CN2914481Y - Once side control switch type power supply regulator - Google Patents

Abstract

The utility model relates to a primary-control switch-type power regulator. The power regulator comprises a transformer including a primary winding and an auxiliary winding respectively coupled with a positive power rail and a negative power rail; a switch serially connected with the first and second primary windings for switching the transformer; a control circuit coupled with the switch and the auxiliary winding for producing a switch signal to switch the switch and adjust the output of the switch-type power regulator; a supply capacitor coupled with the control circuit to supply power to the control circuit; and a diode coupled with the negative power rail and the supply capacitor. The auxiliary winding has a leakage inductor for storing energy when the switch is switched on and for supplying the energy to the supply capacitor through the diode when the switch is switched off. The configuration of the transformer and the switch can improve efficiency and reduce electromagnetic interference of the switch-type power regulator.

Description

The switched-mode power supply adjuster of primary side control

Technical field:

The utility model relates to a kind of feed regulator isolator, is meant a kind of switched-mode power supply adjuster of primary side control especially.

Background technology:

Press, the switched-mode power supply adjuster has extensively been applied to provide and has been adjusted voltage and electric current now, and the research focus of feed regulator isolator is to be placed on how to allow the feed regulator isolator can more efficient saving power supply at present.The switched-mode power supply adjuster includes a control circuit, a switch and a transformer usually, control circuit applies to the output voltage and/or the output current of sensing switched-mode power supply adjuster, and produces the switching and output voltage and/or the output current of adjusting switched-mode power supply adjuster of a controlling signal with control switch.

Seeing also Fig. 1, is the circuit diagram of the switched-mode power supply adjuster commonly used.As shown in the figure, commonly use the switched-mode power supply adjuster and include a transformer 10, it includes a first side winding N _P, a secondary side winding N _SWith an auxiliary winding N _A, first side winding N _PAn end couple a positive supply rail V _INOne switch 11, it connects first side winding N _PThe other end, and be connected to a negative supply rail via a resistance 12, negative supply rail is an earth terminal; One control circuit 25, it couples switch 11, is used for control switch 11 with switching transformer 10 and output voltage and/or the output current of adjusting the switched-mode power supply adjuster; Secondary side winding N _S, the one end connects a rectifier 13; One filter capacitor 14, its two ends are coupled in rectifier 13 and secondary side winding N respectively _SThe other end.When switch 11 conductings, energy will be stored to transformer 10, in case switch 11 by the time, transformer 10 stored energy will be via secondary side winding N _SBe released into the switched-mode power supply regulator output, simultaneously the auxiliary winding N of transformer 10 _AProduce a reflected voltage V _AUX1

$V_O+V_F=N_{\mathrm{NS}}\×\frac{\mathrm{d\Φ}}{\mathrm{dt}}---\left(1\right)$

${\mathrm{<figure-callout\; id="1"\; label="V\; AUX"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">V</figure-callout>}}_{\mathrm{AUX}}=N_{\mathrm{NA}}\&times;\frac{\mathrm{d\&Phi;}}{\mathrm{dt}}---\left(2\right)$

According to equation (1) and (2), reflected voltage V _AUX1Can be expressed as:

$V_{\mathrm{<figure-callout\; id="1"\; label="AUX"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">AUX</figure-callout>}1}=\frac{N_{\mathrm{NA}}}{N_{\mathrm{NS}}}\&times;(V_O+V_F)---\left(3\right)$

Wherein, N _NAWith N _NSThe auxiliary winding N of difference indication transformer 10 _AWith secondary side winding N _SUmber of turn; V _OOutput voltage for the switched-mode power supply adjuster; V _FPressure drop for the forward bias voltage drop of rectifier 13; Ф is a magnetic flux, Ф=B * A _e(B is a magnetic density, and Ae is the axle center sectional area of transformer 10).

Control circuit 25, it is provided with a feed end VDD and an earth terminal GND, to be used to receive power supply; One detecting voltage end VS, it is coupled between two resistance 15,16 of a bleeder circuit, and bleeder circuit is connected the auxiliary winding N of transformer 10 _AAnd between the negative supply rail, detecting voltage end VS produces a detecting voltage V _DET1, it can be expressed as:

$V_{\mathrm{<figure-callout\; id="1"\; label="DET"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">DET</figure-callout>}1}=\frac{R_{16}}{{\mathrm{<figure-callout\; id="15"\; label="R"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">R</figure-callout>}}_{15}+{\mathrm{<figure-callout\; id="16"\; label="R"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">R</figure-callout>}}_{16}}\&times;V_{\mathrm{AUX}1}---\left(4\right)$

Wherein, R ₁₅With R ₁₆Be respectively the resistance value of resistance 15 and resistance 16.Reflected voltage V _AUX1More via 17 chargings of 18 pairs one of diodes supply electric capacity, with power supply to control circuit 25.

