KR20170079165A - fire-prevention system possible earthquake observation - Google Patents

Abstract

The present invention relates to a fire prevention disaster prevention system capable of detecting an earthquake by realizing a differential analysis of a shaking motion in a building in order to notify an earthquake warning notification when an earthquake occurs and to increase a safe effective operation time by switching an emergency power state to an emergency power state A fire detection sensor attached to a ceiling or a wall surface of a building to detect a fire occurrence signal of at least one of heat, smoke, and flame and to have a visual alarm function by receiving an external control signal and changing a color; A fire receiver for receiving a fire signal from the fire detector to determine whether or not there is a fire and controlling the fire fighting equipment in the building as a whole and outputting a control signal to the fire detector; Amplifies and transmits the generated signal to receive and process An earthquake detection unit installed in the fire-fighting repeater for detecting information on a shaking motion in the building and transmitting the information to the fire receiver through the fire-fighting repeater; and a fire detector for detecting a fire or an earthquake from the fire receiver, And a terminal for wirelessly receiving the fire or seismic information and transmitting the fire or seismic information to an upper manager when the control signal is outputted.

Description

Fire-prevention system capable of earthquake detection {fire-prevention system possible earthquake observation}

The present invention relates to a fire prevention and disaster prevention system, and more particularly, to a fire prevention and disaster prevention system, in which a differential analysis of a shaking motion in a building is performed in real time to notify an earthquake warning notification when an earthquake occurs and to switch a normal power state to an emergency power state, And a fire fighting system capable of detecting an earthquake.

Currently, disaster prevention systems are designed to enable disaster management at large buildings and subway stations in the event of a disaster. In addition, the facility uses sensor detection signals such as fire sensors to identify disaster situations and actively cope with them. .

However, since such a station is located within the building or the history of the disaster, it can not be free from the disaster, and when the disaster is intensified, the disaster may reach the station and the station may lose control.

In this case, since the internal countermeasures become impossible, there arises a problem that the disaster prevention center such as the firefighting disaster headquarters can not but depend on external disaster prevention activities.

On the other hand, the alarm system is used when it is necessary to prevent damage by alarming the person when an alarm situation occurs in case of fire, security or safety.

Conventionally, when a dangerous situation such as a fire, an earthquake, or a gas leak occurs in a house or a building, a certain detector notifies an occupant or a building user of a dangerous situation by making an alarm sound. That is, if a fire or gas leakage occurs in a certain place such as a house or an office, a sensing device operates to activate a visual or audible alarm to confirm to the user. In addition, there may be a case where a danger warning service is provided in order to prepare for a dangerous situation by providing an automatic communication for contacting a relief facility such as a fire department or a police station for requesting assistance according to the operation of the alarm device.

Such a conventional emergency alarm system continuously provides a warning sound or a visual warning light to the user, but it is difficult for the user to know the exact position of the area where the disaster occurred and the dangerous situation.

Even if there is an automatic communication system with a fire department or a police station, it is only communicated to some system connected by a private line.

Therefore, in a case where a user does not know the structure of the building, for example, a case where the user can not quickly cope with a dangerous situation may cause a great damage. In addition, in the conventional automatic liaison system, users are unconditionally connected to the relief management system without being able to confirm them, so that when the relief management system is slightly delayed, it may be difficult to quickly cope with a dangerous situation.

In order to solve the above problem, the present invention provides a differential analysis of the shaking motion in a building in real time to notify an earthquake warning when an earthquake occurs, and to switch a normal power state to an emergency power state to increase a safe effective operation time And an object of the present invention is to provide a fire prevention system capable of detecting an earthquake.

According to an aspect of the present invention, there is provided a fire prevention system capable of detecting an earthquake, the fire detection system being attached to a ceiling or a wall of a building to detect a fire occurrence signal of at least one of heat, smoke, A fire receiver for controlling the fire fighting equipment in the building by receiving a fire signal from the fire detector to determine whether the fire is present or not and outputting a control signal to the fire detector, A fire-fighting repeater for amplifying and transmitting a fire occurrence signal sensed by the fire-fighting detector to receive and process the fire-related signal received by the fire receiver, and a control unit installed in the fire-fighting repeater to detect information in the building- To the fire receiver; And a terminal for wirelessly receiving the fire or seismic information and transmitting the fire or seismic information to an upper manager when a fire or an earthquake occurs in the fire alarm receiver and the control signal is output to the fire alarm detector.

