JP2008148514A - Dcdc converter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an inexpensive DCDC converter circuit that has a function for highly efficiently supplying a plurality of positive voltages and/or a plurality of negative voltages by using a single inductor. <P>SOLUTION: A first terminal of an inductor 12 is connected to a DC power supply terminal 11. A second terminal of the inductor is connected to a drain terminal of an N-type MOSFET 31. The second terminal of the inductor is connected to an anode terminal of a first rectifier diode 41 and to a first output terminal 21. A source terminal of the N-type MOSFET is connected to a ground (GND). All anode terminals of n rectifier diodes are connected to the second terminal of the inductor. Each cathode terminal of n-1 rectifier diodes other than the first rectifier diode in the n rectifier diodes is respectively connected to a source terminal of each of n-1 separate P-type MOSFETs while being respectively connected to each of n-1 separate output terminals. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a DCDC converter circuit, and more particularly to a DCDC converter circuit that uses a single inductor to provide a plurality of positive and / or negative voltages.

  Battery-powered electronic devices such as laptop computers, cell phones, LCD devices, and computers require conversion from the voltage from the battery that powers the device to the voltage required by the device's circuitry. Various DCDC converters used for such voltage conversion are known.

Among DC / DC converters, DC / DC converters using inductors have been widely used because of their characteristics of being able to output various output pressures with high efficiency. In a DCDC converter using an inductor, conventionally, in order to obtain a plurality of same-polarity voltages, 1) the highest voltage in the system is obtained by the DCDC converter, and then the voltage is obtained at a desired low value by the LDO regulator, or 2 ) The same number of DCDC converters as the number of voltages used in the system were provided, and each voltage was obtained individually.
JP 2006-254700 A

  However, in the method 1), the power loss caused by the regulator is unavoidable, so that the power efficiency is reduced. Further, in the above method 2), the problem of the reduction in power efficiency of 1) is reduced. However, since a plurality of inductors are used, the cost is high.

  An object of the present invention is to provide a low-cost circuit having a function of supplying a plurality of positive voltages and / or negative voltages with high efficiency by using a single inductor.

