KR102426505B1 - Wireless control lighting system for underground common duct - Google Patents

Abstract

A wireless control lighting system for an underground common duct is provided. According to the characteristics of the present invention, the wireless control lighting system for an underground common duct comprises: lighting devices (100) spaced apart at regular intervals along a longitudinal direction of an underground common duct (10) inside the underground common duct (10), performing a switch-on motion and a switch-off motion according to a wireless control signal input, and divided and grouped into a plurality of integrated control groups (G1 to G3); and a wireless switch module (200) disposed at start and end positions of each integrated control group (G1 to G3) inside the underground common conduit (10) and controlling the lighting of the lighting device (100) included in each integrated control group (G1 to G3) while outputting a wireless control signal according to a user manipulation, wherein the wireless switch module (200) selectively controls the lighting devices (100) of each integrated control group (G1 to G3) by outputting wireless control signals (A, B) having different characteristics and set for each integrated control group (G1 to G3). The wireless control lighting system significantly reduces construction cost and construction time and prevents unintentional switching-on/off of the lighting devices included in an adjacent integrated control group.

Description

Wireless control lighting system for underground common areas

The present invention relates to a wirelessly controlled lighting system for an underground tunnel installed in the underground tunnel and used to illuminate the interior, and more particularly, wirelessly each lighting devices spaced apart at regular intervals along the length extended inside the underground tunnel. It relates to a wireless control lighting system for an underground common area that can control lighting with a control signal.

In general, the Ground Common Duct is designed to improve the aesthetics of the ground by accommodating underground facilities such as electricity, gas, and water supply facilities, communication facilities, and sewage facilities. It refers to the facility installed in

In addition, referring to FIG. 1 , a plurality of lighting devices 20 are arranged at intervals of about 4 m to 5 m along the extended length in the underground cavity 10 to provide lighting to work in the internal space, and approximately The light-off switch 30 was disposed at the beginning and the end at intervals of 100 m to 300 m, respectively, so that the lighting devices 20 included in each interval could be integratedly turned on and off at the beginning and end positions.

However, as shown in the drawing, since the signal line (3 way switch construction) for connecting the circuit for operating the turn-off switch 30 and each lighting device 20 at the beginning and the end must be installed together, the lighting system There was a problem in that the construction cost and construction time for building the In addition, in the case of public facilities, there is a problem in that the safety inspection is increased because the signal line is also reflected as an item of the safety inspection since periodic safety inspections are performed for each set period.

Registered Patent Publication No. 10-1272485 (2013.06.03), waterproof LED lighting device for underground power outlets and underground common areas.

The present invention was created to solve the above problems, and an object of the present invention is to classify each lighting device installed in an underground common area into a set integrated control group unit and control the lighting by a wireless control method, so that the lighting system can be built. The cost and construction time can be greatly reduced, and each lighting device can be controlled using different wireless control signals between adjacent integrated control groups. An object of the present invention is to provide a wireless control lighting system for an underground common area that can be prevented from being turned on and off unintentionally.

According to a feature of the present invention, a plurality of underground tunnels 10 are arranged at regular intervals along the lengthwise direction in which the underground tunnels 10 are extended, and light-on and light-off operations are performed according to an input radio control signal, and a plurality of The lighting device 100 is divided and grouped into an integrated control group (G1 to G3); and the lighting included in each integrated control group (G1 to G3) while outputting a wireless control signal according to user manipulation by being disposed at the start position and the end position of each integrated control group (G1 to G3) in the underground common area (10) A wireless switch module 200 for controlling the lighting of the device 100; includes, wherein the wireless switch module 200 includes wireless control signals (A, B) having different wireless characteristics set for each integrated control group (G1 to G3) ) is output to provide a wireless control lighting system for underground common areas, characterized in that the lighting devices 100 of each integrated control group (G1 to G3) are selectively turned on.

According to another feature of the present invention, the lighting device 100 is grouped into a plurality of integrated control groups (G1 to G3) according to a criterion set by reflecting the wireless coverage distance (D) of the wireless control signal. A wireless control lighting system for underground common areas is provided.

