302, it is determined that the first load 94 can be communicated with.

Subsequently, in step S303, it is determined whether or not the request 2 has been acquired. Here, the request 2 is a request signal transmitted from the ECU of the second load 95, and is, for example, a signal for issuing a command to supply electric power from the second power supply unit 92 to drive the actuator or the like. The control unit 44 determines whether or not the request 2 from the second load 95 has been acquired by the acquisition unit 45. As a result of the determination in step S303, when it is determined that the request 2 has been acquired, it is determined that the second load 95 can be communicated with. Then, in step S304, it is determined that "requests 1 and 2 are present".

If it is determined that the request 2 has not been acquired as a result of the determination in step S303, it is determined in step S305 whether or not the acquisition unit 45 has acquired the request 3 from the third load 96. Here, the request 3 is a request signal transmitted from the ECU of the third load 96, and is, for example, a signal for issuing a command to supply electric power from the second power supply unit 92 to drive the actuator or the like. The control unit 44 determines whether or not the request 3 from the third load 96 has been acquired by the acquisition unit 45. As a result of the determination in step S305, when it is determined that the request 3 has been acquired, it is determined that the third load 96 can be communicated with. Then, in step S306, it is determined that "requests 1 and 3 are present".

If it is determined that the request 3 has not been acquired as a result of the determination in step S305, it is determined in step S307 that "there is a request 1".

If it is determined that the request 1 has not been acquired as a result of the determination in step S302, it is determined in step S308 whether or not the acquisition unit 45 has acquired the request 2 from the second load 95. As a result of the determination in step S308, when it is determined that the request 2 has been acquired, it is determined that the second load 95 can be communicated with. Subsequently, in step S309, it is determined whether or not the request 3 has been acquired. If it is determined that the request 3 has not been acquired as a result of the determination in step S309, it is determined in step S304 that "there is a request 2".

If it is determined that the request 3 has been acquired as a result of the determination in step S309, it is determined in step S311 that there is no request. Then, the control unit 44 performs control at the time of abnormality (for example, notification of abnormality without changing the set value).

If it is determined that the request 2 has not been acquired as a result of the determination in step S308, it is determined in step S312 whether or not the request 3 has been acquired. If it is determined that the request 3 has been acquired as a result of the determination in step S312, it is determined in step S313 that "there is a request 3".

If it is determined that the request 3 has not been acquired as a result of the determination in step S312, it is determined in step S314 that there is no request.

When the output determination process shown in FIG. 4 is completed, the control unit 44 determines in step S103 of FIG. 2 whether or not there is a load on the output ports 22 and 23. If it is determined that the output ports 22 and 23 have a load as a result of the determination in step S103, it is determined in step S104 whether or not there are only requests 1 and 2. As a result of the determination in step S104, if it is determined that there are only requests 1 and 2, it is determined in step S105 that "there is a first load 94 and a second load 95". That is, it is determined that the first load 94 is connected to the output port 22 and the second load 95 is connected to the output port 23. Then, the control unit 44 sets a set value corresponding to the vehicle type A (see FIG. 5).

As a result of the determination in step S104, if it is determined that the requirements 1 and 2 are not the only ones, it is determined in the step S106 whether or not there are only the requests 1 and 3. If it is determined that there are only requests 1 and 3 as a result of the determination in step S106, it is determined in step S107 that "there is a first load 94 and a third load 96". That is, it is determined that the first load 94 is connected to the output port 22 and the third load 96 is connected to the output port 23. Then, the control unit 44 sets a set value corresponding to the vehicle type B (see FIG. 5).

As a result of the determination in step S106, if it is determined that the requirements 1 and 3 are not the only ones, it is determined in step S108 that there is no load. Then, the control unit 44 performs control at the time of abnormality (for example, notification of abnormality without changing the set value).

As a result of the determination in step S103, if it is determined that there is no load on both the output ports 22 and 23, it is determined in step S109 whether or not there is a load only on the output port 22. As a result of the determination in step S109, if it is determined that there is a load only on the output port 22, it is determined in step S110 whether or not there is only request 1. As a result of the determination in step S110, if it is determined that there is only request 1, it is determined in step S111 that "there is a first load 94". That is, it is determined that the first load 94 is connected to the output port 22. Then, the control unit 44 sets a set value corresponding to the vehicle type C (see FIG. 5).

