JP2006296049A - Power supply control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce the size, weight and cost of a power supply control device by actuating a DC-DC converter without installing a low-voltage auxiliary battery in addition to a high-voltage battery. <P>SOLUTION: The power supply control device comprises: the high-voltage battery 1; the DC-DC converter 2 that converts a high voltage of the high-voltage battery 1 to a low voltage; and a voltage-dividing circuit 5 that takes out the low voltage from the high-voltage battery 1. The low voltage taken out of the voltage-dividing circuit 5 is fed to a control circuit part 16 of the DC-DC converter 2 to make the DC-DC converter 2 actuated, and after the DC-DC converter 2 is actuated, an output of the DC-DC converter 2 and the control circuit part 16 of the DC-DC converter 2 are connected to each other. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a configuration of a vehicle power supply control device that includes an electric motor and an internal combustion engine as drive sources, and includes a high-voltage power source used for vehicle propulsion and a low-voltage power source used for other applications.

For example, a hybrid vehicle equipped with an electric motor and an internal combustion engine as drive sources includes a high-voltage power source used for vehicle propulsion and a low-voltage power source used for other purposes, and a power control device as shown in FIG. 9 is configured. Has been.
The power supply control device includes a main battery 101 that is a high-voltage power supply, and a DC-DC converter 102 that converts a high voltage of the main battery 101 into a low voltage. The high voltage of the main battery 101 is used for vehicle propulsion, The low voltage output from the DC-DC converter 102 is used as a power source for a low voltage load 105 such as a headlight or an audio device.
In addition to the main battery 101, the power supply control apparatus includes an auxiliary battery 103 for supplying power to the control circuit unit 102a of the DC-DC converter when the DC-DC converter 102 is started. Further, the DC-DC converter 102 includes a switching waveform generation unit 117 that generates a switching waveform of the switching unit 112.
For example, Patent Document 1 discloses a power supply apparatus for a hybrid vehicle including a main battery and an auxiliary battery.

  In many cases, lead-acid batteries are used for the auxiliary battery 103, and by installing double batteries such as the main battery 101 and the auxiliary battery 103, the weight and cost of the entire power supply control device are increased. In addition to causing the increase, a large amount of lead, which is an environmentally hazardous substance, was to be used.

In view of this, a power supply control device has been devised that reduces the weight by omitting the auxiliary battery provided in addition to the main battery.
As a power supply control device that omits the auxiliary battery, for example, as shown in Patent Document 2, a large-capacity DC-DC converter and a small-capacity DC-DC converter are provided, and the required power of a DC load during engine operation or the like is increased. In some cases, a large-capacity DC-DC converter is used when large, and a small-capacity DC-DC converter is used when the required power of the DC load is small when the engine is stopped.
JP 2004-137984 A JP 2001-204137 A

In the case of a power supply control device including a large-capacity DC-DC converter and a small-capacity DC-DC converter, as in the power supply control device described in Patent Document 2, the auxiliary battery can be omitted. Since a plurality of DC-DC converters are required, the power supply control device cannot be sufficiently reduced in size, weight, and cost.
In addition, when the engine is stopped, the small-capacity DC-DC converter is always operated and dark current is supplied. Therefore, when the necessary dark current is large, there is a possibility that the battery of the main battery is increased. .

A power supply control device that solves the above-described problems has the following features.
In other words, the voltage dividing circuit includes a high voltage battery, a DC-DC converter that converts a high voltage of the high voltage battery into a low voltage, and a voltage dividing circuit for taking out the low voltage from the high voltage battery. The low voltage extracted from the circuit is supplied to the control unit of the DC-DC converter so that the DC-DC converter can be started. After the DC-DC converter is started, the output of the DC-DC converter and the DC-DC converter Are connected to the control unit.
This makes it possible to start up the DC-DC converter without providing a separate auxiliary battery for low voltage in addition to the high voltage battery, and sufficiently reduces the size, weight and cost of the power supply control device. Can be aimed at.

