KR102324102B1 - Roof structure with earthquake detection sensor and Building safety management system using the same - Google Patents

Abstract

The present invention relates to a seismic isolator for a solar panel roof structure having an earthquake detection sensor, comprising: a connection unit fixed to a panel support unit supporting a solar panel covering an upper part of a building; an elastic unit to which the connection unit is connected and which includes an elastic unit body provided with a plate spring; an earthquake detection sensor connected to the connection unit to detect vibration according to earthquake or to detect collapse of a panel; and a support unit which supports both sides of the elastic unit and is fastened to a lower panel provided on the upper part of the building. An objective of the present invention is to provide the seismic isolator for the solar panel roof structure having the earthquake detection sensor which guarantees seismic isolation performance and can be universally applied to a roof structure.

Description

A seismic isolator for a solar panel roof structure having an earthquake detection sensor and a building safety management system using the same

The present invention relates to a seismic isolator for a roof structure having an earthquake detection sensor and a building safety management system using the same.

Prefabricated roof structures such as roof panels and solar panels are relatively easy to construct compared to other complex roofs, but due to the nature of the prefabricated structure, they are vulnerable to natural disasters such as earthquakes.

The main members of the above prefabricated roof structures include a steel structure beam such as an H-beam, a purlin perpendicular to the beam, upper and lower panels provided on the upper side of the purlin, and an insulation layer, and the members are clips or bolts, etc. are fastened to each other by a connecting member of

Therefore, when vibration is transmitted to the building due to an earthquake or strong wind, each member is shaken and stress is applied to the connecting member, and as the connecting members that cannot withstand this are damaged, there is a problem in that the members are separated from each other.

That is, since the conventional roof structure does not separately provide a device for buffering vibration when an earthquake occurs, the transmitted vibration directly affects the roof structure, and a serious collapse accident may occur.

Such collapse accidents occur most often near columns where the load by the upper roof structure is concentrated, and the collapsed structures may harm evacuees or become an obstacle to securing an evacuation route.

Therefore, when an earthquake occurs, one of the most important information that evacuees must check for survival is an emergency evacuation route and an emergency exit that are secured.

In general, the emergency evacuation route sign is small on the top of the side wall of the emergency evacuation route, and the emergency exit sign is also attached to the top of the emergency exit. there is a problem.

That is, the existing safety management system has a problem in that it cannot sufficiently deliver specific emergency situation information, such as a collapse location due to an earthquake, to an evacuee.

Moreover, if any one of a plurality of emergency evacuation routes and exits is collapsed, a serious problem of exposing them to a greater risk may occur if an evacuee attempts to escape through the emergency evacuation routes and emergency exits.

An object of the present invention is to provide a seismic isolator for a roof structure having an earthquake detection sensor, which has been devised to solve the above-mentioned problems of the prior art, and which guarantees seismic isolation performance and can be universally applied to a roof structure.

More specifically, it is an object of the present invention to provide a roof panel with guaranteed seismic isolation performance.

More specifically, an object of the present invention is to provide a solar panel assembly with a guaranteed seismic isolation performance.

Another object of the present invention is to guide an emergency evacuation route to an evacuee through a personal display device.

More specifically, an object of the present invention is to guide an evacuee to an optimal emergency evacuation route by analyzing a building structure and a dangerous situation.

According to an embodiment of the present invention, a connection portion fixed to the panel support for supporting the panel covering the upper end of the building; an elastic part to which the connection part is connected and which includes an elastic part body provided with a leaf spring; an earthquake detection sensor connected to the connection part to detect vibration according to an earthquake or to detect the collapse of the panel; and a support part that supports both sides of the elastic part and is fastened to a lower panel provided on the upper part of the building.

In an exemplary embodiment, the elastic unit body has a central portion curved upward to cushion vertical vibrations applied to the building, and the connecting portion becomes narrower in width from the upper portion to the lower portion and is connected to the central portion of the elastic portion body and a connecting part body that becomes have.

