CN203801121U - Line voltage compensating circuit for LED driver - Google Patents
Line voltage compensating circuit for LED driver Download PDFInfo
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- CN203801121U CN203801121U CN201420130014.0U CN201420130014U CN203801121U CN 203801121 U CN203801121 U CN 203801121U CN 201420130014 U CN201420130014 U CN 201420130014U CN 203801121 U CN203801121 U CN 203801121U
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- 238000005070 sampling Methods 0.000 claims abstract description 41
- 238000001514 detection method Methods 0.000 claims description 6
- 238000002955 isolation Methods 0.000 claims description 5
- 230000001939 inductive effect Effects 0.000 description 11
- 230000000694 effects Effects 0.000 description 4
- 239000003990 capacitor Substances 0.000 description 3
- 230000001965 increasing effect Effects 0.000 description 3
- 230000002459 sustained effect Effects 0.000 description 2
- 230000002939 deleterious effect Effects 0.000 description 1
- 238000002474 experimental method Methods 0.000 description 1
- 238000000034 method Methods 0.000 description 1
- 230000035939 shock Effects 0.000 description 1
Abstract
The utility model discloses a line voltage compensating circuit for an LED driver, which comprises a line voltage sampling unit, a compensating voltage generation unit, an inductor peak current sampling resistor, an adder unit, a comparator unit and a control and drive unit. The line voltage sampling unit is used for sampling the busbar voltage of an LED constant-current driver circuit. The compensating voltage generation unit is used for generating a magnitude of compensating voltage required by the LED constant-current driver circuit corresponding to the busbar voltage. The inductor peak current sampling resistor is used for sampling the peak current of an inductor. The adder unit is used for adding up the magnitude of voltage applied across the peak current sampling resistor of the LED constant-current driver circuit and the magnitude of compensating voltage generated by the compensating voltage generation unit. The comparator unit is used for generating a turn-off signal used for turning off a power switch tube. The control and drive unit is used for driving the power switch tube and conducting the constant-current control over the entire LED constant-current driver circuit. According to the technical scheme of the utility model, a line voltage compensating resistor, which is usually adopted in the prior art, is no longer required. Meanwhile, the anti-interference capability and the reliability of the system are improved.
Description
Technical field
The utility model relates to a kind of line voltage compensation circuit, relates in particular to a kind of line voltage compensation circuit driving for LED.
Background technology
In LED drive circuit, adopt widely peak current control mode to realize constant current output, but due to the turn off delay time of the time delay of control chip subsistence logic and power switch pipe, these time delay meetings cause peak current under different busbar voltages, to have inconsistent phenomenon, thereby cause output constant current deleterious.
Traditional solution is at the outside line voltage compensation circuit that adds of control chip, realizes output current compensation by the voltage on direct-detection bus.Concrete implementation is to connect a resistance between bus and peak current sampling pin, and connects a resistance between peak current sampling pin and sampling resistor.According to different busbar voltages, change the magnitude of voltage of resistance between peak current sampling pin and sampling resistor value, thereby improve the consistency problem of peak current under different busbar voltages, thereby output current is compensated.
Fig. 1 is the LED constant-current drive circuit that uses the peak current control of traditional line voltage compensation mode, generally includes: rectifier bridge D1 ~ D4, input filter capacitor C1, supplying resistance R1, power supply capacitor C 2, control chip U1, line voltage compensation resistance R 2, R3, peak current sampling resistor R4, power switch pipe Q1, inductance L 1, sustained diode 5, output capacitance C3, output resistance R5 and LED load LEDs.In the time of power switch pipe Q1 conducting, the electric current in inductance L 1 starts on slope, to rise in time, simultaneously the upper ramp voltage signal that produces of peak current sampling resistor R4.In the time that the voltage signal on the peak current sampling pin of control chip reaches the reference voltage of control chip U1 inside, and after the internal delay time of control chip, power switch pipe Q1 turn-offs.Now the electric current in inductance L 1 continues to output on output capacitance C3 and LED load LEDs by sustained diode 5.Power switch pipe Q1 keeps turn-offing until next cycle starts.Line voltage compensation resistance R 2 detects the height of busbar voltage, in the time that busbar voltage is higher, flow through electric current in line voltage compensation resistance R 2 larger, the pressure drop on on-Line Voltage compensating resistance R3 is larger, thereby power switch pipe Q1 is turn-offed in advance, thereby realize the object of line voltage compensation.
