JP6882900B2 - Power control device, power control system, and power control method - Google Patents

Description

The disclosed embodiments relate to power control devices, power control systems, and power control methods.

Conventionally, there is a device that supplies electric power of an appropriate voltage to an electronic device when the voltage of a battery that supplies electric power to the electronic device drops. For example, Patent Document 1 includes a capacitor charged by a battery that supplies electric power to an electronic device mounted on a vehicle, and is suitable from the capacitor to the electronic device when the voltage of the battery drops due to driving of a cell motor or the like. A voltage guarantee device that supplies voltage power is disclosed.

Japanese Unexamined Patent Publication No. 2012-165518

However, in the conventional voltage guarantee device, when the voltage of the battery to which various electronic devices are connected drops, the power required to guarantee the operation of each electronic device differs depending on the function and role of the electronic device. There may be excess or deficiency in the power supplied to electronic devices.

One aspect of the embodiment is made in view of the above, and is a power supply control device, a power supply control system, which can supply necessary and sufficient electric power to an electronic device when the voltage of the battery drops. And to provide a power control method.

The power supply control device according to one aspect of the embodiment includes a first capacitor and a second capacitor. The first power storage device is charged by a battery that supplies electric power to a plurality of electronic devices, and when the voltage of the battery drops, power is supplied to the plurality of electronic devices in place of the battery. The second capacitor is charged by the battery, has a larger capacity than the first capacitor, and after the power is supplied by the first capacitor, the electric power to the plurality of electronic devices is replaced with the first capacitor. Supply.

The power supply control device, the power supply control system, and the power supply control method according to one aspect of the embodiment can supply necessary and sufficient power to the electronic device when the voltage of the battery drops.

FIG. 1 is an explanatory diagram showing a power supply control method performed by the power supply control device according to the embodiment. FIG. 2 is an explanatory diagram showing an example of the configuration of the source control system according to the embodiment. FIG. 3 is a timing chart showing an example of the operation of the power supply control device according to the embodiment. FIG. 4 is an explanatory diagram showing an example of the configuration of the power supply control system according to the first modification of the embodiment. FIG. 5 is a timing chart showing an example of the operation of the power supply control device according to the embodiment. FIG. 6 is an explanatory diagram showing an example of the configuration of the power supply control system according to the second modification of the embodiment. FIG. 7A is an operation explanatory view of the power supply control device according to the third modification of the embodiment. FIG. 7B is an operation explanatory view of the power supply control device according to the third modification of the embodiment. FIG. 7C is an operation explanatory view of the power supply control device according to the third modification of the embodiment. FIG. 8A is an explanatory diagram showing the operation and effect of the power supply control device according to the third modification of the embodiment. FIG. 8B is an explanatory diagram showing the operation and effect of the power supply control device according to the third modification of the embodiment. FIG. 8C is an explanatory diagram showing the operation and effect of the power supply control device according to the third modification of the embodiment. FIG. 9A is an operation explanatory view of the power supply control device according to the modified example 4 of the embodiment. FIG. 9B is an operation explanatory view of the power supply control device according to the modified example 4 of the embodiment. FIG. 10A is an operation explanatory view of the power supply control device according to the modified example 5 of the embodiment. FIG. 10B is an operation explanatory view of the power supply control device according to the modified example 5 of the embodiment.

Hereinafter, embodiments of the power supply control device, power supply control system, and power supply control method disclosed in the present application will be described in detail with reference to the accompanying drawings. The present invention is not limited to the embodiments shown below.

In the following, an in-vehicle power supply control device for controlling the electric power supplied from a battery mounted in a vehicle to an in-vehicle device which is an example of a plurality of electronic devices will be described as an example. The power supply control device according to the embodiment is not limited to in-vehicle use, and can be applied to any system that supplies electric power from a battery to a plurality of electronic devices.

FIG. 1 is an explanatory diagram showing a power supply control method performed by the power supply control device 1 according to the embodiment. Note that FIG. 1 illustrates the minimum components necessary for explaining the power supply control method performed by the power supply control device 1. A specific configuration example of the power supply control device 1 will be described later with reference to FIG.

As shown in FIG. 1, the power supply control device 1 is a device that receives power input from the battery 20 and supplies power to a plurality of electronic devices 21. The power supply control device 1 includes a first capacitor 2 and a second capacitor 3. The first capacitor 2 and the second capacitor 3 are connected to a power supply line connecting the battery 20 and the electronic device 21, and are charged by the battery 20.

The first capacitor 2 has a smaller capacity than the second capacitor 3, and when the voltage of the battery 20 drops, the first capacitor 2 supplies electric power to a plurality of electronic devices 21 in place of the battery 20. Further, the second capacitor 3 has a larger capacity than the first capacitor 2, and after the power is supplied to the plurality of electronic devices 21 by the first capacitor 2, the plurality of electronic devices 21 replace the first capacitor 2. Power to.

That is, in the power supply control device 1, when the voltage of the battery 20 is maintained at an appropriate voltage and the voltage does not decrease, power is supplied from the battery 20 to the plurality of electronic devices 21 by the path indicated by the thick arrow L1 in FIG. I do. Then, when the voltage of the battery 20 drops, the power supply control device 1 first supplies electric power from the first capacitor 2 to the plurality of electronic devices 21 in place of the battery 20 by the path indicated by the thick arrow L2 in FIG. ..

