CN103248236A - Ringing choke converter - Google Patents

Abstract

The invention discloses a ringing choke converter which is characterized in that the ringing choke converter is provided with a driving compensation circuit having a self-regulating function, wherein the driving compensation circuit is connected between a corresponding terminal of a positive feedback winding of a main transformer and a soft start circuit; when a main power switch tube is conducted, the driving compensation circuit enters a conducting working state; the positive feedback winding charges the soft start circuit quickly through the driving compensation circuit; the compensation intensity is regulated automatically according to a compensation requirement, so that the soft start circuit provides driving energy for the main power switch tube continuously and reasonably; when the main power switch tube is cut off, the driving compensation circuit enters a turn-off working state; and the positive feedback winding and the soft start circuit are disconnected. The ringing choke converter achieves a soft start function, and provides driving compensation having self-regulating capacity for normal working of a product; the driving capacity of the product is improved reasonably; and the anti-interference capacity and the stability of the product are improved.

Description

A kind of self-oscillation anti exciting converter

Technical field

The present invention relates to a kind of self-oscillation anti exciting converter, particularly a kind of self-oscillation anti exciting converter that drives the compensate function soft starting circuit with constant-current source self-regulation.

Background technology

Self-oscillation flyback converter (Ringing Choke Converter) is because its design cost is lower, has the stronger market competitiveness and enjoys designer's favor; Yet the quality of its output characteristic depends on the consistency of each discrete component to a great extent, and when the consistency of components and parts such as transformer, main switch, control triode, optocoupler is more good, its output performance is also more stable.Therefore reduce self-oscillation inverse-excitation converting circuit (RCC) to the conforming harsh requirement of discrete device, improve its output voltage stability and become the emphasis that the designer considers.The designer adopts bias compensation circuit (the control transistor base adds the shutoff compensation) more at present, the stability of its output voltage obtains raising to a certain degree, yet this scheme debugging difficulty is big, consistency of product is still relatively poor, especially increases, influences when output capacitive loading increases more obvious in power output.

The comparatively desirable circuit form of a kind of self-oscillation anti exciting converter (RCC) is disclosed among the Chinese invention patent ublic specification of application CN101997423A, as shown in Figure 1, this self-oscillation anti exciting converter mainly comprises filtering part, soft start part, metal-oxide-semiconductor, transformer, pulse frequency modulated part (PFM), accessory power supply, isolation optocoupler, voltage stabilizing output loop part.The input electric weight connects the output loop part through transformer, soft start partly connects the grid of metal-oxide-semiconductor, the grid of metal-oxide-semiconductor also connects the pulse frequency modulated part, accessory power supply connects the pulse frequency modulated part, the indirection reference amplifier section of pulse frequency modulated part and voltage stabilizing output loop part, isolation optocoupler form voltage negative feedback loop.

The soft starting circuit of above-mentioned anti exciting converter, improved the stability of output voltage when product starts, its operation principle is: after input powers on, soft starting circuit voltage raises, the metal-oxide-semiconductor conducting, output voltage rises gradually, before system enters stable state, soft starting circuit continues as metal-oxide-semiconductor the driving energy is provided, and soft starting circuit voltage reduces gradually simultaneously; After system's operate as normal since the soft starting circuit charging interval much larger than discharge time, soft starting circuit remains at than electronegative potential (during the starting up, the soft start voltage waveform is seen Fig. 6).The shortcoming of this soft starting circuit is: during stable state, capacitor C 9 velocities of discharge are far faster than charging rate in the soft starting circuit, its voltage to earth is seen Fig. 6 near 1V(), therefore metal-oxide-semiconductor drives the feedback winding energy that places one's entire reliance upon, to the metal-oxide-semiconductor undercompensation, the product output performance is subjected to influences such as transformer technology (feedback and input degree of coupling), metal-oxide-semiconductor turn-on threshold, the external capacitive load of output easily during the soft starting circuit operate as normal.When increasing charging rate, be subjected to wide input voltage range and output loading variation influence greatly, overcompensation appears easily, cause shortcomings such as power supply starting up current limliting and product output short-circuit power consumption are big.