As a result of the determination in step S110, if it is determined that the request is not limited to 1, it is determined in step S112 that there is no load. Then, the control unit 44 performs control at the time of abnormality (for example, notification of abnormality without changing the set value).

If it is determined that there is no load on the output port 22 as a result of the determination in step S109, it is determined in step S113 whether or not there is a load only on the output port 23. As a result of the determination in step S113, if it is determined that there is a load only on the output port 23, it is determined in step S114 whether or not there is only request 2. As a result of the determination in step S114, if it is determined that there is only request 2, it is determined in step S115 that "there is a second load 95". That is, it is determined that the second load 95 is connected to the output port 23. Then, the control unit 44 sets a set value corresponding to the vehicle type D (see FIG. 5).

As a result of the determination in step S114, if it is determined that the request 2 is not the only one, it is determined in the step S116 whether or not there is only the request 3. If it is determined that only the request 3 is present as a result of the determination in step S116, it is determined in step S117 that "there is a third load 96". That is, it is determined that the third load 96 is connected to the output port 23. Then, the control unit 44 sets a set value corresponding to the vehicle type E (see FIG. 5).

As a result of the determination in step S116, if it is determined that the request 3 is not the only one, it is determined in step S118 that there is no load. Then, the control unit 44 performs control at the time of abnormality (for example, notification of abnormality without changing the set value).

As a result of the determination in step S113, if it is determined that there is no load on the output port 23, it is determined in step S119 that there is no load. That is, it is determined that none of the loads 94 to 96 is connected (vehicle type F). Then, the setting process is terminated without changing the setting value.

The above-mentioned storage unit stores a program executed by the control unit 44, and this program includes information that defines candidate values for set values for each combination (vehicle type) of loads 94 to 96. .. Based on this information, the control unit 44 sets the set value corresponding to the combination of the loads 94 to 96 connected to the plurality of output ports 22 and 23. As shown in FIG. 5, the set value setting target items include, for example, the number of power storage elements 93, the above-mentioned target voltage value, and the above-mentioned maximum current value.

For the number of power storage elements 93, for example, "3" is set as an initial value. When it is determined in the above-mentioned setting process that both the loads 94 and 95 are connected, the number of the power storage elements 93 is changed to "8", and both the loads 94 and 96 are connected. If it is determined that the device is present, the setting is changed to "9", and if it is determined that only the first load 94 is connected, the setting is changed to "5" and only the second load 95 is connected. If it is determined that the setting is changed to "4", and if it is determined that only the third load 96 is connected, the setting is changed to "5" and the loads 94 to 96. If it is determined that none of the loads are connected, the initial value is left as it is.

By setting the number of power storage elements 93, the control unit 44 can recognize the number of power storage elements 93 corresponding to the combination of loads 94 to 96, and the control related to the number of power storage elements 93 is suitable for the vehicle type. It can be done in an embodiment. For example, the control unit 44 specifies the charging target value of the second power supply unit 92 based on the set number of power storage elements 93. For example, the control unit 44 stores in advance the “charge target value of each power storage element 93” in the storage unit. Then, when the number of power storage elements 93 is set, the number obtained by multiplying the set number of power storage elements 93 by the "charge target value of each power storage element 93" is calculated by "charging the second power supply unit 92". Specify as "target value".

The control unit 44 determines whether or not the charging voltage of the second power supply unit 92 has reached the “charge target value of the second power supply unit 92” while the second power supply unit 92 is being charged. Then, when it is determined that the charging voltage of the second power supply unit 92 has reached the "charging target value of the second power supply unit 92", it is determined that the second power supply unit 92 is fully charged, and the second power supply unit 92 End charging.

Further, as the target voltage value, for example, "7.5V" is set as an initial value. When it is determined in the above setting process that both the loads 94 and 95 are connected, the target voltage value is changed to "10V", and both the loads 94 and 96 are connected. If it is determined, the setting is changed to "11V", and if it is determined that only the first load 94 is connected, the setting is changed to "9V" and only the second load 95 is connected. If it is determined that it is, the setting is changed to "8V", and if it is determined that only the third load 96 is connected, the setting is changed to "8.5V" and the loads 94 to 96. If it is determined that none of them are connected, the initial value is left as it is. The control unit 44 controls the voltage of each of the plurality of sub-side conductive paths 18 so as to be a set target voltage value.