Aforesaid resistance 12, it is used for as a current sensing device, and resistance 12 is connected between switch 11 and the negative supply rail, switches electric current I with one of conversion transformer 10 _PBe a current signal V _CSOne current sense end VI of control circuit 25 connects resistance 12, to be used for detecting current signal V _CS, an output VG of control circuit 25 produces one and switches signal V _PWMWith switching transformer 10.Can be used for adjusting output voltage and output current though commonly use the switched-mode power supply adjuster, it has several shortcomings.First shortcoming is that the leakage inductance of transformer 10 causes high power consumption; form the high voltage surging easily owing to leakage inductance meeting storage power in addition; destroy switch 11 so easily; so the switched-mode power supply adjuster of commonly using is to be provided with a buffer circuit for protection switch 11; it includes buffering diode 19, a buffer capacitor 20 and a buffer resistance 21; be used to consume the stored energy of leakage inductance of transformer 10, avoid forming the high voltage surging with protection switch 11.

Second shortcoming is that the switched-mode power supply adjuster lacks adjustment under underload and non-loaded state.Commonly use the switched-mode power supply adjuster and be auxiliary winding N by transformer 10 _APower supply is to control circuit 25, so the operating current of control circuit 25 is promptly represented auxiliary winding N _ALoad.If the output loading of switched-mode power supply adjuster is lower than auxiliary winding N _ALoad the time, the stored energy of transformer 10 will only can be via diode 18 and auxiliary winding N _ABe released into supply electric capacity 17, so when switch 11 ends, rectifier 13 will still remain closed condition, so the output voltage V of switched-mode power supply adjuster _OCan't be from auxiliary winding N _AFeedback to control circuit 25, so under underload and non-loaded state, the detecting voltage V that detecting voltage end VS is produced _DET1Only relevant with the voltage of feed end VDD, so the switched-mode power supply adjuster of commonly using lacks the property adjusted.

Another known techniques is by United States Patent (USP)s that the people proposed the 6th such as Mr.s Yang, 853, No. 563 " flyback power converter (Primary-side controlled flyback power converter) of primary side control ", one major defect of this known techniques is electromagnetic interference (Electric and MagneticInterference, EMI), the reason of its generation is that the drain of switch is connected directly to positive supply rail, so a parasitic capacitance of switch couples mutually with a stray inductance, thereby form a high-frequency resonance groove, so will produce higher electromagnetic interference.

Therefore, the utility model proposes a kind of switched-mode power supply adjuster, it has the characteristic of high-effect and low electromagnetic interference.In addition, switched-mode power supply adjuster of the present utility model can accurately be adjusted output voltage under underload and non-loaded state.

Novel content:

Main purpose of the present utility model, be to provide a kind of switched-mode power supply adjuster of primary side control, it comprises a transformer, transformer is provided with first side winding and auxiliary winding, be provided with switch between first side winding and the auxiliary winding, so can promote the usefulness and reduction electromagnetic interference of switched-mode power supply adjuster.

Another purpose of the present utility model, be to provide a kind of switched-mode power supply adjuster of primary side control, the leakage inductance of its transformer can allow the voltage of supply electric capacity be higher than the voltage that secondary side winding reflected of transformer, make the output voltage of switched-mode power supply adjuster when switch ends, can feedback to control circuit, so can promote the load of switched-mode power supply adjuster under underload and non-loaded state and adjust property via the auxiliary winding of transformer.

Another purpose of the present utility model, be to provide a kind of switched-mode power supply adjuster of primary side control, its transformer is provided with the second auxiliary winding and can charges to supply electric capacity, so provides second source to control circuit, but and then guarantees control circuit normal operation under vicious situation.

