WO2017125057A1 - 功率器件驱动装置 - Google Patents

功率器件驱动装置 Download PDF

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Publication number
WO2017125057A1
WO2017125057A1 PCT/CN2017/071794 CN2017071794W WO2017125057A1 WO 2017125057 A1 WO2017125057 A1 WO 2017125057A1 CN 2017071794 W CN2017071794 W CN 2017071794W WO 2017125057 A1 WO2017125057 A1 WO 2017125057A1
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Prior art keywords
power device
power
current limiting
capacitor
driving
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PCT/CN2017/071794
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English (en)
French (fr)
Inventor
郭桥石
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广州市金矢电子有限公司
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Priority claimed from CN201610117432.XA external-priority patent/CN105634457B/zh
Application filed by 广州市金矢电子有限公司 filed Critical 广州市金矢电子有限公司
Publication of WO2017125057A1 publication Critical patent/WO2017125057A1/zh

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    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02MAPPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
    • H02M1/00Details of apparatus for conversion
    • H02M1/06Circuits specially adapted for rendering non-conductive gas discharge tubes or equivalent semiconductor devices, e.g. thyratrons, thyristors

Definitions

  • the power device driving device of the invention belongs to the field of electricity, in particular to a power device driving device suitable for driving a power device in an alternating current system.
  • the driving signal is provided by the transformer, and needs a pulse signal generating circuit, a transformer driving circuit, a transformer, a rectifying circuit, and has a driving dead zone caused by a pulse duty ratio, a high frequency interference, a large harmonic generation, a large occupied space, and a low cost performance.
  • a pulse duty ratio a high frequency interference
  • a large harmonic generation a large occupied space
  • a low cost performance there is also a problem that the voltage resistance of the driving circuits of the two unidirectional thyristors is high, and the driving circuits of the two unidirectional thyristors have high requirements on the withstand voltage between the transformer driving circuits.
  • the object of the present invention is to provide a simple circuit, high reliability, low energy consumption, no high frequency interference, high cost performance, convenient use, and versatile power in view of the insufficiency of power device driving such as a unidirectional thyristor. Device driver.
  • a power device driving device includes a first current limiting component, a second current limiting component, a unidirectional conduction device, a capacitor, a voltage stabilizing device, a semiconductor switch, the first current limiting component, the unidirectional conduction device, and a
  • the capacitors are connected in series to form a first series circuit
  • the capacitors are connected in series to form a second series circuit
  • the capacitor passes through the semiconductor switch, and the required driving power a second end of the device, the third end of the power device forming a driving circuit
  • the first power source charges the capacitor through the first current limiting component
  • the second power source passes the capacitor through the second current limiting component Charging
  • the voltage stabilizing device is connected in parallel with the capacitor
  • the first end of the power device and the third end of the power device are main circuit ends of the power device.
  • a power device driving device comprising a first unidirectional conduction device, a second unidirectional conduction device, the first series connection circuit, the first current limiting component, the first unidirectional conduction device
  • the device and the capacitor are connected in series; the second series circuit is formed by connecting the second current limiting component, the second unidirectional conduction device, and the capacitor in series.
  • a power device driving device is connected in parallel with the capacitor through the unidirectional conduction device.
  • a power device driving device, the unidirectional conduction device is a diode, and the first current limiting element and the second current limiting element are resistors.
  • a power device driving device the second power source being provided by a neutral line or provided with respect to another phase line of the power device.
  • a power device driving device the first power source being provided by a first end of the power device.
  • a power device driving device the power device is a half-controlled device
  • the semiconductor switch is a voltage detecting switch
  • the semiconductor switch is connected to the power device
  • the semiconductor switch detects the power device The deadline is expired.
  • a power device driving device includes a resistor and a semiconductor device.
  • a power device driving device wherein the first power source and the second power source are powered by a non-isolated power supply of the power device.
  • a power device driving device for driving a power device of a semi-controlled or fully controlled device in anti-parallel.
  • a power device driving device wherein the power device is a unidirectional thyristor, a first end of the power device, a second end of the power device, and a third end of the power device are respectively a unidirectional thyristor An anode, a trigger pole of the unidirectional thyristor, and a cathode of the unidirectional thyristor.
