CN203775494U - An LED driving device and an LED dimming driving controller thereof - Google Patents

Abstract

The utility model belongs to the technical field of LED driving and provides an LED driving device and an LED dimming driving controller thereof. No peripheral voltage detection circuit is needed and the circuit cost is low. When a timing judging module determines that the time from start to reset of the LED dimming driving controller is greater than a preset time threshold, a counting module outputs a switching counting signal and a signal delay module outputs a dimming enabling signal, a latch makes a voltage selector to adjust output voltage stage by stage so that a constant current control circuit in the LED dimming driving controller controls peak current and switching frequency of a dimming power tube and multi-stage dimming for an LED load is achieved. If the preset time threshold is greater than the time lasting from the start to the resetting during hiccup of an internal power supply source of the LED dimming driving controller, the latch does not make the voltage selector adjust the output voltage and the dimming power tube enables the LED load to maintain the original brightness, so that the error dimming is prevented and the dimming reliability is improved.

Description

A kind of LED drive unit and LED light modulation driving governor thereof

Technical field

The utility model belongs to LED Driving technique field, relates in particular to a kind of LED drive unit and LED light modulation driving governor thereof.

Background technology

At present, in LED lighting field, there is the method that LED light-emitting device is realized to multistage light modulation, it carries out the switch motion repeating to realize multistage dimming function by the switch to LED light-emitting device, and user can freely adjust LED light-emitting device to obtain own needed light-source brightness by this function.

The light modulation scheme that prior art provides is that the detection pin by driving chip coordinates peripheral resistance and capacitor element to detect the switch of AC power, again connect when detecting that AC power is had no progeny in pass, drive chip controls power tube to carry out brightness regulation one time to LED.But above-mentioned light modulation scheme drives the peripheral components of chip owing to having increased, so increased cost, and if peripheral components breaks down, can make to drive the light modulation reliability of chip to reduce.

Moreover in actual applications, LED socket can exist little electric current in the time turn-offing, this little electric current can make to drive the internal power supply of chip, and (voltage is V _dD) there is " having the hiccups " phenomenon (as shown in Figure 1), this can cause driving chip to take for AC power generation switch motion and power ratio control pipe carries out brightness regulation one time to LED, thereby causes the problem of mistuning light.

In sum, prior art exists that light modulation reliability is low, cost is high and easily " has the hiccups " and cause the problem of mistuning light because of chip internal power supply.

Utility model content

The purpose of this utility model is to provide a kind of LED light modulation driving governor, is intended to solve that the existing light modulation reliability of prior art is low, cost is high and easily " have the hiccups " and cause the problem of mistuning light because of chip internal power supply.

The utility model is to realize like this, a kind of LED light modulation driving governor, it comprises constant-current control circuit, described constant-current control circuit is by the feedback end of described LED light modulation driving governor, voltage end, sampling end, compensation end, drain electrode end, gate pole end and ground end are connected with the circuit in LED drive unit, wherein, described gate pole end and described sampling end are connected respectively grid and the source electrode of light modulation power tube, the source electrode of described light modulation power tube is also connected to ground by a sampling resistor, described light modulation power tube carries out brilliance control to the LED load of described LED drive unit, the supply voltage of described voltage end raises in the time that the AC power of described LED drive unit is connected, and decline in the time that described AC power disconnects,

Described LED light modulation driving governor also comprises:

The first comparator, the second comparator, timing judge module, counting module, signal lag module, latch and voltage selector;

The first input end of described the first comparator and the second input access respectively starting resistor and resetting voltage, the 3rd input of described the first comparator, the first input end of described the second comparator, the power end of the power end of described timing judge module and described signal lag module all connects the voltage end of described LED light modulation driving governor, the second input access threshold voltage of described the second comparator, the output of described the first comparator connects the input of described timing judge module and the input of described counting module simultaneously, the output of described timing judge module, the output of the output of described counting module and described signal lag module all connects described latch, described latch also connects described voltage selector, described voltage selector connects described constant-current control circuit.

Another object of the present utility model is to provide a kind of LED drive unit, and it carries out light modulation driving to LED load, and comprises light modulation power tube and above-mentioned LED light modulation driving governor.

The utility model by adopting the LED light modulation driving governor that comprises the first comparator, the second comparator, timing judge module, counting module, signal lag module, latch and voltage selector in LED drive unit, it does not need to configure peripheral voltage testing circuit, and circuit cost is low, judge from starting timing to the time (being that LED light modulation driving governor is from starting to the time of reset) of reset signal that receives the first comparator output while being greater than Preset Time threshold value, counting module output switch count signal and signal lag module output light modulation enable signal at timing judge module, latch control voltage selector step by step regulation output voltage so that peak current and the switching frequency of the constant-current control circuit control light modulation power tube in LED light modulation driving governor, carries out multi-level brightness adjusting thereby realize to LED load, due to Preset Time threshold value be greater than LED light modulation driving governor therein power supply when " having the hiccups " state from starting to the time of reset, latch is not controlled voltage selector regulation output voltage, so that light modulation power tube control LED load keeps original brightness, thereby avoid occurring the problem of mistuning light in the time that the internal power supply of LED light modulation driving governor " is had the hiccups ", promote light modulation reliability, solve the existing light modulation reliability of prior art low, cost is high and easily " have the hiccups " and cause the problem of mistuning light because of chip internal power supply.

