CN201557302U - Multiple-path PWM wave-chopping flow-equalizing circuit suitable for LED driver - Google Patents
Multiple-path PWM wave-chopping flow-equalizing circuit suitable for LED driver Download PDFInfo
- Publication number
- CN201557302U CN201557302U CN2009202692463U CN200920269246U CN201557302U CN 201557302 U CN201557302 U CN 201557302U CN 2009202692463 U CN2009202692463 U CN 2009202692463U CN 200920269246 U CN200920269246 U CN 200920269246U CN 201557302 U CN201557302 U CN 201557302U
- Authority
- CN
- China
- Prior art keywords
- amplifier
- output
- circuit
- current
- flow equalizing
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Fee Related
Links
Images
Landscapes
- Amplifiers (AREA)
Abstract
The utility model discloses a multiple-path PWM (pulse-width modulation) wave-chopping flow-equalizing circuit suitable for an LED (light emitting diode) driver, which includes a single-output constant flow source and a plurality of loads in parallel output, and each load is formed by a plurality of LEDs connected in series and is connected in series with a flow equalizing circuit and a flow-equalizing control circuit. The utility model is characterized in that the flow equalizing circuit consists of a compensating pipe and a sampling resistor which are connected in series; the input of each path of flow-equalizing control circuit comes from each path of sampling resistor sampling the path of current, and a common connection line is formed after the conversion by respective flow-equalizing control circuit and connected with other circuits to form a flow-equalizing bus; and each path of current sampling signal and flow-equalizing bus voltage generates PWM signals or high level signals after being compared and adjusted inside the flow-equalizing control circuit, and the signals can control the working duty cycle of the corresponding flow-equalizing circuit compensating pipe and the current magnitude of each path, and then realize flow equalization of current on each path.
Description
Technical field
The utility model relates to a kind of multi-channel PWM copped wave flow equalizing circuit that is applicable to led driver.Should be a kind of constant-current drive circuit that is used for LED, the technology of current-sharing between multichannel when realizing that the LED multi-path load is in parallel and use specifically in the mode of PWM copped wave.
Background technology
For the application of LED multiple constant current Control Driver, the most frequently used scheme has: 1. constant voltage module+multichannel non-isolation DC/DC constant-current circuit (as the BUCK circuit); 2. the adjustable Voltage stabilizing module of voltage+multi-channel linear is adjusted constant-current circuit.
For first kind of scheme, with reference to Fig. 1, the output of constant voltage module is as the input of multiple constant current circuit, and every road constant-current circuit is done constant current control separately, is easy to guarantee the current-sharing of multichannel output current.But since every road constant-current source need an independent control the DC/DC converter, so circuit complexity, cost height.
For second kind of scheme, with reference to Fig. 2, do linear the adjustment with metal-oxide-semiconductor or triode and realize multiple constant current control, the output voltage of prime Voltage stabilizing module is followed the linear circuit of adjusting of back level constant current, the output voltage of Voltage stabilizing module makes the linear circuit of adjusting can realize that in the output of every road the power consumption on the basis of accurate constant current control is approaching all the time minimum all the time than the highest Lu Lvegao of output voltage in the multi-channel linear adjustment constant-current circuit.Though this scheme circuit cost is low, the current sharing on every road is good, and short circuit is a LED common failure pattern, and when the pressure reduction of LED multi-path was bigger, the linear power consumption of adjusting pipe was very big, makes the led driver heating serious.
Summary of the invention
The utility model proposes the simple PWM flow equalizing circuit of a kind of usefulness at the problems referred to above, realize the constant current control of the well behaved multichannel output of current-sharing LED average current, and when LED multi-path pressure reduction was big, equalizing control circuit self does not produce big power consumption.
