BRPI0902081A2 - bipolar charge / discharge led drive circuit - Google Patents

Abstract

BIPOLAR CHARGE / DISCHARGE LED ACTIVATION CIRCUIT Bipolar discharge LED drive method and circuit, which features a diode connected in series of direct polarity with an LED before being connected in parallel with a bipolar capacitor in the same polarity for constituting the first component, and having a diode, a capacitor and an optional light emitting diode to constitute the second component; the first and second components are connected in series of inverted polarity to be driven by AC source, or DC capable of periodically changing polarity.

Description

"BIPOLAR LOAD / DROP LED DRIVING CIRCUIT"

BACKGROUND OF THE INVENTION

(a) Field of the Invention

The present invention relates to an innovative method circuit design and LED drive circuit which can be powered by an AC or DC power source with polarity change period and, more specifically, a source where the operating function is by the capacitor. To produce bipolar electric charge / discharge source to drive light emitting diode, to have the advantages of low thermal loss, energy consumption and production cost.

(b) Description of the Prior Art

Whereas conventionally, an ac or dc power source driven circuit with polarity change period should always include a rectifying bridge and a limiting resistance to drop, thermal loss, lost energy and increased production costs, As a result, the light emitting diode has faults in both the rectifying bridge and the fall resistance, which are the faults found in the prior art.

SUMMARY OF THE INVENTION

The primary purpose of the present invention is to provide a method of driving bipolar discharge LED and the circuit thereof. The present invention comprises a first component and a second component connected in series of inverted polarity. The first component includes a direct polarity serial diode with a light-conducting polarity of an LED before being connected in parallel at the same polarity with a bipolar capacitor; and the second component comprises a diode and a double-pole capacitor, or the diode may be selected as required to be connected in series with an optional light-emitting diode, so that the method of constituting the second component includes: (1) when the Optional LEDsSelected to be installed, the diode can be connected in series with the LED in direct polarity with the LED's driving conduction polarity before being connected in parallel in the same polarity with a bipolar capacitor, so to constitute a first type of the second component;

(2) If the optional LED is selected not to be installed on the second component, the diode is connected in parallel at the same polarity with the bipolar capacitor to constitute a second type of the second component.

The first component is connected in series of inverted polarity with any type of the second component to constitute an LED drive circuit (U100) capable of charging and discharging. The two terminals of the LED drive circuit (UlOO) capable of charging and discharging are for input:

(1) AC source with constant or variable voltage and constant or variable frequency; or

(2) The electrical source with constant constant voltage and alternating periods of constant constant polarity converted from a DC power source; or

(3) The electrical source with constant constant voltage and alternating periods of constant constant polarity converted from DC source is rectified additionally from AC source.

BRIEF DESCRIPTION OF DRAWINGS

Figure 1 is a schematic view showing a basic circuit configuration of the present invention.

Figure 2 is an exemplary circuit diagram showing a zener diode additionally mounted to a light emitting diode in the circuit of Figure 1.

Figure 3 is an exemplary circuit diagram showing that a discharge / discharge device may be connected in parallel by the two terminals of a current limiting resistor and a light emitting diode in series connection in the circuit of Figure 2. Figure 4 is a An exemplary circuit schematic block diagram showing that the present invention is connected in series to a series disconnect type AC source modulator.

Figure 5 is an exemplary circuit schematic block diagram showing that the present invention is connected in parallel with a parallel disconnect type AC source modulator.

Figure 6 is an exemplary circuit schematic block diagram showing that the present invention is connected in series to an alternating power modulator of periodically modulated series connection type polarities.

Figure 7 is an exemplary circuit schematic block diagram showing that the present invention is connected in parallel with an alternating power modulator of periodically modulated paired connection type polarities.

Figure 8 is a schematic circuit block diagram showing that the present invention is connected in series to an alternating power modulator of periodically modulated connection type polarities in series being electrically driven by a DC to AC inverter output.

Figure 9 is an exemplary circuit schematic block diagram showing that the present invention is connected in parallel with an alternating power modulator of periodically modulated parallel connection type polarities before being electrically driven by an output from a DC to AC inverter. .

Figure 10 is an exemplary circuit schematic block diagram showing that the present invention is electrically driven by an output from a DC to AC inverter.

Figure 11 is an exemplary circuit schematic block diagram showing that the present invention is connected in series with an impedance component. Figure 12 is an exemplary circuit schematic block diagram showing that the impedance components connected in series to the present invention perform connection. series, parallel connection, or serial and parallel connection via the switching device.

DESCRIPTION OF MAIN COMPONENT SYMBOLS

C201, C202: Bipolar CR101 Capacitor, CR102, CR201, CR202: Diode Diode, ESD102: Charge / Discharge Device1010, 1104: Inductive Impedance Component

LED101, LED102: Light Emitting DiodeR101, R102: Discharge ResistorR103, R104: Current Limiting ResistorU100: LED Drive Circuit Capable of Discharge and Discharge

UlOl: The first componentUl02: The second componentZD101, ZD102: Zener diode

300: Emserie Connection Type AC Source Modulator.

310: Parallel Connection Type AC Source Modulator

400: Alternating power modulator from periodically modulated series connection type

410: AC Modulator and Periodically Modulated Pairing Connection Type

500: Impedance Component

600: Switching Device

4000: DC to AC inverter

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

A method of driving a bipolar LED and circuit thereof described in the present invention comprises a first component and a second component in inverted polarity series connection. The first component comprises a direct polarity serially connected diode with a light-conducting polarity of a light emitting diode before being connected in parallel at the same common polarity bipolar capacitor; and the second component consists of a diode and a bipolar capacitor in series connection, or the diode may be selected as required to be connected in series with an optional light emitting diode. The second component constitution methods include: (1) When the optional LED is selected to be installed, the diode can be connected in series with the LED in direct polarity with the LED's driving conduction polarity before be connected in parallel at the same polarity with a bipolar capacitor to form a first type of the second component; and (2) if the optional LED is selected to not be installed on the second component, the diode is connected in parallel at the same polarity with the bipolar capacitor to constitute a second type of the second component.