At this time, when the period during which the voltage of the battery 20 drops is a minute time, the power supply control device 1 does not waste the power charged in the second capacitor 3 and charges the first capacitor 2. Therefore, the operation of the electronic device 21 can be guaranteed. Further, the first capacitor 2 is charged by the battery 20 when the voltage of the battery 20 returns to an appropriate voltage again.

Further, when the voltage of the battery 20 does not return to an appropriate voltage after supplying power from the first capacitor 2 to the plurality of electronic devices 21, the power supply control device 1 follows the path indicated by the thick line arrow L3 in FIG. , Power is supplied from the second capacitor 3 to the plurality of electronic devices 21 in place of the first capacitor 2.

As described above, when the voltage drop period of the battery 20 is a minute time, the power supply control device 1 does not use the electric power charged in the second capacitor 3 and is the minimum required to be charged in the first capacitor 2. The operation of the electronic device 21 can be guaranteed by the electric power of.

Then, the power supply control device 1 is a case where the operation of the electronic device 21 cannot be guaranteed by the electric power charged in the first capacitor 2, that is, only when necessary, the electronic device by the electric power charged in the second capacitor 3. The operation of 21 is guaranteed. As a result, the power supply control device 1 can supply the necessary and sufficient electric power to the plurality of electronic devices 21.

Next, an example of the configuration of the power supply control system 100 including the power supply control device 1 will be described with reference to FIG. FIG. 2 is an explanatory diagram showing an example of the configuration of the power supply control system 100 according to the embodiment.

As shown in FIG. 2, the power supply control system 100 includes a power supply control device 1, an external device 22 which is an example of a plurality of electronic devices, a control device 23, a drive recorder (hereinafter referred to as “DR24”), and an AVN. : Includes Audio Visual Navigation® 25.

In the power supply control device 1, the power input unit is connected to the battery 20, and the power output unit is connected to the external device 22, the control device 23, the DR24, and the AVN25. The electronic device 21 to which the power supply control device 1 supplies electric power is not limited to the external device 22, the control device 23, the DR24, and the AVN25.

The battery 20 is a 12V lead capacitor mounted on a general vehicle. The external device 22 is, for example, a portable terminal device, an audio player, or the like connected to the power supply control device 1 by USB (Universal Serial Bus).

The DR24 includes, for example, a camera that images the front from the vehicle on which the vehicle is mounted, a video recording device that records an image captured by the camera, and the like. For example, the DR 24 constantly records an image while the vehicle is traveling, and each time a new image is recorded, the old image of a predetermined time (for example, several hours) is erased in order.

Further, for example, when an accident occurs, the DR 24 records an image for several seconds before and after the accident (for example, 5 sec to 8 sec), which is a material for investigating the cause of the accident and evidence of the accident. The AVN25 is a device in which a plurality of devices such as an audio device, a television device, a radio device, a video playback device, and a car navigation device are integrated.

The control device 23 includes, for example, a microcomputer having a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), an input / output port, and various circuits. Then, the control device 23 includes an AVN control unit 31 and a DR control unit 32 that function by executing the target detection program stored in the ROM by the CPU using the RAM as a work area.

As shown by the dotted arrow in FIG. 2, the AVN control unit 31 is a processing unit that controls the operation of the AVN 25 by outputting a control signal to the AVN 25. As shown by the dotted arrow in FIG. 2, the DR control unit 32 is a processing unit that controls the operation of the DR 24 by outputting a control signal to the DR 24.

In such a control device 23, for example, during a minute time (for example, 50 msec) in which the starter motor is driven and the engine is cranked, the voltage of the battery 20 drops and the voltage of the supplied electric power is equal to or less than an appropriate voltage. In that case, normal operation control cannot be performed.

Hereinafter, the phenomenon in which the voltage of the battery 20 becomes equal to or lower than the appropriate voltage for a minute period of time is referred to as "instantaneous interruption". The momentary interruption is eliminated after the engine is started, and the voltage of the battery 20 returns to an appropriate voltage.

Further, for example, when a vehicle accident occurs and the battery 20 is disconnected due to the impact and the power supply line is disconnected, the control device 23 can perform normal operation control because the power supply from the battery 20 is cut off. become unable. Hereinafter, the phenomenon in which the power supply from the battery 20 is cut off in this way is referred to as "battery disconnection".

Therefore, for example, when a momentary interruption occurs, the power supply control device 1 supplies electric power of an appropriate voltage to the control device 23 for at least several tens of msec, and resets the AVN 25 to the AVN control unit 31. It is necessary to have the DR control unit 32 perform the reset processing of the DR 24. The reset process here is, for example, a process of holding the state immediately before the occurrence of the momentary interruption in the DR24 or AVN25 in the memory.

Further, the power supply control device 1 supplies power of an appropriate voltage to the control device 23 for at least several seconds even when the battery is removed, and the DR 24 controls the control to continue recording the video. It is necessary to let the unit 32 do it. The external device 22 is a device that does not cause any problem even if the power supply is cut off immediately after the momentary interruption or the battery disconnection occurs.