The technical scheme that addresses the above problem employing is: a kind of multi-channel PWM copped wave flow equalizing circuit that is applicable to led driver, comprise a single output constant-current source and multiplex output circuit, described single output constant-current source input termination AC-input voltage, output termination multiplex output circuit, described each output circuit comprises a flow equalizing circuit, an equalizing control circuit and the load of being made up of a plurality of LED lamps is characterized in that described flow equalizing circuit is composed in series by adjusting pipe and sampling resistor; The input of described every way equalizing control circuit is from the sampled signal of every road sampling resistor to this road electric current, through becoming public connecting line after the equalizing control circuit conversion separately and other each road links together, becomes the current-sharing bus; Every road current sampling signal and current-sharing bus voltage are after equalizing control circuit inside compares adjusting, produce pwm signal or high level signal, this signal is the work duty ratio size of the flow equalizing circuit adjustment pipe of may command correspondence then, control the size of every road electric current then, realize the current-sharing of each road electric current.
The beneficial effects of the utility model:
1. the main circuit of multi-channel PWM copped wave current-sharing and control circuit are simple in structure, and cost is low, and when LED multi-path pressure reduction was big, self did not produce big power consumption the multichannel equalizing control circuit.
2. multi-channel PWM copped wave flow equalizing circuit is independent of single output constant-current source, can be used as module and independently uses, and is applicable to the single channel constant-current supply of standard.When prime single channel constant-current source need change the current stabilization value because of light modulation, multi-channel PWM copped wave flow equalizing circuit still can keep every road electric current average current to divide equally automatically.
Description of drawings
The utility model is described in further detail below in conjunction with drawings and Examples.
Fig. 1 prior art circuits block diagram one.
Fig. 2 prior art circuits block diagram two.
One of Fig. 3 circuit structure block diagram of the present utility model.
Fig. 4 the utility model realize circuit structure one first kind of execution mode.
Fig. 5 the utility model realize circuit structure one second kind of execution mode.
Fig. 6 the utility model realize circuit structure one the third execution mode.
Fig. 7 the utility model realize circuit structure one the 4th kind of execution mode.
Fig. 8 the utility model realize circuit structure one the 5th kind of execution mode.
Fig. 9 the utility model realize circuit structure one the 6th kind of execution mode.
Specific embodiment
With reference to Fig. 3, the multi-channel PWM copped wave flow equalizing circuit that is applicable to led driver of the present utility model, comprise a single output constant-current source and multiplex output circuit, described single output constant-current source input termination AC-input voltage Vac, output termination multiplex output circuit, described each output circuit comprises a flow equalizing circuit, an equalizing control circuit and the load of forming by a plurality of LED lamps, described flow equalizing circuit is by adjusting pipe S1, ..., Sn and sampling resistor Rs1 ..., Rsn is composed in series; The input of described every way equalizing control circuit is from the sampled signal Vs1 of every road sampling resistor to this road electric current ..., Vsn through becoming public connecting line after the equalizing control circuit conversion separately and other each road links together, becomes the current-sharing bus; Every road current sampling signal Vs1, ..., Vsn and current-sharing bus voltage Vshare are after equalizing control circuit inside compares adjusting, produce pwm signal or high level signal, this signal is the work duty ratio size of the flow equalizing circuit adjustment pipe of may command correspondence then, control the size of every road electric current then, realize the current-sharing of each road electric current.
Set forth for convenient, a certain road load of being mentioned in the following statement of supposition here is the r road, and wherein r equals 1,2 ..., n.
With reference to Fig. 4, described AC-input voltage Vac gives each paths of LEDs electric as the input of constant-current source through output continuous current Io behind the constant-current source.Described LED load is that the LED lamp of multichannel n road a plurality of (m) series connection is formed as LED11 ... LEDm1 ..., LED1n ... LEDmn.