Fig. 2 is the circuit theory diagrams of a disclosed embodiment among the Chinese invention patent ublic specification of application CN101997423A, comprises input filter circuit 11, soft starting circuit 12, pulse frequency modulation circuit 13, main power circuit 14, auxiliary power circuit 15, output filter circuit 16, isolates optocoupler OC1, error amplification ADJ circuit 17.Input filter circuit 11 is made up of filter capacitor C0, filter capacitor C1 and filter inductance L0, has formed π type filter circuit.Capacitor C 0 connects power input, other end ground connection, and inductance L 0 connects power input, another termination transformer end of the same name, the termination transformer end of the same name of capacitor C 1, other end ground connection.Also can adopt other existing filter circuit, specifically can be selected by the relevant technologies handbook.Soft starting circuit 12 comprises: divider resistance R10, resistance R 13, resistance R 14 and startup capacitor C 9.Resistance R 10, resistance R 13, resistance R 14 are connected successively, a termination power input of series circuit, an end ground connection.One termination of capacitor C 9 is gone into the node of connecting of resistance R 10 and resistance R 13, other end ground connection.Its operation principle is for when inserting input voltage, and electric current is through 9 chargings of 10 pairs of capacitor C of resistance R, elapsed time

Back capacitance voltage reaches the MOS threshold voltage, realizes the start soft start function; When metal-oxide-semiconductor turn-offs, the feedback winding is reverse, terminal potential of the same name is for negative, therefore the metal-oxide-semiconductor current potential is also for negative, this moment, capacitor C 9 was by resistance R 13 repid discharges, when the metal-oxide-semiconductor conducting, input voltage charges to capacitor C 9 by resistance R 10, because the resistance of resistance R 10 is far longer than the resistance of resistance R 13 (when the R10 value reduces, product output short-circuit power consumption increases, and starting current increases, and table two has exemplified the deficiency of bringing when the R10 value reduces), therefore the velocity of discharge finishes through back capacitor C 9 energy release after a while far faster than charging rate.Pulse frequency modulation circuit 13 comprises: resistance R 6, resistance R 9, resistance R 11, resistance R 111, capacitor C 5, capacitor C 6, capacitor C 12, NPN type triode TR2, positive-negative-positive triode TR3, feedback winding P3.Capacitor C 6 is connected successively with resistance R 11, resistance R 111, resistance R 6, and a termination of series circuit goes into to feed back the end of the same name of winding P3, and the other end inserts the collector electrode of triode TR2.Capacitor C 5 is in parallel with resistance R 9, and a termination of parallel circuits is gone into the base stage of triode TR2, and the other end inserts the collector electrode of triode TR3.Capacitor C 12 is in parallel with resistance R 111, and a termination of parallel circuits is gone into the emitter of triode TR3, and the other end inserts the collector electrode of triode TR3.Its operation principle is: feedback winding P3, capacitor C 6, resistance R 11 branch roads constitute the self-oscillation loop by being coupled with the former secondary of master power switch pipe TR1, and the conducting of control switch pipe is turn-offed; Electric current loop R5 branch road, Voltage loop optocoupler branch road make product output normal by two-tube Drive and Control Circuit TR2, TR3 by-pass cock pipe conducting duty ratio simultaneously.Main power circuit 14 comprises: the former limit of transformer winding P1, output winding P2, and metal-oxide-semiconductor TR1, output rectifier diode D1 realizes that conversion, transmission and input and the output of power supply energy is isolated.Accessory power supply 15 comprises: winding P3, diode D3, and its operation principle is, and feedback winding end of the same name is timing, and diode D3 conducting is for optocoupler provides energy.Output filter circuit 16 comprises filter capacitor C3, also can adopt other existing filter circuit, specifically can be selected by the relevant technologies handbook.Isolating optocoupler comprises: optocoupler OC1, it mainly finishes transmission and the input and output buffer action of signal.Error is amplified ADJ circuit 17 and comprised: sample circuit, signal be amplifying circuit relatively.Its operation principle is: output voltage floats when high, and sample circuit is gathered signal and relatively regulated the optocoupler primary current behind the amplifying circuit through signal, namely regulates the duty ratio of product by Voltage loop.There is flow through sample circuit, error of a sampling current to amplify, the main switch in the main power circuit is carried out negative feedback control after isolating optocoupler, pulse frequency modulated PFM circuit at the output of power supply; Output at input filter circuit is connected with a soft starting circuit, and this soft starting circuit other end and pulse frequency modulated PFM are connected to realize the soft start function of power supply.