Brief description of the drawings

Fig. 1 is the internal power source voltage V that the related LED of background technology drives chip _dDwhile " having the hiccups " and dimmer voltage V _aDJcorresponding oscillogram;

Fig. 2 is the modular structure figure of the LED light modulation driving governor that provides of the utility model embodiment;

Fig. 3 is the supply voltage V of the LED light modulation driving governor shown in Fig. 2 _dDoutput voltage V with voltage selector _aDJcorresponding oscillogram;

Fig. 4 is the supply voltage V of the LED light modulation driving governor shown in Fig. 2 _dDwhile " having the hiccups " and the output voltage V of voltage selector _aDJcorresponding oscillogram;

Fig. 5 is the exemplary circuit structure chart of the timing judge module in the LED light modulation driving governor that provides of the utility model embodiment;

Fig. 6 is the exemplary circuit structure chart of the counting module in the LED light modulation driving governor that provides of the utility model embodiment;

Fig. 7 is the exemplary circuit structure chart of the signal lag module in the LED light modulation driving governor that provides of the utility model embodiment;

Fig. 8 is the circuit structure diagram of the LED drive unit that provides of the utility model the first embodiment;

Fig. 9 is the circuit structure diagram of the LED drive unit that provides of the utility model the second embodiment;

Figure 10 is the circuit structure diagram of the LED drive unit that provides of the utility model the 3rd embodiment.

Embodiment

In order to make the purpose of this utility model, technical scheme and advantage clearer, below in conjunction with drawings and Examples, the utility model is further elaborated.Should be appreciated that specific embodiment described herein is only in order to explain the utility model, and be not used in restriction the utility model.

Fig. 2 shows the modular structure of the LED light modulation driving governor that the utility model embodiment provides, and for convenience of explanation, only shows the part relevant to the utility model embodiment, and details are as follows:

The LED light modulation driving governor 100 that the utility model embodiment provides comprises constant-current control circuit 200, constant-current control circuit 200 is by the feedback end FB of LED light modulation driving governor 100, voltage end VDD, sampling end CS, compensation end COMP, drain electrode end DRAIN, gate pole end GATE and ground end GND are connected with the circuit in LED drive unit, wherein, gate pole end GATE and the sampling end CS of LED light modulation driving governor 100 is connected respectively grid and the source electrode of light modulation power tube Q1, the source electrode of light modulation power tube Q1 is also connected to ground by a sampling resistor Rcs, light modulation power tube Q1 carries out brilliance control (be other circuit modules the electric current adjustment of LED load 300 is realized to brilliance control) in light modulation power tube Q1 cooperated with LED drive unit to the LED load 300 of LED drive unit, the supply voltage V of voltage end VDD _dDin the time that the AC power AC of LED drive unit connects, raise, and decline in the time that AC power AC disconnects.Wherein, LED light modulation driving governor 100 also have a sky connect end NC; Light modulation power tube Q1 is NMOS pipe in the utility model embodiment.

LED light modulation driving governor 100 also comprises the first comparator 101, the second comparator 102, timing judge module 103, counting module 104, signal lag module 105, latch 106 and voltage selector 107.

The first input end of the first comparator 101 and the second input access respectively starting resistor V _hwith resetting voltage V _lthe 3rd input of the first comparator 101, the first input end of the second comparator 102, the power end of timing judge module 103 and the power end of signal lag module 105 all connect the voltage end VDD of LED light modulation driving governor, the second input access threshold voltage V of the second comparator 102 _tRthe output of the first comparator 101 connects the input of timing judge module 103 and the input of counting module 104 simultaneously, the output of the output of timing judge module 103, the output of counting module 104 and signal lag module 105 all connects latch 106, latch 106 also connects voltage selector 107, and voltage selector 107 connects constant-current control circuit 200.

The first comparator 101 is by supply voltage V _dDwith starting resistor V _hand resetting voltage V _lcompare, and according to comparative result output enabling signal or reset signal to timing judge module 103 and counting module 104; The second comparator 102 is by supply voltage V _dDwith threshold voltage V _tRcompare, and according to comparative result output light modulation enable signal or light modulation shutdown signal, light modulation enable signal or light modulation shutdown signal after carrying out delay process, signal lag module 105 export latch 106 to; Counting module 104 is successively receiving starting resistor V _hand resetting voltage V _ltime output switch count signal to latch 106, and the enabling signal that timing judge module 103 is first exported according to the first comparator 101 starts timing, and in the time receiving the reset signal that the first comparator 101 exports, judge from starting timing to the time that receives this reset signal whether be greater than Preset Time threshold value, if, export the qualified signal of timing to latch 106, if not, export timing failure signal to latch 106.Wherein, Preset Time threshold value be greater than LED light modulation driving governor 100 therein power supply in the time of " having the hiccups " state from starting to the time of reset; In fact refer to supply voltage V from starting timing to the time that receives described reset signal _dDfrom rising to starting resistor V _hafter drop to again resetting voltage V _ltime, namely LED light modulation driving governor 100 is from starting to the time of reset.

Latch 106 is exported digital dimming signal to voltage selector 107 in the time receiving the qualified signal of timing that light modulation enable signal that the second comparator 102 exports, switch count signal that counting module 104 is exported and timing judge module 103 export, voltage selector 107 is adjusted into the dimmer voltage corresponding with next stage LED brightness according to this digital dimming signal by output voltage, and constant-current control circuit 200 is adjusted peak current and the switching frequency of light modulation power tube Q1 according to this dimmer voltage.

Latch 106 is not exported digital dimming signal in the time receiving the timing failure signal that light modulation shutdown signal that the second comparator 102 exports or timing judge module 103 export or do not receive the switch count signal that counting module 104 exports, voltage selector 107 is not adjusted output voltage, and constant-current control circuit 200 is not adjusted peak current and the switching frequency of light modulation power tube Q1.

In addition, after AC power AC connects first, the first comparator 101 is at supply voltage V _dDrise to starting resistor V _htime export above-mentioned enabling signal to timing judge module 103 and counting module 104, timing judge module 103 starts timing according to enabling signal but does not export the qualified signal of above-mentioned timing or timing failure signal, counting module 104 is not exported above-mentioned switch count signal yet, the second comparator 102 also can be exported light modulation enable signal to latch 106, latch 106 is controlled voltage selector 107 and is exported initial dimmer voltage, and constant-current control circuit 200 is adjusted peak current and the switching frequency of light modulation power tube Q1 according to this initial dimmer voltage.

