JP2013102692A - Driving circuit for switching element and manufacturing method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a new driving circuit including an integrated circuit which drives a switching element to be driven in a voltage control type; and a manufacturing method thereof.SOLUTION: A driving circuit for a switching element including an integrated circuit which drives a switching element to be driven in a voltage control type, comprises: a charging path for charging electric charge to an opening/closing control terminal of the switching element to be driven. The integrated circuit comprises: an inside circulation regulation element which regulates a current amount; control means which controls circulation and blockage of the current via the charging path; a switching circuit which switches between connecting to an external output terminal included in the integrated circuit, and using the inside circulation regulation element as the charging path by connecting the output terminal of the control means to the member in the integrated circuit; and operation means which performs the switching by operating the switching circuit on the basis of a signal from an external input terminal of the integrated circuit.

Description

  The present invention relates to a driving circuit that drives a voltage-controlled driving target switching element and includes an integrated circuit, and a manufacturing method thereof.

  As a switching element driving circuit, as shown in, for example, Patent Document 1 below, a circuit that charges a gate of a switching element using a constant current circuit has been proposed.

JP 2009-11049 A

  By the way, in recent years, a technology for realizing most of the functions of a drive circuit by an integrated circuit has been put into practical use because of demands for downsizing and cost reduction of the drive circuit. However, when a constant current circuit is mounted in an integrated circuit, the current value of the constant current circuit must be equal to or less than the current (rated current) that can flow without exceeding the upper limit value of the temperature at a predetermined frequency. . On the other hand, when the switching speed of the switching state of the drive target switching element is large, the required current value is large compared to the small switching speed. Moreover, since the thing with a high operating frequency of a drive object switching element has a large heat loss compared with a low thing, it is easy to exceed the upper limit of temperature. For this reason, in order to provide versatility for the purpose of mass production of integrated circuits, it is necessary to set the required current value as the rated current for those having a high switching speed and a high operating frequency. This causes an increase in the size of the integrated circuit, and a circuit having a margin more than necessary for one having a low switching speed and a low driving frequency. This problem is particularly serious in view of the relatively small need for the entire drive circuit although the switching speed of the switching state is particularly high or the drive frequency is particularly high.

  The present invention has been made in the process of solving the above-described problems, and an object of the present invention is to provide a new driving circuit that drives a voltage-controlled driving target switching element and includes an integrated circuit, and a manufacturing method thereof. It is in.

  Hereinafter, means for solving the above-described problems and the operation and effect thereof will be described.

  A first configuration is a drive circuit that drives a voltage-controlled drive target switching element and includes an integrated circuit, and includes a charging path for charging an opening / closing control terminal of the drive target switching element. In the path, a resistor and an external switching element externally attached to the integrated circuit are connected in series, and the integrated circuit includes an internal switching element connected to the external switching element by Darlington connection. And a control means for outputting a signal for controlling the voltage drop amount of the resistor to a specified value at the open / close control terminal of the inner switching element.

  In the above invention, by connecting the outer switching element to the inner switching element by Darlington connection, even when the outer switching element is used, the same processing as when the outer switching element is not used (the voltage drop amount of the resistor is a specified value). Constant current control can be performed by a process of operating the open / close control terminal of the inner switching element to control the switching of the inner switching element.

  The “charge” is not defined as positive or negative. For this reason, charging with negative charge means discharging with positive charge.

  According to a second configuration, in the first configuration, the charging path is for charging a positive charge to an opening / closing control terminal of the driving target switching element, and the second path is one of the pair of terminals of the inner switching element. The terminal on the output side of the current is connected to the terminal on the output side of the pair of terminals of the drive target switching element.

  According to a third configuration, in the first configuration, the charging path is for charging a positive charge to an opening / closing control terminal of the drive target switching element, and the third path is one of the pair of terminals of the inner switching element. A terminal on the current output side is connected to a terminal on the current output side of the pair of terminals of the outer switching element.

  In the said invention, the positive charge output from the terminal of the output side of an inner side switching element can be effectively utilized as a charge charged to the switching control terminal of a drive object switching element.

  According to a fourth configuration, in the first configuration, the charging path is for charging a negative charge to an opening / closing control terminal of the driving target switching element, and the fourth path is one of a pair of terminals of the inner switching element. The terminal on the output side of the current and the switching control terminal of the outer switching element are connected.

  A fifth configuration is characterized in that, in any one of the first to fourth configurations, at least a part of the resistor is externally attached to the integrated circuit.

  The current value of the charging path is different between when the charging path is configured by the outer switching element and the current flowing therethrough is controlled, and when the charging path is configured by the inner switching element and the current flowing through the charging path is controlled. There is. In this case, if the resistance values of the resistors are the same, the amount of voltage drop changes, so it is necessary to change the setting of the control means for performing constant current control based on the amount of voltage drop. In this regard, in the above invention, by externally attaching a resistor, it is easy to adjust the resistance value so that the voltage drop amount corresponding to the target value of the current is the same when the outer switching element is used and when it is not used. It becomes. For this reason, the target value of the current can be changed without changing the setting of the control means.