The DCDC converter of the present invention can obtain a plurality of positive voltages and / or negative voltages by using a single conductor by adopting the following configuration. Further, by using the DCDC converter having the configuration of the present invention for a flat panel display, particularly a liquid crystal display device (LCD), the price of the LCD or the like can be reduced.
(1) At least one inductor, at least one N-type MOSFET, n rectifier diodes, n-1 P-type MOSFETs, n ripple removing capacitors, n control circuits, and n outputs A first terminal of the inductor is connected to a DC power supply terminal, a second terminal of the inductor is connected to a drain terminal of the N-type MOSFET, The cathode of the first rectifier diode among the n rectifier diodes is connected to the first capacitor of the capacitor for removing replies and the first output terminal of the n output terminals, and the N The source terminal of the MOSFET is connected to the ground (GND) terminal, and all the anode terminals of the n rectifier diodes are connected to the second terminal of the inductor. Of the rectifier diodes, the cathode terminals of n−1 rectifier diodes other than the first rectifier diode are respectively connected to the source terminals of the separate n−1 P-type MOSFETs. Each drain terminal of the n-type MOSFET is connected to n−1 ripple removing capacitors other than the first capacitor and n−1 output terminals other than the first output terminal, respectively. The terminal is connected to the output terminal of one of the n control circuits using the DC power supply terminal voltage as a power source, and the gate terminals of the n-1 P-type MOSFETs are connected to the first output. In the DCDC converter circuit connected to the output terminals of the n-1 control circuits that use the terminal voltage as a power source, the voltage of the first output terminal is the other output terminal. Higher than the voltage, and by the voltage of the n output terminals are all differently controlled, DCDC converter circuit for outputting the n different DC voltages.
(2) The DCDC converter circuit according to (1), wherein power is supplied to the n ripple removing capacitors in time division.
(3) The DCDC converter circuit according to (1) or (2), wherein n is 2 and outputs two different DC voltages.
(4) In addition, a second P-type MOSFET is connected between the DC power supply terminal and the first terminal of the inductor, and m rectifier diodes, m−1 N-type MOSFETs, and m ripple removal. A capacitor, m−1 control circuits, and m output terminals (where m represents an integer of 2 or more), and the anode of the first rectifier diode among the rectifier diodes of the m diodes is the A first capacitor of m ripple removing capacitors and a first output terminal of the m output terminals are connected, and all of the cathode terminals of the m rectifier diodes are connected to the first of the inductors. The anode terminals of m−1 rectifying diodes other than the first diode among the m diodes are connected to the terminals, respectively, and the source terminals of the m−1 N-type MOSFETs are respectively separate. And each of the m-1 N-type MOSFETs has drain terminals of m-1 ripple removing capacitors other than the first capacitor and m-1 output terminals other than the first output terminal. And the gate terminals of the (m−1) N-type MOSFETs are respectively connected to the output terminals of (m−1) control circuits that use the voltage of the first output terminal as a power source. The voltage of one output terminal is higher than the voltages of the other m-1 output terminals, and the voltages of the m output terminals are all controlled to be different, and m different negative DC voltages are output. The DCDC converter circuit according to any one of (1) to (3) above.
(5) One inductor, at least one P-type MOSFET, m rectifier diodes, m-1 N-type MOSFET, m ripple removing capacitors, m control circuits, and m output terminals (Where m represents an integer of 2 or more), a source terminal of the P-type MOSFET is connected to a DC power supply terminal, a first terminal of the inductor is connected to a drain terminal of the P-type MOSFET, A second terminal of the inductor is connected to ground (GND), and an anode of the first rectifier diode of the m rectifier diodes is a first capacitor of the ripple removing capacitors and the m outputs. And the cathode terminals of the m rectifier diodes are all connected to the first terminal of the inductor, and the m rectifier diodes are connected to a first output terminal of the terminals. The anode terminals of m-1 rectifier diodes other than the first rectifier diode in the node are respectively connected to the source terminals of the m-1 N-type MOSFETs, and the m-1 N-type MOSFETs are connected. Each drain terminal of the MOSFET is connected to m-1 ripple removing capacitors other than the first capacitor and m-1 output terminals other than the first output terminal, respectively, and the gate terminal of the P-type MOSFET Is connected to the output terminal of one of the m control circuits using the DC power supply terminal voltage as a power source, and the gate terminals of the m-1 N-type MOSFETs are connected to the first output terminal. In the DCDC converter circuit respectively connected to the output terminals of m-1 control circuits that use the voltage of the power supply as a power source, the voltage of the first output terminal is lower than the other output terminal voltages. And wherein m by the voltage of the number of output terminals are all differently controlled, DCDC converter circuit for outputting m different negative DC voltage.
(6) The DCDC converter circuit according to (4) or (5), wherein the negative voltage is supplied to the m ripple removing capacitors in a time-sharing manner.
(7) A flat panel display device using the DCDC converter circuit according to any one of (1) to (6).

  The present invention can provide a low-cost DCDC converter circuit having a function of supplying a plurality of positive voltages and / or negative voltages with high efficiency by using a single inductor. Further, by using the DCDC converter having the configuration of the present invention for a flat panel display, particularly a liquid crystal display device (LCD), the price of the LCD or the like can be reduced.

  Specific examples of the DCDC converter of the present invention will be described in detail by the following examples. The present invention is not limited to these examples.

FIG. 1 is a circuit diagram of a DCDC converter according to a first embodiment of the present invention. As shown in FIG. 1, the DCDC converter according to the first embodiment includes an inductor 12 connected to a DC power supply 11, switching MOSFETs 31 and 32, rectifying Schottky barrier diodes 41 and 42, and output voltage ripple reducing capacitors 61 and 62. , Comprising control circuits 51 and 52 for controlling the switching MOSFET, an output voltage error amplifier (not shown), and output terminals 21 and 22.
According to the circuit configuration as described above, a plurality of positive voltages can be obtained from a single DC power supply using a single inductor.

