KR20140055370A - A system for measuring safety grade of building - Google Patents

Abstract

Disclosed is a system to measure building safety grade which comprises: a pressure detection unit installed in the building structure so as to detect pressure of a certain area when the structure is deformed; an output device outputting information about the appearance of a safety abnormality in the building based on the information detected from the pressure detection unit; a management server controlling the output device depending on the information from the pressure detection device and controlling to perform a determined follow-up situation; and a communication device to send and receive data between the pressure detection device and the management server.

Description

[0001] The present invention relates to a building safety measurement system,

The present invention relates to a building safety measurement system, and more particularly, to a building safety measurement system capable of determining a position of a building when it is fatigued or collapsed and immediately confirming its position.

In recent years, the construction of high-rise buildings has been spreading, and the number of structures requiring structural safety review due to natural disasters and aging of buildings has been increasing rapidly.

Therefore, it is very important to measure the current state of the structure in order to identify the state of the structure in advance, to take measures against it, and to take measures to repair and reinforce it.

Particularly, the safety of structures with degraded performance and structures built long ago is very unstable and can cause large disasters. The change in the state of these structures or the occurrence of breakage is the main cause of the accumulation of fatigue phenomena.

For example, buildings such as apartments and buildings can accumulate the fatigue phenomenon because the wind direction and wind speed of the buildings are different according to the portions of the building, and bridges can accumulate the bridges depending on the speed of the moving vehicle, The fatigue phenomenon can be accumulated due to the vibration of each part of the ship, and the ship can receive the fatigue phenomenon by receiving the influence of the height, direction and force of the waves in different parts of the ship.

In most of the systems that grasp the state of the structure currently being used, there is practically no system that can measure the exact displacement of the structure in real time and quickly detect the deformation or collapse of the structure due to the fatigue phenomenon.

In addition, since there is no system that can easily obtain accurate time data in the displacement measurement, there is a problem that unknown information can not be obtained only by the displacement data such as predicting the collapse time of the structure.

Further, in order to measure the state of the structure, that is, the degree of safety, there is a problem that the measurement person must directly go to the structure and measure the measured displacement for a long time after attaching the measuring device to the outer wall of the structure. There is a problem that it is difficult to immediately check the exact point of the collapse point or the collapse point.

It is an object of the present invention to provide an improved system for measuring the degree of building safety so that the occurrence of fatigue deformation or collapse of a structure can be immediately confirmed by being installed inside a structure.

According to another aspect of the present invention, there is provided a system for measuring building safety, comprising: a pressure sensing device installed inside a building structure to detect a change in pressure of a predetermined area when a structure is deformed; An output device for outputting information on occurrence of a safety fault signal to the building based on the information detected by the pressure sensing device; A control server for controlling the output device in accordance with the information from the pressure sensing device and performing a set follow-up action situation; And a communication device for transmitting and receiving data between the pressure sensing device and the management server.

Here, the pressure sensing device may include a first optical transmission module including a plurality of optical sensors disposed at a predetermined interval, at least one of which is formed with a cut end, and is formed of an optical fiber; A second optical transmission module arranged so as to be orthogonal to the optical fibers of the first optical transmission module at regular intervals and formed with at least one cut end and formed of optical fibers; An optical signal transmission module for generating and outputting an optical signal to the inside of the first optical transmission module and the second optical transmission module through one end of the optical fiber; An optical signal receiving module for receiving an optical signal output from the first optical transmission module and the second optical transmission module and converting the optical signal into an electrical signal and outputting the electrical signal; And a determination controller for analyzing the optical signal output from the optical signal receiving module to determine the optical transmission ratio of the first and second optical transmission modules.

The pressure sensing device may further include a base having the first optical transmission module and the second optical transmission module arranged orthogonally to each other, and the base may be embedded in the building structure.

The determination control unit may analyze the determined optical transmission ratio and calculate the pressure distribution in two-axis coordinates.