The switched-mode power supply adjuster of the utility model primary side control, it includes a transformer, and transformer is provided with a first side winding and an auxiliary winding, and two windings couple a positive supply rail and a negative supply rail respectively; One switch, itself and first side winding and auxiliary winding are in series, and are used for switching transformer; One current sensing device, it couples switch and auxiliary winding, is used for switching electric current according to one of transformer and produces a current signal; One control circuit, it couples the auxiliary winding of switch and transformer, produces one with the foundation current signal and switches signal, switches signal and is used for diverter switch and the output of adjusting the switched-mode power supply adjuster; One supply electric capacity, its connect control circuit with power supply to control circuit; One diode, it couples negative supply rail and supplies electric capacity so that supply electric capacity is charged.Wherein, above-mentioned auxiliary winding has a leakage inductance, and it stores a storage power when switch conduction, and when switch ends, discharges storage power to supplying electric capacity via diode.So can promote the usefulness of switched-mode power supply adjuster and can reduce electromagnetic interference, and can promote the load of switched-mode power supply adjuster under underload and the non-loaded state property adjusted by the set-up mode of above-mentioned transformer and switch.

Description of drawings:

Fig. 1 is the circuit diagram of known switched-mode power supply adjuster;

Fig. 2 is the circuit diagram of switched-mode power supply adjuster of the primary side control of the utility model preferred embodiment;

Fig. 3 is the equivalent circuit diagram of switched-mode power supply adjuster of the primary side control of Fig. 2;

Fig. 4 is the circuit diagram of the control circuit of the utility model preferred embodiment;

Fig. 5 is the circuit diagram of switched-mode power supply adjuster of the primary side control of another preferred embodiment of the utility model;

Fig. 6 is the circuit diagram of switched-mode power supply adjuster of the primary side control of the another preferred embodiment of the utility model.

The figure number explanation:

10 transformers, 11 switches

12 resistance, 13 rectifiers

14 filter capacitors, 15 resistance

16 resistance, 17 supply electric capacity

18 diodes, 19 buffering diodes

20 buffer capacitors, 21 buffer resistances

25 control units, 30 transformers

35 switches, 37 current sensing resistors

39 transformers, 40 buffering diodes

41 buffer capacitors, 42 buffer resistances

45 buffer circuits, 50 bleeder circuits

52 resistance, 55 resistance

60 first diodes, 65 second diodes

70 supply electric capacity, 80 rectifiers

90 filter capacitors, 100 control circuits

110 sampling stick holding circuits, 120 error amplifiers

125 comparators, 150 oscillators

160 flip-flop GND earth terminals

I _PSwitch current L _I1Leakage inductance

L _I2Leakage inductance N _AAuxiliary winding

N _A1The first auxiliary winding N _A2The second auxiliary winding

N _A3The 3rd auxiliary winding N _PFirst side winding

N _SSecondary side winding V _AUX1Reflected voltage

V _AUX2Voltage V _CSCurrent signal

V _DET1Detecting voltage V _DET2Detecting voltage

V _FBBack coupling signal V _INPositive supply rail

V _OOutput voltage V _PWMSwitch signal

V _RWith reference to electric V _RSTThe replacement signal

V _SSample signal VDD feed end

VG output VI current sense end VS detecting voltage end

Embodiment:

For making the auditor further understanding and understanding more be arranged to architectural feature of the present utility model and the effect reached, sincerely help with preferred embodiment figure and cooperate detailed explanation, illustrate as the back:

Seeing also Fig. 2, is the circuit diagram of switched-mode power supply adjuster of the primary side control of the utility model preferred embodiment.As shown in the figure, switched-mode power supply adjuster of the present utility model includes a transformer 30, is used for storage power and shifts the secondary side of storage power to transformer 30 from a primary side of transformer 30.Wherein, the primary side of transformer 30 is provided with a first side winding N _PWith one first auxiliary winding N _A1, the secondary side of transformer 30 then is provided with a secondary side winding N _SFirst side winding N _PWith the first auxiliary winding N _A1Couple the power rail of switched-mode power supply adjuster, i.e. first side winding N _PCouple the positive supply rail V of the power rail of transformer 30 _IN, and the first auxiliary winding N _A1Then couple the negative supply rail of the power rail of transformer 30, that is be coupled to earth terminal.One switch 35, its series connection first side winding N _P, a current sensing resistor 37 and the first auxiliary winding N _A1, be used for switching transformer 30, wherein switch 35 can be a power electric crystal or be a power metal oxide-semiconductor field effect electric crystal (Metal Oxide Semiconductor FieldEffect Transistor, MOSFET).Because switch 35 of the present utility model and first side winding N _PWith the first auxiliary winding N _A1Be in series, therefore can eliminate the caused high-frequency resonance groove of dominant parasitic device, and then reduce electromagnetic interference.