Wherein, the connected mode on a certain road is: described load LED1r ... the flow equalizing circuit r that LEDmr series connection back connection adjustment pipe MOSFET Sr and sampling resistor Rsr form;
The drain electrode of the metal-oxide-semiconductor Sr of described flow equalizing circuit r is connected to the LED load, and its source electrode is connected to the end of sampling resistor Rsr, and the other end of sampling resistor Rsr is connected to output ground, links to each other with constant-current source output ground;
Described equalizing control circuit r is by resistance R 1r, resistance R 2r, capacitor C r, amplifier IC1r, amplifier IC2r, compensating network and triangular signal are formed, an one terminating resistor R1r of the non-ground connection of described resistance R sr and the end of resistance R 2r, the end of another termination capacitor C r of resistance R 2r and the reverse input end of amplifier IC1r, the positive input of another termination amplifier IC1r of resistance R 1r, compensating network is connected between the reverse input end and output of amplifier IC1r, the output of amplifier IC1r is received the positive input of amplifier IC2r, triangular signal is as the reverse input end signal of amplifier IC2r, and the output of amplifier IC2r is received the gate pole of adjusting pipe Sr.
Described current-sharing bus interface is at amplifier IC1r positive input, and one of biasing resistor Rb terminates on the current-sharing bus, another termination power Vcc, the termination current-sharing bus of filter capacitor C0, another termination output ground.
In the described equalizing control circuit, the voltage that obtains on the described current-sharing bus is the average current signal Vshare=(V of each road output
S1..., V
Sn)/n and every road self current sampling signal (V
S1..., V
Sn) compare, if certain road load current is less than average current, then current sampling signal Vsr among the flow equalizing circuit r and average current signal Vshare are relatively, making amplifier IC1r output voltage is high level, this level surpasses the crest voltage of triangular signal, and comparator IC2r output is high level also, makes this road adjustment pipe Sr saturation conduction, when the bigger load road of other electric current when adjustment progressively reduces electric current, this road electric current progressively increases automatically up near average current; If certain road load current is greater than average current, then current sampling signal Vsr among this flow equalizing circuit r and average current signal Vshare are relatively, amplifier IC1r output voltage is progressively reduced, amplifier IC1r must export with triangular wave relatively after, comparator IC2r produces the PWM ripple, and the mean value of this road load current is progressively reduced up to the average current near each paths of LEDs; If certain road electric current equals average current, because the bias of resistance R b, then amplifier is output as high level, thereby this road adjustment is guaranteed adequate food and conducting.
Described load branch LED voltage is low more, and its amplifier IC2r output voltage is just low more, and the duty ratio of adjusting pipe Sr is more little, and is many more thereby the mean value of this paths of LEDs electric current reduces.Because the load road of big electric current is operated under the PWM copped wave state, so need and suitable filter capacitor C0 the filtering alternating current component on the current equalizer Vshare.R2r, Cr are that the current sampling signal to each road carries out filtering.
With reference to Fig. 5, described AC-input voltage Vac, constant-current source, equalizing control circuit 1 to equalizing control circuit n, LED load, the current-sharing bus, biasing resistor Rb, filter capacitor C0, and related connected mode is all identical with Fig. 4, different is that the adjustment pipe Sr in the flow equalizing circuit replaces with NPN type triode by the metal-oxide-semiconductor among Fig. 4;
The collector electrode of the triode Sr of described flow equalizing circuit r is connected to the LED load, its emitter is connected to the end of sampling resistor Rs1, the output that its base stage is received equalizing control circuit r is the output of amplifier IC2r, and the other end of sampling resistor Rs1 is connected to output ground.
It is operated in " saturated-as to end " or saturation condition described adjustment pipe NPN type triode Sr.
With reference to Fig. 6, described AC-input voltage Vac, constant-current source, the LED load, the current-sharing bus, biasing resistor Rb, filter capacitor C0, and related connected mode is all identical with Fig. 4, different is:
Adjustment pipe Sr in the described flow equalizing circuit replaces with the positive-negative-positive triode by the metal-oxide-semiconductor among Fig. 3, the end of the collector electrode connecting resistance Rsr of triode Sr, and its emitter connects the LED load, and the other end of sampling resistor Rs1 is connected to output ground; Described equalizing control circuit, in the base stage of the output termination NPN of IC2r type triode Qr, the emitter of Qr connects output ground, and the collector electrode of Qr connects the base stage of flow equalizing circuit adjustment pipe Sr.