The first optical transmission module or the second optical transmission module may further include a plurality of first optical transmission modules or second optical transmission modules, and a connecting module for optically transferring the first optical transmission modules or the second optical transmission modules to each other good.

The output device may include an audio output unit for outputting an emergency signal as an audio signal when a safety fault signal of the building is generated; And a video output unit for outputting the generated position and the generated state information as a video signal when the safety fault signal of the building is generated.

The video output unit may include a display panel that is controlled by the management server so that the location information and the occurrence time of the building where the safety fault signal is generated are displayed on the map information of the building.

The management server may further include: a storage unit for storing map information and manager information for the building; A main control unit for analyzing data transmitted from the pressure sensing device through the communication device to determine whether the safety abnormal signal is generated and outputting a safety abnormal signal generation information through the output device according to a determination result; .

The management server may further include a call signal transmission unit for transmitting the emergency occurrence information including the safety abnormal signal generation information to the administrator or a corresponding jurisdiction over wired or wireless communication when the safety fault signal is generated It is good.

The main control unit controls the output of the safety fault signal to be popped up on the screen of the display panel of the output apparatus.

According to the building safety measurement system of the present invention, safety of a building can be measured and managed in real time without requiring a manager to measure the safety state of the building using a measurement device directly on site.

In addition, it is possible to more precisely and quickly identify the abnormality in a specific part of the building based on the abnormality signal occurrence information in a specific part of the building structure, so that it can promptly confirm and follow up (repair, evacuation, etc.) There is an advantage that it is possible to prevent damage to property as well as material damage.

FIG. 1A is a schematic block diagram of a building security measurement system according to an embodiment of the present invention.
1B is a block diagram of the pressure sensing device shown in FIG. 1A.
FIG. 2A is a schematic view for explaining the light transmission module of FIG. 1B. FIG.
FIG. 2B is a view for explaining a state in which the optical transmission module is connected using a connecting module.
FIG. 3 is a view for explaining optical signal transmission characteristics of the optical transmission module shown in FIG.
4 is a graph showing the optical transmission ratio of the optical transmission module.
5 is a view for explaining a pressure detecting apparatus for judging a pressure distribution by judging a light transmission rate of an optical transmission module.
6 to 7C are diagrams for explaining the operation of the building safety measurement system,
8 is a view showing an example in which a plurality of pressure sensing devices are installed in a monitored building.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a building security measurement system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1A and 2B, a building safety measurement system according to an embodiment of the present invention includes a pressure sensing device 600 installed in a structure of a monitored building 600 to sense a change in a constant area pressure due to deformation of a structure An output device 200 for outputting information on occurrence of a safety fault signal to the monitored building 600 based on the information detected by the pressure sensing device 100, And a communication device 400 for transmitting and receiving data between the pressure sensing device 100 and the management server 300. The control server 300 controls the output device 200 in accordance with a predetermined condition, Respectively.

The pressure sensing device 100 includes a first optical transmission module 120, a second optical transmission module 130, an optical signal transmission module 140, an optical signal reception module 150, a counter 160, a connecting module 170, a base 180, and a judgment control unit 110.

The first and second optical transmission modules 120 and 130 have an optical signal transmission path having at least one cut end, and the optical signal transmission module 120 (130 Is schematically shown. 2A, the optical signal transmission path includes an optical signal transmission path body 121, at least one optical fiber supporting connector 128, 138, 129, 139, an elastic member 127, A first optical fiber 123a, 133a and a second optical fiber 123b, 133b short-circuited by the mutual insulating end.

The interval between the cut ends of the optical signal transmission paths and the angle between the cut ends are variable by the pressure applied to the base 180 on which the optical signal transmission modules 120 and 130 are installed, And a first optical fiber 123a and a second optical fiber 123b 133b having one cut end. However, the scope of the present invention is not limited thereto.

The optical signal transmission path main bodies 121 and 131 serve to support the optical fiber supporting connectors 128, 138, 129 and 139 and the elastic members 127 and 137, . In addition, the optical signal transmission path bodies 121 and 131 may be integrally formed or partly independently formed by a part of the base 180 such as a matrix provided at the bottom of the monitored area.

