TW201517469A - Load control device - Google Patents
Load control device Download PDFInfo
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- TW201517469A TW201517469A TW103118199A TW103118199A TW201517469A TW 201517469 A TW201517469 A TW 201517469A TW 103118199 A TW103118199 A TW 103118199A TW 103118199 A TW103118199 A TW 103118199A TW 201517469 A TW201517469 A TW 201517469A
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS 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
- H02M5/00—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases
- H02M5/02—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases without intermediate conversion into dc
- H02M5/04—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases without intermediate conversion into dc by static converters
- H02M5/22—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases without intermediate conversion into dc by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
- H02M5/275—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases without intermediate conversion into dc by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal
- H02M5/293—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases without intermediate conversion into dc by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS 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
- H02M5/00—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases
- H02M5/02—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases without intermediate conversion into dc
- H02M5/04—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases without intermediate conversion into dc by static converters
- H02M5/22—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases without intermediate conversion into dc by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
- H02M5/275—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases without intermediate conversion into dc by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal
- H02M5/293—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases without intermediate conversion into dc by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only
- H02M5/2932—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases without intermediate conversion into dc by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only with automatic control of output voltage, current or power
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- Engineering & Computer Science (AREA)
- Power Engineering (AREA)
- Circuit Arrangement For Electric Light Sources In General (AREA)
- Electronic Switches (AREA)
- Power Conversion In General (AREA)
Abstract
Description
本發明,一般而言係關於負載控制裝置,更詳細而言,係關於包含雙方向開關元件之負載控制裝置。The present invention relates generally to load control devices and, more particularly, to load control devices including dual direction switching elements.
作為負載控制裝置,已知例如圖10所示之構成之2線式交流開關100a(參照日本專利申請案公開2011-176921號公報;以下,稱文獻1)。As the load control device, for example, a 2-wire type AC switch 100a having the configuration shown in FIG. 10 is known (refer to Japanese Laid-Open Patent Publication No. 2011-176921; hereinafter referred to as Document 1).
2線式交流開關100a,係用來連接商用交流電源101與照明器具等負載102之間之交流開關。此2線式交流開關100a,包含雙方向開關元件103、全波整流器104、電源電路105、驅動電路(第1閘驅動電路107、第2閘驅動電路108)、與控制電路106。The 2-wire AC switch 100a is an AC switch for connecting a commercial AC power source 101 and a load 102 such as a lighting fixture. The two-wire AC switch 100a includes a bidirectional switching element 103, a full-wave rectifier 104, a power supply circuit 105, a drive circuit (a first gate drive circuit 107, a second gate drive circuit 108), and a control circuit 106.
雙方向開關元件103,係呈電流沿雙方向流動之構成,且導通或切斷該電流之流動,由第III族氮化物半導體構成之雙閘開關元件。雙方向開關元件103,包含: 開關端子S11及開關端子S12,作為開關(導通/非導通)之對象; 控制端子G11及控制端子G12,連接用來控制電流之流動之導通及切斷之2個閘極;及 基板端子SUB,電性連接形成此雙方向開關元件103之基板。 在此,串聯連接商用交流電源101、負載102、與雙方向開關元件103(其開關端子S11及開關端子S12),俾構成閉電路。The bidirectional switching element 103 is a double gate switching element composed of a Group III nitride semiconductor in which a current flows in two directions and a flow of the current is turned on or off. The bidirectional switching element 103 includes: a switch terminal S11 and a switch terminal S12 as a switch (on/off); the control terminal G11 and the control terminal G12 are connected to control the conduction and disconnection of the flow of the current. And a substrate terminal SUB electrically connected to form a substrate of the bidirectional switching element 103. Here, the commercial AC power supply 101, the load 102, and the bidirectional switching element 103 (the switch terminal S11 and the switch terminal S12) are connected in series to form a closed circuit.
全波整流器104,係連接開關端子S11與開關端子S12之間,對自商用交流電源101供給之交流電源進行全波整流之橋式二極體等。The full-wave rectifier 104 is a bridge diode that is connected between the switch terminal S11 and the switch terminal S12 to perform full-wave rectification of the AC power supplied from the commercial AC power supply 101.
電源電路105,係使自全波整流器104輸出之全波整流後之電壓平滑化,供給直流電源之電路。自電源電路105供給第1閘驅動電路107、第2閘驅動電路108及控制電路106所需之電源。The power supply circuit 105 is a circuit that supplies a full-wave rectified voltage from the output of the full-wave rectifier 104 to a DC power supply. The power supply required for the first gate driving circuit 107, the second gate driving circuit 108, and the control circuit 106 is supplied from the power supply circuit 105.
自商用交流電源101對負載102供給電力時,控制電路106,使雙方向開關元件103呈導通狀態。此時,控制電路106控制第1閘驅動電路107及第2閘驅動電路108,俾第1閘驅動電路107及第2閘驅動電路108,分別對雙方向開關元件103之控制端子G11及控制端子G12,輸出具有高於對應控制端子G11及控制端子G12之閘極之臨界值電壓之電壓之控制信號。藉此,控制電路106,使雙方向開關元件103呈導通狀態。When the commercial AC power supply 101 supplies electric power to the load 102, the control circuit 106 turns the bidirectional switching element 103 into an ON state. At this time, the control circuit 106 controls the first gate driving circuit 107 and the second gate driving circuit 108, and the first gate driving circuit 107 and the second gate driving circuit 108 respectively control the control terminal G11 and the control terminal of the bidirectional switching element 103. G12, outputting a control signal having a voltage higher than a threshold voltage of a gate corresponding to the control terminal G11 and the control terminal G12. Thereby, the control circuit 106 causes the bidirectional switching element 103 to be in an on state.
另一方面,控制電路106,在隔斷自商用交流電源101對負載102供給電力時,使雙方向開關元件103呈切斷狀態。此時,控制電路106控制第1閘驅動電路107及第2閘驅動電路108,俾第1閘驅動電路107及第2閘驅動電路108,分別對雙方向開關元件103之控制端子G11及控制端子G12,輸出具有低於對應控制端子G11及控制端子G12之閘極之臨界值電壓之電壓之控制信號。藉此,控制電路106,使雙方向開關元件103呈切斷狀態。On the other hand, when the control circuit 106 blocks the supply of electric power to the load 102 from the commercial AC power supply 101, the bidirectional switching element 103 is turned off. At this time, the control circuit 106 controls the first gate driving circuit 107 and the second gate driving circuit 108, and the first gate driving circuit 107 and the second gate driving circuit 108 respectively control the control terminal G11 and the control terminal of the bidirectional switching element 103. G12, outputting a control signal having a voltage lower than a threshold voltage of a gate corresponding to the control terminal G11 and the control terminal G12. Thereby, the control circuit 106 turns the bidirectional switching element 103 into a disconnected state.
亦即,使雙方向開關元件103導通時,第1閘驅動電路107及第2閘驅動電路108,分別產生控制信號,朝對應之控制端子G11、G12輸出。In other words, when the bidirectional switching element 103 is turned on, the first gate driving circuit 107 and the second gate driving circuit 108 generate control signals and output them to the corresponding control terminals G11 and G12.
控制電路106,係如上述控制第1閘驅動電路107及第2閘驅動電路108之電路。The control circuit 106 is a circuit that controls the first gate drive circuit 107 and the second gate drive circuit 108 as described above.
更詳細而言,自外部設定部109,對控制電路106傳達表示是否自商用交流電源101對負載102供給電力之信號。根據此傳達之信號,控制電路106,對第1閘驅動電路107之輸入端子SIN1及第2閘驅動電路108之輸入端子SIN2,輸出控制用信號。More specifically, the external setting unit 109 transmits a signal indicating whether or not power is supplied from the commercial AC power source 101 to the load 102 to the control circuit 106. Based on the signal transmitted, the control circuit 106 outputs a control signal to the input terminal SIN1 of the first gate drive circuit 107 and the input terminal SIN2 of the second gate drive circuit 108.
第1閘驅動電路107及第2閘驅動電路108,根據來自控制電路106之控制用信號,分別自其輸出端子OUT1及OUT2對雙方向開關元件103之控制端子G11及G12輸出控制信號,藉此控制雙方向開關元件103之開關動作。The first gate drive circuit 107 and the second gate drive circuit 108 output control signals to the control terminals G11 and G12 of the bidirectional switch element 103 from the output terminals OUT1 and OUT2, respectively, based on the control signals from the control circuit 106. The switching operation of the bidirectional switching element 103 is controlled.
文獻1中,未明記關於2線式交流開關100a中第1閘驅動電路107及第2閘驅動電路108各具體電路構成。In Document 1, the specific circuit configuration of each of the first gate drive circuit 107 and the second gate drive circuit 108 in the two-wire AC switch 100a is not clearly described.
又,業界雖期望裝置更小型化,但負載控制裝置中,閘驅動電路,包含用來改變電壓位準之位準移位電路時,傾向於難以更小型化。負載控制裝置中,閘驅動電路,以變壓器驅動雙方向開關元件時,傾向於難以小型化。Further, although the device is expected to be more compact in size, in the load control device, when the gate drive circuit includes a level shift circuit for changing the voltage level, it tends to be more compact. In the load control device, when the gate drive circuit drives the bidirectional switching element with a transformer, it tends to be difficult to miniaturize.
鑒於上述事由,本發明之目的在於提供一負載控制裝置,可小型化。In view of the above, it is an object of the present invention to provide a load control device that can be miniaturized.
本發明之負載控制裝置,包含: 雙方向開關元件,包含第1閘極電極、第2閘極電極、第1源極電極及第2源極電極,可藉由分別對該第1閘極電極與該第1源極電極之間、該第2閘極電極與該第2源極電極之間,施加既定之驅動電壓,使該第1源極電極與該第2源極電極之間導通,設於自交流電源朝負載供電之供電路; 二極體橋式電路,於該第1源極電極連接第1交流輸入端子,於該第2源極電極連接第2交流輸入端子; 電源電路,可使該二極體橋式電路之正端子與該二極體橋式電路之負端子之間之輸出電壓恆定電壓化; 位準轉換電路,可以既定阻抗使該正端子與該負端子之間導通;及 閘驅動電路,可自該電源電路,對該雙方向開關元件之該第1閘極電極及該第2閘極電極,供給用來使該雙方向開關元件導通之該驅動電壓或既定之驅動電流; 且該閘驅動電路,可輸入用來控制該雙方向開關元件之導通、切斷之控制信號,且該控制信號為高位準時,自該電源電路,對該第1閘極電極及該第2閘極電極,供給該驅動電壓或該驅動電流, 該位準轉換電路, 包含雙極性電晶體,該雙極性電晶體之集極端子連接於該正端子,射極端子連接於該負端子,可對基極端子,輸入該控制信號, 該控制信號為高位準時,該雙極性電晶體為導通。A load control device according to the present invention includes: a bidirectional switching element including a first gate electrode, a second gate electrode, a first source electrode, and a second source electrode, respectively, which can be respectively used for the first gate electrode A predetermined driving voltage is applied between the first source electrode and the second source electrode and the second source electrode, and the first source electrode and the second source electrode are electrically connected to each other. a circuit for supplying power from an AC power source to a load; a diode bridge circuit having a first AC input terminal connected to the first source electrode and a second AC input terminal being connected to the second source electrode; The output voltage between the positive terminal of the diode bridge circuit and the negative terminal of the diode bridge circuit can be constantly voltage-regulated; the level conversion circuit can have a predetermined impedance between the positive terminal and the negative terminal And a gate driving circuit for supplying the first gate electrode and the second gate electrode of the bidirectional switching element from the power supply circuit for turning on the bidirectional switching element The driving voltage or the predetermined driving current; and the gate driving circuit can input a control signal for controlling the turning on and off of the bidirectional switching element, and the control signal is at a high level, from the power circuit, to the a gate electrode and the second gate electrode supply the driving voltage or the driving current, the level conversion circuit comprising a bipolar transistor, the collector terminal of the bipolar transistor being connected to the positive terminal, and the emitter terminal The sub-terminal is connected to the negative terminal, and the control signal is input to the base terminal. When the control signal is at a high level, the bipolar transistor is turned on.
依本發明之負載控制裝置,可小型化。The load control device according to the present invention can be miniaturized.
(實施形態1) 於以下,根據圖1~圖3說明關於本實施形態之負載控制裝置1a。(Embodiment 1) Hereinafter, a load control device 1a according to the present embodiment will be described with reference to Figs. 1 to 3 .
負載控制裝置1a,係包含設於自交流電源8至負載9之供電路之雙方向開關元件2之負載控制裝置。The load control device 1a is a load control device including a bidirectional switching element 2 provided in a supply circuit from the AC power supply 8 to the load 9.
