KR20100020825A - System for wireless lighting control using solar cell - Google Patents

Abstract

PURPOSE: A wireless lighting control system using the solar cell is provided to omit the replacement of battery due to the battery consumption by using the optical energy as the operating voltage of the switch. CONSTITUTION: A wireless lighting control system comprises one or more illumination control part and RF switch manipulation part(100). The illumination control part is electrically connected to one or more lighting apparatus. The illumination control part is input the identification code corresponding to each switch by the manipulation of a user. The illumination control part controls the operation of the lighting apparatus according to the switch signal corresponding to the operation state of the wirelessly transmitted lighting apparatus. The RF switch manipulation part comprises one or more switch corresponding to the illumination control part. The RF switch manipulation part wirelessly transmits the switch signal through the switch operation of the user to the illumination control part. The RF switch manipulation part comprises the solar cell(110) changing the light into the electricity.

Description

Wireless lighting control system using solar cells {System for wireless lighting control using solar cell}

The present invention relates to a lighting control system, and more particularly, to a wireless lighting control system using a solar cell to enable the wireless control of the operation control, such as lighting or a fan through a wireless switch operation unit using the solar cell.

In recent years, it has become increasingly common to renovate a building by carrying out interior and renovation (hereinafter, remodeling) while maintaining the basic structure of the building.

However, when remodeling an existing building, it is rare to apply a switch that controls the electrical wiring or operation of lighting and a fan installed in the existing building. This is because the layout of furniture and lighting fixtures changes as the interior space of the remodeled building changes.

1 is a block diagram of a lighting control system according to a first example of the prior art, Figures 2a and 2b is a block diagram of a lighting control system according to a second example of the prior art.

For example, as shown in FIG. 1, the entire space is divided into Zone A and Zone B, and the office in which four lighting fixtures LA1 to LA4 and LB1 to LB4 are installed in each of Zones A and B is remodeled. Or the internal structure is changed, it is changed to Zones A, B and C, and two lighting fixtures (LA1 to LA2, LB1 to LB2) are installed in each of Zones A and B, and four fixtures (LC1 to When the LC4) is installed, the power wiring PLA, PLB, PLC and the switch position SW should be changed as shown in FIGS. 2A and 2B.

That is, as shown in FIG. 2A, the power wires are rearranged so that only the lighting devices LA1 to LA2, LB1 to LB2, and LC1 to LC2 positioned in the areas A, B, and C are respectively connected, or as shown in FIG. 2B. Position and power wiring (PLA, PLB, PLC) must also be relocated.

In this case, the remodeling cost increases because a specialized company for relocating the power wiring and the switch must be installed.

3 is a block diagram of a lighting control system according to a third example of the related art.

If you want to install a new lighting fixture (L) as shown in Figure 3, to install a new switch (SW) for controlling this, and also to install a new signal line (Ctrl) connected thereto, which is material and construction In addition to the difficulties of the construction, there is a problem that hurts the aesthetics after construction.

4 is a block diagram of a lighting control system according to a fourth example of the related art.

As shown in FIG. 4, a motion detection sensor or the like is installed in an external space (for example, a staircase), and a stair lamp L is often controlled through this. In this case, due to the motion detection sensor sen There is a limit to the choice of lamp type, and its lamp life is short, so frequent lamp replacement occurs. At this time, the motion detection sensor and the like are also frequently replaced by a switch. In addition, when the motion detection sensor is replaced with a switch at this time, as described above, a problem arises in that it is difficult to install the power wiring. And since these switches must be connected to the lighting fixtures and wired, there was a problem that you can not move the switch freely.

On the other hand, as the prediction of the depletion of existing energy resources such as oil and coal recently, there is a growing interest in alternative energy to replace them. Among them, solar energy is particularly attracting attention because it is rich in energy resources and has no problems with environmental pollution. There are two ways to use solar energy: solar energy that generates steam required to rotate turbines using solar heat, and solar energy that converts sunlight into electrical energy using the properties of semiconductors. This refers to a solar cell (hereinafter, referred to as a "cell").