In an exemplary embodiment, the elastic part further includes sliding ribs protruding from both ends of the elastic part body, and the support part includes: a support body having a lower surface and both sides; and sliding slits formed on both sides of the support body and into which the sliding ribs are inserted, wherein the sliding slits are formed along the longitudinal direction of the support body, and the sliding ribs are inserted into the sliding slits to insert the support body The width may be wider than the width of the sliding rib so as to be movable along the longitudinal direction of the rib.

In an exemplary embodiment, the earthquake detection sensor may be an acceleration sensor.

In an exemplary embodiment, the earthquake sensor may be a pressure sensor.

In an exemplary embodiment, a plurality of earthquake detection sensors may be provided.

In an exemplary embodiment, it is applied to a seismic isolator for a roof structure having the seismic sensor, and receives a vibration or a collapse signal of the panel from one or more seismic sensors and evacuates to a personal terminal inside a building through a server A building safety management system for transmitting guidance information, the server comprising: an image generating unit generating image information among evacuation guidance information; a communication unit for transmitting and receiving information to and from the earthquake sensor and the personal terminal through a network; and a control unit that controls the image generating unit and the communication unit to transmit evacuation guidance information to the personal terminal when a detection signal is received through the communication unit. It can provide a building safety management system that uses

In an exemplary embodiment, on the screen of the personal terminal that has received the image information from the server, a first area guiding the evacuation direction in which the evacuee should immediately move from the point where the personal terminal is located is provided, and in the first area The evacuation route according to the guided evacuation direction is configured to exclude points where the panel has collapsed or there is a risk of collapse due to vibration. A direction may be guided to each of the first regions.

In an exemplary embodiment, a second area including an evacuation guide map showing an evacuation route of a building in which the personal terminal is located is provided on the screen of the personal terminal receiving the image information from the server, and the evacuation route is a panel It may be provided with an earthquake detection sensor, characterized in that configured to be excluded from the point determined to be collapsed or there is a risk of collapse due to vibration.

In an exemplary embodiment, the control unit may continue to transmit evacuation guidance information to the personal terminal until it receives location information confirming that the personal terminal has moved from the inside of the building to the outside of the building.

* The present invention has been devised to solve the above problems of the prior art, and has the effect of providing a seismic isolator for a roof structure having an earthquake detection sensor that can be universally applied to a roof structure and guarantees seismic isolating performance.

More specifically, the present invention has the effect of providing a roof panel with guaranteed seismic isolation performance.

More specifically, the present invention has the effect of providing a solar panel assembly with a guaranteed seismic isolation performance.

In addition, the present invention has an effect of guiding an emergency evacuation route to an evacuee through a personal display device.

More specifically, the present invention has an effect of guiding an evacuee to an optimal emergency evacuation route by analyzing a building structure and a dangerous situation.

1 is a perspective view of a seismic isolator for a roof structure having an earthquake detection sensor according to an embodiment of the present invention.
2 is an exploded perspective view of a seismic isolator for a roof structure having the earthquake detection sensor.
3 illustrates an example in which the seismic isolator for a roof structure provided with the earthquake detection sensor is installed on a roof structure.
4 is a schematic diagram of a building safety management system according to an embodiment of the present invention.
5 illustrates an evacuation guidance screen provided to a personal terminal by the building safety management system when an earthquake occurs.
6 shows a detailed configuration of the building safety management system.
7 illustrates a control method of the building safety management system.

Hereinafter, various embodiments of the present invention will be described with reference to the drawings.

First, an overall configuration of a seismic isolator for a roof structure having an earthquake detection sensor according to an embodiment of the present invention will be described with reference to FIG. 1 .

The seismic isolator 1 for a roof structure having an earthquake detection sensor according to an embodiment of the present invention may be installed on a roof structure covering the upper part of the building, and is installed on the roof structure to protect against external forces such as earthquakes or wind. Vibration transmitted to the roof structure can be attenuated.

