CN203205828U - LED driving power supply input overvoltage protection circuit - Google Patents

Abstract

The utility model relates to an LED driving power supply input overvoltage protection circuit. The circuit comprises an alternating current input voltage, a power supply circuit, an alternating current isolation detection circuit, a signal amplification circuit, a rectifying sampling circuit, an overvoltage return difference circuit and a control circuit. The power supply circuit converts the alternating current input voltage into a first direct current voltage and then outputs the first direct current voltage to the signal amplification circuit, the overvoltage return difference circuit and the control circuit. The alternating current isolation detection circuit converts the received alternating current input voltage into a low voltage, and then outputs the low voltage to the signal amplification circuit. The signal amplification circuit amplifies low voltage signals, and then outputs the amplified signals to the rectifying sampling circuit. The rectifying sampling circuit rectifies the amplified voltage signals, and then outputs the rectified voltage to the overvoltage return difference circuit. The overvoltage return difference circuit compares the rectified second direct current voltage to a preset voltage, and then outputs level signals to the control circuit. The control circuit controls power supply and power outage of an LED driving power supply. The LED driving power supply input overvoltage protection circuit can protect an LED driving power supply from the surge of overvoltage of a power grid and is advantaged by low cost and high reliability.

Description

LED driving power protection circuit against input over-voltage

Technical field

The utility model relates to the overvoltage crowbar technology, is specifically related to a kind of LED driving power protection circuit against input over-voltage.

Background technology

Because the forward voltage-current characteristic of LED is very steep, dynamic electric resistor is less, powers so that it can not directly use civil power to exchange input, otherwise when change appears in voltage, especially when voltage increased, the electric current that flows through LED can sharply increase, and causes the LED load to be damaged.Thereby must exchange with civil power between the input in the LED load LED driving power is set, fully satisfying the LED required driving requirement of working, thereby bring into play to greatest extent the performance of LED, reduce failure rate.The LED driving power is that the power supply supply is converted to specific electric current and voltage with the luminous electric pressure converter of driving LED.The LED driving power of prior art with exchange the input between without any overvoltage crowbar; and the operating current fluctuation at the LED two ends that the LED driving power can't cause fluctuating because of external voltage is adjusted; mains supply spread of voltage again; fluctuation is large; therefore; very easily cause the driving power of large quantities of street lamps to damage, even cause LED to damage.

Summary of the invention

The purpose of this utility model is for the deficiencies in the prior art; a kind of LED driving power protection circuit against input over-voltage is provided; this LED driving power protection circuit against input over-voltage is arranged on the LED driving power and exchanges between the input; protection LED driving power is avoided the impact of electrical network overvoltage voltage, and this overvoltage crowbar has advantages of that cost is low, reliability is high.

The purpose of this utility model is achieved in that a kind of LED driving power protection circuit against input over-voltage, comprise AC-input voltage, power circuit, interchange isolation detection circuit, signal amplification circuit, rectification sample circuit, overvoltage return difference circuit and control circuit, described power circuit converts AC-input voltage to first direct voltage and exports to respectively signal amplification circuit, overvoltage return difference circuit and control circuit power supply; Described interchange isolation detection circuit converts the AC-input voltage that receives to low-voltage and passes to signal amplification circuit; Described signal amplification circuit is exported to the rectification sample circuit after low voltage signal is amplified; Described rectification sample circuit carries out the voltage signal after signal amplification circuit amplifies to export to overvoltage return difference circuit after the rectification; Described overvoltage return difference circuit compares the second direct voltage after the rectification of rectification sample circuit and the magnitude of voltage of presetting, and outputs level signals is to control circuit; Described control circuit is controlled powering on, cutting off the power supply of LED driving power according to the level signal of overvoltage return difference circuit output.

