CN201388313Y - High-efficiency constant-current LED driving circuit - Google Patents

Abstract

The utility model discloses a high-efficiency constant-current LED driving circuit. The driving circuit comprises a resistor R1 and a voltage stabilizing tube Z1 which are connected in series, a first capacitor C1 which is connected with the voltage stabilizing tube Z1 in parallel, and a freewheeling diode D1 and an inductor L which are connected at two ends of a load LED in series, as well as a power switch MOS transistor and a source driver control circuit, wherein the gate of the power switch MOS transistor is connected with the negative pole of the voltage stabilizing tube Z1, the drain is connected between the inductor L and the freewheeling diode D1, the source is connected with the positive pole of a feeding diode D2, the negative pole of the feeding diode D2 is connected with the negative pole of the voltage stabilizing tube Z1, and the source driver control circuit is connected between the source of the power switch MOS transistor and a sampling resistor RCS for adaptive control of the power switch MOS transistor from the source. The driving circuit can realize less current consumption and low voltage drop on a power supply path, thereby reducing power consumption and improving efficiency; and the driving circuit can simultaneously generate self-adaptive off-time which is inversely proportional to output voltage, thereby realizing constant-current output.

Description

High efficiency constant current LED drive circuit

Technical field

The utility model relates to a kind of led drive circuit, relates in particular to a kind of high efficiency constant current LED drive circuit.

Background technology

Fig. 1 is the schematic diagram of traditional led drive circuit.As shown in Figure 1, resistance R that between power supply VIN and ground, is connected in series 1 and voltage-stabiliser tube Z1, the positive pole of voltage-stabiliser tube Z1 is connected to ground, and the negative pole of voltage-stabiliser tube Z1 is connected to an end of resistance R 1, and the other end of resistance R 1 is connected to power supply VIN; Capacitor C1 is connected in parallel in the two ends of voltage-stabiliser tube Z1; The negative pole of sustained diode 1 is connected to positive pole and the power supply VIN of load LED, and the positive pole of sustained diode 1 is connected to first end of inductance L, and second end of inductance L is connected to the negative pole of load LED; Switching tube M1 is connected between inductance L and the sampling resistor RCS, the controlled control circuit that illustrates in the frame of broken lines that is formed on of this switching tube M1, it by resistance R 1, capacitor C1, voltage-stabiliser tube Z1 from power supply VIN power taking.Control circuit generally includes timer 12, comparator 11 and rest-set flip-flop 13.

During switching tube M1 conducting, the inductance L electric current increases, node CS place voltage increases, when node CS place voltage is elevated to reference voltage V1, comparator 11 upsets, rest-set flip-flop 13 zero clearings, switching tube M1 turn-offs, timer 12 picks up counting, and inductance L is by sustained diode 1, load LED discharge, and electric current reduces; When the timer timing finished, rest-set flip-flop 13 was put height, and switching tube M1 opens again, finishes one-period.

In above-mentioned traditional drive circuit, there are following two shortcomings: the first, power supply VIN gives drive circuitry by resistance R 1, capacitor C1, voltage-stabiliser tube Z1.Usually drive circuit works voltage is about 12 volts, and the power supply electrifying pressure may be the high pressure more than two hectovolts, on resistance R 1, just have the pressure drop of hundreds of volt like this, even the driving circuit section current sinking is 1mA, also can consume the hundreds of milliwatt on the resistance, in addition because system adopts the very big Alternating Current Power Supply of ripple, also can provide drive circuit required electric current in order to satisfy when the voltage trough, and when the voltage crest, electric current on the resistance R 1 can increase greatly, this unnecessary electric current is discharged into ground by voltage-stabiliser tube Z1, when for example the trough supply voltage was 100V, electric current 1mA on the resistance R 1 was when peak voltage 200V, electric current is about 2mA on the resistance R 1, and unnecessary 1mA arrives ground by voltage-stabiliser tube Z1.In addition, because switching tube M1 is the high-voltage power metal-oxide-semiconductor, its grid parasitic capacitance is very big, thereby drives the electric current that this power tube need be very big, causes the quiescent current of whole drive circuit big, thereby makes that the power consumption on the resistance R 1 is bigger.The second, this driving method comes the constant output electric current by control peak current and ripple current, and peak current is by comparator 11, reference voltage V1 and sampling resistor RCS determine, the electric current descending slope of inductance L is directly proportional with output voltage V out, and as shown in Figure 2, ripple current can be drawn by following formula

$I_{\mathrm{pp}}=\frac{\mathrm{Vout}}{L}*\mathrm{Toff}$

Inductive current waveform and average inductor current when dotted line is corresponding to high output voltage among Fig. 2, clearly, in the identical turn-off time, the output voltage height, ripple current is big, and average current is low.

