JP2007020327A - Control unit for dc-dc converters - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To appropriately cancel soft-start control after start of operation, without having to separately provide a component dedicated to current detection. <P>SOLUTION: A control unit for DC-DC converters is provided with first and second MOSFETs 22, 24 connected to a coil 18 provided between charging/discharging means 12, 14. Current, flowing in the forward direction in a body diode 28, formed between the source and the drain of the second MOSFET 24, is detected. In steady-state operation, synchronous rectification control is carried out to cause the MOSFETs 22, 24 to perform inversion operation, relative to each other and supply direct-current power from the charging/discharging means 12 to the charging/discharging means 14. When operation is started, soft-start control is carried out, while gradually increase the on-duty period of the first MOSFET 22 and the second MOSFET 24 is turned off. When the current is continuously zero or is higher during the off-duty period of the first MOSFET 22 in soft-start control, the soft-start control is canceled or terminated, and synchronous rectification control is started. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a control device for a DC-DC converter, and more particularly, by appropriately operating at least a pair of switching elements connected to a coil provided between two charging / discharging means, from one charging / discharging means to the other. The present invention relates to a control device for a DC-DC converter that supplies DC power to charging / discharging means.

  2. Description of the Related Art Conventionally, a DC-DC converter that is connected between two charging / discharging units and supplies DC power from one charging / discharging unit to the other charging / discharging unit is known (for example, see Patent Document 1). This DC-DC converter includes a coil provided between two charging / discharging means, and a pair of switching elements (MOS transistors) connected to the coil, and each switching element is turned on and off to each other. By performing the inversion operation, DC power conversion from one charging / discharging unit to the other charging / discharging unit is realized.

  Further, in this DC-DC converter, the on-duty time is initially set in order to prevent an overcurrent from flowing to the switching element due to the switching element being turned on for a long time when the operation is started. The soft start control is executed so as to reach a desired on-duty time while gradually shortening the value and gradually increasing the value. In this soft start control, the on-duty time is gradually increased as described above for one of the pair of switching elements, and the off-state is continued for the other.

Furthermore, a current sensor for detecting a current flowing through the path is provided between the coil of the DC-DC converter and the charge / discharge means. The soft start control described above is terminated when the current value detected by the current sensor exceeds a predetermined threshold value, and thereafter, as usual, the pair of switching elements are inverted with respect to each other for a predetermined period. It is supposed to be turned on and off.
Japanese Patent No. 3501226

  However, in the conventional DC-DC converter, it is necessary to provide a current sensor between the coil and the charging / discharging means in order to end the soft start control. For this reason, the number of parts in the DC-DC converter increases, leading to an increase in manufacturing cost and an increase in mounting space, and further, a large power loss is caused due to the presence of the shunt resistor of the current sensor.

  The present invention has been made in view of the above points, and is a controller for a DC-DC converter that appropriately realizes release of soft start control after the start of operation without separately providing a component dedicated to current detection. The purpose is to provide.

  The above object is achieved by at least a pair of switching elements connected to a coil provided between two charging / discharging means, and the charging / discharging means from one charging / discharging means by reversing the pair of switching elements. And a normal control execution means for supplying direct-current power to the DC-DC converter control device, wherein the on-duty period of one switching element is gradually increased at the start of operation while the other switching element is turned off. Or soft start control execution means for executing soft start control for turning on the other switching element for a time shorter than the off duty period during the off duty period of the one switching element, and the other switching element Detects current flowing in the forward direction of a parasitic diode between both ends Current detection means, and a soft start control that terminates the soft start control when the current detected by the current detection means is in a state where the current detected by the current detection means is equal to or greater than a predetermined value for a predetermined period. And a control device for the DC-DC converter comprising start control end means.

  In the invention of this aspect, at the start of operation, while gradually increasing the on-duty period of one switching element, the other switching element is continuously turned off or during the off-duty period of the one switching element. In the soft start control for turning on the other switching element for a shorter time, the current flowing in the forward direction of the parasitic diode between the both ends of the other switching element during the control execution is not less than a predetermined value of zero or more. If the state continues for a predetermined period, it is terminated. In such a configuration, no overcurrent flows through any of the switching elements during execution of the soft start control. Parasitic diodes are formed at both ends of the switching element structure. Therefore, according to the present invention, the release of the soft start control after the start of the operation can be appropriately realized without separately providing a component dedicated to current detection.

  In this case, in the above-described DC-DC converter control device, the soft start control ending means is continuously detected by the current detecting means during the off-duty period of the one switching element during execution of the soft start control. When the current to be applied is equal to or greater than the predetermined value, the soft start control may be terminated.

  In the above-described DC-DC converter control device, the soft start control execution means may switch the other switching element to the current during an off-duty period of the one switching element during execution of the soft start control. It may be turned on when the current detected by the detection means is greater than or equal to the predetermined value, and turned off when the current detected by the current detection means is less than the predetermined value.

  According to the present invention, the release of the soft start control after the start of the operation can be appropriately realized without separately providing a current detection dedicated component.

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

  FIG. 1 shows a configuration diagram of a system including a controller for a DC-DC converter according to a first embodiment of the present invention. The system of the present embodiment is a system mounted on, for example, a vehicle. As shown in FIG. 1, the DC-DC converter 10 of this embodiment is provided between two charging / discharging means 12 and 14, and direct current is transferred from the charging / discharging means 12 on the input side to the charging / discharging means 14 on the output side. It is a DC-DC voltage converter that steps down and supplies electric power. The charging / discharging means 12 and 14 are a capacitor for storing electric power generated by a generator or the like possessed by a vehicle or a battery having a voltage such as 12 volts or 300 volts, and drives auxiliary equipment such as a vehicle headlight or an air conditioner. Used for

  The DC-DC converter 10 includes a coil 18 having a reactance L and a pair of switching elements 20 made of a semiconductor. The coil 18 is provided between the two charging / discharging means 12 and 14 described above. The pair of switching elements 20 includes a first MOSFET 22 and a second MOSFET 24 connected in series. The first MOSFET 22 has one end connected to the input side charge / discharge unit 12 and the other end of the coil 18. One end of the second MOSFET 24 is connected to one end of the coil 18 and the other end is grounded. That is, one end of the coil 18 is connected to a connection point between the first MOSFET 22 and the second MOSFET 24. The other end of the coil 18 is connected to the output side charge / discharge means 14.

  A body diode 26 is formed between the source and drain of the first MOSFET 22, and a body diode 28 is formed between the source and drain of the second MOSFET 24. The body diode 26 is a parasitic diode whose forward direction is from the one end side of the coil 18 and the second MOSFET 24 side toward the charge / discharge means 12. The body diode 28 is a parasitic diode whose forward direction is from the ground side toward the one end side of the coil 18 and the first MOSFET 22 side.

  The gates of the first MOSFET 22 and the second MOSFET 24 are connected to a control unit 30 that drives the MOSFETs 22 and 24 for switching. The control unit 30 includes a driver that drives each of the first MOSFET 22 and the second MOSFET 24 on and off, and appropriately controls switching of the DC-DC converter 10 to charge / discharge from the charging / discharging unit 12 as will be described in detail later. Step-down conversion to the discharge means 14 is performed.