According to another feature of the present invention, each wireless switch module 200 outputs a wireless control signal of the Zigbee communication method having a 2.4 GHz band to control lighting of each lighting device 100, but each integrated control group (G1) It is characterized in that the lighting devices 100 of each integrated control group (G1 ~ G3) are selectively controlled by outputting a wireless control signal having a different control code for each ~G3 or a wireless control signal having a different frequency value. A wireless control lighting system for underground common areas is provided.

According to another feature of the present invention, the wireless switch module 200 is fixedly installed between two adjacent integrated control groups (G1, G2) in the underground common area 10, and one integrated control according to user operation. Outputting a first wireless control signal for lighting control of the lighting devices 100 of the group G1 or a second wireless control signal for lighting control of lighting devices 100 of the other integrated control group G2 A wireless control lighting system for an underground common area is provided.

According to another feature of the present invention, the wireless switch module 200 is configured to generate a first operation button 211 for generating a first user input signal according to a user operation and a second user input signal according to a user operation. and a manipulation unit 210 including a second manipulation button 212, and outputs the first wireless control signal when the first user input signal is generated and the second wireless control when the second user input signal is generated There is provided a wirelessly controlled lighting system for an underground common area, characterized in that it outputs a signal.

According to another feature of the present invention, the lighting devices 100 included in each integrated control group (G1 to G3) sequentially follow the set lighting direction (W) when a wireless control signal is input from the wireless switch module (200). There is provided a wireless control lighting system for an underground common area, characterized in that the relay lighting operation.

According to another feature of the present invention, the lighting devices 100 included in each integrated control group (G1 to G3) are individually turned on when the set delay time elapses when the wireless control signal is input. The delay time is provided with a wireless control lighting system for an underground common area, characterized in that it is set to gradually become longer in the set lighting direction (W).

According to another feature of the present invention, the first lighting device 100a closest to the wireless switch module 200 among the lighting devices 100a to 100c included in each integrated control group G1 to G3 is the wireless When the wireless control signal (A) for lighting is input from the switch module 200, the second lighting is directed toward the adjacent second lighting device 100b in the lighting direction (W) set at the time when the set delay time elapses while the lighting operation is performed. Outputs a wireless control signal A1 for turning on the device 100b, and when the wireless control signal A1 is input, the second lighting device 100b turns on the lighting direction when a set delay time elapses. A wireless control signal A2 for turning on the third lighting device 100c is output toward the third lighting device 100c adjacent to (W), and the third lighting device 100c receives a wireless control signal A2. ) is input, a wireless control signal (A3) for turning on the fourth lighting device 100d toward the fourth lighting device 100d adjacent in the lighting direction W when the set delay time elapses while the lighting operation is performed There is provided a wireless control lighting system for an underground common area, characterized in that it outputs.

Meanwhile. According to another feature of the present invention, the wireless control signal A1 has a wireless communication distance D3 greater than or equal to a distance that can be input to the third lighting device 100c, and the third lighting device 100c If the wireless control signal A2 of the second lighting device 100b is not input within the set waiting time in a state in which the wireless control signal A1 of the first lighting device 100a is input, the fourth lighting device 100b automatically turns on. There is provided a wireless control lighting system for an underground common area, characterized in that outputting a wireless control signal (A3) toward the lighting device (100d).

As described above, according to the present invention,

First, the lighting device 100 is spaced apart at regular intervals along the longitudinal direction in which the underground tunnel 10 is extended inside the underground tunnel 10, and turns on and turns off according to the input radio control signal. is divided into integrated control groups (G1 to G3) of While outputting a wireless control signal according to the lighting control of the lighting device 100 included in each integrated control group (G1 ~ G3), but the wireless control signal (A) of different wireless characteristics set for each integrated control group (G1 ~ G3) By outputting ,B) and selectively lighting-controlling the lighting devices 100 of each integrated control group (G1 to G3), the wireless control signal for lighting control of the lighting devices 100 included in an arbitrary integrated control group is applied. Accordingly, it is possible to prevent the lighting devices 100 of the adjacent integrated control group from being unintentionally turned on or off.