  The invention according to claim 1 is a drive circuit that drives a voltage-controlled drive target switching element and includes an integrated circuit, and includes a charging path for charging an opening / closing control terminal of the drive target switching element, The integrated circuit includes an inner flow regulating element that regulates an amount of current, a control unit that controls flow and interruption of current through the charging path, and an output terminal of the control unit connected to a member in the integrated circuit A switching circuit for switching whether to use the inner flow restriction element as the charging path or to connect to an external output terminal of the integrated circuit, and to operate the switching circuit based on a signal from the external input terminal of the integrated circuit And operating means for performing the switching.

  In the above invention, since the switching circuit can be operated by inputting a signal from the external input terminal, whether or not the inner flow restriction element is used as a charge charging path to the open / close control terminal of the drive target switching element. Accordingly, the member operated by the control means can be changed.

  According to a second aspect of the present invention, in the first aspect of the present invention, a resistor is provided in the charging path, and the control means controls the voltage drop amount of the resistor to a constant value. A signal is output, and the switching circuit switches whether the control means is connected to an open / close control terminal of an inner switching element as the inner flow restricting element or to an external output terminal included in the integrated circuit. It is characterized by being.

  In the said invention, the electric current which flows through a charge path | route can be controlled to a fixed value by outputting a signal from the said control means to the switching control terminal of the switching element which comprises a charge path | route.

  According to a third aspect of the invention, in the second aspect of the invention, the external input terminal is a dedicated terminal for instructing the switching.

  According to a fourth aspect of the present invention, in the second aspect of the invention, the external input terminal includes a plurality of terminals for inputting a detection signal of a detection unit for a state quantity of the drive target switching element, and the operation The means determines whether or not the detection means is connected to any of the external input terminals. If it is determined that the detection means is connected, the control means operates the switching circuit to output the control means to the external output. It is connected to a terminal.

  When excessive current flows through the driving target switching element or when the temperature becomes excessively high, it is necessary to limit the driving of the driving target switching element. Is well known in the art. On the other hand, a plurality of drive target switching elements may be connected in parallel from the viewpoint of the rated current for the drive target switching element. In this case, the state quantity detection means also tends to be provided for each of the plurality of drive target switching elements. For this reason, in order to give versatility to the integrated circuit, it is desirable to provide a plurality of external input terminals to which the detection means is connected.

  Here, since the amount of current required for performing constant current control is smaller as the number of parallel connection (including 1) of the switching elements to be driven is smaller, the charging path can be configured by the inner switching elements. In this case, since there is an external input terminal that is not connected to the detection means, it is possible to determine whether or not the charging path is configured by the inner switching element based on the presence or absence of this connection.

  According to a fifth aspect of the present invention, in the second aspect of the invention, the external input terminal is a power supply terminal of the integrated circuit, and the operation means switches the switching according to a voltage value applied to the power supply terminal. It is characterized by operating a circuit.

  In the above invention, since the operation means is instructed using the power supply terminal, it is possible to avoid providing a dedicated terminal in the integrated circuit for the instruction of the operation means.

  The invention according to claim 6 is the invention according to claim 2, wherein the external input terminal is a terminal to which an operation signal for instructing on / off of the drive target switching element is input, and the operation means includes: The switching circuit is operated based on a difference between a signal input to the external input terminal and the operation signal.

  In the above invention, since the operation means is instructed using the terminal to which the operation signal is input, it is possible to avoid providing a dedicated terminal in the integrated circuit for the instruction of the operation means.

  According to a seventh aspect of the present invention, in the invention according to any one of the second to sixth aspects, at least a part of the resistor is externally attached to the integrated circuit.

  In the case where the charging path is configured by the switching element outside the integrated circuit (outer switching element) and the current flowing therethrough is controlled, and in the case where the charging path is configured by the inner switching element and the current flowing through the charging path is controlled, The current value of the charging path may be different. In this case, if the resistance values of the resistors are the same, the amount of voltage drop changes, so it is necessary to change the setting of the control means for performing constant current control based on the amount of voltage drop. In this regard, in the above invention, by externally attaching a resistor, it is easy to adjust the resistance value so that the voltage drop amount corresponding to the target value of the current is the same when the outer switching element is used and when it is not used. It becomes. For this reason, the target value of the current can be changed without changing the setting of the control means.

  The invention according to claim 8 is an internal flow restricting element that is a flow restricting element that restricts a current amount in a current flow path in a drive circuit that drives a voltage-controlled driving target switching element and includes an integrated circuit, A forming step of forming, by the integrated circuit, a control means for controlling the flow and interruption of the current in the charging path of the switching control terminal of the driving target switching element; and the charging path according to a request for use of the driving target switching element. A determination step for determining whether or not to use the inner flow restriction element; and if negative determination is made by the determination step, an outer flow restriction element is provided outside the integrated circuit and current flow in the outer flow restriction element A path connected to the open / close control terminal of the drive target switching element, and a current flow through the outer flow restricting element. An external step of connecting the outer flow restricting element to the integrated circuit so that passage and shut-off are controlled by the control means; and when the affirmative judgment is made by the judging step, the inner flow restricting element is switched to the drive target switching And an internal process for connecting to the open / close control terminal of the element.