The shortcoming of foregoing circuit is:

1) product the startup stage, band is fully loaded, especially during large capacitive load, can not enter stable state, the product output abnormality; After the foregoing circuit start, need be through vibration after a while, product just can enter stable state; In unstable state period, feedback winding energy a little less than, rely on capacitor C 9 compensation energy this moment, (capacitor C 9 start voltage waveforms are seen Fig. 6 yet capacitor C 9 voltages begin after the metal-oxide-semiconductor conducting period 1 to descend, its voltage descends gradually after the metal-oxide-semiconductor conducting), provide energy more and more a little less than, so this circuit is in full load, underload, especially during large capacitive load, vibration easily, it is on the low side to show as output voltage.When output band capacitive load, the product output voltage rising rise time is elongated, it is that WRB4805D, power are the supply convertor operate as normal of 3W and the output voltage waveforms during with 1000 μ f electric capacity that Figure 10 has contrasted model, wherein CH1 is the operate as normal waveform, rise time is about 0.5ms, CH2 is the work wave with 1000 μ f electric capacity, rise time is about 3.7ms, Voltage loop was not in runaway condition when output voltage was formally set up, this moment, metal-oxide-semiconductor drove if can not obtain adequate remedy, the easy failure of oscillation of feedback winding shows as poor starting.Below introduce this phase process in detail: be that the supply convertor of 3W is example with existing WRB4805D, power, its start-up circuit parameter has been taken into account key performances such as short-circuit dissipation, starting current, circuit theory is seen Fig. 2, each parameter value is as follows in this soft starting circuit 12: R10=332 Κ Ω, R13=3.3 Κ Ω, R14=150 Κ Ω, C9=1 μ f, the feedback winding drives branch road R11=100 Ω in the control circuit 13, C6=4700PF, main power circuit 14 parts, each parameter of its transformer T1 is: Np=25, Ns=7, Nf=8.Product is in the starting stage of metal-oxide-semiconductor conducting, the feedback winding voltage is less, this stage G electrode potential is almost nil, so unstable state discharge time constant in period can be approximately T2 ≈ R13*C9 ≈ 3.3ms, charge constant T1 ≈ R14*C9=332ms again, so unstable state period, capacitor C 9 current potentials descend gradually after the metal-oxide-semiconductor conducting, and Fig. 6 has shown the voltage waveform on (test condition: underloading Io=0.06A, high pressure 72V test) capacitor C 9, after the metal-oxide-semiconductor conducting, capacitance voltage descends gradually.Above-mentioned parameter R10 value is 332 Κ Ω, has taken into account starting up's electric current and the output short-circuit power consumption of product.Table one has exemplified input voltage 36V, 48V, 72V, the power supply starting up irreducible minimum flow valuve when being fully loaded with Io=0.6A and the output short-circuit power consumption under the each point condition.

Table one

Test event	Low pressure 36V	Nominal 48V	High pressure 72V
				Output short-circuit power consumption (W)	0.36	0.48	0.72
Operate as normal is fully loaded with input current (mA) Iin	107	84	64
				Start minimum limit electric current (mA) I Limit	135	135	135
Starting current multiple (I Limit/Iin）	1.262	1.607	2.109

Table two has exemplified R10 when getting 332 Κ Ω, the average voltage of capacitor C 9 under different loads and input voltage condition.

Table two

As can be seen from Table I, product starting current, short-circuit dissipation are all less, and maximum short-circuit dissipation is 0.72W only; As can be seen from Table II, when the R10 value was big, Vc9 change in voltage scope was big, and to the compensation intensity instability that metal-oxide-semiconductor drives, it is the poorest to compensate when nominal is unloaded, and voltage is 0.886V only.When the R10 value diminishes, its charge constant T1=R10*C9 reduces, the energy compensating of capacitor C 9 strengthens, owing to reduce R10, its compensation intensity is not easy control, especially is difficult to take into account the compensation intensity of each point at input voltage, product that the load variations scope is big, and its shortcoming of bringing is: 1) starting up's electric current becomes big by 2) short-circuit dissipation increases, especially short-circuit dissipation increases obviously when high pressure, and product is burnt when serious.After table three has exemplified and has changed R10 into 50 Κ Ω by 332 Κ Ω, output short-circuit power consumption and the starting current of product.Table four has exemplified the average voltage of capacitor C 9 under this condition.

Table three

Test event	Low pressure 36V	Nominal 48V	High pressure 72V
				Output short-circuit power consumption (W)	2.664	3.168	4.032
Operate as normal is fully loaded with input current (mA) Iin	107	84	64
				Start minimum limit electric current (mA) I Limit	247	255	255
Starting current multiple (I Limit/Iin）	2.308	3.035	3.984

Table four

As can be seen from Table III: 1) all more former scheme increases of short-circuit dissipation, reach 3.96W during high pressure, long-time short circuit will damage product 2) starting current increases obviously, and especially the more former scheme of starting current increases nearly 1.88 times, startup current limliting when may cause the client to use this moment during high pressure.After table four is R10 value 50 Κ Ω, under different loads and the voltage conditions, the average voltage level of C9, after this table demonstration reduces R10, capacitor C 9 change in voltage under each loading condition is bigger, and maximum voltage is 12.8V, and minimum voltage is 4.51V only, it compensated strong, caused the product starting current big and short-circuit dissipation is big.On former scheme basis, change R13 into 7.5 Κ Ω by 3.3 Κ Ω after, the starting up is bad for nominal full load product, so discharge time constant allows to change less.To sum up, change the R10 value, it drives the compensation poor stability to metal-oxide-semiconductor, occurs overcompensation and undercompensation easily.