A pair of optical fiber supporting connectors 128, 129, 138, 139 are provided in the optical signal transmission path body 121 (131), and when the interval of at least one cut end is bent by the pressure And supports the optical fibers 123a, 123b, 133a, and 133b so as to be variable. In the example shown in FIG. 2A, since the first optical fiber and the second optical fibers 123a, 123b, 133a, and 133b are cut and confronted with each other, only one pair of optical fiber supporting connectors 128 129, 138 and 139 may be provided. However, the scope of the present invention is not limited thereto, and each of the first and second optical fibers 123a, 123b, 133a, and 133b may have two or more cut ends.

The elastic members 127 and 137 are connected to at least one pair of optical fiber supporting connectors 128 and 129 and 138 and 139 for supporting the optical fiber supporting connectors 128 and 129 and 138 and 139, Are biased elastically in mutually approach directions. Therefore, after the optical signal transmitting modules 120 and 130 are installed on the base 180, the amount of the first and second optical fibers 123a and 123b and 133a and 133b The free ends of the first and second optical fibers 123a, 123b and 133a, 133b, which are cut off as shown in FIG. 2A, are bent when the base 180 is pressed and bent, The first and second optical fibers 123a and 123b and 133a are separated from each other by the elastic members 127 and 137 when the pressure is removed again. And both free ends of the second end 133b are abutted or abutted. With such a mechanism, the amount of the optical signal transmitted at both free ends of the first and second optical fibers 123a, 123b, 133a, 133b is varied.

The optical signal transmitting module 140 generates and outputs an optical signal. Although not shown, the optical signal transmitting module 140 may include an optical signal generator and an optical signal transmitter. The optical signal transmitting module 140 may be implemented as an LED that generates an optical signal of a specific wavelength. However, the scope of the present invention is not limited thereto.

The optical signal receiving module 150 receives an optical signal output from the optical signal transmitting module 140 and outputs the electrical signal to the optical transmitting module 120 or 130 having the optical signal transmitting path. The optical signal receiving module 150 may be implemented as a photodiode driven in response to a received optical signal. However, the scope of the present invention is not limited thereto.

The optical signal receiving module 150 has an amplifier and an analog-to-digital converter (not shown). The amplifier 150 amplifies and amplifies a signal output from the photodiode. The analog-to-digital converter converts the output signal of the amplifier into a digital signal, do.

The judgment control unit 110 analyzes the digital signal output from the optical signal receiving module 150 and finally detects the distribution of the pressure. In this case, it is preferable that the digital signal is sampled at a predetermined sampling rate in order to reduce the data throughput of the digital signal output from the optical signal receiving module 150. In addition, processing for converting a digital signal into a signal of a predetermined communication standard type may be included. This is merely one example, and the scope of the present invention is not limited thereto.

The optical signal transmission module 140 and the connection portions 125 and 135 of the optical signal transmission path between the optical signal transmission module 140 and the optical signal reception module 150 perform stable connection with the optical signal transmission module 140 and the optical signal reception module 150 It is preferable that the optical fibers 123a, 123b, 133a, and 133b are formed of a rigid material that can protect the optical fibers 123a, 123b, 133a, and 133b from the outside. Here, the connection portions 125 and 135 may be directly connected to the connection portions of the optical signal transmission module 140 and the optical signal reception module 150 as shown in FIG. 2A, Sensor or the like may be attached. Therefore, the shapes of the connection portions 125 and 150 need not be limited to those shown, and various embodiments are possible.

In addition, a plurality of first optical transmission modules 120 may extend in parallel and extend in parallel, or a plurality of second optical transmission modules 130 may extend in parallel with each other, 170 are provided. The connecting module 170 is provided with connecting portions 171 and 172 at positions opposite to each other so as to connect the connecting portions 125 and 135 in parallel with each other so that a plurality of first and second optical transmitting modules 120 and 130 Can be extended to each other. Therefore, it is possible to selectively connect left and right based on the base 180 of the basic size in accordance with the area and plan structure of the monitored area. Therefore, the length of the connecting module 170 can be formed to correspond to the width or length of the base 180, and the thickness of the connecting module 170 can also be formed to correspond to the thickness of the base 180.