The fire fighting system capable of detecting an earthquake according to the embodiment of the present invention has the following effects.

First, differential analysis of shaking in buildings can be performed in real time to notify an earthquake warning when an earthquake occurs, and to switch the normal power state to the emergency power state to increase the safe effective operation time.

Second, by analyzing vibration caused by earthquake and general vibration, seismic alarm can be detected by converting the color of fire detector and guidance light so that people in the building can evacuate through visual alarm.

1 is a block diagram schematically showing a fire prevention system capable of detecting earthquakes according to the present invention
Figure 2 is a schematic representation of the fire detector of Figure 1;
3 is a block diagram schematically showing a fire prevention system capable of detecting an earthquake according to another embodiment of the present invention
Fig. 4 is a view schematically showing the evacuation guidance lamp of Fig. 3

Hereinafter, the present invention will be described in detail with reference to the drawings. It is to be noted that the same elements among the drawings are denoted by the same reference numerals whenever possible. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

1 is a block diagram schematically showing a fire prevention system capable of detecting an earthquake according to the present invention.

As shown in FIG. 1, a fire prevention system capable of detecting an earthquake according to the present invention is installed on a ceiling or a wall of a building to detect a fire occurrence signal of at least one of heat, smoke, and flame, receives an external control signal A fire detector 110 having a visual alarm function through a color change and a fire detection signal from the fire detector 110 to determine whether or not there is a fire to control the fire fighting equipment in the building as a whole, (130) for amplifying and transmitting a fire occurrence signal sensed by the fire detector (120) to the fire receiver (120) to receive and process the fire occurrence signal, (130), detects information on the shaking of the building, and transmits the information to the fire receiver (120) through the fire-fighting repeater (130) And a control unit for receiving the fire or seismic information wirelessly and transmitting the fire or seismic information to an upper manager when a fire or an earthquake occurs from the fire receiver 120 to output the control signal to the fire detector 110 And a terminal 150.

The fire receiver 120 includes an A / D converter 121 for converting an analog signal of a fire and an earthquake generated through the fire-fighting repeater 130 into a digital signal, and an A / D converter 121 A gateway module 122 for receiving a digital signal from the A / D converter 121 to determine whether a fire has occurred, and outputting a control signal to the fire detector 110; And an earthquake determination unit (123) for determining whether or not an earthquake has occurred by performing in real time.

The earthquake sensing unit 140 senses the occurrence of an earthquake through acceleration and tilt measurement.

The earthquake determination unit 123 receives the information about the shaking in the building transmitted from the earthquake sensing unit 140, performs differential analysis in real time, filters the general vibration, determines only an earthquake, If the gateway module 122 determines that the earthquake is caused by the earthquake determination unit 123, the fire alarm detector 110 outputs a control signal to the fire detector 110 so that the fire detector 110 emits red light, So that the user can quickly respond to the earthquake warning by visually informing the user of the earthquake warning.

In addition, when the earthquake determination unit 123 determines that the earthquake is caused by an earthquake, the earthquake determination unit 123 informs an upper level manager of an earthquake alert notification by SMS to the terminal 150, To the emergency power state, thereby increasing the safe effective operation time so as to cope with emergency situations promptly.

In addition, the fire receiver 120 receives a fire occurrence signal from the fire detector 110, analyzes it in the gateway module 122, and outputs a control signal to the fire detector 110 when it is determined that a fire has occurred The fire alarm can be visualized by inducing the fire detector 110 to emit red light.

Although the fire receiver 120, the A / D converter 121, and the gateway module 122 are shown as a single unit, they may be separately configured.

The gateway module 122 is not specifically shown in the drawing, but includes a power source, a storage and control unit, and a communication unit.

FIG. 2 is a schematic view of the fire detector of FIG. 1; FIG.

2, the fire detector 110 includes a main body case 111, an optical fiber 112, a battery BATT 113, a human body sensor 114, an RF sensor 115, an LED driving unit 116, a red LED 117, a green LED 118, and an MCU 119.

Here, the main body case 111 is attached to a ceiling or a wall surface, and has an internal space for mounting the components.

The optical fiber 112 is configured to surround the inner space of the body case 111. A red LED 117 is coupled to one side of the optical fiber 112 and a green LED 118 is coupled to the other side.

