CN208063518U - LED illumination System - Google Patents

Abstract

A kind of LED illumination System comprising：During the temperature of LED illumination System is increased to second temperature T2 by initial temperature T0, it is initial current I0 to control the LED light electric current；During the temperature is increased to third temperature T3 by second temperature T2, controls the LED light electric current and the first electric current I1 is dropped to by initial current I0；During the temperature is increased to the 5th temperature T5 by third temperature T3, controls the LED light electric current and the second electric current I2 is dropped to by the first electric current I1；During the temperature drops to the 4th temperature T4 by third temperature T3, controls the LED light electric current and be maintained at the first electric current I1；During the temperature drops to the first temperature T1 by the 4th temperature T4, controls the LED light electric current and restored to initial current I0 by the first electric current I1.The temprature control method makes LED illumination System during the work time will not flashing light.

Description

LED illumination System

Technical field

The utility model belongs to electron electric power technical field more particularly to a kind of LED illumination System.

Background technology

Common LED illumination System is made of on hardware lampshade, control power supply and lamp bead, as shown in Figure 1.Wherein, it controls Power supply processed controls the brightness of LED lamp bead, namely the power of control LED light with this for controlling the electric current for flowing through lamp bead.LED For lighting system as light source, when converting electrical energy into luminous energy, there is transfer efficiencies, will produce higher environment temperature, and add Upper control power supply itself can generate heat, and therefore, when LED illumination System works, control power supply in order to prevent and lamp bead is burnt, need It is controlled come the temperature carried out to LED illumination System under high temperature by temperature-current curve.

Although at present in the industry frequently with temperature-current curve as shown in Fig. 2, the controlling mechanism can reach protection control electricity Source is not because of the purpose of high temperature damage, still, carries out temperature detection to LED illumination System by sensor, according to Fig. 2, is sensing During device temperature TS is gradually increased to T2 by T0, the electric current ILED of LED keeps I0 constant；When sensor temperature is continued by T2 During rising to T3, the electric current of LED is continuously decreased by I0 as I1；When sensor temperature reaches T3, for prevent component because High temperature damages, and LED illumination System is closed；After LED illumination System is closed, sensor temperature continuously decreases, when sensor temperature drops When down to T1, LED illumination System reopens, and the electric current of LED reverts to I0.As long as the above analysis is it is found that sensor temperature TS T3 can be reached, then LED illumination System can recycle in closing and unlatching, so as to cause flashing light phenomenon.

Utility model content

The utility model provides a kind of LED illumination System, it is intended to solve traditional temperature for LED illumination System and control Scheme can cause LED illumination System the problem of flashing light phenomenon occur.

A kind of LED illumination System, including a rectifier bridge, an input capacitance, an energy storage inductor, a decompression control chip, one Rectifier diode, a load capacitance, a sampling resistor, LED light bead string and one obtain the temperature of the temperature of the LED light bead string in real time Spend sensor, the rectifier bridge two input termination power, the input capacitance be connected to the rectifier bridge positive and negative output end it Between, the power pins of the decompression control chip connect the positive and negative output end of the rectifier bridge respectively, the decompression control chip Driving pin connects the anode of the rectifier diode, and the current detecting pin of the decompression control chip passes through the sampling resistor The negative output terminal of the rectifier bridge is connect, the cathode of the rectifier diode connects the positive output end of the rectifier bridge, the load electricity In parallel with the rectifier diode after appearance and energy storage inductor series connection, the anode of the LED light bead string connects the rectifier bridge The cathode of positive output end, the LED light bead string connects the connects end altogether of the load capacitance and the energy storage inductor；The decompression control Chip includes temperature current control module, and the temperature current control module is used for：

During the temperature is increased to second temperature T2 by initial temperature T0, the LED of the LED light bead string is controlled Lamp current is initial current I0, wherein initial temperature T0 is the temperature when LED light bead string starts；

During the temperature is increased to third temperature T3 by second temperature T2, the LED light electric current is controlled by first Beginning electric current I0 drops to the first electric current I1；

During the temperature is increased to the 5th temperature T5 by third temperature T3, the LED light electric current is controlled by One electric current I1 drops to the second electric current I2；

During the temperature drops to the 4th temperature T4 by third temperature T3, controls the LED light electric current and keep In the first electric current I1；

During the temperature drops to the first temperature T1 by the 4th temperature T4, the LED light electric current is controlled by One electric current I1 restores to initial current I0；

Wherein, T4 is less than T2, and T1 is more than T0, and I2 ratios I0 is the second ratio, and I1 ratios I0 is the first ratio；Second ratio Less than or equal to first ratio.

