KR101667566B1 - Led lighting system for remote control of jewelry and led lighting method for remote control of jewelry using the same - Google Patents

Abstract

The present invention relates to an LED lighting system for remotely illuminating jewelry and a method for remotely illuminating jewelry using the same, capable of maximizing the beauty of jewelry with brilliant effects due to scattering, refraction and diffused reflection of the light, etc., by installing a remotely controllable LED lighting system to illuminate the LED light to the surfaces of the jewelry with multiple angles and multiple screens at desired time for desired period of time. More specifically, the LED lighting system for remotely illuminating jewelry includes: a body part; a jig formed in the body part; a jewel mounted on the jig; a light illuminating part; and a remote controlling part. The light illuminating part includes: a first case which is installed in the inside of the body part and the bottom of the first case is opened; an infrared radiation receiving part installed in the inside of the first case; a first PCB which is installed in the inside of the first case and connected with a plurality of LEDs and the infrared radiation receiving part; a second PCB which is connected with a microprocessor for controlling the operation of the LEDs and electrically connected with the first PCB; a battery for applying electrical power to the second PCB; and a cover to open and close the bottom of the first case. The remote controlling part operates the second case by receiving electrical power from an infrared radiation transmission part installed in the inside of the second case, and includes a plurality of control buttons which are provided in the second case.

Description

TECHNICAL FIELD [0001] The present invention relates to an LED light emitting system for remotely controlling a jewelery, and an LED light emitting method for remotely controlling a jewelery using the LED light emitting system.

The present invention relates to an LED light emitting system for remote control of jewelery and an LED light emitting method for remote control of jewelery using the same, and more particularly to an LED light emitting system for remote control of a jewelery such as a bracelet, a necklace, an earring and a ring made of a jig for holding a body part, (Diamond, ruby, sapphire, emerald, crystal, pearl, cubic, etc.) for a desired time period and a desired time by incorporating an LED light emitting system equipped with a one-chip microprocessor in the body part of the same precious metal, (LED) light by irradiating LED light to the surface of a jeweler's remote control, which can maximize the beauty of the jewel by the radiance effect caused by light scattering, refraction and diffuse reflection, And a method of controlling LED light emission.

Traditionally, various kinds of accessories made of artificial jewelery and natural jewelry have been produced as ornaments in jewelery ornaments, and the market size thereof is increasing day by day.

Generally, as various kinds of accessories, designs, colors, and the like are diversified, they are manufactured by attaching artificial jewelry or natural jewelry to rings, necklaces, earrings, bags, and brooches or fixing them with clips.

In the case of jewelry using such jewelery, the brilliance effect is great due to its specific luster and reflectivity during the daytime, but it is difficult to attain the purpose of wearing it without nighttime illumination.

In order to solve such a problem, an accessory manufacturer has been concentrating on the development of ornaments capable of emitting light.

On the other hand, a technique relating to light emitting ornaments has been disclosed in Patent No. 10-1138439.

SUMMARY OF THE INVENTION The present invention provides an LED light emitting system for remotely controlling a jewelery, which comprises a light irradiation unit that is miniaturized so as to be applicable to the jewelry or the like by applying a one-chip microprocessor, and a remote control unit that remotely controls the light irradiation unit, There is a purpose.

Another object of the present invention is to provide an LED light emission system for remotely controlling a jewelery remote control system which can set a light emission time, a light emitting period, The purpose is to provide.

Another object of the present invention is to provide an LED light emitting system for remotely controlling a jewelery, which can maximize the luminous effect inherent to jewels regardless of place and time by applying various colors.

It is another object of the present invention to provide an LED light emitting method for remotely controlling a jewelery using an LED light emitting system for remotely controlling the jewelery.

In order to accomplish the above object, the present invention provides an LED light emitting system for remote control of jewelery comprising a body part; A jig formed on the body portion; A jewel that is seated and supported on the jig; A light irradiating unit having a wireless receiver and a plurality of LEDs mounted on the body; And a remote control unit having a wireless transmission unit and controlling the light irradiation unit.

The light irradiation unit may include a first case installed in the body and having a lower opening; An infrared ray receiving unit installed in the first case; A first PCB installed in the first case and connected to the plurality of LEDs and the infrared receiver; A second PCB connected to a microcomputer for controlling operation of the LED, and electrically connected to the first PCB; A battery for supplying power to the second PCB; And a cover for opening and closing a lower portion of the first case.