2) during stable state, under the high pressure underloading condition, capacitor C 9 velocities of discharge are faster than charging rate in the soft starting circuit, its voltage to earth is seen Fig. 6 near 1V(, underloading Io=0.06A, high pressure 72V test), so metal-oxide-semiconductor drives and almost completely depends on feedback winding energy, and this moment, the quality of product output performance depended on the coupling performance of two point: a, feedback winding and former limit winding; B, output loading.When feedback winding and input are coupled variation, under its couple drive energy variation, particularly input voltage saltus step condition, drive energy shortage, cause the product vibration easily; When output loading diminishes (below 10% load), feedback winding energy descends greatly, and its driving energy (couple current) also reduces, and product drives and enters the batch (-type) vibration, and it is on the low side to show as output voltage.When below introducing the high pressure underloading in detail, the course of work of product: be that the supply convertor of 3W is example with existing WRB4805D, power, its start-up circuit parameter has been taken into account key performances such as short-circuit dissipation, starting current, circuit theory is seen Fig. 2, each parameter value is as follows in this soft starting circuit 12: R10=332 Κ Ω, R13=3.3 Κ Ω, R14=150 Κ Ω, C9=1 μ f, the feedback winding drives branch road R11=100 Ω, C6=4700PF in the control circuit 13, main power circuit 14 parts, each parameter of its transformer T1 is: Np=25, Ns=7, Nf=8.Under the limit, (corresponding metal-oxide-semiconductor shutoff) end voltage to earth of the same name when the feedback winding is reverse

=-4.375V, because capacitor C 6 and metal-oxide-semiconductor GS junction capacitance Ciss(adopt its junction capacitance of IRFR220 metal-oxide-semiconductor Ciss to be about 300PF) the appearance value is little, and resistance R 11 values only are 100 Ω, when therefore metal-oxide-semiconductor turn-offs, the feedback winding is reverse, metal-oxide-semiconductor Ciss storage power discharges by PNP triode TR3 on the one hand, on the other hand by driving branch road R11, C6 discharges to feedback winding end of the same name, showing as metal-oxide-semiconductor Vgs current potential is dragged down rapidly, measured waveform is seen Fig. 7 (test condition: Vin=36V, Io=0.6A), from waveform as can be seen, metal-oxide-semiconductor off-phases Vgs ≈-0.9V.Therefore off-phases capacitor C 9 is discharged to the G utmost point by resistance R 13; The product switching frequency is more high, duty ratio is more little, be that the interior turn-off time of unit interval is long, therefore high frequency condition C9 is long discharge time, himself current potential is also lower, Fig. 6 has tested voltage waveform (the high pressure 72V on the C9 electric capacity, output loading 0.06A), after the metal-oxide-semiconductor conducting, capacitance voltage begins to descend as can be seen from this figure, and capacitance voltage has only 1V after the stable state, its corresponding drive waveforms is seen Fig. 8, T ≈ 1.07 μ s wherein, effectively ON time Ton ≈ 0.01 μ s(driving voltage is effective high level, i.e. Vgs greater than opening thresholding〉3.3V), D=0.0093, namely the time of metal-oxide-semiconductor 99.06% is in off state under this condition, therefore effectively discharge time constant T2 ≈ R13*C9=3.3ms, its charge constant T1=R10*C9=332ms again, thus T2＜＜T1.When reducing charge constant R10, increase R13 value, its shortcoming of bringing is same as above, does not repeat them here.

