KR102460699B1 - IoT-based lighting system detecting earthquake - Google Patents

Abstract

The present invention relates to an IoT based lighting system with a tilt detection and management function. The one or more IoT-based lighting systems (110) with an earthquake detection function of the present invention comprise: a lighting system main body (111); a lighting means (112) installed inside the lighting system main body (111); a lighting controller (113) controlling the operation of the lighting means (112); an earthquake detection sensor (114) attached to the lighting system main body (111), detecting earthquakes, and delivering earthquake information to the lighting controller (113); and a lighting communication unit (116) connected to the lighting controller (113) and transmitting and receiving earthquake information to and from the earthquake detection sensor (114). According to the one or more lighting systems (110), the lighting communication part (116) is connected to one or more portable terminals (200) and a management system (300) through a communication network (N) to be able to communicate, and the one or more of the lighting systems (110), the portable terminal (200), or the management system (300) determine that there is an abnormality in the installation state of the corresponding lighting system (110) when the earthquake information detected by the earthquake detection sensor (114) exceeds a safe range, and display and manage the abnormal state. Therefore, the present invention can use the lighting device as a strong warning means.

Description

Internet of Things-based lighting system with earthquake detection function {IoT-based lighting system detecting earthquake}

The present invention relates to an IoT-based lighting system equipped with an earthquake sensing function. A lighting system body 111; and a lighting means 112 installed in the lighting system body 111; ) a lighting controller 113 for controlling the operation; and an earthquake sensor 114 attached to the lighting system body 111 to detect an earthquake and transmit the earthquake information to the lighting controller 113; And, A lighting system 110 that is connected to the lighting controller 113 and includes a lighting communication unit 116 that transmits and receives earthquake information of the earthquake sensor 114; Characterized in that it is configured to include one or more, one or more of the lighting system 110, the lighting communication unit 116 communicates with one or more portable terminals 200 and the management system 300 through a communication network (N) Connected so as to be possible, any one or more of the lighting system 110, the portable terminal 200, or the management system 300, when the earthquake information detected by the earthquake sensor 114 is out of the safe range, It relates to an IoT-based lighting system equipped with an earthquake detection function, characterized in that it is determined that an abnormality has occurred in the installation state of the corresponding lighting system 110, and the abnormal state is displayed and managed.

Recently, lighting lamps installed indoors or outdoors are being replaced with LED lighting lamps due to the development of LED lighting technology having characteristics of low power and high efficiency. In particular, unlike in the past, even in the case of lighting lamps requiring high output, there is an increasing tendency to focus and install high-power LED lighting or a plurality of high-power LED lights.

In the case of such high-power LED lighting, heat dissipation performance becomes important. Due to this, the wind pressure area and weight increase, which increases the need to measure and manage the installation state such as the inclination of the LED lighting in real time in consideration of the structural stability of the installation state. have.

On the other hand, even in the case of such high-power LED lighting, it can be installed in a relatively light weight/small size compared to lighting by other existing methods (eg, metal halide lighting, etc.). Therefore, in addition to the case of installing LED lights by installing a separate lighting support requiring high installation cost, LED lighting is installed in existing facilities (for example, CCTV support installed on the road / traffic light support) cases are increasing. However, when installing ERID lights using existing facilities as described above, construction is extremely easy and cost is greatly reduced because there is no need to install a separate support, but structural stability due to vibration caused by wind or vehicle traffic, etc. The need to measure and manage in real time is even greater.

In particular, in the case of an earthquake, the light tower itself poses a great threat to vehicles or pedestrians.

In the prior art, there was an earthquake-resistant lighting tower (Patent No. 10-2375313) in preparation for an earthquake. The prior art is a tower body; an upper structure in which a lighting device is configured at the upper end of the tower body; A liquid damper configured in the upper structure, filled with a fluid, and composed of a horizontal tube and a vertical tube protruding upward from both ends of the horizontal tube, and an elastic line connecting the vertical tube and a weight configured in the center of the elastic line It is characterized by including;

However, the prior art simply prepares for earthquake resistance in the system itself, has no connection with a good warning device such as lighting, and displays an abnormal situation to users who may be exposed to immediate danger, such as no exchange of information with pedestrians, and warns them. There was a problem that it was impossible to do or manage.

Korean Patent No. 10-2375313

The present invention solves the problems of the existing invention, and it is an object of the present invention to provide a lighting device as a powerful warning means by linking earthquake information with high-brightness lighting installed in a lighting tower.