雙方向開關元件2,包含第1閘極電極G1、第2閘極電極G2、第1源極電極S1及第2源極電極S2,分別對第1閘極電極G1與第1源極電極S1之間、第2閘極電極G2與第2源極電極S2之間施加既定之驅動電壓,藉此,導通第1源極電極S1與第2源極電極S2之間。The bidirectional switching element 2 includes a first gate electrode G1, a second gate electrode G2, a first source electrode S1, and a second source electrode S2, and is respectively paired with the first gate electrode G1 and the first source electrode S1. A predetermined driving voltage is applied between the second gate electrode G2 and the second source electrode S2, thereby turning on between the first source electrode S1 and the second source electrode S2.
且負載控制裝置1a,包含: 二極體橋式電路3,第1交流輸入端子31連接第1源極電極S1,第2交流輸入端子32連接第2源極電極S2; 電源電路4,使二極體橋式電路3之正端子33與二極體橋式電路3之負端子34之間之輸出電壓恆定電壓化; 位準轉換電路5a,以既定阻抗使正端子33與負端子34之間導通;及 閘驅動電路6a,自電源電路4對雙方向開關元件2之第1閘極電極G1及第2閘極電極G2供給驅動電壓。The load control device 1a includes a diode bridge circuit 3, the first AC input terminal 31 is connected to the first source electrode S1, the second AC input terminal 32 is connected to the second source electrode S2, and the power supply circuit 4 is connected to the second source electrode S2. The output voltage between the positive terminal 33 of the polar body bridge circuit 3 and the negative terminal 34 of the diode bridge circuit 3 is constantly voltage-stabilized; the level conversion circuit 5a is between the positive terminal 33 and the negative terminal 34 with a predetermined impedance. And the gate driving circuit 6a supplies a driving voltage from the power supply circuit 4 to the first gate electrode G1 and the second gate electrode G2 of the bidirectional switching element 2.
閘驅動電路6a,可輸入用來控制導通、切斷雙方向開關元件2之控制信號CS,且控制信號CS為高位準VH時,自電源電路4對第1閘極電極G1及第2閘極電極G2供給驅動電壓。位準轉換電路5a,包含雙極性電晶體Q5,雙極性電晶體Q5之集極端子連接正端子33,射極端子連接負端子34,對基極端子,輸入控制信號CS。位準轉換電路5a中,控制信號CS為高位準VH時雙極性電晶體Q5為導通。藉此,負載控制裝置1a,可實現小型化。The gate driving circuit 6a can input a control signal CS for controlling the turning on and off of the bidirectional switching element 2, and when the control signal CS is at the high level VH, the first gate electrode G1 and the second gate are connected from the power supply circuit 4. The electrode G2 supplies a driving voltage. The level conversion circuit 5a includes a bipolar transistor Q5. The collector terminal of the bipolar transistor Q5 is connected to the positive terminal 33, the emitter terminal is connected to the negative terminal 34, and the base terminal is input with a control signal CS. In the level shift circuit 5a, the bipolar transistor Q5 is turned on when the control signal CS is at the high level VH. Thereby, the load control device 1a can be downsized.
以下詳細說明關於負載控制裝置1a各構成要素。The components of the load control device 1a will be described in detail below.
如圖1所示,本實施形態之負載控制裝置1a,包含雙方向開關元件2、二極體橋式電路3、電源電路4、位準轉換電路5a、閘驅動電路6a、與端子7。且負載控制裝置1a包含控制電路100。As shown in FIG. 1, the load control device 1a of the present embodiment includes a bidirectional switching element 2, a diode bridge circuit 3, a power supply circuit 4, a level conversion circuit 5a, a gate drive circuit 6a, and a terminal 7. The load control device 1a includes a control circuit 100.
負載控制裝置1a,在雙方向開關元件2之第1源極電極S1與第2源極電極S2之間,連接並使用交流電源8與負載9之串聯電路。因此,負載控制裝置1a,包含分別連接雙方向開關元件2之第1源極電極S1、第2源極電極S2之第1主端子21、第2主端子22,在第1主端子21與第2主端子22之間,可連接交流電源8與負載9之串聯電路。In the load control device 1a, a series circuit of the AC power supply 8 and the load 9 is connected between the first source electrode S1 and the second source electrode S2 of the bidirectional switching element 2. Therefore, the load control device 1a includes the first main terminal 21 and the second main terminal 22 that respectively connect the first source electrode S1 and the second source electrode S2 of the bidirectional switching element 2, and the first main terminal 21 and the first main terminal 21 Between the main terminals 22, a series circuit of the AC power source 8 and the load 9 can be connected.
負載控制裝置1a中,雙方向開關元件2,在交流電源8與負載9之間,串聯連接交流電源8及負載9。詳細而言,雙方向開關元件2,與交流電源8及負載9一齊構成作為供電路之閉電路。供電路,構成至少包含串聯連接交流電源8、負載9、雙方向開關元件2之電路之閉電路。藉此,負載控制裝置1a,可控制負載9之導通、切斷。交流電源8,係例如商用電源。負載9,係例如照明負載(調光器等)。In the load control device 1a, the bidirectional switching element 2 is connected in series between the AC power source 8 and the load 9 with an AC power source 8 and a load 9. Specifically, the bidirectional switching element 2 constitutes a closed circuit as a supply circuit together with the AC power supply 8 and the load 9. The supply circuit constitutes a closed circuit including at least a circuit in which the AC power supply 8, the load 9, and the bidirectional switching element 2 are connected in series. Thereby, the load control device 1a can control the conduction and disconnection of the load 9. The AC power source 8 is, for example, a commercial power source. The load 9, for example, is a lighting load (dimmer, etc.).
雙方向開關元件2,係沿第1源極電極S1與第2源極電極S2之間之任一偏壓方向,皆可呈導通(導通狀態)與切斷(切斷狀態)之2個穩定狀態之交流開關元件。雙方向開關元件2,以包含第1閘極電極G1、第2閘極電極G2、第1源極電極S1及第2源極電極S2之常閉型異質接頭場效型電晶體(heterojunction field effect transistor:HFET)構成。此時,雙方向開關元件2中,第1源極電極S1構成第1主電極,第2源極電極S2構成第2主電極。The bidirectional switching element 2 is stable in both the conduction state (on state) and the off (disconnection state) in any bias direction between the first source electrode S1 and the second source electrode S2. State AC switching element. The bidirectional switching element 2 is a normally closed type heterojunction field effect transistor including a first gate electrode G1, a second gate electrode G2, a first source electrode S1, and a second source electrode S2. Transistor: HFET). At this time, in the bidirectional switching element 2, the first source electrode S1 constitutes the first main electrode, and the second source electrode S2 constitutes the second main electrode.
作為HFET,例如可採用AlGaN/GaN類HFET。雙方向開關元件2中,第1源極電極S1連接第1主端子21,第2源極電極S2連接第2主端子22。As the HFET, for example, an AlGaN/GaN-based HFET can be used. In the bidirectional switching element 2, the first source electrode S1 is connected to the first main terminal 21, and the second source electrode S2 is connected to the second main terminal 22.
作為雙方向開關元件2,亦可採用圖10之2線式交流開關中之雙方向開關元件103。As the bidirectional switching element 2, the bidirectional switching element 103 of the 2-wire type AC switch of Fig. 10 can also be used.
亦可逆串聯連接2個金屬氧化膜半導體場效型電晶體(metal oxide semiconductor field effect transistor:MOSFET)而構成雙方向開關元件2。雙方向開關元件2中,作為各MOSFET,例如採用增強型(常閉型)n通道MOSFET,連接兩MOSFET之汲極電極彼此即可。又,各MOSFET,包含內建二極體(亦稱「本體二極體」或「寄生二極體」)。各內建二極體,用作為整流用二極體。The two-direction switching element 2 may be formed by connecting two metal oxide semiconductor field effect transistors (MOSFETs) in series in reverse. In the bidirectional switching element 2, for example, an reinforced (normally closed) n-channel MOSFET is used as the MOSFET, and the drain electrodes of the two MOSFETs are connected to each other. Further, each MOSFET includes a built-in diode (also referred to as a "body diode" or a "parasitic diode"). Each built-in diode is used as a rectifier diode.
作為MOSFET,例如可採用Si類MOSFET。MOSFET,不限於Si類MOSFET,例如亦可採用SiC類MOSFET、GaN類MOSFET等。As the MOSFET, for example, a Si-type MOSFET can be used. The MOSFET is not limited to a Si-type MOSFET, and for example, a SiC-based MOSFET or a GaN-based MOSFET can be used.
二極體橋式電路3,如圖2、3所示,係橋式連接4個二極體D01、D02、D03及D04之全波整流電路。The diode bridge circuit 3, as shown in FIGS. 2 and 3, is a bridge-connected full-wave rectifier circuit of four diodes D01, D02, D03, and D04.
二極體橋式電路3中,並聯連接2個二極體D01、D02之串聯電路,與2個二極體D03、D04之串聯電路,藉此,橋式連接4個二極體D01、D02、D03及D04。具體而言,二極體D01之陰極連接二極體D02之陽極,二極體D03之陰極連接二極體D04之陽極,二極體D02之陰極連接二極體D04之陰極,二極體D01之陽極連接二極體D03之陽極。二極體橋式電路3中,2個二極體D01、D02之連接點構成第1交流輸入端子31,2個二極體D03、D04之連接點構成第2交流輸入端子32。且二極體橋式電路3中,2個二極體D02、D04之連接點構成正端子(正極性輸出端子)33,2個二極體D01、D03之連接點構成負端子(負極性輸出端子)34。In the diode bridge circuit 3, a series circuit of two diodes D01 and D02 is connected in parallel, and a series circuit of two diodes D03 and D04 is connected, thereby connecting four diodes D01 and D02 in a bridge manner. , D03 and D04. Specifically, the cathode of the diode D01 is connected to the anode of the diode D02, the cathode of the diode D03 is connected to the anode of the diode D04, the cathode of the diode D02 is connected to the cathode of the diode D04, and the diode D01 The anode is connected to the anode of the diode D03. In the diode bridge circuit 3, the connection point of the two diodes D01 and D02 constitutes the first AC input terminal 31, and the connection point of the two diodes D03 and D04 constitutes the second AC input terminal 32. In the diode bridge circuit 3, the connection points of the two diodes D02 and D04 constitute a positive terminal (positive polarity output terminal) 33, and the connection points of the two diodes D01 and D03 constitute a negative terminal (negative polarity output) Terminal) 34.
簡要而言,二極體橋式電路3,包含第1交流輸入端子31、第2交流輸入端子32、正端子33、與負端子34。二極體橋式電路3中,第1交流輸入端子31連接第1主端子21及第1源極電極S1,第2交流輸入端子32連接第2主端子22及第2源極電極S2。Briefly, the diode bridge circuit 3 includes a first AC input terminal 31, a second AC input terminal 32, a positive terminal 33, and a negative terminal 34. In the diode bridge circuit 3, the first AC input terminal 31 is connected to the first main terminal 21 and the first source electrode S1, and the second AC input terminal 32 is connected to the second main terminal 22 and the second source electrode S2.
二極體橋式電路3,具有將來自連接雙方向開關元件2之第1源極電極S1與第2源極電極S2之間之交流電源8之交流電壓,加以全波整流之功能。簡要而言,二極體橋式電路3,將來自交流電源8之交流電壓經全波整流之電壓,對正端子33與負端子34之間輸出。The diode bridge circuit 3 has a function of full-wave rectifying an AC voltage from an AC power source 8 connecting the first source electrode S1 and the second source electrode S2 of the bidirectional switching element 2. Briefly, the diode bridge circuit 3 converts the AC voltage from the AC power source 8 through a full-wave rectified voltage, and outputs it between the positive terminal 33 and the negative terminal 34.
負載控制裝置1a中,在二極體橋式電路3之正端子33與負端子34之間,連接電源電路4。In the load control device 1a, the power supply circuit 4 is connected between the positive terminal 33 and the negative terminal 34 of the diode bridge circuit 3.
電源電路4,係將二極體橋式電路3之輸出電壓轉換為既定之直流電壓之恆定電壓電路。The power supply circuit 4 is a constant voltage circuit that converts the output voltage of the diode bridge circuit 3 into a predetermined DC voltage.
電源電路4,係包含npn電晶體Q4、齊納二極體ZD4、電阻R4、與平滑電容器C4之恆定電壓電路。此恆定電壓電路,係在二極體橋式電路3之正端子33,與電源電路4之高電位側之輸出端41之間,夾設npn電晶體Q4之串聯型恆定電壓電路。The power supply circuit 4 is a constant voltage circuit including an npn transistor Q4, a Zener diode ZD4, a resistor R4, and a smoothing capacitor C4. The constant voltage circuit is connected between the positive terminal 33 of the diode bridge circuit 3 and the output terminal 41 of the high potential side of the power supply circuit 4, and a series constant voltage circuit of the npn transistor Q4 is interposed.
