KR101807264B1 - mono type firefighting sensor of based IoT - Google Patents

Abstract

The present invention relates to an IoT-based stand-alone fire detector for preventing fire accidents due to a fire by guiding the evacuation route together with a visual warning of the occurrence of a fire. The present invention relates to a stand-alone fire detector which is attached to a ceiling or a wall, The first and second optical fibers are inserted into one end of the first optical fiber and emit red light. The red LED is inserted into the other end of the first optical fiber and emits green light. A blue LED inserted in one end of the second optical fiber to emit blue light and a yellow LED inserted in the other end to emit yellow light; A human body detecting sensor for detecting carbon monoxide, a CO sensor for detecting carbon monoxide, a humidity sensor for detecting humidity, an RF sensor for communicating with the outside, , A human body sensor, a CO sensor, a humidity sensor, and a fire signal to receive at least one signal, and receives a control signal for driving any one of the red LED, the green LED, the blue LED, And a control unit for outputting a control signal for controlling the LED lighting lamp installed in the main body.

Description

[0001] The present invention relates to an IoT-based single fire detector,

The present invention relates to a fire detector, and more particularly, to an IoT-based stand-alone fire detector in which fire escape is prevented by visually warning a fire occurrence and guiding the escape route.

Generally, an induction lamp for evacuating a person in an emergency can be divided into an evacuation guidance light and a pathway guidance light. An evacuation guidance light is installed to easily grasp the escape door in an emergency. The passageway guide light is provided to pass through a hallway, And is installed to be able to inform the direction of evacuation in an emergency.

In this way, the guide light is a device that easily tells the direction and evacuation location to the pizza player in case of a disaster such as a fire, and guides the pizza player in that direction. That is, the guide light is required to have high visibility so that the evacuee can easily recognize the position of the emergency exit or the evacuation site, and low power consumption is required so that the emergency battery can be lit by the emergency battery for a long time.

These guide lights are installed on the wall, installed on the floor, and installed on the ceiling, so that people can quickly escape to a safe place in the event of a fire in a building, a subway, or in an emergency.

1 is a block diagram for explaining an operation system and principle of a fire prevention system according to the prior art.

The prior art fire fighting / disinfection system is composed of a detector 10, a transmitter 20, a receiver 30, an alarm / firefighting facility 40, and a fire / location indicating facility 50, as shown in FIG. The fire alarm device 40 and the fire / location display device 50 are operated to apply a fire signal to the fire alarm device 40 and the fire / do. That is, the detector 10 automatically generates a fire signal in the event of a fire, and the transmitter 20 transmits a fire signal when the button is pressed. When the receiver 30 receives a fire signal from the detector 10 and the transmitter 20, the receiver 30 applies an operation signal to the alarm / fire-fighting facility 40 to activate the fire-fighting facility along with the alarm, 50 to indicate fire and location.

On the other hand, the fire fighting and disinfection system according to the prior art monitors the fire in real time and operates the equipment to operate automatically when a fire occurs. These facilities include emergency broadcasting equipment, automatic fire alarm equipment, and three-wire lighting equipment.

Fig. 2 is a schematic diagram showing a fire prevention / disaster prevention system according to the prior art.

As shown in FIG. 2, the conventional fire fighting / disinfection system comprises a plurality of detectors 10, a transmitter 20, and a receiver 30 for each boundary region. Here, the receiver 30 includes a relay 31, which is connected to a fire indicator 32, a globe indicator 33, an alarm facility 34 and a fire station 35, .

A resistor 21 is provided at the end of the transmitter 20 so that only a small amount of current flows. However, when a current equal to or greater than a predetermined value flows through the circuit, the relay 31 operates to operate the fire indicator 32, the earth indicator 33, the alarm facility 34, and the associated fire fighting facility 35 .

The detector 10 functions as a switch 11 in a circuit, and functions to cause a current exceeding a predetermined value to flow. That is, when a fire occurs, the switch 11 is automatically closed to allow a current equal to or greater than a predetermined value to flow. When the person presses the push switch 22, the switch is closed so that a current of more than a certain value can flow.