The decompression control chip further includes reference voltage source, Logic control module, driving in one of the embodiments, Module, the first metal-oxide-semiconductor, the lowest point detection module, peak detection block, wherein：

The reference voltage source is connect with the power pins of the decompression control chip, and the drain electrode of first metal-oxide-semiconductor connects The driving pin of the decompression control chip, the source electrode of first metal-oxide-semiconductor connect the current detecting that the decompression controls chip and draw Foot；

The lowest point detection module is connected between the grid of first metal-oxide-semiconductor and the temperature current control module, It is output to the temperature current control module according to the lowest point signal for detecting first metal-oxide-semiconductor；

The temperature current control module is connected between the lowest point detection module and the Logic control module, according to The lowest point signal exports the lowest point delay time signal to the Logic control module；

The peak detection block is connected between the source electrode and the Logic control module of first metal-oxide-semiconductor, detection The peak-current signal of first metal-oxide-semiconductor is exported to the Logic control module；

The drive module is connected between the Logic control module and the grid of first metal-oxide-semiconductor, the driving Module logic control module drives first metal-oxide-semiconductor logical according to the lowest point delay time signal and the peak-current signal It is disconnected.

The temperature current control module includes the first hysteresis comparator, the second sluggish ratio in one of the embodiments, Compared with device, a trsanscondutance amplifier, the first divider resistance, the second divider resistance, third divider resistance, the 4th divider resistance, the first electricity Appearance, the second capacitance, the first PTAT current source, the second PTAT current source, a constant-current source, a diode, a zener diode, second Metal-oxide-semiconductor, third metal-oxide-semiconductor, a phase inverter and one and door；

The normal phase input end of first hysteresis comparator connects first PTAT current by first divider resistance Source, the anti-phase input of first hysteresis comparator terminate second PTAT current source, first hysteresis comparator it is defeated Go out the grid for terminating second metal-oxide-semiconductor, the drain electrode of second metal-oxide-semiconductor connects described first late by second divider resistance The drain electrode of the normal phase input end of stagnant comparator, second metal-oxide-semiconductor is also grounded by the third divider resistance, and described second The source electrode of metal-oxide-semiconductor is grounded；The normal phase input end of the trsanscondutance amplifier connects first PTAT current source, the trsanscondutance amplifier Anti-phase input terminate the anode of second PTAT current source and the diode, the minus earth of the diode is described The output of trsanscondutance amplifier terminates the inverting input of the cathode and second hysteresis comparator of the zener diode, described 4th divider resistance and first capacitance are in parallel with the zener diode；The normal phase input end of second hysteresis comparator Connect the drain electrode of the constant-current source and the third metal-oxide-semiconductor and by second capacity earth, second hysteresis comparator The input termination input terminal with door, the input terminal that the phase inverter is terminated with door another input, described and door Output end as temperature current control module output end export the lowest point delay time signal, the phase inverter output termination The grid of the third metal-oxide-semiconductor, the source electrode ground connection that the 2nd MOS is closed, the input terminal of the phase inverter is as temperature current control Detect signal in the input terminal access the lowest point of molding block.

In one of the embodiments,

If the second electric current I2 is less than the first electric current I1, the value range of second ratio is 5%~30%, described the The value range of one ratio is 10%~80%；

If the second electric current I2 is equal to the first electric current I1, the value range of second ratio is 10%~80%, described The value range of first ratio is 10%~80%.

The second electric current I2 is equal to the first electric current I1 in one of the embodiments,.

Third temperature T3 is equal to second temperature T2 in one of the embodiments,.

The 4th temperature T4 is equal to the first temperature T1 in one of the embodiments,.

Based on the LED illumination System that the utility model embodiment provides, in the course of work of LED illumination System, a side Effectively LED illumination System is controlled into trip temperature in face, and protection system will not be damaged because of high temperature, on the other hand can solve tradition Temperature control scheme the problem of leading to LED illumination System flashing light, with the presence of at least one degeneracy point during control so that LED illumination System during the work time will not flashing light, avoid the generation of flashing light phenomenon.