電源電路4中,電阻R4與齊納二極體ZD4之串聯電路,連接二極體橋式電路3之正端子33與負端子34之間。電源電路4中,電阻R4之第1端,連接二極體橋式電路3之正端子33,電阻R4之第2端,連接齊納二極體ZD4之陰極,齊納二極體ZD4之陽極,連接二極體橋式電路3之負端子34。且電源電路4中,npn電晶體Q4之集極端子,連接電阻R4之第1端,基極端子,連接電阻R4與齊納二極體ZD4之連接點。且電源電路4中,平滑電容器C4,在npn電晶體Q4之射極端子與齊納二極體ZD4之陽極之間,並聯連接npn電晶體Q4與齊納二極體ZD4之串聯電路。平滑電容器C4,以鋁電解電容器等有極性之電容器構成。In the power supply circuit 4, a series circuit of a resistor R4 and a Zener diode ZD4 is connected between the positive terminal 33 and the negative terminal 34 of the diode bridge circuit 3. In the power circuit 4, the first end of the resistor R4 is connected to the positive terminal 33 of the diode bridge circuit 3, the second terminal of the resistor R4, the cathode of the Zener diode ZD4, and the anode of the Zener diode ZD4. Connect the negative terminal 34 of the diode bridge circuit 3. Further, in the power supply circuit 4, the collector terminal of the npn transistor Q4 is connected to the first end of the resistor R4, the base terminal, and the connection point of the resistor R4 and the Zener diode ZD4. Further, in the power supply circuit 4, the smoothing capacitor C4 is connected in parallel between the emitter terminal of the npn transistor Q4 and the anode of the Zener diode ZD4 in parallel with the series circuit of the npn transistor Q4 and the Zener diode ZD4. The smoothing capacitor C4 is formed of a capacitor having polarity such as an aluminum electrolytic capacitor.
電源電路4之輸出電壓VDD,係平滑電容器C4之兩端電壓。電源電路4,保持輸出電壓VDD於一定。電源電路4之輸出電壓VDD,為自齊納二極體ZD4之齊納電壓,減去npn電晶體Q4之基極端子・射極端子間電壓之值。又,電源電路4之電路構成,係一例,只要是恆定電壓電路,不特別限定其電路構成。The output voltage VDD of the power supply circuit 4 is the voltage across the smoothing capacitor C4. The power supply circuit 4 keeps the output voltage VDD constant. The output voltage VDD of the power supply circuit 4 is the Zener voltage from the Zener diode ZD4, and the value of the voltage between the base terminal and the emitter terminal of the npn transistor Q4 is subtracted. Moreover, the circuit configuration of the power supply circuit 4 is an example, and the circuit configuration is not particularly limited as long as it is a constant voltage circuit.
負載控制裝置1a,包含輸入由控制電路100產生之控制信號CS之端子7。控制電路100,係控制閘驅動電路6a之電路。控制電路100,對端子7輸出控制信號CS。又,端子7,亦可以由控制電路100輸出控制信號CS之輸出端子構成。且控制電路100,例如可以搭載適當程式之微電腦構成。控制電路100所需之電力,亦可自電源電路4供給。The load control device 1a includes a terminal 7 that inputs a control signal CS generated by the control circuit 100. The control circuit 100 is a circuit that controls the gate drive circuit 6a. The control circuit 100 outputs a control signal CS to the terminal 7. Further, the terminal 7 may be constituted by an output terminal of the control circuit 100 for outputting the control signal CS. Further, the control circuit 100 can be configured, for example, by a microcomputer having an appropriate program. The power required by the control circuit 100 can also be supplied from the power supply circuit 4.
控制電路100,在自交流電源8對負載9供給電力時,使雙方向開關元件2導通。此時,控制電路100控制閘驅動電路6a,俾閘驅動電路6a,對雙方向開關元件2之第1閘極電極G1、第2閘極電極G2,輸出高於第1閘極電極G1與第1源極電極S1之間之第1閘極臨界值電壓、第2閘極電極G2與第2源極電極S2之間之第2閘極臨界值電壓之驅動電壓。藉此,控制電路100,使雙方向開關元件2導通。又,雙方向開關元件2中,第1閘極臨界值電壓與第2閘極臨界值電壓宜相同。The control circuit 100 turns on the bidirectional switching element 2 when power is supplied from the AC power source 8 to the load 9. At this time, the control circuit 100 controls the gate drive circuit 6a, and the gate drive circuit 6a outputs the higher value than the first gate electrode G1 and the first gate electrode G1 and the second gate electrode G2 of the bidirectional switch element 2. The driving voltage of the first gate threshold voltage between the source electrode S1 and the second gate threshold voltage between the second gate electrode G2 and the second source electrode S2. Thereby, the control circuit 100 turns on the bidirectional switching element 2. Further, in the bidirectional switching element 2, the first gate threshold voltage and the second gate threshold voltage are preferably the same.
且控制電路100,在隔斷自交流電源8對負載9供給電力時,使雙方向開關元件2切斷。此時,控制電路100控制閘驅動電路6a,俾閘驅動電路6a,對雙方向開關元件2之第1閘極電極G1、第2閘極電極G2,輸出低於第1閘極臨界值電壓、第2閘極臨界值電壓之電壓。藉此,控制電路100,使雙方向開關元件2切斷。Further, when the control circuit 100 supplies power to the load 9 from the AC power source 8, the bidirectional switching element 2 is turned off. At this time, the control circuit 100 controls the gate drive circuit 6a, and the gate drive circuit 6a outputs the threshold value lower than the first gate threshold voltage to the first gate electrode G1 and the second gate electrode G2 of the bidirectional switch element 2, The voltage of the second gate threshold voltage. Thereby, the control circuit 100 turns off the bidirectional switching element 2.
控制電路100,經由連接端子300,連接外部之設定部200。控制電路100,從設定部200,傳達指示是否自交流電源8對負載9供給電力之信號。控制電路100,根據自設定部200傳達之信號,輸出控制信號CS。具體而言,控制電路100,從設定部200,傳達指示自交流電源8對負載9供給電力之信號時,控制信號CS為高位準VH,傳達指示不自交流電源8對負載9供給電力(隔斷自交流電源8對負載9供給電力)之信號時,控制信號CS為低位準VL。例如設定部200,對控制電路100,輸出指示以既定之頻率及占空比切換自交流電源8對負載9之電力之供給與隔斷之切換信號。此時,控制電路100,作為控制信號CS,輸出依對應來自設定部200之切換信號之頻率及占空比,其電壓在高位準VH與低位準VL交互切換之PWM信號。閘驅動電路6a,根據控制信號CS,控制雙方向開關元件2之開關動作。The control circuit 100 is connected to the external setting unit 200 via the connection terminal 300. The control circuit 100 transmits a signal indicating whether or not the power is supplied from the AC power source 8 to the load 9 from the setting unit 200. The control circuit 100 outputs a control signal CS based on the signal transmitted from the setting unit 200. Specifically, when the control unit 100 transmits a signal indicating that power is supplied from the AC power source 8 to the load 9 from the setting unit 200, the control signal CS is at the high level VH, and the instruction is not to supply power to the load 9 from the AC power source 8 (interruption) When the signal is supplied from the AC power source 8 to the load 9, the control signal CS is at the low level VL. For example, the setting unit 200 outputs, to the control circuit 100, a switching signal for instructing switching of supply and disconnection of power from the AC power source 8 to the load 9 at a predetermined frequency and duty ratio. At this time, the control circuit 100 outputs, as the control signal CS, a PWM signal whose voltage is switched between the high level VH and the low level VL in accordance with the frequency and duty ratio of the switching signal from the setting unit 200. The gate drive circuit 6a controls the switching operation of the bidirectional switching element 2 based on the control signal CS.
閘驅動電路6a,具有自電源電路4對雙方向開關元件2之第1閘極電極G1及第2閘極電極G2供給用來使雙方向開關元件2導通之驅動電壓之功能。The gate driving circuit 6a has a function of supplying a driving voltage for turning on the bidirectional switching element 2 from the power supply circuit 4 to the first gate electrode G1 and the second gate electrode G2 of the bidirectional switching element 2.
閘驅動電路6a,包含MOSFET61、反相器62、第1二極體D1、第2二極體D2、與2個電阻R61、R62。The gate driving circuit 6a includes a MOSFET 61, an inverter 62, a first diode D1, a second diode D2, and two resistors R61 and R62.
閘驅動電路6a,作為MOSFET61,採用增強型p通道MOSFET。MOSFET61中,源極端子,連接電源電路4之高電位側之輸出端41,汲極端子,連接第1二極體D1與第2二極體D2之陽極彼此之連接點,閘極端子,連接反相器62之輸出端子。第1二極體D1、第2二極體D2之各陰極,分別連接第1閘極電極G1、第2閘極電極G2。電阻R61,連接雙方向開關元件2之第1源極電極S1與第1閘極電極G1之間,電阻R62,連接雙方向開關元件2之第2源極電極S2與第2閘極電極G2之間。反相器62中,輸入端子連接端子7。簡要而言,反相器62,使來自端子7之控制信號CS反轉,對MOSFET61之閘極端子輸入。因此,閘驅動電路6a中,控制信號CS為低位準VL時,反相器62之輸出為高位準,MOSFET61為切斷。另一方面,閘驅動電路6a中,控制信號CS為高位準VH時,反相器62之輸出為低位準,MOSFET61為導通。The gate drive circuit 6a, as the MOSFET 61, employs an enhancement type p-channel MOSFET. In the MOSFET 61, the source terminal is connected to the output terminal 41 on the high potential side of the power supply circuit 4, and the 汲 terminal is connected to the junction of the anodes of the first diode D1 and the second diode D2, and the gate terminal is connected. The output terminal of the inverter 62. The cathodes of the first diode D1 and the second diode D2 are connected to the first gate electrode G1 and the second gate electrode G2, respectively. The resistor R61 is connected between the first source electrode S1 and the first gate electrode G1 of the bidirectional switching element 2, and the resistor R62 is connected to the second source electrode S2 and the second gate electrode G2 of the bidirectional switching element 2. between. In the inverter 62, the input terminal is connected to the terminal 7. Briefly, the inverter 62 inverts the control signal CS from the terminal 7 and inputs it to the gate terminal of the MOSFET 61. Therefore, in the gate driving circuit 6a, when the control signal CS is at the low level VL, the output of the inverter 62 is at the high level, and the MOSFET 61 is turned off. On the other hand, in the gate driving circuit 6a, when the control signal CS is at the high level VH, the output of the inverter 62 is at the low level, and the MOSFET 61 is turned on.
亦即,如圖1所示,本實施形態之負載控制裝置1a中,閘驅動電路6a,以開關電路63a、第1並聯電路64、與第2並聯電路65構成。That is, as shown in Fig. 1, in the load control device 1a of the present embodiment, the gate drive circuit 6a is constituted by a switch circuit 63a, a first parallel circuit 64, and a second parallel circuit 65.
本實施形態之開關電路63a,包含連接電源電路4之高電位側之輸出端41之輸入部66a、及輸出部67a,控制信號CS為高位準VH時,對輸出部67a供給來自輸入部66a之電力。The switch circuit 63a of the present embodiment includes an input unit 66a that connects the output terminal 41 on the high potential side of the power supply circuit 4, and an output unit 67a. When the control signal CS is at the high level VH, the output unit 67a is supplied from the input unit 66a. electric power.
一例中,開關電路63a,由夾設在輸入部66a與輸出部67a之間之MOSFET61,及反相器62構成。例如開關電路63a中,由反相器62輸入之控制信號CS為高位準VH時,MOSFET61為導通,對輸出部67a供給來自輸入部66a之電力。In one example, the switch circuit 63a is composed of a MOSFET 61 interposed between the input unit 66a and the output unit 67a, and an inverter 62. For example, in the switch circuit 63a, when the control signal CS input from the inverter 62 is at the high level VH, the MOSFET 61 is turned on, and the power from the input unit 66a is supplied to the output unit 67a.
本實施形態之第1並聯電路64,夾設在開關電路63a之輸出部67a與第1閘極電極G1之間,於第1閘極電極G1與第1源極電極S1之間連接雙方向開關元件2。第1並聯電路64,在控制信號CS為高位準VH時,對第1閘極電極G1與第1源極電極S1之間施加驅動電壓。The first parallel circuit 64 of the present embodiment is interposed between the output portion 67a of the switch circuit 63a and the first gate electrode G1, and is connected to the bidirectional switch between the first gate electrode G1 and the first source electrode S1. Element 2. When the control signal CS is at the high level VH, the first parallel circuit 64 applies a driving voltage between the first gate electrode G1 and the first source electrode S1.
