CN103326596B - Power Supply Circuit and AC Signal Rectification Method - Google Patents

Abstract

The invention provides a power supply circuit and an alternating current signal rectification method. The power supply circuit is used for converting an Alternating Current (AC) signal into a rectified signal, wherein the AC signal includes a line signal and a neutral signal. The power supply circuit comprises a bridge rectifier circuit and a control circuit. The bridge rectifier circuit comprises a pair of diodes with reverse terminals coupled with each other and a pair of switch elements coupled with each other. The control circuit generates a switch operation signal according to the AC signal to operate the pair of switch elements. The pair of switch elements includes a first switch and a second switch, the first switch is coupled to the line bit signal, the second switch is coupled to the neutral signal, the second switch is turned on when the line bit signal is higher than a default value of the neutral signal, and the first switch is turned on when the neutral signal is higher than the default value of the line bit signal.

Description

Translated fromChinese

电源供应电路及交流讯号整流方法Power Supply Circuit and AC Signal Rectification Method

技术领域technical field

本发明涉及一种电源供应电路及交流讯号整流方法，特别是指一种改善整流效率并节省电力的电源供应电路及交流讯号整流方法。The invention relates to a power supply circuit and an AC signal rectification method, in particular to a power supply circuit and an AC signal rectification method which improve rectification efficiency and save power.

背景技术Background technique

图1显示一种典型的桥式整流电源供应电路100，其中，桥式整流电路11包含一对逆向端互相耦接的二极管与一对顺向端互相耦接的二极管，并接于交流讯号AC之间，以将交流讯号AC转换为整流讯号Vol。这种典型的桥式整流电源供应电路100提供交流讯号AC的全波整流(full-wave rectification)，但由于二极管具有顺向压降(forward voltagedrop)，对许多应用来说，相较于输出电压，此顺向压降不可被忽略，因此造成整流效率的下降。此外，在高频的切换式电源供应电路中，二极管的热消散(heat dissipation)问题，亦会降低整流效率，且造成电路可靠度的问题。FIG. 1 shows a typical bridge rectification power supply circuit 100, wherein the bridge rectification circuit 11 includes a pair of diodes with reverse terminals coupled to each other and a pair of diodes with forward terminals coupled to each other, and connected to the AC signal AC Between, in order to convert the AC signal into a rectified signal Vol. This typical bridge rectification power supply circuit 100 provides full-wave rectification of the AC signal AC, but due to the forward voltage drop of the diode, for many applications, compared with the output voltage , this forward voltage drop cannot be ignored, thus resulting in a drop in rectification efficiency. In addition, in the high-frequency switching power supply circuit, the problem of heat dissipation of the diode will also reduce the rectification efficiency and cause the problem of circuit reliability.

请参阅图2，显示美国专利US7,411,768所揭示的电源供应电路200。如图所示，电源供应电路200将交流讯号AC整流后转换为整流讯号Vo2。相较于前述典型桥式整流电源供应电路100，电源供应电路200虽然可以改善整流效率以及热消散问题；但其利用金属氧化物半导体(metal oxide semiconductor，MOS)元件与肖特基二极管元件的物理特性，无法精确控制开关导通的时间点，仍有整流效率的问题；且这种整流的方式，无法达成省电的模式控制。Please refer to FIG. 2 , which shows a power supply circuit 200 disclosed in US Pat. No. 7,411,768. As shown in the figure, the power supply circuit 200 rectifies the AC signal AC and converts it into a rectified signal Vo2. Compared with the aforementioned typical bridge rectification power supply circuit 100, although the power supply circuit 200 can improve rectification efficiency and heat dissipation; characteristics, it is impossible to precisely control the time point when the switch is turned on, and there is still a problem of rectification efficiency; and this rectification method cannot achieve power-saving mode control.

此外，上述现有技术中，尚包含其它的缺点，例如：温度的变化往往影响其元件的操作；精确度较差；去除噪声能力较弱；无法根据需求调整；无法达成省电模式；其侦测交流讯号的电路的RC值较低，容易造成元件贯穿(shoot through)等等。In addition, the above-mentioned prior art still contains other disadvantages, for example: the change of temperature often affects the operation of its components; the accuracy is poor; the ability to remove noise is weak; The RC value of the circuit for measuring AC signals is low, which is easy to cause component shoot through and so on.

有鉴于此，本发明即针对上述现有技术的不足，提出一种电源供应电路及交流讯号整流方法，可改善整流效率并节省电力。In view of this, the present invention aims at the shortcomings of the above-mentioned prior art, and proposes a power supply circuit and an AC signal rectification method, which can improve rectification efficiency and save power.

发明内容Contents of the invention

本发明目的之一在于克服现有技术的不足与缺陷，提出一种电源供应电路。One of the objectives of the present invention is to overcome the deficiencies and defects of the prior art and provide a power supply circuit.

本发明另一目的在于，提出一种交流讯号整流方法。Another object of the present invention is to provide an AC signal rectification method.

为达上述目的，就其中一观点言，本发明提供了一种电源供应电路，用以将一交流讯号转换为一整流讯号，该交流讯号包括一线位(line)讯号与一中位(neutral)讯号，该电源供应电路包含：一桥式整流电路，包括一对逆向端互相耦接的二极管与一对互相耦接的开关元件，该对二极管与该对开关元件并接于该线位讯号与该中位讯号之间，该桥式整流电路根据至少一开关操作讯号，操作该对开关元件，以转换该交流讯号为该整流讯号；以及一控制电路，根据该交流讯号，产生该开关操作讯号，以操作该对开关元件；其中，该对开关元件包括一第一开关与一第二开关，该第一开关耦接于该线位讯号，且该第二开关耦接于该中位讯号，当该线位讯号高于该中位讯号一第一默认值时，导通该第二开关，当该中位讯号高于该线位讯号一第二默认值时，导通该第一开关。该第一默认值与该第二默认值可以相同或不同。In order to achieve the above purpose, from one point of view, the present invention provides a power supply circuit for converting an AC signal into a rectified signal, the AC signal includes a line signal and a neutral (neutral) signal, the power supply circuit includes: a bridge rectifier circuit, including a pair of diodes with opposite ends coupled to each other and a pair of switching elements coupled to each other, the pair of diodes and the pair of switching elements are connected in parallel between the line signal and Between the neutral signal, the bridge rectifier circuit operates the pair of switch elements according to at least one switch operation signal to convert the AC signal into the rectified signal; and a control circuit generates the switch operation signal according to the AC signal , to operate the pair of switching elements; wherein, the pair of switching elements includes a first switch and a second switch, the first switch is coupled to the line signal, and the second switch is coupled to the neutral signal, When the line signal is higher than a first default value of the neutral signal, the second switch is turned on; when the middle signal is higher than a second default value of the line signal, the first switch is turned on. The first default value and the second default value may be the same or different.