  A current sensor 32 for detecting a current flowing between the drain and source of the second MOSFET 24 is connected to the control unit 30. The current sensor 32 outputs the drain voltage and source voltage of the second MOSFET 24, that is, the voltages at the anode terminal and the cathode terminal of the body diode 28, toward the control unit 30. The control unit 30 detects a current flowing in the forward direction of the body diode 28 in the second MOSFET 24 based on each voltage supplied from the current sensor 32.

  Next, the operation of the DC-DC converter 10 of this embodiment will be described with reference to FIG. FIG. 2 shows an operation timing chart of the DC-DC converter 10 of the present embodiment. 2A is a timing chart of the switching operation of the first MOSFET 22, FIG. 2B is a timing chart of the switching operation of the second MOSFET 24, and FIG. The timing chart of the current flowing between the drain and source of the MOSFET 22 (the direction flowing from the charging / discharging means 12 toward the coil 18 is positive), FIG. 4D shows the current flowing between the drain and source of the second MOSFET 24. The timing chart of the current (the forward direction of the body diode 28, that is, the direction flowing from the ground side to the coil 18 side is positive) is shown.

  In the present embodiment, the control unit 30 performs on / off duty driving by inverting the first and second MOSFETs 22 and 24 in a steady state after the operation of the DC-DC converter 10 is started. That is, when one is driven on, the other is driven off, and when one is driven off, the other is turned on, and the on / off operation is repeated at a predetermined cycle. It should be noted that when the MOSFETs 22 and 24 are switched on and off, a dead time may be provided so that both the MOSFETs 22 and 24 are not turned on. Hereinafter, the control for inverting the MOSFETs 22 and 24 in this way is referred to as synchronous rectification control.

  During the execution of the synchronous rectification control, the control unit 30 determines that the duty ratio γ for the first MOSFET 22 is a ratio between the voltage of the output side charging / discharging unit 14 and the voltage of the input side charging / discharging unit 12. 10 controls are performed. According to such synchronous rectification control, the voltage of the input side charging / discharging unit 12 is stepped down as desired by switching control in a steady state after the operation of the DC-DC converter 10 is started, and the input side charging / discharging unit 12 Can be supplied to the output-side charging / discharging means 14.

  Further, immediately after the operation of the DC-DC converter 10 is started, the control unit 30 realizes the output side charging / discharging unit 14 in which the duty ratio for the first MOSFET 22 is calculated in a steady state prior to the above-described synchronous rectification control. The DC-DC converter 10 is controlled so as to start from a value smaller than the ratio of the power voltage and the voltage of the input side charging / discharging means 12 (for example, zero) and then gradually increase. In this case, as shown in FIG. 2A, the on-duty period of the first MOSFET 22 starts from a shorter one than that in the steady state, and then gradually increases. In addition, in the process of gradually increasing the on-duty period of the first MOSFET 22 as described above, the control unit 30 maintains the second MOSFET 24 in the off state as shown in FIG. Hereinafter, such control is referred to as soft start control.

  According to such soft start control, even when the on-duty time of the first MOSFET 22 increases from a very short value immediately after the operation starts, the inversion operation is performed with respect to the first MOSFET 22 during the synchronous rectification control. The second MOSFET 24 does not start from a very long on-duty time. For this reason, it is avoided that a large current (overcurrent) flows from the output side charging / discharging means 14 to the second MOSFET 24 side via the coil 18 by turning on the second MOSFET 24 at the start of operation. The two MOSFETs 24 are prevented from being destroyed by the overcurrent flow.

  After starting the soft start control, the control unit 30 detects the current flowing in the forward direction of the body diode 28 in the second MOSFET 24 based on the output signal of the current sensor 32 during the execution of the soft start control. Then, it is determined whether or not the current value is equal to or greater than a predetermined value. The predetermined value is zero or a value that is set to be slightly larger than zero or zero or more with the forward direction of the body diode 28 as the positive direction. When the duty of the first MOSFET 22 is turned off during execution of the soft start control, the value of the current flowing in the forward direction of the body diode 28 in the second MOSFET 24 is continuously set to zero or more during the off-duty period. It is determined whether or not the predetermined value is exceeded.

  During the on-duty period of the first MOSFET 22, a current flows through the first MOSFET 22 from the charging / discharging unit 12 toward the coil 18. As shown in FIG. 2C, this current increases as the state where the first MOSFET 22 is in the duty-on state becomes longer. Further, when the first MOSFET 22 is switched from the duty-on state to the duty-off state, thereafter, current starts to flow through the second MOSFET 24 from the forward direction of the body diode 28, that is, from the ground side to the coil 18 side. As shown in FIG. 2D, this current substantially coincides with the current flowing through the first MOSFET 22 immediately before the switching of the first MOSFET 22, but gradually decreases thereafter.

  When the current continues to flow in the forward direction of the body diode 28 in the second MOSFET 24 during the off-duty period of the first MOSFET 22, even if the second MOSFET 24 is turned on, the charge / discharge on the output side A large current (overcurrent) does not flow from the means 14 through the coil 18 to the second MOSFET 24 side. On the other hand, during the off-duty period of the first MOSFET 22, when there is even a state in which no current flows through the second MOSFET 24 in the forward direction of the body diode 28, the output is output when the second MOSFET 24 is turned on. There is a possibility that an overcurrent flows from the charging / discharging means 14 on the side to the second MOSFET 24 side via the coil 18.

  Therefore, in order to prevent such overcurrent, in the system of the present embodiment, the control unit 30 sets the second MOSFET during the off-duty period when the first MOSFET 22 is in the duty-off state during the execution of the soft start control. When it is determined that the detected value of the current flowing in the forward direction of the body diode 28 in the MOSFET 24 may be less than the predetermined value set to zero or more, the execution of the soft start control is continued. On the other hand, when it is determined that the detected value of the current flowing in the forward direction of the body diode 28 in the second MOSFET 24 continuously during the off-duty period of the first MOSFET 22 is equal to or greater than a predetermined value set to zero or more (FIG. 2). At time t1), the soft start control is canceled and terminated at that time, and the normal synchronous rectification control, that is, the first MOSFET 22 is driven on and off at a desired duty ratio, and the second MOSFET 24 is driven to the first time. The process shifts to execution of a process for inverting the MOSFET 22. In this case, during the off-duty period of the first MOSFET 22 after the next, the second MOSFET 24 is in a duty-on state, and synchronous rectification control is executed.

  FIG. 3 shows a flowchart of an example of a control routine executed by the control unit 30 in the system of the present embodiment in order to realize the above function. The routine shown in FIG. 3 is started after the operation of the DC-DC converter 10 is started. When the routine shown in FIG. 3 is started, first, the process of step 70 is executed.

  In step 70, as an initial setting of the soft start control, a process of turning off both the first and second MOSFETs 22 and 24 and resetting the first set time tg1 to “0” is executed. The first set time tg1 is a continuation time during which the first MOSFET 22 should be kept on, and is changed by a process in step 76 described later. When the processing in step 70 is executed, next, in step 72, processing for resetting the elapsed time t to “0” is executed.