One current sensing device, for example graphic current sensing resistor 37, its two ends connect the switch 35 and the first auxiliary winding N respectively _A1, with the switch current I of foundation transformer 30 _PProduce a current signal V _CSIn order to adjust an output voltage V of switched-mode power supply adjuster _O, a control circuit 100 couples switch 35 and assists winding N with first of transformer 30 _A1, switch signal V to produce one _PWM, switch signal V _PWMBe used for diverter switch 35 and the output voltage V of adjusting the switched-mode power supply adjuster _OOne supply electric capacity 70, it connects control circuit 100, to control circuit 100, is provided with one first diode 60 between the negative supply rail of supply electric capacity 70 and transformer 30 with power supply.

One buffer circuit 45, it is coupled to first side winding N _PWith positive supply rail V _INBetween, buffer circuit 45 includes buffering diode 40, a buffer capacitor 41 and a buffer resistance 42.One end of buffering diode 40 couples first side winding N _PWith switch 35, buffer capacitor 41 is coupled to the other end and the positive supply rail V of buffering diode 40 _INBetween, buffer resistance 42 then is in parallel with buffer capacitor 41.One bleeder circuit 50, it is coupled to the first auxiliary winding N _A1And between the negative supply rail, bleeder circuit 50 includes resistance 52,55, and resistance 52 is coupled between control circuit 100 and the negative supply rail, and resistance 55 then is coupled to the resistance 52 and the first auxiliary winding N _A1Between.One rectifier 80, the one end couples secondary side winding N _SAn end, and the two ends of a filter capacitor 90 are to be respectively coupled to secondary side winding N _SThe other end and the other end of rectifier 80.

Seeing also Fig. 3, is the equivalent circuit diagram of the switched-mode power supply adjuster of Fig. 2.As shown in the figure, first side winding N _PWith the first auxiliary winding N _A1Leakage inductance L is arranged respectively _I1, L _I2Because the geometrical structure factor of transformer, cause the storage power of the primary side of transformer can not be transferred to other windings of transformer, leakage inductance L fully _I1, L _I2Represent that promptly storage power can't be transferred fully.When switch 35 conductings, switch current I _PIn inflow transformer 30, energy promptly is stored to transformer 30 and leakage inductance L _I1, L _I2In, and when switch 35 ended, transformer 30 stored storage power can be released into secondary side winding N _S, while leakage inductance L _I1, L _I2Stored storage power can be in the loop circulating transfer, if when the loop is blocked, then can produce an abrupt voltage wave, it can be expressed as:

$V=L\&times;\frac{\mathrm{di}}{\mathrm{dt}}---\left(5\right)$

For these reasons, buffer circuit 45 promptly applies to consume leakage inductance L _I1Storage power, to avoid producing a high voltage surging and protection switch 35.The power P that the buffer resistance 42 of buffer circuit 45 is consumed _RCan be expressed as:

$P_R=\frac{{{\mathrm{<figure-callout\; id="42"\; label="V\; R"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">V</figure-callout>}}_R}^2}{{\mathrm{<figure-callout\; id="42"\; label="R"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">R</figure-callout>}}_{42}}=\frac{1}{2}\&times;L_I\&times;{I_{\mathrm{<figure-callout\; id="2"\; label="P"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">P</figure-callout>}}}^2\&times;\mathrm{fsw}---\left(6\right)$

Wherein, R ₄₂Resistance value for buffer resistance 42; V _R42Both end voltage for buffer resistance 42; L _IBe leakage inductance L _I1Inductance value; f _SWSwitching frequency for switch 35.

By above-mentioned equation (6) as can be known, the inductance value that reduces the leakage inductance of transformer 30 will promote the usefulness of switched-mode power supply adjuster, yet in order to allow the switched-mode power supply adjuster meet safety condition, the winding of transformer 30 always can produce a significant leakage inductance value, and the simple and easy method that therefore reduces the leakage inductance value promptly reduces the umber of turn of winding.The relation of inductance value and umber of turn is shown in following equation:

$L=\mathrm{\&mu;}\&times;\frac{0.4\mathrm{\&pi;}\&times;\mathrm{Ae}}{\mathrm{li}}\&times;N^2---\left(7\right)$

Wherein, L is an inductance value; μ is the axle center magnetic capacity; Li is the length of magnetic path; N is a umber of turn; Ae is the axle center sectional area of transformer 30.