就另一观点，本发明也提供了一种交流讯号整流方法，用以将一交流讯号转换为一整流讯号，该交流讯号包括一线位(line)讯号与一中位(neutral)讯号，该交流讯号整流方法包含：提供一桥式整流电路，其包括一对逆向端互相耦接的二极管与一对互相耦接的开关元件，该对二极管与该对开关元件并接于该线位讯号与该中位讯号之间，其中该对开关元件包括一第一开关与一第二开关，该第一开关耦接于该线位讯号，且该第二开关耦接于该中位讯号；当该线位讯号高于该中位讯号一第一默认值时，导通该第二开关；以及当该中位讯号高于该线位讯号一第二默认值时，导通该第一开关，通过此，将该交流讯号转换为该整流讯号。该第一默认值与该第二默认值可以相同或不同。From another point of view, the present invention also provides an AC signal rectification method for converting an AC signal into a rectified signal. The AC signal includes a line signal and a neutral signal. The AC signal The signal rectification method includes: providing a bridge rectification circuit, which includes a pair of diodes with opposite ends coupled to each other and a pair of switching elements coupled to each other, the pair of diodes and the pair of switching elements are connected in parallel between the line signal and the Between the neutral signal, wherein the pair of switching elements includes a first switch and a second switch, the first switch is coupled to the line signal, and the second switch is coupled to the neutral signal; when the line When the bit signal is higher than the first default value of the neutral signal, the second switch is turned on; and when the middle signal is higher than the line bit signal, a second default value, the first switch is turned on, through , converting the AC signal into the rectified signal. The first default value and the second default value may be the same or different.

在其中一种实施型态中，其中该控制电路宜包括：一第一比较电路，比较相关于该线位讯号的一第一讯号与相关于该中位讯号的一第二讯号，并根据比较结果，产生一第二开关控制讯号以控制该第二开关；以及一第二比较电路，比较该第二讯号与该第一讯号，并根据比较结果，产生一第一开关控制讯号以控制该第一开关。In one of the implementation forms, the control circuit preferably includes: a first comparison circuit, which compares a first signal related to the line bit signal with a second signal related to the median signal, and according to the comparison As a result, a second switch control signal is generated to control the second switch; and a second comparison circuit compares the second signal with the first signal, and generates a first switch control signal to control the first switch according to the comparison result a switch.

上述电源供应电路中，控制电路宜更包括一轻载侦测电路，具有：一第三比较电路，比较一第三参考讯号与该第二讯号，并根据比较结果，产生一第一侦测讯号；一第四比较电路，比较该第三参考讯号与该第一讯号，并根据比较结果，产生一第二侦测讯号；一第一逻辑电路，根据该第一侦测讯号与该第二开关控制讯号，决定该第二开关导通或不导通；以及一第二逻辑电路，根据该第二侦测讯号与该第一开关控制讯号，决定该第一开关导通或不导通。In the above power supply circuit, the control circuit preferably further includes a light load detection circuit, which has: a third comparison circuit, which compares a third reference signal with the second signal, and generates a first detection signal according to the comparison result ; A fourth comparison circuit, which compares the third reference signal with the first signal, and generates a second detection signal according to the comparison result; a first logic circuit, which generates a second detection signal according to the first detection signal and the second switch A control signal determines whether the second switch is turned on or not; and a second logic circuit determines whether the first switch is turned on or not according to the second detection signal and the first switch control signal.

在另一种实施型态中，控制电路宜更包括一去突波电路与一操作电路，其中该去突波电路与该第一比较电路与该第二比较电路耦接，以对该第一比较电路与该第二比较电路的比较结果，进行去突波处理；且该操作电路根据该第一比较电路与该第二比较电路的比较结果，产生该开关操作讯号以操作该第一开关与该第二开关。In another implementation mode, the control circuit preferably further includes a surge removal circuit and an operation circuit, wherein the surge removal circuit is coupled to the first comparison circuit and the second comparison circuit to control the first The comparison result of the comparison circuit and the second comparison circuit is subjected to deglitch processing; and the operation circuit generates the switch operation signal to operate the first switch and the second comparison circuit according to the comparison result of the first comparison circuit and the second comparison circuit. the second switch.

在另一种实施型态中，电源供应电路宜更包含一分压电路，以将该线位讯号与该中位讯号分别转换为该第一讯号与该第二讯号，使得该第一讯号与该第二讯号分别正比于该线位讯号与该中位讯号。In another implementation mode, the power supply circuit preferably further includes a voltage divider circuit to convert the line signal and the neutral signal into the first signal and the second signal respectively, so that the first signal and the The second signal is respectively proportional to the line signal and the median signal.

下面通过具体实施例详加说明，当更容易了解本发明的目的、技术内容、特点及其所达成的功效。The following will be described in detail through specific embodiments, so that it is easier to understand the purpose, technical content, characteristics and effects of the present invention.