  In step 74, it is determined whether or not the first set time tg1 is less than the on-duty time TG1 at which the first MOSFET 22 is to be kept on at a desired duty ratio determined from the input voltage and the output voltage. Determined. As a result, if it is determined that tg1 <TG1 is satisfied, the process of step 76 is performed next. On the other hand, if it is determined that tg1 <TG1 is not satisfied, the process of step 92 is executed next.

  In step 76, the first set time tg1 is incremented by a predetermined time “a” and the second set time tg2 is calculated. The predetermined time “a” is the time required from the previous process to the current process. Further, the second set time tg2 is a continuation time during which the first MOSFET 22 should be maintained in the off state, and is calculated by the following equation (1) using the first set time tg1 and the duty cycle TW.

tg2 = TW−tg1 (1)
In step 78, a process for turning on the first MOSFET 22 is executed. In step 80, it is determined whether or not an elapsed time t after the first MOSFET 22 is turned on is less than the first set time tg1. As a result, when it is determined that t <tg1 is established, the process of step 78 is repeatedly executed. On the other hand, if it is determined that t <tg1 does not hold because the elapsed time t reaches the first set time tg1, the process of step 82 is executed next.

  In step 82, a process of turning off the first MOSFET 22 is executed, the elapsed time t is reset to “0”, and a process of setting the flag flg to “1” is executed. The flag flg is a flag indicating that a current of a predetermined value or more is flowing in the forward direction of the body diode 28 of the second MOSFET 24.

  In step 84, it is determined whether or not the current I (D) flowing in the forward direction of the body diode 28 through the second MOSFET 24 detected using the current sensor 32 is below a predetermined value Ith set to a value of zero or more. Determined. As a result, if it is determined that I (D) <Ith does not hold due to the current flowing through the second MOSFET 24 in the forward direction of the body diode 28, the process of step 88 is executed next.

  In step 88, it is determined whether or not the elapsed time t after the first MOSFET 22 is turned off in step 82 is less than the second set time tg2 set in step 76. As a result, when it is determined that t <tg2 is satisfied, the process of step 84 is repeatedly executed.

  On the other hand, if it is determined in step 84 that the current in the forward direction of the body diode 28 does not flow through the second MOSFET 24 and I (D) <Ith is established, the process of step 86 is executed next. . In step 86, a process for resetting the flag flg to "0" is executed. When the process of step 86 is executed, the process of step 88 is executed next.

  If it is determined in step 88 that t <tg2 does not hold because the elapsed time t reaches the second set time tg2, the process of step 90 is executed next. In step 90, it is determined whether or not the flag flg is set to "1". When the flag flg is reset to “0” at the time of such processing, current does not flow in the forward direction of the body diode 28 in the second MOSFET 24 during the off-duty period (tg2) of the first MOSFET 222. Therefore, if such a negative determination is made, the process of step 72 is then repeatedly executed to continue the execution of the soft start control. On the other hand, when the flag flg is set to “1” at the time of processing of this step 90, the body MOSFET 28 is directed in the forward direction to the second MOSFET 24 during the off-duty period (tg 2) of the first MOSFET 22. Since it can be determined that the current has continued to flow, if such an affirmative determination is made, then the process of step 92 is executed.

  In step 92, the soft start control is finished, and the normal synchronous rectification control is performed, that is, the first MOSFET 22 is driven on and off at a desired duty ratio, and the second MOSFET 24 is inverted with respect to the first MOSFET 22. Processing for starting control is executed. When the process of step 92 is completed, the current process is terminated.

  According to the system in which such a step-down DC-DC converter 10 is mounted, after the operation is started, switching from the soft start control to the synchronous rectification control is performed by overcurrent from the charge / discharge means 14 on the output side to the second MOSFET 24. Therefore, it is possible to prevent the overcurrent from flowing to the second MOSFET 24 during the execution of the soft start control.

  Further, in the system of the present embodiment, in order to cancel the soft start control and start the synchronous rectification control after the operation is started, the current in the forward direction of the body diode 28 flowing through the second MOSFET 24 is the first current. This current detection is necessarily formed between the drain and the source due to the structure of the second MOSFET 24 which is a semiconductor switching element. This is performed based on the voltage generated across the body diode 28.

  For this reason, according to the configuration of this embodiment, when performing current detection for determining the end of the soft start control in the DC-DC converter 10, it is not possible to separately provide a dedicated component such as a shunt resistor on the path. As a result, the number of parts in the DC-DC converter 10 can be reduced, and the manufacturing cost can be reduced, the size and weight can be reduced, and the power loss due to the presence of the shunt resistor can be reduced. It is possible to suppress the occurrence. Therefore, according to the system of the present embodiment, it is possible to appropriately realize the release / end of the soft start control after the operation of the DC-DC converter 10 is started without separately providing a current detection dedicated component. ing.

  In the first embodiment, the pair of switching elements 20, the first MOSFET 22 and the second MOSFET 24 are the "pair of switching elements" described in the claims, and the first MOSFET 22 is the claims. The second MOSFET 24 corresponds to “the other switching element” described in the claims, and “one switching element” described in the range.

  In the first embodiment, the control unit 30 executes the synchronous rectification control for the DC-DC converter 10 so that the “normal control execution unit” described in the claims executes the soft start control. Thus, the “soft start control execution means” described in the claims detects the current flowing in the forward direction of the body diode 28 between the drain and the source of the second MOSFET 24 using the current sensor 32. In the “current detection means” described in the claims, the current flowing in the forward direction of the body diode 28 in the second MOSFET 24 during the off-duty period of the first MOSFET 22 during execution of the soft start control is equal to or greater than a predetermined value. Claim soft claims by ending soft start control when the condition continues Was "soft-start control end means", has been realized, respectively.

  By the way, in the first embodiment, the soft start control is performed by gradually increasing the on-duty period of the first MOSFET 22 and maintaining the second MOSFET 24 in the off state. As shown in FIG. 4, when the forward current of the body diode 28 flowing through the second MOSFET 24 is greater than or equal to a predetermined value during the off-duty period of the first MOSFET 22, as shown in FIG. The MOSFET 24 may be turned on, and the second MOSFET 24 may be turned off when the current becomes less than a predetermined value. In this case, in addition to turning off the first MOSFET 22 in step 82 in the routine shown in FIG. 3, a process for turning on the second MOSFET 24 is executed, and the flag flg is set to “ In addition to resetting to 0 ″, a process of turning off the second MOSFET 24 is executed.

  According to such a configuration, even if the second MOSFET 24 is turned on during the execution of the soft start control, the on state is realized only when a current flows in the forward direction of the body diode 28. An overcurrent is prevented from flowing into the second MOSFET 24 from the charging / discharging means 14 on the side. Therefore, also in this modification, it is possible to prevent an overcurrent from flowing through the second MOSFET 24 during execution of the soft start control.