The first side winding N of transformer 30 of the present utility model _PWith the first auxiliary winding N _A1Be in series and reduce umber of turn, so can reduce first side winding N _PThe leakage inductance value, to improve the usefulness of switched-mode power supply adjuster.In addition, in case switch 35 by the time, leakage inductance L _I2Storage power will through first diode 60 be released into the supply electric capacity 70, so be stored in leakage inductance L _I2Storage power will be supplied to control circuit 100 as power supply, the voltage V that produced of supply electric capacity 70 _DDCan be expressed as:

$V_{\mathrm{DD}}=[\frac{N_{\mathrm{NA}1}}{N_{\mathrm{NS}}}\&times;(V_O+V_F)]+V_{\mathrm{LI}2}---\left(8\right)$

Wherein, N _NA1With N _NSBe respectively the first auxiliary winding N of transformer 30 _A1With secondary side winding N _SUmber of turn; V _LI2Be leakage inductance V _LI2The voltage that is produced, it is shown in following equation and try to achieve:

$\frac{1}{2}\&times;{\mathrm{<figure-callout\; id="70"\; label="C"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">C</figure-callout>}}_{70}\&times;{{\mathrm{<figure-callout\; id="2"\; label="V\; LI"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">V</figure-callout>}}_{\mathrm{LI}}}^2=\frac{1}{2}\&times;L_{I2}\&times;{I_P}^2---\left(9\right)$

${\mathrm{<figure-callout\; id="2"\; label="V\; LI"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">V</figure-callout>}}_{\mathrm{LI}}=\sqrt{\frac{L_{I2}}{{\mathrm{<figure-callout\; id="70"\; label="C"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">C</figure-callout>}}_{70}}}\&times;I_P---\left(10\right)$

Wherein, C ₇₀Capacitance for supply electric capacity 70; L _I2Be leakage inductance L _I2Inductance value.

Because leakage inductance L _I2The voltage V that is produced _LI2Allow the supply electric capacity 70 voltage V _DDThe secondary side winding N that is higher than transformer 30 _SThe voltage that is reflected, thus switch 35 by the time, rectifier 80 will be unlocked, so the output voltage V of switched-mode power supply adjuster _OCan be via the first auxiliary winding N _A1The so appropriate use first auxiliary winding N is provided to control circuit 100 _A1Leakage inductance L _I2, can improve the load of switched-mode power supply adjuster under underload and the non-loaded state property adjusted.

Seeing also Fig. 4, is the circuit diagram of the control circuit of the utility model preferred embodiment.As shown in the figure, control circuit 100 of the present utility model includes a feed end VDD and an earth terminal GND, and feed end VDD and earth terminal GND supply in parallel electric capacity 70 are to receive power supply.Feed end VDD more connects first diode 60, and earth terminal GND more connects the first auxiliary winding N _A1One detecting voltage end VS, it couples the first auxiliary winding N via bleeder circuit 50 _A1, to be used for the first auxiliary winding N from transformer 30 _A1Detect side one detecting voltage V _DET2, detecting voltage V _DET2Can be expressed as:

${\mathrm{<figure-callout\; id="2"\; label="V\; DET"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">V</figure-callout>}}_{\mathrm{DET}}=\frac{R_{52}}{{\mathrm{<figure-callout\; id="52"\; label="R"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">R</figure-callout>}}_{52}+{\mathrm{<figure-callout\; id="55"\; label="R"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">R</figure-callout>}}_{55}}\&times;V_{\mathrm{AUX}2}---\left(11\right)$

Wherein, R ₅₂With R ₅₅Be respectively the resistance value of resistance 52,55; V _AUX2Be the first auxiliary winding N _A1Voltage.

One current sense end VI, it couples switch 35 and current sensing resistor 37, is used for received current signal V _CSOne output VG, the output that it couples a flip-flop 160 is used for producing switching signal V _PWMTo see through switch 35 switching transformers 30.One oscillator 150, it produces one-period property pulse wave signal and transfers to one of flip-flop 160 sets end, is used for starting switching signal V _PWMOne comparator 125, it is used to close switching signal V _PWMOne negative input end of comparator 25 is to connect current sense end VI, in order to received current signal V _CS, a positive input terminal of comparator 125 then connects an output of an error amplifier 120, in order to receive a back coupling signal V _FB

In case current signal V _CSBe higher than back coupling signal V _FBThe time, switch signal V _PWMTo be cut off.Comparator 125, one output connect a replacement end of flip-flop 160, in order to produce a replacement signal V _RSTAnd be sent to the replacement end of flip-flop 160, with by switching signal.Error amplifier 120, it is used for producing back coupling signal V _FB, a positive input terminal of error amplifier 120 receives a reference voltage V _R, a negative input end of error amplifier 120 then connects an output of a sampling stick holding circuit 110, to receive a sample signal V _S, be used for producing back coupling signal V _FBSampling stick holding circuit 110, one input end couples detecting voltage end VS, in order to see through bleeder circuit 50 from this detecting voltage of transformer 30 detectings V _DET2, to produce sample signal V _S