Description of the drawings

Fig. 1 is common LED illumination System；

Fig. 2 is traditional LED illumination System temperature current controlling curve；

Fig. 3 is the first embodiment LED illumination System temperature current controlling curve of the utility model；

Fig. 4 is the second embodiment LED illumination System temperature current controlling curve of the utility model；

Fig. 5 is the 3rd embodiment LED illumination System temperature current controlling curve of the utility model；

Fig. 6 is the fourth embodiment LED illumination System temperature current controlling curve of the utility model；

Fig. 7 is the 5th embodiment LED illumination System temperature current controlling curve of the utility model；

Fig. 8 is the LED illumination System structural schematic diagram that one embodiment of the utility model provides；

Fig. 9 is the exemplary circuit schematic diagram of temperature current control module in LED illumination System shown in Fig. 8.

Specific implementation mode

In order to make the purpose of the utility model, technical solutions and advantages more clearly understood, below in conjunction with attached drawing and implementation Example, the present invention will be further described in detail.It should be appreciated that specific embodiment described herein is only used to explain The utility model is not used to limit the utility model.

Here, being described in detail elaboration to the temprature control method of the LED illumination System of the utility model embodiment offer：

When LED illumination System works, the temperature of LED illumination System is obtained in real time, specifically, passes through temperature sensor reality When obtain the temperature of LED illumination System, and control according to the temperature and its situation of change that get the LED of LED illumination System Lamp current.In the utility model embodiment, the LED light electric current refers both to the electric current that power supply flows through LED lamp bead.

In the utility model embodiment, for the temperature and its situation of change of LED illumination System, LED is flowed through to power supply The electric current of lamp bead executes following control program：

1, during the temperature of LED illumination System is increased to second temperature T2 by initial temperature T0, LED illumination is controlled The LED light electric current of system is initial current I0.Here, temperature when initial temperature T0 is LED illumination System startup.

That is, during the temperature of LED illumination System is gradually increased to T2 by initial temperature T0, the LED light of LED is controlled It is constant that electric current remains I0.

2, during the temperature of LED illumination System is increased to third temperature T3 by second temperature T2, LED illumination is controlled The LED light electric current of system drops to the first electric current I1 by initial current I0.

That is, after the temperature of LED illumination System reaches T2, during temperature continues to rise to T3 by T2, LED is controlled The LED light electric current of lighting system is continuously decreased by I0 as I1.

3, during the temperature of LED illumination System is increased to the 5th temperature T5 by third temperature T3, LED illumination is controlled The LED light electric current of system drops to the second electric current I2 by the first electric current I1.

That is, after the temperature of LED illumination System reaches T3, if temperature continues to rise to T5, LED illumination System is controlled LED light electric current I2 is dropped rapidly to larger slope.In the utility model embodiment, I2 is the electric current of a very little Value, it is preferable that the value range of the ratio of I2 and I0 is 5%~30%, that is, the current value of I2 can be the current value of I0 5%~30%.

Here, due to I2 value very littles, when the LED light electric current of LED illumination System is I2, the fever of LED illumination System Very little is measured, therefore, unless external heat source is to LED illumination System continuous heating, otherwise with the calorific value of LED illumination System itself, The temperature of LED illumination System can not possibly be made to continue to rise to T5, to protect the component of LED illumination System will not be due to temperature is excessively high Damage.

4, during the temperature of LED illumination System drops to the 4th temperature T4 by third temperature T3, LED illumination is controlled The LED light electric current of system is maintained at the first electric current I1.

That is, after being down to T3 at a temperature of LED illumination System, if temperature continues to drop to T4, LED illumination System is controlled It is constant that LED light electric current is maintained at I1.

5, during the temperature of LED illumination System drops to the first temperature T1 by the 4th temperature T4, LED illumination is controlled The LED light electric current of system is restored by the first electric current I1 to initial current I0.

That is, during the temperature of LED illumination System drops to T1 by T4, control the LED light electric current of LED illumination System by I1 is gradually brought to I0.

The above control program can be realized based on temperature-current curve as shown in Figure 3, wherein T4 is less than T2, and T1 is big It is the second ratio in T0, I2 ratios I0, I1 ratios I0 is the first ratio；Second ratio is less than or equal to the first ratio.It, should with reference to Fig. 3 In curve, the slop control of introducing T2 to T3 and the slop control of T4 to T1, slope K 3=I1 ÷ I0,10%≤K3≤ 80%, keep the LED light curent change of LED illumination System slow；The sluggish electric current for introducing I0 and I1, enhances anti-interference ability.