  In the first embodiment described above, the current flowing through the second MOSFET 24 is detected by detecting the potential difference generated between the drain and source of the second MOSFET 24 using the current sensor 32. Whether or not the current value is equal to or greater than a predetermined value in the forward direction of the diode 28 is determined. The current sensor 32 is connected to the drain terminal and the source terminal of the second MOSFET 24, that is, the body diode 28 as shown in FIG. It is also possible to provide a comparator 40 in which both terminals are connected to the inverting input terminal and the non-inverting input terminal. In this case, the comparator 40 outputs a signal according to the potential difference generated between the drain and source of the second MOSFET 24, and the voltage at the connection point between the coil 18, the first MOSFET 22 and the second MOSFET 24 is higher than the ground voltage. When it is high, an on signal is output. When an ON signal is supplied from the comparator 40 during the off-duty period of the first MOSFET 22 during execution of the soft start control, the control unit 30 causes a current to flow in the forward direction of the body diode 28 through the second MOSFET 24. If there is no time, the soft start control is continued. On the other hand, when no ON signal is supplied from the comparator 40, the current continues to the second MOSFET 24 in the forward direction of the body diode 28 during that period. As a result, the execution of the soft start control is canceled / terminated.

  In the above embodiment, the second MOSFET 24 is formed with the body diode 28 between the drain and the source. However, the second MOSFET 24 is connected to the cathode terminal of the body diode 28 as shown in FIG. May be a sense diode that is grounded via a resistor 50. In this case, a comparator 52 in which both terminals of the resistor 50 are connected to the inverting input terminal and the non-inverting input terminal is provided as the current sensor 32, and the comparator 52 outputs a signal according to the potential difference generated between both ends of the resistor 50. The ON signal is output when the voltage at the cathode terminal of the body diode 28 is higher than the ground voltage. When an ON signal is supplied from the comparator 52 during the off-duty period of the first MOSFET 22 during execution of the soft start control, the control unit 30 causes a current to flow in the forward direction of the body diode 28 through the second MOSFET 24. If there is no time, the soft start control is continued. On the other hand, when no ON signal is supplied from the comparator 40, the current continues to the second MOSFET 24 in the forward direction of the body diode 28 during that period. As a result, the execution of the soft start control is canceled / terminated.

  Further, similarly, as shown in FIG. 7, the second MOSFET 24 may be configured as a pair of sense MOSs 62 together with a third MOSFET 60 commonly connected to its drain. In such a configuration, the third MOSFET 60 is formed on the same substrate as the second MOSFET 24, and is set to a predetermined area ratio so as to have a predetermined shunt ratio with respect to the second MOSFET 24. When the current flowing through the second MOSFET 24 increases or decreases, the current flowing through the third MOSFET 60 also increases or decreases at a rate equivalent to the change. In this case, the current sensor 32 is provided with a configuration for detecting the current flowing in the forward direction of the body diode 64 in the third MOSFET 60, and the control unit 30 uses the current sensor 32 to indirectly connect the second current sensor 32. The current flowing in the forward direction of the body diode 28 in the MOSFET 24 may be detected.

  FIG. 8 shows a configuration diagram of a system including a control device for a DC-DC converter according to a second embodiment of the present invention. As shown in FIG. 8, the DC-DC converter 100 of this embodiment is provided between two charging / discharging means 102 and 104, and direct current is transferred from the charging / discharging means 102 on the input side to the charging / discharging means 104 on the output side. A DC-DC voltage converter that boosts and supplies electric power. Similarly to the charging / discharging means 12 and 14 of the first embodiment, the charging / discharging means 102 and 104 are a capacitor for storing electric power generated by a generator or the like of the vehicle, or a battery having a voltage such as 12 volts or 300 volts. It is used to drive auxiliary equipment such as vehicle headlights and air conditioners.

  The DC-DC converter 100 includes a coil 108 having reactance L provided between the two charging / discharging means 102 and 104 described above, and a pair of switching elements 110 made of a semiconductor. The pair of switching elements 110 includes a first MOSFET 112 and a second MOSFET 114 connected in series. The first MOSFET 112 has one end connected to one end of the coil 108 and the other end grounded, and the second MOSFET 114. The one end is connected to the output side charging / discharging means 104 and the other end is connected to one end of the coil 108. That is, one end of the coil 108 is connected to a connection point between the first MOSFET 112 and the second MOSFET 114. The other end of the coil 108 is connected to the input side charging / discharging means 102.

  The first MOSFET 112 is formed with a body diode 116 between its source and drain, and the second MOSFET 114 is formed with a body diode 118 between its source and drain. The body diode 116 is a parasitic diode whose forward direction is from the ground side toward the one end side of the coil 108 and the second MOSFET 114 side. The body diode 118 is a parasitic diode whose forward direction is from the one end side of the coil 108 and the first MOSFET 112 side toward the charging / discharging means 104.

  The gates of the first MOSFET 112 and the second MOSFET 114 are connected to a control unit 120 that performs switching driving of the MOSFETs 112 and 114, respectively. The control unit 120 includes a driver that drives each of the first MOSFET 112 and the second MOSFET 114 on and off. As will be described in detail later, the controller 120 appropriately controls switching of the DC-DC converter 100 to charge / discharge from the charging / discharging unit 102. Boost conversion to the discharging means 104 is performed.

  A current sensor 122 for detecting a current flowing between the drain and source of the second MOSFET 114 is connected to the control unit 120. The current sensor 122 outputs the drain voltage and the source voltage of the second MOSFET 114, that is, the voltages of the anode terminal and the cathode terminal of the body diode 118, to the control unit 120. The control unit 120 detects a current flowing in the forward direction of the body diode 118 in the second MOSFET 114 based on each voltage supplied from the current sensor 122.

  Next, the operation of the DC-DC converter 100 of this embodiment will be described. In the present embodiment, the control unit 120 performs on / off duty driving by inverting the first and second MOSFETs 112 and 114 in a steady state after the operation of the DC-DC converter 100 is started. That is, when one is driven on, the other is driven off, and when one is driven off, the other is turned on, and synchronous rectification control is performed to repeat the on / off at a predetermined cycle. It should be noted that a dead time may be provided so that both the MOSFETs 112 and 114 are not turned on when the MOSFETs 112 and 114 are switched on and off.

  When executing the synchronous rectification control, the control unit 120 sets the ratio of the voltage of the output side charging / discharging unit 104 to the voltage of the input side charging / discharging unit 102 with respect to the duty ratio γ for the first MOSFET 112 as 1 / (1−γ). The DC-DC converter 100 is controlled so that the following conditions are satisfied. According to such synchronous rectification control, the voltage of the input side charging / discharging unit 102 is boosted as desired by switching control in a steady state after the operation of the DC-DC converter 100 is started, and the input side charging / discharging unit 102 Can be supplied to the output side charging / discharging means 104.

  Further, immediately after the operation of the DC-DC converter 100 is started, the control unit 120 has a duty ratio with respect to the first MOSFET 112 smaller than that satisfying the above-described condition (for example, zero) prior to the above-described synchronous rectification control. Soft-start control of the DC-DC converter 100 that maintains the second MOSFET 114 in the off state in the process of gradually increasing and then increasing the on-duty period of the first MOSFET 112. Execute. In this case, the on-duty period of the first MOSFET 112 starts from a shorter one than that in the steady state, and thereafter gradually increases.