Particularly, suppose that LED light modulation driving governor 100 that the utility model embodiment provides is for realizing three grades of light modulations to LED load 300.After AC power AC connects first, supply voltage V _dDstart to rise to starting resistor V _h, now, the first comparator 101 can be exported high level (being above-mentioned enabling signal) to timing judge module 103 and counting module 104, due to supply voltage V _dDnot yet drop to resetting voltage V _l, so starting timing, timing judge module 103 do not export any signal, counting module 104 is exported " 00 " level (being zero output) to latch 106, the second comparator 102 can be exported high level (being above-mentioned light modulation enable signal), so latch 106 keeps initial condition and controls voltage selector 107 and export first order dimmer voltage (being above-mentioned initial dimmer voltage), constant-current control circuit 200 in LED light modulation driving governor 100 makes light modulation power tube Q1 according to corresponding peak current and switching frequency work according to first order dimmer voltage, so that LED load 300 is luminous according to the brightness corresponding with first order dimmer voltage.While being disconnected after AC power AC connects first, supply voltage V _dDcan decline, when dropping to resetting voltage V _ltime, the first comparator 101 meeting output low levels (being above-mentioned reset signal), counting module 104 (is above-mentioned switch count signal according to this low level output " 01 " logic level, corresponding decimal number 1) to latch 106, the low level judgement that timing judge module 103 can be exported according to the first comparator 101 is simultaneously greater than Preset Time threshold value from starting timing to receiving this low level time, and export the qualified signal of timing to latch 106, supply voltage V subsequently _dDcan be from resetting voltage V _lplace continues to decline, at supply voltage V _dDdrop to resetting voltage V _lwith threshold voltage V _tRbetween time, the second comparator 102 can be exported high level (being above-mentioned light modulation enable signal) by entering latch 106 after 105 time delays of signal lag module, " 01 " logic level, the timing judge module 103 that latch 106 is exported according to counting module 104 exported the qualified signal of timing and the high level through 105 time delays of signal lag module, controls voltage selector 107 output voltage is adjusted into second level dimmer voltage.In the time that AC power AC connects again, constant-current control circuit 200 in LED light modulation driving governor 100 is adjusted the peak current of light modulation power tube Q1 and switching frequency to change the electric current of LED load 300 according to second level dimmer voltage, thereby makes LED load 300 luminous according to the brightness corresponding with second level dimmer voltage.

While disconnection again after AC power AC connects for the second time, owing to being that AC power AC switches on and off normally, so low level output " 10 " logic level (corresponding decimal number 2) that counting module 104 is exported according to the first comparator 101, the low level judgement that timing judge module 103 still can be exported according to the first comparator 101 is greater than Preset Time threshold value from starting timing to receiving this low level time, and export the qualified signal of timing to latch 106, at supply voltage V _dDdrop to resetting voltage V _lwith threshold voltage V _tRbetween time, the second comparator 102 can be exported high level (being above-mentioned light modulation enable signal) by entering latch 106 after 105 time delays of signal lag module, and therefore latch 106 can be controlled again voltage selector 107 output voltage is adjusted into third level dimmer voltage.In the time that AC power AC connects for the third time, constant-current control circuit 200 in LED light modulation driving governor 100 is adjusted the peak current of light modulation power tube Q1 and switching frequency to change the electric current of LED load 300 according to third level dimmer voltage, thereby makes LED load 300 luminous according to the brightness corresponding with third level dimmer voltage.

While disconnection again after AC power AC connects for the third time, low level output " 11 " logic level (corresponding decimal number 3) that counting module 104 is exported according to the first comparator 101, the low level judgement that timing judge module 103 still can be exported according to the first comparator 101 is greater than Preset Time threshold value from starting timing to receiving this low level time (being that LED light modulation driving governor 100 is from starting to the time of reset), and export the qualified signal of timing to latch 106, at supply voltage V _dDdrop to resetting voltage V _lwith threshold voltage V _tRbetween time, the second comparator 102 can output high level (being above-mentioned light modulation enable signal) by entering latch 106 after 105 time delays of signal lag module, therefore latch 106 can be controlled voltage selector 107 output voltage is returned and is adjusted into first order dimmer voltage.

According to the switch of said process repetitive control AC power AC, just can control by LED light modulation driving governor 100 peak current and the switching frequency of light modulation power tube Q1, to realize, LED load 300 is carried out to three grades of light modulations, supply voltage V _dDoutput voltage V with voltage selector 107 _aDJcorresponding oscillogram as shown in Figure 3, t1, t2 and t3 be respectively LED light modulation driving governor 100 AC power AC first, for the second time and for the third time when switch from starting to the time of reset, V1, V2 and V3 are respectively above-mentioned first order dimmer voltage, second level dimmer voltage and third level dimmer voltage.

If AC power AC is access failure after disconnection, supply voltage V _dDcan drop to threshold voltage V _tRbelow, the second comparator 102 can output low level (being above-mentioned light modulation shutdown signal) enter latch 106 by signal lag module 105, output voltage is returned and is adjusted to initial first order dimmer voltage according to this low level control voltage selector 107 by latch 106, be now equivalent to light modulation reset operation.