NPN type triode Qr in described adjustment pipe positive-negative-positive triode Sr and the equalizing control circuit, all be operated in " saturated-by " or saturation condition.
Above Fig. 4, Fig. 5, adjusting pipe Sr among the embodiment of Fig. 6 also can be devices such as IGBT.
With reference to Fig. 7, described AC-input voltage Vac gives each paths of LEDs electric as the input of constant-current source through output continuous current Io behind the constant-current source.Described LED load is that the LED lamp of multichannel n road a plurality of (m) series connection is formed as LED11 ... LEDm1 ..., LED1n ... LEDmn.Described load LED1r ..., the flow equalizing circuit r that LEDmr series connection back connection adjustment pipe MOSFET Sr and sampling resistor Rsr form.
The drain electrode of the metal-oxide-semiconductor Sr of described flow equalizing circuit r is connected to the LED load, and its source electrode is connected to the end of sampling resistor Rs1, and the other end of sampling resistor Rs1 is connected to output ground, links to each other with constant-current source output ground.
Described equalizing control circuit r is by resistance R 1r, resistance R 2r, resistance R br, diode Dr, and amplifier IC1r, amplifier IC2r, amplifier IC3r, filter circuit, compensating network and triangular signal are formed.The input of the one termination filter circuit on the non-ground of described resistance R sr, the end of the output connecting resistance R1r of filter circuit and the positive input of amplifier IC3r, the reverse input end of amplifier IC3r connects anode and the current-sharing bus of diode Dr, the negative electrode of diode Dr connects the output of amplifier IC3r, the reverse input end of another termination amplifier IC1r of resistance R 1r, compensating network is connected between the reverse input end and output of amplifier IC1r, the positive input connecting resistance R2r of amplifier IC1r and the end of resistance R br, another termination current-sharing bus of resistance R 2r, another termination power Vcc anode of resistance R br, the output of amplifier IC1r is received the positive input of amplifier IC2r, triangular signal is as the positive input signal of amplifier IC2r, and the output of amplifier IC2r is received the gate pole of adjusting pipe Sr.
One of described biasing resistor Rb0 terminates on the current-sharing bus, another termination power Vcc anode, Vcc negativing ending grounding.
In the described equalizing control circuit, the circuit that amplifier IC3r and diode Dr form can be realized the minimum value of the voltage Vshare of current-sharing bus for each load branch current sampling signal, and wherein resistance R b0 is the biasing resistor of this circuit.This minimum value and every road self current sampling signal (V
S1..., V
Sn) compare.If certain road load current is greater than minimum current, then current sampling signal Vsr among this flow equalizing circuit r and minimum current signal Vshare are relatively, amplifier IC1r output voltage on the equalizing control circuit r progressively reduces, amplifier IC1r output and triangular wave relatively after, produce the PWM ripple, this road load current is progressively reduced; If certain road electric current equals minimum current, because the bias of resistance R br, then amplifier IC1r is output as high level, and this level is higher than the peak value of triangular signal in amplifier IC2r, make amplifier IC2r be output as high level, adjusts pipe Sr saturation conduction.Under this interaction, realize the current-sharing of each road load current.
Described load branch LED voltage is low more, and its amplifier IC2r output voltage is just low more, and the duty ratio of adjusting pipe Sr is more little, thereby the reduction of this paths of LEDs electric current is many more.Because the load road of big electric current is operated under the PWM copped wave state, so filter circuit carries out filtering to the current sampling signal on this road.
With reference to Fig. 8, described AC-input voltage Vac, constant-current source, equalizing control circuit 1 to equalizing control circuit n, the LED load, and connected mode is all identical with Fig. 7, different is that the adjustment pipe Sr in the flow equalizing circuit replaces with NPN type triode by the metal-oxide-semiconductor among Fig. 7.