Of course, the connecting module 170 may be connected to any one of the connection portions 125 and 135, or may be integrally coupled to the base 180. Therefore, it is natural that the optical signal transmitting module 140 and the optical signal receiving module 150 can be connected to the connecting module 170 and used.

The connecting portions 171 and 172 on both sides of the connecting module 170 are formed in symmetrical shapes opposite to each other, that is, one is protruded and one is in a so-called arm and water structure, So that the connection between the optical transmission modules 120 and 130 can be directly performed by connecting the base 180 and the base 180 directly.

Of course, when installed in the structure of the building 600, the base 180 may be integrally formed directly with the structure (building wall or floor) at the time of building construction, or may be installed outside the main frame have.

In addition, the pressure sensing device 100 may be formed in a mesh structure by omitting the base 180 and installed inside the building structure or the main gravel. In this case, the connection portion may be exposed to the outside through the wall of the building 600 .

The pressure sensing device 100 according to the preferred embodiment of the present invention is configured to measure a variation amount of an optical signal transmitted by the optical signal transmission module 120 or 130 according to the above-described mechanism, that is, based on a light transmission rate The pressure or pressure distribution can be determined by the structure in which the optical signal transmission modules 120 and 130 are arranged to be orthogonal.

3 is a view for explaining optical signal transmission characteristics of the optical signal transmission modules 120 and 130, and FIG. 4 is a diagram illustrating optical transmission rates of the optical signal transmission modules 120 and 130. Referring to FIG. 3, a light transmission rate (LTR), which is a ratio of an optical signal received by an optical signal receiver to an optical signal output from an optical signal transmitter, ) 130 is gradually decreased as it is warped. 4, the optical transmission ratio (LTR) of the optical signal transmission modules 120 and 130 is determined by the optical signal transmission modules 120 and 130 Quot;) is varied according to the pressure.

FIG. 5 shows a pressure sensing apparatus 100 according to a preferred embodiment of the present invention. Hereinafter, a method of sensing pressure will be described with reference to FIG.

A plurality of the first optical transmission modules 120 are arranged at regular intervals in the x axis direction and a plurality of the second optical transmission modules 130 are arranged orthogonally to the first optical transmission module 120 at regular intervals in the y axis direction .

The optical transmission module 140 is disposed at one end of the first optical transmission module 120 and the optical transmission module 150 is disposed at the other end. Although the optical transmission module 140 and the optical reception module 150 are shown separately in order to facilitate understanding of the drawings, the optical transmission module 140 and the optical reception module 150 may be different from each other.

5, it can be seen that the optical transmission ratio is 100% in the state where the uppermost optical transmission module 140 is not bent. In the case of the fourth optical transmission module 140, the optical transmission ratio is 85% . Therefore, it is possible to judge the pressure by analyzing the optical transmission ratio in which the optical transmission ratio is varied and varied according to the degree of warpage.

Also, by arranging the first optical transmission module 140 and the second optical transmission module 150 so as to be orthogonal to each other as in the present invention, it is possible to coordinate and calculate the optical transmission ratio in the form of x-y coordinates. Will be described with reference to Figs. 6, 7A and 7B.

As shown in FIG. 6, when it is assumed that the first light transmitting module 120 and the second light transmitting module 130 are not bent, that is, an ideal situation in which no external pressure is applied, The optical transmission ratio of the optical signal received by the optical fiber 150 is 100%.

At this time, as shown in FIGS. 7A and 7B, when a certain pressure is applied, a change in the optical transmission ratio is slight in any optical signal transmission module, but a change in the optical transmission ratio is significant in some optical signal transmission modules.

