JP7053292B2 - DC / DC converter - Google Patents

Description

The present invention relates to a DC / DC converter, and more particularly to a starting voltage generation circuit of a control circuit that controls the operation of a DC / DC converter having a wide input voltage range.

In information communication equipment, a power supply system that supplies a large current at a low voltage is required in order to support high-speed and large-capacity data processing, and in order to meet such a demand, a distributed power supply system having an intermediate bus configuration is required. Widely adopted.

As an example of this type of power supply system, AC power supplied from a commercial AC line is converted into DC power and distributed to each device, and the DC power is intermediated in each device by an isolated DC / DC converter. There is a system that steps down to the bus voltage and supplies it to each board, and further steps down the intermediate bus voltage to the operating voltage of each load in the vicinity of each load on each board.

The voltage range of the DC power supply of these distributed power supply systems has various standards and covers a wide range. Further, since the current that can be supplied by the converter is limited, the intermediate bus voltage can be set high when the power consumption is relatively high, and the intermediate bus voltage can be set low when the power consumption is low. Therefore, when a large current needs to be supplied at a very low operating voltage to drive a load, a system is adopted in which the step-down is distributed in two stages from a high intermediate bus voltage to a low intermediate bus voltage. In some cases.

As described above, in order to support a wide range of power supply systems in which various DC voltages are set, a DC / DC converter that can operate over a wide input voltage range is required. Generally, a DC / DC converter is equipped with a control circuit for controlling its operation, and when it is started, the control circuit is started first, and then the control circuit starts the converter and operates. It is a mechanism to make it.

However, if the control circuit itself has an operable voltage range and the input voltage range of the DC / DC converter itself includes a voltage range lower than the operating voltage range of the control circuit, the low voltage is externally applied. When supplied, it is necessary to boost the voltage to at least the lower limit of the operating voltage range of the control circuit.

In general, it is difficult for a booster circuit to boost the input voltage slightly, so the input voltage is once stepped down to a voltage sufficiently lower than the lower limit of the operating voltage of the control circuit, and then the control circuit is re-introduced. It is necessary to boost the voltage to the operating voltage. On the other hand, when the input voltage is within the operating voltage range of the control circuit, it is only necessary to directly supply the input voltage.

Therefore, regardless of the input voltage input to the DC / DC converter, if the configuration is such that the booster circuit is always passed, a sufficiently high input voltage within the operating voltage range of the control circuit is set to be higher than the lower limit of the operating voltage range. Since the voltage is stepped down to a sufficiently low voltage and then stepped up again, excessive power is consumed and the loss becomes large. In addition, since the loss is converted into heat and raises the temperature during operation of the converter, it is necessary to install a function for suppressing an excessive temperature rise, which increases the manufacturing cost.

Further, it is possible to add a further converter capable of outputting the operating voltage of the control circuit over the entire wide input voltage range of the DC / DC converter. However, a converter that can operate in such a wide input voltage range will eventually have a large-scale configuration including an isolation transformer and a buck-boost circuit, and the increase in mounting area and the increase in manufacturing cost are remarkable, which is not realistic.

The present invention has been made in view of such a situation, and an object of the present invention is to supply a DC / DC converter having a wide input voltage range with low loss and low cost.

The DC / DC converter according to the first aspect of the present invention has an input terminal to which an input voltage is applied, a voltage generation circuit to which the input voltage is supplied to output a start-up voltage, and a start-up voltage to which the start-up voltage is supplied. The voltage generation circuit comprises a control circuit that outputs a control signal, a voltage conversion circuit that receives the control signal and operates, transforms the supplied input voltage, and outputs an output voltage. A first path connecting the input terminal and the rectifying circuit, a second path connecting the input terminal and the rectifying circuit and connected in parallel with the first path, and a rectifying circuit. It has a constant voltage circuit connected in series with the second path, to which the input voltage is supplied and supplies a constant voltage to the rectifier circuit, and the rectifier circuit is supplied with the input voltage and the constant voltage. Then, the starting voltage is supplied to the control circuit.

According to the second aspect of the present invention, in the first aspect, the constant voltage circuit includes a step-down circuit to which the input voltage is supplied to output a step-down voltage and the constant voltage to which the step-down voltage is supplied. Includes a booster circuit that outputs.

According to the third aspect of the present invention, the rectifier circuit comprises a diode OR circuit having the input voltage and the constant voltage as inputs.

According to the fourth aspect of the present invention, in any one of the first aspect to the third aspect, the rectifier circuit has a voltage higher than the input voltage and the constant voltage. Is output as the control signal.

According to the present invention, when an input voltage lower than the operating voltage range of the control circuit is supplied, the starting voltage boosted to the operating voltage range is controlled through a path in which the voltage is stepped down to a sufficiently low voltage and then boosted again. When the input voltage supplied to the circuit and within the operating voltage range of the control circuit is supplied, the supplied input voltage is directly supplied to the control circuit through another path. As a result, the loss due to the booster circuit is minimized, and excessive temperature rise suppression measures are not required. Therefore, it is possible to achieve the effect of supplying a DC / DC converter having a wide input voltage range with low loss and low cost. can.