According to a second aspect of the present invention, the voltage dividing circuit is provided with a switch for opening and closing the voltage dividing circuit.
As a result, the power supply from the voltage dividing circuit to the control circuit unit is only performed while the voltage dividing circuit is closed by the switch. Therefore, the voltage dividing circuit is stopped when the power supply control device is stopped or after the power supply control device is started. In this way, the resistors, wiring, and other components that make up the voltage divider circuit are smaller and have a lower power type than when the power is always supplied from the voltage divider circuit. It becomes possible to do.

According to a third aspect of the present invention, the voltage dividing circuit is provided with a relay in series with the switch, and the relay opens the voltage dividing circuit after the activation of the DC-DC converter is completed.
As a result, even if the switch is turned on for some reason (operated in the direction to close the voltage dividing circuit), the current does not continue to flow through the voltage dividing circuit, and the fuse provided in the voltage dividing circuit It is possible to prevent the circuit from being cut off or the circuit itself from being burned out.

According to a fourth aspect of the present invention, the output unit of the DC-DC converter includes an output voltage detection unit, and the completion of starting of the DC-DC converter is determined by the detection value of the output voltage detection means.
As a result, when the set voltage is not output from the DC-DC converter for some reason, the output of the DC-DC converter and the control unit of the DC-DC converter are not connected. After the lapse of time, as in the case where the output of the DC-DC converter and the controller of the DC-DC converter are connected, the output voltage from the voltage dividing circuit flows out to the low voltage load side, It is possible to prevent the control of the low-voltage operation device including the DC-DC converter from being stopped.
Therefore, when the set voltage is output from the DC-DC converter, the control circuit unit and the low voltage load can be reliably operated by the output from the DC-DC converter.

  According to the present invention, the DC-DC converter can be started without providing a low voltage auxiliary battery in addition to the high voltage battery, and the power control device can be reduced in size, weight and cost. Can be sufficiently achieved.

  Next, modes for carrying out the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 1, a power supply control device according to the present invention takes out a low voltage from a high voltage battery 1, a DC-DC converter 2 that converts the high voltage of the high voltage battery 1 into a low voltage, and the high voltage battery 1. The voltage dividing circuit 5 is provided.
The DC-DC converter 2 includes an input filter unit 11, a switching unit 12 composed of a MOSFET, a transformer unit 13, and a rectifying / smoothing unit 14, and a high voltage from a high voltage battery passes through the input filter unit 11 and the DC− It is input to the DC converter 2, converted to AC by the switching unit 12, then transformed by the transformer 13, and further rectified and smoothed by the rectifier / smoothing unit 14, so that a DC low voltage is output. Has been.

The low voltage output terminal 2a from the DC-DC converter 2 is connected to a low voltage load 3 such as a light, a wiper, or an audio device.
The DC-DC converter 2 includes a switching waveform generation unit 17 that generates a switching waveform of the switching unit 12 and a control circuit unit 16 that controls the operation of the DC-DC converter 2.

The voltage dividing circuit 5 includes resistors R1, R2, and R3, and the voltage across the resistor R2 is supplied to the control circuit unit 16 of the DC-DC converter 2. In the case of this example, the voltage of the high voltage battery 1 is configured to 288V, and the output voltage from the voltage dividing circuit 5 (the voltage across the resistor R2) is set to 12V.
In addition, the voltage dividing circuit 5 is configured by only the resistors R1, R2, and R3 in this example, but is not limited thereto, and is configured by only passive elements and requires a power source in addition to the high voltage battery 1. Any circuit that does not need to be used.

The control circuit unit 16 is provided with a charging terminal 19 for relief. By connecting an external power source to the charging terminal 19, the high voltage battery 1 is raised and a low voltage is supplied to the control circuit unit 16. Even when it is not performed, the DC-DC converter 2 and the low voltage load 3 can be started up.
Further, the control circuit unit 16 is connected to the output terminal 2a of the DC-DC converter 2, and a second relay 18 is interposed between the control circuit unit 16 and the output terminal 2a.

The procedure from the start of operation of the power supply control device configured as described above to the supply of power to the low voltage load 3 will be described with reference to the flow shown in FIG.
First, when a low voltage (for example, 12 V) from the voltage dividing circuit 5 is input to the control circuit unit 16 (S01), a switching waveform is generated by the switching waveform generation unit 17 under the control of the control circuit unit 16. The switching operation of the switching unit 12 is started by this switching waveform (S02). Further, simultaneously with the start of the switching operation of the switching unit 12, the timer 16a provided in the control circuit unit 16 is started (S03).