In FIG. 6, P1 and P2 indicate that the optical transmission ratio on the x-axis is 100% and the optical transmission ratio on the y-axis is 100%, but the pressure is applied as shown in FIGS. 7A and 7B, The optical transmission ratio to the x-axis is 70%, the optical transmission ratio to the y-axis is 70%, and the optical transmission ratio to the y- % to be.

The coordinates of P1 are changed from (100, 100) to (87, 97) and the coordinates of P2 are changed from (100, 100) to (70, 70) It can be determined that the pressure is greater than the pressure applied to P1.

The determination control unit 110 analyzes the optical signal received from the optical receiving module 150 to calculate the optical transmission ratio and determines the pressure distribution in the form of x-y coordinates.

It is clear that the number of the first optical transmission module 120 arranged in the x-axis and the number of the second optical transmission modules 130 arranged in the y-axis are not limited to those shown in the figure, If necessary, more optical transmission modules 120 and 130 can be disposed.

Here, the first and second light transmission modules 120 and 130 may be arranged to be orthogonal to the base 180, and the base may have a structure such as a matrix or a thin pad. As shown in FIG. 8, May be installed in the bottom wall inside the monitored building 600 or inside the vertical wall or at the time of constructing the building 600 on the main frame (column or frame frame). The judgment control unit 110 analyzes the change of the calculated pressure distribution and transmits the pressure change occurrence information to the management server 300 through the communication device 400 when the pressure suddenly changes beyond the reference value.

In addition, when the first and second optical transmission modules 120 and 130 are installed on a horizontal wall, that is, a floor or a ceiling wall, the first and second optical transmission modules 120 and 130 may detect a position that is deformed according to two axis coordinates, And when it is installed on a vertical wall, it is set as an xz coordinate or a yz coordinate value, so that the deformed position can be detected. Therefore, it is preferable that the first and second optical transmission modules 120 and 130 are set to have unique IDs for each installation position of the building 600, or the installation location information is stored and managed in the management server 300. Therefore, when the pressure suddenly changes beyond the reference value by analyzing the change of the pressure distribution sensed by the first and second optical transmission modules 120 and 130, the judgment control unit 110 compares the pressure change occurrence information and the pressure The management server 300 can immediately check the location where the abnormality signal of the building 600 is generated by matching the change occurrence position information with the management server 300 through the communication device 400. [

Meanwhile, the pressure distribution detection method may be implemented as a computer-readable code on a computer-readable recording medium, and the pressure sensing device 100 according to an embodiment of the present invention may be stored in a computer- Or by executing a computer program to perform the pressure sensing method.

A computer-readable recording medium includes all kinds of recording apparatuses in which data that can be read by a computer system is stored. For example, computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage, and the like.

In addition, the computer-readable recording medium may be distributed over network-connected computer systems so that computer readable codes can be stored and executed in a distributed manner. The functional programs, codes, and code segments for implementing the pressure sensing method according to an embodiment of the present invention can be easily deduced by programmers in the technical field of the present invention.

The output device 200 is controlled by the management server 300 to output information on the appearance of the monitored object to the monitored area based on the information sensed by the pressure sensing device 100. The output apparatus 200 includes an audio output unit 210 and a video output unit 220. The audio output unit 210 may include a speaker provided in a situation room or a management center, and outputs an emergency signal as an audio signal when the monitored object appears. For example, the audio signal may include the detected position information as a voice signal such as "Please observe the object is detected at the entrance of the first building, which is the monitored area, " .

The video output unit 220 may include a display panel that outputs the appearance position and appearance state information of the monitored object as a video signal. The video output unit 220 is installed in a control room, a management room, a work room, etc., and displays the location of the monitored object along with the map information of the monitored area on the display screen. have.

In addition, the management server 300 can control the appearance of the monitored object and the positional information, etc., in a pop-up window on the screen of the video output unit 220 when the monitored object appears.

The management server 300 controls the output device 200 according to the information from the pressure sensing device 100 to control the output of the appearance information of the monitored object in the monitored area, And controls the action situation to be performed.

