KR102094959B1 - Wireless road stud and the method thereof - Google Patents

Abstract

The radio beacon system according to the present invention is a radio beacon system installed inside the tunnel and outside the tunnel, centering on the tunnel on the road, and is installed inside the tunnel to receive power at all times and transmit data every predetermined signal transmission cycle. After that, the central control means for switching to the sleep mode; A plurality of repeaters that are installed in a predetermined allocation zone inside the tunnel and outside the tunnel to receive data transmitted at regular intervals from the central control means, and then retransmit the data; And at least one or more continuously installed at predetermined intervals on the road inside the tunnel and outside the tunnel, and detecting a battery power state and changing a corresponding data reception mode period to receive data transmitted from the repeater. It is characterized by the inclusion of labeling devices.
According to the present invention, when transmitting and receiving data depending on the solar charging battery power in a situation where it is installed outside the tunnel and the power of the signage device is not always supplied, by adjusting the power-on state of the data receiving cycle according to the battery charging state Even in a situation where charging is not possible, data can be transmitted and received while saving battery power as much as possible.

Description

Wireless signage system and its control method {Wireless road stud and the method thereof}

The present invention relates to a wireless labeling system and a method thereof, particularly when installed on the outside of a tunnel and transmitting / receiving data depending on the solar charging battery power in a situation where the power of the labeling device is not always supplied, data according to the battery charging state The present invention relates to a wireless labeling system and a control method for transmitting and receiving data while maximally saving battery power even in a situation where charging is not possible by adjusting the power-on state of the reception cycle.

In general, roads, tunnels, underpasses, roads in foggy areas, road borders, and median separators indicate the road's driving direction, and drivers or pedestrians can easily recognize dangerous areas such as traffic accidents or construction at night. Therefore, safety induction lamps or road marking devices to prevent safety accidents are installed.

Such a road marking device is installed at a boundary or at the end of a road on a driving line of a vehicle or a reciprocating road running in both directions, but after drilling a hole in the road and inserting the lower post of the road marking device into the hole, epoxy or It is fixed by cement or the like, and is made by providing a reflector or a luminous body on the top of the road marking device so that the driver of the vehicle can easily identify it.

The road sign device is largely composed of a head part exposed on the road surface and a pillar buried in the road.It uses natural light or reflected light by light emitted from a vehicle, or it can be self-contained by electricity generated inside the road sign device. It is possible to use a method of emitting light.

First, in the case of using reflected light, a reflecting plate reflecting light on its side is formed in an oval or circular shape on the head portion, and the upper surface of the head portion forms a flat shape or provides another reflecting plate to smoothly reflect light. The posts provided at the bottom of the road marking device are formed in a column shape so that they can be inserted into the holes formed in the road, and after inserting the posts into the holes, the road marking device is fixed by epoxy or cement. Do not deviate.

On the other hand, the road marking device that emits light by electricity generated from the inside is provided with a light emitting body that emits light by electricity on the side of the head portion, but is provided so that the shape seen from the outside is oval or circular, and the upper surface of the head portion A solar cell is provided to generate electricity using sunlight, and a storage battery (not shown) is provided inside the road signage device to store electricity generated by sunlight. The method and configuration of fixing to the road are the same as those of the road sign using the above reflector, and the description is omitted.

In the case of the road signage device using the sunlight, the data transmitted from the central control unit is received and turned on or flashing. At this time, data transmitted to the labeling device is transmitted through a signal repeater called a repeater, and the repeater and labeling devices retransmit the transmitted signal to an adjacent labeling device or repeater so that the labeling device or repeater having the corresponding ID receives the signal. Retransmission is performed.

However, since the signage devices installed outside the tunnel receive the charged power from the sunlight, charging from the solar panel is difficult on a cloudy or rainy day, and thus, when the battery is discharged, smooth data transmission / reception occurs. .

