SYSTEM AND METHOD FOR REPURPOSING 120VAC WIRING ARCHITECTURE TO RETROFITABLE LOW VOLTAGE DC POWER 2-WIRE LED DIMMING

Abstract

A 2-Wire LED dimming system and method re-purposes existing 120V AC architecture and hardware to carry low voltage PWM gradient DC power to the LED lamps provides a consistent gradation over a 0-100% dimming range. An LED Driver is electrically connected to an AC power source and connect to at least one LED lamp. The AC power source is electrically connected to an AC to DC converter where the AC power is converted to filtered and regulated DC power for the control unit and the power switch. The power switch is electrically connected to the AC to DC converter DC power output. The control unit is electrically connected to the power switch which is turned ON or OFF according to the pulse width modulation PWM signal from the control unit in order to connect or disconnect the DC power from the AC to DC converter.

Claims

1. A dimming circuit requiring not more than 2 wires, configured to dim a lighting module, comprising: one or more LED lamp(s) that is electrically connected to a single external LED driver; an over-voltage protection unit that prevents damage to the components in the event of an over voltage condition; a rectifier circuit to convert AC and DC voltage signals to the correct polarity; a LED module electrically connected to the rectifier circuit and the current regulator input terminal; a current regulator electrically connected to the LED module, with the rectifier circuit electrically connected to the current regulator; a shutdown switch is electrically connected to the LED module and the rectifier circuit; a voltage detection unit which monitors the voltage between the LED module cathode terminals, with the shutdown switch electrically connected to the base of a transistor; a voltage detection unit is configured to turn a transistor on when the voltage at the LED module cathode terminal exceeds a predetermined level, which connects with the base of another transistor to turn it off; a driver that contains a power factor corrected, filtered and regulated DC power supply that provides power to the control circuitry as well as the lamps; a high dimming ratio to achieve “deep” dimming, which serves as a function of the driver's PWM signal; a consistent brightness between adjacent lamps where the brightness of all lamps are controlled by the same PWM power; a consistent brightness between adjacent lamps where the brightness of all lamps are controlled by the same PWM power; and dimming angle sensing, which converts a “reverse” or “forward” AC mains phase-cut signal to an isolated low voltage control signal CTL, thus allowing for third party phase-cut dimmers interchangeable use of this low voltage LED system.

2. The dimming circuit of claim 1, wherein the voltage detecting unit comprises: a voltage monitor between the LED module cathode terminal, wherein a shutdown switch is electrically connected to the base of a transistor, and the voltage detection unit is configured to turn a transistor on when the voltage at the LED module cathode terminal exceeds a predetermined level, which connects the base of another transistor to turn that transistor off.

3. The dimming circuit of claim 1, further comprising: an interruption to the current flow to the current regulator, protecting it in the event of an LED module short circuit or excessive input voltage.

4. A dimmable LED lamp or series of dimmable lamps comprising: a driver module; an LED lamp or plurality of lamps that is electrically connected to a single external LED driver; an over-voltage protection unit that prevents damage to the components in the event of an over voltage condition; a rectifier circuit to convert AC and DC voltage signals to the correct polarity; an LED module electrically connected to the rectifier circuit and the current regulator input terminal; a current regulator electrically connected to the LED module, with the rectifier circuit electrically connected to the current regulator; a shutdown switch is electrically connected to the LED module and the rectifier circuit; a voltage detection unit monitors the voltage between the LED module cathode terminals, with the shutdown switch electrically connected to the base of a transistor; a voltage detection unit is configured to turn a transistor on when the voltage at the LED module cathode terminal exceeds a predetermined level, which connects with the base of another transistor to turn it off; a driver that contains a power factor corrected, filtered and regulated DC power supply that provides power to the control circuitry as well as the lamps; a high dimming ratio to achieve “deep” dimming, which serves as a function of the driver's PWM signal; a consistent brightness between adjacent lamps where the brightness of all lamps are controlled by the same PWM power; and a consistent brightness between adjacent lamps where the brightness of all lamps are controlled by the same PWM power.

5. The dimmable LED lamp device of claim 4, wherein an externally connected LED Driver is electrically connected to an AC power source, and contains an AC to DC converter, control unit and power switch.

6. The dimmable LED lamp device of claim 4, further comprising: a receiving module electrically connected to the control unit, and configured to receive an external dimming signal and to output a control signal to the control unit according to the external dimming signal; wherein the control unit is configured to adjust a duty cycle of the pulse width modulation signal according to the control signal to control a terminal voltage of the lighting module.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0017] FIG. 1 shows a schematic view of an LED driver according to an embodiment of the present invention.

[0018] FIG. 2 shows a schematic view of an LED lamp according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

[0019] FIG. 1 shows LED driver 100 which is electrically connected to an AC power source 110. The LED driver 100 output terminals LED+ and LED− electrically connect to a plurality of LED lamps 150 as described in FIG. 2. The AC power source 110 is electrically connected to the AC to DC converter 120 where the AC power is converted to filtered and regulated DC power V.sub.PS for the control unit 130 and the power switch 140.

[0020] The power switch 140 is electrically connected to the AC to DC converter 120 DC power output V.sub.PS. The control unit 130 is electrically connected to the power switch 140. The power switch 140 is turned ON or OFF according to the pulse width modulation PWM signal from the control unit 130 in order to connect or disconnect the DC power (V.sub.PS) from the AC to DC converter 120 to the positive output terminal LED+ of the LED driver 100. In the present disclosure, the power switch 140 may be implemented with a P-type metal-oxide semiconductor (PMOS), in which the gate terminal of the PMOS is connected to the control unit 130, the drain terminal on the PMOS is connected to the positive output terminal LED+ and the source terminal of the PMOS is connected to the AC to DC converter voltage V.sub.PS. However, such a configuration is not meant to limit the power switch 140 of the present disclosure. The power switch 140 could be implemented with either a PMOS, NMOS or bipolar transistor as either a high-side, low-side or push-pull type switch to connect or disconnect the output terminal LED+ of the LED driver 100.