  • a power device driving device wherein an average operating current through the first current limiting element and the second current limiting element is less than a minimum trigger current required by the unidirectional thyristor.
  • a power device driving device includes a photocoupler for controlling conduction of the unidirectional thyristor.
  • a power device driving device further comprising a lead, an insulating material, wherein the power device driving device is encapsulated in the insulating material, and the power device driving device is externally connected through the corresponding pin.
  • a power device driving device includes a first current limiting component R1, a second current limiting component R2, a unidirectional conduction device D1 (diode), a capacitor C1, a voltage stabilizing device Z1 (stabilizing diode), a semiconductor
  • the switch OPT1, the first current limiting component R1, the unidirectional conduction device D1, and the capacitor C1 are connected in series to form a first series circuit
  • the second current limiting component R2, the unidirectional conduction device D1, and the capacitor C1 are connected in series to form a second series circuit.
  • the capacitor C1 forms a driving circuit through the semiconductor switch OPT1, the second end of the power device SCR1 to be driven, and the third end of the power device SCR1.
  • the first power source charges the capacitor C1 through the first current limiting component R1, and the second power source passes the
  • the second current limiting component R2 charges the capacitor C1, and the voltage stabilizing device Z1 is connected in parallel with the capacitor C1.
  • the first end of the power device SCR1 and the third end of the power device SCR1 are the main circuit end of the power device SCR1.
  • the first power source can be provided by the first end of the power device, and the second power source is provided by the neutral line or another phase line relative to the power device, and has the advantages of simple circuit, high reliability, high cost performance, and convenient use.
  • Embodiment 1 is a circuit principle of Embodiment 1 of a power device driving device of the present invention.
  • FIG. 2 is a circuit schematic diagram of a second embodiment of a power device driving device of the present invention.
  • FIG. 3 is a schematic diagram of the package of the power device driving device of the present invention.
  • Embodiment 1 of the power device driving device of the present invention is as shown in FIG. 1:
  • a power device driving device includes a first current limiting component R1 (resistor), a second current limiting component R2 (resistor), a unidirectional conduction device D1 (diode), a capacitor C1, a voltage stabilizing device Z1 (stabilizing diode),
  • the semiconductor switch OPT1, the first current limiting component R1, the unidirectional conduction device D1, the capacitor C1 are connected in series to form a first series circuit
  • the second current limiting component R2 the unidirectional conduction device D1, and the capacitor C1 are connected in series to form a second series circuit.
  • the capacitor C1 forms a driving circuit through the semiconductor switch OPT1, the second end (trigger) of the power device SCR1 (the unidirectional thyristor) to be driven, and the third end (cathode) of the power device SCR1, and the first end of the power device SCR1
  • the first power source (anode) is supplied to charge the capacitor C1 through the first current limiting element R1, and the second power source (provided by the neutral line in FIG.
  • the phase line provides) charging capacitor C1 through the second current limiting component R2, and the voltage stabilizing device Z1 is connected in parallel with the capacitor C1 (the voltage stabilizing device Z1 can also be connected in parallel with the capacitor C1 through the unidirectional conduction device D1), the first end of the power device SCR1
  • the third end of the power device SCR1 is the power device SCR1 End of the loop.
  • the driving of the power device used for arc extinguishing in a single-pole mechanical switch is
  • the power device SCR1 is connected in parallel with the power device SCR2.
  • the mechanical switch K1 connected to the main circuit end of the power device SCR1 is normally open, the first power source charges the capacitor C1 through the first current limiting component R1 and the one-way conduction device D1.
  • the semiconductor switch OPT1 control signal is provided, the capacitor C1 drives the power device SCR1 to be turned on by the semiconductor switch OPT1, the mechanical switch K1 is closed, and the semiconductor switch OPT1 is turned on to turn on the control signal, and the power device SCR1 is turned on.