The collector electrode of the triode Sr of described flow equalizing circuit r is connected to the LED load, its emitter is connected to the end of sampling resistor Rs1, the output that its base stage is received equalizing control circuit r is the output of amplifier IC2r, and the other end of sampling resistor Rs1 is connected to output ground.
It is operated in " saturated-as to end " or saturation condition described adjustment pipe NPN type triode Sr.
With reference to Fig. 9, described AC-input voltage Vac, constant-current source, the LED load, and connected mode is all identical with Fig. 7, different is:
Adjustment pipe Sr in the described flow equalizing circuit replaces with the positive-negative-positive triode by the metal-oxide-semiconductor among Fig. 3, the end of the collector electrode connecting resistance Rsr of triode Sr, and its emitter connects the LED load, and the other end of sampling resistor Rs1 is connected to output ground; In the base stage of the output termination NPN of IC2r type triode Qr, the emitter of Qr connects output ground in the described equalizing control circuit, and the collector electrode of Qr connects the base stage of flow equalizing circuit adjustment pipe Sr.
Above Fig. 7, Fig. 8, adjusting pipe Sr among the embodiment of Fig. 9 also can be devices such as IGBT.
At last, it is also to be noted that what more than enumerate only is specific embodiment of the utility model.Obviously, the utility model is not limited to above embodiment, and many distortion can also be arranged.All distortion that those of ordinary skill in the art can directly derive or associate from the disclosed content of the utility model all should be thought protection range of the present utility model.
Claims (11)
1. multi-channel PWM copped wave flow equalizing circuit that is applicable to led driver, comprise a single output constant-current source and multiplex output circuit, described single output constant-current source input termination AC-input voltage (Vac), output termination multiplex output circuit, described each multiplex output circuit comprises a flow equalizing circuit, an equalizing control circuit and the load of forming by a plurality of LED lamps, it is characterized in that described flow equalizing circuit is by adjusting pipe (S1, ..., Sn) and sampling resistor (Rs1, ..., Rsn) be composed in series; The input of described every way equalizing control circuit from every road sampling resistor to the sampled signal of this road electric current (Vs1 ..., Vsn),, become the current-sharing bus through becoming public connecting line after the equalizing control circuit conversion separately and other each road links together; Every road current sampling signal (Vs1, ..., Vsn) and current-sharing bus voltage (Vshare) after equalizing control circuit inside compares adjusting, produce pwm signal or high level signal, this signal is the work duty ratio size of the flow equalizing circuit adjustment pipe of may command correspondence then, control the size of every road electric current then, realize the current-sharing of each road electric current.
2. the multi-channel PWM copped wave flow equalizing circuit that is applicable to led driver as claimed in claim 1, adjustment pipe (the S1 that it is characterized in that described flow equalizing circuit, ..., first utmost point Sn) is connected to the LED load, and its second utmost point is connected to sampling resistor (Rs1, ..., Rsn) a end, sampling resistor (Rs1 ..., Rsn) an other end is connected to output ground, links to each other with constant-current source output ground; Described equalizing control circuit is by resistance R 1r, resistance R 2r, capacitor C r, amplifier IC1r, amplifier IC2, compensating network and triangular signal are formed, an one terminating resistor R1r of the non-ground connection of described resistance R sr and the end of resistance R 2r, the end of another termination capacitor C r of resistance R 2r and the reverse input end of amplifier IC1r, the positive input of another termination amplifier IC1r of resistance R 1r, compensating network is connected between the reverse input end and output of amplifier IC1r, the output of amplifier IC1r is received the positive input of amplifier IC2r, triangular signal is as the reverse input end signal of amplifier IC2r, and the output of amplifier IC2r is received the control utmost point of adjusting pipe Sr; Wherein: r represents r road output circuit, r=1, and 2 ..., n.
3. the multi-channel PWM copped wave flow equalizing circuit that is applicable to led driver as claimed in claim 2, adjustment pipe (the S1 that it is characterized in that described flow equalizing circuit, ..., Sn) being metal-oxide-semiconductor, its drain electrode is connected to the LED load, its source electrode is connected to sampling resistor (Rs1, ..., end Rsn), its gate pole is connected to amplifier (IC21, ..., output IC2n).