In addition, using IoT-based technology, it is an Internet of Things-based IoT-based technology equipped with an earthquake detection function that can generate more accurate judgment data by collecting pedestrian input information and real-time earthquake information by receiving information such as pedestrians. It is an object of the present invention to provide a lighting system.

In addition, not only the abnormal state of each lighting system itself, but also the integrated data management of each lighting system is possible. It aims to provide an Internet-based lighting system.

In order to achieve the above object, an IoT-based lighting system equipped with an earthquake detection function of the present invention includes a lighting system body 111; and a lighting means 112 installed in the lighting system body 111; and , a lighting controller 113 for controlling the operation of the lighting means 112; and an earthquake sensor attached to the lighting system body 111 to detect an earthquake and transmit the earthquake information to the lighting controller 113 (114); And, is connected to the lighting controller 113, the lighting communication unit 116 for transmitting and receiving earthquake information of the earthquake sensor 114; a lighting system 110 comprising a; Characterized in that it is configured to include one or more, one or more of the lighting system 110, the lighting communication unit 116 communicates with one or more portable terminals 200 and the management system 300 through a communication network (N) Connected so as to be possible, any one or more of the lighting system 110, the portable terminal 200, or the management system 300, when the earthquake information detected by the earthquake sensor 114 is out of the safe range, It is determined that an abnormality has occurred in the installation state of the corresponding lighting system 110 , and the abnormal state is displayed and managed.

In addition, when it is determined that the earthquake is sensed by the earthquake sensor 114, it is characterized in that it further comprises a display unit 118 for pedestrians to check whether the earthquake to the pedestrian.

In addition, when it is determined that an earthquake is sensed by combining the earthquake information by the earthquake sensor 114 and the pedestrian information from the pedestrian display unit, the lighting controller 113 includes the LED installed in the lighting means 112 . It is characterized in that the color of the lighting equipment is changed or flickered.

In addition, any one of the portable terminals 200 receives the state information about the state of the lighting system 110 together with the position information of the portable terminal itself and shares it through the communication network N, and the portable terminal 200 Alternatively, any one or more of the management system 300 reflects the state information to determine whether an abnormality has occurred in the installation state of each lighting system 110 , and displays and manages it.

In addition, the management system 300 is characterized in that it provides the closest location information to the pedestrian among the location information of the safe lighting controller that does not send earthquake information.

In the case of the present invention, there is an advantage that the lighting equipment can be used as a powerful warning means by linking the earthquake information with the high-brightness lighting installed in the lighting tower.

In addition, by using IoT-based technology, it has the advantage of generating more accurate judgment data by receiving information from pedestrians, etc., and collecting the input information of pedestrians and earthquake information received in real time.

In addition, there is an advantage in that not only the abnormal state of each lighting system itself, but also the integrated data management of each lighting system is possible, so that the location of the safety zone can be identified and provided to pedestrians.

1 is a view showing a state in which an IoT-based lighting system equipped with an earthquake detection function according to an embodiment of the present invention is installed.
Figure 2: A diagram showing the configuration of an IoT-based lighting system equipped with an earthquake detection function according to an embodiment of the present invention.

Hereinafter, an IoT-based lighting system equipped with an earthquake detection function according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. First, it should be noted that in the drawings, the same components or parts are denoted by the same reference numerals as much as possible. In describing the present invention, detailed descriptions of related well-known functions or configurations are omitted so as not to obscure the gist of the present invention.

As shown in FIG. 2 , the IoT-based lighting system 100 equipped with the earthquake detection function of the present invention comprises each lighting system 110 , the portable terminal 200 and the management system 300 . do.

First, the lighting system 110 will be described. The lighting system 110 can be installed on a support 10 that is installed previously, such as a support for CCTV installation, as shown in FIG. 1 . In this case, it is possible to set and fix the optical axis of the lighting system 110 in a predetermined direction through the installation bracket. Meanwhile, the lighting system 110 may also be installed on a separately installed support or support structure. As shown in FIG. 2 , the lighting system 110 comprises a lighting system body 111 , while in the lighting system body 111 , as shown in FIG. 2 , lighting means 112 , a lighting controller 113 , an earthquake sensor 114 , and a lighting communication unit 116 are installed.

The lighting means 112 is generally constituted by an LED lighting consisting of one or a plurality of arrays, but other lighting may be applied. In particular, since the lighting means serves to assist driving at an intersection at night, the luminance has a significant characteristic. Therefore, a strong warning means is possible by using the lighting means.

The lighting controller 113 is configured to control the operation of the lighting means 112 on/off, as well as adjusting the illuminance or changing the color. In addition, it is possible to display safe location information (from the management system 300 to be described later). For example, when a plurality of rows and columns are provided, an arrow moving toward a safe place may be implemented. In the direction of the arrow, the vehicle can be evacuated quickly.