Korean Patent Publication No. 10-2011-0055882

When the present invention is installed outside the tunnel and transmits and receives data on the basis of the solar charging battery power in a situation where the power of the signage device is not always supplied, it is not charged by adjusting the power-on state of the data receiving cycle according to the battery charging state. It is an object of the present invention to provide a wireless labeling system and a control method for transmitting and receiving data while saving battery power as much as possible.

The wireless signage system according to the present invention for achieving the above problems is a wireless signage system installed inside the tunnel and outside the tunnel with the tunnel as the center on the road. Central control means for switching to a sleep mode after transmitting data for each signal transmission cycle; A plurality of repeaters that are installed in a predetermined allocation zone inside the tunnel and outside the tunnel to receive data transmitted at regular intervals from the central control means, and then retransmit the data; And at least one or more continuously installed at predetermined intervals on the road inside the tunnel and outside the tunnel, and detecting a battery power state and changing a corresponding data reception mode period to receive data transmitted from the repeater. It is characterized by the inclusion of labeling devices.

Here, in particular, the plurality of repeaters, the repeaters installed inside the tunnel are always supplied with power, the repeaters installed outside the tunnel are supplied with battery power, and the data is received from the central control means at regular intervals in the data reception standby mode. It is characterized in that, when received, it transmits data to the labeling device and switches back to the standby mode.

Here, in particular, the signage device installed inside the tunnel receives constant power, the signage device installed outside the tunnel receives battery power, and the signage device installed outside the tunnel is characterized by monitoring the battery power state. .

Here, in particular, the signage device installed outside the tunnel includes: a power supply unit for charging the battery with power generated from the solar panel to supply power; A battery sensing unit monitoring a battery state of the power unit; A control unit for changing a data reception mode period in response to the battery charging state detected by the battery detection unit and outputting a lighting control signal in response to the data signal; A communication unit that receives data from the repeater or an adjacent label device and retransmits data to another adjacent label device in response to a data reception mode period set by the control unit; And a display unit that blinks in response to the lighting control signal of the control unit.

Here, in particular, the control unit sets a predetermined time to the data reception mode period (T1), and the data reception mode period (T1) is the time to maintain the battery power off mode and the time to maintain the battery power on mode (T2). The inclusion point has its characteristics.

Here, in particular, the controller sets a time T2 for maintaining the power-on mode longer than a signal transmission cycle of the central control means when the state of charge of the battery detected by the battery detector is greater than or equal to a preset value, and charges the battery If the state is less than a preset value, the feature is that the time T2 for maintaining the power-on mode is set to be shorter than the signal transmission period of the central control means.

Here, in particular, when it is determined that the control unit misses data reception by the communication unit, the data reception mode period T1 is adjusted after adjusting the data reception mode period T1, and then the data reception mode period T1 is initialized. It is characterized by setting it to.

In addition, the control method of the radio sign system according to the present invention for achieving the above object is a central control means in the control method of the radio sign system installed inside the tunnel and outside the tunnel with the tunnel as the center on the road. Transmitting data every predetermined signal transmission cycle; Retransmitting the data after receiving the data transmitted from the central control means at the repeater; Monitoring a battery charging state of a signage device installed outside the tunnel; Changing a data reception mode period in response to a battery charge state of the monitored label device; Receiving data at the changed data reception mode period; And flashing a display unit in response to a control signal of the received data.

Here, in particular, in the step of changing the data reception mode period, a certain time is set to the data reception mode period (T1) state, and the data reception mode period (T1) is the time to maintain the battery power off mode and the battery power on mode It is characterized in that it includes a time (T2) for holding.

Here, in particular, in the step of changing the data reception mode period, if the state of charge of the battery is equal to or greater than a preset value, the time T2 for maintaining the power-on mode is set longer than the signal transmission period of the central control means, and the battery If the state of charge is less than the preset value, the feature is that the time T2 for maintaining the power-on mode is set to be shorter than the signal transmission period of the central control means.