  The DCDC circuit supplies power from the direct current 11 to the output terminals 21 and 22 that alternately output power in a time-sharing manner. At this time, if the output voltage is insufficient with respect to the target value, the error amplifier The control signal (not shown) is transmitted to the control circuits 51 and 52 to supply power. In addition, when the output voltage exceeds the target value, the driving of the switching MOSFET is stopped by a control signal from the air lamp. Moreover, since the voltage control operation is individually performed on each output in a time-sharing manner, power can be supplied to only one side. The control request of this circuit for the output voltage is 1) power supply to the output terminals 21 and 22, 2) power supply only to the output terminal 21, 3) power supply only to the output terminal 22, 4) power supply stoppage Four types of states are assumed.

  Here, 1) When supplying power to the output terminals 21 and 22, first, the output of the control circuit 52 becomes “high” level and the output of the control circuit 51 becomes “high” level with the P-type MOSFET 32 turned off. The N-type MOSFET 31 is turned on, and a voltage is applied across the inductor 12. The current of the inductor 12 increases in proportion to time, and then the control circuit 51 outputs “low”, whereby the N-type MOSFET 31 is turned off, and the increase in the current of the inductor 12 is stopped. Thereafter, the voltage across the inductor rises to a voltage at which one of the rectifier diodes 41 and 42 is turned on. At this time, the gate voltage of the P-type MOSFET 32 is the voltage of the output terminal 21, and the inductor voltage necessary for supplying power to the output terminal 22 supplies power to the output terminal 21. Is higher than the inductor voltage necessary for the P-type MOSFET by Vth. That is, in this state, the voltage across the inductor is such that the rectifier diode 41 is turned on first, and power is supplied to the output terminal 21 via the inductor. For this reason, the voltage at which the P-type MOSFET 32 is turned on is not reached, and power is not supplied to the output terminal 22. Thereafter, the inductor current continues to fall while supplying power to the output terminal 21, and eventually returns to zero.

  Next, the operation proceeds to power supply operation to the output terminal 22. First, when the output of the control circuit 52 changes from “high” to “low” and the P-type MOSFET 32 is turned on, the output of the control circuit 51 becomes “high” level and the N-type MOSFET 31 is turned on. A voltage is applied. The current of the inductor 12 increases in proportion to time, and then the control circuit 51 outputs “low”, whereby the N-type MOSFET 31 is turned off, and the increase of the current of the inductor 12 is stopped. Thereafter, the voltage across the inductor 12 rises to a voltage at which one of the rectifier diodes 41 and 42 is turned on. At this time, the gate of the P-type MOSFET 32 is at the ground (GND) voltage, and a voltage equal to or higher than Vth When applied to the source, it is turned on. If the voltage of the output terminal 22 is set lower than the voltage of the output terminal 22, the rectifier diode 42 is turned on first. Therefore, the voltage of the inductor 12 is clipped by the voltage at which the rectifier diode 42 is turned on. Power is supplied to the output terminal 22 via That is, in this state, the rectifier diode 42 is turned on first, and power is supplied to the output terminal 22 via the inductor 12. For this reason, electric power is not supplied to the output terminal 21 without reaching the voltage at which the rectifier diode 41 is turned on. Thereafter, the current of the inductor 12 continues to fall while supplying power to the output terminal 22, and eventually returns to zero. Thereafter, the current of the inductor 12 continues to fall while supplying power to the output terminal 22, and eventually returns to zero.

  By repeating the above operation, power supply to the output terminals 21 and 22 can be performed in a time division manner.

  Next, 2) when power is supplied only to the output terminal 21, the latter half of the operation of 1) is skipped. 3) When supplying power only to the output terminal 22, the operation of the first half of the above 1) is skipped. 4) When the power supply is stopped, all the operations in 1) are skipped. That is, the control circuit 51 outputs a “low” level to turn off the N-type MOSFET 31.