Second, the wireless switch module 200 is fixedly installed between two adjacent integrated control groups G1 and G2 in the underground common area 10, and the lighting device of one integrated control group G1 according to the user's operation By outputting a first wireless control signal for lighting control of 100 or a second wireless control signal for lighting control of lighting devices 100 of another integrated control group G2, the two integrated control groups G1, G2) of the lighting device 100 can be turned on and off, respectively, and the number of wireless switch modules 200 that must be installed at the same time can be reduced by half, thereby significantly reducing system construction costs and maintenance costs.

Third, the wireless switch module 200 includes a first operation button 211 for generating a first user input signal according to a user operation and a second operation button 212 for generating a second user input signal according to a user operation. and a manipulation unit 210 comprising: outputting the first wireless control signal when the first user input signal is generated It is possible to turn on and off the lighting device 100 of the desired integrated control group (G1 to G3) by operation, thereby maximizing the user's convenience.

Fourth, the lighting devices 100 included in each integrated control group (G1 to G3) sequentially relay lighting operation along the set lighting direction (W) when a wireless control signal is input from the wireless switch module 200. The lighting devices 100 of the corresponding integrated control group G1 to G3 can be integrated lighting control with the current value.

Fifth, among the lighting devices 100a to 100c included in each integrated control group G1 to G3, the first lighting device 100a closest to the wireless switch module 200 is turned on from the wireless switch module 200. When a wireless control signal (A) for outputs a wireless control signal A1 for A wireless control signal A2 for turning on the third lighting device 100c is output toward the third lighting device 100c, and the third lighting device 100c turns on when the wireless control signal A2 is input. When the set delay time elapses, a wireless control signal A3 for turning on the fourth lighting device 100d is output toward the fourth lighting device 100d adjacent in the lighting direction W, but the wireless control The signal A1 has a wireless coverage distance D3 greater than or equal to a distance that can be input to the third lighting device 100c, and the third lighting device 100c receives a wireless control signal ( If the wireless control signal A2 of the second lighting device 100b is not input within the set waiting time while A1) is input, the wireless control signal A3 toward the fourth lighting device 100d while turning on automatically. ), even if any of the lighting devices 100a to 100d of the corresponding integrated control group fails to output the wireless control signal A2 due to a failure in the subsequent lighting devices 110c and 100d) It is possible to control the lighting in the relay method, so that it is possible to prevent in advance a situation in which lighting control of the other lighting devices 100c and 100d is not possible due to a failure of one lighting device 100b.

1 is a side view showing the configuration of a wirelessly controlled lighting system according to the prior art;
2 is a side view showing the configuration of a wireless control lighting system for an underground common area according to a preferred embodiment of the present invention;
3 is a side view showing a configuration for controlling lighting by placing a wireless switch module between each integrated control group according to a preferred embodiment of the present invention;
4 is a perspective view showing the configuration of a lighting device according to a preferred embodiment of the present invention;
5 is a block diagram showing a functional configuration of a lighting device according to a preferred embodiment of the present invention;
6 is a side view showing the configuration of a wireless switch module according to a preferred embodiment of the present invention;
7 is a block diagram showing a functional configuration of a wireless switch module according to a preferred embodiment of the present invention;
8 is a side view showing a configuration in which radio control signals having different radio characteristics are output for each radio switch module according to a preferred embodiment of the present invention;
9 is a side view showing a configuration in which two wireless switch modules are matched for each integrated control group according to a preferred embodiment of the present invention;
10 is a side view showing a configuration in which lighting devices according to a preferred embodiment of the present invention are individually controlled to be turned on in a relay manner while individually delayed lighting;
11 is a side view showing a configuration in which a lighting device according to a preferred embodiment of the present invention is controlled to light in a relay manner while transmitting a wireless control signal with delay;
12 is a side view illustrating a configuration in which a subsequent lighting device is automatically controlled to be turned on when an arbitrary lighting device fails in the relay method of FIG. 11 .