In the time that AC power AC disconnects, because LED lamp socket exists little electric current, so supply voltage V _dDcan enter " having the hiccups " state (as shown in Figure 4).Now timing judge module 103 can judge supply voltage V by timing _dDfrom rising to starting resistor V _hafter drop to again resetting voltage V _ltime, owing to being the voltage fluctuation that little electric current causes, so (equal supply voltage V from starting timing to the time (being that LED light modulation driving governor 100 is from starting to the time of reset) that receives the reset signal that the first comparator 101 exports _dDvoltage wave cycle, as the t1 of dash area in Fig. 4, t2 and t3) can be less than Preset Time threshold value, timing judge module 103 can be exported timing failure signal to latch 106, so that latch 106 is controlled voltage selector 107, to maintain current output voltage (second level dimmer voltage V2 shown in Fig. 4) constant, the constant-current control circuit 200 in LED light modulation driving governor 100 is not adjusted peak current and the switching frequency of light modulation power tube Q1, there is not brightness regulation in LED load 300, thereby avoid the generation of mistuning optical phenomenon, promote the light modulation reliability of LED light modulation driving governor 100.

Taking above-mentioned LED light modulation driving governor 100, for LED load 300 being realized to three grades of light modulations as example, the particular circuit configurations in detailed description LED light modulation driving governor 100 is as follows:

As shown in Figure 5, timing judge module 103 comprises:

The first d type flip flop U1, the second d type flip flop U2,3d flip-flop U3, four d flip-flop U4 and the 5th d type flip flop U5;

The power end VDD of power end VDD, four d flip-flop U4 and the power end VDD of the 5th d type flip flop U5 of power end VDD, the 3d flip-flop U3 of the power end VDD of the first d type flip flop U1 and the second d type flip flop U2 connect the power end of formed common contact as timing judge module 103 altogether, the input D of the first d type flip flop U1 is the input of timing judge module 103, and the input D of the first d type flip flop U1 is connected with reversed-phase output QB, the clock end CLK incoming clock signal S of the first d type flip flop U1 _cLK1, the Enable Pin SB of the Enable Pin SB of the first d type flip flop U1 and the second d type flip flop U2, the Enable Pin SB of 3d flip-flop U3, the Enable Pin SB of the Enable Pin SB of four d flip-flop U4 and the 5th d type flip flop U5 all accesses enable signal EN, the clock end CLK of the second d type flip flop U2 connects the in-phase output end Q of the first d type flip flop U1, the input D of the second d type flip flop U2 is connected with reversed-phase output QB, the clock end CLK of 3d flip-flop U3 connects the in-phase output end Q of the second d type flip flop U2, the input D of 3d flip-flop U3 is connected with reversed-phase output QB, the clock end CLK of four d flip-flop U4 connects the in-phase output end Q of 3d flip-flop U3, the input D of four d flip-flop U4 is connected with reversed-phase output QB, the clock end CLK of the 5th d type flip flop U5 connects the in-phase output end Q of four d flip-flop U4, the input D of the 5th d type flip flop U5 is connected with reversed-phase output QB, the in-phase output end Q of the 5th d type flip flop U5 is the output of timing judge module 103.

As shown in Figure 6, counting module 104 comprises:

The 6th d type flip flop U6, the 7th d type flip flop U7 and the 8th d type flip flop U8;

The Enable Pin RB of the Enable Pin RB of the Enable Pin RB of the 6th d type flip flop U6 and the 7th d type flip flop U7 and the 8th d type flip flop U8 all accesses enable signal EN, the input D of the 6th d type flip flop U6 is the input of counting module 104, and the input D of the 6th d type flip flop U6 is connected with reversed-phase output QB, the clock end CLK incoming clock signal S of the 6th d type flip flop U6 _cLK2the in-phase output end Q of the in-phase output end Q of the 6th d type flip flop U6 and the 7th d type flip flop U7 forms the output of counting module 104 jointly, and the clock end CLK of the 7th d type flip flop U7 connects the in-phase output end Q of the 6th d type flip flop U6, the input D of the 7th d type flip flop U7 is connected with reversed-phase output QB, the clock end CLK of the 8th d type flip flop U8 connects the in-phase output end Q of the 7th d type flip flop U7, the input D of the 8th d type flip flop U8 is connected with reversed-phase output QB, and the in-phase output end Q sky of the 8th d type flip flop U8 connects.

Wherein, the in-phase output end Q of the 6th d type flip flop U6 in counting module 104 and the in-phase output end Q of the 7th d type flip flop U7 composition binary logic level output port are to export two binary switch count signals, " 01 " described above, " 10 " and " 11 ", corresponding decimal number " 1 ", " 2 " and " 3 " respectively, count the on-off times of AC power AC thereby realize.

As shown in Figure 7, signal lag module 105 comprises:

The one NMOS pipe N1, resistance R, the 2nd NMOS pipe N2, current source I1, capacitor C, Schmidt trigger Smit and inverter INV;

The grid of the one NMOS pipe N1 is the input of signal lag module 105, source electrode and the substrate of the one NMOS pipe N1 are connected to ground altogether, the one NMOS pipe drain electrode of N1 and the first end of resistance R are connected to the grid of the 2nd NMOS pipe N2 altogether, the common contact of the second end of resistance R and the input of current source I1 is the power end of signal lag module 105, source electrode and the substrate of the 2nd NMOS pipe N2 are connected to ground altogether, the drain electrode of the 2nd NMOS pipe N2 and the output of current source I1 and the first end of capacitor C are connected to the input of Schmidt trigger Smit altogether, the second end ground connection of capacitor C, the output of Schmidt trigger Smit connects the input of inverter INV, the output of inverter INV is the output of signal lag module 105.

Wherein, in the time that the grid of a NMOS pipe N1 receives the high level (being above-mentioned light modulation enable signal) that the second comparator 102 exports, the one NMOS pipe N1 conducting also drags down the grid potential of the 2nd NMOS pipe N2 so that the 2nd NMOS pipe N2 turn-offs, the electric current of current source I1 output charges to capacitor C, Schmidt trigger Smit overturns and processes rear output low level the voltage of capacitor C, and this low level is exported high level after the anti-phase processing of inverter INV; In like manner, in the time that the grid of a NMOS pipe N1 receives the low level (being above-mentioned light modulation shutdown signal) that the second comparator 102 exports, a NMOS pipe N1 turn-offs, and the grid of the 2nd NMOS pipe N2 obtains supply voltage V by resistance R _dDthe 2nd NMOS manages N2 conducting and the voltage of the input of Schmidt trigger Smit is dragged down, Schmidt trigger Smit overturns the low level of input to process rear output high level, this high level is output low level after the anti-phase processing of inverter INV, thereby realized, signal is carried out to delay process.