附图说明Description of drawings

图1显示一种典型的桥式整流电源供应电路；Figure 1 shows a typical bridge rectifier power supply circuit;

图2显示美国专利US7,411,768所揭示的电源供应电路；Figure 2 shows the power supply circuit disclosed in US Patent No. 7,411,768;

图3显示本发明第一个实施例；Fig. 3 shows the first embodiment of the present invention;

图4显示线位讯号L、中位讯号N、开关操作讯号G1与G2的讯号波形；FIG. 4 shows the signal waveforms of the line position signal L, the neutral position signal N, and the switch operation signals G1 and G2;

图5显示本发明第二个实施例；Fig. 5 shows the second embodiment of the present invention;

图6显示本发明第三个实施例；Fig. 6 shows the third embodiment of the present invention;

图7显示本发明第四个实施例；Fig. 7 shows the fourth embodiment of the present invention;

图8显示本发明第五个实施例；Fig. 8 shows the fifth embodiment of the present invention;

图9A-9B显示本发明第六个实施例；9A-9B show a sixth embodiment of the present invention;

图10A-10B显示负载电路分别为重载与轻载时的线位讯号L、中位讯号N、与虚接地FGND的讯号波形图；10A-10B show the signal waveform diagrams of the line signal L, the neutral signal N, and the virtual ground FGND when the load circuit is heavy load and light load respectively;

图11A-11B显示负载电路分别为重载与轻载时的线位讯号L、中位讯号N、虚接地FGND、与开关操作讯号G1与G2的讯号波形图；11A-11B show the signal waveform diagrams of the line signal L, the neutral signal N, the virtual ground FGND, and the switch operation signals G1 and G2 when the load circuit is heavy load and light load respectively;

图12显示应用本发明的电路示意图；Fig. 12 shows the schematic circuit diagram of applying the present invention;

图13显示本发明在不同应用情况下，电力节省比例的示意图。FIG. 13 shows a schematic diagram of power saving ratios of the present invention under different application conditions.

图中符号说明Explanation of symbols in the figure

31 桥式整流电路31 bridge rectifier circuit

33，43，53 控制电路33, 43, 53 control circuit

100，200，300 电源供应电路100, 200, 300 power supply circuit

331，332，433，434 比较电路331, 332, 433, 434 comparison circuits

338，339 分压电路338, 339 voltage divider circuit

435 轻载侦测电路435 light load detection circuit

536，537 电路536, 537 circuits

AC 交流讯号AC AC signal

AND1，AND2 门电路AND1, AND2 gate circuit

App1-4 应用一～四App1-4 Application 1-4

D1，D2 二极管D1, D2 Diodes

Div1，Div2 讯号Div1, Div2 signal

FGND 虚接地FGND virtual ground

G1，G2 开关操作讯号G1, G2 switch operation signal

G11，G21 开关控制讯号G11, G21 switch control signal

Id 电流Id current

L 线位讯号L line bit signal

N 中位讯号N median signal

Q1，Q2 开关元件Q1, Q2 switching elements

Vo1，Vo2，Vo3 整流讯号Vo1, Vo2, Vo3 rectified signal

Vref1，Vref2 默认值Vref1, Vref2 default value

Vref3，Vref4 参考讯号Vref3, Vref4 reference signal

具体实施方式detailed description

请参阅图3，显示本发明第一个实施例，以说明本发明的基本概念。电源供应电路300包含桥式整流电路31以及控制电路33。桥式整流电路31将交流讯号AC转换为整流讯号Vo3，其中，交流讯号AC包含线位讯号L与中位讯号N，线位讯号L与中位讯号N的讯号波形如图4上方所示，其例如为相位相差180度的两正弦波。桥式整流电路31包括一对逆向端互相耦接的二极管D1与D2；与一对互相耦接的开关元件Q1与Q2。二极管对D1与D2与开关元件对Q1与Q2并接于线位讯号L与中位讯号N之间。控制电路33根据交流讯号AC，产生开关操作讯号G1与G2，分别操作开关元件Q1与Q2，以转换交流讯号AC为整流讯号Vo3。Please refer to FIG. 3, which shows the first embodiment of the present invention to illustrate the basic concept of the present invention. The power supply circuit 300 includes a bridge rectifier circuit 31 and a control circuit 33 . The bridge rectifier circuit 31 converts the AC signal AC into a rectified signal Vo3, wherein the AC signal AC includes a line signal L and a neutral signal N, and the signal waveforms of the line signal L and the neutral signal N are shown at the top of FIG. 4 . It is, for example, two sine waves with a phase difference of 180 degrees. The bridge rectifier circuit 31 includes a pair of diodes D1 and D2 with inverse terminals coupled to each other; and a pair of switching elements Q1 and Q2 coupled to each other. The pair of diodes D1 and D2 and the pair of switch elements Q1 and Q2 are connected in parallel between the line signal L and the neutral signal N. The control circuit 33 generates switch operation signals G1 and G2 according to the AC signal AC, respectively operates the switch elements Q1 and Q2 to convert the AC signal AC into a rectified signal Vo3.

其中，开关元件Q1耦接于线位讯号L，且开关元件Q2耦接于中位讯号N。请参阅图4，除显示线位讯号L与中位讯号N之外，并显示开关操作讯号G1与G2的讯号波形。当线位讯号L高于中位讯号N加上默认值Vref1时，控制电路33产生的开关操作讯号G2例如由低位准转为高位准，以导通开关元件Q2；而当中位讯号N高于线位讯号L加上默认值Vref1时，开关操作讯号G1例如由低位准转为高位准，以导通开关元件Q1。Wherein, the switch element Q1 is coupled to the line signal L, and the switch element Q2 is coupled to the neutral signal N. Please refer to FIG. 4 , which shows the signal waveforms of the switch operation signals G1 and G2 in addition to the line signal L and the neutral signal N. When the line signal L is higher than the neutral signal N plus the default value Vref1, the switch operation signal G2 generated by the control circuit 33 is changed from a low level to a high level, for example, to turn on the switching element Q2; and the neutral signal N is higher than When the line level signal L is added with a default value Vref1, the switching operation signal G1 is changed from a low level to a high level to turn on the switching element Q1.

与典型的桥式整流电路相较之下，第一个实施例利用开关元件Q1与Q2取代两二极管，以避免二极管导通时的顺向电压过高，并且提高桥式整流电路31的效率。此外，默认值Vref1用以确保开关元件Q1与Q2不会同时导通，以避免造成造成元件贯穿(shoot through)的问题。Compared with the typical bridge rectifier circuit, the first embodiment uses switching elements Q1 and Q2 instead of two diodes to avoid excessive forward voltage when the diodes are turned on and improve the efficiency of the bridge rectifier circuit 31 . In addition, the default value Vref1 is used to ensure that the switching elements Q1 and Q2 are not turned on at the same time, so as to avoid the problem of element shoot through.