The objects, features and advantages of the present invention described above will become more apparent through the following detailed description. Hereinafter, a preferred embodiment of the present invention will be described based on the accompanying drawings.

The wireless control lighting system for an underground common area according to a preferred embodiment of the present invention can control lighting in a wireless control method by dividing each lighting device installed in the underground common area into a set integrated control group unit, thereby reducing the construction cost and Construction time can be greatly reduced, and each lighting device can be turned on and controlled using different wireless control signals between adjacent integrated control groups. As a lighting system capable of preventing from being turned on and off inadvertently, it includes a lighting device 100 and a wireless switch module 200 as shown in FIG. 2 .

First, the lighting device 100 is a light source means for providing illumination light for illuminating the inside of the underground cavity 10, and at regular intervals along the longitudinal direction in which the underground cavity 10 extends inside the underground cavity 10. It is spaced apart and operates to turn on and off according to an input radio control signal, and is divided into a plurality of integrated control groups (G1 to G3) and grouped.

Here, the predetermined interval at which each lighting device 100 is spaced apart can be adjusted according to the length of the inner space height or width of the underground cavity 10, and the light distribution range of the lighting device 100, and the average underground cavity 10 and Considering the standard of the lighting device 100, it is preferably determined within the range of about 4m to 5m.

In addition, the criteria for setting the plurality of integrated control groups (G1 to G3) may be determined by reflecting the wireless coverage distance (D) of the wireless control signal output from the wireless switch module 200, and the top and bottom left and right are cement walls. Considering an environment in which a power line and a communication line that is shielded and generates electromagnetic waves capable of distorting a radio signal are installed, it is preferable to set a distance relatively shorter than the radio coverage distance (D). In addition, in addition to the wireless communication distance (D), the standard is adjusted according to the structure (section division and intersection) of the underground tunnel 10, the distance between each lighting device 100, or the location of each entrance in the underground tunnel 10 it might be Considering the wireless communication environment of a typical underground tunnel, it is preferable to set it within the range of about 100m to 300m.

Here, each integrated control group (G1 to G3) is grouped according to the location of dividing a section preset in the underground common area 10 in addition to the wireless communication distance D, or according to the location of the entrance arranged in the underground common area 10 You can also set standards.

In addition, as shown in Figs. 4 and 5, the lighting device 100 is a signal connection between the LED module 110 that emits illumination light according to the driving power applied to the inside of the main body, and the wireless switch module 200. The device communication unit 120 for the device communication unit 120, the device control unit 130 for controlling the lighting so that the LED module 110 is selectively turned on or off according to the wireless control signal of the wireless switch module 200 input to the device communication unit 120, and, The LED module 100 includes a device power supply unit 140 for supplying driving power required to drive light emission. Here, the device power supply unit 140 may receive input power from a commercial power line installed in the underground tunnel 10 and may be provided in the form of a battery in which charging power is stored.

The wireless switch module 200 is a means for the user to operate to turn on each lighting device 100, and as shown in FIG. It is disposed at the start position and the end position of the lighting device 100 in each integrated control group (G1 ~ G3) while outputting a wireless control signal according to a user operation to control the lighting.

Here, as shown in FIGS. 6 and 7 , the wireless switch module 200 includes a manipulation unit 210 that generates a user input signal according to a user manipulation, and a device communication unit 120 of the lighting device 100 and a signal. The module communication unit 220 for connection, the module control unit 230 for controlling the wireless control signal set according to the generated user input signal to be output through the device communication unit 120, and the wireless switch module 200 are required for operation. and a module power supply unit 240 for supplying driving power. Here, the module power supply unit 240 may be provided in the form of a battery in which charging power is stored or may receive input power from a commercial power line installed in the underground common tunnel 10 .