Further, for the maximum current value, for example, "19A" is set as an initial value. If it is determined in the above setting process that both loads 94 and 95 are connected, the maximum current value is changed to "40A", and if both loads 94 and 96 are connected. If it is determined, the setting is changed to "50A", and if it is determined that only the first load 94 is connected, the setting is changed to "30A" and only the second load 95 is connected. If it is determined that the load is set to "20A", the setting is changed to "20A", and if it is determined that only the third load 96 is connected, the setting is changed to "20A". If it is determined that the current is not connected, the default value is used. When the current value of the sub-side conductive path 18 reaches the maximum current value, the control unit 44 performs the above-described protection operation on the sub-side conductive path 18.

As described above, the power supply control device 1 of the present disclosure is set according to the combination of the acquisition unit 45 that acquires the requests from the loads 94 to 96 and the loads 94 to 96 connected to the plurality of output ports 22 and 23. It has a setting unit 46 for setting a value, and a control unit 44 for controlling backup based on the set value set by the setting unit 46. Then, the setting unit 46 sets the setting value based on the setting information in which the candidate value of the setting value is determined for each combination of the request acquired by the acquisition unit 45 and the loads 94 to 96.
In this way, a highly versatile method can be applied to a plurality of types of vehicles in which the combination of the loads 94 to 96 to be mounted is different and the set value needs to be determined according to the combination of the loads 94 to 96 to be mounted. It can be applied appropriately, and since the acquisition unit 45 can acquire the requests from the loads 94 to 96 and set the set value based on the requests acquired in this way, the peripheral circuit of the control unit 44 The above effect can be obtained while suppressing the complication of the above.
For example, when trying to determine the combination of loads by monitoring the output status of each output port, it is conceivable to monitor the current and voltage of each path, but the control unit to monitor is simply configured in this configuration. Requires too many ports. Therefore, the power supply control device 1 of the present disclosure includes a request processing unit 48 in which information corresponding to requests from a plurality of loads 94 to 96 is input to a common input terminal in the control unit 44, so that the load 94 to be connected is provided. Since information specifying the types of ~ 96 can be input via a common route, the number of ports can be reduced.

The power supply control device 1 of the present disclosure includes a voltage / current monitoring unit 42 that detects output states at a plurality of output ports 22 and 23, and the request includes information that identifies the type of the load 94 to 96 that issued the request. The setting unit 46 sets the set value based on the output state detected by the voltage / current monitoring unit 42, the request acquired by the acquisition unit 45, and the setting information.
In this way, it is possible to more reliably confirm which loads 94 to 96 are connected to which output ports 22 and 23. Moreover, the types of loads 94 to 96 can be specified based on the request, and the set value can be set according to the types of loads 94 to 96.

In the power supply control device 1 of the present disclosure, the second power supply unit 92 has a plurality of power storage elements 93, and the setting unit 46 sets the number of power storage elements 93 as a set value.
In this power supply control device 1, the number of power storage elements 93 can be set as a set value corresponding to the combination of loads 94 to 96 connected to the output ports 22 and 23. Therefore, a plurality of types of vehicles in which the number of power storage elements 93 differs depending on the combination of the loads 94 to 96 to be mounted can be appropriately applied as application candidates by a highly versatile method.

In the power supply control device 1 of the present disclosure, the setting unit 46 sets a target value of the charging voltage as a set value, and the control unit 44 performs charging control so that the charging voltage of the second power supply unit 92 becomes the set value. ..
The power supply control device 1 can set a target value of the charging voltage as a set value corresponding to a combination of loads 94 to 96 connected to the output ports 22 and 23. Therefore, a plurality of types of vehicles having different storage capacities of the second power supply unit 92 depending on the combination of the loads 94 to 96 to be mounted can be appropriately applied as application candidates by a highly versatile method, and are applied. In the vehicle, charging control can be performed so that the charging voltage of the second power supply unit 92 becomes an appropriate target value.