一例中,第1並聯電路64,由第1二極體D1與電阻(第1並聯電阻)R61構成。第1二極體D1中,陽極連接輸出部67a,陰極連接第1閘極電極G1。電阻R61,連接第1二極體D1之陽極與第1閘極電極G1之連接點,和第1源極電極S1之間。In one example, the first parallel circuit 64 is composed of a first diode D1 and a resistor (first parallel resistor) R61. In the first diode D1, the anode is connected to the output portion 67a, and the cathode is connected to the first gate electrode G1. The resistor R61 connects the connection point between the anode of the first diode D1 and the first gate electrode G1 and the first source electrode S1.
本實施形態之第2並聯電路65,夾設在開關電路63a之輸出部67a與第2閘極電極G2之間,於第2閘極電極G2與第2源極電極S2之間連接雙方向開關元件2。第2並聯電路65,在控制信號CS為高位準VH時,對第2閘極電極G2與第2源極電極S2之間施加驅動電壓。The second parallel circuit 65 of the present embodiment is interposed between the output portion 67a of the switch circuit 63a and the second gate electrode G2, and is connected to the bidirectional switch between the second gate electrode G2 and the second source electrode S2. Element 2. When the control signal CS is at the high level VH, the second parallel circuit 65 applies a driving voltage between the second gate electrode G2 and the second source electrode S2.
一例中,第2並聯電路65,由第2二極體D2與電阻(第2並聯電阻)R62構成。第2二極體D2中,陽極連接輸出部67a,陰極連接第2閘極電極G2。電阻R62,連接第2二極體D2之陽極與第2閘極電極G2之連接點,和第2源極電極S2之間。In one example, the second parallel circuit 65 is composed of a second diode D2 and a resistor (second parallel resistor) R62. In the second diode D2, the anode is connected to the output portion 67a, and the cathode is connected to the second gate electrode G2. The resistor R62 connects the connection point between the anode of the second diode D2 and the second gate electrode G2 and the second source electrode S2.
位準轉換電路5a,設於二極體橋式電路3與電源電路4之間。位準轉換電路5a,具有以既定阻抗Imp1使二極體橋式電路3之正端子33與負端子34之間導通之功能。位準轉換電路5a,包含雙極性電晶體Q5,雙極性電晶體Q5之集極端子連接正端子33,射極端子連接負端子34,對基極端子,輸入控制信號CS。位準轉換電路5a,包含電阻R51,雙極性電晶體Q5之基極端子,經由電阻R51連接端子7。The level conversion circuit 5a is provided between the diode bridge circuit 3 and the power supply circuit 4. The level shift circuit 5a has a function of turning on between the positive terminal 33 and the negative terminal 34 of the diode bridge circuit 3 with a predetermined impedance Imp1. The level conversion circuit 5a includes a bipolar transistor Q5. The collector terminal of the bipolar transistor Q5 is connected to the positive terminal 33, the emitter terminal is connected to the negative terminal 34, and the base terminal is input with a control signal CS. The level conversion circuit 5a includes a resistor R51, a base terminal of the bipolar transistor Q5, and is connected to the terminal 7 via a resistor R51.
位準轉換電路5a,在控制信號CS為低位準VL時,雙極性電晶體Q5為切斷,使二極體橋式電路3之正端子33與負端子34之間為非導通。In the level conversion circuit 5a, when the control signal CS is at the low level VL, the bipolar transistor Q5 is turned off, and the positive terminal 33 and the negative terminal 34 of the diode bridge circuit 3 are rendered non-conductive.
位準轉換電路5a,在控制信號CS為高位準VH時,雙極性電晶體Q5為導通,以既定之阻抗Imp1使二極體橋式電路3之正端子33與負端子34之間導通。在此,本實施形態中,既定阻抗Imp1,係雙極性電晶體Q5之導通電阻,略為零。The level shifting circuit 5a turns on the bipolar transistor Q5 when the control signal CS is at the high level VH, and turns on between the positive terminal 33 and the negative terminal 34 of the diode bridge circuit 3 with a predetermined impedance Imp1. Here, in the present embodiment, the predetermined impedance Imp1 is the on-resistance of the bipolar transistor Q5, which is slightly zero.
圖2、3,係控制信號CS為高位準VH時負載控制裝置1a之動作說明圖。2 and 3 are explanatory diagrams of the operation of the load control device 1a when the control signal CS is at the high level VH.
負載控制裝置1a中,形成自電源電路4之平滑電容器C4對第1閘極電極G1及第2閘極電極G2供給閘極電流之電流通道,俾控制信號CS為高位準VH時,維持雙方向開關元件2之導通狀態,自交流電源8對負載9供給電力。圖2、3中,以短劃線表示此電流通道。In the load control device 1a, a smoothing capacitor C4 from the power supply circuit 4 is formed to supply a current path of a gate current to the first gate electrode G1 and the second gate electrode G2, and when the ? control signal CS is at a high level VH, the bidirectional direction is maintained. The conduction state of the switching element 2 supplies electric power to the load 9 from the AC power source 8. In Figures 2 and 3, this current path is indicated by a dashed line.
圖2中,以短劃線表示交流電源8之交流電壓之極性,為圖2中電流沿箭頭B1所示之方向流動之極性之期間(交流電源8,對第1主端子21施加正電壓之期間;以下,此期間稱「第1期間」)所形成之電流通道(以下,稱「第1電流通道CP1」。)。第1電流通道CP1,係電源電路4之平滑電容器C4→閘驅動電路6a之MOSFET61→閘驅動電路6a之第1二極體D1、第2二極體D2→雙方向開關元件2之第2源極電極S2→二極體橋式電路3之二極體D04→位準轉換電路5a之雙極性電晶體Q5→平滑電容器C4之通道。In FIG. 2, the polarity of the AC voltage of the AC power source 8 is indicated by a dashed line, and the polarity of the current flowing in the direction indicated by the arrow B1 in FIG. 2 (the AC power source 8 applies a positive voltage to the first main terminal 21). In the following, the current channel formed in the "first period" (hereinafter, referred to as "the first current channel CP1"). The first current channel CP1 is a smoothing capacitor C4 of the power supply circuit 4 → a MOSFET 61 of the gate driving circuit 6 a → a first diode D1 and a second diode D2 of the gate driving circuit 6 a → a second source of the bidirectional switching element 2 The pole electrode S2 → the diode D04 of the diode bridge circuit 3 → the channel of the bipolar transistor Q5 → the smoothing capacitor C4 of the level shifting circuit 5a.
圖3中,以短劃線表示交流電源8之交流電壓之極性,為圖3中電流沿箭頭B2所示之方向流動之極性之期間(交流電源8,對第2主端子22施加正電壓之期間;以下,稱此期間為「第2期間」)所形成之電流通道(以下,稱「第2電流通道CP2」。)。第2電流通道CP2,係電源電路4之平滑電容器C4→閘驅動電路6a之MOSFET61→閘驅動電路6a之第1二極體D1、第2二極體D2→雙方向開關元件2之第1源極電極S1→二極體橋式電路3之二極體D02→位準轉換電路5a之雙極性電晶體Q5→平滑電容器C4之通道。In FIG. 3, the polarity of the AC voltage of the AC power source 8 is indicated by a dashed line, and is a period in which the current flows in the direction indicated by the arrow B2 in FIG. 3 (the AC power source 8 applies a positive voltage to the second main terminal 22). In the following, the current channel formed by the "second period" is referred to as "the second current channel CP2". The second current channel CP2 is a smoothing capacitor C4 of the power supply circuit 4 → a MOSFET 61 of the gate driving circuit 6 a → a first diode D1 and a second diode D2 of the gate driving circuit 6 a → a first source of the bidirectional switching element 2 The pole electrode S1 → the diode D02 of the diode bridge circuit 3 → the channel of the bipolar transistor Q5 → the smoothing capacitor C4 of the level shifting circuit 5a.
簡要而言,負載控制裝置1a中,可藉由位準轉換電路5a,形成自電源電路4之平滑電容器C4對雙方向開關元件2之第1閘極電極G1及第2閘極電極G2雙方供給閘極電流之第1電流通道CP1、第2電流通道CP2各一部分。換言之,控制信號CS為高位準VH時,MOSFET61為導通,且雙極性電晶體Q5為導通,藉此,形成自電源電路4對第1閘極電極G1及第2閘極電極G2雙方供給閘極電流之電流通道CP1、CP2,雙方向開關元件2之第1源極電極S1與第2源極電極S2之間導通。藉此,負載控制裝置1a中,可不於閘驅動電路6a,設置用來各別產生分別以第1源極電極S1、第2源極電極S2為基準之電位之位準移位電路,藉由以二極體橋式電路3之負端子34為基準之電壓驅動雙方向開關元件2。藉此,負載控制裝置1a,可實現小型化。Briefly, in the load control device 1a, the smoothing capacitor C4 from the power supply circuit 4 can be used to supply both the first gate electrode G1 and the second gate electrode G2 of the bidirectional switching element 2 by the level conversion circuit 5a. Each of the first current channel CP1 and the second current channel CP2 of the gate current. In other words, when the control signal CS is at the high level VH, the MOSFET 61 is turned on, and the bipolar transistor Q5 is turned on, whereby the gate electrode is supplied from the power supply circuit 4 to both the first gate electrode G1 and the second gate electrode G2. The current paths CP1 and CP2 of the current are electrically connected between the first source electrode S1 and the second source electrode S2 of the bidirectional switching element 2. Thereby, in the load control device 1a, the level shift circuit for generating the potentials based on the first source electrode S1 and the second source electrode S2, respectively, can be provided without the gate drive circuit 6a. The bidirectional switching element 2 is driven by a voltage based on the negative terminal 34 of the diode bridge circuit 3. Thereby, the load control device 1a can be downsized.
特別是,負載控制裝置1a中,可不設置以往用於開關元件之驅動之變壓器,驅動雙方向開關元件2,故可實現裝置之小型化。In particular, in the load control device 1a, the transformer for driving the switching element can be omitted, and the bidirectional switching element 2 can be driven, so that the size of the device can be reduced.
如以上說明,本實施形態之負載控制裝置1a,如圖1所示,包含雙方向開關元件2、二極體橋式電路3、電源電路4、位準轉換電路5a、與閘驅動電路6a。雙方向開關元件2,設於自交流電源8對負載9之供電路。雙方向開關元件2,包含第1閘極電極G1、第2閘極電極G2、第1源極電極S1及第2源極電極S2,分別對第1閘極電極G1與第1源極電極S1之間、第2閘極電極G2與第2源極電極S2之間施加既定之驅動電壓,藉此,第1源極電極S1與第2源極電極S2之間導通。二極體橋式電路3中,第1交流輸入端子31連接第1源極電極S1,第2交流輸入端子32連接第2源極電極S2。電源電路4,使二極體橋式電路3之正端子33與二極體橋式電路3之負端子34之間之輸出電壓恆定電壓化。位準轉換電路5a,以既定阻抗使正端子33與負端子34之間導通。閘驅動電路6a,自電源電路4對雙方向開關元件2之第1閘極電極G1及第2閘極電極G2供給用來使雙方向開關元件2導通之驅動電壓。閘驅動電路6a,可輸入用來控制導通、切斷雙方向開關元件2之控制信號CS,且控制信號CS為高位準VH時,自電源電路4對第1閘極電極G1及第2閘極電極G2供給驅動電壓。位準轉換電路5a,包含雙極性電晶體Q5,雙極性電晶體Q5之集極端子連接正端子33,射極端子連接負端子34,對基極端子,輸入控制信號CS。位準轉換電路5a,在控制信號CS為高位準VH時,雙極性電晶體Q5為導通。As described above, the load control device 1a of the present embodiment includes the bidirectional switching element 2, the diode bridge circuit 3, the power supply circuit 4, the level conversion circuit 5a, and the gate drive circuit 6a as shown in Fig. 1 . The bidirectional switching element 2 is provided in a supply circuit from the AC power source 8 to the load 9. The bidirectional switching element 2 includes a first gate electrode G1, a second gate electrode G2, a first source electrode S1, and a second source electrode S2, and is respectively paired with the first gate electrode G1 and the first source electrode S1. A predetermined driving voltage is applied between the second gate electrode G2 and the second source electrode S2, whereby the first source electrode S1 and the second source electrode S2 are electrically connected to each other. In the diode bridge circuit 3, the first AC input terminal 31 is connected to the first source electrode S1, and the second AC input terminal 32 is connected to the second source electrode S2. The power supply circuit 4 constantly voltages the output voltage between the positive terminal 33 of the diode bridge circuit 3 and the negative terminal 34 of the diode bridge circuit 3. The level shift circuit 5a turns on between the positive terminal 33 and the negative terminal 34 with a predetermined impedance. The gate drive circuit 6a supplies a driving voltage for turning on the bidirectional switching element 2 from the power supply circuit 4 to the first gate electrode G1 and the second gate electrode G2 of the bidirectional switching element 2. The gate driving circuit 6a can input a control signal CS for controlling the turning on and off of the bidirectional switching element 2, and when the control signal CS is at the high level VH, the first gate electrode G1 and the second gate are connected from the power supply circuit 4. The electrode G2 supplies a driving voltage. The level conversion circuit 5a includes a bipolar transistor Q5. The collector terminal of the bipolar transistor Q5 is connected to the positive terminal 33, the emitter terminal is connected to the negative terminal 34, and the base terminal is input with a control signal CS. The level shift circuit 5a turns on the bipolar transistor Q5 when the control signal CS is at the high level VH.