  FIG. 2 shows a DCDC converter circuit according to Embodiment 2 of the present invention. The second embodiment is an example in which three or more voltages are output in the circuit of the first embodiment. As shown in FIG. 2, in this embodiment, the output terminals are set in the order of 21, 22, 23, 24 from the higher voltage side. For example, when power is supplied to the output terminal 23, the output terminal of the corresponding control circuit 53 is set to “low” level, the P-type MOSFET 33 is turned on, and then the output of the control circuit 51 is set to “high” level. The N-type MOSFET 31 is turned on. Thereafter, the current of the inductor 12 is proportional to time, and the control circuit 51 outputs “low”, whereby the N-type MOSFET 31 is turned off, and the increase in the inductor current is stopped. Thereafter, the current of the inductor 12 increases in proportion to time, and the control circuit 51 outputs “low”, whereby the N-type MOSFET 31 is turned off, and the current increase of the inductor 12 is stopped. Thereafter, the voltage across the inductor 12 rises to a voltage at which any of the rectifier diodes 41 to 44 is turned on. Here, since the P-type MOSFET 33 is on, power is supplied only to the output terminal 23 via the rectifier diode 43. Here, since the voltages of the output terminals 21 and 22 of the diodes 41 and 42 are higher than that of the second terminal 71 of the inductor, the rectifier diode 41 has a reverse bias potential, so that it is turned off and no power is supplied. Further, although the voltage at the output terminal 24 is lower than the voltage at the output terminal 23, no power is supplied to the output terminal 24 because the P-type MOSFET 34 is off. Thereafter, the supply to the output terminals 22 and 24 is performed in the same procedure as described above.

  FIG. 3 shows a DCDC converter circuit according to Embodiment 3 of the present invention. The third embodiment is an example in which a negative voltage is further output in the circuit of the second embodiment. Unlike the second embodiment, in order to output a plurality of negative voltages, a P-type MOSFET 35 and a control circuit 55 are provided on the input side, and rectifier diodes 101, 102, 103, and 104 are provided on the output side. 62, 61, output terminals 121, 122, 123, 124, control circuits 112, 113, 114, and P-type MOSFETs 92, 93, 94 are added. The operation of supplying power to the output terminals 121, 122, 123, and 124 is the same as that in the first embodiment.

  First, in order to supply a negative voltage to the output terminal 121, the output of the control circuit 55 is set to “low” and the P-type MOSFET 35 is turned on. Thereafter, the output of the control circuit 51 is set to “high”, and the N-type MOSFET 31 is turned on. As a result, the inductor current increases in proportion to time. Next, when a “high” level is output from the control circuit 55, the P-type MOSFET 35 is turned off and the increase in the inductor current is stopped. Here, since the N-type MOSFET 31 remains on, the inductor second terminal 71 is fixed to the ground (GND) level. For this reason, the inductor first voltage continues to decrease to a voltage at which one of the rectifying diodes is turned on. At this time, the gate voltages of the N-type MOSFETs 92, 93, and 94 are the voltages of the output terminal 121, and the N-type MOSTFET is more than the inductor voltage necessary for supplying power to the output terminals 122, 123, and 124. Of Vth. That is, in this state, the voltage across the inductor decreases until the rectifier diode 101 is turned on first and the rectifier diode 101 is turned on with a forward bias. A current flows from the output terminal 121 via the rectifier diode 101, the inductor 12, and the N-type MOSFET, and a negative voltage is supplied to the output terminal 121. Thereafter, the inductor current continues to decrease and eventually returns to zero. In a series of operations, the rectifier diodes 41, 42, 43, 44 are reverse-biased, so that no reverse current flows from the output terminals 21, 22, 23, 24.