与图2所显示的现有技术相比，本实施例可精确控制开关元件Q1与Q2导通的时间点，而进一步增加整流效率；且利用本发明的整流方式，可以达成省电的模式控制。此外，本发明尚包含其它优于上述现有技术之处，例如：本发明可以避免温度的变化所造成的影响；可设计去噪声电路，以降低噪声的影响；并可根据应用需求调整；侦测交流讯号的电路，可利用比较电路提高RC值，进一步确保避免造成元件贯穿等等。Compared with the prior art shown in FIG. 2 , this embodiment can precisely control the time point at which the switching elements Q1 and Q2 are turned on, thereby further increasing the rectification efficiency; and using the rectification method of the present invention, power-saving mode control can be achieved . In addition, the present invention still includes other advantages over the above-mentioned prior art, for example: the present invention can avoid the influence caused by the change of temperature; the denoising circuit can be designed to reduce the influence of noise; and it can be adjusted according to application requirements; For circuits measuring AC signals, the comparison circuit can be used to increase the RC value to further ensure that components are not penetrated and so on.

图5显示本发明第二个实施例。与第一个实施例不同的是，如图5所示，开关操作讯号G1与开关操作讯号G2保持在高位准的时间不同，也就是说，本发明可以根据需要，设置不同的默认值Vref1与Vref2，以使开关操作讯号G1与开关操作讯号G2保持在高位准的时间不同。如图所示，当线位讯号L高于中位讯号N加上默认值Vref1时，控制电路33产生的开关操作讯号G2例如由低位准转为高位准，以导通开关元件Q2；而当中位讯号N高于线位讯号L加上默认值Vref2时，开关操作讯号G1例如由低位准转为高位准，以导通开关元件Q1。Fig. 5 shows a second embodiment of the present invention. The difference from the first embodiment is that, as shown in FIG. 5 , the switch operation signal G1 and the switch operation signal G2 are kept at a high level at different times. That is to say, the present invention can set different default values Vref1 and Vref1 as required. Vref2 , so that the switching operation signal G1 and the switching operation signal G2 are kept at a high level at different times. As shown in the figure, when the line level signal L is higher than the neutral level signal N plus the default value Vref1, the switching operation signal G2 generated by the control circuit 33 is changed from a low level to a high level, for example, to turn on the switching element Q2; When the bit signal N is higher than the line bit signal L plus the default value Vref2, the switching operation signal G1 is changed from a low level to a high level, for example, to turn on the switching element Q1.

图6显示本发明第三个实施例。本实施例为控制电路33一个较具体的实施例。如图所示，控制电路33包含比较电路331与332。讯号Div1相关于线位讯号L，例如为线位讯号L的分压；讯号Div2相关于中位讯号N，例如为中位讯号N的分压。比较电路331比较讯号Div1与讯号Div2，并根据比较结果，产生开关控制讯号G21以控制开关元件Q2，例如但不限于如图所示，当讯号Div1高于讯号Div2加上参考讯号Vref3时，开关控制讯号G21例如由低位准转为高位准。开关控制讯号G21例如可通过具有适当驱动力的驱动闸而产生开关操作讯号G2，以操作开关元件Q2。类似地，比较电路332比较讯号Div2与讯号Div1，并根据比较结果，产生开关控制讯号G11以控制开关元件Q1，例如但不限于如图所示，当讯号Div2高于讯号Div1加上参考讯号Vref3时，开关控制讯号G11例如由低位准转为高位准。开关控制讯号G11例如可通过具有适当驱动力的驱动闸而产生开关操作讯号G1，以操作开关元件Q1。其中，参考讯号Vref3可以设计成比较电路331、332两输入端之间的内部偏移值(internal offset)，或也可以设计成一个可调整的独立元件。对照图4与图6可知，参考讯号Vref3的设定可根据图4中的Vref1来决定；又，如果将比较电路331、332中的参考讯号Vref3改为不同值，即可达成图5的波形。比较电路331、332可以为一般比较器或磁滞比较器。Fig. 6 shows a third embodiment of the present invention. This embodiment is a more specific embodiment of the control circuit 33 . As shown in the figure, the control circuit 33 includes comparison circuits 331 and 332 . The signal Div1 is related to the line signal L, for example, it is a divided voltage of the line signal L; the signal Div2 is related to the neutral signal N, for example, it is a divided voltage of the neutral signal N. The comparison circuit 331 compares the signal Div1 and the signal Div2, and generates a switch control signal G21 to control the switch element Q2 according to the comparison result. For example, but not limited to, when the signal Div1 is higher than the signal Div2 plus the reference signal Vref3, the switch For example, the control signal G21 changes from a low level to a high level. The switch control signal G21 can, for example, generate a switch operation signal G2 through a gate with an appropriate driving force to operate the switch element Q2. Similarly, the comparison circuit 332 compares the signal Div2 and the signal Div1, and generates a switch control signal G11 to control the switch element Q1 according to the comparison result. For example, but not limited to, as shown in the figure, when the signal Div2 is higher than the signal Div1 plus the reference signal Vref3 , the switch control signal G11 changes from a low level to a high level, for example. The switch control signal G11 can, for example, generate a switch operation signal G1 through a gate with an appropriate driving force to operate the switch element Q1. Wherein, the reference signal Vref3 can be designed as an internal offset between the two input terminals of the comparison circuits 331, 332, or can also be designed as an adjustable independent component. Comparing Figure 4 and Figure 6, it can be known that the setting of the reference signal Vref3 can be determined according to the Vref1 in Figure 4; and if the reference signal Vref3 in the comparison circuits 331 and 332 is changed to a different value, the waveform in Figure 5 can be achieved . The comparison circuits 331 and 332 can be general comparators or hysteresis comparators.

图7显示本发明第四个实施例。本实施例为控制电路43另一个较具体的实施例。相较于图6所示的第三个实施例，本实施例的控制电路43除包含比较电路331与332外，更包含轻载侦测电路435；其中，比较电路331与332的工作方式与前述实施例相同，不另重复说明，而轻载侦测电路435包含比较电路433与434，以及门电路AND1与AND2。有关轻载侦测电路435的目的与作用，请先参阅图10A-10B。Fig. 7 shows a fourth embodiment of the present invention. This embodiment is another more specific embodiment of the control circuit 43 . Compared with the third embodiment shown in FIG. 6 , the control circuit 43 of this embodiment includes not only the comparison circuits 331 and 332, but also a light-load detection circuit 435; wherein, the operation mode of the comparison circuits 331 and 332 is the same as The foregoing embodiments are the same, and the description will not be repeated, but the light load detection circuit 435 includes comparison circuits 433 and 434 , and gate circuits AND1 and AND2 . For the purpose and function of the light load detection circuit 435, please refer to FIGS. 10A-10B first.