Therefore, the power supply control device 1 includes a first capacitor 2 charged by the battery 20 and a second capacitor 3 charged by the battery 20 and having a capacity larger than that of the first capacitor 2. Further, the power supply control device 1 includes a first transformer 4, a second transformer 5, a third transformer 6, a fourth transformer 8, a charging circuit 7, a first diode D1, a second diode D2, and a third diode. It is equipped with D3.

Specifically, in the power supply control device 1, the fourth transformer 8 is connected in series between the wiring connected to the battery 20 and the external device 22. The fourth transformer 8 is a step-down DC / DC converter, and steps down 12V, which is the voltage of the battery 20, to 5V and outputs the voltage to the external device 22.

In the power supply control device 1, the third diode D3, the first transformer 4, and the first diode D1 are connected in series between the wiring connected to the battery 20 and the control device 23. In the third diode D3, the anode is connected to the battery 20 and the cathode is connected to the input of the first transformer 4. The third diode D3 functions as a reverse voltage protection element when the voltage of the battery 20 drops.

Further, one electrode of the first capacitor 2 is connected to the wiring connecting the cathode of the third diode D3 and the first transformer 4. The other electrode of the first capacitor 2 is grounded. The first capacitor 2 is, for example, an electrolytic capacitor having a relatively high withstand voltage and a capacity smaller than that of the second capacitor 3, and is charged to 12 V by the battery 20.

The first transformer 4 is, for example, a step-down DC / DC converter, and steps down the output voltage of the first capacitor 2 to 3.3 V, which is an example of the first voltage, and outputs the voltage to the first diode D1. In the first diode D1, the anode is connected to the output of the first transformer 4, and the cathode is connected to the control device 23.

As a result, when, for example, a momentary interruption occurs and the voltage of the battery 20 drops for several tens of msec, the power supply control device 1 replaces the battery 20 with an appropriate voltage from the first capacitor 2 to the control device 23. It can supply power.

The cathode of the first diode D1 is also connected to the DR24. The output of the first transformer 4 is also connected to the AVN25. As a result, the first capacitor 2 can supply electric power having an appropriate voltage to the DR 24 and the AVN 25 for several tens of msec when a momentary interruption occurs.

When the power supply control device 1 needs to supply electric power to another electronic device when a momentary interruption occurs, the power supply control device 1 is provided with a booster circuit in front of the first capacitor 2, and the voltage of the battery 20 is charged by the booster circuit, for example. , 24V may be boosted to charge the first capacitor 2. As a result, the first capacitor 2 can supply electric power to electronic devices other than the external device 22, the control device 23, the DR24, and the AVN25 when a momentary interruption occurs.

Further, in the power supply control device 1, the third transformer 6, the charging circuit 7, the second transformer 5, and the second transformer are connected between the wiring connecting the first capacitor 2 and the first transformer 4 and the DR 24. The diode D2 is connected in series.

Further, one electrode of the second capacitor 3 is connected to the wiring connecting the charging circuit 7 and the second transformer 5. The other electrode of the second capacitor 3 is grounded. The second capacitor 3 is, for example, an electric double layer capacitor having a relatively low withstand voltage and a larger capacity than the first capacitor 2.

The third transformer 6 is, for example, a step-down DC / DC converter, which steps down the output voltage of the first capacitor 2 to 5 V and outputs it to the charging circuit 7. An AVN25 is connected to the wiring connecting the third transformer 6 and the charging circuit 7. As a result, the first capacitor 2 can supply electric power having an appropriate voltage to the AVN 25 via the third transformer 6 for several tens of msec when a momentary interruption occurs.

The charging circuit 7 charges the second capacitor 3 to 5V. The second transformer 5 is a step-down DC / DC converter, and steps down the output voltage of the second capacitor 3 to 3.1 V, which is an example of a second voltage lower than the first voltage, and outputs the output voltage to the second diode D2. ..

In the second diode D2, the anode is connected to the output of the second transformer 5 and the cathode is connected to the DR24. Further, the cathode of the second diode D2 is also connected to the wiring connecting the card of the first diode D1 and the control device 23.

While the power supply control device 1 outputs a voltage of 3.3 V, which is higher than the output voltage of 3.1 V, which is the output voltage of the first diode D1 to the second diode D2, the first diode D1 to the control device 23 and the DR24 Power to. Then, in the power supply control device 1, when the output voltage of the first diode D1 becomes lower than the output voltage of 3.1 V of the second diode D2, the power is supplied from the second diode D2 to the control device 23 and the DR 24.

As a result, when a momentary interruption occurs, the power supply control device 1 powers the control device 23 and the DR 24 from the first capacitor 2 via the first transformer 4 and the first diode D1 for at least several tens of msec. Can be supplied. As a result, the power supply control device 1 can supply the control device 23 with the minimum required power for the reset process.

Further, when the battery is removed, the power supply control device 1 first supplies electric power from the first capacitor 2 to the control device 23 and the DR 24 via the first transformer 4 and the first diode D1 for several tens of msec. Can be supplied. After that, when the discharge of the first capacitor 2 is completed, the power supply control device 1 powers the control device 23 and the DR 24 from the second capacitor 3 via the second transformer 5 and the second diode D2 for at least several seconds. Can be supplied.

As a result, the power supply control device 1 can supply sufficient power to the control device 23 and the DR 24 for continuing the recording of the video by the DR 24 for several seconds after the battery disconnection occurs. Therefore, the power supply control device 1 can supply the necessary and sufficient power to the control device 23 and the DR 24 when the voltage of the battery 20 drops.