Here, in particular, if it is determined that the data reception is missed in the step of receiving data in the data reception mode period, the data reception mode period (T1) is adjusted to receive data, and then the data reception mode period ( The characteristic is that T1) is set to the initial state.

According to the present invention, when transmitting and receiving data depending on the solar charging battery power in a situation where it is installed outside the tunnel and the power of the signage device is not always supplied, by adjusting the power-on state of the data receiving cycle according to the battery charging state Even in a situation where charging is not possible, data can be transmitted and received while saving battery power as much as possible.

1 is a view schematically showing the configuration of a wireless labeling system according to an embodiment of the present invention.
2 is a view schematically showing the configuration of a labeling device according to an embodiment of the present invention.
Figure 3a is a diagram showing the output of a signal for transmitting and receiving data in each configuration installed inside the tunnel of the wireless labeling system according to the present invention.
Figure 3b is a diagram showing the output of a signal for transmitting and receiving data in each configuration installed outside the tunnel of the wireless labeling system according to the present invention.
Figure 4 is a flow chart for a control method of a wireless labeling system according to an embodiment of the present invention.

The present invention can be variously changed and can have various embodiments, and specific embodiments will be illustrated in the drawings and described in detail through detailed description. However, this is not intended to limit the present invention to a specific embodiment, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

In the description of the present invention, when it is determined that detailed descriptions of related known technologies may unnecessarily obscure the subject matter of the present invention, detailed descriptions thereof will be omitted. In addition, the numbers (for example, first, second, etc.) used in the description process of the present specification are only identification symbols for distinguishing one component from other components.

Further, in this specification, when one component is referred to as "connected" or "connected" with another component, the one component may be directly connected to the other component, or may be directly connected, but in particular, It should be understood that, as long as there is no objection to the contrary, it may or may be connected via another component in the middle.

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

1 is a diagram schematically showing a configuration of a wireless labeling system for preventing data retransmission according to an embodiment of the present invention, and FIG. 2 is a view schematically showing a configuration of a labeling device according to an embodiment of the present invention. , Figure 3a is a diagram showing the output of a signal for transmitting and receiving data in each configuration installed inside the tunnel of the wireless labeling system according to the present invention, Figure 3b is in each configuration installed outside the tunnel of the wireless labeling system according to the present invention It is a diagram showing the output of a signal to which data is transmitted and received.

As shown in FIG. 1, in a wireless signage system installed inside a tunnel and outside of both ends of a tunnel centering on a tunnel on a road, the power is installed inside the tunnel to receive power at all times and transmit data every predetermined signal transmission cycle. Then, the central control means 110 for switching to the sleep mode; A plurality of repeaters 120 which are installed in a predetermined allocation zone inside the tunnel and outside the tunnel to receive data transmitted at regular intervals from the central control means and retransmit the data; And at least one or more continuously installed at predetermined intervals on the road inside the tunnel and outside the tunnel, and detecting the battery power state to change the data reception mode period corresponding to the received data transmitted from the repeater 120 It comprises a plurality of marker devices 130.

The central control means 110 is provided in a tunnel in which a wireless labeling device is generally installed to monitor repeater and status information of the labeling device, and transmit control data by assigning IDs to each labeling device and repeater. At this time, the central control means 110 is always supplied with power.

More specifically, as shown in FIG. 3A, the central control means 110 transmits data at predetermined time intervals. That is, in the data transmission, a signal transmission period (Tmprd) including a time (Tmsnd) for transmitting data and a slim mode (mslp) from transmission to the next transmission is repeated.

The data transmitted in the signal transmission period (Tmprd) may include a transmission side ID, data length information, lighting control information, and transmission / reception line position information provided to each labeling device and repeater. Here, the central control means 110 transmits data using IDs assigned to manage and control all repeaters and labeling devices. At this time, the transmitted data signal is a data control signal for on / off control of the labeling device, lighting cycle, lighting color, lighting brightness, flashing cycle, and the like.