The first auxiliary winding N _A1Voltage V _AUX2With secondary side winding N _SVoltage (V _O+ V _F) between the relation, can be expressed as:

$V_O+V_F=\frac{N_{\mathrm{<figure-callout\; id="1"\; label="NS\; N\; NA"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">NS</figure-callout>}}}{N_{\mathrm{NA}}}\&times;V_{\mathrm{AUX}2}---\left(12\right)$

According to equation (11) and (12), output voltage V _OCan be expressed as:

$V_O=(\frac{{\mathrm{<figure-callout\; id="52"\; label="R"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">R</figure-callout>}}_{52}+R_{55}}{{\mathrm{<figure-callout\; id="52"\; label="R"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">R</figure-callout>}}_{52}}\&times;\frac{N_{\mathrm{<figure-callout\; id="1"\; label="NS\; N\; NA"\; filenames="Y20062011357300231.png"\; state="\{\{state\}\}">NS</figure-callout>}}}{N_{\mathrm{NA}}}\&times;V_{\mathrm{DET}2})-V_F---\left(13\right)$

Can learn the output voltage V of switched-mode power supply adjuster by equation (13) _OBe to be adjusted.

Seeing also Fig. 5, is the circuit diagram of switched-mode power supply adjuster of the primary side control of another preferred embodiment of the utility model.As shown in the figure, the transformer 38 of this embodiment comprises first side winding N _P, the first auxiliary winding N _A1With one second auxiliary winding N _A2, the second auxiliary winding N of transformer 38 _A2Be to connect the first auxiliary winding N _A1, the second auxiliary winding N _A2More connect supply electric capacity 70 via one second diode 65.The earth terminal GND of control circuit 100 then connects the first auxiliary winding N _A1With the second auxiliary winding N _A2, and feed end VDD connects supply electric capacity 70, first diode 60 and second diode 65.

When switch 35 ends, because the first auxiliary winding N _A1With power supply to control circuit 100, so the voltage V that produced of supply electric capacity 70 _DDIt is output voltage V with the switched-mode power supply adjuster _ORelevant, if the switched-mode power supply adjuster produces output voltage V under the situation of overcurrent and/or short circuit _O, the first auxiliary winding N _A1Voltage V _AUX2Will be too low and be unable to supply enough power supplys to control circuit 100.Therefore the utility model is to set up the second auxiliary winding N _A2, when switch 35 conductings, the second auxiliary winding N _A2Will be to 70 chargings of supply electric capacity, so the second auxiliary winding N _A2Can provide a second source with power supply to control circuit 100, but it is to guarantee control circuit 100 still normal operation under the situations such as fault of overcurrent and/or short circuit.

Seeing also Fig. 6, is the circuit diagram of switched-mode power supply adjuster of the primary side control of the another preferred embodiment of the utility model.As shown in the figure, the transformer 39 of this embodiment comprises first side winding N _P, an inductance 32 and one the 3rd auxiliary winding N _A3, inductance 32 is connected between current sensing resistor 37 and the negative supply rail, and inductance 32 more sees through first diode 60 and is connected in supply electric capacity 70.The 3rd auxiliary winding N of transformer 39 _A3Be to see through second diode 65 and connection supply electric capacity 70, the three auxiliary winding N _A3More be connected with inductance 32.One bleeder circuit 56 includes two resistance 58,59, and bleeder circuit 56 is coupled to the 3rd auxiliary winding N _A3And between the inductance 32, resistance 58 is coupled in the 3rd auxiliary winding N _A3, 59 of resistance and resistance 58 and inductance 32 are in series.The detecting voltage end VS of control circuit 100 is connected between the resistance 58,59, and the earth terminal GND of control circuit 100 then is connected in the 3rd auxiliary winding N _A3With inductance 32.The inductance 32 of this embodiment is to be used for providing power supply to control circuit 100 via first diode 60 when switch 35 ends, so the 3rd auxiliary winding N _A3With inductance 32 is to be used to provide power supply to control circuit 100, so will increase the load control of switched-mode power supply adjuster under underload and no-load condition.