The power supply control device 1 of the present disclosure includes a voltage / current monitoring unit 42 that monitors the voltage of the conductive paths 17 and 18 connected between the output ports 22 and 23 and the loads 94 to 96. Then, when each of the plurality of conductive paths 17 and 18 is connected to each of the plurality of output ports 22 and 23, the respective conductive paths 17 and 18 supply electric power to the respective loads 94 to 96, respectively. The voltage / current monitoring unit 42 monitors each voltage of each of the conductive paths 17 and 18. Then, the setting unit 46 sets a target voltage value of the voltage monitored by the voltage / current monitoring unit 42 as a set value. Then, the control unit 44 controls the voltage of each of the conductive paths 17 and 18 to be a set value by turning on and off the switching elements provided in each of the conductive paths 17 and 18.
The power supply control device 1 can set a target voltage value as a set value corresponding to a combination of loads 94 to 96 connected to the output ports 22 and 23. Therefore, a plurality of types of vehicles having different target voltage values depending on the combination of loads 94 to 96 to be mounted can be appropriately applied as application candidates by a highly versatile method, and the applied vehicle has a load. Control can be performed so that the voltage value supplied to 94 to 96 becomes an appropriate voltage value.

The power supply control device 1 of the present disclosure includes a voltage / current monitoring unit 42 that monitors the currents of the conductive paths 17 and 18 connected between the output ports 22 and 23 and the loads 94 to 96. When each of the plurality of conductive paths 17 and 18 is connected to each of the plurality of output ports 22 and 23, the respective conductive paths 17 and 18 supply electric power to the respective loads 94 to 96, respectively. The voltage / current monitoring unit 42 monitors each of the currents of the conductive paths 17 and 18, respectively. Then, the setting unit 46 sets the maximum current value of the current monitored by the voltage / current monitoring unit 42 as a set value. Then, the control unit 44 performs a predetermined protection operation when it is determined that the current values of the conductive paths 17 and 18 have reached the set value.
The power supply control device 1 can set a target current value as a set value corresponding to a combination of loads 94 to 96 connected to the output ports 22 and 23. Therefore, it is possible to appropriately apply a plurality of types of vehicles having different maximum voltage values depending on the combination of loads 94 to 96 to be mounted as application candidates by a highly versatile method, and it is appropriate for the applied vehicle. The protective operation can be performed based on the maximum current value specified in.

[Other Embodiments]
It should be considered that the embodiments disclosed this time are exemplary in all respects and not restrictive.
For example, in the embodiment, it is determined whether the load is connected to any of the output ports 22 and 23 by performing the output determination process, but in another embodiment, the output determination process is not performed. There may be. That is, the control unit 44 may perform the setting process only by specifying which load can be communicated with.
In the embodiment, it is determined whether the load is connected to any of the output ports 22 and 23 by performing the output determination process, but in another embodiment, the output of the load connection destination is determined by another method. You may specify the port. For example, it is configured to be able to detect which output port the load ECU is connected to, and information that can identify the output port of the connection destination may be transmitted from this ECU to the control unit 44.
In the embodiment, the "target value of the charging voltage of the second power supply unit 92" is specified based on the number of power storage elements 93 set in the setting process. However, the "target value of the charging voltage of the second power supply unit 92" is stored in advance in association with the combination of loads 94 to 96, and the "second power supply unit" corresponding to the combination of loads 94 to 96 in the setting process. The target value of the charging voltage of 92 may be set.
In the embodiment, charging control is performed based on the number of power storage elements 93 set in the setting process. Instead of this charge control, or in addition to the charge control, it may be determined whether or not the second power supply unit 92 has a failure based on the number of power storage elements 93 set in the setting process. For example, the "target value of the charging voltage of the second power supply unit 92" is specified based on the number of power storage elements 93, and the charging voltage of the second power supply unit 92 is the target value within a predetermined time after the start of charging. If it does not reach, it may be determined as a failure.
In the embodiment, the case where the load types to be mounted is up to three types has been described, but the types of loads to be mounted may be up to four types or more.
In the embodiment, all the main-side switching elements 25 and 27 are turned on, and it is determined whether or not a current flows through the main-side conductive path 17 to determine whether or not each load 94 to 96 is connected. did. However, another method may be used to determine whether or not each load 94 to 96 is connected. For example, it may be determined whether or not each load 94 to 96 is connected based on the voltage of the main side conductive path 17.