  • the capacitor C1 is charged by the second power source through the second current limiting component R2 and the one-way conduction device D1 to satisfy the driving energy required by the power device SCR1;
  • the semiconductor switch OPT1 is turned on to control the signal, then the mechanical switch K1 is turned off, the power device SCR1 is turned on, the semiconductor switch OPT1 is turned off to turn on the control signal, and the arc switch of the mechanical switch K1 is completed. Note: For the convenience of description and understanding, the control of the power device SCR2 is the same and will not be described again.
  • the power device for the hybrid switch is driven. Since the power device uses the capacitive energy storage driving mode, the operating current through the first current limiting component and the second current limiting component can be designed to be less than 0.1 milliamperes. It is 0.1 mA, the operating voltage is 220V, and its power consumption is 0.022W.
  • Embodiment 2 of the power device driving device of the present invention is as shown in FIG. 2:
  • a power device driving device comprising a first current limiting component R1 (resistance), a second current limiting component R2 (resistance), a first unidirectional conduction device D1 (diode), a second unidirectional conduction device D2 (diode), Capacitor C1, voltage regulator device Z1 (Zener diode), semiconductor switch (C), further includes a photocoupler OPT1 for controlling conduction of the unidirectional thyristor SCR1, a first current limiting component R1, and a first unidirectional conduction device D1, capacitor C1 is connected in series to form a first series circuit, second current limiting element R2, second one-way conducting device D2, capacitor C1 are connected in series to form a second series circuit, and capacitor C1 is driven by semiconductor switch (C)
  • the second end (trigger) of the power device SCR1 (the unidirectional thyristor) and the third end (the cathode) of the power device SCR1 form a driving circuit, and the first
  • voltage regulator device Z1 is connected in parallel with capacitor C1 (also can stabilize the device Z1)
  • the first one-way conduction device D1 is connected in parallel with the capacitor C1
  • the other voltage-regulating device is connected in parallel with the capacitor C1 through the second unidirectional thyristor D2.
  • the first end of the power device SCR1 and the third end of the power device SCR1 are power devices. SCR1 main loop end.
  • the power device SCR1 is a semi-controlled device
  • the semiconductor switch (C) is a voltage detecting switch
  • the voltage detecting switch includes a resistor
  • a semiconductor device is connected to the power device SCR1.
  • Rate device SCR1 anti-parallel power device SCR2 (for semi-controlled devices, can also be fully-controlled devices), in the normally open state of the main circuit of the power device SCR1, the first power supply through the first current limiting component R1
  • a single-pass device D1 charges the capacitor C1, and provides a photocoupler OPT1 control signal when the zero-crossing is required.
  • the capacitor C1 drives the power device SCR1 through the semiconductor switch (C) to conduct zero-crossing, and the semiconductor switch (C) When the power device SCR1 is turned on, it is turned off, and the discharge of the capacitor C1 is stopped.
  • the second power source passes through the second current limiting element R2.
  • the second one-way conduction device D2 charges the capacitor C1 to satisfy the driving energy required to maintain the power device SCR1 in an on state.
  • the photocoupler OPT1 is not limited to be connected to the collector of the transistor Q1, and the photocoupler OPT1 may be connected to the base of the transistor Q1.
  • the semiconductor switch (C) is a voltage detecting switch, and the average operating current through the first current limiting element R1 and the second current limiting element R2 can be much smaller than the minimum trigger current required by the unidirectional thyristor, and the first current limiting current is passed.
  • the average operating current of the component R1 and the second current limiting component R2 may be one-tenth to one thousandth of the minimum trigger current required for the unidirectional thyristor, and the first current limiting component R1 and the second current limiting component are greatly reduced.
  • the power device driving device of the above embodiment may be packaged in an insulating material, and corresponding pins (corresponding to P1, P2, P3, P4, P5, and P6 in FIG. 2) may be added.
  • the power device driving device of the embodiment is externally connected through corresponding pins.
  • the other end of the power supply connected to the power device driving device of the present invention is also defined as a neutral line.
  • the present invention has the following advantages:
  • the first power source and the second power source are powered by the working power grid where the power device is located, and have the advantages of simple circuit, low cost and high reliability.