In addition, each wireless switch module 200 outputs a wireless control signal of the Zigbee communication method having a 2.4 GHz band to control lighting of each lighting device 100, but different control for each integrated control group (G1 to G3) By outputting a radio control signal having a code or a radio control signal having different frequency values, it is possible to selectively control lighting of the lighting devices 100 of each integrated control group (G1 to G3). In addition to the ZigBee communication method, various communication methods available in the field of wireless communication technology such as RF communication, Wi-Fi communication, and Bluetooth communication may be used.

In addition, referring to FIG. 2 , the wireless control signal can be divided into a lighting control wireless control signal for turning on the lighting device 100 and a wireless control signal for turning off the lighting device 100, and other necessary Accordingly, a wireless control signal for adjusting the brightness or color temperature of the lighting device 100 may be further divided and output.

As described above, through the combined configuration of the lighting device 100 and the wireless switch module 200, each lighting device 100 installed in the underground common area 10 is divided into a set integrated control group (G1 ~ G3) unit and wireless It is possible to control lighting in a controlled way, so that the construction cost and construction time for building a lighting system can be greatly reduced.

In addition, it is possible to prevent the lighting devices 100 of other adjacent integrated control groups from being unintentionally turned on or off by a wireless control signal for controlling lighting of the lighting devices 100 included in an arbitrary integrated control group.

In addition, as described above, since the integrated control group (G1 to G3) is set to a relatively shorter range than the wireless coverage distance (D) of the wireless control signal output from the matched wireless switch module 200, each wireless switch When a radio control signal of the same radio characteristic is output from the module 200, the lighting apparatus 100 of another adjacent integrated control group may receive it and unintentionally control lighting.

Accordingly, the wireless switch module 200 uses wireless control signals of different wireless characteristics between the wireless switch modules 200 of the adjacent integrated control group (G1 to G3) to the lighting device 100 included in the integrated control group. By selectively controlling the lighting of the lighting devices 100 included in an arbitrary integrated control group, the lighting devices 100 of other adjacent integrated control groups are prevented from being unintentionally turned on or off by a wireless control signal for lighting control. can do.

Here, the different wireless characteristics refer to the wireless switch module 200 of each integrated control group G1 to G3 for controlling lighting by distinguishing the lighting devices 100 of the adjacent integrated control group G1 to G3. It means that the characteristics of the wireless control signal are different from each other. For example, when the signal is connected between the lighting device 100 and the wireless switch module 200 in a ZigBee wireless communication method, each wireless switch module 200 is a ZigBee A wireless control signal of a communication method is output to control lighting of each lighting device 100, and a wireless control signal having a different ZigBee frequency value is output between the wireless switch modules 200 of the adjacent integrated control group (G1 to G3). Thus, lighting devices 100 included in the corresponding integrated control group can be selectively controlled.

In addition to the frequency value, the radio characteristics of the radio control signal may be set differently even in a manner in which a modulation method of the radio control signal is different or a recognition code included in the radio control signal is different.

In this way, each wireless switch module 200 uses a wireless control signal of different wireless characteristics between the wireless switch modules 200 of the adjacent integrated control group (G1 to G3) to the lighting device ( By selectively controlling the lighting of 100), the lighting devices 100 of other adjacent integrated control groups are unintentionally turned on or off by a wireless control signal for controlling lighting of the lighting devices 100 included in an arbitrary integrated control group. it can be prevented

In addition, since each lighting device 100 is sequentially arranged along the extended length of the underground tunnel 10 , each integrated control group G1 to G3 may also be set consecutively in the extending direction of the underground tunnel 10 .

Accordingly, as described above, radio control signals having different radio characteristics are used between the radio switch modules 200 of the adjacent integrated control groups G1 to G3, but as shown in FIG. 3, radios having two different radio characteristics are used. The control signals A and B can be alternately used in the direction in which each integrated control group G1 to G3 is set. For example, in one integrated control group G1, a radio control signal A having a first radio characteristic is used, and in another integrated control group G2 adjacent to the corresponding integrated control group G1, the second A radio control signal A having a radio characteristic is used, and another integrated control group G3 adjacent to the integrated control group G2 may use the radio control signal A. As described above, since the lighting devices 100 of each integrated control group G1 to G3 can be divided and controlled by the two wireless control signals A and B, the control method can be simplified and product costs can be reduced.

