CN101282088A - Source electrode driven inverse-excitation converting circuit - Google Patents

Source electrode driven inverse-excitation converting circuit Download PDF

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Publication number
CN101282088A
CN101282088A CNA2008100284224A CN200810028422A CN101282088A CN 101282088 A CN101282088 A CN 101282088A CN A2008100284224 A CNA2008100284224 A CN A2008100284224A CN 200810028422 A CN200810028422 A CN 200810028422A CN 101282088 A CN101282088 A CN 101282088A
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circuit
switch mos
diode
mos pipe
connects
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CN100592614C (en
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尹向阳
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Mornsun Guangzhou Science and Technology Ltd
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Mornsun Guangzhou Science and Technology Ltd
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Abstract

The invention discloses an flyback converting circuit of source electrode drive comprising a starting circuit, an absorbing circuit, a transformer, a first switch MOS tube, a frequency generator, an output circuit, also comprising a second switch MOS tube in which the grid electrode is connected with the frequency generator, the source electrode is connected with the ground, the drain electrode is connected with the source electrode of the first switch MOS tube; a feedback circuit which is connected between the grid electrode and the source electrode of the first switch MOS tube; an assistant power circuit which is connected between the grid electrode of the first switch MOS tube and the ground. Because the first switch MOS tube uses the source electrode drive mode to realize soft starting and closing, the on-off process is transitied slowly, which can control the appearance of outburst short time sharp peak on current when opening the first switch MOS tube, thereby reducing the opening consume and improving the product efficiency, and the electric quantity in transformer leakage inductance at the moment of closing the first switch MOS tube is used, thereby improving the product frequency.

