KR101510845B1 - Light emitting diode lamp for possible color temperature conversion and method for using controling the same - Google Patents

Abstract

The present invention relates to an LED lamp capable of color temperature conversion for controlling a color temperature of an LED unit by only the operation of a power switch through a simple control unit connected to the SMPS and a method for converting color temperature of an LED lamp using the LED lamp. An additional means connected to the SMPS for receiving a voltage change of the SMPS and controlling a color temperature of the LED, and a plurality of LED devices connected to the additional control means and having different color temperatures, And a switch connected between the external power supply and the SMPS to turn the external power supply on and off so that the voltage change can be transmitted to the additional control means.

Description

TECHNICAL FIELD [0001] The present invention relates to an LED lamp capable of color temperature conversion and a method for converting color temperature of an LED lamp using the same. BACKGROUND OF THE INVENTION 1. Field of the Invention [0002]

The present invention relates to an LED lamp capable of color temperature conversion and a color temperature conversion method of an LED lamp using the LED lamp. More particularly, the present invention relates to a color temperature conversion method for controlling a color temperature of an LED unit And a color temperature conversion method of an LED lamp using the LED lamp.

In general, mixing multiple colored LEDs to obtain mixed colors is a common way to produce white or colored light. The generated light is determined by a number of factors, such as the type of LED used, the color ratio, the driving ratio, the mixing ratio, and the like. However, the optical properties of LEDs change as the temperature of the LED increases during operation: the flux output decreases and the peak wavelength changes.

To overcome or alleviate this problem, various color control systems have been proposed to compensate for this change in the optical properties of the LED during use. Examples of color control systems or algorithms are described in, for example, P. Deurenberg, "Achieving color point stability in RGB multi-chip LED modules using various color control loops ", Proc. SPIE Vol. (Color coordinate feedback), temperature feed forward (TFF), flux feedback (FFB), or a combination of the last two (FBB + TFF), as disclosed in US Pat. .

In addition, it has been proposed to use various so-called phosphor converted LEDs that produce mixed color light, which is more stable in light output than conventional intrinsic LEDs. In the phosphor-converted LED, a part of the light from the lower LED is converted into light of another wavelength by a color converter (for example, a phosphor).

However, the phosphor conversion LEDs tend to leak some of the (untranslated) light from the lower LEDs. This leakage mixes with the converted light to change the apparent color emitted from the phosphor converted LED. Moreover, this leakage varies with time and temperature (due to, for example, the temperature sensitivity of the lower LEDs), resulting in a change in output (e.g., unconverted light from the lower LED increases, Lt; / RTI > decreases). This change is particularly important when the wavelength of the light from the lower LED is within the visible spectrum.

This change can not be compensated in a satisfactory manner by the above-mentioned color control system because such a color control system can not identify the leakage of unconverted light from the lower LED from the total output of the phosphor conversion LED Because.

Further, if a color control system or a specific LED element is used to convert the color of the LED to solve the above-described problems, the manufacturing cost of the LED lighting product increases, resulting in a high product price .

In general, an LED lighting device converts a color of an LED to a device such as a color conversion switch or a wireless remote controller so that a user can change the color of the LED. In addition, complicated wiring work is required to install the product.

A related prior art is Korean Patent Laid-Open No. 10-2008-0079269.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an additional control means which can be easily connected to an SMPS used in conventional LED lighting products, And a color temperature conversion method of the LED lamp using the LED lamp.

The technical objects to be achieved by the present invention are not limited to the above-mentioned technical problems.

According to an aspect of the present invention, there is provided an LED lamp capable of converting color temperature, comprising: an SMPS for converting an external power source to output an appropriate level of DC power; An LED unit connected to the additional unit and configured by a plurality of LED elements having different color temperatures; an LED unit connected between the external power source and the SMPS to turn on / off the external power source, And a switch for allowing the voltage change to be transmitted to the additional control means. The LED lamp according to claim 1, wherein the additional control means further comprises: a power source input end into which the output power of the SMPS and a voltage change are inputted; A clock conversion unit connected to the input terminal and configured to convert a change in the voltage of the input power source into a clock signal; An IC unit which is connected to the clock conversion unit and sequentially outputs any one of a plurality of output pins each time a clock signal of the clock conversion unit is inputted; a flicker prevention unit for preventing a flicker of the LED lamps during a color temperature conversion; A reset unit connected between the power input terminal and the IC unit to initialize the IC unit when a voltage change of the power input terminal flows after a predetermined time elapses after the switch is shut off, And an LED selector for receiving an output signal of the SMPS and applying an output power of the SMPS to the selected LED element.