Under the control of temperature-current curve shown in Fig. 3, it is VOUT, illumination system to enable the output voltage of LED illumination System The energy conversion efficiency of system is η 0, and light energy use efficiency is η 1, and it is RT (unit to enable the thermal resistance of LED illumination System：DEG C/W), then：

The calorific value calculation formula of LED illumination System is P=VOUT × ILED ÷ η 0 × (1- η 1), wherein ILED is upper LED light electric current described in text；

In ILED=I0, P_I0=VOUT × I0 ÷ η 0 × (1- η 1)；

In ILED=I1, P_I1=VOUT × I1 ÷ η 0 × (1- η 1)；

Enable the LED illumination System of no temperature-current curve control when output current is I0, output voltage is VOUT Temperature is T_I0, then：

T_I0=P_I0 ÷ RT+TE, wherein TE are environment temperature.

Enable the LED illumination System of no temperature-current curve control output current is I1, output voltage is VOUT (LED Varied less when modulating voltage changes with output current, ignore here output voltage variation) when control system temperature be T_I1, Then：

T_I1=P_I1 ÷ RT+TE；

(T_I1-TE) ÷ (T_I0-TE)=P_I1 ÷ P_I0=I1 ÷ I0=K3；

So there is following equation 1：(T_I1-TE) ÷ (T_I0-TE)=I1 ÷ I0=K3.

The meaning of formula 1 is：It is identical in output voltage, control the Wen Shengyu output electricity of LED illumination System It flows directly proportional.

For a LED illumination System, if T1 < T_I0 < T2, T_I1 < T2, T_I0 > T1, then the system subtracts from T2 Small be reduced to again to T4 in the curve of T1 can find some system is allowed to settle out, similarly, from T1 increase to T2 be further added by Any can also be found in the curve of T3 allows system to settle out；If T_I0 < T1, then the system is stablized；If T_I0 > T2, And T_I1 < T3, then the system is reduced in the curve of T3 from T2 and can find some system is allowed to settle out, similarly, from T3 Any can also be found system is allowed to settle out by being reduced to T4 and being reduced to again in the curve of T1；If T_I1 > T3, then the system Any can be found by, which increasing to from T3 in the curve of T5, allows system to settle out.

Based on the analysis above to temperature-current curve as shown in Figure 3, the temperature-current curve T1 to T2 to T3 extremely With the presence of at least one degeneracy point in the curved section of T4 to T1 so that LED illumination System during the work time will not flashing light.

As one embodiment of the utility model, the simplification of the temperature-current curve of Fig. 3 displayings is further given Version, as shown in figure 4, the curve is on the basis of curve as shown in Figure 3, enable the second electric current I2 equal with the first electric current I1 It arrives.

With reference to Fig. 4, in the curve, slope K 4=I1 ÷ I0,10%≤K4≤80% protects system will not be because of temperature mistake It is high and damage.In the curve, the slop control of T2 to T3 and the slop control of T4 to T1 are introduced, LED illumination System is made LED light curent change is slow；The sluggish electric current for introducing I0 and I1, enhances anti-interference ability.

Based on the analysis to temperature-current curve shown in Fig. 3, similarly, temperature-current curve shown in Fig. 4 T1 extremely With the presence of at least one degeneracy point in the curved section of T2 to T3 to T4 to T1 so that LED illumination System during the work time will not Flashing light.

As one embodiment of the utility model, the another of the temperature-current curve of Fig. 3 displayings is further given Simple version enables third temperature T3 and second temperature T2 phases as shown in figure 5, the curve is on the basis of curve as shown in Figure 4 Etc. obtaining.

With reference to Fig. 5, in the curve, slope K 5=I1 ÷ I0,50%≤K5≤80%, and expression formula need to be met：(T1 ﹣ TE) ÷ (T2 ﹣ TE)≤K5, protects system not damaged because temperature is excessively high.In the curve, the slop control of T4 to T1 is introduced, is made The LED light curent change of LED illumination System is slow；The sluggish electric current for introducing I0 and I1, enhances anti-interference ability；It is required that 50% ≤ K5≤80%, (T1 ﹣ TE) ÷ (T2 ﹣ TE)≤K5, and have strict demand to K5 and T1, T2, it ensure that the hair of LED illumination System Wen Sheng caused by heat is in T1 to T2 to T4 to controlled between T1.