In the R type system, when the detector 10 or the transmitter 20 operates, a specific communication signal is transmitted to the receiver 30 and the relay 31 is connected to the relay 30, .

Meanwhile, the detector 10 should include a sensor function for detecting a physical or chemical change amount generated when a fire occurs, a determination function for determining whether or not it is a fire, and a transmission function for transmitting a fire signal to a receiver.

Here, the sensor function of the sensor 10 causes physicochemical changes of heat, smoke, and flame (flame). At this time, the detector 10 senses one or two of the physicochemical changes. The sensor 10 senses heat according to an object to be sensed, a smoke detector that detects smoke, a flame sensor that detects a flame, And a hot-melt detector for detecting the temperature.

The determination function of the detector 10 determines that the fire is a fire if the amount of physico-chemical change due to the fire lasts more than a predetermined amount of time. The amount of physicochemical change, which is a criterion for determining that the detector 10 is a fire, is defined in the sensor type approval and verification technical standard rule and is referred to as sensitivity. The sensitivity is classified into scoop, 1, 2, and 3 types, and responds to small changes as the scoop increases. The determination function is generally performed by the sensor 10 itself, but the analog type sensor transmits only the amount of physicochemical change around the sensor to the receiver, and the determination of the fire is made in the receiver.

The originating function of the detector 10 is a fire signal sent to the receiver 30, and includes a contact signaling method and a communication signaling method.

The contact signaling system is a method of establishing a contact point to a wire connected to a sensor from a receiver, and when a current flows, it is a fire.

The communication signal system is a system in which a communication device is built in a detector and a receiver to exchange communication signals with each other. However, since the detector incorporating the communication device is disadvantageous in that it is economically burdensome, the receiver incorporates a communication device and constitutes a signal conversion device for converting a contact signal into a communication signal between the sensor 10 and the receiver. In addition, a sensor having a built-in communication device can send not only a fire signal but also an address of the sensor 10 together. Such a sensor is called an address type sensor.

The principle of automatically closing the switch 11 of the detector 10 is to utilize the expansion force of the air generated by the fire and to change the physicochemical change occurring during the fire into the current flow to close the circuit.

First, the method using the inflation force of air is called a differential type air-type heat sensor. However, when the temperature rises due to the occurrence of a fire, the air in the air chamber expands and pushes up the thin film to close the contact.

A method of converting the current into a current flow is a method of converting the amount of heat, smoke, and flame generated in a fire into an electric current to close the contact by using the electromagnetic force.

In addition, the smoke detector-photoelectric sensor uses the principle that smoke blocks or reflects light, and uses a light emitting element that emits light and a photoelectric element that converts light into electricity. The photoelectric sensor can be of the spot type, the separable type, and the air suction type.

A relay or relay is a device that generates electromagnetic force when a coil is energized by using the principle of an electromagnet to form a contact. A relay is formed inside the detector to convert heat, smoke, and flame generated in a fire into a current flow so that the relay operates to transmit a signal to the receiver.

However, the fire detector of the fire-fighting system according to the prior art has a disadvantage that a separate indicator lamp must be installed as a fire indicator because it includes only a sensor function for detecting a fire, a judgment function, and a calling function.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an IoT-based single fire detector for allowing a person to promptly detect a fire occurrence alarm and thereby safely evacuate by turning on or blinking a warning light, The purpose is to provide.

It is another object of the present invention to provide an IoT-based stand-alone fire detector which can minimize the damage of a person by quickly locating and rescuing a person who can not escape during a fire.

In addition, according to the present invention, the red LED is turned on or blinked in the area where the fire occurs in the fire, and the green LED is turned on or blinked in the area where the fire does not occur so that people can evacuate to the area where the fire does not occur quickly It is an object of the present invention to provide a single fire detector based on an IoT.