Such solar cells have been used in various fields, and among them, they are widely used as a means of replacing batteries used in simple electronic devices. In the case of batteries, the capacity of the battery is limited, and the use time is limited, and after using the battery for some time, it is inconvenient to replace the battery or to charge the battery by connecting an external power source with another device. Because it generates power, it can be used semi-permanently. It is necessary to find a way to make the solar cell with such many advantages available in various fields.

The present invention has been made to solve the above problems, to provide a wireless lighting control system using a solar cell that can control the operation of the lighting control system wirelessly through a wireless switch operation unit using a solar cell. have.

In order to achieve the above object, the wireless lighting control system using the solar cell according to the present invention, in the wireless lighting control system for controlling the operation of the lighting equipment through a wireless signal, is electrically connected to at least one lighting equipment At least one lighting control unit controlling an operation of the lighting device according to a switch signal that specifies an operation state of the lighting device that is received wirelessly and receives an identification code corresponding to each switch by a user's operation; And at least one switch corresponding to each of the at least one lighting controller, and generating and transmitting wirelessly a switch signal including operation state information specific to the lighting controller to be controlled by the user's manipulation of the switch. It includes; wireless switch operation unit, wherein the wireless switch operation unit is characterized in that it comprises a solar cell for converting light into electricity.

Preferably, the wireless switch operation unit, the solar cell is installed to be exposed to the outside to convert the incident light into electrical energy; A solar cell power supply unit configured to output electric energy converted from the solar cell to a driving power source of the wireless switch operation unit; A switch unit which specifies an operating state of the luminaire; A switch signal generator configured to generate the switch signal including an operating state of the switch; An identification code transmitter for transmitting a unique identification code of the wireless switch operation unit; And a wireless transmitter for transmitting the switch signal to an illumination controller corresponding to the switch.

In the present invention, the identification code transmitter may be separately provided outside the wireless switch operation unit to specify a unique identification code of at least one wireless switch operation unit, and then transmit the specified unique identification code.

In the present invention, the operating state of the luminaire is specified by the turn on-off operation of the switch or the light intensity control.

Preferably, the wireless switch operation unit, a solar cell power detection unit for checking whether the driving power output from the solar cell power source; And an auxiliary battery for assisting the solar cell power supply unit. When the driving power is not output from the solar cell power supply unit, the driving power may be output from the auxiliary battery.

Preferably, the solar cell power supply unit may further include energy storage means for storing the electric energy converted from the solar cell, and output the electric energy stored in the energy storage means as a driving power source.

Preferably, each of the at least one lighting control unit, the wireless receiving unit for receiving and demodulating the switch signal wirelessly received from the wireless switch operation unit; A connection code setting unit receiving an identification code corresponding to the switch controlling the at least one lighting control unit; A memory unit for storing an identification code and an operation state inputted through the connection code setting unit; A signal analysis unit for extracting an operation state signal of the switch from the demodulated switch signal from the wireless receiver, and generating a control signal specifying the operation state of the luminaire by comparing the extracted operation state signal with the operation state stored in the memory; An illumination power control unit controlling an operation state of each of the at least one lighting device according to a control signal of the signal analysis unit; And a power supply unit receiving the indoor power and outputting driving power of the lighting controller from the indoor power.

In the present disclosure, the lighting power control unit turns on or off each of the at least one lighting device according to the comparison result.

In the present invention, each of the at least one lighting control unit further includes a manual operation unit for allowing a user to manually control the operating state of the lighting fixture.

Preferably, each of the at least one wireless switch operation unit may be composed of a wireless switch operation unit body installed so that the solar cell is exposed to the outside, and a cradle for fixing the wireless switch operation unit body on the wall of the home, the wireless switch operation unit body Can be attached or detached to the cradle.