  In the above invention, since it is possible to select whether or not the inner flow restriction element is used for the charging path, the inner flow restriction element is not required to have an excessively large rated current or excessive heat resistance performance. For this reason, it becomes easy to reduce the size of the integrated circuit. Moreover, even if it is a case where it chooses not to use, the component of an integrated circuit can be utilized as much as possible, and the versatility of the component in an integrated circuit can also be improved by extension.

  The “charge” is not defined as positive or negative. For this reason, charging with negative charge means discharging with positive charge.

  The invention according to claim 9 is the invention according to claim 8, wherein a resistor is provided in a charge charging path to the switching control terminal of the drive target switching element, and the integrated circuit is connected to the inner side. An inner switching element as a flow regulating element, and the control means is a control means for outputting a signal for controlling a voltage drop amount of the resistor to a specified value at an open / close control terminal of the inner switching element, The externally attaching step is a step of Darlington connection of the outer switching element as the outer flow restricting element to the inner switching element.

  In the above invention, by connecting the outer switching element to the inner switching element by Darlington connection, even when the outer switching element is used, the same processing as when the outer switching element is not used (the voltage drop amount of the resistor is a specified value). Constant current control can be performed by a process of operating the open / close control terminal of the inner switching element to control the switching of the inner switching element.

  According to a tenth aspect of the present invention, in the eighth aspect of the present invention, a resistor is provided in the charge charging path to the open / close control terminal of the drive target switching element, and the forming step is performed on the inner side. An inner switching element as a flow restricting element, a control means for outputting a signal for controlling a voltage drop amount of the resistor to a specified value, and the control means is connected to the inner switching element or provided in the integrated circuit A step of forming, by the integrated circuit, a switching circuit for switching whether to connect to an external output terminal and an operating means for performing the switching by operating the switching circuit based on a signal from an external input terminal of the integrated circuit. It is characterized by that.

  In the above invention, the switching circuit and the operating means are formed in the integrated circuit in the forming step, so that depending on whether the inner flow restricting element or the outer flow restricting element is used according to the signal of the external input terminal. Appropriate processing can be performed.

1 is a system configuration diagram according to a first embodiment. FIG. The circuit diagram which shows the circuit structure of the drive unit concerning the embodiment. The circuit diagram which shows the circuit structure of the drive unit concerning the embodiment. The flowchart which shows the manufacturing process of the drive unit concerning the embodiment. The circuit diagram which shows the circuit structure of the drive unit concerning 2nd Embodiment. The circuit diagram which shows the circuit structure of the drive IC concerning 3rd Embodiment. The circuit diagram which shows the circuit structure of the drive IC concerning 4th Embodiment. The circuit diagram which shows the circuit structure of the drive IC concerning 5th Embodiment. The circuit diagram which shows the circuit structure of the drive IC concerning 6th Embodiment.

<First Embodiment>
Hereinafter, a first embodiment in which a drive device for a power switching element according to the present invention is applied to a hybrid vehicle will be described with reference to the drawings.

  FIG. 1 shows the system configuration of this embodiment. As shown in the figure, a motor generator 10 as an in-vehicle main machine is connected to a high voltage battery 12 having a terminal voltage of, for example, 100 V or more via an inverter IV and a converter CV. The inverter IV is configured by connecting three series-connected bodies of a switching element Swp on the high potential side and a switching element Swn on the low potential side in parallel. Connection points of these switching elements Swp and switching elements Swn are connected to the respective phases of motor generator 10. Converter CV connects capacitor C, a series connection body of switching element Swp on the high potential side and switching element Swn on the low potential side, a connection point of switching element Swp and switching element Swn, and high voltage battery 12. And a reactor L.

  Between the input / output terminals (between the collector and the emitter) of the switching element Swp on the high potential side and the switching element Swn on the low potential side, the free wheel diode FDp on the high potential side and the free wheel diode FDn on the low potential side are connected. The cathode and anode are connected.

  A drive unit DU is connected to the open / close control terminals (gates) of the switching elements Swp and Swn constituting the inverter IV. As a result, the switching element Sw # (# = p, n) is driven by the control device 16 that uses the low-voltage battery 14 whose terminal voltage is lower than that of the high-voltage battery 12 as a power source via the drive unit DU. The control device 16 controls the operation signals gup, gvp, gwp for operating the switching elements Swp for the U phase, the V phase, and the W phase of the inverter IV, and the switching elements Swn based on detection values of various sensors (not shown). Operation signals gun, gvn, and gwn are generated and output. Further, operation signals gcp and gcn for operating the switching elements Swp and Swn of the converter CV are generated and output. As a result, the switching elements Swp and Swn are operated by the control device 16 via the drive unit DU.

  Note that the high voltage system including the inverter IV and the converter CV and the low voltage system including the control device 16 are insulated by an insulating means such as a photocoupler (not shown), and the operation signal is high via the insulating means. Output to the voltage system.

  Each of the switching elements Sw # is composed of an insulated gate bipolar transistor (IGBT). Further, the switching element Sw # includes a sense terminal St that outputs a minute current having a correlation with a current flowing between the input terminal and the output terminal.