4. the multi-channel PWM copped wave flow equalizing circuit that is applicable to led driver as claimed in claim 2, adjustment pipe (the S1 that it is characterized in that described flow equalizing circuit, ..., Sn) being NPN type triode, its collector electrode is connected to the LED load, its emitter is connected to sampling resistor (Rs1, ..., end Rsn), its base stage is connected to amplifier (IC21, ..., output IC2n).
5. the multi-channel PWM copped wave flow equalizing circuit that is applicable to led driver as claimed in claim 2, it is characterized in that described flow equalizing circuit the adjustment pipe (S1 ..., Sn) be the positive-negative-positive triode, the amplifier of described equalizing control circuit (IC21 ..., output IC2n) is connected to a NPN type triode (Q1, ..., Qn) base stage, described adjustment pipe (S1 ..., Sn) emitter is connected to the LED load, its collector electrode be connected to sampling resistor (Rs1 ..., end Rsn), its base stage is connected to triode (Q1, ..., collector electrode Qn), triode (Q1, ..., grounded emitter Qn).
6. as any one described multi-channel PWM copped wave flow equalizing circuit that is applicable to led driver of claim 2-5, it is characterized in that also being provided with on the described current-sharing bus biasing resistor (Rb) and filter capacitor (C0), another termination power (Vcc) of described biasing resistor (Rb), the other end ground connection of described filter capacitor (C0).
7. the multi-channel PWM copped wave flow equalizing circuit that is applicable to led driver as claimed in claim 1, adjustment pipe (the S1 that it is characterized in that described flow equalizing circuit, ..., first utmost point Sn) is connected to the LED load, and its second utmost point is connected to sampling resistor (Rs1, ..., Rsn) a end, sampling resistor (Rs1 ..., Rsn) an other end is connected to output ground, links to each other with constant-current source output ground; Described equalizing control circuit comprises resistance R 1r, resistance R 2r, resistance R br, diode Dr, amplifier IC1r, amplifier IC2r, amplifier IC3r, filter circuit, compensating network and triangular signal, the input of the one termination filter circuit on the non-ground of described resistance R sr, the end of the output connecting resistance R1r of filter circuit and the positive input of amplifier IC3r, the reverse input end of amplifier IC3r connects anode and the current-sharing bus of diode Dr, the negative electrode of diode Dr connects the output of amplifier IC3r, the reverse input end of another termination amplifier IC1r of resistance R 1r, compensating network is connected between the reverse input end and output of amplifier IC1r, the positive input connecting resistance R2r of amplifier IC1r and the end of resistance R br, another termination current-sharing bus of resistance R 2r, another termination power Vcc anode of resistance R br, the output of amplifier IC1r is received the positive input of amplifier IC2r, triangular signal is as the positive input signal of amplifier IC2r, and the output of amplifier IC2r is received the gate pole of adjusting pipe Sr; Wherein: r represents r road output circuit, r=1, and 2 ..., n.
8. the multi-channel PWM copped wave flow equalizing circuit that is applicable to led driver as claimed in claim 7, adjustment pipe (the S1 that it is characterized in that described flow equalizing circuit, ..., Sn) being metal-oxide-semiconductor, its drain electrode is connected to the LED load, its source electrode is connected to sampling resistor (Rs1, ..., end Rsn), its gate pole is connected to amplifier (IC21, ..., output IC2n).
9. the multi-channel PWM copped wave flow equalizing circuit that is applicable to led driver as claimed in claim 7, adjustment pipe (the S1 that it is characterized in that described flow equalizing circuit, ..., Sn) being NPN type triode, its collector electrode is connected to the LED load, its emitter is connected to sampling resistor (Rs1, ..., end Rsn), its base stage is connected to amplifier (IC21, ..., output IC2n).