Described interchange isolation detection circuit comprises voltage transformer pt 1 and resistance, wherein, resistance R 7 one ends connect the first input end of voltage transformer pt 1, the other end connects the L end that exchanges input, the second input of voltage transformer pt 1 connects the N end that exchanges input, resistance R 8 is connected between two outputs of voltage transformer pt 1, the end of resistance R 10 1 end contact resistance R8, the first output of voltage transformer pt 1, the end of resistance R 10 other end contact resistance R9, ground, the other end of the other end contact resistance R8 of resistance R 9, the second output of voltage transformer pt 1, the first output of voltage transformer pt 1 connects the input of signal amplification circuit.

Described signal amplification circuit comprises amplifier U2A and resistance, resistance R 11 1 ends connect the normal phase input end of amplifier U2A, the other end connects the output that exchanges isolation detection circuit, resistance R 19 1 ends connect the output of amplifier U2A, the other end connects inverting input, resistance R 18 1 ends of amplifier U2A, resistance R 18 other end ground connection, the output of amplifier U2A connects the input of rectification sample circuit.

Described rectification sample circuit comprises current-limiting resistance R12, rectifier diode D4, and the charge-discharge circuit that is formed by resistance R 13 and capacitor C 8, described current-limiting resistance R12 and rectifier diode D4 are connected between the input of the output of signal amplification circuit and overvoltage return difference circuit, and described resistance R 13 and capacitor C 8 are connected in parallel between the negative pole and ground of rectifier diode D4.

Described overvoltage return difference circuit comprises comparator U2B and resistance, voltage-stabiliser tube, resistance R 15 1 ends connect the inverting input of comparator U2B, the other end connects the output of rectification sample circuit, resistance R 14 1 ends connect the output of reference voltage circuit, the other end connects in-phase input end, resistance R 16 1 ends of comparator U2B, the other end of resistance R 16 connects the negative pole of voltage-stabiliser tube Z2, the plus earth of voltage-stabiliser tube Z2, one end of resistance R 17 connects the output of comparator U2B, and the other end of resistance R 17 connects the input of control circuit, the negative pole of voltage-stabiliser tube Z2.

Described reference voltage circuit comprises three terminal regulator and resistance, resistance R 1, resistance R 2 and resistance R 3 are connected between supply power voltage VCC and the ground successively, the input of three terminal regulator is connected between resistance R 1 and the resistance R 2, the output of three terminal regulator is connected between resistance R 2 and the resistance R 3, the earth terminal ground connection of three terminal regulator.

Described control circuit comprises triode Q1, diode D1, D3, relay K and resistance, the negative pole of diode D1 connects the output of overvoltage return difference circuit, the end of the anodal contact resistance R5 of diode D1, one end of resistance R 4, the other end of resistance R 4 connects supply power voltage VCC, the base stage of the other end connecting triode Q1 of resistance R 5, the grounded collector of triode Q1, the emitter of triode Q1 connects an end of the coil of relay K, the other end of the coil of relay K connects supply power voltage VCC, diode D3 is connected in parallel on the coil two ends of relay K, normally-closed contact one end of relay K connects the L end that exchanges input, and the other end connects the 1st pin of LED driving power.

Described power circuit comprises the AC-DC power module, and first, second and third input of AC-DC power module connects respectively L end, N end, the EARTH end of interchange input, is in series with fuse F1 between the L end of interchange input and the first input end of AC-DC power module.

Described power circuit also comprises an anti-interference filtration circuit, and the output of this anti-interference filtration circuit is connected with first and second input of AC-DC power module, and the input of this anti-interference filtration circuit is connected with the N end of fuse F1 one end, interchange input.

The beneficial effects of the utility model are: since the LED driving power with exchange LED driving power protection circuit against input over-voltage is set between inputting after; when line voltage is higher than default magnitude of voltage; pass through control relay; the power supply of automatic disconnection LED driving power; when line voltage recovers normal; the LED driving power re-powers automatically, has so just guaranteed the normal operation of LED driving power.And the utility model is simple in structure, cost is low, and reliability is high.