When a certain time (for example, 2 seconds) elapses from the start of the timer 16a (S04), the second relay 18 is switched from the open state to the closed state (S05).
When the second relay 18 is switched to the closed state, the low voltage output from the DC-DC converter 2 has reached a set voltage (for example, 12V), and therefore the output from the DC-DC converter 2 is It is supplied to the control circuit unit 16, and a stable power supply cycle such as operation of the DC-DC converter 2 → low voltage power supply to the control circuit unit 16 → operation of the DC-DC converter 2 →. Established (S06).

  In this way, a simple voltage dividing circuit 5 that can be configured with only passive elements is provided, and the low voltage extracted from the voltage dividing circuit 5 is supplied to the control circuit unit 16 of the DC-DC converter 2, and the DC -After the DC converter 2 is activated and the activation of the DC-DC converter 2 is completed, the output of the DC-DC converter 2 and the control circuit unit 16 of the DC-DC converter 2 are connected by the second relay 18 With this configuration, it becomes possible to start the DC-DC converter 2 without providing an auxiliary battery for low voltage in addition to the high voltage battery 1, thereby reducing the size and weight of the power supply control device. In addition, the cost can be sufficiently reduced.

Further, the output from the DC-DC converter 2 to the control circuit unit 16 by switching the second relay 18 from the open state to the closed state may be performed at the following timing.
That is, as shown in FIG. 3, an output voltage detector 21 can be provided at the output portion of the DC-DC converter 2 and the power supply control device can be started up according to the procedure shown in the flow of FIG. 4.

First, when a low voltage (for example, 12 V) from the voltage dividing circuit 5 is input to the control circuit unit 16 (S11), a switching waveform is generated by the switching waveform generation unit 17 under the control of the control circuit unit 16. The switching operation of the switching unit 12 is started by this switching waveform (S12).
Thereafter, the output voltage detector 21 detects the output voltage of the DC-DC converter 2 to determine whether or not the detected output voltage has reached a set voltage (for example, 12V) (S13). If it is determined that the set voltage has been reached, the second relay 18 is switched from the open state to the closed state (S14).

When the second relay 18 is switched to the closed state, the low voltage output from the DC-DC converter 2 that has reached the set voltage is supplied to the control circuit unit 16, and the operation of the DC-DC converter 2 is controlled. A stable power supply cycle such as low voltage power supply to the circuit unit 16 → operation of the DC-DC converter 2 →... Is established (S15).
As described above, the output portion of the DC-DC converter 2 includes the output voltage detector 21, and the output voltage of the DC-DC converter 2 reaches the set voltage and the start-up is completed. Judgment is made based on the detected value.

  For example, as described above, if the set voltage is not output from the DC-DC converter 2 for some reason when the second relay 18 is switched to the closed state after a predetermined time has elapsed from the start of the timer 16a, the voltage dividing circuit The output voltage from 5 may flow out to the low voltage load 3 side, and control of the low voltage operating device including the DC-DC converter 2 may be stopped.

However, in this example, the second relay 18 is switched to the closed state after confirming that the output voltage of the DC-DC converter 2 has reached the set voltage. When the output is not made, the second relay 18 is not closed, and the output voltage from the voltage dividing circuit 5 flows out to the low voltage load 3 side to control the low voltage operation equipment including the DC-DC converter 2. Will never stop.
Therefore, when the set voltage is output from the DC-DC converter 2, the control circuit unit 16 and the low voltage load 3 are reliably operated by the output from the DC-DC converter 2.

Further, when the power supply control device is configured as shown in FIG. 1 or FIG. 3, the voltage dividing circuit 5 is always connected to the high voltage battery 1, so that the power of the high voltage battery 1 is consumed by dark current. Will end up. In particular, when the current flowing to the voltage dividing circuit 5 side is large, there is a risk that the battery of the high-voltage battery 1 will rise.
Furthermore, since the elements such as resistors R1, R2, and R3 constituting the voltage dividing circuit 5 always generate heat when a current flows, it is necessary to provide cooling means or use large components in consideration of heat dissipation. There is.