图10A-10B分别显示在实际应用上，未采用轻载侦测电路，且当负载电路分别为重载(heavy load)与轻载(light load)时的线位讯号L、中位讯号N、与虚接地FGND的讯号波形图，其中虚接地FGND的节点位置可参阅图3。如图10A所示，当整流讯号端耦接至重载时，也就是流经整流讯号端的电流相对较高时，虚接地FGND的位准可以跟上线位讯号L与中位讯号N中较低的位准。另一方面，如图10B所示，当整流讯号端耦接至轻载时，也就是流经整流讯号端的电流相对较低时，虚接地FGND的位准无法完全跟上线位讯号L与中位讯号N中较低的位准。这是因为当整流讯号端的电流相对较低时，开关元件Q1与Q2的本体寄生二极管没有完全导通而暂时产生较大的源漏极压差，使得虚接地FGND的位准无法完全跟上线位讯号L与中位讯号N中较低的位准，产生暂时偏离的现象。因此，如在轻载状况下直接将讯号Div1与讯号Div2相比较，由于讯号Div1与讯号Div2都是相对于虚接地FGND的讯号，故虚接地FGND的位准偏离将会使G1，G2有硬切效应，造成额外耗损与元件损坏。10A-10B respectively show the line position signal L, neutral position signal N, The signal waveform diagram with the virtual ground FGND, where the node position of the virtual ground FGND can refer to FIG. 3 . As shown in Figure 10A, when the rectified signal terminal is coupled to a heavy load, that is, when the current flowing through the rectified signal terminal is relatively high, the level of the virtual ground FGND can keep up with the lower of the upper line signal L and the neutral signal N. level. On the other hand, as shown in FIG. 10B , when the rectified signal terminal is coupled to a light load, that is, when the current flowing through the rectified signal terminal is relatively low, the level of the virtual ground FGND cannot completely keep up with the line signal L and the neutral position. The lower level in signal N. This is because when the current of the rectified signal terminal is relatively low, the body parasitic diodes of the switching elements Q1 and Q2 are not completely turned on, and a large source-drain voltage difference is temporarily generated, so that the level of the virtual ground FGND cannot completely keep up with the line level. The lower level of the signal L and the neutral signal N produces a temporary deviation. Therefore, if the signal Div1 is directly compared with the signal Div2 under light load conditions, since the signal Div1 and the signal Div2 are both signals relative to the virtual ground FGND, the level deviation of the virtual ground FGND will cause G1 and G2 to have a hard Cutting effect, causing additional wear and component damage.

在图7所示本发明第四个实施例中，设置轻载侦测电路435，即是用以解决上述问题。详言之，根据本发明，轻载侦测电路435根据负载电路是否为轻载，而调整开关元件Q1与Q2导通的时间。轻载侦测电路435具有比较电路433与434、以及门电路AND1与AND2。比较电路433比较参考讯号Vref4与讯号Div2，并根据比较结果，产生侦测讯号Det1。此侦测讯号Det1与开关控制讯号G21作逻辑运算，以产生正确的开关操作讯号G2(未示出)来操作开关元件Q2(未示出)。例如如图所示，可将侦测讯号Det1与开关控制讯号G21输入门电路AND1作及逻辑运算，以决定开关元件Q2是否导通，例如但不限于在侦测讯号Det1与开关控制讯号G21皆为高位准时，导通开关元件Q2。相似地，比较电路434比较参考讯号Vref4与讯号Div1，并根据比较结果，产生侦测讯号Det2。此侦测讯号Det2与开关控制讯号G11作逻辑运算，以产生正确的开关操作讯号G1(未示出)来操作开关元件Q1(未示出)。例如如图所示，可将侦测讯号Det2与开关控制讯号G11输入门电路AND2作及逻辑运算，以决定开关元件Q1是否导通，例如但不限于在侦测讯号Det2与开关控制讯号G11皆为高位准时，导通开关元件Q1。如此一来，当负载电路为轻载时，可适应性调整开关元件Q1与Q2导通的时间，以避免较高的放电电流自虚接地FGND流至开关元件，而造成损坏。In the fourth embodiment of the present invention shown in FIG. 7 , a light load detection circuit 435 is provided to solve the above problems. In detail, according to the present invention, the light-load detection circuit 435 adjusts the turn-on time of the switching elements Q1 and Q2 according to whether the load circuit is light-loaded. The light load detection circuit 435 has comparison circuits 433 and 434 , and gate circuits AND1 and AND2 . The comparison circuit 433 compares the reference signal Vref4 and the signal Div2, and generates a detection signal Det1 according to the comparison result. The detection signal Det1 performs logic operation with the switch control signal G21 to generate a correct switch operation signal G2 (not shown) to operate the switch element Q2 (not shown). For example, as shown in the figure, the detection signal Det1 and the switch control signal G21 can be input into the gate circuit AND1 for AND logic operation to determine whether the switch element Q2 is turned on, for example but not limited to both the detection signal Det1 and the switch control signal G21 When the level is high, the switching element Q2 is turned on. Similarly, the comparison circuit 434 compares the reference signal Vref4 and the signal Div1, and generates a detection signal Det2 according to the comparison result. The detection signal Det2 performs logic operation with the switch control signal G11 to generate a correct switch operation signal G1 (not shown) to operate the switch element Q1 (not shown). For example, as shown in the figure, the detection signal Det2 and the switch control signal G11 can be input into the gate circuit AND2 for AND logic operation to determine whether the switch element Q1 is turned on, for example but not limited to both the detection signal Det2 and the switch control signal G11 When the level is high, the switching element Q1 is turned on. In this way, when the load circuit is light-loaded, the conduction time of the switching elements Q1 and Q2 can be adaptively adjusted to avoid damage caused by high discharge current flowing from the virtual ground FGND to the switching elements.