To this end, the seismic isolator 1 for a roof structure having the earthquake detection sensor supports the connection part 12 fixed to the panel support part provided on the lower side of the panel covering the upper part of the building, and the connection part 12, It is fixed to the elastic part 11 provided with a leaf spring, the separation prevention part 13 which prevents the connection part 12 from leaving the elastic part 11, and the purlin 3 provided at the top of the building. It may include a support portion 14 fixed to the lower panel (2).

The elastic part 11 attenuates the forward, backward, left, right and vertical vibrations transmitted to the connection part 12 through the lower panel 2, so that the panel (roof panel, solar panel) is separated from the building by an earthquake. can be prevented

Conversely, the elastic part 11 may attenuate the vibration transmitted to the lower panel 2 through the connection part 12, which prevents the panel exposed to the outside from being shaken and damaged by strong wind. do.

In addition, the seismic isolator 1 for a roof structure having the seismic sensor is connected to the connection part 12 or the escape prevention part 13 to detect vibrations caused by an earthquake or to detect the collapse of the panel. (S) may be further included.

The earthquake detection sensor (S) is provided as a pressure sensor, and as the connection part 12 moves downward due to vibration or collapse of the panel and pressurizes the earthquake detection sensor (S), it is possible to detect an earthquake or collapse due to an earthquake. can

In addition, the earthquake detection sensor (S) may be provided as an acceleration sensor, based on the acceleration measured as the connection part 12 moves up and down due to vibration or collapse of the panel, earthquake or earthquake-induced collapse may detect it.

When the earthquake detection sensor S is provided as an acceleration sensor, vibration or collapse generated as the connection part 12 moves forward or backward or in the left and right directions by an earthquake may be detected by the configuration described below.

Hereinafter, a seismic isolator for a roof structure having an earthquake detection sensor according to an embodiment of the present invention will be described in detail with reference to FIG. 2 .

First, the elastic part 11 is provided at the center of the elastic part body 111, the elastic part body 111, which is a plate spring whose central part is curved upward to cushion vertical vibration, and the connection part 12 is inserted. A slit connecting part insertion hole 111a, a sliding rib 112 protruding from both ends of the elastic part body 111 and provided to be slidable on the support part 14, and protruding from both ends of the elastic part body 111 It may include a stopper rib 113 that prevents the elastic body 111 from being lowered by the weight of the panel and the panel support part 5 .

The elastic body 111, the sliding rib 112, and the stopper rib 113 may be manufactured by cutting and bending a single metal plate, and thus may be integrally formed.

Next, the support part 14 is formed on a lower surface 1411 and a support body 141 having both side surfaces 1412 supporting the stopper rib 113, and both side surfaces 1412 of the support body, and the sliding It may include a sliding slit 141a into which the rib 112 is inserted.

In more detail, the sliding slit 141a is formed along the longitudinal direction of both side surfaces 1412 of the support body, and the sliding rib 112 is inserted into the sliding slit 141a to extend the length of the both side surfaces 1412. A width of the sliding rib 112 may be greater than a width of the sliding rib 112 to be movable along the direction.

This is to attenuate the vibration transmitted to the panel support and the panel when the building structure vibrates in the same or similar direction to the longitudinal direction of the side surfaces 1412 of the support body.

The support part 14 may be fastened to the lower panel 2 of the roof structure, and the lower panel 2 is provided on the lower panel body 21 and the lower panel body 21 , and includes the support part 14 . It may include a seismic isolator accommodating unit 22 for a roof structure having an earthquake detection sensor that is a recess recessed downward to accommodate it.

In this case, the lower panel body 21 may be provided as a perforated panel.

On the other hand, the connection part 12 may include a connection part body 121 that is narrowed in width from the top to the bottom and is inserted into the connection part insertion hole 111a, and at least a part of the upper part of the connection part body 121 . The width of may be provided to be wider than the width of the connection part insertion hole (111a).

This is to stop at a specific point while descending after being inserted into the connector insertion hole 111a into which the connector body 121 is inserted.

In addition, a first hole 121a of the connector body into which a fastening member K for connecting the connector body 121 to the panel support 5 is inserted may be formed in the upper portion of the connector body 121 , , a connection part body second hole 121b into which a fastening member K for connecting the separation preventing part 13 is inserted may be formed in a lower portion of the connection part body 121 .