  According to such soft start control, even when the on-duty time of the first MOSFET 112 increases from a very short value immediately after the operation starts, the inversion operation is performed with respect to the first MOSFET 112 during the synchronous rectification control. The second MOSFET 114 does not start from a very long on-duty time. For this reason, it is avoided that a large current (overcurrent) flows from the charge / discharge means 104 on the output side to the second MOSFET 114 side by turning on the second MOSFET 114 at the start of operation, and the second MOSFET 114 is excessive. It is prevented from being destroyed by the current flow.

  After starting the soft start control described above, the control unit 120 detects the current flowing in the forward direction of the body diode 118 in the second MOSFET 114 based on the output signal of the current sensor 122 during the execution of the soft start control. Then, it is determined whether or not the current value is equal to or greater than a predetermined value. The predetermined value is a value set to be equal to or greater than zero with the forward direction of the body diode 118 as the positive direction. During the soft start control, when the duty of the first MOSFET 112 is turned off, the current value flowing in the forward direction of the body diode 118 in the second MOSFET 114 is continuously set to zero or more during the off-duty period. It is determined whether or not the predetermined value is exceeded.

  As a result, if a negative determination is made, the soft start control continues to be executed. On the other hand, if an affirmative determination is made, the soft start control is canceled and terminated at that time, and the normal synchronous rectification control is performed as usual. That is, the first MOSFET 112 is turned on / off at a desired duty ratio, and the second MOSFET 114 is inverted to the first MOSFET 112. In this case, the second MOSFET 114 is in a duty-on state during the off-duty period of the first MOSFET 112 after the next, and synchronous rectification control is executed.

  According to the system in which such a step-up DC-DC converter 100 is mounted, after the operation is started, switching from the soft start control to the synchronous rectification control is performed by overcurrent from the charge / discharge means 104 on the output side to the second MOSFET 114. Therefore, it is possible to prevent the overcurrent from flowing to the second MOSFET 114 during the execution of the soft start control.

  In addition, in the system of the present embodiment, in order to cancel the soft start control and start the synchronous rectification control after the operation is started, the current in the forward direction of the body diode 118 flowing through the second MOSFET 114 is the first current. This current detection is necessarily formed between the drain and the source due to the structure of the second MOSFET 114 which is a semiconductor switching element. This is performed based on the voltage generated across the body diode 118.

  For this reason, also in the configuration of the present embodiment, as in the configuration of the first embodiment, when performing current detection for determining the end of the soft-start control in the DC-DC converter 100, the shunt resistance, etc. It is not necessary to separately provide a dedicated part on the path, and thus the number of parts in the DC-DC converter 100 can be reduced, and the manufacturing cost can be reduced, and the size, weight, and space can be reduced. At the same time, it is possible to suppress the occurrence of power loss due to the presence of the shunt resistor. Therefore, according to the system of the present embodiment, it is possible to appropriately realize the release / end of the soft start control after the operation of the DC-DC converter 10 is started without separately providing a current detection dedicated component. ing.

  In the second embodiment, the pair of switching elements 110, the first MOSFET 112, and the second MOSFET 114 are the "pair of switching elements" described in the claims, and the first MOSFET 112 is the claims. The second MOSFET 114 corresponds to “the other switching element” described in the claims, and “one switching element” described in the range.

  In the second embodiment, the control unit 120 executes the synchronous rectification control for the DC-DC converter 100 so that the “normal control execution means” described in the claims executes the soft start control. Thus, the “soft start control execution means” described in the claims detects the current flowing in the forward direction of the body diode 118 between the drain and the source of the second MOSFET 114 using the current sensor 122. In the “current detection means” described in the claims, the current flowing in the forward direction of the body diode 118 in the second MOSFET 114 during the off-duty period of the first MOSFET 112 during execution of the soft start control is greater than or equal to a predetermined value. Patented by ending soft start control when the condition continues Described in the scope of the determined "soft-start control ending means" are realized respectively.

  FIG. 9 shows a configuration diagram of a system including a DC-DC converter control apparatus according to a third embodiment of the present invention. As shown in FIG. 9, the DC-DC converter 200 of this embodiment is provided between two charging / discharging means 202 and 204, and boosts DC power between the charging / discharging means 202 and the charging / discharging means 104. Alternatively, it is a bi-directional DC-DC voltage converter that supplies a step-down voltage. The charging / discharging means 202, 204 is similar to the charging / discharging means 12, 14 of the first embodiment, such as a capacitor for storing electric power generated by a generator or the like of the vehicle, or a battery having a voltage such as 12 volts or 300 volts. It is used to drive auxiliary equipment such as vehicle headlights and air conditioners.

  The DC-DC converter 200 includes a reactance L coil 208 provided between the two charging / discharging means 202 and 204 described above, and first to fourth MOSFETs 211 to 214 which are four switching elements made of a semiconductor. And. The first MOSFET 211 has one end connected to the charging / discharging means 202 and the other end connected to one end of the coil 208. The second MOSFET 212 has one end connected to one end of the coil 208 and the other end grounded. The third MOSFET 213 has one end connected to the charging / discharging means 204 and the other end connected to the other end of the coil 208. The fourth MOSFET 214 has one end connected to the other end of the coil 208 and the other. The end is grounded. That is, the coil 208 has one end connected to the connection point between the first MOSFET 211 and the second MOSFET 212 and the other end connected to the connection point between the third MOSFET 213 and the fourth MOSFET 214. Yes.

  The first MOSFET 211 has a body diode 216 between its source and drain, the second MOSFET 212 has a body diode 217 between its source and drain, and the third MOSFET 213 has a body diode 218 between its source and drain. In the fourth MOSFET 214, a body diode 219 is formed between its source and drain. The body diode 216 is a parasitic diode having a forward direction from one end side of the coil 208 and the second MOSFET 212 toward the charging / discharging means 202, and the body diode 217 is one end side of the coil 208 and the first MOSFET 211 from the ground side. The body diode 218 is a parasitic diode whose forward direction is the direction from the other end side of the coil 208 and the fourth MOSFET 214 side to the charging / discharging means 204. The body diode 219 is a parasitic diode whose forward direction is from the ground side toward the other end side of the coil 208 and the third MOSFET 213 side.

  The gates of the first and fourth MOSFETs 211 to 214 are connected to a control unit 220 that performs switching driving of the MOSFETs 211 to 214, respectively. The control unit 220 includes a driver that drives each of the first to fourth MOSFETs 211 to 214 on and off, and appropriately controls switching of the DC-DC converter 200 to charge and discharge the charging / discharging means 202 and the charging unit 202 as will be described in detail later. A step-down conversion and a step-up conversion are performed bidirectionally with the discharging means 204.