3) when extraneous factor interference control signal (for example static), switching tube is thoroughly closed within a short period of time, after disturbing disappearance, product needed can enter steady operation through soft start charging, metal-oxide-semiconductor conducting to two periods of output normal (being generally output rise time 0.5ms), this moment, output showed as the power down phenomenon.Fig. 9 tested WRB4805D, power be the supply convertor of 3W under high pressure, light-load conditions, after the input 4KV electrostatic interference, output power down waveform, when this waveform showed input static, product was exported easy power down, disturbed client to restart when serious.Below introduce the power down reason in detail: circuit theory is seen Fig. 2, starts 12 parts, and R10=332 Κ Ω, C9 get 1 μ f, R13=3.3 Κ Ω; Switching tube adopts IRFR220, and looking into its thresholding of specifications is 2V-4V, surveys its turn-on threshold V (th)=3.3V, so the fastest start-up time during Vin=36V =31.91ms, because the metering function of R13, can be longer than above-mentioned calculated value actual start-up time slightly, actual measurement is about 35ms, and therefore after electrostatic interference was turn-offed metal-oxide-semiconductor, product was if restart through soft starting circuit, then the turn-off time must be elongated, and product output shows as the power down phenomenon.This scheme reduces the R10 value, can strengthen the soft start compensation ability, reduce the power down risk, yet be subjected to input voltage and the big influence of load variations scope, reduce R10 and be difficult to compensation under compatible different input voltage point and the loading condition, bring when compensation intensity is excessive that short-circuit dissipation increases, starting current increases, compensate and to address the above problem again when too small.

Summary of the invention

The purpose of this invention is to provide a kind of self-oscillation anti exciting converter, when realizing soft start function, for the product operate as normal provides the compensation of the driving with self-adjusting ability, rationally strengthen the product driving force, improve product antijamming capability and stability.

The objective of the invention is to realize by following technical measures:

A kind of self-oscillation anti exciting converter, comprise that following circuit connects: direct-flow input signal passes through input filter circuit successively, export direct current signal behind main power circuit and the output filter circuit, main power circuit comprises master power switch pipe and main transformer, the direct current signal of output passes through voltage stabilizing circuit successively, isolation optocoupler and Drive and Control Circuit are carried out negative feedback to the master power switch pipe and are controlled to realize stable output, between the output of input filter circuit and Drive and Control Circuit, be connected with soft starting circuit, also comprise the driving compensating circuit with self-regulating function, this driving compensating circuit is connected between the end of the same name and described soft starting circuit of described main transformer positive feedback winding; During described master power switch pipe conducting, drive compensating circuit and enter the conducting operating state, described positive feedback winding is given described soft starting circuit quick charge by driving compensating circuit, simultaneously according to compensation needs self-regulation compensation intensity, make described soft starting circuit continue, reasonably provide the driving energy for described master power switch pipe, when described master power switch pipe ends, drive compensating circuit and enter the shutoff operating state, be equivalent to open circuit between described positive feedback winding and the soft starting circuit.

As one embodiment of the present invention, described driving compensating circuit with automatic regulatory function comprises diode and constant-current source, the anode of described diode is connected to the end of the same name of described main transformer positive feedback winding, the negative electrode of described diode is connected with the positive pole of constant-current source, and the negative pole of described constant-current source is connected to the Voltage Reference end of self-oscillation anti exciting converter by described soft starting circuit.

As one embodiment of the present invention, described driving compensation intensity conditioned circuit also comprises constant-current source; The constant-current source negative pole is connected the anode of described diode, and the constant-current source positive pole links to each other with the end of the same name of main transformer positive feedback winding, and diode cathode is connected to the Voltage Reference end of self-oscillation anti exciting converter by described soft starting circuit.

Described constant-current source can be by the multiple mode of forming, and described constant-current source can be single constant-current source, or the constant-current source parallel form, or the constant-current source that is composited of constant-current source and triode, voltage-stabiliser tube, resistance, or the constant-current source that constitutes of triode and resistance.

Compared with prior art, the present invention has the following advantages:

One of advantage of the present invention: improve the converter product and start ability and band capacitance load capability, product can normally be started and steady operation when full load and large capacitive load.It is that WRF4815P, power are the former scheme and the capacitance load capability contrast of adopting after the technical solution of the present invention of the supply convertor of 6W that table five has been enumerated model.

Table five

From table five as can be seen, adopt technical scheme of the present invention after, converter product tape capacitance load capability improves greatly.

Two of advantage of the present invention: improve the product antijamming capability, efficiently solve output power down phenomenon.Adopting model in the experiment is that WRB4805D, power are that the supply convertor product of 3W is the single-chip microcomputer power supply, and when input was beaten 4KV static, single-chip microcomputer resetted, this supply convertor output power down; After adopting technical scheme of the present invention to improve, input is beaten 4KV static, and the output of converter product is normal, and single-chip microcomputer is working properly.