Based on the analysis to temperature-current curve shown in Fig. 3, similarly, temperature-current curve shown in fig. 5 T1 extremely With the presence of at least one degeneracy point in the curved section of T2 to T4 to T1 so that LED illumination System during the work time will not flashing light.

As one embodiment of the utility model, the another of the temperature-current curve of Fig. 3 displayings is further given Simple version enables the 4th temperature T4 and the first temperature T1 phases as shown in fig. 6, the curve is on the basis of curve as shown in Figure 4 Etc. obtaining.

LED illumination System temperature current controlling curve as shown in Figure 6, is to enable I2=on the basis of curve as shown in Figure 3 I1 enables T4=T1 obtain.

With reference to Fig. 6, in the curve, slope K 6=I1 ÷ I0,50%≤K6≤80%, and expression formula need to be met：(T1 ﹣ TE) ÷ (T2 ﹣ TE)≤K6, protects system not damaged because temperature is excessively high.In the curve, the slop control of T2 to T3 is introduced, is made System change is slow；The sluggish electric current for introducing I0 and I1, enhances anti-interference ability；It is required that 50%≤K6≤80%, (T1 ﹣ TE) ÷ (T2 ﹣ TE)≤K6, and have strict demand to K6 and T1, T2, it ensure that Wen Sheng is in T1 caused by the calorific value of LED illumination System To T2 to T3 to controlled between T1.

Based on the analysis to temperature-current curve shown in Fig. 3, similarly, temperature-current curve shown in fig. 6 T1 extremely With the presence of at least one degeneracy point in the curved section of T2 to T3 to T1 so that LED illumination System during the work time will not flashing light.

As one embodiment of the utility model, the simplification of the temperature-current curve of Fig. 3 displayings is further given Version enables I2=I1, enables T4=T1, T3=T2 is enabled to obtain as shown in fig. 7, the curve is on the basis of curve as shown in Figure 3 It arrives.

With reference to Fig. 7, in the curve, slope K 7=I1 ÷ I0,60%≤K7≤80%, and need to meet (T1 ﹣ TE) ÷ (T2 ﹣ TE)≤K7 protects system not damaged because temperature is excessively high；In the curve, the sluggish electric current of I0 and I1 is introduced, is enhanced anti- Interference performance；It is required that 60%≤K7≤80%, (T1 ﹣ TE) ÷ (T2 ﹣ TE)≤K7, and have strict demand to K7 and T1, T2, ensure Wen Sheng caused by the calorific value of LED illumination System is in T1 between T2 controlled.

Based on the analysis to temperature-current curve shown in Fig. 3, similarly, LED illumination System temperature current shown in Fig. 7 Controlling curve, with the presence of at least one degeneracy point, makes LED illumination System exist in the temperature-current curve of T1 to T2 to T1 It will not flashing light in the course of work.

Using one of the LED illumination System temperature current controlling curve specific embodiment of the utility model：Voltage-dropping type LED shines The schematic diagram of bright control system is as shown in Figure 8；

A kind of LED illumination System, including a rectifier bridge (D1-D4), an input capacitance CIN, an energy storage inductor L0, a decompression Control chip 100, a rectifier diode D4, a load capacitance CL, a sampling resistor RCS, LED light bead string 200 and one obtain in real time The temperature sensor (not shown) of the temperature of the LED light bead string 200, the rectifier bridge (D1-D4) two is taken to input termination power, The input capacitance CIN is connected between the positive and negative output end of the rectifier bridge (D1-D4), the decompression control chip 100 Power pins (Vcc+, Gnd) connect the positive and negative output end of the rectifier bridge (D1-D4) respectively, the decompression control chip 100 Driving pin Out connects the anode of the rectifier diode D4, and the current detecting pin CS of the decompression control chip 100 passes through institute The negative output terminal that sampling resistor RCS meets the rectifier bridge (D1-D4) is stated, the cathode of the rectifier diode D4 connects the rectifier bridge It is (D1-D4) in parallel with the rectifier diode D4 after positive output end, the load capacitance CL and energy storage inductor L0 series connection, The anode of the LED light bead string 200 connects the positive output end of the rectifier bridge (D1-D4), and the cathode of the LED light bead string 200 connects The connects end altogether of the load capacitance CL and the energy storage inductor L0；The decompression control chip 100 includes that temperature current controls mould Block 101, the temperature current control module 101 are used for：