The block diagram which concerns on embodiment of this invention. Block diagram of the voltage generation circuit according to the embodiment of the present invention The circuit diagram of the rectifier circuit which concerns on embodiment of this invention. A detailed block diagram according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram according to an embodiment of the present invention. The DC / DC converter 1 includes a voltage generation circuit 2, a control circuit 4, and a voltage conversion circuit 6.

The DC / DC converter 1 includes an input terminal (+ side) 11a to which an input voltage (+ side) is input and an input terminal (-side) 11b to which an input voltage (+ side) is input. Then, an input voltage Vin, which is the difference between the input voltage (+ side) and the input voltage (-side), is applied between the input terminals 11, and the output terminal (+ side) 61a and the output terminal (-side) 61b An output voltage Vout obtained by transforming the input voltage Vin is output to the output terminal 61 between the two.

The input voltage (+ side) is supplied to the voltage generation circuit 2 and the voltage conversion circuit 6 through the input voltage (+ side) supply line 13, and the input voltage (-side) is a voltage through the input voltage (-side) supply line 14. It is supplied to the generation circuit 2, the control circuit 4, and the voltage conversion circuit 6.

The voltage generation circuit 2 uses the input input voltage Vin to generate a starting voltage V1 for starting the control circuit 4, and supplies the starting voltage V1 to the control circuit 4 through the starting voltage supply line 15. The control circuit 4 is started by the starting voltage V1 supplied from the voltage generation circuit 2, and outputs a control signal to the voltage conversion circuit 6 via the control signal supply line 16. Then, the voltage conversion circuit 6 receives the control signal and operates, transforms the input voltage Vin directly supplied from the input voltage (+ side) supply line 13, and has a desired output voltage Vout between the output terminals 61. Is output.

FIG. 2 is a block diagram showing the configuration of the voltage generation circuit 2. The voltage generation circuit 2 has a rectifier circuit 25, a first path 7 connecting the input terminal (+ side) 11a and the rectifier circuit 25, and an input terminal (+ side) connected in parallel with the first path 7. It has a second path 8 connecting the 11a and the rectifier circuit 25. Here, the first path 7 is a path for directly supplying the input voltage Vin to the rectifier circuit 25 through the input voltage (+ side) supply line 13. Further, in the second path 8, the constant voltage circuit 21 is connected in series between the input terminal (+ side) 11a and the rectifier circuit 25.

An input voltage Vin is applied to the constant voltage circuit 21, and a constant voltage V12 is supplied to the rectifier circuit 25 through the constant voltage supply line 18. However, it is difficult for a voltage conversion circuit such as the constant voltage circuit 21 to generate a target output voltage when the value of the input voltage Vin is too close to the value of the constant voltage V12 which is the target value of the output. .. Therefore, it is common to once generate a reference voltage sufficiently lower than the constant voltage V12 which is the target value of the output, and boost the reference voltage to obtain the constant voltage V12 which is the target value.

Therefore, the constant voltage circuit 21 is composed of two circuit blocks, a step-down circuit 22 and a step-up circuit 23. The step-down circuit 22 and the step-up circuit 23 are each connected in series on the path of the second path 8. In the operation, first, the input voltage Vin is supplied to the step-down circuit 22, and the step-down circuit 22 once steps down the input voltage Vin to the step-down voltage V11 which is the reference voltage. Next, the step-down voltage V11 stepped down is supplied to the step-up circuit 23, and the step-up voltage V11 is stepped up to a constant voltage V12 and output to the constant voltage supply line 18. For example, since the booster circuit 23 can operate efficiently by boosting the input voltage to about 2 to 3 times, the step-down voltage V11 can be set to a value of 1/2 to 1/3 of the constant voltage V12. preferable.

As shown in FIG. 4, the step-down circuit 22 may be configured as a low voltage stabilizing circuit 22b including, for example, a low voltage regulator 22a, a transistor Q0, and a resistance element R0, and further, a resistance element R1. , R2 may have a voltage adjusting circuit 22c. Further, the booster circuit 23 may use, for example, a small DC / DC converter circuit.

FIG. 3 shows a circuit diagram of the rectifier circuit 25. The rectifier circuit 25 is a diode including a first rectifier element 27 for enabling the input voltage Vin to be output from the rectifier circuit 25 and a second rectifier element 28 for enabling the constant voltage V12 to be output from the rectifier circuit 25. It is composed of an OR circuit. The output of the rectifier circuit 25 is the starting voltage V1 and is supplied to the starting voltage supply line 15.

The rectifier circuit 25 outputs the higher voltage from the supplied input voltage Vin and the constant voltage V12 to the starting voltage supply line 15 as the starting voltage V1. Here, when the constant voltage V1 is higher than the input voltage Vin, the first rectifying element 27 prevents the backflow of current from the starting voltage supply line 15 to the input terminal (+ side) 11a, and the constant voltage. When the input voltage Vin is higher than V1, the second rectifying element 28 prevents the backflow of current from the starting voltage supply line 15 to the booster circuit 23.