Latch 106 is the conventional sequential logical circuit that once can store multidigit binary number being made up of several clock d type flip flops.

Voltage selector 107 is the conventional voltage follower circuit that comprises multidiameter option switch branch road, its logic level gating of exporting according to latch 106 wherein a road selector switch branch road to export corresponding dimmer voltage.

LED light modulation driving governor 100 based on above-mentioned, the utility model embodiment also provides a kind of LED drive unit, and it carries out light modulation driving to LED load 300, and comprises above-mentioned light modulation power tube Q1 and LED light modulation driving governor 100.

In the utility model the first embodiment, as shown in Figure 8, LED drive unit also comprises:

The first rectifier bridge BD1, the first capacitor C 1, the second capacitor C 2, the 3rd capacitor C 3, the first resistance R 1, the first diode D1, the second resistance R 2, the 3rd resistance R 3, the first coupling inductance T1, the second diode D2, the 4th resistance R 4, the 4th capacitor C 4 and the 5th resistance R 5; Light modulation power tube Q1 is NMOS pipe;

The first input end 1 of the first rectifier bridge BD1 and the second input 2 positive half cycle alternating current and negative half period alternating current of incoming transport power supply AC respectively, the output 3 of the first rectifier bridge BD1 and the first end of the first capacitor C 1, the drain electrode end DRAIN of LED light modulation driving governor 100, the negative electrode of the second diode D1, the first end of the first end of the 4th capacitor C 4 and the 5th resistance R 5 is connected to the input of LED load 300 altogether, the first end of the first end of the second capacitor C 2 and the first resistance R 1 is connected to the voltage end VDD of LED light modulation driving governor 100 altogether, the second end of the first resistance R 1 connects the negative electrode of the first diode D1, the first end of the anode of the first diode D1 and the second resistance R 2 is connected to the different name end of the secondary winding of the first coupling inductance T1 altogether, the second end of the second resistance R 2 and the first end of the 3rd resistance R 3 are connected to the feedback end FB of LED light modulation driving governor 100 altogether, the Same Name of Ends of the second end of the 3rd resistance R 3 and the secondary winding of the first coupling inductance T1 is connected to ground altogether, the first end of the 3rd capacitor C 3 connects the compensation end COMP of LED light modulation driving governor 100, the first end of the 4th resistance R 4 connects the source electrode of light modulation power tube Q1, the second end of the earth terminal 4 of the first rectifier bridge BD1 and the first capacitor C 1, the second end of the second capacitor C 2, the second end of the 3rd capacitor C 3, the ground end GND of LED light modulation driving governor 100 and the second end of the 4th resistance R 4 are connected to ground altogether, the different name end of the armature winding of the first coupling inductance T1 and the anode of the second diode D2 are connected to the drain electrode of light modulation power tube Q1 altogether, the second end of the second end of the Same Name of Ends of the armature winding of the first coupling inductance T1 and the 4th capacitor C 4 and the 5th resistance R 5 is connected to the output of LED load 300 altogether.In addition; for fear of in the time that overvoltage appears in AC power AC, LED drive unit being caused to damage; between the input 1 of the first rectifier bridge BD1 and AC power AC, be also connected with the first fuse F1, the first fuse F1 disconnects so that LED drive unit is realized to overvoltage protection in the time of AC power AC overvoltage.

In the utility model the second embodiment, as shown in Figure 9, LED drive unit also can comprise:

The second rectifier bridge BD2, the 5th capacitor C 5, the 6th resistance R 6, the 7th resistance R 7, the 8th resistance R 8, inductance L 1, the 6th capacitor C 6, the 7th capacitor C 7, the 3rd diode D3, the 4th diode D4, the 9th resistance R 9, the tenth resistance R 10, the 8th capacitor C 8; Light modulation power tube Q1 is NMOS pipe;

The first input end 1 of the second rectifier bridge BD2 and the second input 2 positive half cycle alternating current and negative half period alternating current of incoming transport power supply AC respectively, the drain electrode end DRAIN of the output 3 of the second rectifier bridge BD2 and the first end of the 5th capacitor C 5 and LED light modulation driving governor 100 is connected to the drain electrode of light modulation power tube Q1 altogether, the negative electrode of the first end of the 6th resistance R 6 and the 3rd diode D3 is connected to the source electrode of light modulation power tube Q1 altogether, the second end of the 6th resistance R 6 and the first end of the 7th resistance R 7, the first end of inductance L 1, the first end of the first end of the 6th capacitor C 6 and the 7th capacitor C 7 is connected to the ground end GND of LED light modulation driving governor 100 altogether, the second end of the 7th resistance R 7 and the first end of the 8th resistance R 8 are connected to the feedback end FB of LED light modulation driving governor 100 altogether, the second end of the 8th resistance R 8 and the second end of inductance L 1, the anode of the 4th diode D4, the positive pole of the first end of the tenth resistance R 10 and the 8th capacitor C 8 is connected to the input of LED load 300 altogether, the first end of the 9th resistance R 9 connects the negative electrode of the 4th diode D4, the second end of the second end of the 9th resistance R 9 and the 7th capacitor C 7 is connected to the voltage end VDD of LED light modulation driving governor 100 altogether, the second end of the 6th capacitor C 6 connects the compensation end COMP of LED light modulation driving governor 100, the earth terminal 4 of the second rectifier bridge BD2, the second end of the 5th capacitor C 5, the anode of the 3rd diode D3, the second end of the tenth resistance R 10, the output of the negative pole of the 8th capacitor C 8 and LED load 300 is connected to ground altogether.In addition; for fear of in the time that overvoltage appears in AC power AC, LED drive unit being caused to damage; between the input 2 of the second rectifier bridge BD2 and AC power AC, be also connected with the second fuse F2, the second fuse F2 disconnects so that LED drive unit is realized to overvoltage protection in the time of AC power AC overvoltage.