  FIG. 2 shows a circuit configuration of the drive unit DU according to the present embodiment.

  As illustrated, the drive unit DU includes a semiconductor integrated circuit (drive IC 30). The drive IC 30 uses the power supply 20 as a power supply means. The power source 20 may be, for example, the output side of a flyback converter that receives the low-voltage battery 14, but it is more preferable that the output voltage of the flyback converter is adjusted by a series regulator. The power supply 20 is connected to the source of a P-channel MOS field effect transistor (switching element 32) constituting a constant current circuit in the drive IC 30 via the resistor 22 and the terminal T1, and the drain of the switching element 32 is connected to the terminal T2 Is connected to an open / close control terminal (gate) of the switching element Sw # (# = p, n).

  The voltage at the switching control terminal (gate) of the switching element 32 is operated by the operational amplifier 34. That is, the reference voltage Vref of the reference power supply 36 is applied to the plus input terminal of the operational amplifier 34, and the minus input terminal is the terminal T3 that has the voltage of the power supply 20 decreased by the amount of voltage drop due to the resistor 22. Is applied. Thereby, the gate voltage of the switching element 32 is controlled so that the voltage drop amount of the resistor 22 becomes a specified value (a value obtained by subtracting the reference voltage from the voltage of the power supply 20). As a result, the resistor 22 and the switching element 32 are controlled. The current flowing through the positive charge charging path to the gate of the switching element Sw # is controlled to a constant value. Note that the output terminal of the operational amplifier 34 is pulled up to the power source 20 via the malfunction preventing resistor 38 and the terminal T4. This is to prevent the operational amplifier 34 from malfunctioning. A protective resistor 40 is provided between the gate and source of the switching element 32. This is to avoid a situation where a voltage exceeding the withstand voltage is applied between the source and gate of the switching element 32.

  The gate of the switching element Sw # is connected to the drain of the N-channel MOS field effect transistor (switching element 42) via the terminal T5 of the drive IC 30, and the source is connected to the switching element Sw # via the terminal T6 and the resistor 24. Connected to the emitter. The emitter of the switching element Sw # is connected to the terminal T8 of the drive IC 30. In the drive IC 30, the potential of the terminal T8 is set as a reference potential.

  The gate voltage of the switching element 42 is operated by the operational amplifier 44. The reference voltage Vref of the reference power source 36 is applied to the negative input terminal of the operational amplifier 44, and a voltage higher than the emitter voltage of the switching element Sw # by the voltage drop amount of the resistor 24 is applied to the positive input terminal at the terminal T7. It is applied through. Thereby, the gate voltage of the switching element 42 is controlled so that the voltage drop amount of the resistor 24 becomes equal to the reference voltage Vref. Therefore, the current flowing through the gate discharge path (negative charge charging path) of the switching element Sw # configured to include the switching element 42 and the resistor 24 is controlled to a constant value. The output terminal of the operational amplifier 44 is pulled down to the reference potential via the malfunction prevention resistor 46. This is for preventing the operational amplifier 44 from malfunctioning. A protective resistor 48 is provided between the gate and source of the switching element 42. This is to avoid a situation where a voltage exceeding the withstand voltage is applied between the source and gate of the switching element 42.

  The operations of the operational amplifiers 34 and 44 are controlled by a drive control circuit 50. The drive control circuit 50 controls the operation of the operational amplifiers 34 and 44 based on the operation signal g * # (* = u, v, w, c; # = p, n) input via the terminal T9. That is, when the operation signal g * # is an on operation command, the operational amplifier 34 is driven to turn on the switching element 32, while when the operation signal g * # is an off operation command, the switching element 42 is turned on. Therefore, the operational amplifier 44 is driven.

  The external attachment of the resistors 22 and 24 to the drive IC 30 is related to facilitating the use of the drive IC 30 in a wide range of applications as a versatile circuit while reducing the size. Specifically, in the present embodiment, the drive IC 30 is also used for a switching element Sw # having a high switching speed and high switching frequency. Here, when the switching speed and the switching frequency are high, the heat generation of the switching elements 32 and 42 increases. For this reason, when constant current control is performed using the drive IC 30, it is necessary to enlarge the drive IC 30. On the other hand, in this embodiment, as shown in FIG. 3, the function of the drive IC 30 is used for the function of using the operational amplifiers 34 and 44 according to the input of the operation signal g * # (function to turn on / off). However, a current distribution restriction element in the charging path of positive and negative charges to the gate of the switching element Sw # is externally attached to the drive IC 30 according to the situation.

  That is, as shown in FIG. 3, a P-channel MOS field effect transistor (switching element 60) is connected to the switching element 32, and an N-channel MOS field effect transistor (switching element 64) is connected to the switching element 42, respectively. .

  Specifically, the gate of the switching element 60 is connected to the source of the switching element 32 via the terminal T1, and the source of the switching element 60 is connected to the power source 20 via the resistor 22, The drain of 60 is connected to the gate of the switching element Sw #. The drain of the switching element 32 is set to the same potential as the emitter of the switching element Sw # via the terminal T2. According to such a configuration, the gate voltage of the switching element 32 is manipulated so that the voltage drop amount of the resistor 22 becomes a specified value (a value obtained by subtracting the reference voltage Vref from the voltage of the power supply 20). The current flowing through the switching element 60 is controlled.