In sum, the winding set-up mode of transformer of the present utility model, it is the inductance value that can reduce leakage inductance, the storage power of the storage power of this external inductance or the leakage inductance of auxiliary winding can be used for power supply to control circuit, so can reach preferable usefulness and can promote the load of switched-mode power supply adjuster under underload and the no-load condition property adjusted.In addition, because switch is arranged between two windings of transformer, so can reduce electromagnetic interference.

The above, it only is the utility model one preferred embodiment, be not to be used for limiting the scope that the utility model is implemented, so the equalization of doing according to the described shape of the utility model claim, structure, feature and spirit changes and modifies such as, all should be included in the claim of the present utility model.

Claims (18)

1, a kind of switched-mode power supply adjuster of primary side control is characterized in that it includes:

One transformer shifts the secondary side of energy to this transformer from a primary side of this transformer, and this transformer is provided with a first side winding and an auxiliary winding, and this first side winding couple a positive supply rail and a negative supply rail respectively with assisting winding;

One switch, itself and this first side winding assists winding to be in series with being somebody's turn to do, and is used to switch this transformer;

One control circuit couples this switch and should assist winding, produces one and switches signal, is used to switch this switch and the output of adjusting this switched-mode power supply adjuster;

One supply electric capacity connects this control circuit, and power supply is to this control circuit;

One diode couples this negative supply rail and this supply electric capacity to this supply electric capacity charging.

2, switched-mode power supply adjuster as claimed in claim 1, it is characterized in that, more include a current sensing device, it is connected this switch and should assists between the winding, this current sensing device switches electric current according to one of this transformer and produces a current signal, and this control circuit receives this current signal and produces this switching signal.

3, switched-mode power supply adjuster as claimed in claim 1 is characterized in that, this auxiliary winding has a leakage inductance, and this leakage inductance stores a storage power when this switch conduction, and when this switch ended, this leakage inductance discharged this storage power and supplies electric capacity to this.

4, switched-mode power supply adjuster as claimed in claim 1 is characterized in that, this control circuit more includes:

One feed end connects this supply electric capacity and this diode;

One earth terminal connects this supply electric capacity and receives power supply, and this earth terminal more connects this auxiliary winding;

One detecting voltage end couples this auxiliary winding, detects a voltage;

One current sense end couples this switch, receives a current signal;

One output produces this switching signal according to this voltage and this current signal, switches this switch and switches this transformer.

5, switched-mode power supply adjuster as claimed in claim 4 is characterized in that, this control circuit more includes:

One sampling stick holding circuit couples this detecting voltage end, detects this voltage, produces a sample signal;

One error amplifier couples this sampling stick holding circuit, receive this sample signal with

One reference voltage produces a back coupling signal;

One comparator couples this error amplifier and this current sense end, receives this back coupling signal and this current signal, produces a replacement signal;

One oscillator produces one-period property pulse wave signal;

One flip-flop couples this oscillator, this comparator and this output, produces this switching signal, and this periodic pulses signal and this replacement signal start respectively and end this switching signal.

6, a kind of switched-mode power supply adjuster of primary side control is characterized in that it includes:

One transformer, shift the secondary side of energy from a primary side of this transformer to this transformer, this transformer is provided with a first side winding, one first auxiliary winding and one second auxiliary winding, this first side winding and this first auxiliary winding couple a positive supply rail and a negative supply rail respectively, and this second auxiliary winding couples this first auxiliary winding;

One switch, itself and this first side winding is in series with this first auxiliary winding, is used to switch this transformer;

One control circuit couples this switch and this first auxiliary winding, produces one and switches signal, is used to switch this switch and the output of adjusting this switched-mode power supply adjuster;

One supply electric capacity connects this control circuit, and power supply is to this control circuit;

One first diode couples this negative supply rail and this supply electric capacity to this supply electric capacity charging;

One second diode couples this second auxiliary winding and this supply electric capacity to this supply electric capacity charging.

7, switched-mode power supply adjuster as claimed in claim 6, it is characterized in that, more include a current sensing device, it is connected between this switch and this first auxiliary winding, this current sensing device switches electric current according to one of this transformer and produces a current signal, and this control circuit receives this current signal and produces this switching signal.

8, switched-mode power supply adjuster as claimed in claim 6, it is characterized in that this first auxiliary winding has a leakage inductance, this leakage inductance stores a storage power when this switch conduction, when this switch ended, this leakage inductance discharged this storage power and supplies electric capacity to this.