1 ... Power supply control device 3 ... Power supply device 11 ... 1st input side conductive path 12 ... 2nd input side conductive path 13 ... Intermediate conductive path 15 ... Output side conductive path 17, 17A, 17B ... Main side conductive path 18, 18A, 18B ... Sub-side conductive path 19 ... Common path 22, 23 ... Output port 22A, 22B, 23A, 23B ... Output port 24 ... Voltage converter 25, 27 ... Main side switching element 25A, 25B, 27A, 27B ... Main side switching Elements 26, 28 ... Sub-side switching elements 26A, 26B, 28A, 28B ... Sub-side switching elements 30 ... Fuse 32 ... Current detector 40 ... Power supply monitoring unit 42 ... Voltage and current monitoring unit 44 ... Control unit 45 ... Acquisition unit 46 ... Setting unit 48 ... Request processing unit 90 ... 1st power supply unit 92 ... 2nd power supply unit 93 ... Power storage element 94 ... 1st load 95 ... 2nd load 96 ... 3rd load 100 ... Power supply system

Claims (7)

It has a plurality of output ports, a first power supply unit, and at least a second power supply unit that functions as a backup power source when the power supply from the first power supply unit is interrupted, and the first power supply unit has a plurality of. It is used in an in-vehicle power supply system in which power is supplied to each load connected to each of the output ports, and the second power supply unit functions as a backup power supply when the power supply from the first power supply unit is interrupted. It is a power control device
An acquisition unit that acquires a request from the load,
A setting unit that sets a setting value corresponding to a combination of the loads connected to the plurality of output ports, and a setting unit.
A control unit that controls backup based on the set value set by the setting unit,
Have,
The setting unit is an in-vehicle power supply control device that sets the set value based on the setting information that defines the candidate value of the set value for each combination of the request and the load acquired by the acquisition unit. It has a detector that detects the output status of the plurality of output ports.
The request includes information that identifies the type of load that issued the request.
The vehicle-mounted power control device according to claim 1, wherein the setting unit sets the set value based on the output state detected by the detection unit, the request acquired by the acquisition unit, and the setting information. The second power supply unit has a plurality of power storage elements and has a plurality of power storage elements.
The vehicle-mounted power supply control device according to claim 1 or 2, wherein the setting unit sets the number of power storage elements as the set value. The setting unit sets a target value of the charging voltage as the set value, and sets the target value.
The vehicle-mounted power supply control device according to claim 1 or 2, wherein the control unit performs charge control so that the charging voltage of the second power supply unit becomes the set value. A voltage monitoring unit for monitoring the voltage of the conductive path connected between the output port and the load is provided.
When each of the plurality of conductive paths is connected to each of the plurality of output ports, each of the conductive paths serves as a path for supplying electric power to each of the loads, and each of the voltage monitoring units serves as a path for supplying power to each of the loads. Monitor each voltage of the conductive path of
The setting unit sets a target voltage value of the voltage monitored by the voltage monitoring unit as the set value.
The vehicle-mounted device according to claim 1 or 2, wherein the control unit controls the voltage of each of the conductive paths to be the set value by turning on and off switching elements provided in each of the conductive paths. Power control device for. A current monitoring unit for monitoring the current of the conductive path connected between the output port and the load is provided.
When each of the plurality of conductive paths is connected to each of the plurality of output ports, each of the conductive paths serves as a path for supplying electric power to each of the loads, and each of the current monitoring units serves as a path for supplying power to each of the loads. Monitor each current in the conductive path of
The setting unit sets the maximum current value of the current monitored by the current monitoring unit as the set value.
The vehicle-mounted power supply control device according to claim 1 or 2, wherein the control unit performs a predetermined protection operation when it is determined that the current value of the conductive path has reached the set value. With the second power supply unit
The vehicle-mounted power supply control device according to any one of claims 1 to 6.
In-vehicle power supply equipped with.

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