The first component is connected in series of inverted polarity with any type of the second component to constitute an LED drive circuit (UlOO) capable of charging and discharging. The two terminals of the LED drive circuit (UlOO) capable of charging and discharging are for input:

(1) AC source with constant or variable voltage and constant or variable frequency; or

(2) The electrical source with constant listenable voltage and alternating periods of constant listenable polarities converted from DC source; or

(3) The electrical source with constant constant voltage and alternating periods of constant constant polarity converted from DC source is rectified additionally from AC source.

Referring to Figure 1, this is a schematic view of a basic circuit configuration of the present invention.

As illustrated in Figure 1, the bipolar discharge LED circuit and same circuit operation method essentially comprises: A bipolar capacitor: comprises bipolar capacitors (C201) and (C202) which are capable of charge and discharge, where bipolar capacitors may have the same. or different electrical capacity;

The first component (UlOl): comprises a diode (CRlOl) capable of performing unidirectional conduction in direct polarity series connection to at least one light emitting diode (LEDlOl) before being connected in parallel at the same polarity with a bipolar capacitor, so to constitute the first component (UlOl);

The second component (U102): comprises a diode (CR102) capable of performing unidirectional conduction in direct polarity series connection to at least one light emitting diode (LED102) before being connected in parallel at the same polarity with a bipolar capacitor, such as to constitute the second component (U102);

In addition, if the light emitting diode (LED102) is selected not to be installed as needed, the diode (CRI 02) can be directly connected in parallel with the bipolar capacitor (C202) to form the second component (U102). );

The first component (U101) and the second component (U102) are connected in series of inverted polarity to constitute the discharge and discharge capable LED drive circuit (U100), wherein the two terminals of the load-capable LED drive circuit (U100) and discharge are available for entry:

(1) AC source with constant or variable voltage and constant or variable frequency; or

(2) The electrical source with constant listenable voltage and alternating periods of constant listenable polarities converted from DC source; or

(3) The electrical source with constant constant voltage and alternating periods of constant constant polarity converted from DC source is rectified additionally from AC source. In the LED (UlOO) circuit capable of discharge and discharge, multiple combination modes are available for choice. between the LED (LED101) constituting the first component (UlOl), and the LED (LED102) constituting the second component (U102) as follows:

1. The LED (LED10) comprises one or a plurality of LEDs;

2. If the second component (U102) is selected to include LED (LED102), LED (LED102) comprises one or a plurality of LEDs;

3. The LED (LED10) or LED (LED102) constitution modes include either an individually illuminated direct current current LED, or two or more than two LEDs. polarity arising from direct illumination in series or parallel connection, or consisting of three or more than three light-emitting diode light polarity diodes in series connection, parallel connection or series-parallel connection;

4. The number of LEDs constituting the LED (LED101) and the number of LEDs constituting the LED (LED102) may be the same or different;

5. Whereas the electrical power source is related to an AC source, or a bi-directional power source with alternating periods of polarity that is converted from a DC source, the LED (LED10) or the LED (LED102) ) is not continuously driven by the DC source, so as to allow selection of a peak operating voltage value for each light emitting diode that refers to the input voltage waveform and the complete current conduction and disconnection cycle, as well as the voltage value. operating current setting. Selections include (1) having a voltage lower than a voltage rated as normal as the peak voltage; (2) have the rated voltage as normal as the peak voltage; and (3) have a higher voltage than normal rated voltage as the peak voltage.

The present invention operates from the presence of a power supply having a polarity to charge the bipolar capacitor (C202) from the second component (U102) by the diode (CR101) and the LED (LED1010) from the first component. (UlOl), and the charged electrical source keeps the illuminated LED (LEDlOl); and having the power supply with the other polarity to charge the bipolar capacitor (C201) from the first component (UlOl) by the diode (CR102) and the light emitting diode (LED102) from the second component (U102), and The charged electrical source keeps the LED (LED102) illuminated. If the second component (U102) is not arranged with the light emitting diode (LED102), the electrical source directly charges the bipolar capacitor (C201) from the first component (UlOl) by the diode (CR102) of the second component (U102).

When applied in practical applications, the charging and discharging LED drive circuit (U100) as illustrated in Figure 1 may optionally be provided with multiple auxiliary circuit components as applicable, including the option to be installed or not as required and the installed quantity option to be one or more than one. If more than one component is selected, they may be in series connection, parallel connection or series-parallel connection of selected polarity ratio according to the requirements of the circuit function; constituent components and optional auxiliary circuit devices include:

Discharge Resistance (R101): is an optional device connected in parallel with both terminals of the bipolar capacitor (C201) from the first component (U101) to discharge electrical residual charge from the bipolar capacitor (C201);

Discharge Resistance (R102): is an optional device connected in parallel with both terminals of the bipolar capacitor (C202) from the second component (U102) to discharge residual electrical charge from the bipolar capacitor (C202);

Current Limiting Resistance (R103): is an optional device that is arranged to be serially connected to diode (CR101) and light-emitting diode (LED10) from the first component (Ul10) to limit currents passing through the LED (LED10); The current limiting resistance (R103) may be replaced by an inductive resistor (1103);

Current Limiting Resistance (R104): is an optional device that is arranged to be serially connected to diode (CR102) and light-emitting diode (LED102) from the second component (U102) to limit currents passing through the LED (LED102); The current limiting resistance (R104) can be replaced by an inductive resistor (1104).

In addition, to prevent the LED from being damaged or having a reduced life due to abnormal voltage, in the charging and discharging LED drive circuit (U100) of the present invention, a zener diode can be additionally connected in parallel with both diode terminals. light emitting diode, as illustrated in Figure 2, showing an exemplary circuit diagram that has added the zener diode to the light emitting diode in the circuit shown in Figure 1; or at least one zener diode may be serially connected at least one diode to generate zener voltage function together when connecting in parallel to both terminals of the light emitting diode. Whose detailed description is given as follows:

In circuit examples, as illustrated in Figure 2, a zener diode (ZD101) is connected in parallel to both of the first component (Ul101) LED terminals (LED101) to protect the LED, where its polarity comparison is that in which the diode zener voltage (ZD101) is used to limit the operating voltage across the two LED terminals (LED101); As applicable, the diode (CR201) can be selected to be connected in series as a zener diode (ZD101), which provides the advantages of (1) protecting the zener diode (ZD101) against reverse current; and (2) achieve temperature compensation between zener diode (ZD101) and diode (CR201).