需说明的是，门电路AND1与AND2仅为应用本发明的一种实施方式，不必须为如图所示的及门电路，只要达成确认导通开关元件Q1与Q2时间点的功能即可，而可为其它电路，且可随开关元件Q1与Q2的型式不同(为P型或N型元件)或随比较电路331、332、433、434的输入端安排方式的不同而改变，皆包含在本发明的范围内，此功能设计为相同技术领域中具有通常知识者所熟知，在此不予赘述。It should be noted that the gate circuits AND1 and AND2 are only an embodiment of the present invention, and they do not need to be AND gate circuits as shown in the figure, as long as the function of confirming the time point of turning on the switching elements Q1 and Q2 is achieved, It can be other circuits, and can be changed with the different types of the switch elements Q1 and Q2 (for P-type or N-type elements) or with the arrangement of the input ends of the comparison circuits 331, 332, 433, 434, all of which are included in Within the scope of the present invention, this functional design is well known to those with ordinary knowledge in the same technical field, and will not be repeated here.

以下说明轻载侦测电路435如何调整开关元件Q1与Q2的导通时间。请同时参阅图7、11A-11B与图12，当整流讯号端耦接至重载时，也就是电流Id相对较高时，讯号Div1、讯号Div2、与虚接地FGND的讯号波形如图11A所示意，由于虚接地FGND的位准大致可以完全跟上线位讯号L与中位讯号N中较低的位准，因此，图7中比较电路433与434的输出(讯号Det1与Det2)将不会变化、或是，讯号Det1与Det2将在讯号G21与G11变化之前，就已经就绪，因此门电路AND1与AND2的输出将会由讯号G21与G11来主控，而不会受讯号Det1与Det2所影响。这表示当整流讯号端耦接至重载时，轻载侦测电路435不会影响开关操作讯号G1与开关操作讯号G2。The following describes how the light load detection circuit 435 adjusts the conduction time of the switching elements Q1 and Q2. Please refer to FIG. 7, 11A-11B and FIG. 12 at the same time. When the rectified signal terminal is coupled to a heavy load, that is, when the current Id is relatively high, the signal waveforms of the signal Div1, the signal Div2, and the virtual ground FGND are shown in FIG. 11A It is shown that since the level of the virtual ground FGND can roughly completely follow the lower level of the upper line signal L and the middle signal N, the outputs (signals Det1 and Det2) of the comparison circuits 433 and 434 in FIG. 7 will not change, or, the signals Det1 and Det2 will be ready before the changes of the signals G21 and G11, so the outputs of the gate circuits AND1 and AND2 will be controlled by the signals G21 and G11, and will not be controlled by the signals Det1 and Det2 influences. This means that when the rectified signal terminal is coupled to a heavy load, the light load detection circuit 435 will not affect the switch operation signal G1 and the switch operation signal G2.

然而，当整流讯号端耦接至轻载时，也就是电流Id相对较低时，讯号Div1、讯号Div2、与虚接地FGND的讯号波形如图11B所示意，由于虚接地FGND的位准无法完全跟上线位讯号L与中位讯号N中较低的位准，故如图所示，讯号Div2低于参考讯号Vref4的时间将会晚于讯号Div1高于[讯号Div2加上参考讯号Vref3]的时间，亦即讯号Det1变化的时间将晚于讯号G21变化的时间，因此门电路AND1的输出将会等待讯号Det1变化之后，才会输出高位准。相似地，门电路AND2的输出也会等待讯号Det2变化之后，才会输出高位准。这表示当整流讯号端耦接至轻载时，轻载侦测电路435调整了开关操作讯号G1与开关操作讯号G2的导通时间，在确定虚接地FGND的位准已经跟上线位讯号L与中位讯号N中较低的位准之后，才导通开关元件Q1或Q2。However, when the rectified signal terminal is coupled to a light load, that is, when the current Id is relatively low, the signal waveforms of the signal Div1, the signal Div2, and the virtual ground FGND are shown in FIG. 11B, because the level of the virtual ground FGND cannot be completely Keep up with the lower level of the upper line signal L and the middle signal N, so as shown in the figure, the time when the signal Div2 is lower than the reference signal Vref4 will be later than the time when the signal Div1 is higher than the [signal Div2 plus the reference signal Vref3] Time, that is, the time when the signal Det1 changes will be later than the time when the signal G21 changes, so the output of the gate circuit AND1 will wait for the signal Det1 to change before outputting a high level. Similarly, the output of the gate circuit AND2 will wait for the signal Det2 to change before outputting a high level. This means that when the rectified signal terminal is coupled to a light load, the light load detection circuit 435 adjusts the conduction time of the switch operation signal G1 and the switch operation signal G2, and determines that the level of the virtual ground FGND has reached the line level signal L and The switch element Q1 or Q2 is turned on only after the lower level of the neutral signal N.

图8显示本发明第五个实施例。本实施例为控制电路53另一个较具体的实施例。相较于图7所示的第四个实施例，本实施例的控制电路53除包含比较电路331、332、433与434，以及门电路AND1与AND2外，更包含电路536与电路537。电路536例如包含两个去突波电路，分别与门电路AND1与AND2耦接，以对门电路AND1与AND2所产生的讯号进行去突波处理，并将结果输入电路537。电路537例如包含两个操作电路，以接收去突波后的讯号，将其调整至适当位准，并避免开关元件Q1与Q2同时导通，而产生开关操作讯号G1与G2，以操作开关元件Q1与Q2。在电路537中，同时可以设置其它安全上的保护电路，例如过电流保护或过电压保护等，以避免电路损坏，并加入省电模式的功能等，此为相同领域具有通常知识者所熟知，在此不予赘述。Fig. 8 shows a fifth embodiment of the present invention. This embodiment is another more specific embodiment of the control circuit 53 . Compared with the fourth embodiment shown in FIG. 7 , the control circuit 53 of this embodiment further includes a circuit 536 and a circuit 537 in addition to comparison circuits 331 , 332 , 433 and 434 , and gate circuits AND1 and AND2 . The circuit 536 includes, for example, two deglitch circuits, which are respectively coupled to the gate circuits AND1 and AND2 to perform deglitch processing on the signals generated by the gate circuits AND1 and AND2, and input the result to the circuit 537 . The circuit 537 includes two operating circuits, for example, to receive the de-glitch signal, adjust it to an appropriate level, and prevent the switching elements Q1 and Q2 from being turned on at the same time, so as to generate switching operation signals G1 and G2 to operate the switching elements Q1 and Q2. In the circuit 537, other safety protection circuits, such as over-current protection or over-voltage protection, can be set at the same time to avoid circuit damage, and the function of power-saving mode can be added, which is well known to those with ordinary knowledge in the same field. I won't go into details here.