In the utility model the 3rd embodiment, as shown in figure 10, LED drive unit also can comprise:

The 3rd rectifier bridge BD3, the 9th capacitor C 9, the tenth capacitor C the 10, the 11 capacitor C the 11, the 11 resistance R 11, the 5th diode D5, the 12 resistance R the 12, the 13 resistance R 13, the second coupling inductance T2, the 14 resistance R the 14, the 12 capacitor C 12, the 6th diode D6, the 7th diode D7, the 13 capacitor C the 13, the 15 resistance R the 15 and the 16 resistance R 16; Light modulation power tube Q1 is NMOS pipe;

The first input end 1 of the 3rd rectifier bridge BD3 and the second input 2 positive half cycle alternating current and negative half period alternating current of incoming transport power supply AC respectively, the output 3 of the 3rd rectifier bridge BD3 and the first end of the 9th capacitor C 9, the drain electrode end DRAIN of LED light modulation driving governor 100, the first end of the 14 resistance R 14, the first end of the 12 capacitor C 12 is connected to the Same Name of Ends of the armature winding of the second coupling inductance T2 altogether, the tenth first end of capacitor C 10 and the first end of the 11 resistance R 11 are connected to the voltage end VDD of LED light modulation driving governor 100 altogether, the second end of the 11 resistance R 11 connects the negative electrode of the 5th diode D5, the 5th anode of diode D5 and the first end of the 12 resistance R 12 are connected to the different name end of the auxiliary winding of the second coupling inductance T2 altogether, the second end of the 12 resistance R 12 and the first end of the 13 resistance R 13 are connected to the feedback end FB of LED light modulation driving governor 100 altogether, the Same Name of Ends of the second end of the 13 resistance R 13 and the auxiliary winding of the second coupling inductance T2 is connected to ground altogether, the first end of the 11 capacitor C 11 connects the compensation end COMP of LED light modulation driving governor 100, the second end of the 14 resistance R 14 and the second end of the 12 capacitor C 12 are connected to the negative electrode of the 6th diode D6 altogether, the different name end of the armature winding of the anode of the 6th diode D6 and the second coupling inductance T2 is connected to the drain electrode of light modulation power tube Q1 altogether, the first end of the 16 resistance R 16 connects the source electrode of light modulation power tube Q1, the second end of the earth terminal 4 of the 3rd rectifier bridge BD3 and the 9th capacitor C 9, the second end of the tenth capacitor C 10, the second end of the 11 capacitor C 11, the ground end GND of LED light modulation driving governor 100 and the second end of the 16 resistance R 16 are connected to ground altogether, the different name end of the secondary winding of the second coupling inductance T2 and the anodic bonding of the 7th diode D7, the negative electrode of the 7th diode D7 and the 13 first end of capacitor C 13 and the first end of the 15 resistance R 15 are connected to the input of LED load 300 altogether, the second end of the Same Name of Ends of the secondary winding of the second coupling inductance T2 and the 13 capacitor C 13 and the second end of the 15 resistance R 15 are connected to the output of LED load 300 altogether.In addition; for fear of in the time that overvoltage appears in AC power AC, LED drive unit being caused to damage; between the input 1 of the 3rd rectifier bridge BD3 and AC power AC, be also connected with the 3rd fuse F3, the 3rd fuse F3 disconnects so that LED drive unit is realized to overvoltage protection in the time of AC power AC overvoltage.

At the LED drive unit shown in Fig. 8, Fig. 9 and Figure 10, by LED light modulation driving governor 100 according to peak current and the switching frequency of aforesaid light modulation principle control light modulation power tube Q1, to realize the control of the electric current to exporting LED load 300 to, thereby realize corresponding light modulation operation.

In sum, the utility model embodiment by adopting the LED light modulation driving governor 100 that comprises the first comparator 101, the second comparator 102, timing judge module 103, counting module 104, signal lag module 105, latch 106 and voltage selector 107 in LED drive unit, it does not need to configure peripheral voltage testing circuit, therefore circuit cost is low, judge from starting timing to the time (being that LED light modulation driving governor 100 is from starting to the time of reset) that receives the reset signal that the first comparator 101 exports and be greater than Preset Time threshold value at timing judge module 103, when counting module 104 output switch count signals and signal lag module 105 are exported light modulation enable signal, latch 106 control voltage selector 107 step by step regulation output voltage so that the constant-current control circuit 200 in LED light modulation driving governor 100 is controlled peak current and the switching frequency of light modulation power tube Q1, thereby realize LED load 300 is carried out to multi-level brightness adjusting, due to Preset Time threshold value be greater than LED light modulation driving governor 100 therein power supply when " having the hiccups " state from starting to the time of reset, latch 106 is not controlled voltage selector 107 regulation output voltages, so that controlling LED load 300, light modulation power tube Q1 keeps original brightness, thereby avoid occurring the problem of mistuning light in the time that the internal power supply of LED light modulation driving governor " is had the hiccups ", promote light modulation reliability, solve the existing light modulation reliability of prior art low, cost is high and easily cause the problem of mistuning light because " having the hiccups " appears in chip power voltage.

The foregoing is only preferred embodiment of the present utility model; not in order to limit the utility model; all any amendments of doing within spirit of the present utility model and principle, be equal to and replace and improvement etc., within all should being included in protection range of the present utility model.

