KR101311775B1 - A control system for minimize brightness of deviation in case ac driving led - Google Patents

Abstract

The present invention relates to a control system for minimizing brightness deviation between AC driving LEDs. The present invention relates to a full-wave rectifying unit for rectifying a commercial power supply voltage, an LED unit in which a plurality of LEDs are arranged in series, a slave source controller for dual control, and a plurality of LEDs. Section instantaneous current controller to control the constant current group of the LED groups of the non-sequential, Overvoltage protection unit for protecting the LED and the active element in the case of transient voltage input, Active sub-group for compensation of input power against input voltage fluctuation 1 group) Input power compensator to control current height and current angle and main TR (FET) of subgroup LED (first group) by compensating similarly to subgroup LED (first group) current by increasing current magnitude. It consists of a higher group secondary instantaneous current compensation to minimize the loss of the circuit.
According to the present invention, by reducing the current deviation between the LED group and the terminal LED group, it is possible to implement a lamp with a uniform luminous flux (brightness) as much as possible throughout the entire section, to maximize the LED luminous efficiency through the optimal I _F setting, input power When compensating, switching off time is minimized to minimize luminous flux degradation, and cost reduction and control efficiency can be maximized through the dual control method of the upper group controller.

Description

A control system for minimizing brightness deviation between AC drive LEDs {A CONTROL SYSTEM FOR MINIMIZE BRIGHTNESS OF DEVIATION IN CASE AC DRIVING LED}

The present invention relates to a control system for minimizing the variation in the luminous flux (brightness) between the LED or LED group of the AC direct drive method, which is one of the LED lamp driving method used as a real and internal light source. After rectifying the circuit, the series LEDs are sequentially controlled in order to reduce the current deviation between the first LED group and the terminal LED group, which is the biggest problem of the driving method to increase the current, so that the luminous flux (brightness) as much as possible can be realized. In addition, the present invention relates to a control system for minimizing brightness deviation between AC drive LEDs, which is improved to maximize control efficiency and LED use efficiency through dual control.

In general, the LED is a light emitting diode that is injected by a small number of carriers (electrons or holes) by using the pn junction structure of the semiconductor and is re-combined, also known as a light emitting diode, and because of the high efficiency of converting electrical energy into light energy up to 90 Energy savings of up to% are gaining attention as next-generation light sources.

These LEDs are usually driven by SMPS, which converts AC 100V or AC 220V power sources to DC 12 to 48V.

Therefore, LEDs must be driven by using a DC voltage converter SMPS and a constant current driver, which leads to a high manufacturing cost. In particular, a lifetime of the electrolytic capacitor is limited as an essential component of the SMPS. come.

In order to improve this, in recent years, AC direct-driven LED control technology has been disclosed in a semi-permanent manner that does not use an electrolytic capacitor, thereby enabling the manufacture of high-quality LED lamps and lighting fixtures that can have a long life at the lowest cost.

1 is a driving circuit diagram of a conventional AC drive LED module according to the related art. As shown in FIG. 1, a conventional AC direct drive LED control technique includes LED taps for each group for high power factor, high efficiency, and active input power compensation. And a sequential switching circuit, wherein the voltage and current waveforms on the circuit are as shown in FIG. 2.

In addition, the characteristics that each group LED is sequentially turned ON / OFF according to the potential of the AC input voltage (AC voltage changes with time, phase) is the same as the example of FIG.

Referring to the operation sequence as shown in Figure 3, in the case of LED group 1 is all ON in the 1-9 section, LED group 2 → LED group 3 → LED group 4 is turned on as the interval becomes smaller, LED group 5 It can be seen that it is ON only in 5 sections, and according to the series LED sequential control method, the current deviation between the first LED group and the terminal LED group is about 50% or more, and it is not possible to realize uniform brightness across the bulbs. Have

In addition, it is difficult to expect the best luminous flux due to the luminous flux characteristics depending on the LED I _F current, which is inefficient.

In addition, there is an inefficient disadvantage because LEDs having the same specifications must be used regardless of the current deviation between LED groups.

The present invention was created in view of the above-described problems in the prior art, and an object of the present invention is to reduce the current deviation between the first LED group and the end LED group, which is a problem of the conventional AC drive LED control, for the entire section. By implementing the most uniform luminous flux (brightness) and reducing the current deviation between LED groups, it is possible to maximize the LED luminous flux efficiency through optimal I _F setting.It also reduces the current deviation between LED groups to maximize the LED usage efficiency. The purpose of the present invention is to provide a control system for minimizing brightness deviation between AC driving LEDs, which can realize low cost and high efficiency through the dual control method of the LED group controller.