  Next, the operation proceeds to a negative voltage supply operation to the output terminal 122. First, the output of the control circuit 55 is set to “low”, and the P-type MOSFET 35 is turned on. Thereafter, the output of the control circuit 51 is set to “high”, and the N-type MOSFET 31 is turned on. As a result, the inductor current increases in proportion to time. Next, when a “high” level is output from the control circuit 55, the P-type MOSFET 35 is turned off and the increase in the inductor current is stopped. Here, since the N-type MOSFET 31 remains on, the inductor second terminal 71 is fixed to the ground (GND) level. For this reason, the inductor first voltage continues to decrease to a voltage at which one of the rectifying diodes is turned on. At this time, the gate voltage of the P-type MOSFET 92 is the ground (GND) voltage, and the gate voltages of the N-type MOSFETs 93 and 94 are the voltages of the output terminal 121 to supply power to the output terminals 123 and 124. It is lower than the required inductor voltage by Vth of the N-type MOSTFET. That is, in this state, the voltage across the inductor decreases until the rectifier diode 102 is turned on first and the rectifier diode 102 is turned on with a forward bias. A current flows from the output terminal 122 through the rectifier diode 102, the inductor 12, and the N-type MOSFET, and a negative voltage is supplied to the output terminal 121. Thereafter, the inductor current continues to decrease and eventually returns to zero. In a series of operations, since the rectifier diodes 101, 103, and 104 are reverse-biased, no reverse current flows from the output terminals 121, 123, and 124. Thereafter, the supply to the output terminals 123 and 124 is performed in the same procedure as described above. As described above, a negative voltage can be sequentially supplied to the output terminals 121, 122, 123, and 124.

  FIG. 4 shows a DCDC converter circuit according to Embodiment 4 of the present invention. Example 4 is an example in which only a plurality of negative voltages are output without outputting a positive voltage. As shown in FIG. 4, a P-type MOSFET 35 and a control circuit 55 on the input side, a plurality of rectifying diodes 101, 102, 103, 104 on the output side, a plurality of ripple removing capacitors 64, 63, 62, 61, and a plurality Output terminals 121, 122, 123, 124, control circuits 112, 113, 114, and P-type MOSFETs 92, 93, 94 are provided. The operation for supplying a negative voltage to the output terminals 121, 122, 123, and 124 is the same as that in the third embodiment.

1 is a circuit diagram of a DCDC converter according to Embodiment 1 of the present invention. The DCDC converter circuit diagram of Example 2 of this invention is shown. The DCDC converter circuit diagram of Example 3 of this invention is shown. The DCDC converter circuit diagram of Example 4 of this invention is shown.

Explanation of symbols

11 DC power supply 12 Inductor 21 Output terminal 22 Output terminal 23 Output terminal 24 Output terminal 25 Output terminal 31 N-type MOSFET
32 P-type MOSFET
33 P-type MOSFET
34 P-type MOSFET
35 P-type MOSFET
41 rectifier diode 42 rectifier diode 43 rectifier diode 44 rectifier diode 45 rectifier diode 51 control circuit 52 control circuit 53 control circuit 54 control circuit 61 ripple removing capacitor 62 ripple removing capacitor 63 ripple removing capacitor 64 ripple removing capacitor 71 inductor no. 2-terminal 72 inductor first terminal 92 P-type MOSFET
93 P-type MOSFET
94 P-type MOSFET
101 Rectifier Diode 102 Rectifier Diode 103 Rectifier Diode 104 Rectifier Diode 112 Control Circuit 113 Control Circuit 114 Control Circuit

Claims (7)