  On the other hand, the gate of the switching element 64 is connected to the source of the switching element 42 via the terminal T6, and the source of the switching element 64 is set to the same potential as the emitter of the switching element Sw # via the resistor 24. The drain of the switching element 64 is connected to the gate of the switching element Sw #. Note that the drain of the switching element 42 is pulled up to the power source 20 via the terminal T5. According to such a configuration, the gate voltage of the switching element 42 is operated so that the voltage drop amount of the resistor 24 becomes a specified value (reference voltage Vref), and the current flowing through the resistor 24 and the switching element 64 is controlled. The

  A protective resistor 62 is connected between the source and gate of the switching element 60, and a protective resistor 66 is connected between the source and gate of the switching element 64.

  FIG. 4 shows a manufacturing procedure of the drive unit DU according to the present embodiment.

  In this series of processing, first, in step S10, request information about the switching speed and switching frequency of the switching element Sw # is acquired. In step S12, based on the request information, it is determined whether switching elements 32 and 42 in drive IC 30 can be used as a charging path for positive and negative charges to the gate of switching element Sw #. This determination is based on whether or not the current for satisfying the switching speed requirement is less than or equal to the rated current of the switching elements 32 and 42 and whether or not the heat generated in the drive IC 30 according to the switching speed and frequency is within an allowable range. This is based on whether or not. If a negative determination is made in step S12, it is determined in step S14 that the external switching elements 60 and 64 are employed, and the switching elements 60 and 64 are connected to the drive IC 30. On the other hand, if an affirmative determination is made in step S12, it is determined in step S16 that the switching elements 32 and 42 in the drive IC 30 are adopted as the charging path for the switching element Sw #, and the switching elements 32 and 42 are switched. Connected to the gate of the element Sw #.

  According to the embodiment described in detail above, the following effects can be obtained.

  (1) The switching elements 60 and 64 external to the drive IC 30 are connected to the switching elements 32 and 42 by Darlington connection in accordance with the magnitude of the charge / discharge current of the gate of the switching element Sw # and the switching speed. Thus, even when the switching elements 60 and 64 are used, the same processing as when the switching elements 60 and 64 are not used (the switching element 32 is used to control the voltage drop amount of the resistors 22 and 24 to a specified value). , 42 is operated), constant current control can be performed.

  (2) The resistors 22 and 24 are externally attached to the drive IC 30. Thereby, it is easy to adjust the resistance value so that the voltage drop amount corresponding to the target value of the current is the same when the switching elements 60 and 64 are used and when the switching elements 60 and 64 are not used.

<Second Embodiment>
Hereinafter, the second embodiment will be described with reference to the drawings with a focus on differences from the first embodiment.

  FIG. 5 shows a Darlington connection method according to the present embodiment. In FIG. 5, the same reference numerals are given for the sake of convenience corresponding to the members shown in FIG. 3.

  As illustrated, in the present embodiment, the drain of the switching element 32 is connected to the drain of the switching element 60 via the terminal T2. Thereby, the current flowing through switching element 32 can be used as the charging current for the gate of switching element Sw #.

<Third Embodiment>
Hereinafter, the third embodiment will be described with reference to the drawings with a focus on differences from the first embodiment.

  FIG. 6 shows a configuration of the drive IC 30 according to the present embodiment. In FIG. 6, the same reference numerals are assigned for convenience to those corresponding to the members shown in FIG. 2.

  As shown in the figure, the present embodiment includes a switching circuit 70 that switches whether the output terminal of the operational amplifier 34 is connected to the gate of the switching element 32 or to the terminal T1. Further, a switching circuit 72 is provided for switching whether the output terminal of the operational amplifier 44 is connected to the gate of the switching element 42 or to the terminal T6. These switching circuits 70 and 72 can be switched from the outside via a dedicated terminal T10 for operating the switching circuits 70 and 72 among the terminals of the drive IC 30. Here, by operating the switching circuits 70 and 72, the output terminal of the operational amplifier 34 is connected to the gate of the switching element 32, and the output terminal of the operational amplifier 44 is connected to the gate of the switching element 42, so that FIG. A constant current circuit identical to that shown in FIG. When the output terminal of the operational amplifier 34 is connected to the terminal T1 and the output terminal of the operational amplifier 44 is connected to the terminal T6, the terminals T1 and T6 are used as the gate voltage application means for the switching elements 60 and 64. Thus, a constant current circuit can be configured.

  According to this embodiment described above, in addition to the effect (2) of the first embodiment, the following effect can be obtained.

  (3) The switching circuits 70 and 72 are provided, and the switching circuits 70 and 72 can be operated via the dedicated terminal T10. Thereby, the operation target of the operational amplifiers 34 and 44 can be changed.

<Fourth Embodiment>
Hereinafter, the fourth embodiment will be described with reference to the drawings with a focus on differences from the third embodiment.

  FIG. 7 shows a configuration of the drive IC 30 according to the present embodiment. In FIG. 7, the same reference numerals are attached for convenience to those corresponding to the members shown in FIG.