In addition, the color of the LED is characterized by a plurality of colors.

Further, the cover is detachably attached to the first case in a spiral manner.

The light irradiation unit may further include: a battery; A power supply unit for boosting the power supplied from the battery and transmitting the power; An infrared ray (IR) receiving unit operating with power supplied through the power transmitting unit; A backflow prevention part connected between the power supply part and the infrared receiver part; A voltage stabilizing unit connected to the infrared ray receiver and the backflow prevention unit; A microcomputer (microprocessor) operating with power supplied thereto and operating a plurality of LEDs according to a signal transmitted through the infrared receiver; An I / O input / output terminal connected to the microcomputer, the I / And a system function switch for operating the light irradiating unit.

The remote control unit may further include: a second case; An infrared ray transmission unit operable to receive power, and being installed in the second case; And a plurality of control buttons formed on the second case, and the control signal generated through the control button is transmitted to the wireless receiving unit through the infrared transmitting unit.

Meanwhile, the LED light emitting method for remotely controlling the jewelery using the LED light emitting system for remotely controlling the jewelery according to the present invention comprises: a first step of applying power to the light irradiating unit and the remote control unit; And a second step of controlling the light irradiation unit through the remote control unit.

In this case, the second step may include: a second step of operating one of the LEDs; A second step 2-2 of operating another LED; And a second step of simultaneously operating any one of the LEDs and the other LED.

A mode signal input step of inputting a standby signal for operating the selected LED in each of the second stage, the second stage, and the second stage, wherein the mode signal is terminated when the standby signal is not inputted; And a lighting time setting step of inputting a lighting time for setting the lighting duration time of the selected LED and ending the lighting time of the selected LED.

In addition, after the lighting time setting step, the number of repetitions is set so that the operation of turning off the selected LED is repeated, and when the number of repetition times is not set, the selected LED is turned on and off, ; ≪ / RTI >

The method may further include a first setting signal input step for inputting a setting signal for proceeding to the next step after the mode signal input step and ending when the setting signal is not inputted.

In addition, after the lighting time setting step, a second setting signal input step of inputting a setting signal for proceeding to the next step and lighting the selected LED for the set duration when the setting signal is not inputted .

Further, the method further includes a setting mode progressing step after the mode signal inputting step is terminated after the LED selected by the predetermined lighting duration time and the number of repetition times is operated.

As described above, according to the present invention, since a one-chip microprocessor is applied and remotely controlled, miniaturization can be performed, and thus it can be easily applied to jewelry, such as rings, earrings, and necklaces.

In addition, since a plurality of various LED colors can be used, it is possible to realize an appropriate luster effect according to the color of the jewelry.

Further, the lower cover can be configured to be detachable by the spiral coupling, thereby facilitating maintenance of the system.

In addition, when the display unit is provided in the remote control unit, it is possible to more easily control the light irradiation unit.

In addition, since the color of light emitted by the LED, the light emission time, the light emission period, and the number of light emission can be selectively set according to the user's need, the user can obtain the desired effect regardless of the place and time.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic configuration diagram of an LED light emitting system for remote control of a jewelery according to an embodiment of the present invention;
FIG. 2 is a conceptual view of the internal configuration of the light irradiation unit viewed from the side of FIG. 1,
3 is a view illustrating a state and a structure of a first case and a cover according to an embodiment of the LED light emission system for remote control of a jewelery according to the present invention,
4 is a conceptual circuit configuration diagram of a light irradiating unit according to an embodiment of an LED light emitting system for remote control of a jewelery according to the present invention,
5 is a diagram illustrating an LED light emitting method for remote control of a jewelery according to an embodiment of the present invention,
6 is a flowchart according to an embodiment of an LED emission method for remotely controlling a jewelery according to the present invention.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail.

It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. Like reference numerals are used for like elements in describing each drawing.

The terms including ordinal, such as second, first, etc., may be used to describe various elements, but the elements are not limited to these terms.