Description

A kind of inverse-excitation converting circuit of source drive
Technical field
The present invention relates to a kind of inverse-excitation converting circuit, particularly a kind of inverse-excitation converting circuit of source drive.
Background technology
Inverse-excitation converting circuit commonly used at present mainly is made up of start-up circuit, absorption circuit, transformer T1, the first switch MOS pipe Q1, frequency generator and output circuit as shown in Figure 1.The voltage input connects the first switch MOS pipe Q1 grid after dividing three the tunnel, the one tunnel to be connected in series start-up circuit and frequency generator successively again; One the tunnel connects the elementary winding N1 of transformer T1 different name end and first switch MOS pipe Q1 drain electrode after absorbing circuit; One the tunnel connects the elementary winding N1 of transformer T1 end of the same name, the elementary winding N1 of transformer T1 different name termination first switch MOS pipe Q1 drain electrode, the first switch MOS pipe Q1 source ground; Transformer T1 secondary winding N2 two termination output circuits are to load.
Wherein start-up circuit is first resistance R 1; Absorbing circuit is the 3rd resistance R 3 the 3rd capacitor C 3 back serial connection second diode D2 in parallel, and the effect of this part is to absorb transformer T1 leakage inductance energy; Frequency generator adopts power management chip PWMIC; Output circuit is composed in series by the first diode D1 and first capacitor C 1, the transformer T1 secondary winding N2 different name termination first diode D1 anode, the first diode D1 negative electrode is connected altogether with transformer T1 secondary winding N2 end of the same name after first capacitor C 1, and wherein first capacitor C, 1 two ends are voltage output end.
The operation principle of this circuit is that voltage is after input Vin input, triggering power management chip PWMIC through first resistance R 1 starts working, when power management chip PWMIC output high level, the first switch MOS pipe Q1 is open-minded, the elementary winding N1 of electric current inflow transformer T1, this moment, transformer T1 carried out energy storage.When power management chip PWMIC output low level, the first switch MOS pipe Q1 turn-offs, and electric weight is coupled to transformer T1 secondary winding N2 through transformer T1, and energy is offered load through output circuit.Because electric weight can only discharge through absorbing circuit in the shutdown moment transformer T1 leakage inductance, promptly enter RC network the 3rd resistance R 3 and the 3rd capacitor C 3 by the second diode D2, thereby consume on the 3rd resistance R 3, cause the certain energy loss, circuit efficiency is reduced.As shown in Figure 2; because the Miller effect when the first switch MOS pipe Q1 is opened is without any safeguard measure; thereby the first switch MOS pipe Q1 spike in short-term can occur on the electric current when opening, and the turn-on consumption of the first switch MOS pipe Q1 is to can not get control at this moment.
Summary of the invention
The object of the invention is to provide a kind of high efficiency inverse-excitation converting circuit, and this circuit adopts source pole driving mode, thereby improves the energy loss of Circuits System when shutdown moment and conducting.
The present invention adopts following scheme to realize above-mentioned purpose: a kind of inverse-excitation converting circuit of source drive, comprise: start-up circuit, absorb circuit, transformer, the first switch MOS pipe, frequency generator and output circuit, the input electric weight divides three the road to insert, the first via connects primary winding N1 end of the same name, the drain electrode of the primary winding N1 different name termination first switch MOS pipe, the second the tunnel connects different name end and the drain electrode of the first switch MOS pipe of primary winding N1 after absorbing circuit, Third Road connects the frequency generator and the first switch MOS tube grid through start-up circuit, transformer secondary output winding N2 two ends connect load behind output circuit, it is characterized in that, also comprise: the second switch metal-oxide-semiconductor, its grid connects frequency generator, source ground, drain electrode connects the source electrode of the first switch MOS pipe; Feedback circuit is connected between the grid, source electrode of the first switch MOS pipe; Auxilliary power circuit is connected between the grid and ground of the first switch MOS pipe;
Wherein said auxilliary power circuit, comprise the 4th diode and second electric capacity, the 4th diode cathode connects first resistance, the 4th diode anode ground connection, second electric capacity is connected in parallel on the 4th diode two ends, after being used to absorb the transformer and the first switch MOS pipe energy, discharge, energy is fed back to circuit use in the next work period.
Wherein said feedback circuit, comprise the 4th resistance and the 3rd diode, the 4th resistance is connected in series behind the negative electrode of the 3rd diode, the 4th resistance connects first resistance, the 3rd diode anode connects the first switch MOS pipe source electrode, is used to form energy and discharges the loop and the first switch MOS pipe source voltage is carried out clamp.
Described first switch MOS pipe and second switch metal-oxide-semiconductor all are N channel-type metal-oxide-semiconductors.
Described the 4th diode is a Zener diode.
The present invention can also do following improvement:
Described source electrode and drain electrode one the 5th electric capacity that is connected in parallel at the first switch MOS pipe, effect are that the leakage inductance at the former limit N1 of transformer adds capacitance to the path of accessory power supply capacitor C 2, improve the circuit dynamic property.
Described one the 4th electric capacity that is connected in parallel at the 4th resistance two ends, effect are that the leakage inductance at the former limit N1 of transformer TX1 adds capacitance to the path of accessory power supply capacitor C 2, improve the circuit dynamic property.
Also set up the auxiliary winding N3 of the 5th diode and transformer, after the end of the same name of the auxiliary winding N3 of the anode of the 5th diode and transformer was connected in series, the negative electrode of the 5th diode connect first resistance, the different name end ground connection of the auxiliary winding N3 of transformer.
In small-power or low-voltage input application, can remove described absorption circuit.
The present invention is relative, and the prior art advantage is:
Because the first switch MOS pipe is adopted source pole driving mode, realize soft start, soft shutoff, the mild transition of make and break process, the burst that the energy good restraining first switch MOS pipe occurs on the electric current when opening is spike in short-term, thereby reduced turn-on consumption, improve product efficiency, and electric weight in the first switch MOS pipe shutdown moment transformer leakage inductance is utilized, further improve product efficiency.The design that improves for the product frequency simultaneously provides possibility.
Figure of description
Fig. 1 is prior art circuits figure;
Fig. 2 is the first switch MOS pipe conducting current waveform figure of prior art;
Fig. 3 is a circuit block diagram of the present invention;
Fig. 4 is the circuit diagram of the embodiment of the invention one;
Fig. 5 is the first switch MOS pipe conducting current waveform figure of the embodiment of the invention one;
Fig. 6 is the circuit diagram of the embodiment of the invention two;
Fig. 7 is the circuit diagram of the embodiment of the invention three;
Fig. 8 is the circuit diagram of the embodiment of the invention four;
Fig. 9 is the circuit diagram of the embodiment of the invention five.
Embodiment
Embodiment one
As shown in Figure 3, Figure 4, the present invention adopts following scheme to realize above-mentioned purpose: a kind of inverse-excitation converting circuit of source drive, comprise: start-up circuit, absorption circuit, transformer T1, the first switch MOS pipe Q1, frequency generator and output circuit, the input electric weight divides three the road to insert: the first via connects the elementary winding N1 of transformer T1 end of the same name, drain electrode through the elementary winding N1 of the transformer T1 different name termination first switch MOS pipe Q1, through the drain electrode of the source electrode of first switch MOS pipe Q1 serial connection second switch metal-oxide-semiconductor Q2, again through the source ground of second switch metal-oxide-semiconductor Q2; The second the tunnel connects transformer T1 different name end and first switch MOS pipe Q1 drain electrode after absorbing circuit; Third Road divides four branch roads after connecing start-up circuit, the first via is through auxilliary power circuit ground connection, the second the tunnel connects the grid of second switch metal-oxide-semiconductor Q2 through frequency generator, Third Road connects feedback circuit, the four the tunnel connects the grid of the first switch MOS pipe Q1, and transformer T1 secondary winding N2 two ends connect load behind output circuit.
Wherein start-up circuit is first resistance R, 1, one termination input Vin, a termination frequency generator;
Feedback circuit, comprise the 4th resistance R 4 and the 3rd diode D3, the 4th resistance R 4 is connected in series behind the negative electrode of the 3rd diode D3, the 4th resistance R 4 connects first resistance R 1, the 3rd diode D3 anode connects the first switch MOS pipe Q1 source electrode, is used to form energy and discharges the loop and the first switch MOS pipe Q1 source voltage is carried out clamp;
Auxilliary power circuit, comprise the 4th diode D4 and second capacitor C 2, the 4th diode D4 negative electrode connects first resistance R 1, plus earth, second capacitor C 2 is connected in parallel on the 4th diode D4 two ends, after being used to absorb the transformer T1 and the first switch MOS pipe Q1 energy, discharge, energy is fed back to circuit use in the next work period;
Absorb circuit, comprise the 3rd resistance R 3, the 3rd capacitor C 3 and the second diode D2, after the negative electrode of the 3rd resistance R 3 and the second diode D2 is connected in series, the 3rd resistance R 3 meets the elementary winding N1 of transformer T1, the anode of the second diode D2 connects the different name end of the elementary winding N1 of transformer T1, the 3rd capacitor C 3 in parallel at the 3rd resistance R 3 two ends, the absorption circuit of the elementary winding N1 of formation transformer T1 leakage inductance;
Frequency generator is power management chip PWMIC;
Output circuit, comprise the first diode D1 and first capacitor C 1, the anode of the first diode D1 connects the different name end of transformer T1 secondary winding N2, the negative electrode of the first diode D1 connects load, the negative electrode of first capacitor C, 1 one terminations, the first diode D1, the other end of first capacitor C 1 is connected altogether with transformer secondary output winding N2 end of the same name;