[0021] The control unit 130 is configured to receive external control signal CMD via wired or wireless connection and adjust the duty cycle of the pulse width modulated PWM signal according to the control commands.

[0022] The control unit 130 monitors voltage V.sub.PS from the AC to DC converter 120 to provide over and under voltage protection to the LED lamps. The control unit 130 monitors the LED− return current to provide short circuit and over-load protection for the LED driver 100. If the control unit 130 detects any of these conditions, it turns OFF the power switch 140 disconnecting it from the LED lamp(s) 150.

[0023] The control unit 130 is also configured to receive control signal CTL from the dimming angle sensing unit 121 and adjust the duty cycle of the pulse width modulated PWM signal accordingly. The dimming angle sensing unit 121 can be electrically connected to an AC mains forward or reverse phase cut signal 111 generated by an external dimmer unit. The dimming angle sensing unit 121 generates the electrically isolated low voltage control signal CTL corresponding to the conduction angle of the phase cut signal 111.

[0024] FIG. 2 shows an embodiment of an LED lamp 150. The LED lamp 150 input terminals V.sub.INA and V.sub.INB electrically connect to a single LED driver 100 terminals LED+ and LED− in shown in FIG. 1.

[0025] The input terminals V.sub.INA and V.sub.INB are electrically connected to the input over-voltage protection unit 160. The input over-voltage protection unit 160 is a bi-directional crowbar circuit that prevents damage to the LED lamp 150 circuits from an accidental over-voltage condition. In the event of an over-voltage condition, the bi-directional thyristor D1 switches ON providing a low resistance path between input terminals V.sub.INA and V.sub.INB. The excessive current causes the fuse F1 to open interrupting power to the lamp.

[0026] The rectifier circuit 170 is electrically connected to the protected side (V.sub.INP) of fuse F1 and LED lamp 150 input terminal V.sub.INB. The rectifier circuit 170 is configured to convert the PWM input power at terminals V.sub.INA and V.sub.INB of either polarity to the correct polarity required by the LED module 190 and the lamp circuits. For example, in one embodiment, the rectifier circuit 170 may be implemented by a bridge rectifier including diodes D2, D3, D4, and D5, in which the cathode terminals of the diodes D2 and D3 are electrically connected to the anode terminal A of the LED module 190, and the anode terminals of the diodes D4 and D5 are electrically connected to the LED power return V−. Note that the rectifier circuit 170 may be implemented in a variety of ways, and the bridge rectifier illustrated in FIG. 2 is only an example and not meant to limit the present disclosure.

[0027] The LED module 190 anode terminal A is electrically connected to the V+ terminal of the rectifier circuit 170 diodes D2 and D3 cathode terminals. The LED module 190 cathode terminal K is electrically connected to the current regulator input terminal V.sub.C. In an embodiment of the present disclosure, the LED module 190 can be comprised of, but not limited to, SMD (Surface Mount Device) LEDs in a series, parallel or series-parallel arrangement or LED COB (Chip On Board) module.

[0028] The current regulator 200 is electrically connected to the LED module 190 cathode terminal K. The rectifier circuit 170 terminals V+ and V− are electrically connected to the current regulator 200. The current regulator 200 provides a fixed (constant) current to the LED module 190. For example, in one embodiment, the current regulator 200 may be implemented with a constant current sink. LED voltage V+ is converted to current by resistor R1 to provide base current to the transistor Q2 current amplifier. Error amplifier OA1 and transistor Q3 operate to maintain a fixed voltage across LED current limiting resistor R2. The inverting input 204 of OA1 is configured to receive voltage reference V.sub.REF. The non-inverting input 202 of OA1 is configured to receive transistor Q2 emitter voltage V.sub.E. Error voltage at the input 202 of OA1 will result in a corresponding increasing or decreasing current at the output terminal 206 of OA1 which drives the base of transistor Q3. Transistor Q3 will shunt more or less base current from Q2 to maintain a fixed voltage V.sub.E that is equal to reference voltage V.sub.REF. Voltage V.sub.E across resistor R2 determines the LED current. Note that the current regulator 200 may be implemented in a variety of ways, and the constant current sink illustrated in FIG. 2 is only an example and not meant to limit the present disclosure.

[0029] The shutdown switch 180 is electrically connected to the LED module 190 cathode terminal K and the rectifier circuit 170 V− terminal. The voltage detection unit 182 monitors the voltage between the LED module 190 cathode terminal K and V−. The shutdown switch 180 is electrically connected to the base V.sub.B of transistor Q2. In the present disclosure, the switch Q1 is implemented with an N-type metal-oxide semiconductor (NMOS), in which the gate terminal of Q1 is connected to the voltage detection unit 182, the drain terminal of Q1 is connected to the base terminal of Q2 and the source terminal of Q1 is connected to the V− terminal of the rectifier circuit 170. The voltage detection unit 182 is configured to turn Q1 ON when the voltage at the LED module 190 cathode terminal K exceeds a predetermined level. This connects of base of Q2 to V− to turn Q2 OFF. This interrupts the current flow to the current regulator 200, protecting it in the event of an LED module 190 short circuit or excessive input voltage.