When the LED (LED102) is selected to be included in the second component (U102), a zener diode (ZD102) is connected in parallel with both LED terminals (LED102), where its polarity ratio is that voltage. Diode Zener (ZD102) is used to limit the working voltage across the two LED "terminals (LED102); as applicable, diode (CR202) can be selected to be connected in series with zener diode (ZD102), wherein it provides advantages of (1) protecting the zener diode (ZD102) against inverted current, and (2) achieving temperature compensation between the zener diode (ZD102) and diode (CR202).

To achieve the lighting stability of the light source produced by the light emitting diode and to reduce illumination pulsation, on the LED drive circuit (U100) capable of charging and discharging, both or at least one of the first component (UlOl) and the second component (U102) may additionally be installed with a discharge / discharge device. Figure 3 shows an exemplary circuit diagram where a discharge / discharge device is connected in parallel by the two light-emitting diode terminals and connected in series to the current limiting resistor in the circuit of Figure. 2.

In the circuit examples as illustrated in Figure 3, to promote the lighting stability of the light source produced by the light emitting diode, the two light emitting diode (LED101) terminals and the resulting limiting resistor (R103) in series connection from first component (UlOl) or directly to the two terminals of the light emitting diode (LEDlOl) can be connected in parallel with a charge / discharge device (ESD10l) according to the polarity to randomly charge or discharge the power source LED light emission (LED10) operation. If the light emitting diode (LED102) is selected for the second component (U102), a charge / discharge device (ESD102) may be selected as required to be connected in parallel with the two terminals of the LED (LED102) and Current limiting resistance (R104) in series connection, or directly connected in parallel to the two terminals of the LED (LED102) according to the polarity to randomly discharged the electrical source, so as to stabilize the operation of light emitting diode light emitting diode (LEDl02).

Charging / discharging devices (ESD101) and (ESDI02) may comprise conventional charge and discharge batteries, or super capacitors or capacitors, etc.

In addition, the bipolar discharge and circuit LED actuation method of the present invention in either or at least one of the first component (UlO1) and the second component (U102) may be arranged additionally with the charge / discharge devices (ESD101). and (ESD102) to charge or randomly discharge the electrical source, so as to stabilize the light emitting operation of LEDs (LED10) and (LED102); and in the event of a power failure, either or both of the reserved electrical sources in the discharge / discharge devices (ESD101) and (ESD 102) discharge the stored electrical source so as to continue to provide power to maintain at least one of the light emitting diodes (LED101). ) or (LED102) illuminated.

The first component (UlO1), the second component (U102), the light emitting diodes (LED101), (LED102) as well as various optional auxiliary circuit components as shown in Figures 1 to 3 are based on application requirements to be optionally installed. not installed as needed, and the amount of installation includes one or more than one, where more than one component is selected in the application, they may be in serial connection, parallel connection, or serial-to-serial connection. selected polarity according to the circuit function requirements; wherein the constituent components and circuit components including auxiliary include:

1. The first component (UlOl) may consist of one or more than one in serial connection, parallel connection, or serial-parallel connection;

2. The second component (U102) may consist of one or more than one in serial connection, parallel connection, or serial-parallel connection;

3. The light-emitting diode (LED10) may consist of a direct-illumination current-polarity LED, or two or more than two LEDs in series or parallel polarity arising from direct illumination, or by three or more than three LEDs in series connection, parallel connection, or direct illumination polarity series-parallel connection;

4. The LED (LED102) may consist of one direct illumination current polarity LED, or two or more than two LEDs in series or parallel direct current polarity, or by three or more than three LEDs in series, parallel connection, or series directional connection of direct illumination polarity;

5. The discharge resistance (R101) may consist of one or more than one in series connection, parallel connection, or series-parallel connection;

6. The discharge resistance (R102) may consist of one or more than one in series connection, parallel connection, or series-parallel connection;

7. The current limiting resistor (R103) may consist of one or more than one series connection, parallel connection, or series-parallel connection;

8. The current limiting resistor (R104) may consist of one or more than one in series connection, parallel connection, or series-parallel connection; The current limiting inductive resistor 1103 may be one or more than one in series, parallel connection, or series-parallel connection;

10. The current limiting inductive resistor 1104 may be one or more than one in series connection, parallel connection, or series-parallel connection;

11. The diode (CR101) may consist of one diode, or more than one diode in direct polarity series connection, or in parallel connection at the same polarity, or series-parallel connection;

12. The diode (CR102) may consist of one diode, or more than one diode in direct polarity series connection, or in parallel connection at the same polarity, or series-parallel connection;

13. The zener diode (ZD101) may consist of one zener diode, or more than one zener diode in direct polarity series connection, or in parallel connection at the same polarity, or in series-parallel connection;

14. The zener diode (ZD102) may consist of a zener diode, or more than one zener diode in direct polarity series connection, or in parallel connection at the same polarity, or in serial-parallel connection;

15. The diode (CR201) may consist of one diode, or more than one diode in direct polarity series connection, or in parallel connection at the same polarity, or series-parallel connection;

16. The diode (CR202) may consist of one diode, or more than one diode in direct polarity series connection, or in parallel connection at the same polarity, or series-parallel connection;

17. The loading / unloading device (ESD101) may consist of a loading / unloading device or more than one loading / unloading device in direct polarity serial connection, or in parallel connection at the same polarity, or in serial polarity connection. parallel;

18. The loading / unloading device (ESD102) may consist of a loading / unloading device or more than one loading / unloading device in direct polarity serial connection, or in parallel connection at the same polarity, or in serial connection. parallel;

When applied, the bipolar discharge and circuit LED actuation method of the present invention may provide for input:

(1) AC source with constant or variable voltage and constant or variable frequency; or

(2) The electrical source with constant listenable voltage and alternating periods of constant listenable polarities converted from DC source; or

(3) The electrical source with constant constant voltage and alternating periods of constant constant polarity converted from DC source is rectified additionally from AC source.