Description of drawings

Fig. 1 is schematic block circuit diagram of the present utility model;

Fig. 2 is circuit diagram of the present utility model.

In the accompanying drawing, 1 is AC-input voltage, and 2 is power circuit, and 3 for exchanging isolation detection circuit, and 4 is signal amplification circuit, and 5 are the rectification sample circuit, and 6 are overvoltage return difference circuit, and 7 is control circuit, and 8 is the LED driving power.

Embodiment

Referring to Fig. 1, a kind of LED driving power protection circuit against input over-voltage, comprise AC-input voltage 1, power circuit 2, exchange isolation detection circuit 3, signal amplification circuit 4, rectification sample circuit 5, overvoltage return difference circuit 6 and control circuit 7, described power circuit 2 converts AC-input voltage 1 to first direct voltage and exports to respectively signal amplification circuit 4, overvoltage return difference circuit 6 and control circuit 7 power supplies; Described interchange isolation detection circuit 3 converts the AC-input voltage 1 that receives to low-voltage and passes to signal amplification circuit 4; Described signal amplification circuit 4 is exported to rectification sample circuit 5 after low voltage signal is amplified; Described rectification sample circuit 5 carries out the voltage signal after signal amplification circuit amplifies to export to overvoltage return difference circuit 6 after the rectification; Described overvoltage return difference circuit 6 compares the second direct voltage after the rectification of rectification sample circuit and the magnitude of voltage of presetting, and outputs level signals is to control circuit 7; Described control circuit 7 is controlled powering on, cutting off the power supply of LED driving power 8 according to the level signal of overvoltage return difference circuit output.

Referring to Fig. 2, described power circuit comprises AC-DC power module M1, first, second and third input of AC-DC power module M1 connects respectively L end, N end, the EARTH end that exchanges input, wherein, and the 3rd input of AC-DC power module M1 and exchanges the EARTH that inputs and hold all pick shell or frame.Be in series with fuse F1 between the L end of interchange input and the first input end of AC-DC power module.Described power circuit also comprises an anti-interference filtration circuit, piezo-resistance VR1, thermistor RT1, and piezo-resistance VR1 one end connects fuse F1 one end, and the other end connects the N end that exchanges input.The input of this anti-interference filtration circuit is connected with the N end of fuse F1 one end, interchange input, and the output of this anti-interference filtration circuit is connected with the input of AC-DC power module.Described anti-interference filtration circuit comprises common mode inductance LP1, differential mode suppresses capacitor C X1, common mode inhibition capacitor C 1, C2 forms, wherein, differential mode suppresses capacitor C X1 and is connected between two inputs of common mode inductance LP1, common mode inhibition capacitor C 1, C2 connects first and is connected in parallel on afterwards between two outputs of common mode inductance LP1, common mode inhibition capacitor C 1, shell or frame pick between the C2, differential mode suppresses the end of capacitor C X1 and the end of piezo-resistance VR1, fuse F1 one end, differential mode suppresses the other end of capacitor C X1 and the other end of piezo-resistance VR1, the N end that exchanges input connects, thermistor RT1 one end connects an end of common mode inhibition capacitor C 1, the first output of common mode inductance LP1, the other end of thermistor RT1 connects the first input end of AC-DC power module M1.The output of AC-DC power module M1 is connected with voltage stabilizing circuit, described voltage stabilizing circuit comprises voltage-stabiliser tube Z1, capacitor C 3, capacitor C 4, voltage-stabiliser tube Z1, capacitor C 3, capacitor C 4 parallel connections, the positive pole of voltage-stabiliser tube Z1 connects the second output of AC-DC power module M1, the negative pole of voltage-stabiliser tube Z1 connects the first output of AC-DC power module M1, the positive pole of capacitor C 3 connects the first output of AC-DC power module M1, the negative pole of capacitor C 3 connects the second output of AC-DC power module M1, one end of capacitor C 4 connects the first output of AC-DC power module M1, and the other end of capacitor C 4 connects the second output of AC-DC power module M1.