Claims (8)

1. a LED light modulation driving governor, it comprises constant-current control circuit, described constant-current control circuit is by the feedback end of described LED light modulation driving governor, voltage end, sampling end, compensation end, drain electrode end, gate pole end and ground end are connected with the circuit in LED drive unit, described gate pole end and described sampling end are connected respectively grid and the source electrode of light modulation power tube, the source electrode of described light modulation power tube is also connected to ground by a sampling resistor, described light modulation power tube carries out brilliance control to the LED load of described LED drive unit, the supply voltage of described voltage end raises in the time that the AC power of described LED drive unit is connected, and decline in the time that described AC power disconnects, it is characterized in that:

Described LED light modulation driving governor also comprises the first comparator, the second comparator, timing judge module, counting module, signal lag module, latch and voltage selector;

The first input end of described the first comparator and the second input access respectively starting resistor and resetting voltage, the 3rd input of described the first comparator, the first input end of described the second comparator, the power end of the power end of described timing judge module and described signal lag module all connects the voltage end of described LED light modulation driving governor, the second input access threshold voltage of described the second comparator, the output of described the first comparator connects the input of described timing judge module and the input of described counting module simultaneously, the output of described timing judge module, the output of the output of described counting module and described signal lag module all connects described latch, described latch also connects described voltage selector, described voltage selector connects described constant-current control circuit.

2. the LED light modulation driving governor as shown in claim 1, is characterized in that, described timing judge module comprises:

The first d type flip flop, the second d type flip flop, 3d flip-flop, four d flip-flop and the 5th d type flip flop;

The power end of the power end of described the first d type flip flop and described the second d type flip flop, the power end of described 3d flip-flop, the power end of the power end of described four d flip-flop and described the 5th d type flip flop connects the power end of formed common contact as described timing judge module altogether, the input of described the first d type flip flop is the input of described timing judge module, and the input of described the first d type flip flop is connected with reversed-phase output, the clock end incoming clock signal of described the first d type flip flop, the Enable Pin of the Enable Pin of described the first d type flip flop and described the second d type flip flop, the Enable Pin of described 3d flip-flop, the Enable Pin of the Enable Pin of described four d flip-flop and described the 5th d type flip flop all accesses enable signal, the clock end of described the second d type flip flop connects the in-phase output end of described the first d type flip flop, the input of described the second d type flip flop is connected with reversed-phase output, the clock end of described 3d flip-flop connects the in-phase output end of described the second d type flip flop, the input of described 3d flip-flop is connected with reversed-phase output, the clock end of described four d flip-flop connects the in-phase output end of described 3d flip-flop, the input of described four d flip-flop is connected with reversed-phase output, the clock end of described the 5th d type flip flop connects the in-phase output end of described four d flip-flop, the input of described the 5th d type flip flop is connected with reversed-phase output, the in-phase output end of described the 5th d type flip flop is the output of described timing judge module.

3. the LED light modulation driving governor as shown in claim 1, is characterized in that, described counting module comprises:

The 6th d type flip flop, the 7th d type flip flop and the 8th d type flip flop;

The Enable Pin of the Enable Pin of the Enable Pin of described the 6th d type flip flop and described the 7th d type flip flop and described the 8th d type flip flop all accesses enable signal, the input of described the 6th d type flip flop is the input of described counting module, and the input of described the 6th d type flip flop is connected with reversed-phase output, the clock end incoming clock signal of described the 6th d type flip flop, the common output that forms described counting module of in-phase output end of the in-phase output end of described the 6th d type flip flop and described the 7th d type flip flop, and the clock end of described the 7th d type flip flop connects the in-phase output end of described the 6th d type flip flop, the input of described the 7th d type flip flop is connected with reversed-phase output, the clock end of described the 8th d type flip flop connects the in-phase output end of described the 7th d type flip flop, the input of described the 8th d type flip flop is connected with reversed-phase output, the in-phase output end sky of described the 8th d type flip flop connects.

4. the LED light modulation driving governor as shown in claim 1, is characterized in that, described signal lag module comprises:

The one NMOS pipe, resistance, the 2nd NMOS pipe, current source, electric capacity, Schmidt trigger and inverter;

The grid of a described NMOS pipe is the input of described signal lag module, the source electrode of a described NMOS pipe and substrate are connected to ground altogether, a described drain electrode for NMOS pipe and the first end of described resistance are connected to the grid of described the 2nd NMOS pipe altogether, the common contact of the second end of described resistance and the input of described current source is the power end of described signal lag module, the source electrode of described the 2nd NMOS pipe and substrate are connected to ground altogether, the first end of described the 2nd drain electrode of NMOS pipe and the output of described current source and described electric capacity is connected to the input of described Schmidt trigger altogether, the second end ground connection of described electric capacity, the output of described Schmidt trigger connects the input of described inverter, the output of described inverter is the output of described signal lag module.

5. a LED drive unit, it carries out light modulation driving to LED load, and comprises light modulation power tube, it is characterized in that, and described LED drive unit also comprises the LED light modulation driving governor as described in claim 1 to 4.