9, switched-mode power supply adjuster as claimed in claim 6 is characterized in that, this control circuit more includes:

One feed end connects this supply electric capacity, this first diode and this second diode;

One earth terminal connects this supply electric capacity and receives power supply, and this earth terminal more connects this first auxiliary winding and second assists winding with this;

One detecting voltage end couples this first auxiliary winding, detects a voltage;

One current sense end couples this switch, receives a current signal;

One output produces this switching signal according to this voltage and this current signal, switches this switch and switches this transformer.

10, switched-mode power supply adjuster as claimed in claim 9 is characterized in that, this control circuit more includes:

One sampling stick holding circuit couples this detecting voltage end, detects this voltage, produces a sample signal;

One error amplifier couples this sampling stick holding circuit, receives this sample signal and a reference voltage, produces a back coupling signal;

One comparator couples this error amplifier and this current sense end, receives this back coupling signal and this current signal, produces a replacement signal;

One oscillator produces one-period property pulse wave signal;

One flip-flop couples this oscillator, this comparator and this output, produces this switching signal, and this periodic pulses signal and this replacement signal start respectively and end this switching signal.

11, a kind of switched-mode power supply adjuster of primary side control is characterized in that it includes:

One transformer is provided with a first side winding and an auxiliary winding, and this first side winding coupled a power rail of this switched-mode power supply adjuster with assisting winding;

One switch, itself and this first side winding assists winding to be in series with being somebody's turn to do, and is used to switch this transformer;

One control circuit couples this switch and this transformer, produces one and switches signal, is used to switch this switch and the output of adjusting this switched-mode power supply adjuster;

One supply electric capacity connects this control circuit;

One diode couples this transformer and this supply electric capacity to this supply electric capacity charging.

12, switched-mode power supply adjuster as claimed in claim 11, it is characterized in that, more include a current sensing device, it is connected this switch, this current sensing device switches electric current according to one of this transformer and produces a current signal, and this control circuit receives this current signal and produces this switching signal.

13, switched-mode power supply adjuster as claimed in claim 11, it is characterized in that this transformer has at least one leakage inductance, this leakage inductance stores a storage power when this switch conduction, when this switch ended, this leakage inductance discharged this storage power and supplies electric capacity to this.

14, switched-mode power supply adjuster as claimed in claim 11 is characterized in that, this control circuit more includes:

One feed end connects this supply electric capacity and this diode;

One earth terminal connects this supply electric capacity and this transformer;

One detecting voltage end couples this transformer, detects a voltage;

One current sense end couples this switch, receives a current signal;

One output produces this switching signal according to this voltage and this current signal, switches this switch and switches this transformer.

15, a kind of switched-mode power supply adjuster of primary side control is characterized in that it includes:

One transformer is provided with a first side winding and an auxiliary winding, and this first side winding couples a positive supply rail;

One inductance couples a negative supply rail and should assist winding;

One switch, itself and this first side winding is in series with this inductance, is used to switch this transformer;

One control circuit couples this switch and should assist winding, produces one and switches signal, is used to switch this switch and the output of adjusting this switched-mode power supply adjuster;

One supply electric capacity connects this control circuit;

One first diode couples this inductance and this supply electric capacity to this supply electric capacity charging;

One second diode couples this transformer and this supply electric capacity to this supply electric capacity charging.

16, switched-mode power supply adjuster as claimed in claim 15, it is characterized in that, more include a current sensing device, it is connected this switch, this current sensing device switches electric current according to one of this transformer and produces a current signal, and this control circuit receives this current signal and produces this switching signal.

17, switched-mode power supply adjuster as claimed in claim 15 is characterized in that, this control circuit more includes:

One feed end connects this supply electric capacity, this first diode and this second diode;

One earth terminal connects this supply electric capacity, this inductance and should assist winding;

One detecting voltage end couples this transformer, detects a voltage;

One current sense end couples this switch, receives a current signal;

One output produces this switching signal according to this voltage and this current signal, to switch this switch and to switch this transformer.

18, switched-mode power supply adjuster as claimed in claim 17 is characterized in that, this control circuit more includes:

One sampling stick holding circuit couples this detecting voltage end, detects this voltage, produces a sample signal;

One error amplifier couples this sampling stick holding circuit, receives this sample signal and a reference voltage, produces a back coupling signal;

One comparator couples this error amplifier and this current sense end, receives this back coupling signal and this current signal, produces a replacement signal;

One oscillator produces one-period property pulse wave signal;

One flip-flop couples this oscillator, this comparator and this output, produces this switching signal, and this periodic pulses signal and this replacement signal start respectively and end this switching signal.

Images