In this way, the power supply control device 1 automatically performs after the power supply from the first capacitor 2 is completed by a simple circuit configuration called OR that utilizes the difference in output voltage between the first diode D1 and the second diode D2. The power supply from the second capacitor 3 can be started.

Next, an example of the operation of the power supply control device 1 will be described with reference to FIG. FIG. 3 is a timing chart showing an example of the operation of the power supply control device 1 according to the embodiment. FIG. 3 shows the transition of the supply voltage of the battery 20 in the upper row, the transition of the voltage of the first capacitor 2 in the middle row, and the transition of the power supply voltage to the control device 23 and the DR 24 in the lower row. The horizontal axis shown in FIG. 3 is time.

As shown in FIG. 3, for example, when the ACC (accessory switch) of the vehicle is turned on at time t1, the power control device 1 starts charging the first capacitor 2, and the voltage of the first capacitor 2 is 0V to 12V. Gradually rise to. Along with this, the first transformer 4 is activated, and the feeding voltage to the control device 23 and the DR 24 rises from 0V to 3.3V.

After that, if a momentary interruption occurs at time t2, the supply voltage of the battery 20 drops. At this time, if the first capacitor 2 is not provided, the supply voltage to the control device 23 and the DR 24 decreases as the supply voltage of the battery 20 decreases, as shown by the broken line in the lower part of FIG.

On the other hand, since the power supply control device 1 includes the first capacitor 2, the control device 23 is supplied with the electric power charged in the first capacitor 2 instead of the battery 20 to the control device 23 and the DR 24. And the supply voltage to the DR24 can be maintained at 3.3V. As a result, the power supply control device 1 can supply the control device 23 with the minimum power required for the reset process.

After that, when the momentary interruption is resolved at time t3 before the discharge of the first capacitor 2 is completed, the power supply control device 1 gradually returns the supply voltage of the battery 20 to 12 V, and the first capacitor 2 is accompanied by this. Charging of No. 2 is started, and the voltage of the first capacitor 2 gradually rises to 12V.

After that, when the battery is removed at time 5t, the power supply control device 1 controls the power charged in the first capacitor 2 until the time t6 when the first capacitor 2 is discharged and the voltage of the first capacitor 2 becomes 0V. It supplies to the device 23 and the DR24. As a result, the power supply control device 1 can maintain the supply voltage to the control device 23 and the DR 24 at 3.3 V.

Then, when the voltage of the first capacitor 2 becomes 0 V at time t6, the power supply control device 1 supplies the electric power charged in the second capacitor 3 to the control device 23 and the DR 24 instead of the first capacitor 2. Along with this, the supply voltage to the control device 23 and the DR 24 drops from 3.3 V to 3.1 V, but the power supply control device 1 supplies the control device 23 and the DR 24 from the time t7 to several seconds. The voltage can be maintained at 3.1V.

As a result, the power supply control device 1 can supply sufficient power to the control device 23 and the DR 24 for continuing the recording of the video by the DR 24 for several seconds after the battery disconnection occurs. The power control device 1 can supply necessary and sufficient power to the control device 23 and the DR 24 in the event of a momentary interruption or battery disconnection.

The configuration of the power supply control device 1 shown in FIG. 2 is an example and can be modified in various ways. Next, with reference to FIG. 4, an example of the configuration of the power supply control system 101 including the power supply control device 1a according to the first modification will be described. FIG. 4 is an explanatory diagram showing an example of the configuration of the power supply control system 101 according to the first modification of the embodiment.

As shown in FIG. 4, in the power supply control system 101, the configuration of the power supply control device 1a is different from that of the power supply control device 1 shown in FIG. 2, and other configurations are the same as those shown in FIG. Therefore, here, the difference between the power supply control device 1a according to the first modification and the power supply control device 1 shown in FIG. 2 will be described.

The power supply control device 1a includes a first FET (Field Effect Transistor) tr1 in place of the first diode D1, and a second FET tr2 in place of the second diode D2. The first FET tr1 and the second FET tr2 are P-channel MOS (Metal Oxide Semiconductor) FETs. A diode D4 for reverse voltage protection is connected in parallel to the first FET tr1, and a diode D5 for reverse voltage protection is connected in parallel to the second FET tr2.

The first FET tr1 keeps on for a period when the voltage of the battery 20 is an appropriate voltage. Then, the first FET tr1 is switched from on to off after the voltage of the battery 20 drops and a predetermined time (for example, several tens of msec) elapses.

As a result, the power supply control device 1a passes through the first capacitor 2 to the first transformer 4, the wiring V1, the first FETtr1, and the wiring V2 until the voltage of the battery 20 drops and a predetermined time elapses several tens of msec. , DR24, and AVN25 can be supplied with power having an appropriate voltage.

Further, the second FET tr2 is switched from off to on when the first FET tr1 is switched from on to off. As a result, the power supply control device 1a can supply electric power of an appropriate voltage from the second capacitor 3 to the DR24 and the AVN25 via the wiring V3, the second transformer 5, the wiring V4, the second FETtr2, and the wiring V2. ..