图9A-9B显示本发明第六个实施例。本实施例显示控制电路33、43、或53可更包含分压电路338与339，用以将线位讯号L与中位讯号N分别转换为讯号Div1与讯号Div2，使得讯号Div1与讯号Div2分别正比于线位讯号L与中位讯号N。如图所示，分压电路338与339分别与线位讯号L与中位讯号N耦接，其例如但不限于包含两电阻，并分别取其中一个电阻的跨压作为为讯号Div1与讯号Div2。9A-9B show a sixth embodiment of the present invention. This embodiment shows that the control circuit 33, 43, or 53 may further include voltage divider circuits 338 and 339, which are used to convert the line signal L and the neutral signal N into the signal Div1 and the signal Div2 respectively, so that the signal Div1 and the signal Div2 are respectively It is proportional to the line signal L and the neutral signal N. As shown in the figure, the voltage divider circuits 338 and 339 are respectively coupled to the line signal L and the neutral signal N, which include but not limited to two resistors, and take the voltage across one of the resistors as the signal Div1 and the signal Div2 respectively. .

图13显示本发明在不同应用情况下，电力节省比例的示意图。其中，应用情况的条件如下列：FIG. 13 shows a schematic diagram of power saving ratios of the present invention under different application conditions. Among them, the application conditions are as follows:

应用一App1：输入电压Vin为265Vrms，开关元件Q1与Q2导通电阻Ron为1Ω，分压电阻Rd为10MΩ；Application 1 App1: the input voltage Vin is 265Vrms, the on-resistance Ron of the switching elements Q1 and Q2 is 1Ω, and the voltage divider resistance Rd is 10MΩ;

应用二App2：输入电压Vin为85Vrms，开关元件Q1与Q2导通电阻Ron为1Ω，分压电阻Rd为10MΩ；Application 2 App2: The input voltage Vin is 85Vrms, the on-resistance Ron of switching elements Q1 and Q2 is 1Ω, and the voltage divider resistance Rd is 10MΩ;

应用三App3：输入电压Vin为265Vrms，开关元件Q1与Q2导通电阻Ron为0.5Ω，分压电阻Rd为20MΩ；Application 3 App3: The input voltage Vin is 265Vrms, the on-resistance Ron of the switching elements Q1 and Q2 is 0.5Ω, and the voltage divider resistance Rd is 20MΩ;

应用四App4：输入电压Vin为85Vrms，开关元件Q1与Q2导通电阻Ron为0.5Ω，分压电阻Rd为20MΩ。Application 4 App4: The input voltage Vin is 85Vrms, the on-resistance Ron of the switching elements Q1 and Q2 is 0.5Ω, and the voltage dividing resistor Rd is 20MΩ.

以应用一App1的应用情况为例，当输入电流峰值Ip为0.2A时，也就是图13中的A点所示意，其节省功率比例的计算如下：Taking the application of App1 as an example, when the peak value of the input current Ip is 0.2A, as indicated by point A in Figure 13, the calculation of the power saving ratio is as follows:

P_L＝V_D*Ip＝0.6V*0.2A*∫sin(wt)dt/T＝0.12W*(-cos(wt))/T＝0.12W*2/π＝0.076WP_L ＝V_D *Ip＝0.6V*0.2A*∫sin(wt)dt/T＝0.12W*(-cos(wt))/T＝0.12W*2/π＝0.076W

P_RDIV＝Vin²/Rd＝(265V*√2)²*∫sin²(wt)dt/T/RdP_RDIV ＝Vin² /Rd＝(265V*√2)² *∫sin² (wt)dt/T/Rd

＝(265V*√2)²*(-1/2*sin(wt)*cos(wt)dt+1/2*∫1dt)/T/Rd＝(265V*√2)² *(-1/2*sin(wt)*cos(wt)dt+1/2*∫1dt)/T/Rd

＝70225*2*/2/10MW＝0.007W＝70225*2*/2/10MW＝0.007W

P_Ron＝Ip²*∫sin²(wt)dt*Ron＝0.2A²/2*1W＝0.02WP_Ron ＝Ip² *∫sin² (wt)dt*Ron＝0.2A² /2*1W＝0.02W

ΔP＝0.076W-0.007W-0.02W＝0.049WΔP＝0.076W-0.007W-0.02W＝0.049W

Psave％＝ΔP/P_L＝0.049W/0.076W＝64.5％Psave% = ΔP/_PL = 0.049W/0.076W = 64.5%

其中，P_L为桥式整流电路中二极管的消耗功率，V_D为桥式整流电路中二极管的压降，T为输入电流的周期，P_RDIV为分压电阻Rd的消耗功率，P_Ron为开关元件的消耗功率，ΔP为节省功率，Psave％为节省功率比例。由此可以了解，应用本发明节省功率比例相当高，此为本发明优于现有技术的优点之一。Among them, P_L is the power consumption of the diode in the bridge rectifier circuit, V_D is the voltage drop of the diode in the bridge rectifier circuit, T is the cycle of the input current, P_RDIV is the power consumption of the voltage dividing resistor Rd, and P_Ron is the switch Component power consumption, ΔP is power saving, Psave% is power saving ratio. From this, it can be understood that the application of the present invention saves a relatively high proportion of power, which is one of the advantages of the present invention over the prior art.

以上已针对较佳实施例来说明本发明，只是以上所述，仅为使本领域技术人员易于了解本发明的内容，并非用来限定本发明的权利范围。在本发明的相同精神下，本领域技术人员可以思及各种等效变化。例如，开关元件Q1与Q2可为PMOS或NMOS晶体管；在所示各实施例电路中，可插入不影响讯号主要意义的元件，如其它开关等；又例如比较器或误差放大器的输入端正负可以互换，仅需对应修正电路的讯号处理方式即可。凡此种种，皆可根据本发明的教示类推而得，因此，本发明的范围应涵盖上述及其它所有等效变化。The present invention has been described above with reference to preferred embodiments, but the above description is only for those skilled in the art to easily understand the content of the present invention, and is not intended to limit the scope of rights of the present invention. Under the same spirit of the present invention, various equivalent changes can be conceived by those skilled in the art. For example, the switching elements Q1 and Q2 can be PMOS or NMOS transistors; in the circuits of each embodiment shown, elements that do not affect the main meaning of the signal can be inserted, such as other switches; Interchange only needs to correspond to the signal processing method of the correction circuit. All of these can be deduced according to the teaching of the present invention, therefore, the scope of the present invention should cover the above and all other equivalent changes.