Specifically, the management server 300 includes a storage unit 310, an input unit 320, a main control unit 330, and a call signal transmission unit 340. The storage unit 310 stores map information and manager information on the monitored area. For example, as shown in FIG. 8, when the monitored area is the specific building 600, the floor map information (plan view) of the building 600 and the area code A1 A9, B1 to B5) and the external area code C1 are stored together. Here, the area to be monitored inside the building 600 is divided into the office spaces 510, the corridor 520, and the entrance 530, respectively. The storage unit 310 may store manager information, that is, manager personal information, manager phone number, and the like, and may store contact information of a corresponding jurisdiction such as a police station.

The input unit 320 is provided for inputting information to be stored in the storage unit 310 and may be input through an external computer device or directly input information through input means such as a keyboard and a touch screen .

The main control unit 330 analyzes the data transmitted from the pressure sensing device 100 through the communication device 400 to determine whether or not a monitoring target object is present and outputs the monitored object through the output device 200 And controls to output information. Specifically, as described above, the main control unit 330 outputs a voice signal or the like through the audio output unit 210 so that the administrator can recognize the voice signal. The main control unit 330 also displays a popup window on the screen through the video output unit 220, So that the monitoring object appearance information and the position information can be output together so that the manager can recognize it immediately.

In addition, the main control unit 330 transmits emergency state occurrence information including appearance information of the monitored object to the manager (terminal) or a corresponding jurisdiction (police station, etc.) via the wired or wireless communication network through the paging signal transmitting unit 340 . Preferably, the emergency situation occurrence information includes at least one of character and voice information.

The communication device 400 includes a transmitter 410 for transmitting a signal generated by the pressure sensing device 100 and a receiver 420 for receiving information transmitted from the transmitter 410 and providing the received information to the management server 300 Respectively. The transmitting unit 410 may be installed individually in the pressure sensing apparatus 100 or may be integrated with the plurality of pressure sensing apparatuses 100. (Pressure change amount or abnormality signal generation information) together with the division code information (ID, position information), and transmits the pressure detection information (the pressure change amount or the abnormal signal generation information) to the receiving unit 420 It is good to do. The receiving unit 420 provides the received information to the management server 300. The transmitting unit 410 and the receiving unit 420 may include various communication modules capable of transmitting and receiving data through wired or wireless communication networks.

Accordingly, by transmitting the sensing signals from the plurality of pressure sensing devices 100 installed at each of the plurality of points of the monitoring target building 600 to the remote management server 300 in real time together with the location information (code information) (300) can identify a specific area (which can be divided into a floor, a building, etc.) of the building based on the abnormality signal occurrence information and confirm the occupation to patrol the building, or additionally monitor A camera can be installed and a specific area (pressure change occurrence point) of the building can be intensively monitored through the photographed image.

To this end, a plurality of surveillance cameras 500 may be installed in the monitored building 600 to photograph the plurality of points of the building 600 in real time and transmit them to the management server, or by remote control in the management server 300 It is preferable that the start and end of the photographing operation are controlled so that a specific area can be photographed only when necessary so as to be monitored.

The main control unit 330 controls the output device 200 to output the information indicating the change in pressure and the position information from the pressure sensing device 100. The call signal transmission unit 340, To the administrator (terminal) and a jurisdiction agency (fire department, government office, etc.), and furthermore, the surveillance camera 500 which is located to photograph the point where the pressure change occurs is controlled by remote control so as to photograph the suspicious area do. The image information photographed by the surveillance camera 500 is transmitted to the management server 300 and is output in real time through the audio output unit 220 so that the administrator can confirm the image information and the image information is stored in the storage unit 310 And can be used for future research and analysis.

In FIG. 8, reference numerals A1 to A4 denote intrinsic code information of column structures of the building 600, and reference numerals B1 to B3 denote examples of intrinsic code information of each floor or ceiling structure of the building 600 .