  In the present embodiment, the switching circuits 70 and 72 are switched according to the voltage of the power supply 20. That is, the comparator 74 compares the voltage of the terminal T4 connected to the power supply 20 with the threshold voltage Vth of the threshold power supply 76, and the switching circuits 70 and 72 are operated based on the output signal of the comparator 74. For example, if the output terminal of the flyback converter that uses the low voltage battery 14 as the input voltage is the power source 20, the voltage of the power source 20 can be adjusted by the time ratio control of the switching elements that constitute the power source 20. Further, for example, when a series regulator for adjusting the output voltage of the flyback converter is provided, the voltage of the power supply 20 may be adjusted by adjusting the voltage of the series regulator.

  According to this embodiment described above, in addition to the effect (2) of the first embodiment, the following effect can be obtained.

  (4) By operating the switching circuits 70 and 72 based on the voltage applied to the terminal T4, an increase in the number of terminals of the drive IC 30 can be avoided.

<Fifth Embodiment>
Hereinafter, the fifth embodiment will be described with reference to the drawings with a focus on differences from the third embodiment.

  FIG. 8 shows a configuration of the drive IC 30 according to the present embodiment. In FIG. 8, components corresponding to those shown in FIG. 6 are given the same reference numerals for convenience.

  In the present embodiment, a switching operation circuit 78 that operates the switching circuits 70 and 72 based on a signal input from the terminal T9 is provided. Here, the switching operation circuit 78 operates the switching circuits 70 and 72 based on a signal input via the terminal T9 within a time having a predetermined length from the timing when the drive IC 30 is powered on. This is because the terminal T9 is basically a terminal to which the operation signal g * # (* = u, v, w; # = p, n) is input. That is, immediately after the drive IC 30 is powered on, the inverter IV and the converter CV are not operated by the operation signal g * #. Therefore, during this period, the operation signals of the switching circuits 70 and 72 are sent via the terminal T9. Enter.

  However, the processing of the switching operation circuit 78 is not limited to the input signal at the terminal T9 immediately after the drive IC 30 is powered on. For example, the switching circuits 70 and 72 may be operated according to the switching frequency of the operation signal g * #. That is, since the amount of heat generated in the drive IC 30 tends to increase as the switching frequency increases, a request to use the external switching elements 60 and 64 arises. For this reason, the switching circuits 70 and 72 can be appropriately switched by storing the switching frequency when using the external switching elements 60 and 64 as the threshold frequency in the switching operation circuit 78.

  According to this embodiment described above, in addition to the effect (2) of the first embodiment, the following effect can be obtained.

  (5) By operating the switching circuits 70 and 72 based on the signal input from the terminal T9, an increase in the number of terminals of the drive IC 30 can be avoided.

<Sixth Embodiment>
Hereinafter, the sixth embodiment will be described with reference to the drawings with a focus on differences from the third embodiment.

  FIG. 9 shows a configuration of the drive IC 30 according to the present embodiment. In FIG. 9, components corresponding to those shown in FIG. 6 are given the same reference numerals for convenience.

  As shown in the drawing, in the present embodiment, the function of the drive IC 30 is specified specifically for dealing with an abnormality in which an overcurrent flows through the switching element Sw # and an abnormality in which the temperature of the switching element Sw # becomes excessively high. That is, the voltage drop amount at the shunt resistor 80 due to the minute current output from the sense terminal St of the switching element Sw # is taken into the terminal T11a. The voltages applied to the terminals T11a and T11b are respectively compared with the voltage V1 of the power source 86 in the comparators 82 and 84. Here, the voltage V1 corresponds to a voltage drop amount in the shunt resistor 80 when a threshold current flows through the switching element Sw #. The output signals of the comparators 82 and 84 are logically synthesized by the OR circuit 88 and then taken into the drive control circuit 50. As a result, when the comparators 82 and 84 determine that the applied voltages at the terminals T11a and T11b are larger, the drive control circuit 50 stops driving the operational amplifiers 34 and 44, and the switching element Sw # is forcibly turned off. Is done. At this time, it is assumed that a known path for forcibly discharging the gate charge is provided, but the description is omitted in FIG. 9 for convenience.

  On the other hand, the output voltage of the temperature sensitive diode SD that detects the temperature of the switching element Sw # is taken into the terminal T12a. The voltages applied to the terminals T12a and T12b are compared with the voltage V2 of the power supply 94 in the comparators 90 and 92, respectively. Here, the voltage V2 is a value of the output voltage of the temperature sensitive diode SD corresponding to the allowable limit temperature (threshold temperature) of the switching element Sw #. The output signals of the comparators 90 and 92 are logically synthesized by the OR circuit 96 and taken into the drive control circuit 50. As a result, when the comparators 82 and 84 determine that the voltages applied to the terminals T12a and T12b are smaller, the drive control circuit 50 stops driving the operational amplifiers 34 and 44, and the switching element Sw # is forcibly turned off. Is done. Here, it is assumed that the output voltage of the temperature sensitive diode SD has a negative correlation with the temperature.