Three of advantage of the present invention: in full load, full input voltage range, soft starting circuit obtains to continue, reasonably power supply, and then provides suitable driving compensation for metal-oxide-semiconductor; This scheme is in the product of 2:1 series at input voltage especially, and its compensation effect is comparatively desirable, has overcome the shortcoming of former scheme undercompensation and overcompensation.After table six had been enumerated and adopted the constant-current source of 0.6mA, model was that WRB4805D, power are short-circuit dissipation, the startability of the supply convertor of 3W.

Table six

Test event	Low pressure 36V	Nominal 48V	High pressure 72V
				Output short-circuit power consumption (W)	1.08	0.768	0.864
Operate as normal is fully loaded with input current (mA) Iin	107	84	64
				Start minimum limit electric current (mA) I Limit	135	135	135
Starting current multiple (I Limit/Iin）	1.262	1.607	2.109

Contrast table three, its short-circuit dissipation descends greatly as can be seen, and product possesses long-time short-circuit protection function; The starting current of each input voltage point all reduces than table three, reduces 120mA during nominal, reduces amplitude 88.88%, reduces client starting up power supply current limliting risk.

Description of drawings

The present invention is described in further detail below in conjunction with the drawings and specific embodiments:

Fig. 1 is the theory diagram of self-oscillation anti exciting converter in the prior art;

Fig. 2 is the circuit theory diagrams of self-oscillation anti exciting converter in the prior art;

Fig. 3 is the theory diagram of self-oscillation anti exciting converter of the present invention;

Fig. 4 is the circuit theory diagrams of the embodiment of the invention one;

Fig. 5 is the circuit theory diagrams that drive the compensating circuit part in the embodiment of the invention two;

Fig. 6 is for starting the voltage oscillogram of capacitor C 9 in the soft starting circuit of self-oscillation anti exciting converter;

Fig. 7 is that WRB4805D, power are the supply convertor low pressure of 3W, the Vgs drive waveforms figure of full load for model;

Fig. 8 is WRB4805D, the power Vgs drive waveforms figure when being supply convertor underloading, the high pressure of 3W for model;

Fig. 9 is that WRB4805D, power are the supply convertor input of 3W when beating 4KV static for model, the voltage waveform of output;

Figure 10 is that WRB4805D, power are the supply convertor of 3W output voltage rising waveform when not being with capacitive load and being with 1000 μ f capacitive loads for model;

Figure 11 is the constant-current source parallel form;

Figure 12 is the compound constant-current source of constant-current source, resistance, voltage-stabiliser tube, triode formation;

Figure 13 is the constant-current source that PNP triode, resistance constitute;

Figure 14 is the single tube Drive and Control Circuit.

Embodiment

The present invention is described in further detail below in conjunction with the drawings and specific embodiments.

As shown in Figure 3, self-oscillation anti exciting converter of the present invention, comprise that following circuit is formed and connection: direct-flow input signal is exported direct current signal through behind input filter circuit, main power circuit and the output filter circuit successively, and main power circuit comprises master power switch pipe and main transformer; The direct current signal of output successively by voltage stabilizing circuit, isolate optocoupler and Drive and Control Circuit and the master power switch pipe is carried out negative feedback control to realize stable output, between the output of input filter circuit and Drive and Control Circuit, be connected with soft starting circuit; Also comprise the driving compensating circuit with self-regulating function, this driving compensating circuit is connected between the end of the same name and soft starting circuit of main transformer positive feedback winding; During the conducting of master power switch pipe, drive compensating circuit and enter the conducting operating state, the positive feedback winding is given the soft starting circuit quick charge by driving compensating circuit, simultaneously according to compensation needs self-regulation compensation intensity, make soft starting circuit continue, reasonably provide the driving energy for the master power switch pipe, when the master power switch pipe ends, drive compensating circuit and enter the shutoff operating state, be equivalent to open circuit between positive feedback winding and the soft starting circuit.

Referring to Fig. 4, drive the self-oscillation flyback converter embodiment of the soft starting circuit of compensation for band self-regulating function of the present invention.In the present embodiment one, adopt pulse frequency modulation circuit 13 as the Drive and Control Circuit of converter, the realization circuit of present embodiment mainly comprises following part: input filter circuit 11, soft starting circuit 12, the driving compensating circuit 18 of tool self-regulating function, pulse frequency modulation circuit 13, main power circuit 14, accessory power supply 15, output filter circuit 16, voltage stabilizing circuit 17, wherein input filter circuit 11, soft starting circuit 12, pulse frequency modulation circuit 13, main power circuit 14, accessory power supply 15, output filter circuit 16, the circuit structure of voltage stabilizing circuit 17 is identical with the circuit structure of circuit shown in Figure 2 in the background technology, and the difference of present embodiment and circuit shown in Figure 2 is that present embodiment has increased the tool self-regulating function and driven compensating circuit 18:

In the present embodiment, the master power switch pipe in the main power circuit 14 adopts metal-oxide-semiconductor TR1, and main transformer adopts transformer T1, and former limit winding P1, output winding P2 and positive feedback winding P3 are arranged on the transformer T1.