藉此,本實施形態之負載控制裝置1a,可實現小型化。Thereby, the load control device 1a of the present embodiment can be downsized.
於以下,根據圖4說明關於本實施形態之負載控制裝置1a之變形例之負載控制裝置1b。變形例之負載控制裝置1b中,不包含實施形態1之負載控制裝置1a中之位準轉換電路5a,代之以位準轉換電路5b,此點與實施形態1之負載控制裝置1a相異。又,就與實施形態1之負載控制裝置1a相同之構成要素,賦予相同之符號,省略說明。Hereinafter, a load control device 1b according to a modification of the load control device 1a of the present embodiment will be described with reference to Fig. 4 . The load control device 1b according to the modification does not include the level conversion circuit 5a of the load control device 1a of the first embodiment, and the level conversion circuit 5b is replaced with the load control device 1a of the first embodiment. The same components as those of the load control device 1a of the first embodiment are denoted by the same reference numerals and will not be described.
位準轉換電路5b,電路構成與位準轉換電路5a略同,包含連接雙極性電晶體Q5之射極端子與二極體橋式電路3之負端子34之間之第1電阻R52之點相異。The level conversion circuit 5b has a circuit configuration similar to that of the level conversion circuit 5a, and includes a phase of the first resistor R52 connecting the emitter terminal of the bipolar transistor Q5 and the negative terminal 34 of the diode bridge circuit 3. different.
位準轉換電路5b,在控制信號CS為高位準VH時雙極性電晶體Q5為導通,以既定阻抗Imp2使二極體橋式電路3之正端子33與負端子34之間導通。在此,本變形例中,既定阻抗Imp2,為雙極性電晶體Q5之導通電阻,與第1電阻R52之電阻值之合成電阻值。雙極性電晶體Q5之導通電阻值略為零,故既定阻抗Imp2,可視為第1電阻R52之電阻值。The level shifting circuit 5b turns on the bipolar transistor Q5 when the control signal CS is at the high level VH, and turns on between the positive terminal 33 and the negative terminal 34 of the diode bridge circuit 3 with a predetermined impedance Imp2. Here, in the present modification, the predetermined impedance Imp2 is a combined resistance value of the on-resistance of the bipolar transistor Q5 and the resistance value of the first resistor R52. The on-resistance value of the bipolar transistor Q5 is slightly zero, so the predetermined impedance Imp2 can be regarded as the resistance value of the first resistor R52.
負載控制裝置1b中,位準轉換電路5b,包含第1電阻R52,藉此,可使於位準轉換電路5b流動之電流恆定電流化,限制分別於雙方向開關元件2之第1閘極電極G1及第2閘極電極G2流動之閘極電流。藉此,負載控制裝置1b中,第1電阻R52用作為限流用電阻,相較於負載控制裝置1a,可實現閘驅動電路6a之低消耗電流化。In the load control device 1b, the level conversion circuit 5b includes the first resistor R52, whereby the current flowing through the level conversion circuit 5b can be made constant current, and the first gate electrode of the bidirectional switching element 2 is limited. The gate current flowing through G1 and the second gate electrode G2. As a result, in the load control device 1b, the first resistor R52 functions as a current limiting resistor, and the gate drive circuit 6a can achieve a lower current consumption than the load control device 1a.
如以上說明,本變形例之負載控制裝置1b中,如圖4所示,位準轉換電路5b,更包含連接雙極性電晶體Q5之射極端子與二極體橋式電路3之負端子34之間之第1電阻R52。藉此,可實現閘驅動電路6a之低消耗電力化。As described above, in the load control device 1b of the present modification, as shown in FIG. 4, the level conversion circuit 5b further includes an emitter terminal connecting the bipolar transistor Q5 and a negative terminal 34 of the diode bridge circuit 3. The first resistor R52 is between. Thereby, the power consumption of the gate drive circuit 6a can be reduced.
(實施形態2) 於以下,根據圖5~圖7B說明關於本實施形態之負載控制裝置1c。又,就與實施形態1之負載控制裝置1a相同之構成要素,賦予相同符號,適當省略說明。(Embodiment 2) Hereinafter, a load control device 1c according to the present embodiment will be described with reference to Figs. 5 to 7B. The same components as those of the load control device 1a of the first embodiment are denoted by the same reference numerals, and the description thereof will be appropriately omitted.
本實施形態之負載控制裝置1c,不包含實施形態1之負載控制裝置1a之閘驅動電路6a,代之以閘驅動電路6c,此點相異。The load control device 1c of the present embodiment does not include the gate drive circuit 6a of the load control device 1a of the first embodiment, and the gate drive circuit 6c is replaced by the gate drive circuit 6c.
閘驅動電路6c,自電源電路4對雙方向開關元件2之第1閘極電極G1及第2閘極電極G2供給用來使雙方向開關元件2導通之既定之驅動電流ID。The gate drive circuit 6c supplies a predetermined drive current ID for turning on the bidirectional switch element 2 from the power supply circuit 4 to the first gate electrode G1 and the second gate electrode G2 of the bidirectional switch element 2.
本實施形態之閘驅動電路6c,如圖6所示,控制信號CS自低位準VL朝高位準VH變化時,對第1閘極電極G1及第2閘極電極G2恰供給作為閘極電流大於驅動電流ID之電流設定時間T1。閘驅動電路6c,在自結束恰對第1閘極電極G1及第2閘極電極G2供給大於驅動電流ID之電流設定時間T1之時點,至控制信號CS自高位準VH朝低位準VL變化之時點,持續對第1閘極電極G1及第2閘極電極G2供給驅動電流ID。As shown in FIG. 6, when the control signal CS changes from the low level VL to the high level VH, the gate drive circuit 6c of the present embodiment supplies the first gate electrode G1 and the second gate electrode G2 as the gate current is larger than The current of the drive current ID is set to time T1. The gate drive circuit 6c changes the control signal CS from the high level VH to the low level VL from the time when the current setting time T1 greater than the drive current ID is supplied to the first gate electrode G1 and the second gate electrode G2. At the time, the drive current ID is continuously supplied to the first gate electrode G1 and the second gate electrode G2.
如圖5所示,閘驅動電路6c,具有npn電晶體Q1、與包含第1pnp電晶體Q2、第2pnp電晶體Q3及第2電阻R1之電流鏡電路60c。As shown in FIG. 5, the gate driving circuit 6c includes an npn transistor Q1 and a current mirror circuit 60c including a first pnp transistor Q2, a second pnp transistor Q3, and a second resistor R1.
npn電晶體Q1中,射極端子連接二極體橋式電路3之負端子34而接地,對基極端子輸入控制信號CS。npn電晶體Q1之基極端子,宜經由電阻R63連接端子7。簡要而言,閘驅動電路6c,宜包含電阻R63。包含電阻R63,藉此,可抑制控制信號CS之雜訊分量等,故可使npn電晶體Q1之動作穩定。In the npn transistor Q1, the emitter terminal is connected to the negative terminal 34 of the diode bridge circuit 3 to be grounded, and the control signal CS is input to the base terminal. The base terminal of the npn transistor Q1 is preferably connected to the terminal 7 via a resistor R63. Briefly, the gate drive circuit 6c preferably includes a resistor R63. The resistor R63 is included, whereby the noise component of the control signal CS and the like can be suppressed, so that the operation of the npn transistor Q1 can be stabilized.
第1pnp電晶體Q2中,射極端子連接電源電路4之高電位側之輸出端41,連接基極端子與集極端子之間。In the first pnp transistor Q2, the emitter terminal is connected to the output terminal 41 on the high potential side of the power supply circuit 4, and is connected between the base terminal and the collector terminal.
第2pnp電晶體Q3中,射極端子連接電源電路4之高電位側之輸出端41,集極端子,經由第1二極體D1連接第1閘極電極G1,且經由第2二極體D2連接第2閘極電極G2,基極端子,連接第1pnp電晶體Q2之基極端子。In the second pnp transistor Q3, the emitter terminal is connected to the output terminal 41 on the high potential side of the power supply circuit 4, and the collector terminal is connected to the first gate electrode G1 via the first diode D1 and via the second diode D2. The second gate electrode G2 is connected to the base terminal, and the base terminal of the first pnp transistor Q2 is connected.
第2電阻R1,連接npn電晶體Q1之集極端子與第1pnp電晶體Q2之集極端子之間。閘驅動電路6c,包含並聯連接第2電阻R1之兩端間之電容器C1。藉此,設定時間T1,由第2電阻R1與電容器C1之並聯電路之時間常數決定。The second resistor R1 is connected between the collector terminal of the npn transistor Q1 and the collector terminal of the first pnp transistor Q2. The gate drive circuit 6c includes a capacitor C1 connected in parallel between both ends of the second resistor R1. Thereby, the set time T1 is determined by the time constant of the parallel circuit of the second resistor R1 and the capacitor C1.
電流鏡電路60c,係使與於第2電阻R1流動之電流相等之電流,朝第2pnp電晶體Q3流動之電路。又,電流鏡電路60c中,第2pnp電晶體Q3構成輸出電晶體。The current mirror circuit 60c is a circuit that flows a current equal to the current flowing through the second resistor R1 toward the second pnp transistor Q3. Further, in the current mirror circuit 60c, the second pnp transistor Q3 constitutes an output transistor.
以下說明關於負載控制裝置1c之閘驅動電路6c之動作。The operation of the gate drive circuit 6c of the load control device 1c will be described below.
在此,首先說明關於本實施形態之基本構成之負載控制裝置1e(參照圖11)。基本構成之負載控制裝置1e中,閘驅動電路6e不包含電容器C1。此基本構成之負載控制裝置1e中,電流鏡電路60c,構成恆定電流電路(亦稱「恆定電流源」。),分別對第1閘極電極G1及第2閘極電極G2輸出一定之閘極電流。Here, first, a load control device 1e (see FIG. 11) having a basic configuration of the present embodiment will be described. In the load control device 1e of the basic configuration, the gate drive circuit 6e does not include the capacitor C1. In the load control device 1e of the basic configuration, the current mirror circuit 60c constitutes a constant current circuit (also referred to as a "constant current source"), and outputs a certain gate to the first gate electrode G1 and the second gate electrode G2, respectively. Current.
根據圖7A、7B所示之等價電路,說明關於此基本構成之負載控制裝置1e之雙方向開關元件2之動作。又,圖7A、7B,係第1期間(交流電源8之極性,為電流沿圖2之箭頭B1所示之方向流動之極性之期間)之動作例。圖7A、7B中,「+V」,係第1主端子21(參照圖5)之電位(>0),「0V」,係第2主端子22(參照圖5)之電位。圖7A、7B中,以恆定電流源之圖記號表示電流鏡電路60c。且圖7A、7B中,以連接包含第1閘極電極G1及第1源極電極S1之第1電晶體Tr1,與包含第2閘極電極G2及第2源極電極S2之電晶體Tr2,之汲極電極彼此之電路,表示雙方向開關元件2。The operation of the bidirectional switching element 2 of the load control device 1e of this basic configuration will be described based on the equivalent circuits shown in Figs. 7A and 7B. 7A and 7B are operation examples of the first period (the polarity of the AC power source 8 and the period in which the current flows in the direction indicated by the arrow B1 in Fig. 2). In FIGS. 7A and 7B, "+V" is the potential (>0) of the first main terminal 21 (see FIG. 5), and "0V" is the potential of the second main terminal 22 (see FIG. 5). In Figs. 7A and 7B, the current mirror circuit 60c is indicated by a symbol of a constant current source. 7A and 7B, the first transistor Tr1 including the first gate electrode G1 and the first source electrode S1 and the transistor Tr2 including the second gate electrode G2 and the second source electrode S2 are connected. The circuit of each of the drain electrodes represents the bidirectional switching element 2.
圖7A,係緊接在控制信號CS自低位準VL朝高位準VH變化後,基本構成之負載控制裝置1e之重要部位之等價電路。基本構成之負載控制裝置1e中,自閘驅動電路6e之恆定電流源60c對雙方向開關元件2開始供給閘極電流後,閘極電流即通過第2二極體D2朝低電位側之第2電晶體Tr2之閘極電極G2流動,第2電晶體Tr2導通。另一方面,第2電晶體Tr2導通前,連接第1電晶體Tr1之閘極電極G1之第1二極體D1逆偏壓,故閘極電流不流往第1電晶體Tr1。Fig. 7A is an equivalent circuit of an important portion of the load control device 1e basically constituted after the control signal CS changes from the low level VL to the high level VH. In the load control device 1e of the basic configuration, after the constant current source 60c of the gate drive circuit 6e starts supplying the gate current to the bidirectional switching element 2, the gate current passes through the second diode D2 toward the second side of the low potential side. The gate electrode G2 of the transistor Tr2 flows, and the second transistor Tr2 is turned on. On the other hand, before the second transistor Tr2 is turned on, the first diode D1 connected to the gate electrode G1 of the first transistor Tr1 is reversely biased, so that the gate current does not flow to the first transistor Tr1.