The repeater 120 is installed for each zone allocated at a predetermined interval to receive data transmitted from the central control means 110, and data to other repeaters installed in the adjacent allocation zone or a labeling device installed in each zone. Will be resent.

Here, the repeater installed inside the tunnel receives power at all times, the repeater installed outside the tunnel receives battery power, and when data is received from the central control means at regular intervals in a data reception standby mode, to the labeling device Transmit the data and switch back to the standby mode. At this time, the repeater 120 immediately retransmits the data to the labeling device without delay after a time (Tmsnd) for transmitting the data of the signal transmission period of the central control means. At this time, the repeater receives data in the always-on standby mode to receive data from the central control means and retransmits it.

The marking device 130 is continuously installed at predetermined intervals along both sides of the ascending and descending lines of the road, and the marking devices 130 are separately divided and managed. That is, the labeling devices 130 installed on the upward line are provided so that the repeater 120 transmits data in each allocation area, and the labeling device receiving the data of the repeater 120 is located outside of each allocation area. It will retransmit the data to other label devices within. Here, the signage devices can be divided into a signage device installed inside the tunnel and a signage device installed outside the both ends of the tunnel, and the signage device installed inside the tunnel is always supplied with power, and the signage devices installed outside the tunnel are generated from solar panels. Power is supplied by using.

As illustrated in FIG. 2, the sign device 130 installed outside the tunnel includes a power supply unit 210, a battery detection unit 220, a control unit 230, a communication unit 240, and a display unit 250.

The power supply unit 210 supplies power generated from the solar panel to power. At this time, although not shown, a solar panel is provided on each of the signage devices to charge the produced electric power to the battery to supply power.

The battery detection unit 220 monitors the battery state of the power supply unit 210. Here, when the state of charge of the battery is detected to be greater than or equal to a preset value, the battery detector determines that the battery state is sufficient, and if it is less than the preset value, determines that the battery state is not sufficient. At this time, if the battery state is less than a predetermined value, it is determined that the power of the battery is not sufficient, so that the maintenance time in the on state can be reduced to reduce the discharge of the battery.

The controller 230 changes the data reception mode period in response to the battery charging state detected by the battery detector 220 and outputs a lighting control signal in response to the data signal.

More specifically, as illustrated in FIG. 3B, the control unit 230 sets a predetermined time to a data reception mode period (T1) state. Here, the data reception mode period T1 includes a time for maintaining the battery power off mode and a time for maintaining the battery power on mode T2.

When the state of charge of the battery detected by the battery detector 220 is greater than or equal to a preset value, the control unit 230 extends the time T2 for maintaining the power-on mode longer than the signal transmission period of the central control unit 110. Set, and if the state of charge of the battery is less than a predetermined value, the time T2 for maintaining the power-on mode is set to be shorter than the signal transmission period of the central control means. For example, if the data reception mode period (T1) is set to 10 seconds, and the time for maintaining the battery power off mode is 7 seconds and the time for maintaining the battery power on mode (T2) is 3 seconds, the battery is charged. If is less than the preset value, the time (T2) of maintaining the battery power on mode can be reduced to 2 seconds. That is, it is controlled to be shorter than the signal transmission period of the central control means.

In addition, if it is determined that the controller has missed data reception by the communication unit, the data reception mode period T1 is adjusted to the initial state after adjusting the data reception mode period T1 to receive data. Will be set. For example, when data reception is missed, the data reception mode period (T1) is adjusted so as not to be a multiple of the signal transmission period, and when the data sewing is canceled again, the data reception mode period (T1) is the time of the signal transmission period. It is set to be a multiple. At this time, in the data reception mode period T1, an on-state section precedes the off-state section.

The communication unit 240 receives data from the repeater or an adjacent label device in response to a data reception mode period set by the control unit 230 and retransmits data to another adjacent label device.

The display unit 250 blinks in response to the lighting control signal of the control unit. Various LED elements are provided to distinguish colors and light or blink in response to the control signal of the control unit 20.