Input filter circuit 11 comprises filter capacitor C0, filter capacitor C1 and filter inductance L0, and its structure is known π type filter circuit theory structure, does not describe in detail at this.

Soft starting circuit 12 comprises divider resistance R10, divider resistance R13, divider resistance R14, starts capacitor C 9.Divider resistance R10, divider resistance R13, divider resistance R14 connect successively, start capacitor C 9 one termination divider resistance R10 and divider resistance R13, an end ground connection.Its operation principle is for when inserting input voltage, and electric current charges the elapsed time through divider resistance R10 to starting capacitor C 9

Back capacitance voltage reaches the MOS threshold voltage, realizes the start soft start function.

The tool self-regulating function drives compensating circuit 18, comprises diode D4, constant-current source D1A, and diode D4 anode connects feedback winding P3 end of the same name, and negative electrode and constant-current source D1A positive pole join, and constant-current source D1A negative pole links to each other with capacitor C 9 one ends with resistance R 13.Its operation principle is, the startup stage, metal-oxide-semiconductor TR1 conducting, (its both end voltage is positive feedback winding P3 from the input coupling energy Wherein Vin is input voltage, Nf is the feedback winding number of turns, and Np is former flange number), positive feedback winding P3 end of the same name is for just, diode D4 conducting, constant-current source is started working, for start-up circuit provides constant current compensation, when selecting suitable constant-current source just can satisfy different input voltages with different output loading, the suitable compensation that metal-oxide-semiconductor TR1 drive circuit is required, thus guarantee to start normal; Steady-state process, during metal-oxide-semiconductor TR1 conducting, positive feedback winding P3 end of the same name is for just, and diode D4 conducting, constant-current source D1A enter constant-current phase, and this moment, maximum compensation intensity was limited, and had avoided overcompensation; Metal-oxide-semiconductor TR1 off-phases, positive feedback winding P3 end of the same name is for negative, and diode D4, constant-current source D1A all end.During output short-circuit, feed back winding coupled voltage in theory and approach zero volt, actual existence owing to leakage inductance, there is the peak voltage of low duty ratio in short-circuit condition feedback winding, and this voltage charges to soft starting circuit by diode D4, constant-current source D1A, because constant-current source is to the restriction of maximum current, its compensation effect is relatively poor, i.e. short-circuit condition, and metal-oxide-semiconductor TR1 drives compensation have been reduced, therefore its short-circuit dissipation also descends, and reaches the self-regulation effect of short-circuit condition.Table seven is that WRB4805D, power are the supply convertor of 3W for model, after constant-current source D1A adopts the constant-current source of 0.6mA, the magnitude of voltage of capacitor C 9 under different input voltages and loading condition, contrast table two, table four, after adopting the technology of the present invention, voltage on the capacitor C 9 is basicly stable, and excursion is 3.51V only, has avoided the metal-oxide-semiconductor TR1 that resistance R 10 value differences cause in the former scheme to drive overcompensation and undercompensation.

Table seven

Pulse frequency modulation circuit 13 comprises: resistance R 6, resistance R 9, resistance R 11, resistance R 111, capacitor C 5, capacitor C 6, capacitor C 12, NPN type triode TR2, positive-negative-positive triode TR3.Capacitor C 6 is connected successively with resistance R 11, resistance R 111, resistance R 6, and a termination of series circuit is gone into the end of the same name of positive feedback winding P3, and the other end inserts the collector electrode of triode TR2.Capacitor C 5 is in parallel with resistance R 9, and a termination of parallel-current is gone into the base stage of triode TR2, and the other end inserts the collector electrode of triode TR3.Capacitor C 12 is in parallel with resistance R 111, and a termination of parallel circuits is gone into the emitter of three utmost point TR3, and the other end inserts the base stage of three utmost point TR3.Its operation principle is: positive feedback winding P3, capacitor C 6, resistance R 11 branch roads constitute the self-oscillation loop by being coupled with the former secondary of main power transformer T1, and control metal-oxide-semiconductor TR1 conducting is turn-offed; Electric current loop resistance R 5 branch roads, Voltage loop optocoupler OC1 branch road make product output normal by by triode TR2, the two-tube Drive and Control Circuit by-pass cock of triode TR3 pipe conducting duty ratio simultaneously.