  The controller 220 includes a current sensor 221 for detecting a current flowing between the drain and source of the first MOSFET 211, a current sensor 222 for detecting a current flowing between the drain and source of the second MOSFET 212, and A current sensor 223 for detecting a current flowing between the drain and source of the third MOSFET 213 and a current sensor 224 for detecting a current flowing between the drain and source of the fourth MOSFET 214 are connected. The current sensor 221 outputs the drain voltage and source voltage of the first MOSFET 211, that is, the voltages of the anode terminal and the cathode terminal of the body diode 216, toward the control unit 220. The current sensor 222 outputs the drain voltage and the source voltage of the second MOSFET 212, that is, the voltages at the anode terminal and the cathode terminal of the body diode 217 toward the control unit 220. The current sensor 223 outputs the drain voltage and the source voltage of the third MOSFET 213, that is, the voltages of the anode terminal and the cathode terminal of the body diode 218, to the control unit 220. The current sensor 224 outputs the drain voltage and source voltage of the fourth MOSFET 214, that is, the voltages at the anode terminal and the cathode terminal of the body diode 219, to the control unit 220. The control unit 220 detects a current flowing in the forward direction of the body diode 216 in the first MOSFET 211 based on each voltage supplied from the current sensor 221, and similarly each voltage supplied from the current sensors 222 to 224. Based on the above, currents flowing in the forward direction of the body diodes 217 to 219 are detected in the second MOSFET 212 to the fourth MOSFET 214, respectively.

  Next, the operation of the DC-DC converter 200 of this embodiment will be described. In this embodiment, the control unit 220 starts the operation of supplying power from the charging / discharging unit 202 to the charging / discharging unit 204 using the DC-DC converter 200, and at first, the third MOSFET 213 is turned on at the time of step-down in the steady state. After the fourth MOSFET 214 is fixed in the on state and the fourth MOSFET 214 is in the off state, synchronous rectification control is performed in which the first MOSFET 211 and the second MOSFET 212 are inverted to perform on / off duty driving. Further, at the time of boosting in a steady state, first, the first MOSFET 211 is fixed to the on state and the second MOSFET 212 is fixed to the off state, and then the third MOSFET 213 and the fourth MOSFET 214 are operated to invert each other. Thus, synchronous rectification control that performs on / off duty driving is executed.

  The control unit 220 adjusts the duty ratio γ for the first MOSFET 211 to the ratio of the voltage of the charging / discharging unit 204 and the voltage of the charging / discharging unit 202 at the time of step-down, and the duty ratio γ to the fourth MOSFET 214 at the time of step-up. The DC-DC converter 200 is controlled so that the condition that the ratio between the voltage of the charging / discharging unit 204 and the voltage of the charging / discharging unit 202 is 1 / (1-γ) is satisfied. According to such synchronous rectification control, the voltage of the charging / discharging unit 202 is stepped down or boosted as desired by switching control in a steady state after the operation of the DC-DC converter 200 is started, and the charging / discharging unit 202 has Electric power can be supplied to the charging / discharging means 204.

  Further, immediately after the start of the operation of the DC-DC converter 200, the control unit 220 prior to the synchronous rectification control, the duty ratio with respect to the first MOSFET 211 is smaller than that satisfying the above-described conditions at the time of step-down ( For example, the second MOSFET 212 is kept off in the process of starting from zero), gradually increasing, and gradually increasing the on-duty period of the first MOSFET 211. In the process of starting the duty ratio with respect to the MOSFET 214 from a value smaller than that satisfying the above condition (for example, zero), gradually increasing, and gradually increasing the on-duty period of the fourth MOSFET 211 DC-DC converter for maintaining third MOSFET 213 in OFF state 00 to run the soft-start control of.

  According to such soft start control, the on-duty time of the first MOSFET 211 is increased at the time of step-down, and the on-duty period of the fourth MOSFET is increased from a very short time immediately after the operation is started at the time of step-up. In addition, during the synchronous rectification control, the on-duty time of the second MOSFET 212 that performs the inversion operation with respect to the first MOSFET 211 and the on-duty time of the third MOSFET 213 that performs the inversion operation with respect to the fourth MOSFET 214 are very long. Never start with something. Therefore, at the start of the operation for supplying power from the charging / discharging unit 202 to the charging / discharging unit 204, the second MOSFET 212 is turned on at the time of step-down, and the third MOSFET 213 is turned on at the time of step-up. The overcurrent is prevented from flowing, and the second and third MOSFETs 212 and 213 are prevented from being destroyed by the overcurrent flow.

  After starting the soft start control described above, the control unit 220 performs a current that flows in the forward direction of the body diode 217 to the second MOSFET 212 based on the output signal of the current sensor 222 during step-down during the execution of the soft start control. Is detected, and it is determined whether or not the current value is equal to or greater than a predetermined value. The predetermined value is a value set to be equal to or greater than zero with the forward direction of the body diode 217 as the positive direction. When the duty of the first MOSFET 211 is turned off during the execution of the soft start control, the value of the current flowing in the forward direction of the body diode 217 in the second MOSFET 212 is set to zero or more continuously during the off-duty period. It is determined whether or not the predetermined value is exceeded. As a result, if a negative determination is made, the soft start control continues to be executed. On the other hand, if an affirmative determination is made, the soft start control is canceled and terminated at that time, and the normal synchronous rectification control is performed as usual. Is executed. In this case, the second MOSFET 212 is in a duty-on state during the off-duty period of the first MOSFET 211 after the next, and synchronous rectification control is executed.

  Further, at the time of step-up, the soft start control is executed in the same manner as at the time of step-down by detecting the current flowing in the forward direction of the body diode 218 in the third MOSFET 213 based on the output signal of the current sensor 223. Judgment is made regarding continuation, cancellation, and termination. When the soft start control release / end condition is satisfied, the third MOSFET 213 is in a duty-on state during the off-duty period of the fourth and subsequent MOSFETs 214, and synchronous rectification control is executed.

  Conversely, the same processing is performed when power is supplied from the charging / discharging unit 204 to the charging / discharging unit 202 using the DC-DC converter 200. Therefore, when power is supplied from the charging / discharging means 204 to the charging / discharging means 202, according to the synchronous rectification control, the voltage of the charging / discharging means 204 is stepped down as desired by switching control in a steady state after the start of the operation. Alternatively, it is possible to boost the voltage and supply the electric power of the charging / discharging unit 204 to the charging / discharging unit 202, and according to the soft start control, the first MOSFET 211 is turned on at the time of step-down. Further, since the overcurrent from the charging / discharging means 202 is avoided by turning on the fourth MOSFET 214 during boosting, the first and fourth MOSFETs 211 and 214 are prevented from being destroyed by the overcurrent flow. Is done.

  Further, in a situation where power is supplied from the charging / discharging means 204 to the charging / discharging means 202 using the DC-DC converter 200, during the soft start control, the fourth time is determined based on the output signal of the current sensor 224 during step-down. A current flowing in the forward direction of the body diode 219 in the MOSFET 214 is detected, and it is determined whether or not the current value is a predetermined value or more. During execution of the soft start control, when the duty of the third MOSFET 213 is turned off, the value of the current flowing in the forward direction of the body diode 219 in the fourth MOSFET 214 is set to zero or more continuously during the off-duty period. It is determined whether or not the predetermined value is exceeded. As a result, if a negative determination is made, the soft start control continues to be executed. On the other hand, if an affirmative determination is made, the soft start control is canceled and terminated at that time, and the normal synchronous rectification control is performed as usual. Is executed. In this case, the fourth MOSFET 214 is in a duty-on state during the off-duty period of the third and subsequent third MOSFETs 213, and synchronous rectification control is executed.