  Here, the terminals T11b and T12b are used when the switching elements Sw # are connected in parallel and are driven by the same operation signal g * #. The switching element Sw # is connected in parallel when the maximum value of the current flowing through the switching element Sw # is large. When the switching element Sw # is used in parallel, a voltage drop amount corresponding to the current output from the sense terminal St of each switching element Sw # is applied to each of the terminals T11a and T11b. In addition, the output voltage of the temperature sensitive diode SD that senses the temperature of each switching element Sw # is applied to the terminals T12a and T12b.

  By the way, when parallel use is performed, the charge amount of the gate of the switching element Sw # is increased, so that it is necessary to increase the constant current of the constant current circuit. On the other hand, when the constant current increases, it becomes difficult to use the circuit in the drive IC 30. Therefore, in this embodiment, when the switching element Sw # is used in parallel, the output terminals of the operational amplifiers 34 and 44 are connected to the terminals T1 and T6 by the switching circuits 70 and 72, respectively, and the external switching element 60, 64 is used. On the other hand, as shown in FIG. 9, when the switching element Sw # is a single switching element, a constant current circuit is configured using the switching elements 32 and 42. Here, the switching circuits 70 and 72 are operated by the switching operation circuit 100 based on the voltage at the terminal T12b. In the present embodiment, the terminal T12b is connected to the power source 20 when the parallel connection is not made. As a result, when the parallel connection is not made, a voltage that cannot be assumed when the parallel connection is made is applied to the terminal T12b. , 72 can be operated.

  According to this embodiment described above, in addition to the effect (2) of the first embodiment, the following effect can be obtained.

(5) By operating the switching circuits 70 and 72 based on the signal input from the terminal T12b, an increase in the number of terminals of the drive IC 30 can be avoided.
<Other embodiments>
Each of the above embodiments may be modified as follows.

"Regulators for constant current circuit"
The resistors 22 and 24 for controlling the voltage drop amount to the specified value are not limited to those externally attached to the drive IC 30. For example, a part thereof may be mounted in the drive IC 30. Further, for example, a resistor may be provided outside the drive IC 30 only when the switching elements 32 and 42 are used as elements for supplying a constant current for charging / discharging the gate of the switching element Sw # or not. That is, for example, when the switching elements 32 and 42 are employed as elements for supplying a constant current for charging / discharging the gate of the switching element Sw #, a resistor in the drive IC 30 and an external resistor are connected in series to perform switching. When the elements 60 and 64 are employed, only the resistor in the drive IC 30 may be used. Conversely, for example, when the switching elements 32 and 42 are employed as elements for supplying a constant current for charging and discharging the gate of the switching element Sw #, only the resistor in the drive IC 30 is used, and the switching elements 60 and 64 are employed. In this case, an external resistor may be connected in parallel to the resistor in the drive IC 30. This is because a larger resistance value is required when switching elements 32 and 42 are used as elements for supplying a constant current to charge and discharge the gate of switching element Sw # than when switching elements 60 and 64 are used. In view of the above.

  Further, when the charge / discharge current amount of the gate is the same, the voltage drop amount is controlled to a specified value when selecting the switching elements 32 and 42 or the switching elements 32 and 42 according to the driving frequency. All of the resistors 22 and 24 may be mounted in the drive IC 30. However, even if the amount of current changes, all of the resistors may be mounted on the drive IC 30 so that the resistance value can be adjusted via the external connection terminal. Further, by changing the voltage applied to the resistor 22, the amount of voltage drop may be constant regardless of the change in the amount of current.

"Constant current circuit"
The switching element for passing a constant current is not limited to a MOS field effect transistor. For example, a bipolar transistor may be used.

  The flow restricting element constituting the constant current circuit is not limited to one consisting of one switching element. For example, the base of the first bipolar transistor and the collector of the second bipolar transistor are connected, a resistor is connected between the collector and the base of the first bipolar transistor, and the resistor is connected between the base and the emitter of the second bipolar transistor. The transistor circuit may be connected to each other.

  The constant current circuit may be, for example, a series connection body of a constant current diode and a switching element.

  The control means constituting the constant current circuit is not limited to the operational amplifier. For example, when the flow regulating element is a series connection body of a constant current diode (or the above transistor circuit) and a switching element, the switching element constituting either the series connection body inside the drive IC 30 or the external series connection body is turned on / off. It may be a means for operating. As described above, if the switching element corresponding to whether the switching element for opening and closing the charging path is provided inside or outside the drive IC 30 is turned on and off, the distribution regulation element is very wide. It is thought that various technologies can be applied. And if the switching function of the output and interruption | blocking of the electric current by such each distribution control element is comprised as a control means in drive IC30, the versatility can be improved.

"About switching elements to be driven"
The driving target switching element is not limited to the IGBT. For example, a power MOS field effect transistor may be used. In the case of using a P-channel one here, when the switching element is turned on, the open / close control terminal (gate) is charged with a negative charge (positive charge is discharged from the gate), and when the switching element is turned off, the gate is turned on. A positive charge will be charged.

"Detection means used for switching"
In the sixth embodiment, switching between the inner switching element and the outer switching element is performed based on whether or not the temperature-sensitive diode SD is connected, but the present invention is not limited to this. For example, the switching between the inner switching element and the outer switching element may be performed using whether or not the shunt resistor 80 for detecting a minute current output from the sense terminal St is connected.