Main power circuit 14 comprises former limit winding P1, the output winding P2 of transformer T1, and metal-oxide-semiconductor TR1, current-limiting resistance R5 absorb capacitor C 14, and output rectifier diode D1 realizes conversion, transmission and the input and output isolation of power supply energy.

Accessory power supply 15 comprises positive feedback winding P3, diode D3, and its operation principle is timing diode D3 conducting for feedback winding end of the same name, for optocoupler provides energy.

Output filter circuit 16 comprises capacitor C 3, also can adopt other existing filter circuit, specifically can be selected by the relevant technologies handbook.

Voltage stabilizing circuit 17 mainly comprises pressurizer ADJ, and it is connected to main power circuit and accessory power supply 15 and pulse frequency modulation circuit 13 by optocoupler OC1, does not repeat them here.

Below embodiment two is briefly described, wherein only illustrate and have self-regulating function and drive the compensating circuit part, the connection of other parts is identical with Fig. 4.

Fig. 5 is that the tool self-regulating function of the embodiment of the invention two drives the compensating circuit part, and other circuit part is identical with operation principle and the method for attachment of circuit shown in Figure 4.Its difference is that the tool self-regulating function of present embodiment drives that diode D4 changes with constant-current source D1A position among the compensating circuit A1, the anodal feedback winding end of the same name that inserts of constant-current source D1A, and negative pole and diode D4 anode join, diode D4 negative electrode access capacitor C 9.

Need to prove that above-mentioned constant-current source can be by the multiple mode of forming, it can be constant-current source parallel form of the prior art, as Figure 11; The constant-current source that constant-current source of the prior art and triode, voltage-stabiliser tube, resistance are composited, its constant current is output as Io=(V as Figure 12 _2D-V _BE1)/R; Can also be the constant-current source that triode of the prior art and resistance constitute, as Figure 13, its constant current output Io=V _Be/ R ₅₀₅Etc..

Except several enforcement circuit of above-mentioned explanation; industry technical staff can associate naturally for example by above description and accompanying drawing other be equal to application scheme; for example the Drive and Control Circuit of converter adopts as among Figure 14; by triode TR2; resistance R 6; the single tube Drive and Control Circuit that capacitor C 5 and resistance R 9 are formed replaces the pulse frequency modulation circuit in above-described embodiment etc.; for those skilled in the art; under the prerequisite that does not break away from the principle of the invention, the present invention is carried out some improvement and modification falls in the protection range of claim of the present invention.

Claims (4)

1. self-oscillation anti exciting converter, direct-flow input signal are exported direct current signal through behind input filter circuit, main power circuit and the output filter circuit successively, and main power circuit comprises master power switch pipe and main transformer; The direct current signal of described output carries out negative feedback by voltage stabilizing circuit, isolation optocoupler and Drive and Control Circuit to the master power switch pipe successively and controls to realize stable output, between the output of input filter circuit and Drive and Control Circuit, be connected with soft starting circuit, it is characterized in that: also comprise the driving compensating circuit with self-regulating function, this driving compensating circuit is connected between the end of the same name and described soft starting circuit of described main transformer positive feedback winding.

2. self-oscillation anti exciting converter according to claim 1, it is characterized in that: described driving compensating circuit with automatic regulatory function comprises diode (D4) and constant-current source (D1A), the anode of described diode (D4) is connected to the end of the same name of described main transformer positive feedback winding, the negative electrode of described diode (D4) is connected with the positive pole of constant-current source (D1A), and the negative pole of described constant-current source (D1A) is connected to the Voltage Reference end of self-oscillation anti exciting converter by described soft starting circuit.

3. self-oscillation anti exciting converter according to claim 1, it is characterized in that: described driving compensating circuit with automatic regulatory function comprises diode (D4) and constant-current source (D1A), the negative pole of described constant-current source (D1A) is connected to the anode of described diode (D4), the positive pole of described constant-current source (D1A) is connected with the end of the same name of described main transformer positive feedback winding, and the negative electrode of described diode (D4) is connected to the Voltage Reference end of self-oscillation anti exciting converter by described soft starting circuit.

4. according to each described self-oscillation anti exciting converter of claim 1 to 3, it is characterized in that: described constant-current source (D1A) is single constant-current source, or constant-current source parallel form, or the constant-current source that is composited of constant-current source and triode, voltage-stabiliser tube, resistance, or the constant-current source that constitutes of triode and resistance.

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