The earthquake sensor 114 is installed in the lighting system body 111 and is configured to transmit the measured earthquake information to the lighting controller 113 . The earthquake sensor is preferably installed at the lower end of the lighting tower as much as possible to remove noise such as wind direction. Various embodiments are possible as a method of implementing such an earthquake sensor 114 . Since the sensor for detecting an earthquake is a level widely known and used in the technical field to which the present invention pertains, a detailed description thereof will be omitted.

As shown in FIG. 2 , the lighting communication unit 116 is connected to the lighting controller 113 and is configured to transmit and receive information including earthquake information of the earthquake sensor 114 . In this case, the lighting communication unit 116 is an Internet of Things (IoT) network, Bluetooth. It is configured to exchange information with the portable terminal 200 or the management system 300 through a communication network N including a wired/wireless Internet network such as Wi-Fi.

The speaker unit 117 is an output means for warning a pedestrian or the like. When the lighting controller 113 determines that it is an earthquake, a siren or a warning message is transmitted by the speaker unit 117 .

The pedestrian display unit 118 is configured for interactive information exchange. There are many factors that cause malfunction of the earthquake sensor, such as when the wind speed is high, such as a typhoon. In particular, since the light tower has a structure that can only be shaken by the wind, a malfunction of the seismic sensor can be expected. Through the display unit, it is possible to additionally receive simple information from a nearby pedestrian. For example, when a pedestrian is notified that an earthquake is occurring through the display unit, the pedestrian can input information on whether he or she can sense the current earthquake and information on the degree of wind, and the like.

Next, the portable terminal 200 will be described. As shown in FIG. 2 , the portable terminal 200 is configured to exchange information and the like with the lighting communication unit 116 or the management system 300 through the communication network N. In this case, various embodiments of the portable terminal 200 are possible, such as a smart phone, a PDA, a notebook computer, and an input/output device including a display/touch screen, a photographing means capable of photographing a picture/video, and the like, and the portable terminal 200. A GPS module that can determine the location is provided. As in an operation process to be described later, the portable terminal 200 displays and warns a user (a pedestrian or a manager) of an abnormal state of the lighting system 110 while operating through an installed application program and the like, as well as the lighting It is configured so that it is possible to input, share and manage the abnormal state of the system 110 .

Pedestrians may pre-download an application of the management system 300 to be described later. The management system is connected to a plurality of lighting controllers 113 and receives earthquake information from the lighting controllers. Therefore, it also has location information of a safe lighting controller that does not receive earthquake information. When the GPS information of the pedestrian is known, the location of the lighting controller closest to the location information of the pedestrian can be found, and this can be reported to the pedestrian.

Next, the management system 300 will be described. The management system is configured to communicate with one or more portable terminals 200 and the lighting communication unit 116 through a communication network N as shown in FIG. 2 . The management system 300 is configured to include a central processing unit in which a management program or application can operate, and a database in which management history, etc. can be stored.

Hereinafter, an operation of an IoT-based lighting system equipped with an earthquake detection function according to an embodiment of the present invention will be described.

First, each earthquake sensor 114 measures an earthquake in real time. This measurement value is sent to the lighting controller 113 and also sent to the management system 300 . When the earthquake information exceeds a preset value, the lighting controller 113 determines that it is dangerous and controls the lighting means 112 . Lights can be flickered in turn, can have different illuminance, and can change color. As described above, the high-brightness LED used in the lighting tower itself can be a powerful warning means.

Also, a warning is broadcast through the speaker unit 117 . Warning broadcasting is possible with siren, warning message, and guidance message.

A simple guide and query for the pedestrian is provided to the pedestrian display unit 118 together with this guidance message. Basically, it asks for information such as whether or not an earthquake was felt, to what extent if it was felt, what is the wind speed, and whether the lighting tower was damaged. The additional information voluntarily by the pedestrian is collected by the lighting controller 113, and it is determined by the lighting controller whether to continue to provide an alarm.

All of the above information is transmitted to the management system 300 . The management system collects earthquake information from all the lighting controllers it manages. If there is damage information on the lighting tower, it is managed, such as by calling a technician for repair.

In addition, if seismic information from a plurality of lighting controllers is collected, it is possible to determine relatively accurate earthquakes, as well as to know the location information of safe lighting controllers. If the pedestrian is subscribed to the app of the management system 300, the location information of the pedestrian can also be known, so the management system 300 can provide the pedestrian with location information that is safe from earthquakes. Such safe location information may be provided not only to the pedestrian's portable terminal but also to the pedestrian display unit 118 .