Further, the present invention may further be incorporated with the following active demodulation circuit devices, wherein the modulating circuit devices include:

- Serial Connection Type AC Source Modulator (300): Consists of conventional electromechanical components or solid state power components and related electronic circuit components to be connected in series to the charging and discharging LED (UlOO) drive circuit To receive the electrical source from the AC source to perform power modulations including pulse width modulation (PWM), conduction phase angle control, and impedance modulation for the AC source with constant or variable voltage and constant or variable frequency. from the power source;

- The Parallel Connection Type AC Source Modulator (310): Consists of conventional electromechanical components or solid state power components and related electronic circuit components, wherein their output terminals are arranged to be connected in parallel to the power drive circuit. LED (UlOO) capable of charging and discharging, while its input terminals are arranged to receive the AC source to perform power modulations including pulse width modulation (PWM), conduction phase angle control, and impedance modulation. for AC source with constant or variable voltage and constant or variable frequency from the power source;

The alternating power modulator of series connection type periodically modulated polarities (400): It consists of the conventional electromechanical components or solid state power components and related electronic circuit components for serial connection to the load-capable LED (UlOO) circuit. and the discharge to receive an electrical source from the power source to perform power modulations including pulse width modulation (PWM), conduction phase angle control, and impedance modulation for the electrical source with constant or variable voltage and alternating periods of time. constant or variable polarities converted from DC source, or the constant or variable voltage electrical source and alternating periods of constant or variable polarities converted from the DC source which is further rectified from the AC source;

The alternating power modulator with periodically modulated parallel connection type polarities (410): Consists of conventional electromechanical components or solid state power components and related electronic circuit components, wherein their output terminals are arranged to be connected in parallel to the drive circuit. LED (U100) capable of charging and discharging, while its input terminals are arranged to receive the electrical source from the power source, so as to perform power modulations including pulse width modulation (PWM), conduction phase angle control , and impedance modulation for the electrical source with constant constant voltage and alternating periods of constant constant polarity converted from DC source, or the electrical source with constant or variable voltage and alternating periods of constant or variable polarity converted from the DC source that is rectified additionally from AC source - DC to AC inverter (4000): Consists of conventional electromechanical components or solid state power components and related electronic circuit components, where their input terminals are arranged to receive constant voltage DC source or variable, as selected, while their output terminals are arranged to produce a bidirectional sinewave, square-wave, or bidirectional pulsed wave with constant or variable voltage and alternating periods of audible constant polarity;

- Impedance (500): comprises at least one resistive impedance component, inductive impedance component and / or a capacitive impedance component, or comprises at least two types of mixed impedance components to perform serial connection, parallel connection, or serial-parallel connection. to provide DC impedance or AC impedance; or the capacitive impedance component and the inductive impedance component are mutually connected in series to have the same frequency as the bidirectional electrical source such as AC source from the power supply or the same alternating periods of constant or variable voltage electrical supply and alternating polarity periods. constants or variablesconverted from the DC source so that a series resonant state and a corresponding series resonant final voltage state appear at the two terminals of the corresponding capacitive impedance component or corresponding inductive impedance component; or the capacitive impedance component and inductive impedance component are mutually connected in parallel to have the same frequency as the directional electrical source such as AC source from the power source or the same alternating periods of polarity of the electrical source with constant or variable voltage and alternating periods of time. constant or variable polarities so that a parallel resonance state and corresponding final voltage appear;

- Switching device (600): comprising dynamo-mechanical switching devices or solid-state switching devices to be arranged to modulate at least two impedance components (500) to perform commutations between series, parallel and series-parallel connections;

The lightning strike and circuit LED actuation method of the present invention may constitute various application circuits as follows by incorporating a type of active power modulator mentioned above:

1. The present invention is connected in series to AC source modulator; wherein the charge and discharge capable LED drive circuit (U100) is serially connected to the conventional serially connected type AC source modulator (300) before being powered by the audible constant voltage and constant or variable frequency AC supply. , so as to modulate the input power of the charge and discharge capable LED drive circuit (U100), wherein the connection method is to connect the two devices in series, as illustrated in Figure 4, is an exemplary schematic block diagram of circuitry showing that the present invention is serially connected to a serially connected type AC source modulator;

2. The present invention is connected in parallel with an AC source modulator; wherein the charging and discharging LED (U100) drive circuit is connected in parallel with the output terminals of the conventional AC power modulator in parallel connection type (310), whereas the AC source with constant or variable voltage and frequency constant or variable is arranged to be fed to the input terminals of the modulator. parallel connection type AC power supply (310), then delivered by the output terminals of the parallel connection type AC power modulator (310) to the charging and discharging LED drive circuit (U100) to modulate the power supply of the LED drive circuit (U100) capable of charging and discharging as illustrated in Figure 5 for an exemplary circuit schematic block diagram of the present invention to be connected in parallel with a parallel-type AC source modulator;

3. The charge and discharge capable LED drive circuit (U100) is serially connected to the conventional periodically modulated polarity alternating power modulator of the serial connection type (400) before receiving the power supply with constant or variable voltage and alternating periods of polarity. variables converted from the dc source, or the electric source with constant or variable voltage and alternating periods of constant or variable polarities converted from dc source that is further rectified from the ac source so as to modulate the power supply of the LED drive circuit (U100) capable loading and unloading as illustrated in Figure 6 for an exemplary circuit schematic block diagram showing that the present invention is connected in series to a periodically modulated polarity alternating power modulator of the serial connection type;

4. The charge and discharge capable LED drive circuit (U100) is connected in parallel with a conventional parallel-type modulated polarity alternating power output of the parallel connection type (410); constant or variable voltage electrical source and alternating periods of constant or variable polarity converted from a DC source, or the constant-voltage electrical source and alternating constant-frequency polarities converted from the DC source which is further rectified from the AC source is arranged to be fed to an input terminal of the parallel connection type periodically modulated polarity alternating power modulator (410) and thereafter produced from a periodically modulated alternating power output terminal of the parallel connection type (410) to LED charging circuit (U100) capable of charging and discharging to modulate the input power of LED charging circuit (U100) capable of charging and discharging, as illustrated in Figure 7 for an exemplary circuit schematic block diagram of the present invention for be connected in parallel with an alternating power modulator of periodically modulated polarities of parallel connection type;