Specifically, the additional control means sets a reference time by a capacitor and a resistor included in the reset unit, and when the switch is turned off and the power output from the SMPS is cut off, When the next operation signal is inputted through the switch, the IC unit may be initialized such that the power outputted from the SMPS is applied to the maximum or minimum color temperature LED element.

According to an aspect of the present invention, there is provided a color temperature conversion method using an LED lamp capable of color temperature conversion. The method includes: initializing a switch connected between an external power supply and an SMPS and initializing an IC unit; Converting a voltage change of the switch into a clock signal so as to be recognized as a clock signal in the IC unit and transmitting the converted clock signal to the IC unit; and when the voltage change is input to the input pin of the IC device as a clock signal, A step of outputting a signal to an output pin of the IC element and transmitting the signal to an LED selector; and the LED selector selects one LED element for each color temperature type for applying power by a corresponding circuit element of the output pin of the IC element Selecting one of the color temperature LEDs for each of the selected color temperature types, the output power of the SMPS is supplied and turned on, The IC unit continuously outputs a signal to the same output pin so that the LED unit continues to check the same color temperature in the absence of a voltage change to be turned off, And when the switch is turned OFF, it is determined whether the reference time has elapsed by detecting the time of the next voltage change, and the switch is turned ON without the reference time elapsing, And returning to the step of inputting such a voltage change as a clock signal to the IC section, and when the reference time elapses with the switch being off, cutting off the power of the SMPS transmitted to the LED section . ≪ / RTI >

As described above, according to the present invention, it is possible to provide additional control means that can be easily connected to the SMPS used in existing LED lighting products, and to select any one of the other types of LEDs to which the output power of the SMPS is applied There is an effect that the color temperature of the LED portion can be controlled only by the operation of the power switch without a separate color temperature changeover switch.

Further, according to the present invention, since the additional control means is separate from the control circuit of the existing SMPS and is simple in construction compared with the conventional LED lighting product in which the color temperature change switch is separately mounted, The effect that can be utilized without changing, and consequently the manufacturing cost is reduced, and the installation effect is easier than the existing product having the same function.

1 is a view illustrating a structure of an LED lamp capable of color temperature conversion according to an embodiment of the present invention.
Figure 2 is a block diagram of the further control means shown in Figure 1;
3 is a specific circuit diagram of the additional control means shown in Fig.
4 is a flowchart illustrating a method of converting a color temperature of an LED lamp using an LED lamp capable of color temperature conversion according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same components are denoted by the same reference symbols whenever possible. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

FIG. 1 is a view showing an LED lamp capable of color temperature conversion according to an embodiment of the present invention. The LED lamp includes an SMPS 10 for converting an external power source and outputting an appropriate level of DC power, (20) for controlling the color temperature of the LED unit (30) by receiving a voltage change of the LED unit (40), an LED unit (30) composed of a plurality of LED units having different color temperatures, ON / OFF) and a voltage change corresponding thereto can be transmitted to the additional control means 20.

First, the SMPS 10 is connected between the switch 40 and the additional control means 20, and when the external power is applied through the operation of the switch 40, the SMPS 10 is controlled by the additional control means 20, ) To the LED element in the light emitting diode. The LED elements which are supplied with power by the SMPS 10 are classified by the color temperature and selected by the additional control means 30.

At this time, the SMPS 10 can apply power to one or more LED elements among a plurality of LED elements having different color temperatures. That is, for example, when the additional control means 20 outputs a control signal for selecting either one type of LED element or selecting two types of LED elements at the same time, As shown in FIG.