  • the first power terminal of the present invention can be provided by the first end of the power device (not limited thereto), the second power terminal is provided by the neutral line or another phase of the power device, and is also convenient in three Used in the system of phase three control.

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  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Power Conversion In General (AREA)

Abstract

一种功率器件驱动装置,属于电学领域,交流供电中用于驱动功率器件的功率器件驱动装置;包括第一限流元件(R1)、第二限流元件(R2)、单向导通器件(D1、D2)、电容(C1)、稳压器件(Z1)、半导体开关(OPT1、C),第一限流元件(R1)、单向导通器件(D1)、电容(C1)串联而成第一串联电路,第二限流元件(R2)、单向导通器件(D2)、电容(C1)串联而成第二串联电路,电容(C1)通过半导体开关(OPT1、C)、所需驱动的功率器件(SCR1)的第二端(2)、功率器件(SCR1)的第三端(3)形成驱动回路,第一电源通过第一限流元件(R1)对电容(C1)充电,第二电源通过第二限流元件(R2)对电容(C1)充电,稳压器件(Z1)与电容(C1)并联,功率器件(SCR1)的第一端(1)、功率器件(SCR1)的第三端(3)为功率器件(SCR1)主回路端。该功率器件驱动装置具有电路简单、可靠性高的优点。

Description

功率器件驱动装置 技术领域
本发明功率器件驱动装置属于电学领域,特别是一种适合在交流系统中用于驱动功率器件的功率器件驱动装置。
背景技术
在各种交流供电系统用电场合,使用单向晶闸管等功率器件对负载进行投切控制极其普遍,其传统的驱动装置是采用脉冲变压器输出两路电气隔离的驱动信号分别驱动两只单向晶闸管,其存在以下缺点:
驱动信号由变压器提供,需要脉冲信号发生电路、变压器驱动电路、变压器、整流电路,其存在脉冲占空比带来的驱动盲区、高频干扰大、产生谐波大、占用空间大及性价比低等缺点,还存在两个单向晶闸管的驱动回路之间耐压绝缘要求高、两个单向晶闸管的驱动回路对变压器驱动电路之间耐压绝缘要求高的问题。
发明内容
本发明的目的在于针对现有单向晶闸管等功率器件驱动的不足之处而提供一种电路简单、高可靠、工作能耗小、无高频干扰、性价比高、使用方便、通用性强的功率器件驱动装置。
实现本发明的目的是通过以下技术方案来达到的:
一种功率器件驱动装置,包括第一限流元件、第二限流元件、单向导通器件、电容、稳压器件、半导体开关,所述第一限流元件、所述单向导通器件、所述电容串联而成第一串联电路,所述第二限流元件、所述单向导通器件、所述电容串联而成第二串联电路,所述电容通过所述半导体开关、所需驱动的功率器件的第二端、所述功率器件的第三端形成驱动回路,第一电源通过所述第一限流元件对所述电容充电,第二电源通过所述第二限流元件对所述电容充电,所述稳压器件与所述电容并联,所述功率器件的第一端、所述功率器件的第三端为所述功率器件的主回路端。
一种功率器件驱动装置,所述单向导通器件包括第一单向导通器件、第二单向导通器件,所述第一串联电路由所述第一限流元件、所述第一单向导通器件、所述电容串联而成;所述第二串联电路由所述第二限流元件、所述第二单向导通器件、所述电容串联而成。
一种功率器件驱动装置,所述稳压器件通过所述单向导通器件与所述电容并联。