圖7B,係緊接在第2電晶體Tr2導通後之重要部位之等價電路。基本構成之負載控制裝置1e中,第2電晶體Tr2導通後,第1二極體D1即順偏壓,高電位側之第1電晶體Tr1亦導通,雙方向開關元件2導通。Fig. 7B is an equivalent circuit immediately after an important portion of the second transistor Tr2 is turned on. In the load control device 1e of the basic configuration, after the second transistor Tr2 is turned on, the first diode D1 is biased, the first transistor Tr1 on the high potential side is also turned on, and the bidirectional switching element 2 is turned on.
亦即,基本構成之負載控制裝置1e中,閘驅動電路6e,在控制信號CS為高位準VH時,自電源電路4對第1閘極電極G1及第2閘極電極G2供給既定之驅動電流。又,基本構成之負載控制裝置1e,在控制信號CS為高位準VH之期間內,輸出一定之驅動電流ID。In other words, in the load control device 1e having the basic configuration, the gate drive circuit 6e supplies a predetermined drive current to the first gate electrode G1 and the second gate electrode G2 from the power supply circuit 4 when the control signal CS is at the high level VH. . Further, the load control device 1e having a basic configuration outputs a constant drive current ID while the control signal CS is at the high level VH.
相對於此,本實施形態之負載控制裝置1c中,控制信號CS自低位準VL朝高位準VH變化時,對第1閘極電極G1及第2閘極電極G2恰供給作為閘極電流大於驅動電流ID之電流設定時間T1。亦即,本實施形態之負載控制裝置1c中,電容器C1連接第2電阻R1之兩端間。因此,閘驅動電路6c,在使電容器C1充電之期間,對第1及第2閘極電極G1、G2,供給大於電容器C1充電後之電流。On the other hand, in the load control device 1c of the present embodiment, when the control signal CS changes from the low level VL to the high level VH, the first gate electrode G1 and the second gate electrode G2 are supplied as the gate current is larger than the drive. The current of the current ID sets the time T1. That is, in the load control device 1c of the present embodiment, the capacitor C1 is connected between both ends of the second resistor R1. Therefore, the gate drive circuit 6c supplies a current larger than the charge of the capacitor C1 to the first and second gate electrodes G1 and G2 while the capacitor C1 is being charged.
藉此,負載控制裝置1c中,至雙方向開關元件2導通止,增加過渡狀態下之電流,使雙方向開關元件2更快地確實導通,其後,保持雙方向開關元件2在穩定狀態下之電流於一定,藉此,可低消耗電流化。過渡狀態之期間,通常,約為數ns~數μs。藉此,負載控制裝置1c中,若控制信號CS之高位準VH之期間較過渡狀態之期間充分地夠長,即可實現低消耗電流化。因此,設定時間T1,例如,設定在過渡狀態之期間之約2~10倍之範圍內即可。又,本實施形態中,設定時間T1,可依第2電阻R1與電容器C1之並聯電路之時間常數決定。Thereby, in the load control device 1c, the bidirectional switching element 2 is turned on, the current in the transient state is increased, and the bidirectional switching element 2 is surely turned on more quickly, and thereafter, the bidirectional switching element 2 is kept in a stable state. The current is constant, whereby current consumption can be reduced. The period of the transition state is usually about several ns to several μs. As a result, in the load control device 1c, when the period of the high level VH of the control signal CS is sufficiently longer than the period of the transient state, the current consumption can be reduced. Therefore, the set time T1 may be set, for example, within a range of about 2 to 10 times the period of the transition state. Further, in the present embodiment, the set time T1 can be determined by the time constant of the parallel circuit of the second resistor R1 and the capacitor C1.
亦即,如圖5所示,本實施形態之負載控制裝置1c中,閘驅動電路6c,由開關電路63c、第1並聯電路64、與第2並聯電路65構成。That is, as shown in Fig. 5, in the load control device 1c of the present embodiment, the gate drive circuit 6c is composed of a switch circuit 63c, a first parallel circuit 64, and a second parallel circuit 65.
本實施形態之開關電路63c,包含連接電源電路4之高電位側之輸出端41之輸入部66c,及輸出部67c,控制信號CS為高位準VH時,將來自輸入部66c之電力對輸出部67c供給。The switch circuit 63c of the present embodiment includes an input unit 66c that connects the output terminal 41 on the high potential side of the power supply circuit 4, and an output unit 67c. When the control signal CS is at the high level VH, the power from the input unit 66c is output to the output unit. 67c supply.
一例中,開關電路63c,由npn電晶體Q1、包含第1pnp電晶體Q2、第2pnp電晶體Q3及第2電阻R1之電流鏡電路60c、與電容器C1構成。在輸入部66c與輸出部67c之間,夾設電流鏡電路60c。例如開關電路63c中,輸入npn電晶體Q1之控制信號CS為高位準VH時,npn電晶體Q1為導通,將來自輸入部66c之電力對輸出部67c供給。In one example, the switch circuit 63c includes an npn transistor Q1, a current mirror circuit 60c including a first pnp transistor Q2, a second pnp transistor Q3, and a second resistor R1, and a capacitor C1. A current mirror circuit 60c is interposed between the input unit 66c and the output unit 67c. For example, when the control signal CS input to the npn transistor Q1 is at the high level VH in the switch circuit 63c, the npn transistor Q1 is turned on, and the power from the input unit 66c is supplied to the output unit 67c.
本實施形態之第1並聯電路64,夾設在開關電路63c之輸出部67c與第1閘極電極G1之間。第1並聯電路64,在控制信號CS為高位準VH時,於第1閘極電極G1與第1源極電極S1之間施加驅動電壓。The first parallel circuit 64 of the present embodiment is interposed between the output portion 67c of the switch circuit 63c and the first gate electrode G1. When the control signal CS is at the high level VH, the first parallel circuit 64 applies a driving voltage between the first gate electrode G1 and the first source electrode S1.
本實施形態之第2並聯電路65,夾設在開關電路63c之輸出部67c與第2閘極電極G2之間。第2並聯電路65,在控制信號CS為高位準VH時,於第2閘極電極G2與第2源極電極S2之間施加驅動電壓。The second parallel circuit 65 of the present embodiment is interposed between the output portion 67c of the switch circuit 63c and the second gate electrode G2. When the control signal CS is at the high level VH, the second parallel circuit 65 applies a driving voltage between the second gate electrode G2 and the second source electrode S2.
同樣地,圖11所示之基本構成之負載控制裝置1e中,閘驅動電路6e,由開關電路63e、第1並聯電路64、與第2並聯電路65構成。Similarly, in the load control device 1e having the basic configuration shown in FIG. 11, the gate drive circuit 6e is composed of a switch circuit 63e, a first parallel circuit 64, and a second parallel circuit 65.
開關電路63e,由npn電晶體Q1、與包含第1pnp電晶體Q2、第2pnp電晶體Q3及第2電阻R1之電流鏡電路60c構成。例如開關電路63e,在輸入npn電晶體Q1之控制信號CS為高位準VH時,npn電晶體Q1為導通,將來自輸入部66e之電力對輸出部67e供給。The switch circuit 63e is composed of an npn transistor Q1 and a current mirror circuit 60c including a first pnp transistor Q2, a second pnp transistor Q3, and a second resistor R1. For example, when the control signal CS input to the npn transistor Q1 is at the high level VH, the switching circuit 63e turns on the npn transistor Q1, and supplies the power from the input unit 66e to the output unit 67e.
圖8,顯示本實施形態之負載控制裝置1c中之變形例之閘驅動電路6ca。此閘驅動電路6ca中,不設置閘驅動電路6c之電容器C1,代之以包含第3電阻R2、與npn電晶體(第2npn電晶體)Q8,此點與閘驅動電路6c相異。第3電阻R2中,第1端,連接第1pnp電晶體Q2之集極端子與第2電阻R1之連接點,第2端,連接npn電晶體Q8之集極端子。npn電晶體Q8中,射極端子,連接二極體橋式電路3之負端子34,基極端子,連接在輸入控制信號CS(以下,亦稱「第1控制信號CS」。)之端子7之外另外設置之端子7a。端子7a,輸入用來使npn電晶體Q8導通、切斷之第2控制信號CS2。第2控制信號CS2,係自低位準Vla朝高位準VHa上升之時機,與第1控制信號CS之上升之時機同步,恰維持高位準VHa設定時間T2期間,再朝低位準VLa下降之信號。輸入端子7a之第2控制信號CS2,宜例如由控制電路100產生輸出。Fig. 8 shows a gate drive circuit 6ca according to a modification of the load control device 1c of the present embodiment. In the gate drive circuit 6ca, the capacitor C1 of the gate drive circuit 6c is not provided, and the third resistor R2 and the npn transistor (second npn transistor) Q8 are included, which is different from the gate drive circuit 6c. In the third resistor R2, the first end is connected to the junction of the collector terminal of the first pnp transistor Q2 and the second resistor R1, and the second terminal is connected to the collector terminal of the npn transistor Q8. In the npn transistor Q8, the emitter terminal is connected to the negative terminal 34 of the diode bridge circuit 3, and the base terminal is connected to the terminal 7 of the input control signal CS (hereinafter also referred to as "the first control signal CS"). Terminal 7a is additionally provided. The terminal 7a receives a second control signal CS2 for turning on and off the npn transistor Q8. The second control signal CS2 is a signal that rises from the low level VLa toward the high level VHa, and is synchronized with the timing of the rise of the first control signal CS, and is maintained at a low level VHa for a period T2 and then at a lower level VLa. The second control signal CS2 of the input terminal 7a is preferably outputted by the control circuit 100, for example.
圖8之構成中,大於電流不流往第3電阻R2時之驅動電流ID之電流,恰可流動並聯連接第2電阻R1與第3電阻R2之設定時間T2。藉此,變形例之閘驅動電路6ca中,至雙方向開關元件2導通止,增加過渡狀態下之電流,使雙方向開關元件2更快地確實導通,其後,保持雙方向開關元件2在穩定狀態下之電流於一定,藉此,可低消耗電流化。In the configuration of Fig. 8, the current of the drive current ID when the current does not flow to the third resistor R2 is equal to the set time T2 of the second resistor R1 and the third resistor R2. Thereby, in the gate drive circuit 6ca of the modified example, the bidirectional switching element 2 is turned on, and the current in the transient state is increased, so that the bidirectional switching element 2 is surely turned on more quickly, and thereafter, the bidirectional switching element 2 is kept at The current in the steady state is constant, whereby the current consumption can be reduced.
本實施形態之負載控制裝置1c中,包含閘驅動電路6c,藉此,設定時間T1,依第2電阻R1與電容器C1之並聯電路之時間常數決定,故相較於採用變形例之閘驅動電路6ca時,可簡化電路構成。In the load control device 1c of the present embodiment, the gate drive circuit 6c is included, whereby the set time T1 is determined by the time constant of the parallel circuit of the second resistor R1 and the capacitor C1, so that the gate drive circuit is modified as compared with the modified example. At 6ca, the circuit configuration can be simplified.
本實施形態及變形例之負載控制裝置1c、基本構成之負載控制裝置1e中,亦可不包含位準轉換電路5a,代之以例如,實施形態1之負載控制裝置1a之變形例之負載控制裝置1b(參照圖4)中之位準轉換電路5b。The load control device 1c according to the present embodiment and the modified example and the load control device 1e having the basic configuration may not include the level conversion circuit 5a, and may be replaced with, for example, the load control device according to the modification of the load control device 1a of the first embodiment. The level conversion circuit 5b in 1b (refer to FIG. 4).
如以上說明,本實施形態及變形例之負載控制裝置1c、基本構成之負載控制裝置1e中,閘驅動電路(6c;6ca;6e),自電源電路4對雙方向開關元件2之第1閘極電極G1及第2閘極電極G2供給用來使雙方向開關元件2導通之既定之驅動電流ID。閘驅動電路(6c;6ca;6e),在控制信號CS為高位準VH時,自電源電路4對第1閘極電極G1及第2閘極電極G2供給驅動電流ID。As described above, in the load control device 1c of the present embodiment and the modification, and the load control device 1e having the basic configuration, the gate drive circuit (6c; 6ca; 6e), the first gate of the bidirectional switching element 2 from the power supply circuit 4 The electrode electrode G1 and the second gate electrode G2 supply a predetermined drive current ID for turning on the bidirectional switching element 2. The gate drive circuit (6c; 6ca; 6e) supplies the drive current ID to the first gate electrode G1 and the second gate electrode G2 from the power supply circuit 4 when the control signal CS is at the high level VH.