The separation preventing part 13 is provided in the lower portion of the elastic body 111, and the preventing body 131 fastened to the lower part of the connecting part body 121, and the connecting part body 121 is provided in the connection part insertion hole 111a. An elastic part contact rib 132 bent at the upper end of the prevention part body 131 to prevent it from being removed from the body 131 , and a fastening formed on the prevention part body 131 and connected to the connection part body 121 . It may include a body hole 131a for preventing the member K is inserted.

Accordingly, even if the connection part body 121 moves up and down due to vibration, the connection part body 121 may not be separated from the connection part insertion hole 111a.

FIG. 3 shows that the seismic isolator 1 for a roof structure provided with the seismic sensor is connected to the panel support 15 and the lower panel 2, which are one component of the roof structure.

As described above, the seismic isolator 1 for a roof structure having the earthquake detection sensor buffers vibrations in vertical and horizontal directions through the elastic part 11, and the supporting part 14 and the elastic part ( 11), vibration in the front-back direction (the longitudinal direction of the support part) can be buffered through the connection structure.

A beam-shaped furin P may be provided at a lower portion of the seismic isolator 1 for a roof structure having the seismic detection sensor, and horizontal members B1 and B1' are provided at the lower portion of the furlin, and the horizontal A column B2 may be provided under the members B1 and B1 ′.

In the building, since all the loads of the roof structure are concentrated on the pillars B2, the upper and lower portions of the pillars B2 are most vulnerable when an earthquake occurs, and when the pillars B2 collapse, serious human and property damage may occur.

Accordingly, the position of the earthquake detection sensor S of the seismic isolator 1 for a roof structure having the earthquake detection sensor according to an embodiment of the present invention is the position of the pillar B2, which is most vulnerable to collapse during an earthquake because the load is concentrated. It may be located on the upper side.

When a plurality of the earthquake detection sensors S are provided, they may be respectively provided on the upper side of the plurality of pillars B2 supporting the building.

Meanwhile, the seismic isolator for a roof structure provided with the earthquake detection sensor may be applied to a solar panel, which is one of the roof structures.

The seismic isolator 1 for a roof structure having the earthquake detection sensor may be applied to other types of roof structures in addition to the above-described roof panel and solar panel.

Hereinafter, referring to FIG. 4, building safety that receives vibration or panel collapse signals from the plurality of seismic sensors (S) and transmits evacuation guidance information to the personal terminal (A) inside the building through the server (E) Describe the management system.

The building safety management system is accessible to the network (W) through wired or wireless communication and a server (E) that stores information, a personal terminal (A) that transmits and receives information with the server (E), and a wired or It can be connected to the network (W) through wireless communication and may include the server (E), the user terminal (A), and the manager terminal (B) for transmitting and receiving information with the earthquake sensor (S).

A plurality of the personal terminal (A), the manager terminal (B), and the earthquake detection sensor (S) may be connected to the network as needed.

In this specification, a terminal may mean including any unit including a device that enables transmission through a wired or wireless Internet network.

That is, it corresponds to a device for accessing through the Internet, and broadly, input devices such as a keyboard and mouse for inputting various data, output devices such as monitors and printers, transceivers such as modems or LANs, microprocessors or graphic cards, etc. It may be composed of the same processing device and a storage device loaded with various programs for operating or controlling them.

For example, a personal communication system (PCS), a global system for mobile communications (GSM) terminal, a personal digital cellular terminal (PDC), a personal handyphone system (PHS) terminal, a personal information terminal (Personal) Digital Assistant; PDA), smart phone (Smart Phone), telematics (Telematics), wireless data communication terminal and / or portable Internet terminal, personal computer (Personal Computer), notebook (Notebook), and the like.

In addition, the server (E) may be composed of a dedicated hardware system and a wired/wireless communication network, as well as implemented through a virtual file-based web cloud service.