The additional control means 20 is connected between the SMPS 10 and the LED portion 30. The additional control means 20 receives the voltage change of the SMPS 10 when the switch 40 is turned ON as an input signal, And controls the SMPS 10 and the LED unit 30 so that the output power of the SMPS 10 is applied to the corresponding LED device by outputting a control signal for selecting the LED device in the LED unit 30. [

At this time, the control method of the additional control means 20 is such that the switch 40 is turned on / off so that the change of the input voltage can be divided into three cases in order to change the operating state.

First, when the switch 40 is in the ON state, the current state is maintained unless the next voltage change is inputted. Second, the switch 40 is turned off from the OFF state within the set reference time (3) the case where the switch 40 is in the OFF state and then the ON state after the reference time has elapsed; and (3) And the selection of the LED element is started again from the initial value.

In this way, the additional control means 20 outputs a control signal for selecting the corresponding color temperature LED element of the LED unit 30, and the power outputted from the SMPS 10 through the control signal is supplied to the corresponding LED of the LED unit 30 And the color temperature of the LED unit 30 is changed.

The LED unit 30 is connected to the output terminal OUT of the additional control means 20 and two or more types of LED devices according to the color temperature may be arranged inside the LED unit 30 in an intersecting manner.

At this time, the output terminal OUT of the additional control means 20 connected to the LED unit 30 is connected to each of them according to the type of the LED device. For example, the output terminal OUT of the additional control means 20 is two, and one of the output terminals OUT is one of the two types of LED elements. Type LED element and the other output terminal OUT is connected to another kind of LED element.

In addition, the voltage is applied to only one kind of LED element by the above connection, so that the LED part 30 is irradiated with the first color temperature, and then, the voltage is applied to only the other type of LED element, The color temperature at which the LED unit 30 emits light in a manner that the output power of the SMPS 10 is applied to both types of LED elements and is irradiated at the third color temperature is controlled by the additional control means 20). ≪ / RTI >

The additional control means 20 can be connected to the existing SMPS 10 simply by controlling the output temperature of the LED unit 30 in a configuration different from the circuit for controlling the output power of the conventional SMPS 10 .

The further control means 20 of the present invention constituted as described above will be described in more detail.

Fig. 2 is a block diagram of the additional control means 20 according to the present invention, and Fig. 3 is a diagram showing a specific circuit configuration of the additional control means 20 accordingly.

2 and 3, the additional control means 20 converts the voltage change of the power supply input terminal 21 into which the output power and voltage changes of the SMPS 10 are inputted to be recognized as a clock signal A flicker prevention unit 23 for preventing a flicker during the color temperature conversion of the LED lamp, and a flip-flops 23 and 24 for sequentially outputting any one of a plurality of output pins When the voltage of the power input terminal 21 flows after a certain time has elapsed after the switch 40 is shut off due to the connection between the IC unit 24 for outputting power and the IC unit 24 and the power input terminal 21, And a LED selector 26 for receiving the signal output from the IC unit 24 and applying the output power of the SMPS 10 to the selected LED device.

The power supply input terminal 21 is connected to the SMPS 10 to allow the output power of the SMPS 10 to be input and at the same time when the power switch 10 is turned on / Is an input of an additional control means (20) for allowing the input of the control means (20).

The clock converting unit 22 includes a plurality of zener diodes ZD1 and ZD2, transistors Q1 and Q7 and a resistor R. The zener diode ZD2 is connected to the power input terminal 21, The change in the voltage flowing into the IC element input pin of the IC section 24 by the transistor Q1 that is intermittently turned on is recognized as a clock signal and is supplied to the IC section 24, Lt; RTI ID = 0.0 > IC < / RTI >

That is, in the clock converter 22, when the switch 40 is changed from the OFF state to the ON state, a change in the voltage is inputted to the power input terminal 21 and the clock connected to the power input terminal 21 The voltage is distributed to the resistor R of the conversion section 22 and the Zener diodes ZD1 and ZD2, respectively. At this time, when the voltage is low due to the characteristics of the zener diodes ZD1 and ZD2, the current hardly flows. However, when the voltage increases and the voltage suddenly flows when a specific voltage is applied and a voltage is applied to the base of the transistor Q1, Current is conducted to the collector terminal. In this case, the transistor Q1 conducts only at a specific voltage or higher, and when the voltage is lower than a specific voltage, the voltage change introduced is recognized as a clock signal and input to the input pin of the IC device.