Therefore, in this power supply control device, it is possible to make the current flow through the voltage dividing circuit 5 only at the time of starting the power supply control device, so that it is possible to omit the cooling means or to use a low-power and small component. I have to.
That is, the power supply control device shown in FIG. 5 displays the voltage divider circuit 5 in the power supply control device shown in FIG. 3 connected to the start switch 23 that opens and closes the voltage divider circuit 5 and the control circuit unit 16. A vessel 24 is further provided.

The start switch 23 is, for example, a monostable button switch with a spring that closes the voltage dividing circuit 5 only during the pushing operation and opens the voltage dividing circuit 5 when the pushing operation is released. .
Moreover, the indicator 24 is comprised by the indicator lamp which switches on / off by control of the control circuit part 16, for example, and it lights when the DC-DC converter 2 starts and the 2nd relay 18 closes.

  In the power supply control device configured as described above, the power supply control device is activated according to the procedure shown in the flow of FIG.

First, when a driver of a vehicle on which the power supply control apparatus is mounted pushes the start switch 23 to start an operation (S21), the voltage dividing circuit 5 is closed and a low voltage (for example, 12V) from the voltage dividing circuit 5 is applied. The data is input to the control circuit unit 16 (S22). When a low voltage is input, a switching waveform is generated in the switching waveform generation unit 17 under the control of the control circuit unit 16, and the switching operation of the switching unit 12 is started (S23).
Thereafter, the output voltage detector 21 detects the output voltage of the DC-DC converter 2 to determine whether or not the detected output voltage has reached a set voltage (for example, 12V) (S24). If it is determined that the set voltage has been reached, the second relay 18 is switched from the open state to the closed state (S25).

When the second relay 18 is connected to the closed state, the low voltage output from the DC-DC converter 2 that has reached the set voltage is supplied to the control circuit unit 16, and the operation of the DC-DC converter 2 → A stable power supply cycle such as low voltage power supply to the control circuit unit 16 → operation of the DC-DC converter 2 →... Is established (S26).
When the power supply cycle is established, the display 24 is turned on under the control of the control circuit unit 16 (S27). The driver confirms that the indicator 24 has been lit, and releases the hand from the start switch 23 that has been pressed since step S21 (S28). When the hand is released from the start switch 23, the voltage dividing circuit 5 is opened, the supply of power from the voltage dividing circuit 5 to the control circuit unit 16 is stopped, and the activation of the power supply control device is completed.

  In this way, the power supply from the voltage dividing circuit 5 to the control circuit unit 16 is from the time when the driver starts pressing the start switch 23 until the start of the power supply control device is completed and the hand is released from the start switch 23 ( For example, when the power supply control device is stopped or after the start-up of the power supply control device is completed, the dark current does not flow through the voltage divider circuit 5 and the resistors constituting the voltage divider circuit 5 are short. Compared to the case where the power supply from the voltage dividing circuit 5 is always performed, it is possible to configure the components R1, R2, R3, wiring, and the like as small and low power types.

Further, in the case of the above-described power supply control device shown in FIG. 5, assuming that the energization time of the voltage dividing circuit 5 (that is, the time during which the operator presses the start switch 23) is short, Parts such as resistors R1, R2, R3 and wiring of the voltage dividing circuit 5 are selected.
Therefore, for example, when the energizing time of the voltage dividing circuit 5 has been energized for a long time or constantly, such as when the driver keeps pressing the start switch 24 even though the indicator 24 is lit, the voltage dividing circuit 5 May overheat, the fuse 28 provided in the voltage dividing circuit 5 may be blown, or the circuit itself may be burned out.

Therefore, the power supply control device can be configured such that the voltage dividing circuit 5 is automatically opened after the start switch 23 is pressed and the DC-DC converter 2 is activated.
The power supply control device shown in FIG. 7 has a first relay 25 that automatically opens the voltage dividing circuit 5 after the DC-DC converter 2 is activated with respect to the voltage dividing circuit 5 in the power supply control device shown in FIG. And more.