According to the present invention, it is very easy to change the space zone arrangement or to change the position of the switch, and the cost according to the installation can be made low. In addition, by using semi-permanent optical energy as the operation power of the switch, there is no need to add a separate battery, there is no need to purchase a battery, there is an effect that does not need to replace the battery due to battery consumption.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, the terms or words used in this specification and claims should not be construed as being limited to their usual or dictionary meanings, and the inventors will properly describe the concept of terms in order to best explain their own design. Based on the principle that it can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

5 is an overall configuration diagram of a wireless lighting control system using a solar cell according to the present invention, Figure 6 is a block diagram showing the configuration of a wireless switch operation unit according to the present invention, Figure 7 is a lighting control unit of the present invention It is a block diagram which shows a structure.

Referring to the drawings, the wireless light control system using a solar cell according to the present invention comprises a wireless switch operation unit 100 and the lighting control unit 200.

The wireless switch operation unit 100 may be freely changed in the installation position by the user, and operates with a driving power source obtained from the solar cell 110 for converting light into electrical energy. The wireless switch operation unit 100 generates a switch signal having an operation state by a user's operation and transmits a wireless signal to the lighting control unit 200 corresponding to the wireless switch operation unit 100.

The lighting control unit 200 may be composed of at least one, each lighting control unit 200 may be at least one lighting device 300 is electrically connected, that is, wired. The lighting control unit 200 receives an identification code corresponding to each switch by the user's operation from the wireless switch operation unit 100 and according to a switch signal specifying an operation state of the lighting apparatus 300 which is wirelessly transmitted. The operation of the 300 is controlled.

Hereinafter, the function of each component will be described in more detail.

As shown in FIG. 6, the wireless switch operation unit 100 includes a solar cell 110, a solar cell power supply unit 120, a solar cell power detection unit 130, an auxiliary battery 140, a switch unit 150, The switch signal generator 160, the identification code transmitter 170, and the wireless transmitter 180 are included.

The solar cell 110 is installed to be exposed to the outside to convert the incident light into electrical energy.

The solar cell power supply unit 120 outputs the electric energy converted from the solar cell 110 as the driving power of the wireless switch operation unit 100. The solar cell power supply unit 120 has a structure in which driving power can be continuously output under a condition in which electrical energy can be converted in the solar cell 110. Through this, it is possible to immediately provide driving power when the wireless switch operation unit 100 is operated by the user. This is because the power used to operate the wireless switch operation unit 100 is sufficient because only a small power is sufficient to operate the wireless switch operation unit 100 even without a separate circuit.

Alternatively, the solar cell power supply unit 120, the energy storage means for storing the electric energy converted from the solar cell 110 (not shown) and the charging control to control the electrical energy is stored in the energy storage means A circuit (not shown) may be further included, and the electrical energy stored in the energy storage means may be output as a driving power source. Here, a supercapacitor may be used as the energy storage means. However, the present invention is not limited by the energy storage means, and it is apparent that various devices capable of charging and discharging electrical energy may be used. In this case, the operating power can be more stably provided to the wireless switch operation unit 100.

The solar cell power detector 130 checks whether the driving power is output from the solar cell power source 120. This is because when the ambient light incident on the solar cell 110 in the surrounding environment of the wireless switch operation unit 100 is not sufficient, the amount of electric energy converted is not enough, so that the driving power cannot be output from the solar cell power supply unit 120. This will be detected.

If it is determined that the driving power of the solar cell power unit 120 is not output by the solar cell power detector 130, the solar cell power detector 130 is additionally installed to assist the solar cell power source 120. The driving power for driving the wireless switch operation unit 100 is output from the battery 140. Through this, it is possible to secure the operability of the wireless switch operation unit 100 without abnormality even in a situation where the optical energy cannot be obtained. On the other hand, the auxiliary battery 140 is composed of a secondary battery capable of charging and discharging so that it is possible to charge the driving power supplied from the solar cell power supply unit 120 while the wireless switch operation unit 100 is not operated. .