In addition, FIG. 4 is a flow chart for a method of controlling a radio label system according to an embodiment of the present invention. As shown in FIG. 3, in the control method of the wireless labeling system according to the present invention, first, the step of transmitting data at a predetermined signal transmission cycle in the central control means is performed (S410). At this time, the data transmitted from the central control means 110 includes the transmission side ID, data length information, lighting control information, and transmission / reception line position information provided to each labeling device 130.

Subsequently, after receiving the data transmitted from the central control means at the repeater, the step of retransmitting the data is performed (S420). More specifically, the repeater installed inside the tunnel receives power at all times, the repeater installed outside the tunnel receives battery power, and when data is received at regular intervals from the central control means in a data reception standby mode, the sign It sends data to the device and switches back to the standby mode. At this time, the repeater 120 immediately retransmits the data to the labeling device without delay after a time (Tmsnd) for transmitting the data of the signal transmission period of the central control means. At this time, the repeater receives data in the always-on standby mode to receive data from the central control means and retransmits it.

Then, a step of monitoring the battery charge state of the signage device installed outside the tunnel is performed (S430). Here, when the state of charge of the battery is detected to be greater than or equal to a preset value, the battery detector determines that the battery state is sufficient, and if it is less than the preset value, determines that the battery state is not sufficient. At this time, if the battery state is less than a predetermined value, it is determined that the power of the battery is not sufficient, so that the maintenance time in the on state can be reduced to reduce the discharge of the battery.

Then, a step of changing the data reception mode period in response to the battery charging state of the monitored label device is performed (S440).

More specifically, the control unit 230 sets a predetermined time to a data reception mode period (T1) state. Here, the data reception mode period T1 includes a time for maintaining the battery power off mode and a time for maintaining the battery power on mode T2.

When the state of charge of the battery detected by the battery detector 220 is greater than or equal to a preset value, the control unit 230 extends the time T2 for maintaining the power-on mode longer than the signal transmission period of the central control unit 110. Set, and if the state of charge of the battery is less than a predetermined value, the time T2 for maintaining the power-on mode is set to be shorter than the signal transmission period of the central control means. For example, if the data reception mode period (T1) is set to 10 seconds, and the time for maintaining the battery power off mode is 7 seconds and the time for maintaining the battery power on mode (T2) is 3 seconds, the battery is charged. If is less than the preset value, the time (T2) of maintaining the battery power on mode can be reduced to 2 seconds. That is, it is controlled to be shorter than the signal transmission period of the central control means.

Then, a step of receiving data in the changed data reception mode period is performed (S450). Here, in particular, if it is determined that the data reception is missed in the step of receiving data in the data reception mode period, the data reception mode period (T1) is adjusted to receive data, and then the data reception mode period ( T1) is set to the initial state.

Finally, a step of blinking a display unit in response to a control signal of the received data is performed (S460).

According to the present invention, when transmitting and receiving data depending on the solar charging battery power in a situation where it is installed outside the tunnel and the power of the signage device is not always supplied, by adjusting the power-on state of the data receiving cycle according to the battery charging state Even in a situation where charging is not possible, data can be transmitted and received while saving battery power as much as possible.

The scope of the present invention is not limited to the above-described embodiment, but may be implemented as various types of embodiments within the scope of the appended claims. Any person skilled in the art to which the invention pertains without departing from the gist of the invention as claimed in the claims is deemed to be within the scope of the claims of the invention to a wide range that can be modified.