一种功率器件驱动装置,所述单向导通器件为二极管,所述第一限流元件、所述第二限流元件为电阻。
一种功率器件驱动装置,所述第二电源由中性线提供,或相对于所述功率器件的另一相线提供。
一种功率器件驱动装置,所述第一电源由所述功率器件的第一端提供。
一种功率器件驱动装置,所述功率器件为半控型器件,所述半导体开关为一电压检测开关,所述半导体开关与所述功率器件连接,所述半导体开关在检测到所述功率器件导通时截止。
一种功率器件驱动装置,所述电压检测开关包括电阻、半导体器件。
一种功率器件驱动装置,所述第一电源、所述第二电源由所述功率器件的工作电网非隔离供电。
一种功率器件驱动装置,其用于反向并联有半控型或全控型器件的所述功率器件的驱动。
一种功率器件驱动装置,所述功率器件为单向晶闸管,所述功率器件的第一端、所述功率器件的第二端、所述功率器件的第三端分别为所述单向晶闸管的阳极、所述单向晶闸管的触发极、所述单向晶闸管的阴极。
一种功率器件驱动装置,通过所述第一限流元件、所述第二限流元件的平均工作电流小于所述单向晶闸管所需的最小触发电流。
一种功率器件驱动装置,包括一用于控制所述单向晶闸管导通的光电耦合器。
一种功率器件驱动装置,还包括引脚、绝缘材料,所述的功率器件驱动装置封装在所述绝缘材料中,所述的功率器件驱动装置通过相应的所述引脚供外部连接。
一种功率器件驱动装置,图1所示,包括第一限流元件R1、第二限流元件R2、单向导通器件D1(二极管)、电容C1、稳压器件Z1(稳压二极管)、半导体开关OPT1,第一限流元件R1、单向导通器件D1、电容C1串联而成第一串联电路,第二限流元件R2、单向导通器件D1、电容C1串联而成第二串联电路,电 容C1通过半导体开关OPT1、所需驱动的功率器件SCR1的第二端、功率器件SCR1的第三端形成驱动回路,第一电源通过第一限流元件R1对电容C1充电,第二电源通过第二限流元件R2对电容C1充电,稳压器件Z1与电容C1并联,功率器件SCR1的第一端、功率器件SCR1的第三端为功率器件SCR1主回路端。
工作原理:在功率器件SCR1主回路端常开状态下,由第一电源通过第一限流元件R1对电容C1充电,在功率器件SCR1主回路端常闭状态下,由第二电源通过第二限流元件R2对电容C1充电,满足功率器件SCR1所需的驱动能量。
本发明功率器件驱动装置,设计合理,具有以下优点:
第一电源可以由功率器件的第一端提供,第二电源由中性线或相对于功率器件的另一相线提供,具有电路简单、可靠性高、性价比高、使用方便的优点。
附图说明
图1本发明功率器件驱动装置实施例一电路原理。
图2本发明功率器件驱动装置实施例二电路原理图。
图3本发明功率器件驱动装置封装示意图。
具体实施方式
本发明功率器件驱动装置的实施例一,如图1所示:
一种功率器件驱动装置,包括第一限流元件R1(电阻)、第二限流元件R2(电阻)、单向导通器件D1(二极管)、电容C1、稳压器件Z1(稳压二极管)、半导体开关OPT1,第一限流元件R1、单向导通器件D1、电容C1串联而成第一串联电路,第二限流元件R2、单向导通器件D1、电容C1串联而成第二串联电路,电容C1通过半导体开关OPT1、所需驱动的功率器件SCR1(单向晶闸管)的第二端(触发极)、功率器件SCR1的第三端(阴极)形成驱动回路,由功率器件SCR1的第一端(阳极)提供的第一电源通过第一限流元件R1对电容C1充电,第二电源(图1为中性线提供,在三相开关使用时,也可以由相对于功率器件SCR1的另一相线提供)通过第二限流元件R2对电容C1充电,稳压器件Z1与电容C1并联(也可以稳压器件Z1通过单向导通器件D1与电容C1并联),功率器件SCR1的第一端、功率器件SCR1的第三端为功率器件SCR1主回路端。