As seen, it is low that traditional LED drives efficient, and output current is subjected to output voltage influence big.

The utility model content

The purpose of this utility model is to solve the aforementioned problems in the prior, and a kind of high efficiency constant current LED drive circuit is provided, and makes output current constant improve to drive efficient and to reduce output voltage to the influence of output current.

For achieving the above object, the utility model provides a kind of high efficiency constant current LED drive circuit, comprise the resistance R 1 and the voltage-stabiliser tube Z1 that are connected in series, the first capacitor C1 that is connected in parallel with voltage-stabiliser tube Z1, and the sustained diode that is connected in series 1 and the inductance L that are connected in load LED two ends, described led drive circuit also comprises: the power switch MOS transistor, its grid is connected to the negative pole of voltage-stabiliser tube Z1, drain electrode is connected between inductance L and the sustained diode 1, source electrode is connected to the positive pole of feedback stream diode D2, and the negative pole of this feedback stream diode D2 is connected to the negative pole of voltage-stabiliser tube Z1; The source drive control circuit, this source drive control circuit is connected between the end of the source electrode of power switch MOS transistor and sampling resistor RCS, thereby from the source electrode power controlling switch mos transistor of power switch MOS transistor, the other end ground connection of sampling resistor RCS.

Preferably, can further comprise the 3rd capacitor C3 between the source electrode that is connected in the power switch MOS transistor and the drain electrode according to drive circuit of the present utility model.

Preferably, also can further comprise resistance R 2 between the positive pole of the source electrode that is connected in the power switch MOS transistor and feedback stream diode according to drive circuit of the present utility model.

Owing to adopted source drive, and powered to control circuit by feedback stream diode, so greatly reduce voltage on the supply access from source electrode; Drive current is provided by the LED load by power supply simultaneously, makes that the driving circuit section quiescent current is little, and the factor of this two aspect makes system power dissipation reduce, and efficient is improved.In addition, the utility model has also been realized the control of self adaptation turn-off time, makes current ripples remain unchanged under wide output voltage range, has realized constant current output with peak current control.

Description of drawings

Fig. 1 is traditional led drive circuit schematic diagram;

Fig. 2 shows the electric current that flows through inductance in the led drive circuit shown in Figure 1;

Fig. 3 is the schematic diagram according to the preferred embodiment of high efficiency constant current LED drive circuit of the present utility model;

Fig. 4 shows the electric current that flows through inductance in the led drive circuit of the present utility model shown in Figure 3.

Embodiment

Below, describe in detail in conjunction with the accompanying drawings according to preferred embodiment of the present utility model.

According to high efficiency constant current LED drive circuit of the present utility model the type of drive and the control mode of as shown in Figure 1 existing drive circuit have been made improvement.With reference to figure 3, similar to prior art is, resistance R that between power supply VIN and ground, is connected in series 1 and voltage-stabiliser tube Z1, the positive pole of voltage-stabiliser tube Z1 is connected to ground, the negative pole of voltage-stabiliser tube Z1 is connected to an end of resistance R 1, the other end of resistance R 1 is connected to power supply VIN, the first capacitor C1 is connected in parallel in the two ends of voltage-stabiliser tube Z1, the negative pole of sustained diode 1 is connected to positive pole and the power supply VIN of load LED, the positive pole of sustained diode 1 is connected to first end of inductance L, and second end of inductance L is connected to the negative pole of load LED.

And unlike the prior art be that the utility model adopts source drive and the control of self adaptation turn-off time.Particularly, led drive circuit of the present utility model also comprises power switch MOS transistor M3 and source drive control circuit, wherein the grid of power switch MOS transistor M3 is connected to the negative pole of voltage-stabiliser tube Z1, drain electrode SWD is connected to an end of inductance L, source S WS is connected to the positive pole of feedback stream diode D2, and the negative pole of this feedback stream diode D2 is connected to the negative pole of voltage-stabiliser tube Z1.And the source drive control circuit is connected between the end of the source electrode of power switch MOS transistor and sampling resistor RCS, thereby from the source electrode power controlling switch mos transistor of power switch MOS transistor.

Can insert resistance R 2 between the positive pole of source S WS that it is pointed out that at power switch MOS transistor M3 and feedback stream diode D2, with the restriction current spike.Also can between the source electrode of power switch MOS transistor M3 and drain electrode, insert the 3rd capacitor C3 simultaneously.

The source drive control circuit is shown in frame of broken lines among Fig. 3, it comprises low tension switch MOS transistor M2, the drain electrode of low tension switch MOS transistor M2 is connected to the source S WS of power switch MOS transistor M1, source electrode is connected to the end of sampling resistor RCS and the positive input terminal of first comparator 31, and its grid is connected to the Q output of rest-set flip-flop 34.