6. LED drive unit as claimed in claim 5, is characterized in that, LED drive unit also comprises:

The first rectifier bridge, the first electric capacity, the second electric capacity, the 3rd electric capacity, the first resistance, the first diode, the second resistance, the 3rd resistance, the first coupling inductance, the second diode, the 4th resistance, the 4th electric capacity and the 5th resistance; Described light modulation power tube is NMOS pipe;

The first input end of described the first rectifier bridge and the second input access respectively positive half cycle alternating current and the negative half period alternating current of described AC power, the first end of the output of described the first rectifier bridge and described the first electric capacity, the drain electrode end of described LED light modulation driving governor, the negative electrode of described the second diode, the first end of the first end of described the 4th electric capacity and described the 5th resistance is connected to the input of described LED load altogether, the first end of the first end of described the second electric capacity and described the first resistance is connected to the voltage end of described LED light modulation driving governor altogether, the second end of described the first resistance connects the negative electrode of described the first diode, the first end of the anode of described the first diode and described the second resistance is connected to the different name end of the secondary winding of described the first coupling inductance altogether, the second end of described the second resistance and the first end of described the 3rd resistance are connected to the feedback end of described LED light modulation driving governor altogether, the Same Name of Ends of the second end of described the 3rd resistance and the secondary winding of described the first coupling inductance is connected to ground altogether, the first end of described the 3rd electric capacity connects the compensation end of described LED light modulation driving governor, the first end of described the 4th resistance connects the source electrode of described light modulation power tube, the second end of the earth terminal of described the first rectifier bridge and described the first electric capacity, the second end of described the second electric capacity, the second end of described the 3rd electric capacity, the second end of the ground end of described LED light modulation driving governor and described the 4th resistance is connected to ground altogether, the different name end of the armature winding of described the first coupling inductance and the anode of described the second diode are connected to the drain electrode of described light modulation power tube altogether, the second end of the second end of the Same Name of Ends of the armature winding of described the first coupling inductance and described the 4th electric capacity and described the 5th resistance is connected to the output of described LED load altogether.

7. LED drive unit as claimed in claim 5, is characterized in that, described LED drive unit also comprises:

The second rectifier bridge, the 5th electric capacity, the 6th resistance, the 7th resistance, the 8th resistance, inductance, the 6th electric capacity, the 7th electric capacity, the 3rd diode, the 4th diode, the 9th resistance, the tenth resistance, the 8th electric capacity; Described light modulation power tube is NMOS pipe;

The first input end of described the second rectifier bridge and the second input access respectively positive half cycle alternating current and the negative half period alternating current of described AC power, the drain electrode end of the first end of the output of described the second rectifier bridge and described the 5th electric capacity and described LED light modulation driving governor is connected to the drain electrode of described light modulation power tube altogether, the negative electrode of the first end of described the 6th resistance and described the 3rd diode is connected to the source electrode of described light modulation power tube altogether, the second end of described the 6th resistance and the first end of described the 7th resistance, the first end of described inductance, the first end of the first end of described the 6th electric capacity and described the 7th electric capacity is connected to the ground end of described LED light modulation driving governor altogether, the second end of described the 7th resistance and the first end of described the 8th resistance are connected to the feedback end of described LED light modulation driving governor altogether, the second end of described the 8th resistance and the second end of described inductance, the anode of described the 4th diode, the positive pole of the first end of described the tenth resistance and described the 8th electric capacity is connected to the input of described LED load altogether, the first end of described the 9th resistance connects the negative electrode of described the 4th diode, the second end of the second end of described the 9th resistance and described the 7th electric capacity is connected to the voltage end of described LED light modulation driving governor altogether, the second end of described the 6th electric capacity connects the compensation end of described LED light modulation driving governor, the earth terminal of described the second rectifier bridge, the second end of described the 5th electric capacity, the anode of described the 3rd diode, the second end of described the tenth resistance, the output of the negative pole of described the 8th electric capacity and described LED load is connected to ground altogether.

8. LED drive unit as claimed in claim 5, is characterized in that, described LED drive unit also comprises:

The 3rd rectifier bridge, the 9th electric capacity, the tenth electric capacity, the 11 electric capacity, the 11 resistance, the 5th diode, the 12 resistance, the 13 resistance, the second coupling inductance, the 14 resistance, the 12 electric capacity, the 6th diode, the 7th diode, the 13 electric capacity, the 15 resistance and the 16 resistance; Described light modulation power tube is NMOS pipe;

The first input end of described the 3rd rectifier bridge and the second input access respectively positive half cycle alternating current and the negative half period alternating current of described AC power, the first end of the output of described the 3rd rectifier bridge and described the 9th electric capacity, the drain electrode end of described LED light modulation driving governor, the first end of described the 14 resistance, the first end of described the 12 electric capacity is connected to the Same Name of Ends of the armature winding of described the second coupling inductance altogether, described the tenth first end of electric capacity and the first end of described the 11 resistance are connected to the voltage end of described LED light modulation driving governor altogether, the second end of described the 11 resistance connects the negative electrode of described the 5th diode, described the 5th anode of diode and the first end of described the 12 resistance are connected to the different name end of the auxiliary winding of described the second coupling inductance altogether, the second end of described the 12 resistance and the first end of described the 13 resistance are connected to the feedback end of described LED light modulation driving governor altogether, the Same Name of Ends of the second end of described the 13 resistance and the auxiliary winding of described the second coupling inductance is connected to ground altogether, the first end of described the 11 electric capacity connects the compensation end of described LED light modulation driving governor, the second end of described the 14 resistance and the second end of described the 12 electric capacity are connected to the negative electrode of described the 6th diode altogether, the different name end of the armature winding of the anode of described the 6th diode and described the second coupling inductance is connected to the drain electrode of described light modulation power tube altogether, the first end of described the 16 resistance connects the source electrode of described light modulation power tube, the second end of the earth terminal of described the 3rd rectifier bridge and described the 9th electric capacity, the second end of described the tenth electric capacity, the second end of described the 11 electric capacity, the ground end of described LED light modulation driving governor and the second end of described the 16 resistance are connected to ground altogether, the different name end of the secondary winding of described the second coupling inductance and the anodic bonding of described the 7th diode, the negative electrode of described the 7th diode and described the 13 first end of electric capacity and the first end of described the 15 resistance are connected to the input of described LED load altogether, the second end of the Same Name of Ends of the secondary winding of described the second coupling inductance and described the 13 electric capacity and the second end of described the 15 resistance are connected to the output of described LED load altogether.