Traditional line voltage compensation Technology Need is at the outside compensating circuit that adds of control chip U1.The shortcoming of doing is like this to have increased the cost of whole circuit framework and the complexity of application debugging, at least will increase by two resistance in system; Also increased the power consumption of system, thereby reduced system effectiveness simultaneously; This traditional compensation technique is also very limited to the effect of output current compensation in addition, and the voltage on compensating resistance R3 is easy to be interfered.Being particular about cost and efficiency and pursuing in the low-power LED driving power design of small size, this traditional line voltage compensation technology more and more has limitation.
Utility model content
For the limitation of traditional wire voltage compensation technology, the utility model discloses a kind of line voltage compensation circuit driving for LED.The voltage that the utility model is sampled on bus indirectly by the ON time of detection power switching tube, this has saved the line voltage compensation resistance in conventional art, simplify the system of external circuit, the efficiency and the cost that has reduced system of system are improved, the more important thing is by integrated line voltage compensation technology, improved greatly antijamming capability and the reliability of system.
The purpose of this utility model is achieved through the following technical solutions: a kind of line voltage compensation circuit driving for LED, comprising: a line voltage sample unit, for the busbar voltage of LED constant-current drive circuit is sampled; One bucking voltage generation unit, for generation of LED constant-current drive circuit in the needed bucking voltage value of corresponding busbar voltage; One inductance peak current sampling resistor, samples for the peak current to inductance; One adder unit, for being added the magnitude of voltage of peak current sampling resistor of LED constant-current drive circuit and the bucking voltage value that bucking voltage generation unit produces; One comparator unit, for the reference voltage signal of the output valve of described adder unit and LED constant-current drive circuit is compared, produces a cut-off signals that described power switch pipe is turn-offed; One controls and driver element, for the output signal of described comparator unit is carried out to logic control, and then driving power switching tube and whole LED constant-current drive circuit is carried out to constant current control.
Further, the output of described line voltage sample unit connects the input of described bucking voltage generation unit, the output of described bucking voltage generation unit connects an input of described adder unit, another input of described adder unit is also connected with described peak current sampling resistor, the output of described adder unit is connected with the input of described comparator unit, another input of described comparator unit is also connected with the reference voltage signal of LED constant-current drive circuit, the output of described comparator unit is connected with the input of driver element with described control, described control is connected with the input of described power switch pipe and the input of described line voltage sample unit respectively with the output of driver element.
Further, described line voltage sample unit comprises a switch control logic unit, a fixed current source, the first switch, second switch and a sampling capacitance; The input of described switch control logic unit is connected with the output of driver element with described control; The output of described switch control logic unit is connected with the first switch and second switch respectively; One end of described the first switch connects described fixed current source, and its other end connects described sampling capacitance; One end of described second switch connects described sampling capacitance, its other end ground connection; One end ground connection of described sampling capacitance, its other end is also connected with described bucking voltage generation unit.
Further preferred, described line voltage sample unit, samples to busbar voltage indirectly by the ON time TON of detection power switching tube;
Further, described bucking voltage generation unit comprises an operational amplifier, the first resistance, the second resistance, a fixed current source, a nmos pass transistor, the first current mirror and the second current mirror; A positive input terminal of described operational amplifier is connected with the output of described line voltage sample unit, and negative input end is connected with described the first resistance, and its output is connected with the grid of described nmos pass transistor; Described first resistance one end ground connection, its other end is connected with the source electrode of described nmos pass transistor; One end of described the first current mirror is connected with the drain electrode of described nmos pass transistor, and its other end is connected with described the second current mirror; The other end of described the second current mirror is connected with described fixed current source; One end ground connection of described the second resistance, its other end is connected with described fixed current source, is connected with an input of described adder unit simultaneously.