Claims (10)

1. a power supply circuit, in order to an AC signal to be converted to a rectification signal, this AC signal includes a line positionPosition signal in signal and, it is characterised in that this power supply circuit comprises:

One bridge rectifier, inversely holds the diode being coupled against each other and the switch element being coupled against each other for a pair including a pair, shouldTo diode and this switch element is connected to this line position signal and in this between signal of position, this bridge rectifier is according at leastOne switching manipulation signal, operate this to switch element, be this rectification signal to change this AC signal；And

One control circuit, according to this AC signal, produces this switching manipulation signal, to operate this to switch element；

Wherein, this includes one first switch and a second switch to switch element, and this switching manipulation signal includes that one first opensClose operation signal and second switch operation signal, to operate this first switch and this second switch respectively, this first switch couplingIt is connected to this line position signal, and this second switch is coupled to position signal in this, position signal one first in this line position signal is higher than thisDuring default value, this second switch operation signal is transferred to a high levels by a low level, to turn on this second switch, when position news in thisNumber higher than this line position signal one second default value time, this first switching manipulation signal is transferred to this high levels by this low level, to leadThis first switch logical；

Wherein, this control circuit includes:

One first comparison circuit, compares one first signal being relevant to this line position signal and is relevant to one second of position signal in thisSignal, and according to comparative result, produce this second switch and control signal, for controlling this second switch；And

One second comparison circuit, compares this second signal and this first signal, and according to comparative result, produces this first switch controlSignal processed, for controlling this first switch；

Wherein, this first comparison circuit and this second comparison circuit include a comparator respectively, in order to compare this first signal withThis second signal.

2. power supply circuit as claimed in claim 1, wherein, this control circuit also includes a underloading circuit for detecting, has:

One the 3rd comparison circuit, compares one the 3rd reference signal and this second signal, and according to comparative result, produces one first and detectSurvey signal；

One the 4th comparison circuit, compares the 3rd reference signal and this first signal, and according to comparative result, produces one second and detectSurvey signal；

One first logic circuit, controls signal according to this first detection signal with this second switch, determines that this second switch turns onOr be not turned on；And

One second logic circuit, according to this second detection signal and this first switch control signal, determines this first switch conductionOr be not turned on.

3. power supply circuit as claimed in claim 1, wherein, this control circuit also includes surging circuit and an operationCircuit, wherein,

This goes surging circuit to couple with this second comparison circuit with this first comparison circuit, with to this first comparison circuit with thisThe comparative result of two comparison circuits, carries out surging and processes；And

This operation circuit, according to the comparative result of this first comparison circuit Yu this second comparison circuit, produces this switching manipulation signalTo operate this first switch and this second switch.

4. power supply circuit as claimed in claim 1, wherein, also comprises a bleeder circuit, with by this line position signal with shouldMiddle position signal is respectively converted into this first signal and this second signal so that this first signal is proportional to respectively with this second signalThis line position signal with this in position signal.

5. power supply circuit as claimed in claim 1, wherein, this first default value is identical with this second default value.

6. an AC signal method for rectifying, in order to an AC signal to be converted to a rectification signal, this AC signal includes onePosition signal in line position signal and, it is characterised in that this AC signal method for rectifying comprises:

According to this AC signal, produce a switching manipulation signal；

Thering is provided a bridge rectifier, it includes a pair inversely holding the diode being coupled against each other and the switch being coupled against each other for a pair unitPart, this to diode and this switch element is connected to this line position signal and in this between signal of position, wherein this is to switch elementIncluding one first switch and a second switch, this first switch is coupled to this line position signal, and this second switch is coupled in thisPosition signal；And

According to this switching manipulation signal, operate this to switch element, and this switching manipulation signal include one first switching manipulation newsNumber with one second switch operation signal, with operate respectively this first switch with this second switch, with change this AC signal for be somebody's turn to doRectification signal；

Wherein, when position signal one first default value during this line position signal is higher than this, this second switch operation signal is by a low levelStandard transfers a high levels to, to turn on this second switch；

Wherein, when in this, position signal is higher than this line position signal one second default value, this first switching manipulation signal is by this low levelStandard transfers this high levels to, to turn on this first switch,

Thus, this AC signal is converted to this rectification signal；

Wherein, this includes according to this AC signal, the step producing this switching manipulation signal:

Utilize one first comparator, compare one first signal being relevant to this line position signal and be relevant to the 1 of position signal in thisTwo signals, and according to comparative result, produce this second switch and control signal, for controlling this second switch；And

Utilize one second comparator, compare this second signal and this first signal, and according to comparative result, produce this first switchControl signal, for controlling this first switch.

7. AC signal method for rectifying as claimed in claim 6, wherein, this produces this switching manipulation according to this AC signalThe step of signal also includes:

Relatively one the 3rd reference signal and this second signal, and according to comparative result, produce one first detection signal；

Relatively the 3rd reference signal and this first signal, and according to comparative result, produce one second detection signal；

Control signal according to this first detection signal with this second switch, determine the conducting of this second switch or be not turned on；And

According to this second detection signal and this first switch control signal, determine this first switch conduction or be not turned on.

8. AC signal method for rectifying as claimed in claim 6, wherein, this produces this switching manipulation according to this AC signalThe step of signal also includes:

Comparative result to this first comparison circuit Yu this second comparison circuit, carries out surging and processes；And

According to the comparative result of this first comparison circuit Yu this second comparison circuit, produce this switching manipulation signal with operate thisOne switch and this second switch.

9. AC signal method for rectifying as claimed in claim 6, wherein, this this first signal distinguishes direct ratio with this second signalPosition signal in this line position signal is with this.

10. AC signal method for rectifying as claimed in claim 6, wherein, this first default value is identical with this second default value.