"others"
-As a drive object switching element, it is not restricted to what comprises the power converter circuit (DC alternating current converter circuit and a converter) connected to a vehicle-mounted main machine. For example, a DC / AC conversion circuit for air conditioning connected to the high voltage battery 12 may be configured. However, the inverter is not limited to the one that constitutes the high-voltage battery 12, and may constitute an inverter of an electric power steering system that is connected to a converter that boosts the voltage of the low-voltage battery 14, for example.

  The malfunction preventing resistors 38 and 46 may not be provided.

  The protective resistors 40, 48, 62, 66 may not be provided. In particular, regarding the protective resistors 40 and 48 in the drive IC 30, when the internal circuit of the operational amplifier 44 can also serve as the protective resistor, it is desirable to reduce the number of parts by deleting this. .

  DESCRIPTION OF SYMBOLS 20 ... Power supply, 22, 24 ... Resistor, 30 ... Drive IC (one embodiment of integrated circuit), 32, 42 ... Switching element (one embodiment of inside switching element), 34, 44 ... Operational amplifier, 60, 64 ... Switching element (one embodiment of outer switching element).

Claims (10)

In a drive circuit that drives a voltage-controlled drive target switching element and includes an integrated circuit,
A charge path for charging the open / close control terminal of the drive target switching element;
The integrated circuit includes an inner flow regulating element that regulates an amount of current, a control unit that controls flow and interruption of current through the charging path, and an output terminal of the control unit connected to a member in the integrated circuit A switching circuit for switching whether to use the inner flow restriction element as the charging path or to connect to an external output terminal of the integrated circuit, and to operate the switching circuit based on a signal from the external input terminal of the integrated circuit And a switching element drive circuit, comprising: an operating means for performing the switching. The charging path is provided with a resistor,
The control means outputs a signal for controlling the voltage drop amount of the resistor to a constant value,
The switching circuit is configured to switch whether the control means is connected to an open / close control terminal of a switching element serving as the inner flow restriction element or to an external output terminal included in the integrated circuit. A driving circuit for a switching element according to 1.   3. The switching element drive circuit according to claim 2, wherein the external input terminal is a dedicated terminal for instructing the switching. The external input terminal includes a plurality of terminals for inputting a detection signal of a detection means for a state quantity of the driving target switching element,
The operation means determines whether or not the detection means is connected to any of the external input terminals. When it is determined that the detection means is connected, the control means is operated by operating the switching circuit. 3. The switching element drive circuit according to claim 2, wherein the switching element drive circuit is connected to an external output terminal. The external input terminal is a power supply terminal of the integrated circuit,
3. The switching element drive circuit according to claim 2, wherein the operation means operates the switching circuit in accordance with a voltage value applied to the power supply terminal. The external input terminal is a terminal to which an operation signal for on / off command of the driving target switching element is input,
3. The switching element drive circuit according to claim 2, wherein the operation means operates the switching circuit based on a difference between a signal input to the external input terminal and the operation signal.   7. The switching element drive circuit according to claim 2, wherein at least a part of the resistor is externally attached to the integrated circuit. In a drive circuit that drives a voltage-controlled drive target switching element and includes an integrated circuit,
The integrated circuit includes an inner flow restriction element that is a flow restriction element that restricts the amount of current in the current flow path, and a control unit that controls flow and interruption of current in the charging path of the switching control terminal of the driving target switching element. Forming process to form;
A determination step of determining whether or not to use the inner flow restriction element in the charging path according to a use request of the driving target switching element;
When a negative determination is made by the determination step, an outer flow restriction element is provided outside the integrated circuit, and a current flow path in the outer flow restriction element is connected to the open / close control terminal of the drive target switching element, and An external step of connecting the outer flow restricting element to the integrated circuit such that current flow and interruption through the outer flow restricting element is controlled by the control means;
A method of manufacturing a drive circuit, comprising: an internal connection step of connecting the inner flow restriction element to an open / close control terminal of the drive target switching element when an affirmative determination is made in the determination step. A resistor is provided in the charge charging path to the open / close control terminal of the drive target switching element,
The integrated circuit includes an inner switching element as the inner flow restriction element,
The control means is a control means for outputting a signal for controlling a voltage drop amount of the resistor to a specified value at an open / close control terminal of the inner switching element,
9. The method of manufacturing a drive circuit according to claim 8, wherein the externally attaching step is a step of Darlington connection of an outer switching element as the outer flow restricting element to the inner switching element. A resistor is provided in the charge charging path to the open / close control terminal of the drive target switching element,
The forming step includes an inner switching element as the inner flow restriction element, a control means for outputting a signal for controlling a voltage drop amount of the resistor to a specified value, and connecting the control means to the inner switching element. A switching circuit for switching whether to connect to an external output terminal included in the integrated circuit, and an operation means for performing the switching by operating the switching circuit based on a signal from an external input terminal of the integrated circuit. 9. The method of manufacturing a driving circuit according to claim 8, further comprising a step of forming the circuit.

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