The terms used herein are used only for the purpose of distinguishing one element from another. For example, without departing from the scope of the present invention, the second component may be referred to as a first component, and similarly, the first component may also be referred to as a second component. And / or < / RTI > includes any combination of a plurality of related listed items or any of a plurality of related listed items.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

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

FIG. 1 is a schematic configuration diagram of an LED light emitting system for remote control of jewelery according to the present invention. FIG. 2 is a conceptual view of an internal configuration of a light irradiation part viewed from the side with reference to FIG. 1, 3 is a view illustrating a combined state and structure of a first case and a cover according to an embodiment of the LED light emission system for remote control of jewelery according to the present invention.

1 to 3, an LED light emitting system for remote control of jewelery according to the present invention will now be described.

The LED light emission system for remote control of a jewelery according to the present invention comprises: a body part (100); A jig 200 formed on the body 100; A jewel 300 that is seated and supported on the jig 200; A light irradiating unit 400 having a wireless receiving unit and a plurality of LEDs 416 mounted on the body 100; And a remote control unit 500 having a wireless transmission unit for controlling the light irradiation unit 400.

Although the body 100 and the jig 200 may be formed as separate bodies, they may be formed as one body. In addition to the ring shown in the figure, the body 100 may include jewelry such as earrings, necklaces, bracelets, It can be applied to all ornaments used.

Jewelry (300) includes both artificial and natural gems such as diamonds, rubies, sapphires, emeralds, crystals, pearls, cubic and the like.

In the drawings, diamonds are shown as jewels 300, and generally, the lower portion of the diamond is processed in a triangular shape so that it can be applied as it is, but it is preferable to cut the diamond flatly as shown in the figure.

1, the jewel 300 may be configured to be inserted at a predetermined depth at an upper end of the body 100, but may be configured to be in contact with the upper surface, And it is not preferable to limit the coupling position therebetween.

The light irradiating unit 400 is mounted on the body 100 and illuminates the LEDs 416 toward the jewel 300. The light irradiating unit 400 irradiates light of the LEDs 416 from the center of the jewel 300 .

As shown in FIGS. 1 and 2, the light irradiation unit 400 includes a first case 410 mounted on the body 100 and opened at a lower portion thereof; An infrared ray receiving unit 411 installed in the first case 410; A first PCB 412 mounted in the first case 410 and connected to the plurality of LEDs 416 and the infrared receiver 411; A second PCB 413 connected to a microcomputer 421 (one-chip microprocessor) for controlling the operation of the LED 416 and electrically connected to the first PCB 412; A battery 414 for applying power to the second PCB 413; And a cover 415 for opening and closing the lower portion of the first case 410.

In addition, a power on / off switch 424 for selectively turning on and off a power source applied to the second battery 413 from the battery 414 may be selectively provided.

It is preferable that the front and rear surfaces of the body part 100 to which the light irradiating part 400 is fastened, that is, the part where the infrared ray receiving part 411 and the power on / off switch 424 are located, are also opened.

The first case 410 may be made of a transparent or opaque material as long as the upper case is opened, but when the upper case is closed as shown in the figure, the first case 410 is made of a transparent material, 300, respectively.

A second PCB 413 is positioned below the first PCB 412 and the first PCB 412 and the second PCB 413 are electrically connected to each other by a support 417.

A microcomputer 421 is mounted on the second PCB 413 and blue and red LEDs 416 are mounted on the first PCB 412.

An infrared receiver 411 and a power on / off switch 424 are connected to the first PCB 412.

The infrared receiver 411 and the power on / off switch 424 protrude to the outside of the first case 410 so as to be exposed to the outside of the body 100, 410).

Although not shown in detail in the case of the power on / off switch 424, the power ON / OFF switch 424 may include a push button that protrudes outward from the body 100 so that the user can touch and operate the push button, It is preferable to configure it as a waterproof button.

The color of the LEDs 416 may be composed of a plurality of colors, and in this specification, blue and red LEDs are applied.

3, a male screw portion is formed on the upper outer circumference of the cover 415, and a female screw is formed on a lower inner circumference portion of the first case 410 so as to be detachably coupled to each other.

Further, it is preferable that the cover 415 is provided with a coupling / separation guide groove 415-1 so as to facilitate detachment.

Although the engaging and detaching guide groove 415-1 is shown in a cross shape on the drawing, it is not preferable to limit the shape and position of the engaging and detaching guide groove 415-1 as long as the engaging and detaching guide groove 415-1 can easily be detached by helical engagement.