That is, a red LED 117 is inserted into one side of the optical fiber 112 and a green LED 118 is inserted into the other side. When the red LED 117 emits light, the entire optical fiber 112 is irradiated with red light And when the green LED 118 emits light, the entire optical fiber 112 emits green light.

The battery 113 is a rechargeable type and supplies power to the human body sensor 114, the RF sensor 115, the LED driver 116, and the MCU 119 when commercial power is not supplied.

The human body detection sensor 114 is provided to detect presence of a person and to detect the presence of a person in the indoor space without being able to evacuate when a fire occurs.

The MCU 119 controls the LED driving unit 116 to drive the red LED 117 in the absence of a human being, And controls the red light to be turned on or blinking at a predetermined time through the optical fiber 112.

If the presence of a person is confirmed in the indoor space through the human body sensor 114, the MCU 119 controls the LED driving unit 116 installed in the area where the person is found, So that the green light is turned on or blinks at a predetermined time through the optical fiber 112.

Accordingly, even when a fire is not generated and can not be prepared, the green LED 118 is selectively illuminated through the human body sensor 114 installed inside the main body case 111, I can cope.

Meanwhile, the human body detection sensor 114 may be configured to detect not only the presence of a human being but also an operation, thereby preventing human accidents due to a fire.

The RF sensor 115 is a communication device and transmits signals to and from an adjacent sensor through Bluetooth communication. Here, although the RF sensor 115 is described as an example in the embodiment of the present invention, the present invention is not limited to the specific communication method, You can also send and receive.

The MCU 119 controls the LED driving unit 116 in response to a control signal from the fire receiver 120. The LED driving unit 116 drives the red LED 117 according to the control of the MCU 119, Or the green LED 118, as shown in FIG.

The MCU 119 can adjust the driving time of the LED driving unit 116. For example, the MCU 119 selectively emits the red LED 117 or the green LED 118 to turn on the red LED 117 when a fire occurs So as to have a predetermined period so that people can easily check it.

Here, the MCU 119 and the LED driver 116 are separately described. However, the present invention is not limited to this, and a control unit may be used.

On the other hand, the main body case 111 is formed by being stacked on a ceiling or a bracket (not shown) provided on a wall surface.

FIG. 3 is a schematic view of a fire prevention system capable of detecting an earthquake according to another embodiment of the present invention.

As shown in FIG. 3, the fire prevention system capable of detecting an earthquake according to another embodiment of the present invention has the same configuration as that of FIG. 3 except that it guides the escape route through an evacuation guide light 160.

That is, the evacuation guidance lamp 160 is installed on a wall or a ceiling of a building to receive a control signal from the fire receiver 120 in an emergency such as an earthquake or a fire to emit green light to guide the evacuation direction.

A gateway 170 is additionally installed to receive control from the fire receiver 120 to apply a control signal to the evacuation guidance lamp 160. At this time, one or more of the gateways 170 may be installed so that all the evacuation guidance lights 160 receive the control signal from the fire receiver 120.

Fig. 4 is a schematic diagram showing the evacuation guidance lamp of Fig. 3; Fig.

4, the evacuation guidance lamp 160 includes a main body case 161, an optical fiber 162, an emergency battery (BATT) 163, a human body detection sensor 164, an RF sensor 165, A second LED module 166 and 167, a red LED 168, a green LED 169, first and second white LEDs 171 and 172, and an MCU 173.

Here, the body case 161 is attached to a ceiling or a wall surface, and has an internal space for mounting the components. It is attached to the ceiling or the wall to be the main body of the guide light, and is used for a passage guide light, an evacuation guide light, an audience guide light.

The optical fiber 162 is configured to surround the inner space of the body case 161. A red LED 168 is coupled to one side of the optical fiber 162 and a green LED 169 is coupled to the other side.

That is, a red LED 168 is inserted into one side of the optical fiber 162, and a green LED 169 is inserted into the other side. When the red LED 168 emits light, the entire optical fiber 162 emits red light And when the green LED 169 emits light, the entire optical fiber 162 emits green light.

The optical fiber 162 is disposed so as to surround the inner space of the main body case 161. When the optical fiber 162 has a certain angle at an edge portion due to the characteristics of the optical fiber 162, The portion is arranged to have a certain curvature in a round shape.