又,本實施形態及變形例之負載控制裝置1c中,如圖6所示,閘驅動電路(6c;6ca),在控制信號CS自低位準VL朝高位準VH變化時,恰對第1閘極電極G1及第2閘極電極G2供給大於驅動電流ID之電流設定時間(T1;T2)。Further, in the load control device 1c according to the present embodiment and the modification, as shown in FIG. 6, the gate drive circuit (6c; 6ca) is just opposite to the first gate when the control signal CS changes from the low level VL to the high level VH. The electrode electrode G1 and the second gate electrode G2 supply a current setting time (T1; T2) larger than the drive current ID.
藉此,至雙方向開關元件2導通止,增加過渡狀態下之電流,使雙方向開關元件2可更快地確實導通。且其後,保持雙方向開關元件2在穩定狀態下之電流於一定,藉此,可低消耗電流化。Thereby, the bidirectional switching element 2 is turned on, and the current in the transient state is increased, so that the bidirectional switching element 2 can be surely turned on more quickly. Then, the current of the bidirectional switching element 2 in the steady state is kept constant, whereby current consumption can be reduced.
如上述說明,本實施形態之負載控制裝置1c中,如圖5所示,閘驅動電路6c,具有npn電晶體Q1、與包含第1pnp電晶體Q2、第2pnp電晶體Q3及第2電阻R1之電流鏡電路60c。npn電晶體Q1中,射極端子連接負端子34而接地,對基極端子輸入控制信號CS。第1pnp電晶體Q2中,射極端子連接電源電路4之高電位側之輸出端41,連接基極端子與集極端子之間。第2pnp電晶體Q3中,射極端子連接電源電路4之高電位側之輸出端41,集極端子,經由第1二極體D1連接第1閘極電極G1,且經由第2二極體D2連接第2閘極電極G2,基極端子,連接第1pnp電晶體Q2之基極端子。第2電阻R1,連接npn電晶體Q1之集極端子與第1pnp電晶體Q2之集極端子之間。電容器C1並聯連接第2電阻R1之兩端間。設定時間T1,依第2電阻R1與電容器C1之並聯電路之時間常數決定。As described above, in the load control device 1c of the present embodiment, as shown in FIG. 5, the gate drive circuit 6c includes the npn transistor Q1 and the first pnp transistor Q2, the second pnp transistor Q3, and the second resistor R1. Current mirror circuit 60c. In the npn transistor Q1, the emitter terminal is connected to the negative terminal 34 to be grounded, and the control signal CS is input to the base terminal. In the first pnp transistor Q2, the emitter terminal is connected to the output terminal 41 on the high potential side of the power supply circuit 4, and is connected between the base terminal and the collector terminal. In the second pnp transistor Q3, the emitter terminal is connected to the output terminal 41 on the high potential side of the power supply circuit 4, and the collector terminal is connected to the first gate electrode G1 via the first diode D1 and via the second diode D2. The second gate electrode G2 is connected to the base terminal, and the base terminal of the first pnp transistor Q2 is connected. The second resistor R1 is connected between the collector terminal of the npn transistor Q1 and the collector terminal of the first pnp transistor Q2. The capacitor C1 is connected in parallel between the two ends of the second resistor R1. The set time T1 is determined by the time constant of the parallel circuit of the second resistor R1 and the capacitor C1.
藉此,可簡化電路構成。Thereby, the circuit configuration can be simplified.
(實施形態3) 於以下,根據圖9說明關於本實施形態之負載控制裝置1d。又,就與實施形態2之負載控制裝置1c相同之構成要素,賦予同一符號,適當省略說明。(Embodiment 3) Hereinafter, a load control device 1d according to this embodiment will be described with reference to Fig. 9 . The same components as those of the load control device 1c of the second embodiment are denoted by the same reference numerals, and description thereof will be omitted as appropriate.
本實施形態之負載控制裝置1d,不包含實施形態2之負載控制裝置1c之閘驅動電路6c,代之以閘驅動電路6d,此點相異。The load control device 1d of the present embodiment does not include the gate drive circuit 6c of the load control device 1c of the second embodiment, and the gate drive circuit 6d is used instead.
閘驅動電路6d,包含不設置第2pnp電晶體Q3,代之以第2pnp電晶體Q31、第3pnp電晶體Q32之電流鏡電路60d。電流鏡電路60d中,連接第1pnp電晶體Q21之基極端子與集極端子。電流鏡電路60d中,使第2pnp電晶體Q31之基極端子及第3pnp電晶體Q32之基極端子,連接第1pnp電晶體Q21之基極端子。閘驅動電路6d中,使第1~第3pnp電晶體Q21、Q31、Q32之射極端子,連接電源電路4之高電位側之輸出端41。閘驅動電路6d中,第2pnp電晶體Q31之集極端子連接第2二極體D2之陽極,第3pnp電晶體Q32之集極端子連接第1二極體D1之陽極。The gate driving circuit 6d includes a current mirror circuit 60d in which the second pnp transistor Q3 is not provided, and the second pnp transistor Q31 and the third pnp transistor Q32 are replaced. In the current mirror circuit 60d, the base terminal and the collector terminal of the first pnp transistor Q21 are connected. In the current mirror circuit 60d, the base terminal of the second pnp transistor Q31 and the base terminal of the third pnp transistor Q32 are connected to the base terminal of the first pnp transistor Q21. In the gate drive circuit 6d, the emitter terminals of the first to third pnp transistors Q21, Q31, and Q32 are connected to the output terminal 41 on the high potential side of the power supply circuit 4. In the gate driving circuit 6d, the collector terminal of the second pnp transistor Q31 is connected to the anode of the second diode D2, and the collector terminal of the third pnp transistor Q32 is connected to the anode of the first diode D1.
設計閘驅動電路6d,俾第1pnp電晶體Q21、第2pnp電晶體Q31及第3pnp電晶體Q32之相互特性相同。藉此,閘驅動電路6d,可使大小與流往第1pnp電晶體Q21之電流相等之電流,分別流往第2pnp電晶體Q31、第3pnp電晶體Q32。藉此,閘驅動電路6d中,第2pnp電晶體Q31及第3pnp電晶體Q32,分別構成電流源。亦即,閘驅動電路6d,包含分別以1對1方式對應第1閘極電極G1、第2閘極電極G2之2個電流源。The gate drive circuit 6d is designed to have the same mutual characteristics of the first 1pnp transistor Q21, the second pnp transistor Q31, and the third pnp transistor Q32. Thereby, the gate drive circuit 6d can flow a current equal in magnitude to the current flowing through the first pnp transistor Q21 to the second pnp transistor Q31 and the third pnp transistor Q32. Thereby, in the gate driving circuit 6d, the second pnp transistor Q31 and the third pnp transistor Q32 constitute a current source. That is, the gate drive circuit 6d includes two current sources that correspond to the first gate electrode G1 and the second gate electrode G2 in a one-to-one manner.
亦即,如圖9所示,本實施形態之負載控制裝置1d中,閘驅動電路6d,由開關電路63d、第1並聯電路64、與第2並聯電路65構成。That is, as shown in Fig. 9, in the load control device 1d of the present embodiment, the gate drive circuit 6d is composed of a switch circuit 63d, a first parallel circuit 64, and a second parallel circuit 65.
本實施形態之開關電路63d,包含連接電源電路4之高電位側之輸出端41之輸入部66d,及輸出部67d,控制信號CS為高位準VH時,將來自輸入部66d之電力對輸出部67d供給。The switch circuit 63d of the present embodiment includes an input unit 66d that connects the output terminal 41 on the high potential side of the power supply circuit 4, and an output unit 67d. When the control signal CS is at the high level VH, the power from the input unit 66d is output to the output unit. 67d supply.
本實施形態之開關電路63d之輸出部67d,包含第1輸出端671d與第2輸出端672d。開關電路63d,在控制信號CS為高位準VH時,將來自輸入部66d之電力對第1輸出端671d及第2輸出端672d供給。The output portion 67d of the switch circuit 63d of the present embodiment includes a first output terminal 671d and a second output terminal 672d. The switch circuit 63d supplies the power from the input unit 66d to the first output terminal 671d and the second output terminal 672d when the control signal CS is at the high level VH.
一例中,開關電路63d,由npn電晶體Q1、與包含第1pnp電晶體Q21、第2pnp電晶體Q31、第3pnp電晶體Q32及第2電阻R11之電流鏡電路60d構成。在輸入端66d與輸出端67d之間,夾設電流鏡電路60d。例如開關電路63d中,輸入npn電晶體Q1之控制信號CS為高位準VH時,npn電晶體Q1為導通,將來自輸入部66d之電力對輸出部67d(第1輸出端671d及第2輸出端672d)供給。In one example, the switch circuit 63d is composed of an npn transistor Q1 and a current mirror circuit 60d including a first pnp transistor Q21, a second pnp transistor Q31, a third pnp transistor Q32, and a second resistor R11. A current mirror circuit 60d is interposed between the input terminal 66d and the output terminal 67d. For example, in the switch circuit 63d, when the control signal CS input to the npn transistor Q1 is at the high level VH, the npn transistor Q1 is turned on, and the power from the input unit 66d is applied to the output unit 67d (the first output terminal 671d and the second output terminal). 672d) Supply.
本實施形態之第1並聯電路64,夾設在開關電路63d之第1輸出端671d(輸出部67d)與第1閘極電極G1之間。第1並聯電路64,在控制信號CS為高位準VH時,於第1閘極電極G1與第1源極電極S1之間施加驅動電壓(第1驅動電壓)。The first parallel circuit 64 of the present embodiment is interposed between the first output end 671d (output portion 67d) of the switch circuit 63d and the first gate electrode G1. When the control signal CS is at the high level VH, the first parallel circuit 64 applies a driving voltage (first driving voltage) between the first gate electrode G1 and the first source electrode S1.
本實施形態之第2並聯電路65,夾設在開關電路63d之第2輸出端672d(輸出部67d)與第2閘極電極G2之間。第2並聯電路65,在控制信號CS為高位準VH時,於第2閘極電極G2與第2源極電極S2之間施加驅動電壓(第2驅動電壓)。The second parallel circuit 65 of the present embodiment is interposed between the second output terminal 672d (output portion 67d) of the switch circuit 63d and the second gate electrode G2. When the control signal CS is at the high level VH, the second parallel circuit 65 applies a driving voltage (second driving voltage) between the second gate electrode G2 and the second source electrode S2.
又,雙方向開關元件2之特性,有時會因例如包含第1閘極電極G1及第1源極電極S1之第1電晶體Tr1(參照圖7A),與包含第2閘極電極G2及第2源極電極S2之第2電晶體Tr2(參照圖7A),之相互之電晶體特性之差異等,產生差異。Further, the characteristics of the bidirectional switching element 2 may include, for example, the first transistor Tr1 including the first gate electrode G1 and the first source electrode S1 (see FIG. 7A) and the second gate electrode G2. The second transistor Tr2 of the second source electrode S2 (see FIG. 7A) has a difference in mutual crystal characteristics and the like.
相對於此,負載控制裝置1d中,閘驅動電路6d,包含分別以1對1方式對應第1閘極電極G1、第2閘極電極G2之2個電流源,故可消除起因於雙方向開關元件2之特性之差異之驅動性能之差異。On the other hand, in the load control device 1d, the gate drive circuit 6d includes two current sources that correspond to the first gate electrode G1 and the second gate electrode G2 in a one-to-one manner, so that the two-way switch can be eliminated. The difference in driving performance of the difference in the characteristics of the component 2.
本實施形態之負載控制裝置1d中,亦可不包含位準轉換電路5a,代之以例如,實施形態1之負載控制裝置1a之變形例之負載控制裝置1b(參照圖4)中之位準轉換電路5b。The load control device 1d of the present embodiment may not include the level conversion circuit 5a, and may be replaced with, for example, the level conversion in the load control device 1b (see FIG. 4) of the modification of the load control device 1a of the first embodiment. Circuit 5b.
如以上說明,本實施形態之負載控制裝置1d中,如圖9所示,閘驅動電路6d,包含分別以1對1方式對應第1閘極電極G1、第2閘極電極G2之2個電流源。As described above, in the load control device 1d of the present embodiment, as shown in FIG. 9, the gate drive circuit 6d includes two currents corresponding to the first gate electrode G1 and the second gate electrode G2 in a one-to-one manner. source.