Comprise according to self adaptation of the present utility model turn-off time control unit: output voltage sampling section, this part are sampled to the output voltage at load LED two ends and output and the proportional electric current of output voltage; Current amplifier 33, its input is connected to the output of output voltage sampling section; Nmos pass transistor M1, the drain electrode of this nmos pass transistor M1 is connected to the output of current amplifier 33, and source ground, grid are connected to the grid of low tension switch MOS transistor M2; The second capacitor C2 is connected between the drain electrode and source electrode of nmos pass transistor M1; Second comparator 32, the positive input terminal of this second comparator 32 is connected to the drain electrode of nmos pass transistor M1, and its negative input end is connected to power supply V2, and its output is connected to the S input of rest-set flip-flop 34.

About the connected mode of other terminals of first comparator 31 and rest-set flip-flop 34 and since to prior art Fig. 1 in similar, so do not repeat them here.

The output voltage sampling section comprises PNP transistor Q1 and resistance R 3, and wherein the base stage of PNP transistor Q1 is connected to the negative pole of LED load, and emitter is connected to the positive pole of LED load via resistance R 3, and collector electrode is connected to the input of current amplifier 33.

Further describe according to the course of work of led drive circuit of the present utility model and the beneficial effect of being realized below with reference to Fig. 3 and Fig. 4.

The utility model with power switch MOS transistor M3 gate voltage fixed at VDD, and drive from its source electrode by low tension switch MOS transistor M2, drive current is provided by load LED, inductance L, power switch MOS transistor M3 by power supply VIN, rather than provide by VDD, still need VDD that electric current is provided though drive low tension switch MOS transistor M2, but because M2 is the low tension switch MOS transistor, parasitic capacitance parasitic capacitance on the grid of power switch MOS transistor M3 on its grid, thereby the drive circuit that its drive current is compared among Fig. 1 is little a lot.

The utility model also adds resistance R 2 and feedback stream diode D2 between power switch MOS transistor M3 source node SDS and drive circuitry power supply node VDD.When low tension switch MOS transistor M2 opens, power supply VIN charges to inductance L by load LED, low tension switch MOS transistor M2, power switch MOS transistor M3 and resistance R CS, node SWD and SWS voltage all approach 0, it is 0 that the 3rd capacitor C3 (also can not external the 3rd capacitor C3, and utilize the parasitic capacitance of power switch MOS transistor M3) goes up voltage; When low tension switch MOS transistor M2 closes, inductive current is by sustained diode 1, the discharge of load LED loop, the voltage at the drain node SWD place of power switch MOS transistor M3 is elevated to supply voltage from 0 at this moment, by resistance R 2, feedback stream diode D2, capacitor C1, C3, power supply VIN, load LED, capacitor C1 is given in the inductance L loop, the C3 charging, the final voltage of capacitor C3 is VIN-VDD, the charging current direction is shown in I among Fig. 3, capacitor C1 energy storage is to supply with drive circuit, dissipative cell in the charging path except that load LED is resistance R 2 and feedback stream diode D2, because in the charging process, voltage on resistance R 2 and the feedback stream diode D2 is very low, thereby extra power consumption is very low.When being used for system start-up, resistance R 1 powers to control circuit, because the quiescent current of control circuit own is little and exist the supply access resistance R 2 of low-power consumption and feedback to flow diode D2, so the circuit that the electric current that passes through on the resistance R 1 is compared among Fig. 1 can reduce greatly, thereby total system power dissipation reduces greatly, and efficient is improved significantly.

Resistance R 3, PNP transistor Q1, current amplifier 33, capacitor C2, nmos pass transistor M1, second comparator 32, reference voltage V2 have constituted a kind of implementation of self adaptation turn-off time control of the present utility model.PNP transistor Q1 and resistance R 3 change into proportional electric current with Vout with output voltage V out, this electric current is adjusted through current amplifier 33, give capacitor C2 charging, voltage and reference voltage V2 that second comparator 32 compares on the capacitor C2, when the voltage on the capacitor C2 reaches reference voltage V2, rest-set flip-flop 34 set, low tension switch MOS transistor M2 opens, and gives capacitor C2 zero clearing by nmos pass transistor M1 simultaneously.When low tension switch MOS transistor M2 turn-offed, nmos pass transistor M1 also turn-offed, and capacitor C2 begins charging, until the voltage on the capacitor C2 when opening low tension switch MOS transistor M2 again when being raised to reference voltage V2 till.Because charging current is directly proportional with output voltage, so low tension switch MOS transistor M2 turn-off time and output voltage V out be inversely proportional to, and the turn-off time is drawn by following formula:

$\mathrm{Toff}=\frac{C2*V2*R3}{\mathrm{Vout}}.$

And the inductive current descending slope is directly proportional with output voltage V out, and therefore, ripple current and Vout are irrelevant, and ripple current is drawn by following formula:

$\mathrm{Ipp}=\frac{\mathrm{Vout}}{L}*\frac{C2*V2*R2}{\mathrm{Vout}}=\frac{C2*V2*R2}{L}.$

As shown in Figure 4, when output voltage changed, the output average current was constant.