The emergency battery 163 is a rechargeable battery and is connected to the first LED 166 through the emergency battery 163 when no power is supplied to the first LED module 166 from an external power supply unit through the MCU 173. [ The module 166 is supplied with power and the first white LED 171 is turned on.

The emergency battery 163 receives a control signal from a fire receiver when an emergency such as a fire occurs and controls the second LED module 167 by the MCU 173 to turn on the red LED 168 or the green LED And selectively emits the second white LEDs 172 along with the first white LEDs 169.

The human body detection sensor 164 is provided to detect presence or absence of a person and can detect the presence of a person in the indoor space without being able to evacuate when a fire occurs.

The MCU 173 controls the second LED module 167 to drive the red LED 168 to emit light through the optical fiber 162 By controlling red light to be on or blinking for a certain period of time, people residing in the room can visually confirm that a fire has occurred.

If the human presence is confirmed through the human body sensor 164, the MCU 173 controls the second LED module 167 installed in the area where the person is found, 169 to control the green light to be turned on or blink at a predetermined time through the optical fiber 162, thereby making it possible to more quickly rescue a person who is not evacuated.

Accordingly, even when a fire occurs and it is impossible to comply with the fire, the green LED 169 is selectively emitted through the human body detection sensor 164 installed in the body case 161 to promptly fire the fire- I can cope.

In addition, the second LED module 167 emits a red LED 168 in a fire area, and emits a green LED 169 in a non-fire area to fire people residing in the indoor space It can inform you quickly, and guide you to evacuate to a fire-free area.

Meanwhile, the human body detection sensor 164 can be configured not only to detect the presence of a person but also to detect an operation, so that a person who requests a structure without being able to evacuate can be identified and a human accident due to a fire can be prevented in advance.

The human body detection sensor 164 can perform a crime prevention function to monitor an intruder at a specific time. That is, when an intruder is detected through the human body detection sensor 164 at a specific time, the MCU 173 notifies the intruder of the intruder, and the MCU 173 turns on or flashes the red LED 168, And can notify the external administrator.

In addition, the red LED 168 is sequentially lit in accordance with the movement path of the intruder, so that the path of the intruder can be grasped.

The RF sensor 165 serves as a communication device to transmit a signal through an RF communication with an adjacent sensor. Here, although the RF sensor 165 is described as an embodiment in the embodiment of the present invention, the RF sensor 165 is not limited to the specific communication method but may be a Wi-Fi communication, a bluetooth and a beacon communication, You can also send and receive.

Here, the RF sensor 165 communicates with neighboring RF sensors to transmit information to each other when a fire generation signal is received.

The MCU 173 receives the sensor analog contact signal from the fire receiver through the RF sensor 165 to control the second LED module 167 and the second LED module 167 controls the MCU 177. [ 173 to selectively drive the red LED 168 or the green LED 169.

The MCU 173 can adjust the driving time of the second LED module 167. For example, the MCU 173 selectively emits the red LED 168 or the green LED 169, So as to have a predetermined period so that people can easily confirm the light emission.

Although the MCU 173 and the second LED module 167 are described as being separate from each other, the present invention is not limited thereto.

The first white LED 171 is connected to the external power supply unit so that the first white LED 171 is kept in a lighted state. If it is determined that the power is not supplied through the MCU 173, 163, respectively.

Meanwhile, the emergency battery 163 and the external power supply unit are provided with a switching circuit 174, which may selectively supply power through the switching circuit 174. [

The second white LEDs 172 are formed of LEDs having higher brightness than the first white LEDs 171. When an emergency occurs such as a fire, the second white LEDs 172 are controlled through the second LED module 167, Function.

In addition, the MCU 173 receives the fire occurrence information or the shaking information of the building and transmits it to the fire receiver 120 in a wired or wireless manner. The fire receiver 120 receives and analyzes the fire occurrence signal It is determined whether or not the fire-fighting equipment operates.

The evacuation guidance lamp 160 according to the present invention configured as described above receives a fire occurrence signal or an earthquake detection signal from the fire detector or the fire receiver from the RF sensor 165 in a state in which the first white LED 171 normally emits light The MCU 173 selectively emits a red LED 168 or a green LED 169 connected to the second LED module 167 so that people in the building can quickly evacuate You will be guided to do so.

At this time, the RF sensor 165 communicates with neighboring guide lights to emit a red LED 168 in a region where a fire has occurred and an area adjacent thereto, and a green LED 169 emits a green LED 169 in a non- Guide the pizzas to evacuate quickly to areas where there is no fire.