In the present invention, a driving power source for driving the wireless switch operation unit 100 through the solar cell 110, the solar cell power supply unit 120, the solar cell power detector 130 and the auxiliary battery 140, which are the aforementioned components. Outputs The reason why the driving power is supplied to the above-described components is to allow the wireless switch operation unit 100 to have mobility by not using the indoor power. In addition, by using semi-permanent optical energy through the solar cell 110 without using a general battery, there is no need to purchase a battery additionally, there is no need to replace the battery due to battery consumption can be conveniently used.

The switch unit 150 corresponds to each of the at least one lighting control unit 200, and has a mechanical or electronic switch that can be switched on or off by a user. Accordingly, when the user wants to operate the lighting device 300 controlled by the specific lighting control unit 200, the user inputs an identification code corresponding to the switch unit 150 to each lighting control unit 200 and the switch unit 150. ), The switch unit 150 wirelessly transmits a control signal to the corresponding lighting control unit 200.

The switch unit 150 corresponds to each of the at least one lighting control unit 200 and includes a mechanical or electronic switch to be switched on or off by a user. Accordingly, when the user wants to operate the lighting device 300 controlled by the specific lighting control unit 200, the user inputs an identification code corresponding to the switch unit 150 in advance to the corresponding lighting control unit 200 to switch unit ( 150 and the lighting control unit 200 are connected. Thereafter, when the user manipulates the switch unit 150, the switch unit 150 sends a switch signal for instructing an operation state of the lighting device 300 to the lighting control unit 200 corresponding to the switch unit 150. Transmit wirelessly.

That is, when the position of the lighting device 300 needs to be changed, such as when the internal structure of the office is changed, the user inputs an identification number of a switch to control the lighting control unit 200 to the lighting control unit 200 to illuminate the lighting. By connecting and controlling the corresponding switch of the control unit 200 and the switch unit 150, it is possible to reset the wireless switch operation unit 100 and the lighting control unit 200 to be controlled in accordance with the changed position in the office in the desired position The lighting fixture 300 can be turned on or off.

The switch signal generator 160 checks an operating state of each of the at least one switch and then generates a switch signal including the operating state. In this case, the operating state may be a turn on-off operation of the switch or adjustment of the light intensity.

The identification code transmitter 170 transmits the unique identification code of each switch configured in the wireless switch operation unit 100 to the corresponding lighting control unit 200.

On the other hand, the identification code transmitter 170 may be provided separately from the outside without being embedded in the wireless switch operation unit 100. In this case, the identification code transmitter 170 specifies a unique identification code to at least one switch, and then transmits the unique identification code to the lighting control unit 200 corresponding to the switch in which the identification code is specified. Such a configuration has an advantage of providing an identification code to the plurality of wireless switch operation units 100 and the lighting control unit 200 even with only one identification code transmitter 170.

The wireless transmitter 180 modulates an operation state signal generated by the switch signal generator 160 to a signal form capable of wireless transmission, and then transmits the signal to the corresponding lighting controller 200 through an antenna. do.

Each lighting control unit 200 is installed to be adjacent to at least one lighting device 300 to be controlled and is electrically connected by wire, and receives and modulates a switch signal wirelessly transmitted from the wireless switch operation unit 100 to provide lighting devices ( The operating state of 300 is directly controlled. In this case, the operating state of the lighting device 300 is specified by the turn on-off operation of the switch or the light intensity control, and the lighting device 300 is operated to correspond to the operating state.

As shown in FIG. 7, the lighting controller 200 includes a wireless receiver 210, a signal analyzer 220, a memory 230, an illumination power controller 240, a power supply 250, and a manual operation unit 260. ) And a connection code setting unit 270.