5. The charge and discharge capable LED drive circuit (U100) is connected in series to the conventional periodically modulated polarity alternating power modulator of the series connection (400) before being connected in parallel with a DC inverter output terminal. for CA (4000); A DC source with constant or variable voltage selected as applicable is introduced into a DC-to-AC drive input terminal (4000), while the DC-to-AC drive output terminal (4000) produces the electrical source of sine wave, or wave. bidirectional square or constant or variable voltage two-way pulsed wave and alternating periods of variable polarity selected as applicable for the charge-and-discharge LED (U100) drive circuit to modulate the power of the charge-and-discharge-capable LED (U100) circuit, as illustrated in Figure 8 for an exemplary circuit schematic block diagram showing that the present invention is connected in series to an alternating power modulator with periodically modulated connection type polarities in series being driven by the electrical source produced from a DC to AC inverter. ;

6. The LED drive circuit (U100) capable of charging and discharging is connected in parallel with an output terminal of the conventional alternating power modulator with periodically modulated parallel-type connection polarities (410); A constant or variable voltage dc source selected as applicable is fed into a DC to AC inverter input terminal (4000), while the output terminal. DC-to-AC inverter (4000) produces bidirectional two-wave sinusoidal, or two-way square wave, constant or variable voltage electrical wave source, and constant or variable polarity alternating periods selected as applicable to a periodically modulated polarity alternating power modulator input terminal. parallel disconnect type (410) before being output to the LED drive circuit (U100) capable of charging and discharging by an alternating power modulator output terminal periodically modulated paired connection type (410) polarities to modulate power Powered from the charge-and-discharge LED operating circuit (U100) as illustrated in Figure 9 for an exemplary circuit schematic block diagram showing that the present invention is connected in parallel with a parallel connection type periodically modulated polarity alternating power modulator. link before it is driven by the electrical source produced from a DC to AC inverter;

7. The charge and discharge capable LED drive circuit (U100) is connected in parallel to a conventional DC to AC inverter output terminal (4000); a selected constant or variable voltage dc source as applicable is fed to a dc to ac inverter input terminal (4000), while the dc to ac inverter output terminal (4000) produces bidirectional sine wave electrical source , bidirectional square wave, or bidirectional pulsed wave with constant or variable voltage and alternating periods of constant or variable polarity selected as applicable for the LED charging circuit (U100) capable of charging and discharging to modulate the power supply of the LED driving circuit (U100) capable charge and discharge as illustrated in Figure 10 for an exemplary circuit diagrammatic block diagram showing that the present invention is driven by the electrical source produced from a DC to AC inverter;

8. The charge and discharge capable LED drive circuit (U100) is serially connected to at least one conventional impedance component (500) before being connected in parallel with a power source; wherein the impedance component (500) comprises:

(1) An impedance component (500): comprises a component with capacitive impedance characteristics; or

(2) An impedance component (500): comprises a component with inductive impedance characteristics; or

(3) An impedance component (500): comprises a component with resistive impedance characteristics; or

(4) An impedance component (500): comprises a single impedance component with the combined impedance characteristics of at least two resistive impedance characteristics, or inductive impedance, or capacitive impedance simultaneously, to provide DC or AC impedances;

(5) An impedance component (500): comprises a single impedance component with the combined impedance and inductive impedance characteristics, where its inherent resonant frequency is equal to the frequency of the bidirectional electrical source such as the AC source of the power supply or alternating periods of constant or variable voltage electrical source polarities and alternating periods of constant or variable polarities converted from a DC source to produce a parallel resonance state; or

(6) An impedance component (500): consists of capacitive impedance components, or inductive impedance components, or resistive impedance components, including one or more of a type and one and more than one impedance component, or two or more than two. one or more types of an impedance component in series connection, or parallel connection, or series-parallel connections, to provide a DC or AC impedance; or

The capacitive impedance component and the inductive impedance component are in mutual series connection, whereby their inherent series resonance frequency is equal to the two-way electrical source frequency such as the power source AC source, or the periodically alternate polarity periods. which DC source converted from DC source so as to produce a series resonance state impedance state and the corresponding series resonance final voltage to appear at the two corresponding capacitive impedance component or inductive impedance terminals; or

The capacitive impedance component and the inductive impedance component are in parallel-parallel connection, whereby their parallel-resonant resonant frequency is equal to the bidirectional electrical source frequency such as the AC power source, or the periodically alternating periods of power. DC source converted from DC source to produce a parallel resonance state impedance state and the corresponding final voltage appears;

Figure 11 is a schematic circuit block diagram showing that the present invention is connected in series to an impedance component.

9. At least two impedance components (500), as mentioned in item 8, perform switching between serial connection, parallel connection and serial-parallel connection by means of a switching device (600) comprising electromechanical components or solid state components. modulating power transmitted to the charge and discharge capable LED drive circuit (U100), wherein Figure 12 is an exemplary circuit schematic block diagram showing those impedance components connected in series to the present invention performing serial connection, connection in parallel or serial-parallel connections by means of a switching device.

The colors of the individual light-emitting diodes (LED101) and (LED102) of the first component (U101) and the second component (U102) in the lightning strike and circuit LED activation method can be optionally selected to be one or more than one. a Collor.

The site arrangement ratios between the individual (LED101) and (LED102) individual light-emitting diodes of the first component (U101) and the second component (U102) in the bipolar discharge LED operation method and circuit thereof include: 1) linear arrangement sequential; 2) distributed sequentially in a plan; 3) cross-linear arrangement; 4) cross distribution in a plane; 5) disposition based on specific geometric layouts in a plane; 6) Arrangement based on 3D geometric position.

The bipolar light-emitting LED drive method and circuit thereof, wherein it comprises circuit components that include: 1) Comprises individual circuit components that are interconnected; 2) At least two circuit components are combined with at least two partial operating units which are additionally interconnected; 3) All components are integrated together in a structure.

Accordingly, a bipolar and circuit discharge LED actuation method of the present invention provides advanced energy-saving, low heat loss and low cost features in driving an LED by charge operation and capacitive discharge.