On the other hand, based on the Internet of Things technology, any one of the portable terminals 200 to recognize and manage the abnormal state of the lighting system 110 in various ways, together with the location information of the portable terminal itself, the lighting system State information about the state of 110 is received and shared through the communication network (N), and any one or more of the portable terminal 200 or the management system 300 reflects the state information to each lighting system (110) It is preferable to operate to determine the presence or absence of abnormality in the installation state, display and manage.

That is, through the portable terminal 200 possessed by a user in the vicinity of the place where the lighting system 110 is installed, the location of the portable terminal itself that can determine the installation location in which the lighting systems 110 are installed together. State information about the state of the lighting system 110 together with the information It is desirable to operate to share and manage through the communication network (N) by receiving an input such as a photograph or video taken of the state of the lighting system (eg, there is a risk of inclination / dropout detected by the naked eye).

On the other hand, the sharing operation of the state information, when the state information is shared using image information such as a photo or a video, the lighting system 110 itself can display whether an abnormal state has occurred (for example, , changing the color of lighting or flickering), it can be performed more efficiently because the installation location of the lighting system 110 in which an abnormal state occurs on the image information can be intuitively determined.

As described above, the observation/management function through the portable terminal 200 can be independently performed, and as described above, additionally to the determination of an abnormal state through the seismic sensor 114 of the lighting system 110 . It is also possible to perform a supplementary /

That is, as described above, when it is determined that an abnormal state has occurred through the measurement of the inclination sensor 114 , the management system 300 uses the location information of the portable terminal 200 to generate the abnormal state. After a request is made to share the state information regarding the state of the lighting system 110 to the portable terminal 200 determined to be in the vicinity of the place where the lighting system 110 is installed, through the portable terminal 200 It is preferable to perform the above-described state information sharing procedure through the portable terminal 200 .

In the above, the best embodiments have been disclosed in the drawings and the specification. Although specific terms are used herein, they are used only for the purpose of describing the present invention, and are not used to limit the meaning or the scope of the present invention described in the claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

N: network
10: installation post
11: CCTV
100: Internet of Things-based lighting system with tilt detection and management function
110: lighting system
111: lighting system body
112: lighting means 113: lighting controller
114: earthquake sensor
116: lighting communication unit
117: speaker unit
200: portable terminal
210: position sensor 220: camera
230: input and output means
300: management system
400: traffic control system

Claims (5)

delete lighting system body 111;
lighting means (112) installed in the lighting system body (111);
a lighting controller 113 for controlling the operation of the lighting means 112;
an earthquake sensor 114 attached to the lighting system body 111 to detect an earthquake and transmit the earthquake information to the lighting controller 113;
A lighting system 110 that is connected to the lighting controller 113 and includes a lighting communication unit 116 that transmits and receives earthquake information of the earthquake sensor 114; It is characterized in that it is configured to include one or more,
One or more of the lighting systems 110,
The lighting communication unit 116 is connected to communicate with one or more portable terminals 200 and the management system 300 through a communication network (N),
Any one or more of the lighting system 110, the portable terminal 200, or the management system 300,
When the seismic information detected by the earthquake sensor 114 is out of the safe range, it is determined that an abnormality has occurred in the installation state of the corresponding lighting system 110, and each abnormal state is displayed to warn and manage,
When it is determined that an earthquake is detected by the earthquake sensor 114, the lighting based on the Internet of Things with an earthquake detection function, characterized in that it further comprises a display unit 118 for pedestrians to check whether an earthquake is present to the pedestrian. system 100.
3. The method of claim 2,
When it is determined that an earthquake is sensed by combining the earthquake information by the earthquake sensor 114 and the pedestrian information from the pedestrian display unit, the lighting controller 113 is provided with LED lighting installed in the lighting means 112 . An IoT-based lighting system 100 with an earthquake detection function, characterized in that the color of the instrument is changed or blinked.
4. The method of claim 3,
Any one of the portable terminals 200 receives the state information about the state of the lighting system 110 together with the position information of the portable terminal itself and shares it through the communication network N,
Any one or more of the portable terminal 200 or the management system 300,
An IoT-based lighting system 100 with an earthquake detection function, characterized in that by reflecting the state information, determining whether an abnormality occurs in the installation state of each of the lighting systems 110, displaying, and managing it.
5. The method of claim 4,
The management system 300 is an Internet of Things-based lighting system 100 with an earthquake detection function, characterized in that it provides the closest location information to a pedestrian among location information of a safe lighting controller that does not send earthquake information.

Images