  Further, at the time of step-up, the soft start control is executed in the same manner as at the time of step-down by detecting the current flowing in the forward direction of the body diode 216 in the first MOSFET 211 based on the output signal of the current sensor 221. Judgment is made regarding continuation, cancellation, and termination. When the soft start control release / end condition is satisfied, the first MOSFET 211 is in a duty-on state during the off-duty period of the second and subsequent MOSFETs 212, and synchronous rectification control is executed.

  As described above, according to the system in which the step-up / step-down DC-DC converter 200 is mounted, a dedicated component such as a shunt resistor is used for current detection for determining the end of the soft-start control in the DC-DC converter 200. It is not necessary to provide a separate path on the path, which can reduce the number of parts in the DC-DC converter 200, reduce the manufacturing cost, reduce the size and weight, and save space. It is possible to suppress the occurrence of power loss due to the presence of the resistor. Therefore, according to the system of the present embodiment, it is possible to appropriately realize the release / end of the soft start control after the start of the operation of the DC-DC converter 200 without separately providing a current detection dedicated component. ing.

  In the third embodiment, the first MOSFET 211 and the second MOSFET 212 or the third MOSFET 213 and the fourth MOSFET 214 are included in the “pair of switching elements” in the claims, and the charging / discharging means 202 The first MOSFET 211 during the step-down from the charging / discharging means 204 to the fourth MOSFET 214 during the step-up, the third MOSFET 213 during the step-down from the charging / discharging means 204 to the charge / discharge means 202, and the second MOSFET 212 during the step-up. The "one switching element" described in the claims includes a second MOSFET 212 when the voltage is lowered from the charge / discharge means 202 to the charge / discharge means 204, a third MOSFET 213 when the voltage is raised, and a charge / discharge means from the charge / discharge means 204. When stepping down to 202, the fourth MOSFET 14, at the time of boosting the first MOSFET211 is, the "other switching elements" described in the claims correspond respectively.

  In the third embodiment, the control unit 220 executes the synchronous rectification control for the DC-DC converter 200 so that the “normal control execution means” described in the claims executes the soft start control. Accordingly, the “soft start control execution means” described in the claims can be applied to the forward direction of the body diodes 216 to 219 between the drains and the sources of the first to fourth MOSFETs 211 to 214 using the current sensors 221 to 224. By detecting the current flowing through the first MOSFET 211, the “current detection means” described in the claims can be applied to the second MOSFET 212 in the forward direction of the body diode 217 during the off-duty period of the first MOSFET 211 during execution of the soft start control. When the state where the current flowing through the capacitor is equal to or greater than the predetermined value continues, the second MOS When the state in which the current flowing in the forward direction of the body diode 216 in the first MOSFET 211 during the off-duty period of the ET 212 is equal to or greater than a predetermined value continues to the body diode in the fourth MOSFET 214 during the off-duty period of the third MOSFET 213 If the state where the current flowing in the forward direction of 219 is equal to or greater than the predetermined value continues, or the current flowing in the forward direction of the body diode 218 to the third MOSFET 213 during the off-duty period of the fourth MOSFET 214 is equal to or greater than the predetermined value The “soft start control ending means” described in the claims is realized by ending the soft start control when the state continues.

  FIG. 10 shows a configuration diagram of a system including a control device for a DC-DC converter according to a fourth embodiment of the present invention. As shown in FIG. 10, the DC-DC converter 300 of this embodiment is provided between two charging / discharging means 302 and 304, and direct current is transferred from the charging / discharging means 302 on the input side to the charging / discharging means 304 on the output side. This is a two-phase multi-phase DC-DC voltage converter that steps down and supplies electric power. Similarly to the charging / discharging means 12 and 14 of the first embodiment, the charging / discharging means 302 and 304 is a capacitor for storing electric power generated by a generator or the like of the vehicle, or a battery having a voltage such as 12 volts or 300 volts. It is used to drive auxiliary equipment such as vehicle headlights and air conditioners.

  The DC-DC converter 300 includes coils 308 and 310 having reactance L provided between the two charging / discharging units 302 and 304 described above, and first to fourth MOSFETs 311 that are four switching elements made of a semiconductor. ˜314. The first MOSFET 311 has one end connected to the input side charging / discharging means 302 and the other end connected to one end of the coil 308, and the second MOSFET 312 has one end connected to one end of the coil 308 and the other end grounded. The third MOSFET 313 has one end connected to the input side charging / discharging means 302 and the other end connected to one end of the coil 310. The fourth MOSFET 314 has one end connected to one end of the coil 310 and the other end. Is grounded. That is, one end of the coil 308 is connected to a connection point between the first MOSFET 311 and the second MOSFET 312, and one end of the coil 310 is connected to a connection point between the third MOSFET 313 and the fourth MOSFET 314. The other end of the coil 308 and the other end of the coil 310 are both connected to the output side charging / discharging means 304.

  The first MOSFET 311 has a body diode 316 between its source and drain, the second MOSFET 312 has a body diode 317 between its source and drain, and the third MOSFET 313 has a body diode 318 between its source and drain. In the fourth MOSFET 314, a body diode 319 is formed between its source and drain. The body diode 316 is a parasitic diode having a forward direction from one end side of the coil 308 and the second MOSFET 312 toward the charging / discharging unit 302, and the body diode 317 is one end side of the coil 308 and the first MOSFET 311 from the ground side. The body diode 318 is a parasitic diode whose forward direction is the direction from the other end side of the coil 310 and the fourth MOSFET 314 toward the charging / discharging means 302, and The body diode 319 is a parasitic diode whose forward direction is from the ground side toward the other end side of the coil 310 and the third MOSFET 313 side.

  The gates of the first and fourth MOSFETs 311 to 314 are connected to a control unit 320 for switching and driving the MOSFETs 311 to 314, respectively. The control unit 320 includes a driver that drives each of the first to fourth MOSFETs 311 to 314 to be turned on and off. As will be described in detail later, the controller 320 appropriately controls switching of the DC-DC converter 300 to charge / discharge from the charging / discharging unit 302. Step-down conversion to the discharge means 304 is performed.

  The controller 320 includes a current sensor 322 for detecting a current flowing between the drain and source of the second MOSFET 312 and a current sensor 324 for detecting a current flowing between the drain and source of the fourth MOSFET 314. It is connected. The current sensor 322 outputs the drain voltage and the source voltage of the second MOSFET 312, that is, the voltages of the anode terminal and the cathode terminal of the body diode 317, to the control unit 320. Further, the current sensor 324 outputs the drain voltage and source voltage of the fourth MOSFET 314, that is, the voltages of the anode terminal and the cathode terminal of the body diode 319 to the control unit 320. The control unit 320 detects a current flowing in the forward direction of the body diode 317 in the second MOSFET 312 based on each voltage supplied from the current sensor 322, and uses the fourth voltage based on each voltage supplied from the current sensor 324. The current flowing in the forward direction of the body diode 319 in the MOSFET 314 is detected.