Referring to Fig. 2, described interchange isolation detection circuit comprises voltage transformer pt 1 and resistance, wherein, resistance R 7 one ends connect the first input end of voltage transformer pt 1, the other end connects the L end that exchanges input, the second input of voltage transformer pt 1 connects the N end that exchanges input, resistance R 8 is connected between two outputs of voltage transformer pt 1, the end of resistance R 10 1 end contact resistance R8, the first output of voltage transformer pt 1, the end of resistance R 10 other end contact resistance R9, ground, the other end of the other end contact resistance R8 of resistance R 9, the second output of voltage transformer pt 1, the first output of voltage transformer pt 1 connects the input of signal amplification circuit.

Referring to Fig. 2, described signal amplification circuit comprises amplifier U2A and resistance, resistance R 11 1 ends connect the normal phase input end of amplifier U2A, the other end connects the output that exchanges isolation detection circuit, the first output of an end of the other end contact resistance 10 of the resistance R 11 in the present embodiment, an end of resistance 8, voltage transformer pt 1.Resistance R 19 1 ends connect the output of amplifier U2A, and the other end connects inverting input, resistance R 18 1 ends of amplifier U2A, resistance R 18 other end ground connection, and the output of amplifier U2A connects the input of rectification sample circuit.

Referring to Fig. 2, described rectification sample circuit comprises current-limiting resistance R12, rectifier diode D4, and the charge-discharge circuit that is formed by resistance R 13 and capacitor C 8, described current-limiting resistance R12 and rectifier diode D4 are connected between the input of the output of signal amplification circuit and overvoltage return difference circuit, in the present embodiment, the end of current-limiting resistance R12 connects the output of amplifier U2A, the other end of current-limiting resistance R12 connects the positive pole of rectifier diode D4, the negative pole of rectifier diode D4 connects an end of capacitor C 8, one end of resistance R 13, described resistance R 13 and capacitor C 8 are connected in parallel between the negative pole and ground of rectifier diode D4.

Referring to Fig. 2, described overvoltage return difference circuit comprises comparator U2B and resistance, voltage-stabiliser tube, and resistance R 15 1 ends connect the inverting input of comparator U2B, and resistance R 15 other ends connect the output of rectification sample circuit, in the present embodiment, the other end of resistance R 15 connects the negative pole of rectifier diode D4.Resistance R 14 1 ends connect the output of reference voltage circuit, the other end connects in-phase input end, resistance R 16 1 ends of comparator U2B, the other end of resistance R 16 connects the negative pole of voltage-stabiliser tube Z2, the plus earth of voltage-stabiliser tube Z2, one end of resistance R 17 connects the output of comparator U2B, and the other end of resistance R 17 connects the input of control circuit, the negative pole of voltage-stabiliser tube Z2.Described reference voltage circuit comprises three terminal regulator and resistance, resistance R 1, resistance R 2 and resistance R 3 are connected between supply power voltage VCC and the ground successively, the input of three terminal regulator is connected between resistance R 1 and the resistance R 2, the output of three terminal regulator is connected between resistance R 2 and the resistance R 3, the earth terminal ground connection of three terminal regulator.

The amplifier U2A of the present embodiment, comparator U2B have formed a double operational U2 jointly, and the 8th pin of double operational U2 connects supply power voltage VCC, the 4th pin ground connection of double operational U2.Be in series with capacitor C 7 between the 8th pin of double operational U2 and the 4th pin.