Claims (15)

1. Bipolar discharge / discharge LED drive circuit, characterized in that it comprises a first component and a second component in inverted polarity series connection, wherein the first component comprises a direct polarity series diode connected with a backlighting polarity of an LED before being connected in parallel at the same polarity with a bipolar capacitor; and the second component is comprised of a diode and a bipolar capacitor in series connection, or the diode may be selected as required to be serially connected with an optional light emitting diode, the constitution of the second component includes: (i) when the emitting diode Optional light is selected to be installed, the diode can be connected in series with the LED in direct polarity with LED's driving conduction light before being connected in parallel in the same polarity with a bipolar capacitor so as to constitute a first type of the second component; and (ii) if the optional LED is selected not to be installed on the second component, the diode is connected in parallel at the same polarity with the bipolar capacitor to constitute a second type of the second component, where the first component is connected in inverse polarity series with any Second component type to constitute an LED drive circuit (UlOO) capable of charging and discharging for input: (i) AC source with constant or variable voltage and constant or variable frequency; or (ii) the electrical source with constant listenable voltage and alternating periods of constant listenable polarities converted from DC source; or (iii) the electrical source with constant constant voltage and alternating periods of constant constant polarity converted from a DC source is further rectified from an AC source, comprising essentially: a bipolar capacitor: comprises bipolar capacitors (C201) and (C202) which are capable of bipolar capacitors and bipolar capacitors may have the same or different electrical capacities, the first component (UlOl) comprises a diode (CR101) capable of performing unidirectional conduction in direct polarity series connection to at least one light (LED101) before being connected in parallel at the same polarity with a bipolar capacitor to form the first component (UlOl), the second component (U102) comprises a diode (CR102) capable of performing unidirectional conduction in series polarity connection at least one LED (LED102) before being connected in parallel at the same polarity bipolar element to form the second component (U102), the first component (U101) may comprise one or more than one in series connection, parallel connection or serial-parallel connections, the second component (U102) may comprise one or more than one component. Serial, Parallel, or Serial-Parallel connections, in addition, if the LED (LED102) is selected not to be installed as required, the diode (CR102) can be directly connected in parallel with the bipolar capacitor ( C202), as the second component (U102), the first component (U101) and the second component (U102) are connected in inverted polarity series to constitute the LED drive circuit (U100) capable of discharging and discharging, wherein the Two terminals of the charge-and-discharge-capable LED operating circuit (U100) are arranged to input to: (i) the AC source with constant or variable voltage and constant or variable frequency ; or (ii) the electrical source with constant listenable voltage and alternating periods of constant listenable polarities converted from DC source; or (iii) the electrical source with constant constant voltage and alternating periods of constant constant polarity converted from a DC source is rectified additionally from an AC source, where in the charging and discharging LED (UlOO) circuit, multiple modes of combination are available for choosing between the light emitting diode (LED101) constituting the first component (UlOl), and the light emitting diode (LED102) constituting the second component (U102); including: (i) the light emitting diode (LED101) comprises one or a plurality of light emitting diodes (ii) if the second component (U102) is selected to include the light emitting diode (LED102), the light emitting diode ( LED102) comprises one or a plurality of light-emitting diodes; (iii) the light-emitting diode (LED101) or light-emitting diode (LED102) modes include being individually constituted by a direct illumination current-polarity LED, or consisting of two or more than two light-emitting diodes of direct illumination in series or parallel connection, or consisting of three or more than three light-emitting diode-polarity light-emitting diodes, (iv) the number of LEDs constituting the LED (LED10) and the number of LEDs constituting the diode The light emitting diode (LED102) may be the same or different, wherein, considering that the electrical power source is related to an AC source, or a bi-directional power source with alternating periods of polarity that is converted from a DC source, the LED (LED10) or LED (LED102) is not continuously driven by the DC source so as to allow selection of a peak operating voltage value for each LED that refers to the voltage waveform introduced and complete cycle of current conduction and disconnection, as well as a selected operating current value. Selections include (i) having a voltage lower than a voltage rated as normal as the peak voltage; (ii) have the voltage rated as normal as the peak voltage; and (iii) have a higher voltage than the rated normal voltage as the peak voltage, wherein by providing a power source with a polarity to charge the bipolar capacitor (C202) from the second component (U102) by the diode (CR101) ) and by the light emitting diode (LED101) from the first component (UlO1), and the charged electrical source keeps the light emitting diode (LED101) illuminated; and having the power supply with the other polarity to charge the bipolar capacitor (C201) from the first component (U101) by the diode (CR102) and the light emitting diode (LED102) from the second component (U102), and charged electrical source keeps the LED (LED102) illuminated; If the second component (U102) is not arranged as a light emitting diode (LED102), the electrical source directly charges the bipolar capacitor (C201) from the first component (U101) by the diode (CR102) of the second component (U102). Bipolar discharge / discharge LED drive circuit according to Claim 1, characterized in that, in practical applications, the charging and discharging LED drive circuit (U100) can be optionally arranged with multiple auxiliary circuit components. as applicable including the option of not being installed as needed and the quantity installed option to be one or more than one; if more than one component is selected, they may be in series, parallel connection or series-parallel connection of selected polarity ratio according to the requirements of the circuit function; constituent components and optional auxiliary devices include: discharge resistance (R101): is an optional device connected in parallel to both bipolar capacitor terminals (C201) from the first component (UlOl) to discharge electrical residual charge from the bipolar capacitor (C201); discharge resistance (R102): is an optional device connected in parallel with both terminals of bipolar capacitor (C202) from the second component (U102) to discharge residual electrical charge from bipolar capacitor (C202); Current Limiting Resistance (R103): is an optional device that is arranged to be prospectively serially connected to diode (CRlOl) and light-emitting diode (LEDlOl) from the first component (UlOl) to limit currents passing through the LED ( LED101); The current limiting resistor (R103) can be replaced by an inductive resistor (1103), the current limiting resistor (R104) is an optional device which is arranged to be connected in series to diode (CR102) and light-emitting diode (LED102). from the second component (U102) to limit currents passing through the LED (LED102); The current limiting resistance (R104) can be replaced by an inductive resistor (1104). Bipolar discharge / discharge LED drive circuit according to claim 1, characterized in that, to prevent the LED from being dimmed or having an abnormal voltage shortened life in the LED drive circuit (U100 ) Capable of charging and discharging, a zener diode can be additionally connected in parallel with both LED terminals; or at least one zener diode can be serially connected to at least one diode to generate zener voltage function together when connecting parallel to both LED terminals, including: a zener diode (ZD101) is connected parallel to both terminals. first component LED (LED101) (U101), wherein its polarity ratio is that where the zener diode zener voltage (ZD101) is used to limit the operating voltage across the two terminals of the light-emitting diode (LED101) - as applicable, the diode (CR201) can be selected to be connected in series with the zener diode (ZD101), which provides the advantages of (i) protecting the reverse counter current zener diode (ZD101); and (ii) achieve temperature compensation between the zener diode (ZD101) and diode (CR201), wherein when the LED (LED102) is selected to be included in the second component (U102), a zener diode (ZD102) is connected. in parallel with both LED (LED102) terminals, where their polarity relationship is that the zener diode zener voltage (ZD102) is used to limit the operating voltage across the two LEDs (LED102) terminals; as applicable, diode (CR202) may be selected to be connected in series with zener diode (ZD102), which provides advantages of (i) protecting the zener diode (ZD102) against reverse current; and (ii) achieve temperature compensation between the zener diode (ZD102) and diode (CR202). Bipolar discharge / discharge LED drive circuit according to claim 1, characterized in that, to achieve the lighting stability of the light source produced by the LED. Reducing the illumination pulse, both or at least one of the first component (UlOl) and the second component (U102) can be additionally installed with a discharge / discharge device, including: the two LED terminals (LED10) and the current limiting resistor (R103) in series connection from the first component (UlOl), or directly to the two LED terminals (LEDlOl) can be connected in parallel with an additional discharge / discharge device (ESD101) according to polarity for charged or randomly discharging the electric source, so as to stabilize the operation of LED light emission (LED10); If the LED (LED102) is selected for the second component (U102), a charge / discharge device (ESD102) may be selected as needed to be connected in parallel with the two LED's terminals (LED10) and the resistor. current limiting device (R104) in series connection, or directly connected in parallel to the two LED terminals (LED102) according to the polarity for randomly charging or discharging the electrical source, in order to stabilize the light emitting diode operation. light (LED102), wherein the charge / discharge devices (ESD101) and (ESD102) may comprise conventional charge and discharge batteries, or super capacitors or capacitors. Bipolar discharge / discharge LED drive circuit according to claim 1, characterized in that both or at least one of the first component (UlOl) and the second component (U102) can be arranged additionally with the devices. charge / discharge (ESD101) and (ESD102) for randomly charging or discharging the electrical source in order to stabilize the light emitting diode (LED10) and (LED102) operation; and in the event of power failure, either or both of the electrical sources reserved in the charge / discharge devices (ESD101) and (ESD 102) discharge the reserved electrical source so as to continue providing power to maintain at least one of the LEDs (LED10). ) or (LED102) -lighted. Bipolar discharge / discharge LED drive circuit according to Claim 1, characterized in that it is additionally incorporated with the following active modulation circuit devices, wherein the active modulation circuit devices comprise one or more of the following devices. : series connection type AC source modulator (300) consisting of conventional electromechanical components or solid state power components and related electronic circuit components to be connected in series to the charging and discharging LED (U100) drive circuit To receive the electrical source from the AC source to perform power modulations including pulse width modulation (PWM), conduction phase angle control, and impedance modulation for the AC source with constant or variable voltage and constant or variable frequency. from power source; font modulator and the parallel connection type AC (310) is comprised of conventional electromechanical components or solid state power components and related electronic circuit components, wherein their output terminals are arranged to be connected in parallel to the LED (UlOO) capable circuit while its input terminals are arranged to receive the AC source to perform power modulations including pulse width modulation (PWM), conduction phase angle control, and impedance modulation for the AC voltage source. constant or variable frequency and constant or variable frequency from the power supply; series connection type periodically modulated polarity alternating power modulator (400) consists of conventional electromechanical components or solid state power components and related electronic circuit components for s The LED operating circuit (U100) capable of charging and discharging to receive electrical source from the power source to perform power modulations including pulse width modulation (PWM), conduction phase angle control, and modulation impedance for the constant or variable voltage electrical source and alternating periods of constant or variable polaritiesconverted from DC source, or the constant voltage or variable electrical source and alternating periods of constant audible polarities from the DC source which is rectified additionally from the AC source; Parallel Connection Type (410) Alternating-Modular Polarity Alternating Power Substances are comprised of conventional electromechanical components or solid-state power components and related electronic circuit components, wherein their output terminals are arranged to be connected in parallel to the deaci circuit. LED (U100) capable of charging and discharging, whereas its input terminals are arranged to receive the power supply from the power source, so as to perform power modulations including pulse width modulation (PWM), phase angle control. conduction, and impedance modulation for constant or variable voltage electrical source and alternating periods of constant or variable polarity converted from a DC source, or the constant-voltage electrical source and alternating periods of a convertible constant polarity of the DC source which is further rectified AC-to-AC inverter (4000) consists of conventional electromechanical components or solid-state power components and related electronic circuit components, where their input terminals are arranged to receive a constant or variable voltage DC source as selected, while that your finished The output signals are arranged to produce a bidirectional sine wave electrical source, bidirectional square wave or constant or variable voltage pulsed wave and alternating periods of constant or variable polarity, impedance (500) comprising at least one resistive impedance component, inductive impedance component and / or a capacitive impedance component or comprising at least two types of mixed impedance components to perform serial connection, parallel connection, or serial-parallel connection to provide DC impedance or AC impedance; or the capacitive impedance component and the inductive impedance component are mutually connected in series to have the same frequency as the bidirectional electrical source such as AC source from the power supply or the same alternating periods of constant or variable voltage electrical supply and alternating polarity periods. constants or variablesconverted from the DC source so that a series resonant state and a corresponding series resonant end voltage state appear at the two terminals of the corresponding capacitive impedance component or corresponding inductive impedance component; or the capacitive impedance component and inductive impedance component are mutually connected in parallel to have the same frequency as the directional electrical source such as AC source from the power source or the same alternating periods of polarity of the electrical source with constant or variable voltage and alternating periods of time. constant or variable polarities such that a parallel resonance state and corresponding end voltage appear; switching device (600) comprising dynamo-mechanical switching devices or solid state switching devices to be arranged to modulate at least two impedance components (500) to perform switching between serial, parallel, and serial-parallel connections. Bipolar discharge / discharge LED drive circuit according to claim 1, characterized in that the charge and discharge capable LED drive circuit (U100) is connected