It is another object of the present invention to provide an IoT-based stand-alone fire detector which is capable of rapidly evacuating people and reducing human injury by controlling green LEDs to be sequentially turned on in the direction of escape when a fire occurs.

It is another object of the present invention to provide an IoT-based stand-alone fire detector which is operable in conjunction with an indoor lighting lamp to visually inform a fire alarm through an LED illuminating lamp by controlling the hue or color temperature of a lighting lamp when a fire occurs.

It is another object of the present invention to provide an IoT-based single fire detector which detects colorless odorless carbon monoxide (CO) and visually informs an alarm through an illuminating lamp or a detector.

It is another object of the present invention to provide an IoT-based standalone fire detector which is capable of threatening and reporting through tracing LED control when a set time intruder is generated and having a security function by generating a voice warning or a siren.

In order to accomplish the above object, the present invention provides a single fire detection system based on IoT, comprising: a main body case attached to a ceiling or a wall surface and having an internal space; 1, a second optical fiber, a red LED inserted into one end of the first optical fiber to emit red light, a green LED inserted into the other end and emitting green light, and a second LED inserted into one end of the second optical fiber to emit blue light A yellow LED inserted in the other end and emitting yellow light, a human body sensor installed in the inner space of the body case for detecting the presence or absence of a human body, a CO sensor for detecting carbon monoxide, a humidity sensor A sensor, an RF sensor for communicating with the outside, and at least one or more of the human body sensor, the CO sensor, the humidity sensor, And a control unit for receiving a control signal for controlling the LED lighting lamp installed in the indoor space together with a control signal for driving any one of the red LED, the green LED, the blue LED and the yellow LED, do.

The IoT-based stand-alone fire detector according to the embodiment of the present invention has the following effects.

First, when a fire is detected through the detector, the warning indicator that is integrated with the detector is turned on or blinking, so that people can quickly identify the fire alarm and can safely evacuate.

Second, it can minimize the damage of people by quickly identifying and restoring the position of the person who can not evacuate in case of fire.

Third, in the area where the fire occurs, the red LED is turned on or blinking, and in the area where the fire does not occur, the green LED is turned on or blinking so that people can quickly evacuate.

Fourth, it is possible to quickly evacuate people by controlling green LEDs to turn on sequentially in the direction of evacuation route in case of fire.

Fifth, it is possible to visually inform the fire alarm through the lighting lamp by controlling the color or the color temperature of the lighting lamp in case of fire in conjunction with the LED lighting lamp installed in the room.

Sixth, colorless odorless carbon monoxide (CO) can be detected and visual alarm can be informed through LED light or detector.

Seventh, it is possible to threaten and report by tracing LED control in case of intruder setting time zone, and to have a security function by generating voice warning or siren.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a block diagram for explaining an operation system and principle of a fire prevention system according to the prior art; FIG.
2 is a block diagram schematically showing a conventional fire fighting / disaster prevention system
3 is a block diagram schematically showing an IoT-based single fire detector according to the present invention
4 to 7 are views showing a state in which the fire detector of FIG. 3 emits blue, yellow, red, and green, respectively
8 is a view showing a state of controlling the LED lighting lamp through the fire detector 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.

FIG. 3 is a block diagram schematically showing an IoT-based single fire detector according to the present invention.

3, the IoT-based single fire detection system 100 according to the present invention includes a body case 110, first and second optical fibers 120 and 130, a battery 140, The first sensor module 150 and the second sensor module 150 may include a RF sensor 160, a humidity sensor 170, a CO sensor 180, first and second LED modules 190 and 200, a red LED 210, A blue LED 230, a yellow LED 240, a relay 250, an audio 260 and an MCU 270.

Here, the main body case 110 is attached to a ceiling or a wall surface, and has an internal space for mounting the components. The main body case 110 is stacked on a ceiling or a wall bracket (not shown).

The first and second optical fibers 120 and 130 are spaced apart from each other by a predetermined distance so as to surround the inner space of the main body case 110 and the optical interference between the first and second optical fibers 120 and 130 The shielding film 131 is formed.