During the temperature is increased to second temperature T2 by initial temperature T0, the LED light bead string 200 is controlled LED light electric current is initial current I0, wherein initial temperature T0 is the temperature when LED light bead string 200 starts；

During the temperature is increased to third temperature T3 by second temperature T2, the LED light electric current is controlled by first Beginning electric current I0 drops to the first electric current I1；

During the temperature is increased to the 5th temperature T5 by third temperature T3, the LED light electric current is controlled by One electric current I1 drops to the second electric current I2；

During the temperature drops to the 4th temperature T4 by third temperature T3, controls the LED light electric current and keep In the first electric current I1；

During the temperature drops to the first temperature T1 by the 4th temperature T4, the LED light electric current is controlled by One electric current I1 restores to initial current I0；

Wherein, T4 is less than T2, and T1 is more than T0, and I2 ratios I0 is the second ratio, and I1 ratios I0 is the first ratio；Second ratio Less than or equal to first ratio.

Decompression control chip 100 further includes reference voltage source 102, Logic control module in a more specific embodiment, 103, drive module 104, the first metal-oxide-semiconductor 105, the lowest point detection module 106, peak detection block 107, wherein：

The reference voltage source 102 is connect with the power pins (Vcc+, Gnd) of the decompression control chip 100, and described the The drain electrode of one metal-oxide-semiconductor 105 meets the driving pin Out of the decompression control chip 100, and the source electrode of first metal-oxide-semiconductor 105 meets institute State the current detecting pin CS of decompression control chip 100；

The lowest point detection module 106 is connected to the grid of first metal-oxide-semiconductor 105 and the temperature current control module Between 101, the temperature current control module 101 is output to according to the lowest point signal for detecting first metal-oxide-semiconductor 105；

The temperature current control module 101 is connected to the lowest point detection module 106 and the Logic control module 103 Between, the lowest point delay time signal is exported to the Logic control module 103 according to the lowest point signal；

The peak detection block 107 is connected to the source electrode and the Logic control module 103 of first metal-oxide-semiconductor 105 Between, the peak-current signal for detecting first metal-oxide-semiconductor 105 is exported to the Logic control module 103；

The drive module 104 is connected between the Logic control module 103 and the grid of first metal-oxide-semiconductor 105, 104 Logic control module 103 of the drive module drives according to the lowest point delay time signal and the peak-current signal First metal-oxide-semiconductor, 105 break-make.

Temperature current control module 101 is put including the first hysteresis comparator HYS1, the second hysteresis comparator HYS2, a mutual conductance Big device GM0, the first divider resistance R0, the second divider resistance R1, third divider resistance R2, the 4th divider resistance R3, the first capacitance C0, the second capacitance C1, the first PTAT (Proportional To Absolute Temperature, with absolute temperature is proportional to) Current source I10, the second PTAT current source I11, a constant-current source I12, a diode D5, a zener diode Z0, the second metal-oxide-semiconductor M0, third metal-oxide-semiconductor M1, a phase inverter INV0 and one and door AND2；

The normal phase input end of the first hysteresis comparator HYS1 connects described first by the first divider resistance R0 The anti-phase input of PTAT current source I10, the first hysteresis comparator HYS1 terminate the second PTAT current source I11, described The output of first hysteresis comparator HYS1 terminates the grid of the second metal-oxide-semiconductor M0, and the drain electrode of the second metal-oxide-semiconductor M0 passes through institute The normal phase input end that the second divider resistance R1 meets the first hysteresis comparator HYS1 is stated, the drain electrode of the second metal-oxide-semiconductor M0 is also It is grounded by the third divider resistance R2, the source electrode ground connection of the second metal-oxide-semiconductor M0；The positive of the trsanscondutance amplifier GM0 Input terminates the first PTAT current source I10, and the anti-phase input of the trsanscondutance amplifier GM0 terminates second PTAT current The anode of source I11 and the diode D5, the minus earth of the diode D5, the output termination of the trsanscondutance amplifier GM0 The inverting input of the cathode of the zener diode Z0 and the second hysteresis comparator HYS2, the 4th divider resistance R3 It is in parallel with the zener diode Z0 with the first capacitance C0；The normal phase input end of the second hysteresis comparator HYS2 meets institute It states the drain electrode of constant-current source I12 and the third metal-oxide-semiconductor M1 and is grounded by the second capacitance C1, second hysteresis comparator The input termination input terminal with door AND2 of HYS2, another input with door AND2 terminate the phase inverter INV0 Input terminal, output end output the lowest point delay time of the output end with door AND2 as temperature current control module 101 Signal, the output of the phase inverter INV0 terminate the grid of the third metal-oxide-semiconductor M1, the source electrode ground connection that the 2nd MOS is closed, institute The input terminal for stating phase inverter INV0 detects signal as the input terminal access the lowest point of temperature current control module 101.