In addition, when a fire occurrence signal is received through the fire detector or the fire receiver, the red LED 168 is turned on or blinked to indicate that a fire has occurred quickly by performing RF communication between the adjacent evacuation lights 160, .

Further, the arrow direction of the evacuation guidance lamp 160 is indicated, and the arrow direction is displayed by the light emission of the red LED or the green LED.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments or constructions. Can be carried out within a limited range. Accordingly, such modifications are deemed to be within the scope of the present invention, and the scope of the present invention should be determined by the following claims.

110: fire detector 120: fire receiver
130: fire-fighting repeater 140: earthquake detection unit
150:

Claims (7)

A fire detector attached to a ceiling or a wall of a building to detect a fire occurrence signal of at least one of heat, smoke, and flame and to receive an external control signal and to have a visual alarm function through color change;
A fire receiver for controlling the fire fighting equipment in the building by receiving a fire signal from the fire detector to determine whether or not there is a fire and outputting a control signal to the fire detector,
A fire-fighting repeater for amplifying the fire occurrence signal detected by the fire detector to the fire receiver so as to receive and process the fire occurrence signal,
An earthquake detection unit installed in the fire-fighting repeater for detecting information on a shaking in the building and transmitting the information to the fire receiver through the fire-
And a terminal for wirelessly receiving the fire or seismic information and transmitting the fire or seismic information to an upper manager when a fire or an earthquake occurs from the fire receiver to output a control signal to the fire detector. . [2] The fire alarm system of claim 1, wherein the fire receiver comprises: an A / D converter for converting an analog signal of fire and earthquake generated through the firefighting repeater into a digital signal and outputting the digital signal; A gateway module for determining the presence or absence of a fire and outputting a control signal to the fire detector; and a digital module for receiving the digital signal of the A / D converter through a gateway module through RF communication to perform differential analysis in real time, And an earthquake determination unit for detecting the earthquake. 3. The gateway module according to claim 2, wherein the earthquake determination unit receives the information about the shaking in the building transmitted from the earthquake sensing unit, performs differential analysis in real time, filters general vibration and determines only an earthquake and sends it to the gateway module, Wherein the control unit outputs a control signal to the fire detector when the earthquake determination unit determines that an earthquake has occurred, so that the fire detector emits red light to visually generate an earthquake warning to residents in the building. system. The fire detector of claim 1, wherein the fire receiver receives a fire occurrence signal from the fire detector, analyzes the fire signal in the gateway module, and outputs a control signal to the fire detector when it is determined that a fire has occurred to cause the fire detector to emit red light Wherein said earthquake detection system comprises: [2] The fire detector according to claim 1, wherein the fire detector comprises: a main body case attached to a ceiling or a wall surface and having an internal space; an optical fiber formed along an edge of the internal space of the main body case; A green LED inserted into the other end of the optical fiber to emit green light, a human body sensor installed in an inner space of the main body case to detect the presence or absence of a human body around the main body case, A wireless communication module that wirelessly communicates with other adjacent body cases and transmits a fire occurrence signal to the fire receiver through the wireless communication; and a red LED or a green LED And a control unit for selectively driving the earthquake- A Fire Prevention System. [Claim 2] The lighting system of claim 1, further comprising an evacuation lighting unit installed on a wall or a ceiling of the building to emit green light in response to a control signal from a fire receiver in an emergency such as an earthquake or fire, Fire prevention system capable of earthquake detection. [Claim 7] The apparatus according to claim 6, wherein the evacuation guidance lamp comprises a body case attached to a ceiling or a wall surface and having an internal space, an optical fiber formed along an edge of the internal space of the body case, A red LED and a green LED for emitting green light, a human body sensor installed in an inner space of the main body case to detect the presence or absence of a human body around the main body case, A wireless communication module for receiving a fire occurrence signal from the fire detector through the wireless communication and transmitting the fire signal to the outside, a first white LED installed inside the main body case and supplied with power from an external power supply half, A battery installed in the body case for supplying power to the first white LED in an emergency, A control unit installed in the body case to receive a fire generation signal through the wireless communication module to control the battery and selectively emit the red LED and the green LED, And a second white LED for receiving a control signal from the control unit to guide the evacuation direction by lighting or flashing in an emergency.

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