A blue LED 230 is coupled to one side of the first optical fiber 120 and a yellow LED 240 is coupled to the other side of the first optical fiber 120.

That is, a blue LED 230 is inserted into one side of the first optical fiber 120 and a yellow LED 240 is inserted into the other side of the first optical fiber 120. When the blue LED 230 emits light, The entirety of the first optical fiber 120 emits blue light, and when the yellow LED 240 emits light, the entire first optical fiber 120 emits yellow light.

A red LED 210 is coupled to one side of the second optical fiber 130 and a green LED 220 is coupled to the other side.

That is, a red LED 210 is inserted into one side of the second optical fiber 130 and a green LED 220 is inserted into the other side of the second optical fiber 130. When the red LED 210 emits light, The whole of the second optical fiber 130 emits red light, and when the green LED 220 emits light, the second optical fiber 130 emits green light as a whole.

The battery 140 is a rechargeable lithium-ion battery. When the commercial power is not supplied, the battery 140 is connected to the human body sensor 150, the RF sensor 160, the humidity sensor 170, the CO sensor 180, The first and second LED modules 190 and 200, the relay 250, the audio 260, and the MCU 270.

The human body detecting sensor 150 is provided to detect presence or absence of a person and can detect a person in the indoor space when a fire occurs.

The MCU 270 controls the second LED module 200 to drive the red LED 210 in the absence of a human being, So that the red light is turned on or blinks at a predetermined time through the second optical fiber 130.

If the presence of a person is confirmed in the indoor space through the human body sensor 150, the MCU 270 controls the second LED module 200 installed in the area where the person is found, 220 so that the green light is turned on or blinks for a predetermined time through the second optical fiber 130.

When there is a person in the space where the fire is generated through the human body sensor 150, the RF sensor 160 informs the neighboring detector of the presence of the person and finally notifies the upper manager of the space where the person exists There is a number.

Accordingly, even when the fire is not generated, the green LED 220 is selectively emitted through the human body detection sensor 150 installed in the main body case 110, I can cope.

Meanwhile, the human body detection sensor 150 may be configured to detect not only the presence of a person but also an operation, thereby preventing a human accident caused by a fire, and also a crime prevention function. Hereinafter, a crime prevention function utilizing the human body detection sensor 150 will be further described.

In addition, when the human body is sensed through the human body sensor 150, the green LED 220 may emit light or flash light through a sensor in a region where fire does not occur to guide the escape route direction.

The RF sensor 160 serves as a communication device to transmit signals to and from an adjacent sensor through RF communication. Here, although the RF sensor 160 is described as an embodiment in the embodiment of the present invention, the present invention is not limited to the specific communication method, but may be applied to other data such as Wi-Fi communication, bluetooth and beacon communication, You can also send and receive.

The humidity sensor 170 senses the humidity of the indoor space and delivers the MCU 270. The MCU 270 receives the humidity information of the room sensed through the humidity sensor 170 and displays the non- , It is determined whether or not it is caused by steam generated during cooking.

The CO sensor 180 detects colorless odorless carbon monoxide (CO) in the indoor space and transmits the detected CO to the MCU 270. The MCU 270 analyzes the carbon monoxide detected through the CO sensor 180, The control unit controls the second LED module 200 to emit or flash the red LED 210 to warn that a fire has occurred.

Under the control of the MCU 270, the first and second LED modules 190 and 200 selectively emit or flash blue, yellow, red, and green light to visually recognize .

The first and second LED modules 190 and 200 receive a control signal from the MCU 270 to detect an intruder in a predetermined time zone and detect an intruder's movement based on detection information of the human body sensor 150 It is possible to recognize that there is an intruder as well as giving an alarm to the intruder by controlling the LEDs to emit light selectively.

The relay 250 receives a control signal from the MCU 270 when a fire occurs and applies a control signal such as color or color temperature to the LED lighting lamp installed in the room to cause the LED lighting lamp to emit light or blink, .