That is, the power supply control device 1a supplies the necessary and sufficient power to the control device 23 and the DR 24 by supplying the same power as the power supply control device 1 shown in FIG. 2 when a momentary interruption or battery disconnection occurs. Can be supplied.

Moreover, the power supply control device 1a improves the power supply efficiency by supplying power to the control device 23 and the DR 24 via the first FET tr1 or the second FET tr2, which has less power loss than the first diode D1 and the second diode D2. be able to.

The power supply control device 1a includes a first voltage detection unit 9, a second voltage detection unit 10, a third FET tr3, and a resistor R in order to realize the power supply operation described above. The third FET tr3 is an N-channel MOSFET. A diode D6 for reverse voltage protection is connected in parallel to the third FET tr3.

The first voltage detection unit 9 is connected to the battery 20 and the second transformer 5, and outputs a start signal EN to the second transformer 5 when the voltage of the battery 20 drops. The second transformer 5 here lowers the output voltage of the second capacitor 3 from 5V to 3.3V, which is the same as the output voltage of the first transformer 4, and outputs the voltage.

The second voltage detection unit 10 is connected to the wiring V4 from which the second transformer 5 outputs electric power, the gate of the first FET tr1, and the gate of the third FET tr3. The source of the third FET tr3 is grounded and the drain is connected to the gate of the second FET tr2. The drain of the third FET tr3 and the source of the second FET tr2 are connected via a resistor R.

The second voltage detection unit 10 detects the output voltage of the wiring V4 from which the second transformer 5 outputs electric power. Then, the second voltage detection unit 10 turns on the first FET tr1 by outputting the low level gate signal G1 during the period when the output voltage of the second transformer 5 is less than a predetermined voltage (for example, 3.3 V). , The third FET tr3 is turned off, and the second FET tr2 is turned off.

Then, when the output voltage of the second transformer 5 reaches 3.3 V, the second voltage detection unit 10 outputs the high level gate signal G1 to turn off the first FET tr1 and turn on the third FET tr3. Then, the second FET tr2 is turned on.

As a result, in the power supply control device 1a, the first capacitor 2 to the first transformer 4, the wiring V1, and the first are until the voltage of the battery 20 drops and the output voltage of the second transformer 5 reaches 3.3 V. Power of an appropriate voltage is supplied to the control device 23 and the DR 24 via the 1FETtr1 and the wiring V2. The power control device 1a can hold the power charged in the second capacitor 3 without using it, for example, when the momentary interruption is resolved during this period.

Then, when the output voltage of the second transformer 5 reaches 3.3 V, the power supply control device 1a passes from the second capacitor 3 via the wiring V3, the second transformer 5, the wiring V4, the second FET tr2, and the wiring V2. Therefore, power of an appropriate voltage can be supplied to the control device 23 and the DR 24.

Therefore, the power supply control device 1a can supply necessary and sufficient power to the control device 23 and the DR 24 in the event of a momentary interruption or battery disconnection, similarly to the power supply control device 1 shown in FIG.

Next, an example of the operation of the power supply control device 1a will be described with reference to FIG. FIG. 5 is a timing chart showing an example of the operation of the power supply control device 1a according to the embodiment. FIG. 5 shows the transition of the supply voltage of the battery 20, the voltage of the first capacitor 2, the wirings V1, V2, V3, V4, the start signal EN, and the gate signal G1 in this order from the upper stage to the lower stage. The horizontal axis shown in FIG. 5 is time.

As shown in FIG. 5, when the ACC of the vehicle is turned on at time t11, the power control device 1a starts charging the first capacitor 2 and the voltage of the first capacitor 2 rises. At this time, the first FET tr1 is on. Therefore, the voltages of the wirings V1 and V2, which are the feeding paths from the first transformer 4 to the control device 23 and the DR 24, increase.

At this time, the second capacitor 3 is also charged by the electric power charged in the first capacitor 2, but the charging voltage of the second capacitor 3 is lower than the charging voltage of the first capacitor 2 in consideration of the withstand voltage. It can be suppressed. Therefore, the voltage of the wiring V3 connected to the output of the second capacitor 3 rises more slowly than the voltage of the first capacitor 2.

After that, if the battery is removed at time t12, the voltage of the battery 20 drops. As a result, the voltage of the start signal EN of the second transformer 5 changes from Low to High, and the voltage of the wiring V4 connected to the output of the second transformer 5 starts to rise. After that, when the voltage of the wiring V4 reaches 3.3V, the voltage of the gate signal G1 changes from Low to High, and accordingly, the first FET tr1 is turned off and the second FET tr2 is turned on.

Therefore, the power control device 1a is the wiring V2 that supplies power to the control device 23 and the DR 24 by the power charged in the first capacitor 2 for a short time (between times t12 and t13) after the battery is removed. The voltage can be maintained at an appropriate voltage.

After that, in the power supply control device 1a, the voltage of the first capacitor 2 drops, becomes equal to or lower than the operating voltage of the first transformer 4 after several tens of msec, and the first transformer 4 stops at time t14. The 1-FET tr1 has already been turned off and the 2nd FET tr2 has been turned on.

Therefore, the power supply control device 1a appropriately adjusts the voltage of the wiring V2 that supplies power to the control device 23 and the DR 24 by the electric power charged in the second capacitor 3 for several seconds from the time t14 to the time t15. Can be maintained at a high voltage.