10. the multi-channel PWM copped wave flow equalizing circuit that is applicable to led driver as claimed in claim 7, it is characterized in that described flow equalizing circuit the adjustment pipe (S1 ..., Sn) be the positive-negative-positive triode, the amplifier of described equalizing control circuit (IC21 ..., output IC2n) is connected to a NPN type triode (Q1, ..., Qn) base stage, described adjustment pipe (S1 ..., Sn) emitter is connected to the LED load, its collector electrode be connected to sampling resistor (Rs1 ... .., end Rsn), its base stage is connected to triode (Q1, ..., collector electrode Qn), triode (Q1, ..., grounded emitter Qn).
11., it is characterized in that also being provided with on the described current-sharing bus biasing resistor (Rb0), another termination power (Vcc) of described biasing resistor (Rb0) as any one described multi-channel PWM copped wave flow equalizing circuit that is applicable to led driver of claim 7-10.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN2009202692463U CN201557302U (en) | 2009-11-12 | 2009-11-12 | Multiple-path PWM wave-chopping flow-equalizing circuit suitable for LED driver |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN2009202692463U CN201557302U (en) | 2009-11-12 | 2009-11-12 | Multiple-path PWM wave-chopping flow-equalizing circuit suitable for LED driver |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN201557302U true CN201557302U (en) | 2010-08-18 |
Family
ID=42616991
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN2009202692463U Expired - Fee Related CN201557302U (en) | 2009-11-12 | 2009-11-12 | Multiple-path PWM wave-chopping flow-equalizing circuit suitable for LED driver |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN201557302U (en) |
Cited By (8)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102487568A (en) * | 2010-12-01 | 2012-06-06 | 海洋王照明科技股份有限公司 | De-jittering control method for LED light source and circuit thereof |
| CN102611300A (en) * | 2012-04-05 | 2012-07-25 | 重庆安谐新能源技术有限公司 | Current-sharing control device of direct-current and current-sharing input system |
| WO2012136030A1 (en) * | 2011-04-02 | 2012-10-11 | 英飞特电子(杭州)有限公司 | Circuit for adjusting led current |
| CN101702849B (en) * | 2009-11-12 | 2012-12-12 | 英飞特电子(杭州)股份有限公司 | Multi-path PWM chopped wave current sharing circuit for LED driver |
| CN103096569A (en) * | 2011-11-08 | 2013-05-08 | 英飞特电子(杭州)股份有限公司 | Current-sharing circuit applicable to multi-channel loading |
| CN103179757A (en) * | 2013-03-25 | 2013-06-26 | 浙江海振电子科技有限公司 | Time-sharing multi-path constant current driving light emitting diode (LED) lamp |
| CN104853506A (en) * | 2014-11-25 | 2015-08-19 | 成都冠深科技有限公司 | Gate driving type blue light LED protection system based on multipath output voltage stabilizing power supply |
| CZ305489B6 (en) * | 2013-04-22 | 2015-10-29 | Varroc Lighting Systems, s.r.o. | Pulse-switched controller for LED lighting of LED power supply module of lighting fixtures in automobile applications provided light sources with LED and power supply module of LED function and excitation |
-
2009
- 2009-11-12 CN CN2009202692463U patent/CN201557302U/en not_active Expired - Fee Related
Cited By (12)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN101702849B (en) * | 2009-11-12 | 2012-12-12 | 英飞特电子(杭州)股份有限公司 | Multi-path PWM chopped wave current sharing circuit for LED driver |
| CN102487568A (en) * | 2010-12-01 | 2012-06-06 | 海洋王照明科技股份有限公司 | De-jittering control method for LED light source and circuit thereof |
| CN102487568B (en) * | 2010-12-01 | 2014-01-01 | 海洋王照明科技股份有限公司 | De-jittering control method for LED light source and circuit thereof |
| WO2012136030A1 (en) * | 2011-04-02 | 2012-10-11 | 英飞特电子(杭州)有限公司 | Circuit for adjusting led current |
| US9018845B2 (en) | 2011-04-02 | 2015-04-28 | Inventronics (Hangzhou), Inc. | Circuit for adjusting LED current |