  In the present embodiment, the control unit 320 shifts the phase relative to the coil 308 and the first and second MOSFETs 311 and 312 and the coil 310 and the third and fourth MOSFETs 313 and 314 while shifting the phase. The same processing as in the first embodiment is executed to perform synchronous rectification control and soft start control. Therefore, in the system of this embodiment, after the operation of the DC-DC converter 300 is started, switching from the soft start control to the synchronous rectification control is performed from the charging / discharging means 304 on the output side to the second and fourth MOSFETs 312 and 314. It is possible to appropriately realize without flowing an overcurrent, to prevent an overcurrent from flowing to the second and fourth MOSFETs 312 and 314 during execution of the soft start control, and to further reduce the switching frequency. The same effect as that obtained by doubling can be obtained.

  Further, in this system, after starting the operation of the DC-DC converter 300, in order to cancel and end the soft start control and start the synchronous rectification control, the body diode 317, which flows through the second and fourth MOSFETs 312 and 314, It is necessary that the current in the forward direction of 319 be continuously equal to or greater than a predetermined value during the off-duty period of the first and third MOSFETs 311 and 313. This current detection is performed by the second and second semiconductor switching elements. This is based on the voltage generated across the body diodes 317 and 319 inevitably formed between the drain and source due to the structure of the fourth MOSFETs 312 and 314. For this reason, according to the configuration of the present embodiment, a dedicated component such as a shunt resistor is not separately provided on the path when performing current detection for determining the end of the soft start control in the DC-DC converter 300. As a result, the number of parts in the DC-DC converter 300 can be reduced, the manufacturing cost can be reduced, the size and weight can be reduced, and the power loss due to the presence of the shunt resistor can be reduced. It is possible to suppress the occurrence. Therefore, also in the system of the present embodiment, it is possible to appropriately realize the release / end of the soft start control after the operation of the DC-DC converter 300 is started without separately providing a component dedicated to current detection. Yes.

  In the fourth embodiment, the first MOSFET 311, the second MOSFET 312, the third MOSFET 313, and the fourth MOSFET 314 are included in the “one pair of switching elements” described in the claims. And the third MOSFET 313 corresponds to “one switching element” recited in the claims, and the second MOSFET 312 and the fourth MOSFET 314 correspond to “other switching elements” recited in the claims, respectively. Yes.

  In the fourth embodiment, the control unit 320 executes the synchronous rectification control for the DC-DC converter 300 so that the “normal control execution means” described in the claims executes the soft start control. Thus, the “soft start control execution means” described in the claims can be applied to the forward direction of the body diodes 317 and 319 between the drain and source of the second and fourth MOSFETs 312 and 314 using the current sensors 322 and 324. By detecting the current flowing through the first and third MOSFETs 311 and 313 during the execution of the soft start control, the “current detection means” described in the claims can detect the second and fourth currents. Current flowing in the forward direction of the body diodes 317 and 319 in the MOSFETs 312 and 314 is a predetermined value. Set forth in the appended claims by ending the soft-start control when a top state continues "soft-start control ending means" are realized respectively.

  By the way, in the fourth embodiment, the number of phases is set to two. However, the number of phases may be three or more. Further, although the multi-phase type DC-DC converter 300 is a step-down type, it may be applied to a step-up type or a step-up / step-down type DC-DC converter.

  Also in the second to fourth embodiments, the configurations shown in FIGS. 5 to 7 may be applied to the MOSFET that is the current sensor and the switching element, as in the first embodiment.

  Further, also in the second to fourth embodiments, the soft start control is performed by gradually increasing the on-duty period of one MOSFET and the order of the body diode flowing in the other MOSFET during the off-duty period of the MOSFET. When the current in the direction is less than a predetermined value, the other MOSFET may be turned off. On the other hand, when the current is higher than the predetermined value, the other MOSFET may be turned on. Even in such a configuration, even when the other MOSFET is turned on during the off-duty period of one MOSFET during execution of the soft start control, the on-state is only when current flows in the forward direction of the body diode. Since it is realized, it is avoided that an overcurrent flows from the charge / discharge means to the other MOSFET.

It is a block diagram of a system provided with the control apparatus of the DC-DC converter which is 1st Example of this invention. It is an operation | movement timing chart of the DC-DC converter of a present Example. It is a flowchart of an example of the control routine performed in a present Example. It is an operation | movement timing chart of the DC-DC converter which is a modification of this invention. It is a block diagram of a system provided with the control apparatus of the DC-DC converter which is a modification of this invention. It is a block diagram of a system provided with the control apparatus of the DC-DC converter which is a modification of this invention. It is a block diagram of a system provided with the control apparatus of the DC-DC converter which is a modification of this invention. It is a block diagram of a system provided with the control apparatus of the DC-DC converter which is 2nd Example of this invention. It is a block diagram of a system provided with the control apparatus of the DC-DC converter which is 3rd Example of this invention. It is a block diagram of a system provided with the control apparatus of the DC-DC converter which is 4th Example of this invention.

Explanation of symbols

10, 100, 200, 300 DC-DC converter 12, 14, 102, 104, 202, 204, 302, 304 Charge / discharge means 18, 108, 208, 308, 310 Coil 20 A pair of switching elements 22, 112, 211, 311 first MOSFET
24, 114, 212, 312 Second MOSFET
26, 28, 116, 118, 216 to 219, 316 to 319 Body diode 30, 120, 220, 320 Control unit 32, 122, 221, 222, 223, 224, 322, 324 Current sensor 213, 313 Third MOSFET
214, 314 Fourth MOSFET

Claims (3)

DC power is supplied from one charging / discharging unit to the other charging / discharging unit by inverting the pair of switching elements connected to a coil provided between two charging / discharging units and the pair of switching elements. A control device for a DC-DC converter, comprising:
At the start of operation, the on-duty period of one switching element is gradually increased while the other switching element is kept off, or during the off-duty period of the one switching element, the other is shorter than the off-duty period. Soft start control execution means for executing soft start control to turn on the switching element of
Current detecting means for detecting a current flowing in the forward direction of the parasitic diode that the other switching element has between both ends;
Soft start control ending means for ending the soft start control when the state in which the current detected by the current detection means is not less than a predetermined value of zero or more continues for a predetermined period during the execution of the soft start control;
A control device for a DC-DC converter, comprising:   The soft start control ending unit continues the off-duty period of the one switching element during execution of the soft start control, and when the current detected by the current detection unit is equal to or greater than the predetermined value, 2. The control apparatus for a DC-DC converter according to claim 1, wherein the soft start control is terminated.   The soft start control execution means is configured such that, during the off-duty period of the one switching element during execution of the soft start control, the current detected by the current detection means is greater than or equal to the predetermined value. 3. The control device for a DC-DC converter according to claim 1, wherein the controller is turned on when the current is detected, and is turned off when the current detected by the current detection means is less than the predetermined value.

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