When the server (E) determines that the roof structure is collapsing or there is a risk of collapse due to an earthquake based on the information received through the earthquake detection sensor (S), in the server (E), the personal terminal (A) ) to transmit evacuation guidance information.

When the evacuation guidance information is received from the personal terminal (A), the screen shows the first area 81 that guides the evacuation direction in which the evacuee must immediately move from the point where the personal terminal is located and the building in which the personal terminal (A) is located. The second area 82 including the evacuation guide may be provided to be partitioned from each other.

In addition, when there are multiple personal terminals A, an evacuation direction optimized based on the location of each personal terminal A may be guided to each of the personal terminals A.

Through the present invention, it is possible to obtain an excellent effect of guiding an evacuation route optimized for individuals in different locations.

5 is an enlarged view of the second area 82 provided to the personal terminal A, and in the evacuation guide of the second area 82, each An evacuation route consisting of the shortest distance from the personal terminals A and A' to the emergency exits K2, K3, and K4 may be provided.

In addition, the evacuation route is configured to exclude the points K1 and K5 where the panel has collapsed or it is determined that there is a risk of collapse due to vibration, thereby ensuring the safety of evacuees.

The first area 81 is also guided in the same direction as the direction indicated in the second area 82 , but the direction in which immediate evacuation is required is larger and more clearly guided.

6 shows detailed configurations of the server (E).

The server (E) is a communication unit (92) for transmitting and receiving information with the earthquake detection sensor (S), the manager terminal (B) and the personal terminal (A) through a network, and a memory (93) for storing the structure information of the building , a location confirmation unit 94 that checks the locations of the earthquake detection sensor S and the personal terminal A in real time, and a voice generation that generates an evacuation guide voice among the evacuation guide information provided to the personal terminal A unit 96, an image generating unit 97 for generating image information among the evacuation guide information provided to the personal terminal A, a disaster information transmitting unit 17 for automatically transmitting a disaster signal to a related organization when an earthquake occurs, and the The control unit 91 may include a communication unit, a memory, a location check unit, a voice generation unit, an image generation unit, and a control unit 91 for controlling the disaster information transmission unit.

7 shows a control method of a building safety management system using a seismic isolator for a roof structure having an earthquake detection sensor controlled by the server control unit 91. With reference to this, evacuation guidance to a personal terminal when an earthquake occurs A flow for transmitting information is described.

The control method of the building safety management system may be configured to continuously transmit evacuation guidance information to the personal terminal (A) until the personal terminal (A) receives location information that is confirmed to have moved from the inside of the building to the outside of the building. have.

This is because, in the case of a strong earthquake with a risk of building collapse, aftershocks usually come several times after the main earthquake occurs.

Specifically, the control method of the building safety management system includes the steps of determining whether an earthquake detection signal is received from the server (E) (S1), automatically transmitting a disaster signal to an external related organization (S2), Step (S3) of checking the location of the earthquake detection sensor (S) and the location of the personal terminal (A) that detects the risk of collapse or collapse according to the earthquake when the earthquake detection signal is received (S3), earthquake detection that detects the risk of collapse or collapse Calculating an evacuation route optimized for each personal terminal A based on the information of the sensor S (S4), transmitting the evacuation guide information from the server E to each personal terminal A (S4) S5) may be included.

In addition, the control method of the building safety management system may further include a step (S6) of determining whether all the personal terminals A have moved out of the building.

In this step, if it is determined that all personal terminals (A) have moved out of the building, the evacuation guidance is terminated. The step of transmitting the evacuation guide information may be continued.

This is to guide the safe evacuation route in real time to individuals who could not evacuate in a building in danger of collapsing.

Even if the effect not described in this specification, the present invention may additionally have different effects of each of the above-described components, and derive a new effect that cannot be seen in the prior art according to the organic coupling relationship between each of the above-described components. can do.

In addition, the embodiments shown in the drawings may be modified and implemented in other forms, and if implemented including the configuration claimed in the claims of the present invention or implemented within the scope of equivalents, it shall be considered to belong to the scope of the present invention. something to do.