The described line voltage compensation circuit driving for LED both can, for the power-supply system of non-isolation, as step-down, boost, the topologys such as buck; Also can for isolation power-supply system in, as normal shock, the topologys such as flyback.
The advantage that the utility model compared with prior art has and effect are:
Line voltage sampling circuit described in the utility model is according to indirectly the sample variation of busbar voltage of the ON time TON of power switch pipe, after converting TON to a corresponding voltage VS, output to line voltage compensation circuit, line voltage compensation circuit produces a bucking voltage according to VS, then after the voltage on described bucking voltage and peak current sampling resistor being added, being sent to comparator and comparing with reference voltage, thereby determine the turn-off time.The voltage that the utility model is sampled on bus indirectly by the ON time of detection power switching tube, this has saved the line voltage compensation resistance in conventional art, simplify the system of external circuit, the efficiency and the cost that has reduced system of system are improved, the more important thing is by integrated line voltage compensation technology, improved greatly antijamming capability and the reliability of system.
Brief description of the drawings
Fig. 1 is the LED drive circuit that tradition is used traditional wire voltage compensating circuit;
Fig. 2 is the inductive current oscillogram of not being with the LED constant-current drive circuit of line voltage compensation circuit;
Fig. 3 is a kind of implementing circuit figure of the line voltage compensation circuit driving for LED described in the utility model;
Fig. 4 is the LED drive circuit inductive current oscillogram that adopts line voltage compensation circuit described in the utility model;
Fig. 5 is a specific embodiment of the line voltage sample unit of line voltage compensation circuit described in the utility model;
Fig. 6 is a specific embodiment of the bucking voltage generation unit of line voltage compensation circuit described in the utility model.
Embodiment
Below in conjunction with embodiment and accompanying drawing, the utility model is described in further detail, but execution mode of the present utility model is not limited to this.
The problems such as traditional line voltage compensation technical efficiency is low, original is high, volume is large in order to solve, poor anti jamming capability, the utility model provides a kind of integrated line voltage compensation circuit, the voltage that described compensating circuit is sampled on bus indirectly by the ON time of detection power switching tube, this has saved the line voltage compensation resistance in conventional art, simplify the system of external circuit, improve the efficiency and the cost that has reduced system of system, improved greatly antijamming capability and the reliability of system.
Due to the logical time delay of control chip inside and the turn off delay time of power switch pipe, drive reference voltage V REF for identical LED constant current, the relation of peak current IPK and busbar voltage is as follows:
Wherein, RCS is peak current sampling resistor value; Lm is inductance value; Td is the time delay of control chip inside.Because the time delay of control chip inside is substantially constant, the size of peak inductive current IPK under different busbar voltages can be different.Can see from formula above, when busbar voltage is higher, the rate of rise of peak inductive current IPK
larger, the overshoot that peak inductive current produces within the td time is larger.
Be illustrated in figure 2 LED constant-current drive circuit corresponding inductive current oscillogram under height busbar voltage of not being with line voltage compensation circuit.Known, when busbar voltage is high, corresponding peak inductive current can be greater than busbar voltage corresponding peak inductive current when low.The effect of integrated line voltage compensation circuit is at the inner bucking voltage VLC increasing with busbar voltage of generation of control chip, makes peak inductive current IPK in the time that busbar voltage changes, can be tending towards constant, to reach the object of line voltage compensation.