Referring to Fig. 2, described control circuit comprises positive-negative-positive triode Q1, diode D1, D2, D3, relay K and resistance, the negative pole of diode D1 connects the output of overvoltage return difference circuit, the negative pole contact resistance R17 of the diode D1 of the present embodiment, the negative pole of voltage-stabiliser tube Z2, the end of the anodal contact resistance R5 of diode D1, one end of resistance R 4, the other end of resistance R 4 connects supply power voltage VCC, the base stage of the other end connecting triode Q1 of resistance R 5, the grounded collector of triode Q1, the emitter of triode Q1 connects an end of the coil of relay K, the other end of the coil of relay K connects supply power voltage VCC, diode D3 is connected in parallel on the coil two ends of relay K, normally-closed contact one end of relay K connects the L end that exchanges input, and the other end connects the 1st pin of LED driving power.In the present embodiment, resistance R 6 and the two ends that are connected in parallel on the normally-closed contact of relay K after capacitor C 6 is connected, resistance R 6 and capacitor C 6 form the electronic arc-absorption circuit of relay K normally-closed contacts.One end of the positive pole of the cathode connecting diode D1 of diode D2, an end of resistance R 4, resistance R 5, the negative pole of diode D2 connects the JDQ pin of single-chip microcomputer, can directly control the LED driving power by the single-chip microcomputer user.

Operation principle of the present utility model is as follows: referring to Fig. 2, AC-input voltage passes the signal to the other end by the voltage transformer pt 1 that exchanges isolation detection circuit after by resistance R 7 current limlitings, by resistance R 8 electric current is changed into low-voltage, after the voltage that sends is amplified by amplifier U2A, the rectification sample circuit of flowing through,, discharged and recharged by capacitor C 8 and resistance R 13 again by diode D3 rectification by resistance R 12 current limlitings, flow to overvoltage return difference circuit.At this moment; when the voltage of the inverting input V-of comparator U2B surpasses the default high voltage V+ of comparator U2B normal phase input end; the output output low level of comparator U2B; triode Q1 is because of the clamper conducting of diode D1; the current potential that the emitter Ctrl of triode Q1 is ordered is dragged down, the coil electricity of relay K, and the normally-closed contact of relay K disconnects; can disconnect the power supply of LED driving power, thereby protect the LED driving power.When the voltage of the inverting input V-of comparator U2B is lower than the default low voltage V+ of comparator U2B normal phase input end, the output output high level of comparator U2B, triode Q1 ends because of the cut-off of diode D1, the current potential that the emitter Ctrl of triode Q1 is ordered is drawn high, the coil blackout of relay K, the normally-closed contact of relay K is closed, and the LED driving power re-powers, and the LED driving power is resumed work again.The default high voltage V+ of the normal phase input end of comparator U2B is called high threshold voltage, the default low voltage V+ of the normal phase input end of comparator U2B is called low threshold voltage, both differences are the overvoltage return difference, and the return difference value is determined by resistance R 14, resistance R 16 and voltage-stabiliser tube Z2.

Claims (9)

1. LED driving power protection circuit against input over-voltage, it is characterized in that: comprise AC-input voltage, power circuit, interchange isolation detection circuit, signal amplification circuit, rectification sample circuit, overvoltage return difference circuit and control circuit, described power circuit converts AC-input voltage to first direct voltage and exports to respectively signal amplification circuit, overvoltage return difference circuit and control circuit power supply; Described interchange isolation detection circuit converts the AC-input voltage that receives to low-voltage and passes to signal amplification circuit; Described signal amplification circuit is exported to the rectification sample circuit after low voltage signal is amplified; Described rectification sample circuit carries out the voltage signal after signal amplification circuit amplifies to export to overvoltage return difference circuit after the rectification; Described overvoltage return difference circuit compares the second direct voltage after the rectification of rectification sample circuit and the magnitude of voltage of presetting, and outputs level signals is to control circuit; Described control circuit is controlled powering on, cutting off the power supply of LED driving power according to the level signal of overvoltage return difference circuit output.

2. LED driving power protection circuit against input over-voltage according to claim 1; it is characterized in that: described interchange isolation detection circuit comprises voltage transformer pt 1 and resistance; wherein; resistance R 7 one ends connect the first input end of voltage transformer pt 1; the other end connects the L end that exchanges input; the second input of voltage transformer pt 1 connects the N end that exchanges input; resistance R 8 is connected between two outputs of voltage transformer pt 1; the end of resistance R 10 1 end contact resistance R8; the first output of voltage transformer pt 1; the end of resistance R 10 other end contact resistance R9; ground; the other end of the other end contact resistance R8 of resistance R 9; the second output of voltage transformer pt 1, the first output of voltage transformer pt 1 connects the input of signal amplification circuit.