The flickering prevention part 23 includes a capacitor C4 and a resistor R and is connected to the clock changing part 22 and the LED selecting part 26 so that the LED flashes instantaneously at the time of color temperature conversion after power is applied to the LED lamp. .

The IC section 24 includes an IC element and is connected between the clock conversion section 22 and the reset section 25. The IC element may be a general commercial counter type circuit element. The IC device changes the clock signal from the LOW state to the HIGH state, and sequentially turns the output pin of any one of the plurality of output pins into the HIGH state.

At this time, since the plurality of output pins of the IC device are connected to different parts of the internal circuit of the LED selector 26, the LEDs corresponding to the respective types of the output pins that are in the HIGH state The output power of the SMPS 10 is applied to each of the LED devices connected to the output OUT of the LED selector 26. [

In other words, when the output pin of the IC element of the IC section 24 is set to three, if the first clock signal is input to the IC element of the IC section 24, the first output pin of the IC element becomes HIGH, The power switch 40 is turned on and off to input a second clock signal to the IC device. When the IC device is in the HIGH state, The second output pin goes to the HIGH state and the third output pin of the IC device goes to the HIGH state when the third clock signal is input.

When the fourth clock signal is input again, the first output pin goes to the HIGH state, and the above process is repeated in sequence, or the fourth output pin is set to the HIGH state by setting the output pin to 4 You can repeat the above process.

That is, the number of fins capable of outputting IC elements can be changed as desired. The IC element of the IC section 23 performs the above-described process by the operation of the switch 40 until power is applied to the reset pin and initialized Repeat.

The reset unit 25 includes a transistor Q2 and a plurality of capacitors C2 and C3 and a resistor R and is connected between the IC unit 24 and the LED selector 25. The collector of the transistor Q2, The terminal is connected to the IC element reset pin of the IC section 24 and the emitter and the base terminal are connected to the power input terminal 21 so that the incoming power is cut off and then turned on again after a predetermined time, A reset signal is applied to the reset pin of the memory cell array.

That is, the transistor Q2 is turned off when the LED lamp is turned on or off, and the transistor Q2 is turned off. When the LED lamp is turned on after a certain period of time has elapsed with the LED lamp turned off, The LED lamp emits light corresponding to the first color temperature among the color temperatures of various stages.

At this time, an operation of determining the elapse of a predetermined time while the LED lamp is turned off is as follows. The power supply switch 40 is turned off and the capacitors C2 and C3 of the reset unit 25 start to discharge and the capacitors C2 and C3 are completely discharged to determine whether a predetermined time has elapsed And the reference time can be adjusted by the capacitances of the capacitors C2 and C3 and the resistors R6, R7 and R8.

This process of the reset unit 25 will be described in detail. When the SMPS 10 is continuously supplied with power, the capacitors C2 and C3 are continuously charged. Therefore, the emitter of the transistor Q2, There is no difference in voltage between the base and the emitter and base. If no current flows through the base, the transistor Q2 is turned off and no power is applied to the reset pin of the IC device, so that the IC device can continue the sequential operation following the previous operation.

On the other hand, when the power is turned off and then turned on, two different operations can be performed depending on the elapse of the reference time.

First, when the power switch 40 is turned on within a predetermined reference time after the power switch 40 is turned off, the capacitor C2 connected to the base of the transistor Q2 is charged again in a state in which it is completely discharged, The voltage of the emitter and the base of the transistor is not different. Thus, as described above, the IC device is not reset and continues the next operation sequentially, following the previous operation.

Second, when the predetermined time elapses after the power switch 40 is turned off, the capacitor C2 connected to the base of the transistor Q2 is charged again in a completely discharged state.