The control circuit 4 may include an internal regulator 41, a control unit 42, and a driver 43. The control circuit 4 can be started, for example, in a starting voltage in the voltage range VL to VH. Here, when the voltage range from VL to VH is relatively wide, the starting voltage may be stepped down to the internal operating voltage by the internal regulator 41 to drive the control unit 42 (FIG. 4).

When the input voltage Vin applied to the input terminal 11 of the DC / DC converter 1 is lower than VL, the input voltage Vin is boosted to VL by the constant voltage circuit 21 on the path of the second path 8. , Can be supplied to the control circuit 4 through the rectifier circuit 25 and the starting voltage supply line 15. When the input voltage Vin is in the range of VL to VH, the input voltage Vin is directly supplied to the control circuit 4 through the first path 7.

As shown in FIG. 4, the voltage conversion circuit 6 may be, for example, a power converter having a half-bridge configuration and driving an isolation transformer by a push-pull method.

At this time, the control circuit 4 sends a control signal for driving each gate terminal of the high-side and low-side transistors Q1 and the transistor Q2 in the half-bridge configuration via the driver 43 to each of the control signal supply lines 16 (control signal supply). It is supplied to the transistor Q1 and the transistor Q2 via the wires 16a and 16b). Further, from the control unit 42 of the control circuit 4, a control signal for push-pull operation of each of the switching transistors Q3 and Q4 is transmitted to the switching transistors Q3 and the switching transistors Q3 via the control signal supply lines 16 (control signal supply lines 16c and 16d), respectively. We are supplying to Q4.

The voltage conversion circuit 6 includes an isolation transformer T. Further, the transistor Q1 and the transistor Q2 connected in series are driven by the control signal supplied via the driver 43 of the control circuit 4, and the output of the intermediate contact thereof is supplied to the primary side of the isolation transformer T. Further, the push side coil and the pull side coil on the primary side of the isolation transformer T are alternately driven by the control signal directly supplied from the control unit 42 of the control circuit 4. Here, the control signal supplied to the switching transistors Q3 and Q4 is synchronized with the control signal supplied to the transistor Q1 and the transistor Q2. The operating current of the primary coil of the isolation transformer T is converted into the current of the corresponding secondary coil, and the input voltage Vin is output as the output voltage Vout between the output terminals 61. The circuit configuration of the voltage conversion circuit 6 is not limited to the method described in this embodiment, and various converter circuit methods can be applied.

1 DC / DC converter 2 Voltage generation circuit 4 Control circuit 6 Voltage conversion circuit 7 1st path 8 2nd path 11 Between input terminals 11a Input terminal (+ side)
11b Input terminal (-side)
13 Input voltage (+ side) supply line 14 Input voltage (-side) supply line 15 Starting voltage supply line 16, 16a, 16b, 16c, 16d Control signal supply line 17 Step-down voltage supply line 18 Constant voltage supply line 21 Constant voltage circuit 22 Step-down circuit 22a Low voltage regulator 22b Low voltage stabilization circuit 22c Voltage adjustment circuit 23 Boost circuit 25 Rectification circuit 27 First rectifier element 28 Second rectifier element 41 Internal regulator 42 Control unit 43 Driver 61 Between output terminals 61a Output terminal (+ Side)
61b output terminal (-side)
Vin input voltage V1 start-up voltage V11 step-down voltage V12 constant voltage Vout output voltage

Claims (4)

The input terminal to which the input voltage is applied and
A voltage generation circuit to which the input voltage is supplied and outputs a starting voltage,
A control circuit that is supplied with the start-up voltage, starts up, and outputs a control signal.
It is provided with a voltage conversion circuit that receives the control signal, operates, transforms the supplied input voltage, and outputs the output voltage.
The voltage generation circuit connects the rectifier circuit, the first path connecting the input terminal and the rectifier circuit, the input terminal and the rectifier circuit, and is connected in parallel with the first path. It has a second path and a constant voltage circuit that is connected in series with the second path and is supplied with the input voltage to supply a constant voltage to the rectifier circuit.
The rectifier circuit is a DC / DC converter to which the input voltage and the constant voltage are supplied and the starting voltage is supplied to the control circuit. The DC / according to claim 1, wherein the constant voltage circuit includes a step-down circuit to which the input voltage is supplied and outputs a step-down voltage, and a step-up circuit to which the step-down voltage is supplied and outputs the constant voltage. DC converter. The DC / DC converter according to claim 1 or 2, wherein the rectifier circuit comprises a diode OR circuit having the input voltage and the constant voltage as inputs. The DC / DC converter according to any one of claims 1 to 3, wherein the rectifier circuit outputs the higher voltage from the input voltage and the constant voltage as the starting voltage .

Images