As described above, according to the building safety measurement system according to the embodiment of the present invention, the pressure sensing device 100 is installed in the structure of the monitored building 600 in a so-called mesh structure, It is possible to immediately detect the occurrence of an abnormal signal in a specific area of the building by detecting the pressure change due to the physical deformation of the structure when the physical deformation due to the collapse or destruction of the building structure occurs. Accordingly, it is possible to monitor the safety degree of the building 600 in real time, as well as to measure and monitor the safety degree in a remote place rather than a direct field visit.

In the event of an abnormal signal of building safety, follow-up measures (repair work, evacuation of persons, etc.) can be taken immediately by starting shooting and patrolling of the building 600, thereby preventing physical and personal damage due to collapse or damage of the building .

100 .. Pressure sensing device 110 .. Judgment control
120. First optical transmission module 130. Second optical transmission module
140 .. Optical signal transmission module 150 .. Optical signal reception module
170 .. connecting module 200 .. output device
210 .. Audio output unit 220 .. Video output unit
300 .. Management server 310 .. Storage
320. Input unit 330. Main control unit
340 .. call signal transmission unit 400 ... communication device
410 transmission unit 420 receiving unit
500 .. Surveillance camera 600 .. Building

Claims (10)

A pressure sensing device installed in the inside of the building structure and sensing a change in the pressure of a predetermined area when the structure is deformed;
An output device for outputting information on occurrence of a safety fault signal to the building based on the information detected by the pressure sensing device;
A control server for controlling the output device in accordance with the information from the pressure sensing device and performing a set follow-up action situation;
And a communication device for transmitting and receiving data between the pressure sensing device and the management server. The pressure sensor according to claim 1,
A first optical transmission module formed of a plurality of optical fibers, a plurality of optical fibers disposed at regular intervals, at least one of which is formed with a cut end;
A second optical transmission module arranged so as to be orthogonal to the optical fibers of the first optical transmission module at regular intervals and formed with at least one cut end and formed of optical fibers;
An optical signal transmission module for generating and outputting an optical signal to the inside of the first optical transmission module and the second optical transmission module through one end of the optical fiber;
An optical signal receiving module for receiving an optical signal output from the first optical transmission module and the second optical transmission module and converting the optical signal into an electrical signal and outputting the electrical signal; And
And a determination controller for analyzing the optical signal output from the optical signal receiving module and determining the optical transmission ratio of the first and second optical transmission modules. The pressure sensor according to claim 2,
Further comprising a base on which the first optical transmission module and the second optical transmission module are arranged orthogonally to each other,
Wherein the base is embedded in a building structure. 3. The method of claim 2,
Wherein the determination control unit analyzes the determined optical transmission ratio to calculate a pressure distribution in two-axis coordinates. 5. The method according to any one of claims 1 to 4,
The first optical transmission module or the second optical transmission module includes a plurality of optical transmission modules,
Further comprising a connecting module connecting the plurality of first optical transmission modules or the second optical transmission modules to each other so as to transmit light. The apparatus according to any one of claims 1 to 4,
An audio output unit for outputting an emergency signal as an audio signal when a safety fault signal of the building is generated;
And a video output unit for outputting the generated position and the generated state information as a video signal when a safety fault signal of the building is generated. The method according to claim 6,
Wherein the video output unit comprises:
And a display panel that is controlled by the management server so that information on location information and occurrence time of the building where the safety fault signal is generated is displayed on the map information of the building. The management server according to any one of claims 1 to 4,
A storage unit for storing map information and manager information for the building;
A main control unit for analyzing data transmitted from the pressure sensing device through the communication device to determine whether the safety abnormal signal is generated and outputting a safety abnormal signal generation information through the output device according to a determination result; Wherein the building safety degree measuring system comprises: 9. The system according to claim 8,
And a call signal transmission unit for transmitting emergency state occurrence information including safety fault signal generation information to the manager or a corresponding jurisdiction over wired or wireless communication when the safety fault signal is generated Measuring system. 9. The method of claim 8,
Wherein the main control unit controls the output of the safety fault signal to be popped up on a screen of a display panel of the output apparatus.

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