At this time, the emitter of the transistor Q2 is directly powered from the power input terminal 21, while the voltage across the base is applied later than the voltage across the emitter by the capacitor C2 connected to the base, The current due to the voltage difference of the base flows from the emitter to the base.

Then, a current flows from the emitter to the collector, current flows into the reset pin of the IC element of the IC section 24 connected to the collector, and the IC element is initialized. After that, when the clock signal is input to the input pin of the IC device, the first operation is resumed, and the first output pin becomes HIGH.

The LED selector 26 includes a plurality of transistors Q3, Q4, Q5 and Q6, a plurality of MOS FETs F1, F2, F3 and F4 and a plurality of resistors R, IC devices of the IC portion 24 are connected to the output terminals OUT of the IC devices 24. Each of the two output pins of the plurality of output pins of the IC portion 24 is connected to the transistors Q3 and Q4 and the other output pin is connected between the transistors Q3 and Q4 And may be connected to resistors R13 and R14.

When a plurality of transistors Q3 and Q4 receive a current from the output pin of the IC device and conduct current to the circuit to distribute the voltage to each connected resistor, the divided voltage acts as a power switch of the SMPS 10 The connected MOS FETs F1, F2, F3 and F4 are controlled.

That is, assuming that the number of output pins for outputting IC elements is set to three and that the type of the LED element is two kinds of first and second LEDs according to the color temperature, the first output pin conducts the transistor Q4, And the power of the SMPS 10 connected to the MOSFETs F4 and F3 is output to any one of the output terminals OUT and applied to the first LED device of the LED unit 30. [ The power supply of the SMPS 10 connected to the MOSFETs F1 and F2 is output to another output terminal OUT so that the LEDs Q1 and Q2 are turned on, Is applied to the second LED element of the light emitting portion (30). The third output pin conducts all the transistors Q3 and Q4 so that the power of the SMPS 10 connected to the MOSFETs F1, F2, F3 and F4 is outputted to the two output terminals OUT, 1 and 2 LED devices.

As a result, the number of output terminals OUT of the additional control means 20 connected to the LED selector 26 is determined according to the type of the LED element depending on the color temperature.

The operation method of the present invention having the above-described structure will now be described.

The switch 40 is turned on in the additional control means 20 connected to the SMPS 10 as shown in Fig. 4 and the IC unit is turned on when the LED lamp is turned on, The color temperature is initialized so as to turn on (S10).

The clock conversion unit 22 of the additional control means 20 converts the voltage change of the power supply switch 40 into a clock signal so as to be recognized as a clock signal in the IC unit 24 and transmits the clock signal to the IC unit 24 S20).

When the IC unit 24 receives a voltage change as a clock signal to the input pin of the IC device, the IC unit 24 sequentially outputs a signal to the output pin of the IC device and transmits the signal to the LED selection unit 26 (S30).

The LED selector 26 selects one LED element for each color temperature type to which power is to be applied by the corresponding circuit element of the output pin of the IC element (S40) And is turned on (S50).

At this time, when the input of the switch 40 is the first signal for operating the LED 30, the additional control means 20 allows the power of the SMPS 10 to be applied to the LED element corresponding to the first color temperature, When the voltage change is inputted, the power source of the SMPS 10 is applied to the LED device corresponding to the second color temperature. Then, when the voltage change is inputted again, the power is applied to both the LED devices. Of course, such a sequence or repeating pattern can be modified in any number of ways.

Once the LED lamp is turned on, it is determined whether the power switch 40 is turned off. If there is no voltage change that is turned off, the IC unit 24 continuously outputs a signal to the same output pin, (Step S60) so that the LED unit 30 continues to check the same color temperature.

That is, if the user does not operate the switch 40 while the LED unit 30 is turned on, the LED unit 30 keeps the current on state.

If the power switch 40 is turned off in the previous step S60, the next time the switch 40 is turned on, it is detected that the reference time has elapsed, When the switch 40 is turned on without elapsing, the process returns to step S20, which is a step of inputting a voltage change to the IC unit (S70).

At this time, when the process returns to step S20, the LED elements corresponding to the next color temperature are sequentially turned on and the above process is repeated.