Specifically, AC power inputs AC signals, by fuse F0, the full-bridge rectification that is made of D0, D1, D2, D3 it Afterwards, electric energy is stored in input capacitance CIN；Electric energy in input capacitance CIN passes through energy storage inductor L0, decompression control chip 100, rectifier diode D4 is depressured, and electric energy is transferred to load capacitance CL, the electric energy in load capacitance CL is to LED light bead string 200 are powered, and achieve the purpose that drive LED light bead string 200；The maximum output current of the voltage-dropping type LED illumination control system It is configured by sampling resistor RCS；The temperature-current curve of the voltage-dropping type LED illumination control system is by internal temperature current control System (curve) module 101 is set.

PTAT current I10 generates PTAT voltage by divider resistance R1, R2, R0, is input to the positive of trsanscondutance amplifier GM0 Input terminal；PTAT current I11 by diode D5 generate CTAT (Complementary to absolute temperature, With absolute temperature complementarity) voltage, it is input to the inverting input of trsanscondutance amplifier GM0；Trsanscondutance amplifier GM0 to PTAT voltage and The difference of CTAT voltage carries out mutual conductance amplification, obtains mutual conductance electric current IGM0, is input to divider resistance R3, capacitance C0, voltage-stabiliser tube Z0, Stable voltage V0 is obtained on capacitance C0；Constant current I12, capacitance C1, the second metal-oxide-semiconductor M1, hysteresis comparator HYS2, phase inverter INV0, with door AND2 to voltage V0 processing, obtain time the lowest point delay time signal T0, it is directly proportional to the voltage of V0；It is defeated It is that signal is detected in the lowest point to enter signal IN, and output signal OUT is the lowest point delay time signal；When the circuit is by increasing the lowest point delay Between, output current is reduced, temperature current controlling curve is obtained；First hysteresis comparator HYS1 and the first metal-oxide-semiconductor M0 and third point The sluggish control of piezoresistance R2 compositions, obtains sluggish temperature control curve.It is bent by temperature current controlling curve and sluggish temperature control Line is combined into the LED illumination System temperature current controlling curve of the utility model.

The above is only the preferred embodiment of the utility model only, is not intended to limit the utility model, all at this All any modification, equivalent and improvement etc., should be included in the utility model made by within the spirit and principle of utility model Protection domain within.

Claims (7)

1. a kind of LED illumination System, which is characterized in that including a rectifier bridge, an input capacitance, an energy storage inductor, a decompression control Coremaking piece, a rectifier diode, a load capacitance, a sampling resistor, LED light bead string and one obtain the LED light bead string in real time Temperature temperature sensor, the rectifier bridge two input termination power, the input capacitance be connected to the rectifier bridge just, Between negative output terminal, the power pins of the decompression control chip connect the positive and negative output end of the rectifier bridge, the decompression respectively The driving pin of control chip connects the anode of the rectifier diode, and the current detecting pin of the decompression control chip passes through institute The negative output terminal that sampling resistor connects the rectifier bridge is stated, the cathode of the rectifier diode connects the positive output end of the rectifier bridge, In parallel with the rectifier diode after the load capacitance and energy storage inductor series connection, the anode of the LED light bead string meets institute The positive output end of rectifier bridge is stated, the cathode of the LED light bead string connects the connects end altogether of the load capacitance and the energy storage inductor；Institute It includes temperature current control module to state decompression control chip, and the temperature current control module is used for：

During the temperature is increased to second temperature T2 by initial temperature T0, the LED light electricity of the LED light bead string is controlled Stream is initial current I0, wherein initial temperature T0 is the temperature when LED light bead string starts；

During the temperature is increased to third temperature T3 by second temperature T2, the LED light electric current is controlled by initial electricity Stream I0 drops to the first electric current I1；

During the temperature is increased to the 5th temperature T5 by third temperature T3, the LED light electric current is controlled by the first electricity Stream I1 drops to the second electric current I2；

During the temperature drops to the 4th temperature T4 by third temperature T3, controls the LED light electric current and be maintained at One electric current I1；

During the temperature drops to the first temperature T1 by the 4th temperature T4, the LED light electric current is controlled by the first electricity Stream I1 restores to initial current I0；

Wherein, T4 is less than T2, and T1 is more than T0, and I2 ratios I0 is the second ratio, and I1 ratios I0 is the first ratio；Second ratio is less than Or it is equal to first ratio.