Concrete operation principle is: electric current is given second capacitor C, 2 chargings of auxilliary power circuit during circuit start by first resistance R, 1 back one tunnel, one the tunnel gives power management chip PWMIC power supply, when voltage rose to power management chip PWMIC operating voltage, power management chip PWMIC began to drive second switch metal-oxide-semiconductor Q2.At the conducting duty ratio ton of power management chip PWMIC during the stage, second switch metal-oxide-semiconductor Q2 conducting, V1 point current potential is dragged down, and the grid potential of the first switch MOS pipe Q1 is constant, because the grid of the first switch MOS pipe Q1-source voltage Vgs increases, thereby makes the first switch MOS pipe Q1 be driven conducting, this moment the flow through elementary winding N1 of transformer T1, the first switch MOS pipe Q1, second switch metal-oxide-semiconductor Q2 of electric current, and rise gradually, transformer T1 carries out energy storage.
When the output signal of power management chip PWMIC was overturn, output signal was a low level by the high level saltus step, and second switch metal-oxide-semiconductor Q2 is turned off.Work in shutoff duty ratio toff during the stage at power management chip PWMIC, because second switch metal-oxide-semiconductor Q2 is turned off, V1 point current potential is raised gradually, and the grid potential of the first switch MOS pipe Q1 is constant, the grid of the first switch MOS pipe Q1-source voltage Vgs reduces gradually, be lower than when turn-offing threshold values up to grid-source voltage Vgs of the first switch MOS pipe Q1, the first switch MOS pipe Q1 begin by, transformer T1 transfers its energy to output circuit.When the output signal of power management chip PWMIC was overturn once more, output signal was a high level by low transition, made second switch metal-oxide-semiconductor Q2 conducting again.And so forth, this circuit just is operated in self oscillating regime.
When circuit working is turn-offing duty ratio toff during the stage, shutoff in succession along with the first switch MOS pipe Q1 and second switch metal-oxide-semiconductor Q2, the leakage inductance energy of the elementary winding N1 of transformer T1 discharges second capacitor C, 2 chargings of giving auxilliary power circuit by parasitic capacitance Cds1, the 3rd diode D3 between the first switch MOS pipe Q1 leakage-source electrode, the 4th resistance R 4, discharge in the next work period afterwards, offer circuit energy, the energy of avoiding refluxing does not become interference signal because of there being the loop of release, realize the reasonable utilization of backflow energy, product efficiency is improved.Simultaneously, junction capacitance Cgs1 stored energy when conducting also discharges second capacitor C, 2 chargings of giving auxilliary power circuit through the 3rd diode D3, the 4th resistance R 4 between grid-source electrode of the first switch MOS pipe Q1.Discharge in the next work period afterwards, energy is offered circuit use, realize the reasonable utilization of backflow energy, product efficiency is improved.
As shown in Figure 5, adopt the circuit of the technology of the present invention, the conducting electric current of the first switch MOS pipe Q1 has been eliminated the Miller effect well in startup, and current waveform smoothly rises.
Embodiment two
As shown in Figure 6, relatively embodiment one different be, at the first switch MOS pipe Q1 source drain two ends and connect one the 5th capacitor C 5, effect is that the leakage inductance at the elementary winding N1 of transformer T1 adds capacitance to the path of auxilliary power supply second capacitor C 2, improves the circuit dynamic property.
Embodiment three
As shown in Figure 7, what relatively embodiment one was different is, at feedback circuit the 4th resistance R 4 two ends and connect one the 4th capacitor C 4, effect is that the leakage inductance at the elementary winding N1 of transformer T1 adds capacitance to the path of auxilliary power supply second capacitor C 2, improves the circuit dynamic property.
Embodiment four
As shown in Figure 8, relatively embodiment one different be to remove the absorption circuit.In small-power or low-voltage input application, because the elementary winding N1 of transformer T1 leakage inductance is less, on the basis of embodiment one, remove the absorption circuit in the circuit, still the leakage inductance energy of transformer T1 all can be fed back to the accessory power supply part, play same effect.
Embodiment five
As shown in Figure 9, relatively embodiment one different be that transformer T1 increases an auxiliary winding N3.Input Vin connects the 5th diode D5 negative electrode after first resistance R 1, the 5th diode D5 anode connects auxiliary winding N3 end of the same name, auxiliary winding N3 different name end ground connection.The same effect that plays accessory power supply.
In the circuit working process, because the break-make of the first switch MOS pipe Q1 is by second switch metal-oxide-semiconductor Q2 the control of V1 point current potential to be realized, the driving that is second switch metal-oxide-semiconductor Q2 is the source voltage type of drive, realize soft start, soft shutoff, the mild transition of make and break process, the current burst spike that made for first switch MOS pipe Q1 conducting moment is by good restraining, thereby reduced turn-on consumption, improves product efficiency.The design that improves for the product frequency simultaneously provides possibility.
The present invention is not limited to above-mentioned execution mode, and other any identical with the present invention or akin products that anyone draws under enlightenment of the present invention are all within protection scope of the present invention.