The wireless receiver 210 receives a switch signal transmitted wirelessly from the wireless switch operation unit 100, demodulates the signal into a signal form that can be recognized by the signal analyzer 220, and provides the signal to the signal analyzer 220. do.

The signal analyzer 220 extracts an operating state signal of a switch from a switch signal demodulated from the wireless receiver 210, and compares the extracted operating state signal with an operating state stored in the memory unit 230. Generate a control signal to change the operating state of 300. That is, the signal analyzer 220 compares the operation state signal of the switch and the operation state stored in the memory unit 230, and when it is determined that the operation states are different from each other, the lighting device 300 controlled by the lighting control unit 200. Generates a control signal for varying the operating state of the switch to the operating state specified by the switch. If the operation state signal of the switch and the operation state stored in the memory unit 230 are the same as each other, the signal analyzer 220 does not separately generate a control signal.

The memory unit 230 stores an identification code corresponding to a unique identification code of each switch and an operating state of the lighting device 300 currently set by the lighting power control unit 240.

The lighting power control unit 240 turns on or off the corresponding luminaire 300 controlled by the lighting control unit 200 according to a control signal generated by the signal analysis unit 220.

The power supply unit 250 is connected to the home power supply from the distribution panel (not shown), and supplies it to the driving power of the lighting control unit 200.

In addition, the manual operation unit 260 is further provided to allow the user to directly control the operating state of the lighting device 300 connected to the lighting control unit 200 manually.

The connection code setting unit 270 receives an identification code corresponding to a unique identification code of each switch and stores it in the memory unit 230.

8 is a perspective view schematically illustrating a wireless switch operation unit according to a first embodiment of the present invention, and FIG. 9 is a perspective view schematically illustrating a wireless switch operation unit according to a second embodiment of the present invention.

As shown in FIG. 8, the wireless switch operation unit 100 according to the first embodiment of the present invention is configured in the same form as a conventional general switch means. The switch unit 150 and the solar cell 110 are installed in the wireless switch operation unit body 101. The solar cell 110 is exposed to the outside is preferably installed at a position where the light can be incident well. In addition, although only one solar cell 110 is illustrated in FIG. 8, it is apparent that one or more solar cells 110 may be installed. In addition, the antenna (not shown) for transmitting a wireless signal is built in the wireless switch operation unit main body 101 to enable wireless transmission of the switch signal generated by the wireless switch operation unit 100. However, the antenna for transmitting the wireless signal is not limited to this example, and the antenna may be configured to protrude to the outside.

As shown in FIG. 9, the wireless switch operation unit 100 according to the second embodiment of the present invention is a cradle 102 for fixing the wireless switch operation unit main body 101 and the wireless switch operation unit main body 101 to a wall surface. It is composed. The switch unit 150 and the solar cell 110 are installed in the wireless switch operation unit body 101. The wireless switch operation unit 100 according to the second embodiment differs only in form, and internal components and operation methods thereof are substantially the same as in the first embodiment. On the other hand, the wireless switch operation unit body 101 is removable from the cradle (102). Through this, the wireless switch operation unit main body 101 can move freely under the position capable of transmitting a wireless signal to the lighting control unit 200 and control the operating state of the lighting device 300.

As described above, the wireless lighting control system using the solar cell according to the present invention includes a wireless switch operation unit 100 and at least one lighting control unit 200 that communicate wirelessly, thereby controlling the operation state of the lighting device 300. can do. In addition, by adopting a solar cell that can convert light into electrical energy, it is not necessary to use a battery, which is an external power source for a general wireless control device. This eliminates the need for electrical wiring for connecting the switch and the luminaire unlike the prior art.

In addition, in the above embodiment, only one lighting control unit corresponds to one switch, but a plurality of lighting apparatuses are connected to one switch, and it is also possible to apply a plurality of lighting apparatuses and control the lighting apparatus. It is also possible to control one or more luminaires with a switch.