The audio 260 receives a control signal from the MCU 270, and when a fire occurs, the audio 260 broadcasts an evacuation announcement or a siren.

In addition, the audio 260 receives the sensing information of the human body from the human body sensing sensor 150 and generates a warning message or a siren when there is an intruder in the room from the outside in the set time period.

The MCU 270 controls the first and second LED modules 190 and 200 when information from various sensors or a fire generation signal is applied to the first and second LED modules 190 and 200, Controls either one of the red LED 210, the green LED 220, the blue LED 230 and the yellow LED 240 to emit light or blink according to the control of the MCU 270, In case of occurrence, the alarm can be visually indicated through a general light or detector.

The MCU 270 can adjust the driving time of the first and second LED modules 190 and 200. For example, the red LED 210, the green LED 220, the blue LED 230, The controller 210 controls the red LED 210 to emit light with a predetermined period so that people can easily check the LED 210 when the fire occurs.

The MCU 270 controls the relay 250 to control the color of the RGB or the color temperature when the LED illumination lamp is driven to emit light or flash, thereby changing the color of the LED illumination light.

The MCU 270 receives at least one of fire, smoke, and flame generated in a fire. The fire signal generated by the smoke sensor or the temperature sensor is converted into a digital signal and received .

Meanwhile, the IoT-based single fire detector according to the present invention may provide various information to the terminal by performing RF communication with the terminal of the administrator, or may install a repeater in the indoor space to deliver the information to the outside.

FIGS. 4 to 7 are views showing a state in which the fire detector of FIG. 3 emits blue, yellow, red, and green, respectively.

As shown in FIGS. 4 to 7, the IoT-based single fire detector according to the present invention selectively emits blue, yellow, red, and green light by receiving information obtained from various sensors and a fire generation signal, You can visually show emergency situations in an emergency.

FIG. 8 is a view showing a state in which general illumination is controlled through the fire detector of FIG. 3. FIG.

As shown in FIG. 8, the fire detector 100 sends RGB color or color temperature control signals to the LED lighting lamp 300 installed therein to control the color or color temperature of the LED lighting lamp 300 in an emergency such as a fire have.

In addition, the fire detector 100 may transmit various information to the terminal 400 of the administrator so that the administrator can manage the indoor information while checking the terminal 400.

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.

100: Fire detector 110: Body case
120: first optical fiber 130: second optical fiber
140: Battery 150: Human body sensor
160: RF sensor 170: Humidity sensor
180: CO sensor 190: first LED module
200: second LED module 210: red LED
220: green LED 230: blue LED
240: yellow LED 250: relay
260: Audio 270: MCU

Claims (7)

A main body case attached to a ceiling or a wall surface and having an internal space,
First and second optical fibers arranged at regular intervals along an edge of the main body case inner space,
A red LED inserted into one end of the first optical fiber to emit red light, a green LED inserted into the other end of the first optical fiber to emit green light,
A blue LED inserted in one end of the second optical fiber to emit blue light, and a yellow LED inserted in the other end to emit yellow light,
A body sensor installed in an inner space of the body case to detect the presence or absence of a human body around the body, a CO sensor for detecting carbon monoxide, a humidity sensor for detecting humidity, an RF sensor for communicating with the outside,
A control signal for driving any one of the red LED, the green LED, the blue LED, and the yellow LED in response to at least one signal detected from the human body sensor, the CO sensor, and the humidity sensor, A control unit for outputting a control signal for controlling the illumination lamp,
And audio for recognizing an intruder when the human body is sensed by the human body detection sensor and generating a warning broadcast or a siren by receiving a control signal through the controller,
Wherein the control unit applies an RGB color or color temperature control signal to the LED lighting lamp installed in the indoor space to convert the color of the LED lighting lamp. The fire detector according to claim 1, further comprising a battery for supplying power to the controller, the human body sensor, the CO sensor, and the RF sensor. delete delete delete The fire detector of claim 1, further comprising a terminal for receiving and storing information of the detector through the RF sensor. delete

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