Meanwhile, the remote control unit 500 includes a second case 510; An infrared ray transmission unit 520 operating with power supplied and installed in the second case 510; And a plurality of control buttons 530 formed in the second case 510. The control signal generated through the control button 530 is transmitted to the wireless receiving unit 520 through the infrared transmitting unit 520, And is transmitted to the infrared ray receiving unit 411.

The control button 530 includes a power on / off button 531 for turning on / off the power of the remote control unit 500; A mode 1 button 532 for controlling the light emission time and the number of light emission of any one of the LEDs 416; A mode 2 button 533 for controlling the light emission time and the number of light emission of the other one of the LEDs 416; A mode 3 button 534 for simultaneously controlling a light emission time and a light emission number of one and the other; A setting button 535 for setting a mode 1 button 532, a mode 2 button 533, and a mode 3 button 534; And a setting progress button 536 for emitting the LED 416 as set by the mode 1 button 532, the mode 2 button 533 and the mode 3 button 534.

The present invention is characterized in that the light irradiation unit 400 is provided with a microcomputer 421 as a one-chip microprocessor and remotely controls the light irradiation unit 400 through the remote control unit 500 and controls the light irradiation unit 400 to the remote control unit 500 By configuring the plurality of control buttons 530 for controlling, it is possible not only to miniaturize the light irradiation unit 400, but also to perform various controls other than the above control.

In addition, although not shown, if the remote control unit 500 further includes a display unit (not shown) for displaying the operation time of the control button 530, the user can directly check and control the control state, A control function can be performed.

The control method according to one embodiment of the remote control unit 500 will be described in more detail below.

FIG. 4 is a conceptual circuit configuration diagram of a light irradiation unit according to an embodiment of the LED light emission system for remote control of jewelery according to the present invention. Referring to FIG. 4, the light irradiation unit 400 includes a battery 414; A power supply transfer unit 418 for stepping up the power supplied from the battery 414 and transmitting the power supply; An infrared ray receiving unit 411 operated by receiving power supplied through the power transmitting unit 418; A backflow preventing part 419 connected between the power supply transmitting part 418 and the infrared receiving part 411; A voltage stabilizing part 420 connected to the infrared ray receiving part 411 and the backflow prevention part 419; A microcomputer 421 (a one-chip microprocessor) that operates in response to a signal transmitted through an infrared receiver 411 and operates a plurality of LEDs 416; An I / O input / output terminal 422 connected to the microcomputer 421; And a system function switch 423 for operating the light irradiation unit 400.

The battery 414 may be a rechargeable battery, but the first 3 volts of power is applied using two 1.5 volt mercury batteries, and the voltage is increased to 5 volts through the power transfer unit 418 and transferred.

The microcomputer 421 is formed of a one-chip microprocessor, and the system function switch 423 functions as a power on / off switch 424.

The microcomputer 421 can program a series of control operation states related to the light emission of the LED 416 via the infrared input / output terminal 422, and the light emission period and the like of the LED 416 can also be set.

Output function through the I / O input / output terminal 422, the function of the backflow prevention unit 419, and the function of the voltage stabilization unit 420 are well known in the art.

FIG. 5 is a diagram illustrating an LED light emitting method according to an embodiment of the present invention, and FIG. 6 is a flowchart illustrating an LED light emitting method according to an embodiment of the present invention.

Referring to FIGS. 5 and 6, an operation state of an LED light emitting method for remotely controlling a jewelery using an LED light emitting system for remote control of jewelery according to an embodiment will be described as follows.

First, as shown in FIG. 5, a first step S100 of applying power to the light irradiation unit 400 and the remote control unit 500; And a second step S200 of controlling the light irradiating unit 400 through the remote control unit 500. The second step S200 includes a second step S200 for operating the second LED 416, -1 step S210; Step 2-2 (S220) of operating the LED (416) of the other (red); And a second step (S230) of simultaneously operating one (blue) and the other (red) LEDs 416.

A standby signal for operating the selected LED 416 is inputted to each of the 2-1st step S210, the 2-2st step S220 and the 2-3 step S230, (S211, S221, S231); And a lighting time setting step (S214, S224, S234) for inputting a duration time for setting the lighting duration time of the selected LED 416 and ending the duration time duration.