In addition, when the wireless coverage distance (D) of the wireless control signal output from the wireless switch module 200 of any integrated control group exceeds the range of the adjacent integrated control group, the lighting device of the integrated control group ( 100) may be unintentionally controlled to turn on by inputting a signal. Accordingly, as shown in FIG. 9, by setting the wireless control signals A, B, and C having three or more different wireless characteristics to be used alternately in the direction in which the respective integrated control groups G1 to G3 are set, the wireless coverage distance Regardless of (D), it is possible to effectively prevent the lighting device 100 at an unintended location from being controlled.

The wireless switch module 200 is fixedly installed between two adjacent integrated control groups G1 and G2 in the underground common area 10, and the lighting device 100 of one integrated control group G1 according to user operation. ) by outputting a first wireless control signal for lighting control or a second wireless control signal for lighting control of the lighting devices 100 of the other integrated control group (G2), the two integrated control groups (G1, G2) It is possible to turn on and turn off the lighting device 100, respectively, and to reduce the number of wireless switch modules 200 to be installed at the same time by half, thereby significantly reducing system construction costs and maintenance costs.

In addition, the wireless switch module 200 includes a first operation button 211 for generating a first user input signal according to a user operation and a second operation button 212 for generating a second user input signal according to a user operation. and a manipulation unit 210 comprising: outputting the first wireless control signal when the first user input signal is generated It is possible to turn on and off the lighting device 100 of the desired integrated control group (G1 to G3) by operation, thereby maximizing the user's convenience.

On the other hand, each integrated control group (G1 ~ G3) may include a plurality of lighting devices 100 according to a set range, each lighting device 100 is turned on at the same time according to the wireless control signal of the wireless switch module 200. In this case, an overcurrent is applied to the power supply means such as a switchboard or a power breaker, and sparks and high heat are generated, which may cause a fire.

Accordingly, in the wireless control lighting system according to a preferred embodiment of the present invention, the lighting devices 100 included in each integrated control group (G1 to G3) are set in the lighting direction (W) when a wireless control signal is input from the wireless switch module (200). ) by sequentially turning on the relay, the lighting devices 100 of the corresponding integrated control group G1 to G3 can be integrated lighting controlled with a minimum current value.

More specifically, as shown in FIG. 10 , the lighting devices 100 included in the corresponding integrated control group for each integrated control group G1 to G3 turn on when the set delay time elapses, but the The delay time may be set to gradually increase in the set lighting direction W.

In addition, as another method, as shown in FIG. 14 , the first lighting device 100a closest to the wireless switch module 200 among the lighting devices 100a to 100c included in each integrated control group G1 to G3. When the wireless control signal (A) for lighting is input from the wireless switch module 200, the lighting operation is turned on and toward the adjacent second lighting device 100b in the lighting direction (W) set at the time when the set delay time elapses. Outputs a wireless control signal A1 for turning on the second lighting device 100b, and when the wireless control signal A1 is input, the second lighting device 100b turns on when the set delay time elapses. A wireless control signal A2 for turning on the third lighting device 100c is output toward the third lighting device 100c adjacent in the lighting direction W, and the third lighting device 100c is wirelessly controlled. When the signal A2 is input, a wireless control signal for turning on the fourth lighting device 100d toward the fourth lighting device 100d adjacent in the lighting direction W when the set delay time elapses while the lighting operation is performed (A3) can be printed.

Here, the wireless control signal A1 has a wireless coverage distance D3 greater than or equal to a distance that can be input to the third lighting device 100c, and the third lighting device 100c has the first lighting device 100a. If the wireless control signal A2 of the second lighting device 100b is not input within the set waiting time while the wireless control signal A1 of A wireless control signal A3 can be output.