| CN103096569A (en) * | 2011-11-08 | 2013-05-08 | 英飞特电子(杭州)股份有限公司 | Current-sharing circuit applicable to multi-channel loading |
| CN102611300A (en) * | 2012-04-05 | 2012-07-25 | 重庆安谐新能源技术有限公司 | Current-sharing control device of direct-current and current-sharing input system |
| CN103179757A (en) * | 2013-03-25 | 2013-06-26 | 浙江海振电子科技有限公司 | Time-sharing multi-path constant current driving light emitting diode (LED) lamp |
| CN103179757B (en) * | 2013-03-25 | 2015-07-08 | 浙江海振电子科技有限公司 | Time-sharing multi-path constant current driving light emitting diode (LED) lamp |
| CZ305489B6 (en) * | 2013-04-22 | 2015-10-29 | Varroc Lighting Systems, s.r.o. | Pulse-switched controller for LED lighting of LED power supply module of lighting fixtures in automobile applications provided light sources with LED and power supply module of LED function and excitation |
| US9338842B2 (en) | 2013-04-22 | 2016-05-10 | Varroc Lighting Systems, s.r.o. | Pulse switched resistor driver |
| CN104853506A (en) * | 2014-11-25 | 2015-08-19 | 成都冠深科技有限公司 | Gate driving type blue light LED protection system based on multipath output voltage stabilizing power supply |
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| CN101702849B (en) | Multi-path PWM chopped wave current sharing circuit for LED driver | |
| CN201557302U (en) | Multiple-path PWM wave-chopping flow-equalizing circuit suitable for LED driver | |
| CN101674693B (en) | Multichannel constant-current control circuit applicable to LED driver | |
| CN101754541B (en) | DC bus voltage following control circuit suitable for multi-path parallel LEDs | |
| CN101916548B (en) | Control circuit of light-emitting diode (LED) lamp tube of liquid crystal display | |
| CN201667742U (en) | LED backlight driving device of light emitting diode and liquid crystal display | |
| CN102118905B (en) | Circuit suitable for multi-path LED current-sharing control | |
| CN102300355B (en) | Light emitting diode (LED) dimming system | |
| CN107155238B (en) | A kind of multiple-channel output constant current driver circuit for LED and driving method | |
| CN103503563A (en) | Dimmable LED driver and method for controlling same | |
| CN103139992A (en) | Light-emitting diode (LED) dimming driving system with silicon controlled bypass dimming circuit | |
| CN201657405U (en) | Circuit applicable to current-sharing control on multiple LEDs | |
| CN201550320U (en) | Multipath constant current control circuit suitable for LED drivers | |
| CN102821526B (en) | The circuit of LED electrical pressure adaptive PWM light modulation is realized under constant-current source pre-driver | |
| CN104661392A (en) | Constant-current driving circuit for LED switch | |
| CN203193980U (en) | Drive circuit for multi-channel dimmable LED (light-emitting diode) lamp tube | |
| CN101827478B (en) | Energy recovering system driven by multi-path parallelly-connected LEDs | |
| CN201781654U (en) | DC bus voltage following type control circuit applicable to LEDs adopting multi-path parallel connection | |
| CN201708995U (en) | LED constant current drive circuit and output voltage adjustable circuit | |
| CN201742607U (en) | LED dimming system | |
| US20130187551A1 (en) | Method and System for Driving LEDs from a Source of Rectified AC Voltage | |
| CN202083974U (en) | Load driving circuit | |
| CN105208750A (en) | LED constant current driving device | |
| TWI716152B (en) | Dimming circuit, dimmer having the same and controller thereof | |
| CN201830527U (en) | High-power LED (light emitting diode) driving power supply |
Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| C14 | Grant of patent or utility model | ||
| GR01 | Patent grant | ||
| C17 | Cessation of patent right | ||
| CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20100818 Termination date: 20121112 |