具體而言,閘驅動電路6d,具有npn電晶體Q1、與包含第1pnp電晶體Q21、第2pnp電晶體Q31、第3pnp電晶體Q32及第2電阻R11之電流鏡電路60d。npn電晶體Q1中,射極端子連接負端子34而接地,對基極端子輸入控制信號CS。第1pnp電晶體Q21中,射極端子連接電源電路4之高電位側之輸出端41,連接基極端子與集極端子之間。第3pnp電晶體Q32中,射極端子連接電源電路4之高電位側之輸出端41,集極端子,經由第1二極體D1連接第1閘極電極G1,基極端子,連接第1pnp電晶體Q21之基極端子。第2pnp電晶體Q31中,射極端子連接電源電路4之高電位側之輸出端41,集極端子,經由第2二極體D2連接第2閘極電極G2,基極端子,連接第1pnp電晶體Q21之基極端子。第2電阻R11,連接npn電晶體Q1之集極端子與第1pnp電晶體Q21之集極端子之間。Specifically, the gate driving circuit 6d includes an npn transistor Q1 and a current mirror circuit 60d including a first pnp transistor Q21, a second pnp transistor Q31, a third pnp transistor Q32, and a second resistor R11. In the npn transistor Q1, the emitter terminal is connected to the negative terminal 34 to be grounded, and the control signal CS is input to the base terminal. In the first pnp transistor Q21, the emitter terminal is connected to the output terminal 41 on the high potential side of the power supply circuit 4, and is connected between the base terminal and the collector terminal. In the third pnp transistor Q32, the emitter terminal is connected to the output terminal 41 on the high potential side of the power supply circuit 4, and the terminal is connected to the first gate electrode G1 via the first diode D1, and the base terminal is connected to the first pnp. The base terminal of crystal Q21. In the second pnp transistor Q31, the emitter terminal is connected to the output terminal 41 on the high potential side of the power supply circuit 4, and the terminal is connected. The second gate electrode G2 is connected via the second diode D2, and the base terminal is connected to the first pnp. The base terminal of crystal Q21. The second resistor R11 is connected between the collector terminal of the npn transistor Q1 and the collector terminal of the first pnp transistor Q21.
藉此,可消除起因於雙方向開關元件2之第1電晶體Tr1與第2電晶體Tr2之間之特性之差異之驅動性能之差異。Thereby, the difference in driving performance due to the difference in characteristics between the first transistor Tr1 and the second transistor Tr2 of the bidirectional switching element 2 can be eliminated.
以上,雖已根據實施形態1~3等說明本發明之構成,但本發明,不限於實施形態1~3等之構成,例如,亦可適當組合實施形態1~3等之部分構成。且本發明,只要在不逸脫其技術構想之範圍內,可適當變更構成。In the above, the configuration of the present invention is described in the first to third embodiments, and the present invention is not limited to the configurations of the first to third embodiments. For example, the configuration of the first to third embodiments may be combined as appropriate. Further, the present invention can be appropriately modified as long as it does not escape the technical concept.
C4‧‧‧平滑電容器
CS‧‧‧控制信號
D1‧‧‧第1二極體
D2‧‧‧第2二極體
G1‧‧‧第1閘極電極
G2‧‧‧第2閘極電極
Imp1‧‧‧阻抗
Q4 npn‧‧‧電晶體
Q5‧‧‧雙極性電晶體
R4‧‧‧電阻
R51‧‧‧電阻
R61、R62‧‧‧電阻
S1‧‧‧第1源極電極
S2‧‧‧第2源極電極
VDD‧‧‧輸出電壓
VH‧‧‧高位準
VL‧‧‧低位準
ZD4‧‧‧齊納二極體
1a‧‧‧負載控制裝置
2‧‧‧雙方向開關元件
3‧‧‧二極體橋式電路
4‧‧‧電源電路
5a‧‧‧位準轉換電路
6a‧‧‧閘驅動電路
7‧‧‧端子
8‧‧‧交流電源
9‧‧‧負載
21‧‧‧第1主端子
22‧‧‧第2主端子
31‧‧‧第1交流輸入端子
32‧‧‧第2交流輸入端子
33‧‧‧正端子
34‧‧‧負端子
41‧‧‧輸出端
61‧‧‧MOSFET
62‧‧‧反相器
63a‧‧‧開關電路
64‧‧‧第1並聯電路
65‧‧‧第2並聯電路
66a‧‧‧輸入部
67a‧‧‧輸出部
100‧‧‧控制電路
200‧‧‧設定部
300‧‧‧連接端子C4‧‧‧Smoothing capacitor
CS‧‧‧Control signal
D1‧‧‧1st dipole
D2‧‧‧2nd Diode
G1‧‧‧1st gate electrode
G2‧‧‧2nd gate electrode
Imp1‧‧‧ Impedance
Q4 npn‧‧‧O crystal
Q5‧‧‧Bipolar transistor
R4‧‧‧ resistance
R51‧‧‧ resistance
R61, R62‧‧‧ resistance
S1‧‧‧1st source electrode
S2‧‧‧2nd source electrode
VDD‧‧‧ output voltage
VH‧‧‧ high standard
VL‧‧‧low standard
ZD4‧‧‧Zina diode
1a‧‧‧Load control device
2‧‧‧Double-direction switching elements
3‧‧‧Diode Bridge Circuit
4‧‧‧Power circuit
5a‧‧‧bit conversion circuit
6a‧‧‧ brake drive circuit
7‧‧‧ Terminal
8‧‧‧AC power supply
9‧‧‧load
21‧‧‧1st main terminal
22‧‧‧2nd main terminal
31‧‧‧1st AC input terminal
32‧‧‧2nd AC input terminal
33‧‧‧ positive terminal
34‧‧‧negative terminal
41‧‧‧ Output
61‧‧‧ MOSFET
62‧‧‧Inverter
63a‧‧‧Switch circuit
64‧‧‧1st parallel circuit
65‧‧‧2nd parallel circuit
66a‧‧ Input Department
67a‧‧‧Output Department
100‧‧‧Control circuit
200‧‧‧Setting Department
300‧‧‧Connecting terminal
圖1係實施形態1之負載控制裝置之電路圖。 圖2係實施形態1之負載控制裝置之動作說明圖。 圖3係實施形態1之負載控制裝置之動作說明圖。 圖4係實施形態1之負載控制裝置之變形例之電路圖。 圖5係實施形態2之負載控制裝置之電路圖。 圖6係實施形態2之負載控制裝置之動作說明圖。 圖7中,圖7A、7B係實施形態2之負載控制裝置之示意動作說明圖。 圖8係實施形態2之負載控制裝置之變形例之閘驅動電路之電路圖。 圖9係實施形態3之負載控制裝置之電路圖。 圖10係習知之2線式交流開關之電路圖。 圖11係實施形態2之負載控制裝置之基本構成之電路圖。Fig. 1 is a circuit diagram of a load control device of the first embodiment. Fig. 2 is an explanatory view showing the operation of the load control device of the first embodiment. Fig. 3 is an explanatory view showing the operation of the load control device of the first embodiment. Fig. 4 is a circuit diagram showing a modification of the load control device of the first embodiment. Fig. 5 is a circuit diagram of a load control device of the second embodiment. Fig. 6 is an explanatory view showing the operation of the load control device of the second embodiment. 7A and 7B are schematic operation explanatory views of a load control device according to a second embodiment. Fig. 8 is a circuit diagram of a gate drive circuit according to a modification of the load control device of the second embodiment. Fig. 9 is a circuit diagram of a load control device of the third embodiment. Figure 10 is a circuit diagram of a conventional 2-wire AC switch. Fig. 11 is a circuit diagram showing a basic configuration of a load control device according to a second embodiment.
C4‧‧‧平滑電容器 C4‧‧‧Smoothing capacitor
CS‧‧‧控制信號 CS‧‧‧Control signal
D1‧‧‧第1二極體 D1‧‧‧1st dipole
D2‧‧‧第2二極體 D2‧‧‧2nd Diode
G1‧‧‧第1閘極電極 G1‧‧‧1st gate electrode
G2‧‧‧第2閘極電極 G2‧‧‧2nd gate electrode
Imp1‧‧‧阻抗 Imp1‧‧‧ Impedance
Q4‧‧‧npn電晶體 Q4‧‧‧npn transistor
Q5‧‧‧雙極性電晶體 Q5‧‧‧Bipolar transistor
R4‧‧‧電阻 R4‧‧‧ resistance
R51‧‧‧電阻 R51‧‧‧ resistance
R61、R62‧‧‧電阻 R61, R62‧‧‧ resistance
S1‧‧‧第1源極電極 S1‧‧‧1st source electrode
S2‧‧‧第2源極電極 S2‧‧‧2nd source electrode
VDD‧‧‧輸出電壓 VDD‧‧‧ output voltage
VH‧‧‧高位準 VH‧‧‧ high standard
VL‧‧‧低位準 VL‧‧‧low standard
ZD4‧‧‧齊納二極體 ZD4‧‧‧Zina diode
1a‧‧‧負載控制裝置 1a‧‧‧Load control device
2‧‧‧雙方向開關元件 2‧‧‧Double-direction switching elements
3‧‧‧二極體橋式電路 3‧‧‧Diode Bridge Circuit
4‧‧‧電源電路 4‧‧‧Power circuit
5a‧‧‧位準轉換電路 5a‧‧‧bit conversion circuit
6a‧‧‧閘驅動電路 6a‧‧‧ brake drive circuit
7‧‧‧端子 7‧‧‧ Terminal
8‧‧‧交流電源 8‧‧‧AC power supply
9‧‧‧負載 9‧‧‧load
21‧‧‧第1主端子 21‧‧‧1st main terminal
22‧‧‧第2主端子 22‧‧‧2nd main terminal
31‧‧‧第1交流輸入端子 31‧‧‧1st AC input terminal
32‧‧‧第2交流輸入端子 32‧‧‧2nd AC input terminal
33‧‧‧正端子 33‧‧‧ positive terminal
34‧‧‧負端子 34‧‧‧negative terminal
41‧‧‧輸出端 41‧‧‧ Output
61‧‧‧MOSFET 61‧‧‧ MOSFET
62‧‧‧反相器 62‧‧‧Inverter
63a‧‧‧開關電路 63a‧‧‧Switch circuit
64‧‧‧第1並聯電路 64‧‧‧1st parallel circuit
65‧‧‧第2並聯電路 65‧‧‧2nd parallel circuit
66a‧‧‧輸入部 66a‧‧ Input Department
67a‧‧‧輸出部 67a‧‧‧Output Department
100‧‧‧控制電路 100‧‧‧Control circuit
200‧‧‧設定部 200‧‧‧Setting Department
300‧‧‧連接端子 300‧‧‧Connecting terminal
Claims (7)
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2013113262A JP2014233161A (en) | 2013-05-29 | 2013-05-29 | Load controller |
Publications (1)
Publication Number | Publication Date |
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TW201517469A true TW201517469A (en) | 2015-05-01 |
Family
ID=51988299
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
TW103118199A TW201517469A (en) | 2013-05-29 | 2014-05-26 | Load control device |
Country Status (3)
Country | Link |
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JP (1) | JP2014233161A (en) |
TW (1) | TW201517469A (en) |
WO (1) | WO2014192246A1 (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
TWI645639B (en) * | 2017-11-09 | 2018-12-21 | 海韻電子工業股份有限公司 | Redundant isolating switch control circuit |
TWI741415B (en) * | 2018-11-30 | 2021-10-01 | 日商松下知識產權經營股份有限公司 | Load controller |
Families Citing this family (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP6534102B2 (en) * | 2015-09-04 | 2019-06-26 | パナソニックIpマネジメント株式会社 | Dimmer |
JP6653452B2 (en) | 2016-09-20 | 2020-02-26 | パナソニックIpマネジメント株式会社 | Protection circuit for dimmer and dimmer |
JP7262046B2 (en) * | 2019-05-28 | 2023-04-21 | パナソニックIpマネジメント株式会社 | LOAD CONTROLLER, LOAD CONTROL METHOD AND PROGRAM |
Family Cites Families (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP4311227B2 (en) * | 2004-02-24 | 2009-08-12 | パナソニック電工株式会社 | Power supply switch |
US7619365B2 (en) * | 2006-04-10 | 2009-11-17 | Lutron Electronics Co., Inc. | Load control device having a variable drive circuit |
JP5895170B2 (en) * | 2010-02-23 | 2016-03-30 | パナソニックIpマネジメント株式会社 | 2-wire AC switch |
-
2013
- 2013-05-29 JP JP2013113262A patent/JP2014233161A/en active Pending
-
2014
- 2014-05-19 WO PCT/JP2014/002613 patent/WO2014192246A1/en active Application Filing
- 2014-05-26 TW TW103118199A patent/TW201517469A/en unknown
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
TWI645639B (en) * | 2017-11-09 | 2018-12-21 | 海韻電子工業股份有限公司 | Redundant isolating switch control circuit |
TWI741415B (en) * | 2018-11-30 | 2021-10-01 | 日商松下知識產權經營股份有限公司 | Load controller |
Also Published As
Publication number | Publication date |
---|---|
JP2014233161A (en) | 2014-12-11 |
WO2014192246A1 (en) | 2014-12-04 |
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