If the reference time elapses in the state where the power switch 40 is turned off in the previous step S70, the additional control means 20 cuts off the power of the SMPS 10 transmitted to the LED unit S80).

That is, if the user does not turn on the switch 40 again after the reference time elapses after the power switch 40 of the LED lamp is turned off, The controller 20 determines that the unit 20 is completely turned off and cuts off the power.

Hereinafter, the present invention will be described with reference to an embodiment.

First, the types of LED devices according to the color temperature of the LED unit 20 are set to 6200K and 2700K, and the reference time until the next voltage change is input after the switch 40 is turned off is 10 seconds And is described as an embodiment. Of course, the number of kinds of LED elements according to the color temperature and the reference time for inputting the voltage change can be adjusted as much as possible by setting the additional control means 20. [

Initially, the user turns on the power by operating the switch 40 while the power of the LED lamp is turned off. At this time, the capacitor of the reset unit 25 of the additional control means 20 is discharged and then the IC unit 24 is reset in the process of charging again.

Next, when the switch 40 is turned on and power is applied to the SMPS 10 and the SMPS 10 changes to an appropriate level to output the DC power, the additional control means 20 connected to the SMPS 10, And the power is supplied to the power inlet terminal 21 of the power supply unit 21 and is transmitted to the inside. At this time, the clock conversion unit 22 converts the change of the introduced voltage so that the IC unit 24 can recognize it as a clock signal, and transmits the converted voltage to the IC unit 24.

When the first voltage change is input to the input pin of the IC device 24 as a clock signal, the IC unit 24 turns the first output pin of the three output pins into a HIGH state to output a signal to the first output pin, To the selection unit (26).

The LED selector 26 allows the MOSFETs F3 and F4 to conduct when the signal is transmitted from the IC unit 24 to the transistor Q4 connected to the corresponding output pin so that the SMPS (10) to the output terminal (OUT) corresponding to the color temperature of 6200K.

At this time, power is applied to an LED element having a color temperature of 6200K disposed inside the LED part 30 from an output terminal (OUT) corresponding to 6200K, and the LED element irradiates the corresponding light.

Next, after the light is turned on for the first time on the LED unit 30, it is determined whether the user operates the switch 40 again.

That is, the additional control means 20 detects whether the switch 40 is turned off again by the voltage change as in the previous step, and if the switch 40 is kept in the current state without being turned off, Section 24 continues to transmit the same output signal to the LED selector 26 via the same output pin. Referring to FIG. 4, it is shown to return to step S40, and as a result, the LED unit 30 continuously irradiates the same light.

Next, if the switch 40 is turned off, the process proceeds to the next step, and it is determined whether a reference time of 10 seconds has elapsed since the switch 40 was turned off.

When the user turns off the power switch 40 and the reference time of 10 seconds has not elapsed and the switch 40 has been turned on, the above process is repeated in sequence. If 10 seconds have elapsed, It proceeds.

That is, if the reference time of 10 seconds has not elapsed, the IC unit 24 sequentially turns the second output pin to the HIGH state by the second voltage change, and the LED selector 26 turns on the second corresponding LED By applying power to the device, the LED unit 30 irradiates light corresponding to 2700K.

If the reference time of 10 seconds has not elapsed yet again after the step of determining whether the reference time has elapsed again, the IC unit 24 sets the third output pin to a HIGH state by the third voltage change, Power is applied to both the first and second LED elements, and the LED unit 30 emits light corresponding to 4000K.

This operation is sequentially and continuously performed every time the switch 40 is turned on and the IC element of the IC unit 24 is initialized after the reference time has elapsed, every time the user turns off the switch Repeat.

However, if the user has turned off the LED 20 in the previous step and the reference time of 10 seconds elapses, the power supply of the LED 30 is finally completely cut off and the capacitor in the reset unit 25 is completely Is discharged.

That is, after 10 seconds as the reference time elapses, when the user turns on the power switch 40, the operation of the first step is newly started. After the elapse of 10 seconds as the reference time, The LED element corresponding to the first color temperature of 6200K is turned on irrespective of the type of the LED element which is turned on in the LED portion 30 of FIG.