Includes at least one inductor, at least one N-type MOSFET, n rectifier diodes, n-1 P-type MOSFET, n ripple removal capacitors, n control circuits, and n output terminals (Where n represents an integer greater than or equal to 2), a first terminal of the inductor is connected to a DC power supply terminal, a second terminal of the inductor is connected to a drain terminal of an N-type MOSFET, The cathode of the first rectifier diode of the rectifier diodes is connected to the first capacitor of the ripple removing capacitors and the first output terminal of the n output terminals, and the N-type MOSFET A source terminal is connected to a ground (GND) terminal, all anode terminals of the n rectifier diodes are connected to a second terminal of the inductor, and the n rectifiers are connected. The cathode terminals of n−1 rectifier diodes other than the first rectifier diode of the anode are connected to the source terminals of the separate n−1 P-type MOSFETs, respectively. Each drain terminal of the MOSFET is connected to n−1 ripple removing capacitors other than the first capacitor and n−1 output terminals other than the first output terminal, respectively, and a gate terminal of the N-type MOSFET. Is connected to the output terminal of one of the n control circuits using the DC power supply terminal voltage as a power supply, and the gate terminals of the n-1 P-type MOSFETs are connected to the first output terminal. In the DCDC converter circuit connected to the output terminals of the n-1 control circuits each having a power source of the voltage, the voltage at the first output terminal is the other output terminal voltage. Ri high and by the voltage of the n output terminals are all differently controlled, DCDC converter circuit for outputting the n different DC voltages. 2. The DCDC converter circuit according to claim 1, wherein power supply to the n ripple removing capacitors is performed in a time-sharing manner. The DC / DC converter circuit according to claim 1, wherein n is 2 and outputs two different DC voltages. Further, a second P-type MOSFET is connected between the DC power supply terminal and the first terminal of the inductor, and m rectifier diodes, m−1 N-type MOSFETs, m ripple removing capacitors, m -1 control circuit and m output terminals (where m represents an integer of 2 or more), and the anode of the first rectifier diode among the rectifier diodes of the m diodes is the m The first capacitor of the ripple removing capacitors and the first output terminal of the m output terminals are connected, and all the cathode terminals of the m rectifier diodes are connected to the first terminal of the inductor. The anode terminals of m−1 rectifying diodes other than the first diode among the m diodes are connected to the source terminals of the m−1 N type MOSFETs, respectively. The drain terminals of the m-1 N-type MOSFETs are respectively connected to m-1 ripple removing capacitors other than the first capacitor and m-1 output terminals other than the first output terminal. The gate terminals of the (m−1) N-type MOSFETs are respectively connected to the output terminals of m−1 control circuits that use the voltage of the first output terminal as a power source. The voltage of the output terminal is higher than the voltages of the other m-1 output terminals, the voltages of the m output terminals are all controlled to be different, and m different negative DC voltages are output. 4. The DCDC converter circuit according to any one of 1 to 3. Including one inductor, at least one P-type MOSFET, m rectifier diodes, m-1 N-type MOSFETs, m ripple removing capacitors, m control circuits, and m output terminals ( Here, m represents an integer of 2 or more), the source terminal of the P-type MOSFET is connected to a DC power supply terminal, the first terminal of the inductor is connected to the drain terminal of the P-type MOSFET, Two terminals are connected to a ground (GND), and an anode of a first rectifier diode of the m rectifier diodes is a first capacitor of the ripple removing capacitors and of the m output terminals. All of the cathode terminals of the m rectifier diodes are connected to the first terminal of the inductor, and the m rectifier diodes are connected to the first output terminal of the m rectifier diodes. The anode terminals of the m−1 rectifier diodes other than the first rectifier diode are connected to the source terminals of the m−1 N type MOSFETs, respectively, and each of the m−1 N type MOSFETs is connected. Are connected to m−1 ripple removing capacitors other than the first capacitor and m−1 output terminals other than the first output terminal, respectively. The output terminal of one of the m control circuits using the DC power supply terminal voltage as a power source is connected, and the gate terminal of each of the (m−1) N-type MOSFETs is the voltage of the first output terminal. In the DCDC converter circuit connected to the output terminals of m-1 control circuits as power sources, the voltage of the first output terminal is lower than the other output terminal voltages. Wherein m by the voltage of the number of output terminals are all differently controlled, DCDC converter circuit for outputting m different negative DC voltage. 6. The DCDC converter circuit according to claim 4, wherein the negative voltage is supplied to the m ripple removing capacitors in a time-sharing manner. The flat panel display apparatus using the DCDC converter circuit in any one of Claim 1 thru | or 6.

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