The first relay 25 is configured as, for example, a normally-on type relay that closes when not excited and opens when excited.
The first relay 25 is connected to the control circuit unit 16 and is switched between an open state and a closed state under the control of the control circuit unit 16. Specifically, before the start switch 23 is pressed and until the start-up of the DC-DC converter 2 is completed after the start switch 23 is pressed, the circuit is closed in a non-excited state. When the start-up of the DC converter 2 is completed, the DC converter 2 is excited and switched from the closed state to the open state.

  In the power supply control device configured as described above, the power supply control device is activated according to the procedure shown in the flow of FIG.

First, when a driver of a vehicle on which the power supply control apparatus is mounted pushes the start switch 23 to start an operation (S31), the voltage dividing circuit 5 is closed and a low voltage (for example, 12V) from the voltage dividing circuit 5 is applied. The data is input to the control circuit unit 16 (S32). When a low voltage is input, a switching waveform is generated in the switching waveform generation unit 17 under the control of the control circuit unit 16, and the switching operation of the switching unit 12 is started (S33).
Thereafter, the output voltage of the DC-DC converter 2 is detected by the output voltage detector 21, and it is determined whether or not the detected output voltage has reached a set voltage (for example, 12V) (S34). If it is determined that the set voltage has been reached, the second relay 18 is switched from the open state to the closed state (S35).

When the second relay 18 is connected to the closed state, the low voltage output from the DC-DC converter 2 that has reached the set voltage is supplied to the control circuit unit 16, and the operation of the DC-DC converter 2 → A stable power supply cycle such as low voltage power supply to the control circuit unit 16 → operation of the DC-DC converter 2 →... Is established (S36).
When the power supply cycle is established, the display 24 is turned on under the control of the control circuit unit 16 (S37). At the same time, the first relay 25 is excited and opened under the control of the control circuit unit 16. Thereby, the voltage dividing circuit 5 is opened, the energization of the voltage dividing circuit 5 is stopped (S38), and the activation of the power supply control device is completed.
Thereafter, the driver confirms that the display 24 is turned on, and releases the hand from the start switch 23 that has been kept pressed since step S31 (S39).

  As described above, when the start-up of the power supply control device is completed, the configuration is such that the energization of the voltage dividing circuit 5 is automatically stopped, so that even if the start switch 23 is released for some reason, the voltage dividing circuit Current does not continue to flow through the circuit 5, and it is possible to prevent the fuse 28 provided in the voltage dividing circuit 5 from being blown or the circuit itself from being burned out.

It is a circuit diagram which shows the power supply control apparatus concerning this invention. It is a figure which shows the flow at the time of starting of a power supply control apparatus. It is a circuit diagram which shows the 2nd Example of a power supply control apparatus. It is a figure which shows the flow at the time of starting of the power supply control apparatus in FIG. It is a circuit diagram which shows the 3rd Example of a power supply control apparatus. It is a figure which shows the flow at the time of starting of the power supply control apparatus in FIG. It is a circuit diagram which shows the 4th Example of a power supply control apparatus. It is a figure which shows the flow at the time of starting of the power supply control apparatus in FIG. It is a circuit diagram which shows the conventional power supply control apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 High voltage battery 2 DC-DC converter 3 Low voltage load 5 Voltage dividing circuit 16 Control circuit part 18 2nd relay 21 Output voltage detector 23 Start switch 24 Indicator 25 1st relay 28 Fuse

Claims (4)

A high-voltage battery, a DC-DC converter that converts a high voltage of the high-voltage battery into a low voltage, and a voltage dividing circuit for taking out the low voltage from the high-voltage battery,
Supplying the low voltage extracted from the voltage dividing circuit to the control unit of the DC-DC converter, enabling the DC-DC converter to start,
A power supply control device comprising: an output of a DC-DC converter and a control unit of the DC-DC converter connected after completion of starting of the DC-DC converter.   The power supply control device according to claim 1, wherein the voltage dividing circuit is provided with a switch for opening and closing the voltage dividing circuit. The voltage dividing circuit is provided with a relay in series with the switch,
The power supply control device according to claim 2, wherein the relay opens the voltage dividing circuit after the start of the DC-DC converter is completed. 4. The output unit of the DC-DC converter includes an output voltage detection unit, and the start-up completion of the DC-DC converter is determined based on a detection value of an output voltage detection unit. A power supply control device according to claim 1.

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