3. LED driving power protection circuit against input over-voltage according to claim 1; it is characterized in that: described signal amplification circuit comprises amplifier U2A and resistance; resistance R 11 1 ends connect the normal phase input end of amplifier U2A; the other end connects the output that exchanges isolation detection circuit; resistance R 19 1 ends connect the output of amplifier U2A; the other end connects inverting input, resistance R 18 1 ends of amplifier U2A; resistance R 18 other end ground connection, the output of amplifier U2A connects the input of rectification sample circuit.

4. LED driving power protection circuit against input over-voltage according to claim 1; it is characterized in that: described rectification sample circuit comprises current-limiting resistance R12, rectifier diode D4; and the charge-discharge circuit that is formed by resistance R 13 and capacitor C 8; described current-limiting resistance R12 and rectifier diode D4 are connected between the input of the output of signal amplification circuit and overvoltage return difference circuit, and described resistance R 13 and capacitor C 8 are connected in parallel between the negative pole and ground of rectifier diode D4.

5. LED driving power protection circuit against input over-voltage according to claim 1; it is characterized in that: described overvoltage return difference circuit comprises comparator U2B and resistance; voltage-stabiliser tube; resistance R 15 1 ends connect the inverting input of comparator U2B; the other end connects the output of rectification sample circuit; resistance R 14 1 ends connect the output of reference voltage circuit; the other end connects the in-phase input end of comparator U2B; resistance R 16 1 ends; the other end of resistance R 16 connects the negative pole of voltage-stabiliser tube Z2; the plus earth of voltage-stabiliser tube Z2; one end of resistance R 17 connects the output of comparator U2B, and the other end of resistance R 17 connects the input of control circuit; the negative pole of voltage-stabiliser tube Z2.

6. LED driving power protection circuit against input over-voltage according to claim 5; it is characterized in that: described reference voltage circuit comprises three terminal regulator and resistance; resistance R 1, resistance R 2 and resistance R 3 are connected between supply power voltage VCC and the ground successively; the input of three terminal regulator is connected between resistance R 1 and the resistance R 2; the output of three terminal regulator is connected between resistance R 2 and the resistance R 3, the earth terminal ground connection of three terminal regulator.

7. LED driving power protection circuit against input over-voltage according to claim 1; it is characterized in that: described control circuit comprises triode Q1; diode D1; D3; relay K and resistance; the negative pole of diode D1 connects the output of overvoltage return difference circuit; the end of the anodal contact resistance R5 of diode D1; one end of resistance R 4; the other end of resistance R 4 connects supply power voltage VCC; the base stage of the other end connecting triode Q1 of resistance R 5; the grounded collector of triode Q1; the emitter of triode Q1 connects an end of the coil of relay K; the other end of the coil of relay K connects supply power voltage VCC; diode D3 is connected in parallel on the coil two ends of relay K; normally-closed contact one end of relay K connects the L end that exchanges input, and the other end connects the 1st pin of LED driving power.

8. LED driving power protection circuit against input over-voltage according to claim 1; it is characterized in that: described power circuit comprises the AC-DC power module; first, second and third input of AC-DC power module connects respectively L end, N end, the EARTH end of interchange input, is in series with fuse F1 between the L end of interchange input and the first input end of AC-DC power module.

9. LED driving power protection circuit against input over-voltage according to claim 8; it is characterized in that: described power circuit also comprises an anti-interference filtration circuit; the output of this anti-interference filtration circuit is connected with first and second input of AC-DC power module, and the input of this anti-interference filtration circuit is connected with the N end of fuse F1 one end, interchange input.

Images