2. LED illumination System as described in claim 1, which is characterized in that the decompression control chip further includes reference voltage Source, Logic control module, drive module, the first metal-oxide-semiconductor, the lowest point detection module, peak detection block, wherein：

The reference voltage source connect with the power pins of the decompression control chip, described in the drain electrode of first metal-oxide-semiconductor connects The driving pin of decompression control chip, the source electrode of first metal-oxide-semiconductor connect the current detecting pin of the decompression control chip；

The lowest point detection module is connected between the grid of first metal-oxide-semiconductor and the temperature current control module, according to The lowest point signal for detecting first metal-oxide-semiconductor is output to the temperature current control module；

The temperature current control module is connected between the lowest point detection module and the Logic control module, according to described The lowest point signal exports the lowest point delay time signal to the Logic control module；

The peak detection block is connected between the source electrode and the Logic control module of first metal-oxide-semiconductor, described in detection The peak-current signal of first metal-oxide-semiconductor is exported to the Logic control module；

The drive module is connected between the Logic control module and the grid of first metal-oxide-semiconductor, the drive module Logic control module drives the first metal-oxide-semiconductor break-make according to the lowest point delay time signal and the peak-current signal.

3. LED illumination System as claimed in claim 1 or 2, which is characterized in that the temperature current control module includes first Hysteresis comparator, the second hysteresis comparator, a trsanscondutance amplifier, the first divider resistance, the second divider resistance, third partial pressure electricity Resistance, the 4th divider resistance, the first capacitance, the second capacitance, the first PTAT current source, the second PTAT current source, a constant-current source, one or two Pole pipe, a zener diode, the second metal-oxide-semiconductor, third metal-oxide-semiconductor, a phase inverter and one and door；

The normal phase input end of first hysteresis comparator meets first PTAT current source, institute by first divider resistance The anti-phase input for stating the first hysteresis comparator terminates second PTAT current source, the output termination of first hysteresis comparator The drain electrode of the grid of second metal-oxide-semiconductor, second metal-oxide-semiconductor connects first sluggishness relatively by second divider resistance The drain electrode of the normal phase input end of device, second metal-oxide-semiconductor is also grounded by the third divider resistance, second metal-oxide-semiconductor Source electrode is grounded；The normal phase input end of the trsanscondutance amplifier connects first PTAT current source, the reverse phase of the trsanscondutance amplifier Input terminates the anode of second PTAT current source and the diode, the minus earth of the diode, and the mutual conductance is put The inverting input of the cathode and second hysteresis comparator of the output termination zener diode of big device, described 4th point Piezoresistance and first capacitance are in parallel with the zener diode；The normal phase input end of second hysteresis comparator connects described The drain electrode of constant-current source and the third metal-oxide-semiconductor simultaneously passes through second capacity earth, the input terminal of second hysteresis comparator Connect the input terminal with door, the input terminal that the phase inverter is terminated with door another input, the output with door End exports the lowest point delay time signal as the output end of temperature current control module, and the output of the phase inverter terminates described the The grid of three metal-oxide-semiconductors, the source electrode ground connection that the 2nd MOS is closed, the input terminal of the phase inverter is as temperature current control module Input terminal access the lowest point detect signal.

4. LED illumination System as described in claim 1, which is characterized in that

If the second electric current I2 is less than the first electric current I1, the value range of second ratio is 5%~30%, first ratio The value range of value is 10%~80%；

If the second electric current I2 is equal to the first electric current I1, the value range of second ratio is 10%~80%, described first The value range of ratio is 10%~80%.

5. LED illumination System as described in claim 1, which is characterized in that the second electric current I2 is equal to the first electric current I1.

6. LED illumination System as claimed in claim 5, which is characterized in that third temperature T3 is equal to second temperature T2.

7. LED illumination System as claimed in claim 5, which is characterized in that the 4th temperature T4 is equal to the first temperature T1.