工作原理:为方便理解,这里以用在单极机械开关灭弧的功率器件的驱动为 例,功率器件SCR1反向并联功率器件SCR2,在功率器件SCR1主回路端连接的机械开关K1常开状态下,由第一电源通过第一限流元件R1、单向导通器件D1对电容C1充电,在需要过零接通时,提供半导体开关OPT1控制信号,电容C1通过半导体开关OPT1驱动功率器件SCR1过零导通,机械开关K1闭合,关闭半导体开关OPT1导通控制信号,在功率器件SCR1主回路端常闭状态下(即机械开关K1闭合状态下),由第二电源通过第二限流元件R2、单向导通器件D1对电容C1充电,满足功率器件SCR1所需的驱动能量;在机械开关分断时,提供半导体开关OPT1导通控制信号,然后机械开关K1断开,功率器件SCR1导通,关闭半导体开关OPT1导通控制信号,完成机械开关K1的无电弧分断。注:为方便描述和理解,功率器件SCR2的控制相同就不再赘述。
本实施例,用于混合式开关的功率器件驱动,由于功率器件采用电容储能驱动方式,通过第一限流元件、第二限流元件的工作电流可设计在0.1毫安以下,当设定为0.1毫安,工作电压为220V,其功耗为0.022W。
本发明功率器件驱动装置的实施例二,如图2所示:
一种功率器件驱动装置,包括第一限流元件R1(电阻)、第二限流元件R2(电阻)、第一单向导通器件D1(二极管)、第二单向导通器件D2(二极管)、电容C1、稳压器件Z1(稳压二极管)、半导体开关(C),还包括一用于控制单向晶闸管SCR1导通的光电耦合器OPT1,第一限流元件R1、第一单向导通器件D1、电容C1串联而成第一串联电路,第二限流元件R2、第二单向导通器件D2、电容C1串联而成第二串联电路,电容C1通过半导体开关(C)、所需驱动的功率器件SCR1(单向晶闸管)的第二端(触发极)、功率器件SCR1的第三端(阴极)形成驱动回路,由功率器件SCR1的第一端提供的第一电源通过第一限流元件R1对电容C1充电,第二电源(图2为中性线提供,在三相开关中使用时,也可以由相对于功率器件SCR1的另一相线提供)通过第二限流元件R2对电容C1充电,稳压器件Z1与电容C1并联(也可以稳压器件Z1通过第一单向导通器件D1与电容C1并联,增加另一稳压器件通过第二单向晶闸管D2与电容C1并联),功率器件SCR1的第一端、功率器件SCR1的第三端为功率器件SCR1主回路端。功率器件SCR1为半控型器件,半导体开关(C)为一电压检测开关,电压检测开关包括电阻、半导体器件,半导体开关(C)与功率器件SCR1连接。
工作原理:为方便理解,这里以用在晶闸管开关的功率器件的驱动为例,功 率器件SCR1反向并联功率器件SCR2(为半控型器件,也可以为全控型器件),在功率器件SCR1主回路端常开状态下,由第一电源通过第一限流元件R1、第一单向导通器件D1对电容C1充电,在需要过零接通时,提供光电耦合器OPT1控制信号,电容C1通过半导体开关(C)驱动功率器件SCR1过零导通,半导体开关(C)在检测到功率器件SCR1导通时截止,停止电容C1的放电,在功率器件SCR1主回路端常闭状态下(即功率器件SCR1导通状态下),由第二电源通过第二限流元件R2、第二单向导通器件D2对电容C1充电,满足保持功率器件SCR1导通状态所需的驱动能量。注:为方便理解,由于功率器件SCR2的控制相同,不再赘述,光电耦合器OPT1不限于与晶体管Q1的集电极连接,光电耦合器OPT1也可以与晶体管Q1的基极连接。
当功率器件(单向晶闸管)长期导通需要持续提供驱动电流时,第一限流元件R1、第二限流元件R2将产生极大的功耗,为减少能耗,达到实用性,本实施例中,半导体开关(C)为一电压检测开关,通过第一限流元件R1、第二限流元件R2的平均工作电流可以远小于单向晶闸管所需的最小触发电流,通过第一限流元件R1、第二限流元件R2的平均工作电流可以为单向晶闸管所需的最小触发电流的几十分之一到千分之一,大大减低第一限流元件R1、第二限流元件R2的功耗;以上所述的单向晶闸管,其定义也包括任一等同器件。
如图3所示,为便于使用,可以对以上实施例的功率器件驱动装置封装在一绝缘材料内,增加相应引脚(对应图2的P1、P2、P3、P4、P5、P6),以上实施例的功率器件驱动装置通过相应的引脚供外部连接。
在交流供电系统中使用时,与本发明功率器件驱动装置连接的相对于功率器件的另一端电源也定义为中性线。