Seismic isolator for roof structure equipped with seismic sensor 1
Earthquake sensor (S) Elastic part 11 Elastic part body 111
Connection insertion hole 111a Sliding rib 112 Stopper rib 113
Connection part 12 Connection part body 121 Connection part body 1st hole 121a
Connection part body 2nd hole 121b separation prevention part 13 prevention part body 131
Prevention part body hole 131a Elastic part contact rib 132 Fastening member K
Support 14 Support body 141 Sliding slit 141a
Bottom 1411 Both sides 1412 Bottom panel 2
Server E Personal Terminal A Manager Terminal (B)

Claims (10)

An earthquake detection sensor comprising a connection part connected to a panel support for supporting a solar panel covering the upper end of a building, and a plurality of earthquake detection sensors for detecting vibration according to an earthquake or for detecting the collapse of the solar panel In the building safety management system for a solar panel roof structure,
a communication unit for receiving vibration or collapse signals of the solar panel from the plurality of earthquake sensors through a network, and transmitting and receiving information to and from a personal terminal;
an image generating unit generating image information including an evacuation route among the evacuation guide information; and
When a detection signal is received through the communication unit, a control unit for controlling the image generating unit and the communication unit so that the evacuation guide information is transmitted to the personal terminal;
On the screen of the personal terminal that has received the image information from the image generator,
A first area guiding only an evacuation direction in which the evacuee must move immediately at the point where the personal terminal is located and a second area including an evacuation guide map showing an evacuation route of the building in which the personal terminal is located are partitioned from each other and provided;
In the evacuation guide map of the second area,
An evacuation route consisting of the shortest distance from the personal terminal to the emergency exit among the points at which the solar panel has collapsed or it is determined that there is a risk of collapse due to vibration, and the route where the solar panel does not collapse and there is no risk of collapse due to vibration is provided,
The lower part of the panel support part is supported by a beam-shaped purlin parallel to the ground, and the lower part of the purlin is supported by a beam-shaped transverse member parallel to the ground, and the lower part of the horizontal member is perpendicular to the ground, and the panel and the supported by columns that support the load of the panel support,
The plurality of seismic sensors are
Located above the point where the pillar, the beam, and the purlin intersect
A building safety management system for a solar panel roof structure having an earthquake detection sensor, characterized in that. The seismic isolator for a solar panel roof structure used in the building safety management system for a solar panel roof structure having the earthquake detection sensor of claim 1,
an elastic part including an elastic part body provided with a plate spring for buffering vertical vibrations applied to a building by connecting the connection part to the central part curved upward; and
Supporting both sides of the elastic part, the support part is fastened to the lower panel provided on the upper part of the building; further comprising,
The connection part includes a connection part body having an upper side connected to the panel support part and a lower side connected to the elastic part body;
The elastic part is formed in the elastic part body, the connection part insertion hole to which the connection part body is connected; including;
A seismic isolator for a solar panel roof structure having an earthquake detection sensor, characterized in that. 3. The method of claim 2,
The elastic part
It further includes; sliding ribs protruding from both ends of the elastic body body;
the support
a support body having a lower surface and both sides; and
It further includes; a sliding slit formed on both sides of the support body and into which the sliding rib is inserted,
The sliding slit is
Doedoe formed along the longitudinal direction of the support body, the width of the sliding rib is wider than the width of the sliding rib so that the sliding rib is inserted into the sliding slit to move along the longitudinal direction of the support body
A seismic isolator for a solar panel roof structure having an earthquake detection sensor, characterized in that. 3. The method of claim 2,
The earthquake sensor
Accelerometer or pressure sensor
A seismic isolator for a solar panel roof structure having an earthquake detection sensor, characterized in that. According to claim 1,
the control unit
An earthquake detection sensor, characterized in that the personal terminal continuously transmits evacuation guidance information to the personal terminal until it receives the location information confirming that it has moved from the inside of the building to the outside of the building
Building safety management system for solar panel roof structures, characterized in that. delete delete delete delete delete

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