The present invention is a means for achieving the above object, a full-wave rectifier is applied AC voltage via a bridge full-wave rectification circuit; A slab connected to an area between the plurality of LEDs or LED groups to non-sequentially dual control from the upper plurality of LEDs or LED groups to the lower plurality of LEDs or LED groups among the plurality of LEDs or LED groups connected in series with the full wave rectifier. An eve source controller; Section instantaneous current control unit connected to the region between the plurality of upper LEDs or LED groups, lower LEDs, or LED groups connected in series, respectively, to sequentially and constantly control the plurality of upper LEDs or LED groups, lower LEDs, or LED groups Wow; It is connected in parallel with the shunt register of the upper group section instantaneous current controller to increase the magnitude of current in the secondary current control to compensate similarly to the lower group LED current to minimize the loss of the main TR (FET) of the lower group section instantaneous current controller. Upper group secondary instantaneous current compensation unit; An input power compensator that is connected in parallel with the shunt-register of the instantaneous current controller in the lower group section and actively controls the lower group current height and current angle to compensate for the input power caused by the input voltage variation; It provides a control system for minimizing the brightness deviation between the AC driving LED, characterized in that it comprises a; overvoltage protection unit to protect the LED and the active element by blocking the current of the section instantaneous current control unit when the transient voltage input.

In this case, the slave source controller supplies a current to the upper group LED until the voltage through the full wave rectifier reaches the threshold voltage of the lower group LED through the slave source controller, and the voltage through the full wave rectifier further increases. As a result, when the threshold voltage of the lower group LEDs is reached, the current of the slave source control unit gradually decreases and then shuts off.

In addition, the upper group secondary instantaneous current compensation unit is composed of a MOS-FET including a resistor input voltage level detection and a series resistance, and during the secondary current control to increase the current size to compensate similarly to the lower group LED current It is also characterized by minimizing the loss of the main TR (FET) of the subgroup LEDs.

In addition, the input power compensator is composed of a MOS-FET including an input voltage level detection and a series resistance of the junction where the RC (R15-R18-C1) meets, and actively compensates for the input power for the input voltage variation. It is also characteristic to control the current height and current angle of the subgroup.

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The brightness deviation minimizing control system between the AC driving LEDs according to the present invention can obtain the following effects.

First, in the AC-driven LED control system, it is possible to realize the lamp with the uniform light flux (brightness) as much as possible by reducing the current deviation between the first LED group and the terminal LED group, so that not only the bulb type such as the incandescent bulb replacement lamp but also the fluorescent lamp The range of applications can be extended to straight lamps such as replacement lamps.

Second, the LED luminous efficiency can be maximized through the optimal I _F setting by reducing the current deviation between LED groups.

Third, efficient LED use is possible by reducing the current deviation between LED groups.

Fourth, the switching off time is minimized by using a combination of current height and current phase control in input power compensation, thereby minimizing luminous flux degradation.

Fifth, it is possible to reduce cost and maximize control efficiency by minimizing LED Tap because the upper part of the entire LED control section is dual controlled.

1 is a driving circuit diagram of a conventional AC driving LED module;
2 is a waveform diagram of input voltage and current when driving an AC drive LED module according to the related art;
3 is a control diagram in which each group LED is turned on / off according to a phase when driving an AC drive LED module according to the related art;
4 is a block circuit diagram showing an example of luminous flux (brightness) deviation minimization control between AC driving LEDs according to the present invention;
5 is an input voltage, current waveform diagram of the control method of luminous flux (brightness) deviation between the AC drive LED according to the present invention;
6 to 11 are current loops for each operation according to time of FIG.
12 is a time schedule according to FIGS. 6 to 11.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

4 is a block circuit diagram schematically showing a configuration of a control method for minimizing luminous flux (brightness) deviation between AC driving LEDs according to the present invention.

As shown in FIG. 4, the full-wave rectifying unit 100 performs full-wave rectification of the commercial power supply voltage to supply the first and second series LED units 200 and 300 and the slave source control unit 400.

The second series LED unit 300 forms an upper LED group, and is grouped and arranged into a plurality of LEDs or LED groups according to efficiency and power factor optimization. In the grouping arrangement, a section instantaneous current controller 600 or 700 is applied to each group. It branches to LED TAP2 and LED TAP3.