When the user operates the LED unit 30 for the first time, the user continuously turns off the power switch 40 and then turns on the power switch 40 within the reference time of 10 seconds The color temperature of the LED unit 20 can be sequentially changed continuously. If the desired light is turned on, the operation of the power switch 40 is stopped in the ON state to maintain the color temperature of the LED unit 30. When the LED unit 20 is completely turned off, the power switch 40 is turned off (OFF) and then the reference time elapses.

The present invention configured as described above provides additional control means that can be easily connected to the SMPS used in conventional LED lighting products and can select any one of other types of LEDs to which the output power of the SMPS is applied, The color temperature of the LED portion can be controlled only by the operation of the power switch without a separate color temperature changeover switch.

Further, according to the present invention, since the additional control means is separate from the control circuit of the existing SMPS and is simple in construction compared with the conventional LED lighting product in which the color temperature change switch is separately mounted, The effect that can be utilized without changing, and consequently the manufacturing cost is reduced, and the installation effect is easier than the existing product having the same function.

The LED lamp capable of color temperature conversion as described above and the color temperature conversion method of the LED lamp using the LED lamp are not limited to the configuration and operation method of the embodiments described above. The embodiments may be configured so that all or some of the embodiments may be selectively combined so that various modifications may be made.

10: SMPS 20: Additional control means
21: Power input stage 22: Clock conversion unit
23: flicker prevention part 24: IC part
25: reset section 26: LED selection section
30: LED unit 40: switch

Claims (3)

An additional control means connected to the SMPS for receiving a voltage change of the SMPS and controlling a color temperature of the LED, and a color temperature controller connected to the additional control means, A switch connected between the external power supply and the SMPS for turning on and off the external power supply and allowing the voltage change to be transmitted to the additional control means; In an LED lamp capable of color temperature conversion,
Wherein the additional control means comprises:
A power input terminal into which the output power of the SMPS and a voltage change are input,
A clock converter for converting the voltage change of the power source connected to the power input terminal to be recognized as a clock signal;
A flicker preventing unit connected between the clock converting unit and the power supply inflow unit to prevent flickering when a color temperature of the LED lamp is changed;
An IC unit connected to the clock conversion unit and sequentially outputting any one of a plurality of output pins each time a clock signal of the clock conversion unit is input;
A reset unit connected between the power input terminal and the IC unit to reset the IC unit when a voltage change of the power input terminal flows after a predetermined time elapses after the switch is shut off,
And an LED selector connected to the IC unit and receiving an output signal from the IC unit to allow the output power of the SMPS to be applied to the selected LED element.
The method according to claim 1,
Wherein the additional control means sets a reference time by a capacitor and a resistor included in a reset unit, and when the switch is turned off and the power output from the SMPS is cut off, Wherein the controller is configured to initialize the IC unit so that power supplied from the SMPS is applied to the LED unit having the maximum or minimum color temperature when the next operation signal is input through the LED unit.
The switch connected between the external power supply and the SMPS is turned on and the IC unit is initialized;
Converting a voltage change of the switch into a clock signal so as to be recognized as a clock signal by the IC unit and transmitting the clock signal to the IC unit;
The IC unit sequentially outputs a signal to the output pin of the IC device when the voltage change is input to the input pin of the IC device as a clock signal, and transmits the signal to the LED selector;
Wherein the LED selector comprises: selecting one LED element for each of the color temperature types to which power is to be applied by a corresponding circuit element of an output pin of the IC element;
The output power of the SMPS is supplied to the selected one of the LED elements of the selected color temperature type so as to be turned on;
Once the LED lamp is turned on, it is determined whether the switch is turned off. If there is no voltage change that is off, the IC unit continues to output a signal to the same output pin so that the LED unit continuously irradiates the same color temperature, Returning to the step of transmitting to the selection unit;
If the switch is turned off, it is determined whether the reference time has elapsed by sensing the time of the next voltage change. If the reference time does not elapse and the switch is turned on, Returning to the step of inputting to the input device; And
And turning off the power of the SMPS transmitted to the LED unit when the reference time elapses while the switch is turned off.

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