Hereinafter, by presenting various application examples of the present invention to help the understanding of the present invention.

FIG. 10 is a first application example of the present invention, and FIGS. 11A to 11B are diagrams illustrating a wireless lighting control system according to a second application example.

Referring to the drawings, the eight lighting control units corresponding to each of the eight lighting devices (431 to 438) 421 to 428, the wireless having a switch for controlling the eight lighting control units (421 to 428) The switch operation unit 410 is installed.

In addition, as shown in FIG. 10, the entire space is divided into two zones A and B, and the operation state of all the lighting fixtures 431 to 438 installed in these two zones can be controlled through the switches of the wireless switch operation unit 410. It may be.

As shown in FIG. 11A, even if the entire space is divided into three zones A, B, and C, the power wiring is not rearranged, and only the identification codes of the eight lighting controllers 421 to 428 installed in the three zones are changed. Three switches can be used to control the operating states of all the lighting fixtures 431 to 438 installed in these three zones.

In addition, as shown in FIG. 11B, when a new door is installed, the user may rearrange the wireless switch operation unit 410 to be adjacent to the new door without additional installation.

12 is a view showing a wireless lighting control system according to a modification of the second application of the present invention.

Referring to the drawings, the entire space is divided into three zones A, B, and C so as to be able to simultaneously control the lighting fixtures 531 to 538 installed in these zones.

That is, the lighting control unit 521 connected to the lighting fixtures 531 and 532 installed in the A zone, the lighting control unit 2 522 connected to the lighting fixtures 533 and 534 installed in the B zone, and the lighting fixture 538 installed in the C zone. The lighting control unit 3 (523) connected to the), the wireless switch operation unit 510 is provided with three switches (SWA ~ SWC) corresponding to each of the lighting control unit (521 ~ 523).

As a result, by controlling each of the three switches, it is possible to simultaneously control the luminaire for each zone.

13 is a view showing a wireless lighting control system according to a third application of the present invention. The present invention inputs identification codes for two or more switches in one luminaire and controls the lighting control unit through each switch corresponding to the input identification code.

14 is a diagram showing a wireless lighting control system according to a fourth application of the present invention. This relates to the installation of a wireless lighting control system when installing a new luminaire.

As shown in FIG. 14, when installing a new luminaire 630 in a new area, the wireless switch operation unit 610 is installed where the user wants, and the lighting control unit 620 is connected to the luminaire 630. After that, only the home power is supplied to them, thereby completing the installation of the wireless lighting control system.

Therefore, according to the wireless lighting control system of the present invention it can be seen that the installation of a new light is much easier than the conventional.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto and is intended by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

The following drawings attached to this specification are illustrative of the preferred embodiments of the present invention, and together with the detailed description of the present invention serves to further understand the technical spirit of the present invention, the present invention is a matter described in such drawings It should not be construed as limited to.

1 is a block diagram of a lighting control system according to a first example of the related art.

2A and 2B show a block diagram of a lighting control system according to a second conventional example.

3 is a block diagram of a lighting control system according to a third example of the related art.

4 is a block diagram of a lighting control system according to a fourth example of the related art.

5 is an overall configuration diagram of a wireless lighting control system using a solar cell according to the present invention.

6 is a block diagram showing the configuration of a wireless switch operation unit according to the present invention.

7 is a block diagram showing the configuration of a lighting control unit according to the present invention.

8 is a perspective view schematically illustrating a wireless switch operation unit according to a first embodiment of the present invention.

9 is a perspective view schematically illustrating a wireless switch operation unit according to a second embodiment of the present invention.

10 is a diagram illustrating a wireless lighting control system according to a first application example of the present invention.

11A to 11B are diagrams illustrating a wireless lighting control system according to a second application example of the present invention.

12 is a view showing a wireless lighting control system according to a modification of the second application of the present invention.

13 is a view showing a wireless lighting control system according to a third application of the present invention.