Claims (9)

1, a kind of inverse-excitation converting circuit of source drive, comprise: start-up circuit, absorb circuit, transformer, the first switch MOS pipe, frequency generator and output circuit, the input electric weight divides three the road to insert, the first via connects primary winding N1 end of the same name, the drain electrode of the primary winding N1 different name termination first switch MOS pipe, the second the tunnel connects different name end and the drain electrode of the first switch MOS pipe of primary winding N1 after absorbing circuit, Third Road connects the frequency generator and the first switch MOS tube grid through start-up circuit, transformer secondary output winding N2 two ends connect load behind output circuit, it is characterized in that, also comprise: the second switch metal-oxide-semiconductor, its grid connects frequency generator, source ground, drain electrode connects the source electrode of the first switch MOS pipe; Feedback circuit is connected between the grid, source electrode of the first switch MOS pipe; Auxilliary power circuit is connected between the grid and ground of the first switch MOS pipe.
2, the inverse-excitation converting circuit of a kind of source drive according to claim 1, it is characterized in that described auxilliary power circuit comprises: the 4th diode and second electric capacity, the 4th diode cathode connects start-up circuit, the 4th diode anode ground connection, second electric capacity are connected in parallel on the 4th diode two ends.
3, the inverse-excitation converting circuit of a kind of source drive according to claim 1, it is characterized in that, described feedback circuit, comprise the 4th resistance and the 3rd diode, the 4th resistance is connected in series behind the negative electrode of the 3rd diode, the 4th resistance connects start-up circuit, and the 3rd diode anode connects the first switch MOS pipe source electrode.
4, the inverse-excitation converting circuit of a kind of source drive according to claim 3 is characterized in that, described the 4th diode is a Zener diode.
5, the inverse-excitation converting circuit of a kind of source drive according to claim 1 is characterized in that, described first switch MOS pipe and second switch metal-oxide-semiconductor all are N channel-type metal-oxide-semiconductors.
6, the inverse-excitation converting circuit of a kind of source drive according to claim 1 is characterized in that, at the source electrode of the first switch MOS pipe and drain electrode one the 5th electric capacity that is connected in parallel.
7, the inverse-excitation converting circuit of a kind of source drive according to claim 1 is characterized in that, also comprises: described the 4th resistance two ends one the 4th electric capacity that is connected in parallel.
8, the inverse-excitation converting circuit of a kind of source drive according to claim 1, it is characterized in that, also comprise: the 5th diode and transformer are assisted winding N3, after the end of the same name of the auxiliary winding N3 of the anode of the 5th diode and transformer is connected in series, the negative electrode of the 5th diode connects start-up circuit, the different name end ground connection of the auxiliary winding N3 of transformer.
9, a kind of inverse-excitation converting circuit of source drive, comprise: start-up circuit, transformer, the first switch MOS pipe, frequency generator and output circuit, the input electric weight divides two the road to insert, the first via connects primary winding N1 end of the same name, the drain electrode of the primary winding N1 different name termination first switch MOS pipe, the second the tunnel connects the frequency generator and the first switch MOS tube grid through start-up circuit, transformer secondary output winding N2 two ends connect load behind output circuit, it is characterized in that, also comprise: the second switch metal-oxide-semiconductor, its grid connects frequency generator, source ground, and drain electrode connects the source electrode of the first switch MOS pipe; Feedback circuit is connected between the grid, source electrode of the first switch MOS pipe; Auxilliary power circuit is connected between the grid and ground of the first switch MOS pipe;
Described auxilliary power circuit comprises: the 4th diode and second electric capacity, and the 4th diode cathode connects start-up circuit, the 4th diode anode ground connection, second electric capacity is connected in parallel on the 4th diode two ends;
Described feedback circuit comprises the 4th resistance and the 3rd diode, and the 4th resistance is connected in series behind the negative electrode of the 3rd diode, and the 4th resistance connects start-up circuit, and the 3rd diode anode connects the first switch MOS pipe source electrode.
CN 200810028422 2008-05-30 2008-05-30 Source electrode driven inverse-excitation converting circuit Active CN100592614C (en)

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CN105896991A (en) * 2016-05-25 2016-08-24 广州金升阳科技有限公司 Bidirectional converter
CN105896991B (en) * 2016-05-25 2018-05-29 广州金升阳科技有限公司 A kind of reversible transducer
CN106253716A (en) * 2016-08-08 2016-12-21 杭州士兰微电子股份有限公司 The Switching Power Supply of primary-side-control and control method
CN106340921A (en) * 2016-09-26 2017-01-18 武汉柏太电力设备有限公司 Current source circuit capable of providing high frequency alternating current
CN106712562A (en) * 2016-12-15 2017-05-24 宁波央腾汽车电子有限公司 Inductive load circuit and method of eliminating current spikes
CN106787766A (en) * 2017-02-08 2017-05-31 深圳市华星光电技术有限公司 Circuit of reversed excitation and electronic installation
CN107612107A (en) * 2017-08-23 2018-01-19 成都芯源系统有限公司 A kind of generating circuit of service voltage and its integrated circuit
CN110649795A (en) * 2019-09-25 2020-01-03 广州金升阳科技有限公司 Driving circuit
CN110518806A (en) * 2019-09-27 2019-11-29 北京机械设备研究所 A kind of MOSFET series circuit for high input voltage reverse exciting switching voltage regulator

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