After time t15, when the voltage of the wiring V3 connected to the output of the second capacitor 3 falls below 3.3V, the voltages of the wirings V2 and V3 gradually decrease. However, the control device 23 can record the video for several seconds from the time t12 when the battery is disconnected to the time t15 when the voltage of the wirings V2 and V3 starts to decrease by the DR24.

Next, with reference to FIG. 6, an example of the configuration of the power supply control system 102 including the power supply control device 1b according to the second modification will be described. FIG. 6 is an explanatory diagram showing an example of the configuration of the power supply control system 102 according to the second modification of the embodiment.

As shown in FIG. 6, in the power supply control system 102, the configuration of the power supply control device 1b is different from that of the power supply control device 1 shown in FIG. 2, and other configurations are the same as those shown in FIG. Therefore, here, the difference between the power supply control device 1b according to the second modification and the power supply control device 1 shown in FIG. 2 will be described.

The power supply control device 1b is different from the power supply control device 1 shown in FIG. 2 in that the voltage detection unit 11, the G sensor 12, the logic circuit 13, the first switch Sw1 and the second switch Sw2 are further provided, and the other configurations are different. , The same configuration as that shown in FIG.

The first switch Sw1 connects the first transformer 4 and the AVN25 in a connectable manner, and is switched on and off according to the control of the logic circuit 13. Further, the second switch Sw2 connects the third transformer 6 and the AVN25 in a connectable manner, and is switched on and off according to the control of the logic circuit 13.

The voltage detection unit 11 is connected to the battery 20 and the logic circuit 13. Then, the voltage detection unit 11 detects the voltage of the battery 20, and when the power supply from the battery 20 is interrupted, outputs a power supply cutoff signal to that effect to the logic circuit 13.

The G sensor 12 is a gyro sensor that detects the acceleration of the power supply control device 1b. When the G sensor 12 detects an acceleration (impact) to the extent that the battery is disconnected, the G sensor 12 outputs a battery disconnection signal indicating that fact to the logic circuit 13.

The logic circuit 13 turns on the first switch Sw1 and the second switch Sw2 during the period when the power supply cutoff signal is not input from the voltage detection unit 11 and the battery disconnection signal is not input from the G sensor 12.

Further, the logic circuit 13 turns off the first switch Sw1 and the second switch Sw2 when the power supply cutoff signal is input from the voltage detection unit 11 or when the battery disconnection signal is input from the G sensor 12.

As a result, the power supply control device 1b mechanically cuts off the power supply of the control device 23 and the AVN 25 from the first capacitor 2 when the battery is removed. As a result, the control device 23 can effectively use the electric power charged in the first capacitor 2 for the reset process of the DR 24 and the AVN 25.

Next, the power supply control device 1c according to the third modification will be described with reference to FIGS. 7A, 7B, 7C, 8A, 8B, and 8C. 7A, 7B, and 7C are operation explanatory views of the power supply control device 1c according to the third modification of the embodiment.

8A, 8B, and 8C are explanatory views showing the operation and effect of the power supply control device 1c according to the third modification of the embodiment. 8A, 8B, and 8C show changes in the output voltage of the first capacitor 2.

The power control device 1c has a configuration related to charging of the first capacitor 2 which is different from that of the power control device 1 shown in FIG. 2, and other configurations are the same as those shown in FIG. Therefore, FIGS. 7A, 7B, and 7C selectively show the configuration related to charging of the first capacitor 2 and the battery 20 and the control device 23 among the configurations included in the power supply control device 1c.

As shown in FIG. 7A, the power supply control device 1c is different from the power supply control device 1 shown in FIG. 2 in that the voltage detection unit 14 and the switch Sw3 are further provided. The switch Sw3 connects the wiring connecting the battery 20 and the first transformer 4 and the first capacitor 2 in a connectable manner, and is switched on and off according to the control of the voltage detection unit 14.

Specifically, as shown in FIG. 7A, the voltage detection unit 14 is connected to the battery 20 to detect the voltage of the battery 20, and outputs a control signal to the switch Sw3 when the voltage of the battery 20 exceeds the threshold value. By doing so, the switch Sw3 is turned on.

As a result, power is supplied from the battery 20 to the first capacitor 2 via the third diode D3 and the switch Sw3, and power is supplied from the battery 20 to the first transformer 4 via the third diode D3.

Then, as shown in FIG. 7B, the voltage detection unit 14 turns off the switch Sw3 by outputting a control signal to the switch Sw3 when the charging of the first capacitor 2 is completed. As a result, the power supply control device 1c can maintain the voltage of the first capacitor 2 at, for example, 12V in a fully charged state until the switch Sw3 is turned on next time. While the switch Sw3 is off, power is supplied from the battery 20 to the first transformer 4 via the third diode D3.

After that, as shown in FIG. 7C, the voltage detection unit 14 turns on the switch Sw3 when the voltage of the battery 20 becomes equal to or less than the threshold value. As a result, the first capacitor 2 can output 12 V of electric power in a fully charged state to the first transformer 4 immediately after the voltage of the battery 20 drops to the threshold value.

Therefore, for example, when there is a desire to lower the threshold value as much as possible, the power control device 1c can normally complete the reset process from the first capacitor 2 to the control device 23 even if a momentary interruption occurs. Can supply as much power as possible.