14 is a view showing a wireless lighting control system according to a fourth application of the present invention.

Claims (10)

In the wireless lighting control system for controlling the operation of the lighting fixture through a wireless signal, Electrically connected to at least one lighting fixture, and receives an identification code corresponding to each switch by a user's operation to control the operation of the lighting fixture according to a switch signal that specifies the operating state of the lighting fixture transmitted wirelessly At least one lighting control unit; And Wireless at least one switch corresponding to each of the at least one lighting control unit for generating and transmitting a switch signal including the operation state information specified to the lighting control unit to be controlled by the user's operation of the switch; Including; switch operation unit, The wireless switch control unit is a wireless light control system using a solar cell, characterized in that it comprises a cell for converting light into electricity. The method of claim 1, The wireless switch operation unit, A solar cell installed to be exposed to the outside to convert incident light into electrical energy; A solar cell power supply unit configured to output electric energy converted from the solar cell to a driving power source of the wireless switch operation unit; A switch unit which specifies an operating state of the luminaire; A switch signal generator configured to generate the switch signal including an operating state of the switch; An identification code transmitter for transmitting a unique identification code of the wireless switch operation unit; And And a wireless transmitter for transmitting the switch signal to a lighting control unit corresponding to the switch. The method of claim 2, The identification code transmitter, A wireless lighting control system using a solar cell, which is provided separately outside the wireless switch operation unit, specifies a unique identification code on at least one switch, and then transmits a specific unique identification code. The method of claim 2, The operating state of the lighting fixture, Wireless lighting control system using a solar cell characterized in that it is specified by the turn on-off operation of the switch or light intensity control. The method of claim 2, In the wireless switch operation unit, A solar cell power detector for checking whether the driving power is output from the solar cell power source; And Further comprising a secondary battery to assist the solar cell power supply, The driving power is output from the auxiliary battery when the driving power is not output from the solar cell power supply unit. The method of claim 2, The solar cell power supply unit, Energy storage means for storing electrical energy converted from the solar cell; And Further comprising a charging control circuit for controlling the electrical energy is stored in the energy storage means, Wireless lighting control system using a solar cell, characterized in that for outputting the electric energy stored in the energy storage means as a driving power source. The method according to claim 5 or 6, Each of the at least one lighting control unit, A wireless receiver configured to receive and demodulate the switch signal wirelessly received from the wireless switch operator; A connection code setting unit receiving an identification code corresponding to the switch controlling the at least one lighting control unit; A memory unit for storing an identification code and an operation state inputted through the connection code setting unit; A signal analysis unit for extracting an operation state signal of the switch from the demodulated switch signal from the wireless receiver, and generating a control signal specifying the operation state of the luminaire by comparing the extracted operation state signal with the operation state stored in the memory; An illumination power control unit controlling an operation state of each of the at least one lighting device according to a control signal of the signal analysis unit; And An illumination power control unit comparing the extracted operation state signal with an operation state signal stored in the memory unit and controlling an operation state of each of the at least one lighting device according to a comparison result; And Wireless power control system using a solar cell, characterized in that it comprises a; power supply for outputting the driving power of the lighting control unit from the indoor power supplied to the indoor power. The method of claim 7, wherein The lighting power control unit, According to the result of the comparison, the wireless lighting control system using a solar cell, characterized in that each of the at least one lighting fixture to turn on or off. The method of claim 8, Each of the at least one lighting controller Wireless lighting control system using a solar cell further comprises a manual operation unit for allowing a user to manually control the operating state of the lighting fixture. The method of claim 9, Each of the at least one wireless switch operation unit A wireless switch operation unit body installed so that the solar cell is exposed to the outside; It consists of a cradle that fixes the main body of the wireless switch control panel on the wall of the house, The wireless switch control unit main body is a wireless lighting control system using a solar cell, characterized in that the mounting or detachable to the cradle.

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