Because line voltage compensation circuit is integrated in control chip inside, not Direct Sampling busbar voltage.The utility model is according to indirectly the sample variation of busbar voltage of the ON time TON of power switch pipe.The relation of the ON time TON of power switch pipe and busbar voltage VDC is as follows:
Can see from formula above, the ON time TON of power switch pipe reduces along with the increase of busbar voltage VDC, and has relation as above.Principle of the present utility model is to utilize power switch pipe ON time TON, the sampled voltage VS who reduces along with busbar voltage increase that samples, and VS produces a bucking voltage VLC who increases with busbar voltage through bucking voltage generation unit afterwards; Bucking voltage VLC and peak current sampled voltage VCS are added, and produce a new peak current sampled voltage VCSN.Because the shutoff threshold value of VCSN is fixed as VREF, when busbar voltage is higher, the shutoff threshold value of VCS is less, makes peak inductive current IPK be tending towards constant after the internal delay time of control chip, thereby has reached the object of line voltage compensation.
Fig. 3 is a kind of implementing circuit figure of the line voltage compensation circuit driving for LED described in the utility model, comprise: rectifier bridge 200, input filter capacitor 201, supplying resistance 202, power supply electric capacity 203, power switch pipe 210, peak current sampling resistor 211, inductance 212, fly-wheel diode 213, output capacitance 214, output resistance 215, LED load 216 and control chip 217.The line voltage compensation circuit of described control chip 217 comprises: line voltage sample unit 204, bucking voltage generation unit 205, adder unit 206, reference voltage unit 207, comparator unit 208 and control and driver element 209.
In the time of described power switch pipe 210 conducting, the electric current of described inductance 212 starts on slope, to rise in time, and now the voltage VCS on described peak current sampling resistor 211 also rises on slope in time.The CS pin of described control chip 217 is connected with described peak current sampling resistor 211, is connected with the input of described adder unit simultaneously.In the conduction period of described power switch pipe 210, the voltage of sampling on bus in described line voltage sample unit 204, and a voltage VS sampling delivers to the input of described bucking voltage generation unit 205.Now described bucking voltage generation unit 205 produces a line voltage compensation voltage VLC, and this line voltage compensation voltage VLC is delivered to another input of described adder unit 206.Peak current sampled voltage VCS is through after being added with described line voltage compensation voltage VLC, export a new peak current sampled voltage VCSN, and deliver to described comparator unit 208 and compare with the reference voltage V REF that described reference voltage unit 207 produces.When the output signal VCSN of described adder unit 206 exceedes after the reference voltage V REF of described reference voltage unit 207, described comparator unit 208 is exported cut-off signals, and turn-offs described power switch pipe 210 by described control and driver element 209.
Fig. 4 is the LED drive circuit inductive current oscillogram in the time of height busbar voltage that adopts line voltage compensation circuit described in the utility model.As we know from the figure, in the time that busbar voltage is high pressure, due to the effect of line voltage compensation circuit, when the peak current of described inductance 212 reaches IREF4, described comparator unit 208 is exported cut-off signals, after chip internal time delay td, described power switch pipe 210 turn-offs, and now the peak current of described inductance 212 reaches IREF.In the time that busbar voltage is low pressure, when the peak current of described inductance 212 arrives IREF3, described comparator unit 208 is exported cut-off signals, after chip internal time delay td, described power switch pipe 210 turn-offs, and now the peak current of described inductance 212 reaches IREF.Therefore the peak current of described inductance 212 can reach unanimity in the time that busbar voltage is high and low pressure, thereby has reached the object of line voltage compensation.
Fig. 5 is a specific embodiment of the line voltage sample unit of line voltage compensation circuit described in the utility model.Described line voltage sample unit 204 is by switch control logic unit 300, fixed current source 301, the first switches 302, and second switch 303 and sampling capacitance 304 form.In the time of described power switch pipe 210 conducting, described the first switch 302 closures, described second switch 303 disconnects; Now charge to described sampling capacitance 304 and produce the sampled voltage VS of busbar voltage in described fixed current source 301; Described sampled voltage VS outputs to described bucking voltage generation unit.In the time that described power switch pipe 210 turn-offs, described the first switch 303 disconnects, described second switch 303 closures; Now described sampling capacitance 304 is discharged to zero over the ground by described second switch 303.