Therefore, even if any of the lighting devices 100a to 100d of the corresponding integrated control group fails to output the wireless control signal A2 due to a failure in any of the lighting devices 100b, the subsequent lighting devices 110c and 100d are relayed. It is possible to control the lighting by using the , so that it is possible to prevent in advance a situation in which lighting control of the other lighting devices 100c and 100d is not possible due to a failure of one lighting device 100b.

The present invention described above is not limited by the above-described embodiments and the accompanying drawings, and it is common in the art to which the present invention pertains that various substitutions, modifications and changes are possible without departing from the technical spirit of the present invention. It will be clear to those who have knowledge.

10...Underground common area 100...Lighting device
200...Wireless switch module 210...Control panel
211...Operation button 212...Group selection button
213...First operation button 214...Second operation button
215...Lighting target display unit 300...Second wireless switch module
G1~G3 : integrated control group A, B... wireless control signal

Claims (6)

A plurality of underground tunnels 10 are spaced apart at regular intervals along the lengthwise direction in which the underground tunnels 10 are extended, and turn on and off according to the input radio control signal, and a plurality of integrated control groups (G1 to G3) ) and grouped lighting devices 100; And it is fixedly installed between two adjacent integrated control groups (G1-G2, G2-G3) in the underground common area 10, and different wireless characteristics set for each integrated control group (G1, G2, G3) according to user operation A wireless switch module 200 for selectively controlling lighting devices 100 of each integrated control group (G1 to G3) by outputting a wireless control signal (A, B) of
The wireless switch module 200,
It includes an operation unit 210 including a first operation button 211 for generating a first user input signal according to a user operation and a second operation button 212 for generating a second user input signal according to a user operation, The first operation button 211 and the second operation button 212 include an ON operation button for turning on the lighting device 100 and an OFF operation button for turning off the lighting device 100, respectively, and the first When the user input signal is generated, a first wireless control signal for controlling lighting of only the lighting device 100 of one integrated control group G1 among the two adjacent integrated control groups G1 to G2 is output, and the second user input When the signal is generated, a second wireless control signal for controlling lighting of only the lighting device 100 of the other one of the two integrated control groups G1 to G2 is output,
Among the lighting devices 100a to 100d included in each of the integrated control groups G1 to G3, the first lighting device 100a closest to the wireless switch module 200 is used for lighting from the wireless switch module 200. When the wireless control signal (A) is input, the wireless for turning on the second lighting device 100b toward the adjacent second lighting device 100b in the lighting direction W set at the time when the set delay time elapses while the lighting operation is performed. The control signal A1 is output, and when the wireless control signal A1 is input, the second lighting device 100b turns on the third lighting adjacent to the lighting direction W when the set delay time elapses. A wireless control signal A2 for turning on the third lighting device 100c is output toward the device 100c, and when the wireless control signal A2 is input, the third lighting device 100c performs a lighting operation while delaying setting. When the time elapses, the relay lighting operation sequentially by outputting the wireless control signal A3 for turning on the fourth lighting device 100d toward the fourth lighting device 100d adjacent in the lighting direction W ,
The wireless control signal A1 has a wireless coverage distance D3 greater than or equal to a distance that can be input to the third lighting device 100c, and the third lighting device 100c is connected to the wireless communication device of the first lighting device 100a. If the wireless control signal A2 of the second lighting device 100b is not input within the set waiting time in a state in which the control signal A1 is input, the light is automatically turned on and wirelessly controlled toward the fourth lighting device 100d A wireless control lighting system for an underground common area, characterized in that it outputs a signal (A3).
delete delete delete The method according to claim 1,
When the wireless control signal is input, the lighting devices 100 included in each integrated control group (G1 to G3) are individually turned on when the set delay time elapses.
The wireless control lighting system for underground tunnels, characterized in that the delay time is set to be gradually longer in the set lighting direction (W). delete

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