In addition, the first series LED unit 200 forms a lower LED group, and arranged in a group of a plurality of LEDs or LED groups according to the efficiency and power factor optimization, the section instantaneous current control unit 800 only one LED in the termination group Branch to TAP1.

Therefore, the LED quantity ratio of the lower LED group and the upper LED group constituting the first and second series LED units 200 and 300 is about 6: 5.

Thus, the primary current flows from the slave rectifier 100 to the upper LED group section instantaneous current controller 600 through the LED TAP2 in the slave source controller 400.

Thereafter, when the full-wave rectified voltage rises to reach the threshold voltage of the next higher LED, the primary current starts to flow from the slave source controller 400 to the uppermost section instantaneous current controller 700 through the LED TAP3.

In addition, the current of the next lower section instantaneous current control unit 600 decreases by the current increase of the uppermost section instantaneous current control unit 700, and is automatically cut off when a current higher than or equal to a set value flows. Group (LED group below LED TAP1) When the threshold voltage of the LED is reached, the current through the slave source controller 400 begins to decrease and as the current decreases, the current flows through the section instantaneous current controller 800 and a current above the set value flows. It is automatically shut off.

That is, when the full-wave rectified voltage through the main source BD + rises to reach the threshold voltage of the next higher LED after D2, which is a diode provided between the LED TAP1 and the LED TAP2, the LED TAP2 at the main source BD +. Through the secondary current flows to the next upper instantaneous section instantaneous current control unit 600 through.

When the full-wave rectified voltage rises to reach the threshold voltage of the uppermost LED group, the secondary current flows from the main source BD + to the uppermost section instantaneous current controller 700 through the LED TAP3.

Subsequently, when the full-wave rectified voltage falls after the maximum value and falls below the uppermost threshold voltage of a plurality of LEDs or LED groups, the current does not flow to the connected LED TAP3 and is driven off in the reverse order of the ON operation.

As described above, the biggest feature of the present invention is to take a very unique method of driving from the upper LED group out of order and repeatedly driving the upper LED group twice in one cycle over the first and second cycles.

At this time, the shape of the input current changes as the input voltage rises is as shown in FIG. 5.

More specifically, with reference to Figures 6 to 11 will be described in detail the operation according to the rise / fall of the full-wave rectified voltage.

In to → t1 of FIG. 6, the voltage through the main source BD + reaches the threshold voltage of the LED 4 through the slave source controller 400.

At the same time, the voltage across the main source BD + approaches the threshold voltage of LED1.

In t1 → t2 of FIG. 7, the primary current flows from the slave source controller 400 to the upper LED group section instantaneous current controller 600 through the LED TAP2.

At this time, a constant current flows through the R12 shunt-resistor and the Q6 of the section instantaneous current controller 600, and is automatically cut off when a current higher than a set value flows.

At the same time, the voltage across the main source BD + passes through LED1 and reaches the threshold voltage of LED2.

In t2 → t3 of FIG. 8, the primary current flows from the slave source controller 400 to the highest LED group section instantaneous current controller 700 through the LED TAP3.

At this time, a constant current flows through the R13 shunt-resistor and the Q7 of the section instantaneous current controller 700, and is automatically cut off when a current higher than a set value flows.

At the same time, the voltage across the main source BD + passes through LED1 and LED2 to reach the threshold voltage of LED3.

In t3 → t4 of FIG. 9, when the threshold voltage of the lower group LED 200 is reached, a voltage is applied to Q2 Vgs of the slave source controller 400 to start a current flow in the drain of Q2.

As the voltage through the main source BD + increases further, the current of Q1 starts to decrease as the current of Q2 increases, and the secondary current flows through the section instantaneous current control unit 800 as the decrease decreases. The current of 400 slowly decreases and then automatically shuts off.

At this time, a constant current flows through the R10 shunt-resistor (Shunt-Resistor) and Q5 of the section instantaneous current control unit 800, and automatically cuts off when a current higher than a set value flows.

In t4? T5 of FIG. 10, the secondary current flows through the LED Tap2 from the main source BD + to the next-order instantaneous current controller 600.

At this time. A constant current flows through the R12 shunt-resistor and Q6 of the section instantaneous current control unit 600, and is automatically cut off when a current higher than a set value flows.

In t5 → t6 of FIG. 11, the secondary current flows through the LED Tap3 from the main source BD + to the uppermost section instantaneous current controller 700.

At this time, a constant current flows through the R13 shunt-resistor and the Q7 of the section instantaneous current controller 700, and is automatically cut off when a current higher than a set value flows.