110 --- Central control means 120 --- Repeater
130 --- Marking device 210 --- Communication department
220 --- Comparison section 230 --- Control section
240 --- Power supply 250 --- Display

Claims (11)

In the wireless signage system installed on the road inside the tunnel centered on the tunnel and outside the both ends of the tunnel,
A central control means installed in the tunnel to receive power at all times and to transmit data at predetermined signal transmission cycles to switch to sleep mode;
A plurality of repeaters that are installed in a predetermined allocation zone inside the tunnel and outside the tunnel to receive data transmitted at regular intervals from the central control means, and then retransmit the data; And
At least one or more continuously installed at predetermined intervals on the road inside the tunnel and outside the tunnel, and detecting a battery power state and changing a corresponding data reception mode period to receive data transmitted from the repeater. Devices; including,
The signage device installed outside the tunnel,
A power supply unit for charging the battery with power generated from the solar panel to supply power;
A battery sensing unit monitoring a battery state of the power unit;
A control unit for changing a data reception mode period in response to the battery charging state detected by the battery detection unit and outputting a lighting control signal in response to the data signal;
A communication unit that receives data from the repeater or an adjacent label device and retransmits data to another adjacent label device in response to a data reception mode period set by the control unit; And
Includes; a display unit flashing in response to the lighting control signal of the control unit,
The control unit sets a predetermined time to the data reception mode period (T1), and the data reception mode period (T1) includes a time for maintaining the battery power off mode and a time for maintaining the battery power on mode (T2), If the state of charge of the battery detected by the battery detection unit is greater than or equal to a preset value, set a time T2 for maintaining the power-on mode longer than a signal transmission period of the central control means, and if the state of charge of the battery is less than a preset value A wireless labeling system characterized in that the time (T2) for maintaining the power-on mode is set to be shorter than the signal transmission period of the central control means.
According to claim 1,
The plurality of repeaters,
The repeater installed inside the tunnel is always supplied with power, the repeater installed outside the tunnel is supplied with battery power, and when data is received from the central control means at regular intervals in a data reception standby mode, data is sent to the marker device. A wireless beacon system characterized in that it transmits and switches back to the standby mode.
According to claim 1,
The labeling device installed inside the tunnel is always supplied with power, the signing device installed outside the tunnel is supplied with battery power, and the signing device installed outside the tunnel monitors battery power status.
delete delete delete According to claim 1,
When the controller determines that the communication unit misses data reception, adjusts the data reception mode period T1 to receive data, and then sets the data reception mode period T1 to an initial state. ,
Adjust the data reception mode period (T1) so that it is not a multiple of the signal transmission period, and when data sewing is canceled again, set the data reception mode period (T1) to be a multiple of the signal transmission period, and receive the data In the mode period (T1), the wireless labeling system characterized in that the on-state section precedes the off-state section.
In the control method of the radio beacon system installed on the road inside the tunnel centered around the tunnel and outside the both ends of the tunnel,
Transmitting data at a predetermined signal transmission cycle in a central control means;
Retransmitting the data after receiving the data transmitted from the central control means at the repeater;
Monitoring a battery charging state of a signage device installed outside the tunnel;
Changing a data reception mode period in response to a battery charge state of the monitored label device;
Receiving data at the changed data reception mode period; And
And blinking a display unit in response to the control signal of the received data,
In the step of changing the data reception mode period, a certain period of time is set to the data reception mode period (T1), and the data reception mode period (T1) is the time for maintaining the battery power off mode and maintaining the battery power on mode. Time (T2),
If the state of charge of the battery is greater than or equal to a preset value, a time T2 for maintaining the power-on mode is set longer than a signal transmission period of the central control means, and if the state of charge of the battery is less than a preset value, the power-on mode is maintained. The control method of the radio label system, characterized in that the time (T2) is set to be shorter than the signal transmission period of the central control means.
delete delete The method of claim 8,
When it is determined that data reception is missed in the step of receiving data in the data reception mode period, the data reception mode period T1 is adjusted after the data reception mode period T1 is adjusted to receive data. Set it to the initial state,
Adjust the data reception mode period (T1) so that it is not a multiple of the signal transmission period, and when data sewing is canceled again, set the data reception mode period (T1) to be a multiple of the signal transmission period, and receive the data In the mode period (T1), the control method of the wireless label system, characterized in that the on-state section before the off-state section.

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