Correspondingly, adopt source drive according to high-efficiency constant-current LED driving method of the present utility model, and give the power supply of source drive control circuit via feedback stream diode D2 from the source electrode of power switch MOS transistor M3, to reduce the voltage on the supply access and to reduce the quiescent current of drive circuit; And utilize the output voltage V out at load LED two ends that power switch MOS transistor M3 is carried out the control of self adaptation turn-off time, so that output current is constant.

Should be appreciated that the technical solution of the utility model one is to adopt source drive, the drive circuit current sinking of this type of drive is few, and has reduced the electric current on the R1 in traditional High Pressure Difference supply access, thereby has reduced power consumption, has improved efficient; The 2nd, produce the self adaptation turn-off time that is inversely proportional to output voltage, realize the output of constant ripple current and average current.

Described in this specification is preferred specific embodiment of the present utility model, and above embodiment is only in order to the explanation the technical solution of the utility model but not to restriction of the present utility model.All those skilled in the art according to design of the present utility model by the available technical scheme of logical analysis, reasoning, or a limited experiment, all should be within as the scope of the present utility model that claim defined.

Claims (6)

1, a kind of high efficiency constant current LED drive circuit, first capacitor C1 that comprises the resistance R 1 that is connected in series and voltage-stabiliser tube Z1, is connected in parallel with voltage-stabiliser tube Z1 and sustained diode that is connected in series 1 and the inductance L that is connected in load LED two ends, it is characterized in that described led drive circuit also comprises:

The power switch MOS transistor, its grid is connected to the negative pole of described voltage-stabiliser tube Z1, drain electrode is connected between described inductance L and the described sustained diode 1, and source electrode is connected to the positive pole of feedback stream diode D2, and the negative pole of this feedback stream diode D2 is connected to the negative pole of described voltage-stabiliser tube Z1;

The source drive control circuit, this source drive control circuit is connected between the end of the source electrode of described power switch MOS transistor and sampling resistor RCS, thereby control described power switch MOS transistor from the source electrode of described power switch MOS transistor, the other end ground connection of described sampling resistor RCS.

2, high efficiency constant current LED drive circuit as claimed in claim 1 is characterized in that: described source drive control circuit comprises:

The low tension switch MOS transistor, the drain electrode of this low tension switch MOS transistor is connected to the source electrode of described power switch MOS transistor, its source electrode is connected to the described end of described sampling resistor RCS and the positive input terminal of first comparator, and its grid is connected to the Q output of rest-set flip-flop;

Self adaptation turn-off time control unit, it is connected to the S input of load LED, described rest-set flip-flop, thereby controls the turn-off time of described low tension switch MOS transistor adaptively according to the output voltage at load LED two ends.

3, high efficiency constant current LED drive circuit as claimed in claim 2 is characterized in that: described self adaptation turn-off time control unit comprises:

Output voltage sampling section, this part are sampled to the output voltage at load LED two ends and output and the proportional electric current of described output voltage;

Current amplifier, its input is connected to the output of described output voltage sampling section;

Nmos pass transistor, the drain electrode of this nmos pass transistor is connected to the output of described current amplifier, and source ground, grid are connected to the grid of described low tension switch MOS transistor;

The second capacitor C2 is connected between the drain electrode and source electrode of described nmos pass transistor;

Comparator, the positive input terminal of this comparator is connected to the drain electrode of described nmos pass transistor, and its negative input end is connected to power supply V2, and its output is connected to the S input of described rest-set flip-flop.

4, high efficiency constant current LED drive circuit as claimed in claim 3, it is characterized in that: described output voltage sampling section comprises PNP transistor Q1 and resistance R 3, the base stage of wherein said PNP transistor Q1 is connected to the negative pole of LED load, emitter is connected to the positive pole of LED load via described resistance R 3, and collector electrode is connected to the input of described current amplifier.

5, high efficiency constant current LED drive circuit as claimed in claim 4 is characterized in that: further comprise the 3rd capacitor C3 between the source electrode that is connected in described power switch MOS transistor and the drain electrode.

6, as each described high efficiency constant current LED drive circuit among the claim 1-5, it is characterized in that: further comprise the resistance R 2 between the positive pole of the source electrode that is connected in described power switch MOS transistor and described feedback stream diode.

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