For example, even if the power supply control device 1c is not provided with the switch Sw3, if the threshold value is 7.5V, the first capacitor 2 normally resets to the control device 23 even if a momentary interruption occurs. Power can be supplied that can complete the process.

Specifically, as shown in FIG. 8A, for example, in the first capacitor 2, when a momentary interruption occurs at time t21, the control device 23 operates normally until the output voltage changes from 12V to the threshold value of 7.5V. Since the control is performed, the output voltage drops sharply during that time.

However, in the first capacitor 2 after that, since the control device 23 performs the reset process with less power consumption than the normal operation control from the time when the output voltage is 7.5 V, until the time t23 when the control device 23 completes the reset process. The minimum required output voltage can be supplied to the control device 23.

However, for example, when the threshold value is lowered to 4.5V, the first capacitor 2 supplies electric power capable of normally completing the reset process from the first capacitor 2 to the control device 23 when a momentary interruption occurs. It can be impossible.

Specifically, as shown in FIG. 8B, in the first capacitor 2, when the control device 23 performs normal operation control until the output voltage changes from 12 V to the threshold value of 4.5 V, and then reset processing is performed. In addition, the discharge may end before the time t23 when the reset process is completed.

Therefore, the power supply control device 1c includes the switch Sw3, and performs the on / off operation of the switch Sw3 shown in FIGS. 7A, 7B, and 7C. As a result, the first capacitor 2 can output 12V of electric power in a fully charged state to the first transformer 4 at time t22 immediately after the output voltage changes from 12V to the threshold value of 4.5V. it can.

Therefore, when there is a desire to lower the threshold value as much as possible, the power supply control device 1c can normally complete the reset process from the first capacitor 2 to the control device 23 even if a momentary interruption occurs. Can be supplied.

Even if the configuration for charging the first capacitor 2 of the power supply control device 1c according to the modification 3 is applied to the power supply control device 1a according to the modification 1 and the power supply control device 1b according to the modification 2, it is a modification. The same effect as that of the power supply control device 1c according to No. 3 can be obtained.

Next, the power supply control device 1d according to the modified example 4 will be described with reference to FIGS. 9A and 9B. 9A and 9B are operation explanatory views of the power supply control device 1d according to the modified example 4 of the embodiment.

The power control device 1d has a configuration related to charging of the first capacitor 2 which is different from that of the power control device 1 shown in FIG. 2, and other configurations are the same as those shown in FIG. Therefore, FIGS. 9A and 9B selectively show the configuration related to charging of the first capacitor 2 and the battery 20 and the control device 23 among the configurations included in the power supply control device 1d.

As shown in FIG. 9A, the power supply control device 1d is different from the power supply control device 1 shown in FIG. 2 in that the voltage detection unit 15 and the FET tr4 are further provided. The FET tr4 is connected in parallel to the third diode D3, and is switched on and off according to the control of the voltage detection unit 15.

Specifically, as shown in FIG. 9A, the voltage detection unit 15 is connected to the battery 20 to detect the voltage of the battery 20, and outputs a control signal to the FET tr4 when the voltage of the battery 20 exceeds the threshold value. By doing so, the FET tr4 is turned on.

As a result, electric power is supplied from the battery 20 to the first capacitor 2 and the first transformer 4 via the FET tr4. At this time, since the FET tr4 has less power loss than the third diode D3, it is possible to output power having a higher voltage to the first capacitor 2 and the first transformer 4 as compared with the case where the FET tr4 passes through the third diode D3. it can. As a result, the first capacitor 2 is charged to a higher voltage than when it is charged by the electric power supplied via the third diode D3.

After that, as shown in FIG. 9B, when the voltage of the battery 20 becomes equal to or lower than the threshold value, the voltage detection unit 15 turns off the FET tr4 by outputting a control signal to the FET tr4. As a result, the first capacitor 2 can supply the first transformer 4 with a higher voltage than when it is charged by the power supplied via the third diode D3. Further, at this time, the FET tr4 is turned off and the third diode D3 functions as a reverse voltage protection element, so that the backflow of the current to the battery 20 can be prevented.

The configuration for charging the first capacitor 2 of the power supply control device 1d according to the modification 4 may be applied to the power supply control device 1a according to the modification 1 and the power supply control device 1b according to the modification 2. The same effect as that of the power supply control device 1d according to No. 4 can be obtained.

Next, the power supply control device 1e according to the modified example 5 will be described with reference to FIGS. 10A and 10B. 10A and 10B are operation explanatory views of the power supply control device 1e according to the modified example 5 of the embodiment.

As shown in FIG. 10A, the power supply control device 1e has a configuration in which the third diode D3 is deleted from the power supply control device 1d shown in FIGS. 9A and 9B.

As shown in FIG. 10A, when the voltage of the battery 20 exceeds the threshold value, the voltage detection unit 15 turns on the FET tr4 by outputting a control signal to the FET tr4. As a result, the FET tr4 can output electric power having a higher voltage to the first capacitor 2 and the first transformer 4 as compared with the case where the third diode D3 is provided. Therefore, the first capacitor 2 is charged to a higher voltage than when the third diode D3 is provided.