The mode signal input steps S211, S221 and S231 can input a wait signal to the microcomputer 421 by using the mode 1 button 532, the mode 2 button 533 and the mode 3 button 534, The mode 2 button 533 and the mode 3 button 534 in the setting steps S214, S224, and S234.

6, after the lighting time setting step (S214, S224, S234), the number of repetitions is set so that the operation of turning off the selected LED 416 is repeated, and when the number of repetitions is not set (S216, S226, S236) in which the selected LED 416 is turned on and then turned off during the set duration.

The repetition times are set in the microcomputer 421 by using the mode 1 button 532, the mode 2 button 533 and the mode 3 button 534 in the repetition number setting steps S216, S226 and S236.

After the mode signal inputting steps S211, S221 and S231, a setting signal for proceeding to the next step is inputted, and a first setting signal inputting step S212, S222, S232 which is terminated when no setting signal is inputted As shown in FIG.

In addition, after the lighting time setting step (S214, S224, S234), a setting signal for proceeding to the next step is inputted, and the LED 416, which is turned on and off for a predetermined duration time, 2 setting signal inputting steps (S215, S225, S235).

The setting signals are inputted by using the setting button 535 in the first setting signal applying steps (S212, S222, S232) and the second setting signal inputting steps (S215, S225, S235).

After the mode signal inputting steps S211, S221 and S231, the setting mode proceeding steps S213, S223 and S233, which are terminated after the LED 416 selected by the predetermined lighting duration time and the number of repetition times is operated, Can be made larger.

The predetermined lighting duration and the number of times of repetition may be configured to be performed according to the immediately preceding setting or may be performed in accordance with the lighting duration and the number of repetitions set separately through the i.ISP I / O terminal 422. [

On the other hand, it is possible to calculate and calculate the duration of pressing the corresponding button at the time of inputting the duration and the number of repetitions, or to calculate and calculate the number of times the button is pressed.

In addition, it is preferable that, when proceeding to the next step in each of the above steps, it is set to end (end) when there is no input signal for a predetermined time (about several seconds).

Hereinafter, a control method (light emitting method) according to an embodiment of the present invention will be described in connection with the control button 530 of the remote control unit 500 by referring to FIG.

However, since the control method of operating the blue LED, the red LED, and the blue LED and the red LED simultaneously is the same, only the control method for the blue LED will be described.

1) First, the power on / off button 531 of the remote control unit 500 and the power on / off switch 424 of the light irradiation unit 400 are turned on.

2) The mode 1 button 532 is pressed, and when not pressed, it is ended (ended).

3) If the setting button 535 is pressed, the operation proceeds to the lighting time setting steps S214, S224 and S234. If the setting button 535 is not pressed, the operation proceeds to the setting mode proceeding steps S213, S223 and S233.

4) In the lighting time setting steps S214, S224, and S234, when the mode 1 button 532 is pressed for 5 seconds, the blue LED 416 is set to be turned on for 5 minutes and then turned off.

5) If the reset button 535 is pressed, the process can proceed to the repeat count setting step (S216, S226, S236). If the setting button 535 is not pressed,

6) In the repetition number setting step S216, S226, and S236, when the mode 1 button 532 is pressed for 10 seconds, the process of turning off the blue LED 416 for 5 minutes and then turning off is repeated 10 times.

7) The cycle repeated in the process of the above 6) is performed in a predetermined cycle through the I / O input / output terminal 422.

8) On the other hand, if the setting button 535 is not pressed in the process of 3), the user can proceed to the setting mode proceeding step (S213, S223, S233) through the setting proceed button 536. [

9) If the setup progress button 536 is not pressed, the process is terminated. If the setup progress button 536 is pressed, the operation is terminated after the predetermined lighting time and the number of repetitions.

10) The control method using the mode 2 button 533 and the mode 3 button 534 is also the same as described above.

As described above, according to the present invention, the user can selectively use LEDs of various colors at desired locations in a desired time zone, thereby enhancing the convenience of the user and maximizing the brilliance of the worn ornaments.