综上所述,本发明具有以下优点:
1.第一电源、第二电源由功率器件所在的工作电网非隔离供电,具有电路简单、成本低、可靠性高的优点。
2.采用两个反并联的全控型或半控型功率器件驱动时,可以采用相同的电源端供电,极方便在单相交流供电系统中使用。
3.由于本发明的第一电源端可以由功率器件的第一端提供(并不限于),第二电源端由中性线或相对于功率器件的另一相电提供,也很方便在三相三控的系统中使用。

Claims (14)

  1. 一种功率器件驱动装置,其特征是:包括第一限流元件、第二限流元件、单向导通器件、电容、稳压器件、半导体开关,所述第一限流元件、所述单向导通器件、所述电容串联而成第一串联电路,所述第二限流元件、所述单向导通器件、所述电容串联而成第二串联电路,所述电容通过所述半导体开关、所需驱动的功率器件的第二端、所述功率器件的第三端形成驱动回路,第一电源通过所述第一限流元件对所述电容充电,第二电源通过所述第二限流元件对所述电容充电,所述稳压器件与所述电容并联,所述功率器件的第一端、所述功率器件的第三端为所述功率器件的主回路端。
  2. 根据权利要求1所述的功率器件驱动装置,其特征是:所述单向导通器件包括第一单向导通器件、第二单向导通器件,所述第一串联电路由所述第一限流元件、所述第一单向导通器件、所述电容串联而成;所述第二串联电路由所述第二限流元件、所述第二单向导通器件、所述电容串联而成。
  3. 根据权利要求1所述的功率器件驱动装置,其特征是:所述稳压器件通过所述单向导通器件与所述电容并联。
  4. 根据权利要求1所述的功率器件驱动装置,其特征是:所述单向导通器件为二极管,所述第一限流元件、所述第二限流元件为电阻。
  5. 根据权利要求1所述的功率器件驱动装置,其特征是:所述第二电源由中性线提供,或相对于所述功率器件的另一相线提供。
  6. 根据权利要求1所述的功率器件驱动装置,其特征是:所述第一电源由所述功率器件的第一端提供。
  7. 根据权利要求1所述的功率器件驱动装置,其特征是:所述功率器件为半控型器件,所述半导体开关为一电压检测开关,所述半导体开关与所述功率器件连接,所述半导体开关在检测到所述功率器件导通时截止。
  8. 根据权利要求7所述的功率器件驱动装置,其特征是:所述电压检测开关包括电阻、半导体器件。
  9. 根据权利要求1所述的功率器件驱动装置,其特征是:所述第一电源、所述第二电源由所述功率器件的工作电网非隔离供电。
  10. 根据权利要求1所述的功率器件驱动装置,其特征是:其用于反向并联有半控型或全控型器件的所述功率器件的驱动。
  11. 根据权利要求1至10任一项所述的功率器件驱动装置,其特征是:所述功率器件为单向晶闸管,所述功率器件的第一端、所述功率器件的第二端、所述功率器件的第三端分别为所述单向晶闸管的阳极、所述单向晶闸管的触发极、所述单向晶闸管的阴极。
  12. 根据权利要求11所述的功率器件驱动装置,其特征是:通过所述第一限流元件、所述第二限流元件的平均工作电流小于所述单向晶闸管所需的最小触发电流。
  13. 根据权利要求11所述的功率器件驱动装置,其特征是:包括一用于控制所述单向晶闸管导通的光电耦合器。
  14. 根据权利要求13所述的功率器件驱动装置,其特征是:还包括引脚、绝缘材料,所述的功率器件驱动装置封装在所述绝缘材料中,所述的功率器件驱动装置通过相应的所述引脚供外部连接。
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JPH1023742A (ja) * 1996-06-28 1998-01-23 Hitachi Ltd 半導体電力変換装置
CN201550072U (zh) * 2009-11-14 2010-08-11 赵树林 场效应管电压调节器低压启动电路
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