Fig. 6 is a specific embodiment of the bucking voltage generation unit of line voltage compensation circuit described in the utility model.Described bucking voltage generation unit 205 is by operational amplifier 400, the first resistance 401, nmos pass transistor 402, the first current mirrors 403, and fixed current source 404, the second current mirrors 405 and the second resistance 406 form.Sampled voltage VS, through described operational amplifier 400, after described nmos pass transistor 402 and described the first resistance 401 operation amplifiers, produces an electric current proportional to VS.Described electric current amplifies through the ratio of described the first current mirror 403 and described the second current mirror 405, and after being subtracted each other by described fixed current source 404, outputs on described the second resistance 406.Thereby produce the bucking voltage VLC of busbar voltage.
Above embodiment is only specific implementations of the present utility model, but not to restriction of the present utility model, all those skilled in the art has made to the utility model the technical scheme that some adjustment and change obtain by logical analysis, reasoning, or a limited experiment according to design of the present utility model, for example change the non-isolation applications circuit in specific embodiment into isolation applications circuit, be still main idea of the present utility model place, all should be within scope of the present utility model.
Claims (2)
1. the line voltage compensation circuit driving for LED, is characterized in that comprising: a line voltage sample unit, for the busbar voltage of LED constant-current drive circuit is sampled;
One bucking voltage generation unit, for generation of LED constant-current drive circuit in the needed bucking voltage value of corresponding busbar voltage;
One inductance peak current sampling resistor, samples for the peak current to inductance;
One adder unit, for being added the magnitude of voltage of peak current sampling resistor of LED constant-current drive circuit and the bucking voltage value that bucking voltage generation unit produces;
One comparator unit, for the reference voltage signal of the output valve of described adder unit and LED constant-current drive circuit is compared, produces a cut-off signals that power switch pipe is turn-offed;
One controls and driver element, for the output signal of described comparator unit is carried out to logic control, and then driving power switching tube and whole LED constant-current drive circuit is carried out to constant current control;
The output of described line voltage sample unit connects the input of described bucking voltage generation unit, the output of described bucking voltage generation unit connects an input of described adder unit, another input of described adder unit is also connected with described peak current sampling resistor, the output of described adder unit is connected with the input of described comparator unit, another input of described comparator unit is also connected with the reference voltage signal of LED constant-current drive circuit, the output of described comparator unit is connected with the input of driver element with described control, described control is connected with the input of power switch pipe and the input of described line voltage sample unit respectively with the output of driver element.
2. the line voltage compensation circuit driving for LED according to claim 1, is characterized in that: described line voltage sample unit comprises a switch control logic unit one fixed current source, the first switch, second switch and a sampling capacitance; The input of described switch control logic unit is connected with the output of driver element with described control; The output of described switch control logic unit is connected with the first switch and second switch respectively; One end of described the first switch connects described fixed current source, and its other end connects described sampling capacitance; One end of described second switch connects described sampling capacitance, its other end ground connection; One end ground connection of described sampling capacitance, its other end is also connected with described bucking voltage generation unit.
3. the line voltage compensation circuit driving for LED according to claim 1, is characterized in that: described line voltage sample unit, indirectly busbar voltage is sampled by the ON time TON of detection power switching tube.
4. the line voltage compensation circuit driving for LED according to claim 1, is characterized in that: described bucking voltage generation unit comprises an operational amplifier, the first resistance, the second resistance, one fixed current source, a nmos pass transistor, the first current mirror and the second current mirror; A positive input terminal of described operational amplifier is connected with the output of described line voltage sample unit, and negative input end is connected with described the first resistance, and its output is connected with the grid of described nmos pass transistor; Described first resistance one end ground connection, its other end is connected with the source electrode of described nmos pass transistor; One end of described the first current mirror is connected with the drain electrode of described nmos pass transistor, and its other end is connected with described the second current mirror; The other end of described the second current mirror is connected with described fixed current source; One end ground connection of described the second resistance, its other end is connected with described fixed current source, is connected with an input of described adder unit simultaneously.