100: Body part
200: jig
300: Jewelry
400:
410: first case 411: infrared receiver
412: First PCB 413: Second PCB
414: battery 415: cover
415-1: Coupling and separation guide groove 416: LED
417: Support base 418: Power supply unit
419: Reverse flow prevention part 420: Voltage stabilization part
421: Microcomputer 422: iSpy input / output terminal
423: System function switch, power on / off switch
500: remote control unit
510: second case 520: infrared transmitter
530: Control button 531: Power on / off button
532: Mode 1 button 533: Mode 2 button
534: Mode 3 button 535: Setting button
536: Setup progress button
S100: first step S200: second step
S210: Step 2-1: Step S220: Step 2-2
S230: Step 2-3
S211, S221, S231: Mode newlyweds input step
S212, S222, S232: a first setting signal input step
S213, S223, S233: the setting mode progressing step
S214, S224, S234: Lighting time setting step
S215, S225, S235: a second setting signal input step
S216, S226, S236: Repeat number setting step

Claims (17)

Body part; A jig formed on the body portion; A jewel that is seated and supported on the jig; A light irradiating unit having a wireless receiver and a plurality of LEDs mounted on the body; And a remote control unit having a wireless transmission unit and controlling the light irradiation unit,
The light-
A first case mounted on the body part and opened at a bottom; An infrared ray receiving unit installed in the first case; A first PCB installed in the first case and connected to the plurality of LEDs and the infrared receiver; A second PCB connected to a microcomputer or a microprocessor for controlling operation of the LED, and electrically connected to the first PCB; A battery for supplying power to the second PCB; A cover which opens and closes a lower portion of the first case, is detachably coupled to the first case and is provided with a coupling and detaching guide groove; And a power on / off switch for turning on and off a power source applied to the second PCB from the battery,
The colors of the LEDs are composed of a plurality of colors,
The light-
battery; A power supply unit for boosting the power supplied from the battery and transmitting the power; An infrared ray (IR) receiving unit operating with power supplied through the power transmitting unit; A backflow prevention part connected between the power supply part and the infrared receiver part; A voltage stabilizing unit connected to the infrared ray receiver and the backflow prevention unit; A microcomputer or a microprocessor operating with a power supply and operating a plurality of LEDs according to a signal transmitted through the infrared receiver; An I / O input / output terminal connected to the microcomputer, the I / And a system function switch for operating the light irradiation unit,
The remote control unit includes:
A second case; An infrared ray transmission unit operable to receive power, and being installed in the second case; A plurality of control buttons that are operated by receiving power and are formed in the second case; And a display unit for displaying an operation time of the control button, wherein a control signal generated through the control button is transmitted to the wireless receiver through the infrared transmitter,
The control button,
A power on / off button for turning on / off the power of the remote control unit; A mode 1 button for controlling the light emission time and the number of light emission of any one of the LEDs; A mode 2 button for controlling the light emission time and the number of light emission of the other one of the LEDs; A mode 3 button for controlling any one of the above and another emission time and the number of emission; A setting button for setting the mode 1 button, the mode 2 button, and the mode 3 button; And a setting progress button for causing the LED to emit light as set by the mode 1 button, the mode 2 button, and the mode 3 button, and an LED light emission method for remotely controlling the jewelery using the LED light emission system for remotely controlling the jewelery As a result,
A first step of applying power to the light irradiation unit and the remote control unit; And
And a second step of controlling the light irradiation unit through the remote control unit,
The second step comprises:
A second step of operating one of the LEDs; A second step 2-2 of operating another LED; And a second step of operating one of the LEDs and the other LED at the same time,
In each of Steps 2-1, 2-2, and 2-3,
A mode signal input step of inputting a standby signal for operating the selected LED and ending when the standby signal is not inputted; And a lighting time setting step of inputting a duration time for setting the lighting duration time of the selected LED,
After the lighting time setting step,
Setting the number of repetitions so that the operation of turning off the selected LEDs is repeated, setting the number of repetitions when the number of repetitions is not set, and turning on the selected LEDs for the set duration; And a second setting signal input step of inputting a setting signal for proceeding to the next step and lighting the selected LED for the set duration when the setting signal is not inputted,
After the mode signal input step,
A first setting signal input step of inputting a setting signal for proceeding to the next step and ending when the setting signal is not input; And a set-mode-proceeding step of terminating the set-up mode after the selected LED is operated for a predetermined duration and a predetermined number of times. delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete

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