in series to the conventional AC type power supply modulator. series connection (300) before it is powered by the audible constant voltage AC supply and constant or variable frequency, so as to modulate the input power of the charge and discharge capable LED drive circuit (U100), where both devices are connected in series. Bipolar discharge / discharge LED drive circuit according to Claim 1, characterized in that the charge and discharge LED drive circuit (U100) is connected in parallel with the terminals. conventional parallel-disconnect AC power modulator output (310), whereas the constant or variable voltage AC source with constant or variable frequency is arranged to be supplied to the parallel-type AC power modulator input terminals ( 310), then delivered through the output terminals of the AC power modulator of the parallel connection type (310) to the charging and discharging LED drive circuit (U100) to modulate the power supply of the capable LED drive circuit (U100) loading and unloading. Bipolar discharge / discharge LED drive circuit according to Claim 1, characterized in that the charging and discharging LED (UlOO) drive circuit is connected in series to the conventional alternating power modulator of periodically modulated polarities of serial connection type (400) before receiving constant or variable voltage electrical supply and constant or variable alternating polarity alternating periods from the DC source that is additionally rectified from the AC source, so as to modulate the power supply of the LED drive circuit ( U100) capable of loading and unloading. Bipolar discharge / discharge LED drive circuit according to claim 1, characterized in that the charge and discharge LED drive circuit (U100) is connected in parallel with a conventional terminal modulator output terminal. alternating power periodically modulated paired connection type polarities (410); the constant or variable voltage electrical source and alternating periods of constant or variable polarities converted from the dc source, or the constant or variable voltage electrical source and alternating constant or variable periods of polarity converted from the dc source that is rectified additionally from the ac source is arranged to be fed to an alternating power modulator input terminal of periodically modulated parallel connection type polarities (410) and then produced from an output terminal of the parallel connection type periodically modulated polarity alternating power modulator (410) for the charging and discharging LED drive circuit (U100) to modulate the input power of the charging capable LED drive circuit (U100). Bipolar discharge / discharge LED drive circuit according to Claim 1, characterized in that the charge and discharge LED drive circuit (U100) is connected in series to the conventional alternating power modulator of periodically modulated polarities. Serial connection type (400) before being connected in parallel with a DC to AC drive output terminal (4000); a DC constant or variable voltage source selected as applicable is input to a DC to AC inverter input terminal (4000), while the DC to AC inverter output terminal (4000) produces the sine-wave directional electrical source, or bidirectional square wave or constant or variable voltage two-way pulsed wave and alternating periods of varying polarity selected as applicable for the charge and discharge capable LED drive circuit (U100) to modulate the power supply of the charge and discharge capable LED drive circuit (U100) . Bipolar discharge / discharge LED drive circuit according to Claim 1, characterized in that the charge and discharge LED drive circuit (U100) is connected in parallel with a conventional terminal modulator output terminal. alternating power periodically modulated paired connection type polarities (410); a constant or variable voltage dc source selected as applicable is fed into a dc to ac inverter input terminal (4000), while the dc to ac inverter output terminal (4000) produces bidirectional sinusoidal, or wave, electrical source. bidirectional or waved bidirectional square with constant or variable voltage and alternating periods of constant or variable polarity selected as applicable to a periodically modulated parallel disconnect-type alternating power modulator input terminal (410) before being output to the circuitode. LED drive (U100) capable of charging and discharging by an alternating power modulator output terminal periodically modulated paired connection type polarities (410) to modulate the power supply of the LED charging circuit (U100) capable of charging and discharging. Bipolar discharge / discharge LED drive circuit according to Claim 1, characterized in that the charge and discharge LED drive circuit (U100) is connected in parallel to a conventional inverter output terminal. DC to AC (4000): A DC source with selected constant or variable voltage as applicable is fed to a DC to AC inverter input terminal (4000), while the DC to AC inverter output terminal (4000) produces 2-way directional sine wave, 2-way square wave or 2-way constant or variable voltage pulsed wave and alternating constant or variable polarity periods selected as applicable to the discharge and discharge capable LED (U100) drive circuit to modulate the power output of the LED (U100) capable of charging and discharging. Bipolar discharge / discharge LED drive circuit according to claim 1, characterized in that the charge and discharge LED drive circuit (U100) is connected in series to at least one conventional impedance component ( 500) before being connected in parallel with a power source; wherein the impedance component (500) comprises: (i) an impedance component (500) comprises a component with capacitive impedance characteristics; or (ii) an impedance component (500) comprises a component with inductive impedance characteristics; or (iii) an impedance component (500) comprises a component with resistive impedance characteristics; or (iv) an impedance component (500) comprises a single impedance component with the combined impedance characteristics of at least two resistive impedance characteristics, or inductive impedance, or capacitive impedance simultaneously, to provide DC or AC impedances, or (v) An impedance component (500) comprises a single impedance component with the combined capacitive impedance and inductive impedance characteristics, where its inherent resonant frequency is equal to the frequency of the two-way electrical source such as the AC source of the power supply or alternating periods of time. polarities of the constant or variable voltage source and alternating periods of constant or variable polarities converted from a DC source to produce a parallel resonance state; or (vi) an impedance component (500) is comprised of capacitive impedance components, or inductive impedance components, or resistive impedance components, including one or more of a type and one and more than one impedance component, or two or more than two. one or more types of an impedance component in series connection, or parallel connection, or series-parallel connections, to provide a DC or AC impedance; that the capacitive impedance component and the inductive impedance component are in mutual series connection, whereby its inherent series resonant frequency is equal to the bidirectional electrical source frequency such as the power source AC source, or the periods of the alternative periodic polarities which DC source converted from DC source to produce a series resonance state impedance state and the corresponding series resonance final voltage to appear at the two terminals of the corresponding capacitive impedance component or inductive impedance component; The capacitive impedance component and the inductive impedance component are in parallel-mutual connection, whereby their parallel-resonant frequency is equal to the frequency of the bidirectional electrical source such as the AC source of the power source, or the alternating polarity periods. periodically from a DC source converted from a DC source so as to produce a parallel resonant state impedance state and the corresponding final voltage appears. 15. Bipolar discharge / discharge LED drive circuit characterized by the fact that it uses at least two impedance components (500) to perform switching between serial connection, parallel connection and serial-parallel connection through the switching device (600) which comprising electromechanical components or solid state components, it modulates the power transmitted to the charging and discharging LED (UlOO) drive circuit.