5. according to the line voltage compensation circuit driving for LED described in claim 1~4 any one, it is characterized in that: the described line voltage compensation circuit driving for LED is for the power-supply system of isolating or the power-supply system of non-isolation.
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CN201420130014.0U CN203801121U (en) | 2014-03-21 | 2014-03-21 | Line voltage compensating circuit for LED driver |
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CN201420130014.0U CN203801121U (en) | 2014-03-21 | 2014-03-21 | Line voltage compensating circuit for LED driver |
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Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
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CN103841730A (en) * | 2014-03-21 | 2014-06-04 | 深圳市梓晶微科技有限公司 | Line voltage compensation circuit used for LED drive |
CN104569548A (en) * | 2014-12-30 | 2015-04-29 | 上海贝岭股份有限公司 | Line voltage detection circuit for switching power supply |
CN105517254A (en) * | 2016-01-28 | 2016-04-20 | 泉芯电子技术(深圳)有限公司 | LED power switch control method |
CN106020314A (en) * | 2016-03-11 | 2016-10-12 | 浙江盾安人工环境股份有限公司 | Constant current drive circuit |
CN106028498A (en) * | 2015-03-27 | 2016-10-12 | 美格纳半导体有限公司 | Current compensation circuit and light apparatus comprising the same |
WO2018210166A1 (en) * | 2017-05-19 | 2018-11-22 | 深圳市晟碟半导体有限公司 | Led driving device and constant power dimming circuit and dimming method therefor |
CN111740591A (en) * | 2020-07-23 | 2020-10-02 | 上海南麟电子股份有限公司 | Constant voltage switch power supply circuit with freewheeling diode voltage compensation |
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2014
- 2014-03-21 CN CN201420130014.0U patent/CN203801121U/en not_active Expired - Lifetime
Cited By (10)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103841730A (en) * | 2014-03-21 | 2014-06-04 | 深圳市梓晶微科技有限公司 | Line voltage compensation circuit used for LED drive |
CN103841730B (en) * | 2014-03-21 | 2016-05-04 | 深圳市梓晶微科技有限公司 | A kind of line voltage compensation circuit driving for LED |
CN104569548A (en) * | 2014-12-30 | 2015-04-29 | 上海贝岭股份有限公司 | Line voltage detection circuit for switching power supply |
CN106028498A (en) * | 2015-03-27 | 2016-10-12 | 美格纳半导体有限公司 | Current compensation circuit and light apparatus comprising the same |
CN106028498B (en) * | 2015-03-27 | 2019-04-05 | 美格纳半导体有限公司 | Current compensation circuit and lighting apparatus including current compensation circuit |
CN105517254A (en) * | 2016-01-28 | 2016-04-20 | 泉芯电子技术(深圳)有限公司 | LED power switch control method |
CN106020314A (en) * | 2016-03-11 | 2016-10-12 | 浙江盾安人工环境股份有限公司 | Constant current drive circuit |
WO2018210166A1 (en) * | 2017-05-19 | 2018-11-22 | 深圳市晟碟半导体有限公司 | Led driving device and constant power dimming circuit and dimming method therefor |
US10721799B2 (en) | 2017-05-19 | 2020-07-21 | Shenzhen Sendis Semiconductor Co., Ltd. | LED driving device, constant-power dimming circuit and dimming method thereof |
CN111740591A (en) * | 2020-07-23 | 2020-10-02 | 上海南麟电子股份有限公司 | Constant voltage switch power supply circuit with freewheeling diode voltage compensation |
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Granted publication date: 20140827 |