After that, as shown in FIG. 10B, when the voltage of the battery 20 becomes equal to or lower than the threshold value, the voltage detection unit 15 turns off the FET tr4 by outputting a control signal to the FET tr4. As a result, the first capacitor 2 can supply electric power having a higher voltage to the first transformer 4 than when the third diode D3 is provided. Further, at this time, since the FET tr4 is turned off, it is possible to prevent the backflow of the current to the battery 20.

The configuration for charging the first capacitor 2 of the power supply control device 1e according to the modification 5 may be applied to the power supply control device 1a according to the modification 1 and the power supply control device 1b according to the modification 2. The same effect as that of the power supply control device 1e according to No. 5 can be obtained. Moreover, since the power supply control device 1e can eliminate the third diode D3, it is possible to simplify the manufacturing process and reduce the manufacturing cost.

Further effects and variations can be easily derived by those skilled in the art. For this reason, the broader aspects of the invention are not limited to the particular details and representative embodiments expressed and described as described above. Therefore, various modifications can be made without departing from the spirit or scope of the general concept of the invention as defined by the appended claims and their equivalents.

1, 1a, 1b, 1c, 1d, 1e Power supply control device 2 1st capacitor 3 2nd capacitor 4 1st transformer 5 2nd transformer 6 3rd transformer 7 Charging circuit 8 4th transformer 9 1st voltage detection Unit 10 2nd voltage detector 12 G sensor 13 Logic circuit 11, 14, 15 Voltage detector 20 Battery 21 Electronic equipment 22 External device 23 Control device 31 AVN control unit 32 DR control unit 100, 101, 102 Power supply control system D1 1st 1 diode D2 2nd diode D3 3rd diode D4, D5, D6 diode EN start signal G1 gate signal R resistance Sw1 1st switch Sw2 2nd switch Sw3 switch tr1 1st FET
tr2 2nd FET
tr3 3rd FET
tr4 FET

Claims (7)

A first power storage device that is charged by a battery that supplies electric power to a plurality of electronic devices and supplies electric power to the plurality of electronic devices in place of the battery when the voltage of the battery drops.
A second battery that is charged by the battery and has a larger capacity than the first capacitor, and after the power is supplied by the first capacitor, power is supplied to the plurality of electronic devices in place of the first capacitor. and a capacitor,
A first transformer that transforms the output voltage of the first capacitor into a first voltage and outputs it,
A first diode whose anode is connected to the power output section of the first transformer and whose cathode is connected to the power input section of the plurality of electronic devices.
A second transformer that transforms the output voltage of the second capacitor to a second voltage lower than the first voltage and outputs it.
A power source having an anode connected to a power output unit of the second transformer and a second diode having a cathode connected to a wiring connecting the cathode of the first diode and the plurality of electronic devices. Control device. A diode whose anode is connected to the battery and whose cathode is connected to the first capacitor.
The wiring for connecting the battery and the first transformer and the first capacitor are connected in a connectable manner, and when the voltage of the battery exceeds the threshold value, the battery is turned on to charge the first capacitor, and the first capacitor is charged . (1 ) The power supply control device according to claim 1, further comprising a switch that turns off when the charging of the capacitor is completed and then turns on when the voltage of the battery falls below the threshold value. A diode whose anode is connected to the battery and whose cathode is connected to the first capacitor.
A claim further comprising an FET, which is connected in parallel to the diode, is turned on for a period of time when the output voltage of the battery exceeds the threshold value, and is turned off when the voltage of the battery falls below the threshold value. power control device according to 1. The battery is connected to the first capacitor and the first transformer in a connectable manner, and is turned on for a period when the output voltage of the battery exceeds the threshold value and turned off when the voltage of the battery falls below the threshold value. The power supply control device according to claim 1 , further comprising a switch that becomes. If the power supply from said battery is interrupted, as claimed in claim 1-4, characterized by further comprising a switch for interrupting the power supply to the electronic device except the drive recorder that is part of the plurality of electronic devices The power control device according to any one. With multiple electronics, including car navigation devices and drive recorders,
A first power storage device that is charged by a battery that supplies electric power to the plurality of electronic devices and supplies electric power to the plurality of electronic devices in place of the battery when the voltage of the battery drops.
After being charged by the battery and having a capacity larger than that of the first capacitor and the power is supplied by the first capacitor, the drive recorder is supplied to the drive recorder among the plurality of electronic devices in place of the first capacitor. A power supply control system characterized by being provided with a second capacitor that supplies electric power. A step of supplying power to the plurality of electronic devices in place of the battery when the voltage of the battery drops, the first storage battery charged by the battery that supplies power to the plurality of electronic devices.
The second capacitor, which is charged by the battery and has a capacity larger than that of the first capacitor, supplies power to the plurality of electronic devices in place of the first capacitor after the power is supplied by the first capacitor. And the process of doing
The first transformer transforms the output voltage of the first storage device into the first voltage, the anode is connected to the power output section of the first transformer, and the cathode is connected to the power input section of the plurality of electronic devices. The process of outputting to the plurality of electronic devices via the first diode
The second transformer transforms the output voltage of the second storage device to a second voltage lower than the first voltage, and an anode is connected to the power output portion of the second transformer to form a cathode of the first diode. A power supply control method comprising a step of outputting to the plurality of electronic devices via a second diode in which a cathode is connected to a wiring connecting the plurality of electronic devices.

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