In addition, subdividing the group of the section instantaneous current controllers 600 and 700 may further improve the total harmonic distortion (THD) for efficiency, power factor, and current.

In addition, the overvoltage protection unit 500 cuts off the current of the section instantaneous current controller 600, 700, and 800 for the purpose of protecting the LEDs and the active elements Q5, Q6, and Q7 when the transient voltage is input.

In addition, the input power compensator 900 is connected in parallel with the shunt register R10 of the section instantaneous current controller 800 connected to the lower group LED, that is, the first series LED unit 200, to input an input voltage variation. Actively control lower LED group current height and current angle for power compensation.

In addition, the upper group secondary instantaneous current compensator 1000 is connected in parallel with the shunt registers R12 and R13 of the upper group section instantaneous current control unit 600 and 700 to increase the magnitude of the current during the secondary current control to lower the lower group. Compensation similar to LED current ensures minimal loss of main TR (FET) and Q5 for subgroup LEDs.

The control method of minimizing luminous flux (brightness) deviation between AC-driven LEDs according to the present invention is a result of testing a sample sample as compared to the conventional AC-driven method, and the current variation rate of each group is shown to be constant. same.

Test item Conditions AC drive method Invention Group1 current 120 Vac / 60 Hz 87.3 mA (standard) 66.5 mA (standard) Group2 current 80.0 mA (-8.36%) 73.8 mA (+ 10.9%) Group3 current 75.8 mA (-13.2%) 71.3 mA (+ 7.21%) Group4 current 63.9 mA (-26.8%) 56.7 mA (-14.7%) Group5 current 45.1 mA (-48.3%) 56.2 mA (-15.4%)

(Here, the data in parentheses shows the rate of change of each group's current compared to the current of Group1.)

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, but is defined by the claims, and the apparatus of the present invention may be substituted, modified, and modified in various ways without departing from the spirit of the present invention. It is apparent to those skilled in the art that modifications are possible.

100: full wave rectifier
200: first series LED unit
300: second series LED unit
400: slave source control unit
500: overvoltage protection unit
600,700,800: Section instantaneous current controller
900: input power compensation unit
1000: Upper group secondary instantaneous current compensation unit

Claims (5)

A full-wave rectifier to which an AC voltage is applied through the bridge full-wave rectifier circuit;
A slab connected to an area between the plurality of LEDs or LED groups to non-sequentially dual control from the upper plurality of LEDs or LED groups to the lower plurality of LEDs or LED groups among the plurality of LEDs or LED groups connected in series with the full wave rectifier. An eve source controller;
Section instantaneous current control unit connected to the region between the plurality of upper LEDs or LED groups, lower LEDs, or LED groups connected in series, respectively, to sequentially and constantly control the plurality of upper LEDs or LED groups, lower LEDs, or LED groups Wow;
It is connected in parallel with the shunt register of the upper group section instantaneous current controller to increase the magnitude of current in the secondary current control to compensate similarly to the lower group LED current to minimize the loss of the main TR (FET) of the lower group section instantaneous current controller. Upper group secondary instantaneous current compensation unit;
An input power compensator that is connected in parallel with the shunt-register of the instantaneous current controller in the lower group section and actively controls the lower group current height and current angle to compensate for the input power caused by the input voltage variation;
And an overvoltage protection unit for blocking the current of the section instantaneous current control unit to protect the LED and the active element when the transient voltage is input.
The method according to claim 1,
The slave source control unit,
Supplying current to the upper group LED until the voltage through the full wave rectifier reaches the threshold voltage of the lower group LED through the slave source control unit,
When the voltage through the full-wave rectifier further increases to reach the threshold voltage of the lower group LEDs, the current of the slave source control unit is to gradually reduce the brightness deviation between the AC drive LED, characterized in that to cut off.
The method according to claim 1,
The upper group secondary instantaneous current compensation unit,
Consists of MOS-FET with resistor input voltage level detection and series resistor.
A control system for minimizing brightness deviation between AC driving LEDs, in which secondary current is controlled to increase the magnitude of current to compensate similarly to the subgroup LED currents to minimize the loss of the main TR (FET) of the subgroup LEDs.
The method according to claim 1,
The input power compensation unit,
It consists of an input voltage level sensing at the junction where RC (R15-R18-C1) meets and a MOS-FET including a series resistor.
A control system for minimizing brightness deviation between AC driving LEDs, which actively controls a current group and a current angle of a subgroup to compensate input power for input voltage variations. delete

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