KR101765210B1 - Smoke and fog sensing system - Google Patents

Abstract

Disclosed is a smoke and fog detection system having a diffraction optical device and a nanotechnique applied thereto. The smoke and fog detection system having the diffraction optical device and the nanotechnique applied thereto of the present invention comprises: a smoke and fog detection body having an optical device module to generate a laser light source; a direction indication module disposed on the smoke and fog detection body, displaying an escape route through a laser light source generated by a power source; a body rotating unit having one side part disposed at the smoke and fog detection body, having the other side part disposed on a ceiling part or a wall body, and rotating the smoke and fog detection body; a smoke and fog detection sensor disposed at the smoke and fog detection body, and detecting smoke and fog generated when there is a fire; a flame detection sensor disposed at the smoke and fog detection body, detecting flame generated when there is a fire; a refraction optical device disposed at the smoke and fog detection body; an emergency electrical power supply unit disposed at the smoke and fog detection body, supplying electric power to an optical device module when electric power is cut off; an image providing unit disposed at a direction indication module, providing an escape image by a laser light source provided from the optical device module, and nanocoated; and a control unit disposed at the smoke and fog detection body, operating the body rotating unit based on signals detected by the flame detection sensor when there is a fire to rotate the smoke and fog detection body in a direction which is different from a flame direction, and to supply electric power of the emergency electric power supply unit to the optical device module and the body rotating unit.

Description

{SMOKE AND FOG SENSING SYSTEM} < / RTI >

The present invention relates to a fire detection system, and more particularly, to a fire detection system capable of stably securing an escape path in case of fire, a diffractive optical element capable of guiding an escape path in a direction different from the fire direction, Sensing system.

In the room, a fire detector for evacuation is installed.

Fire detectors are installed on the ceiling of the room at regular intervals to detect heat or smoke, and generate electrical signals when a fire occurs.

Separately from the fire detector, an emergency light is installed in the hallway to evacuate the person. Emergency lights are installed adjacent to the floor of the corridor to guide the moving direction of a person moving in a low posture.

An indoor space such as a narrow corridor can easily identify the escape route by checking the location of the emergency light.

However, it is difficult to confirm the position of the emergency light due to the large area of the multi-use facilities such as a movie theater or a performance hall, and since many people move to different escape routes, it is difficult to secure an escape route.

Conventionally, there is a problem that the escape route can be guided to the fire direction because the escape route during the fire is not variable but focuses on the fire smoke and guides the escape route.

Furthermore, in the case where the power is cut off by a fire in the past, if an emergency power source is operated, if the electric wire is damaged due to a fire, an escape route is not correctly displayed.

The above-described technical structure is a background technique for assisting the understanding of the present invention, and does not mean the prior art widely known in the technical field to which the present invention belongs.

Korean Patent Laid-Open Publication No. 2013-0074382 (Made by INC.) 2013. 07. 04.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide a naphtha detection system to which a nano technology is applied, and a diffraction optical element capable of reliably securing an escape route in a fire and guiding an escape route in a direction different from the fire direction.

According to an aspect of the present invention, there is provided an image forming apparatus including a mist detection body including an optical element module for generating a laser light source; A direction indication module provided in the mist detection body and displaying an escape route through a laser light source generated by an applied power source; A main body rotating part provided on one side of the mist sensing body and on the other side of the ceiling or wall to rotate the mist sensing body; A mist detection sensor provided in the mist detection body for detecting a mist generated during a fire; A flame detection sensor provided in the mist detection body and detecting a flame generated in a fire; A diffractive optical element provided in the mist detection body; An emergency power supply unit provided in the mist detection body and supplying power to the optical module when power is cut off; A nano-coated image providing unit provided in the direction indicating module and providing an escape image by a laser light source provided in the optical device module; And a control unit for controlling the main body rotation unit based on a signal detected by the flame detection sensor in the event of a fire to rotate the main body in a direction different from the flame direction, And a control unit for supplying the optical element module to the main body rotating unit.

The direction indicating module includes: a body coupled to the mist sensing body and having one side bendable; A cap coupled to the body; And a light guiding member provided inside the body and guiding light transmitted from the optical module to the image providing unit.

The body includes: a body bending portion bent by an external force; And a cap assembly integrally formed with the main body bending portion and detachably coupled to the cap.

The light guide member may include an optical fiber.

The cap may be provided with a cap inclined surface.

The embodiments of the present invention enable the control unit to operate the main body rotation part on the basis of the flame detected by the flame detection sensor to rotate the mist detection main body in the direction different from the flame direction to guide the escape path, .

Also, the exit path can be clearly displayed through the diffractive optical element and the nano-coated image providing unit.

Further, the emergency power supply unit can supply power to the optical element module and the main body rotation unit stably regardless of whether the main power supply or the emergency power supply is shut off.

FIG. 1 is a view schematically showing a diffuse optical element and a nanomaterial-based fog detection system according to an embodiment of the present invention. Referring to FIG.
FIG. 2 is a perspective view of a mist detection body and a direction indicating module applied to the present embodiment.
FIG. 3 is an exploded perspective view of FIG. 2. FIG.
4 is a front view of Fig.
5 is a right side view of Fig.
6 is a cross-sectional view of Fig.
7 is a view showing the image providing unit shown in Fig.
8 is a use state diagram of this embodiment.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

Hereinafter, the present invention will be described in detail with reference to the preferred embodiments of the present invention with reference to the accompanying drawings. Like reference symbols in the drawings denote like elements.

FIG. 1 is a schematic view showing a diffuse optical element and a nanomaterial-based fog detection system according to an embodiment of the present invention. FIG. 2 is a perspective view of a fog detection body and a direction indicating module applied to the present embodiment, Fig. 3 is an exploded perspective view of Fig. 2, and Fig. 4 is a front view of Fig.

Fig. 5 is a right side view of Fig. 3, Fig. 6 is a sectional view of Fig. 4, Fig. 7 is a view showing the image providing unit shown in Fig. 3, and Fig. 8 is a use state view of this embodiment.

As shown in these drawings, the diffuse optical element and the nano-technology applied fog detection system 1 according to the present embodiment include a mist detection body 100 having an optical element module 110 for generating a laser light source, A direction indication module 200 provided in the mist detection main body 100 and displaying an escape route through a laser light source generated by an applied power source, and a display unit 200 having one side provided on the mist detection main body 100, A main body rotation unit 300 installed on the wall of the main body 100 for rotating the main body 100 of the main body 100, a fume detection sensor 400 provided on the main body 100 for sensing fumes generated during a fire, A flame detection sensor 500 for detecting a flame generated in a fire, a diffraction optical element 600 provided in the mist detection main body 100, and an optical element module 600 provided in the mist detection main body 100, ) To power A nano-coated image providing unit 800 provided in the direction indicating module 200 and providing an escape image by a laser light source provided in the optical device module 110, The main body rotation unit 300 is operated on the basis of a signal detected by the flame detection sensor 500 in the main body 100 to rotate the main body 100 in a direction different from the flame direction, And a control unit 900 for supplying power of the light source module 700 to the optical device module 110 and the main body rotation unit 300.

The mist detection body 100 may have a flat cylindrical shape as shown in FIG. 2, and may be rotated 360 degrees by the main body rotation unit 300 when a fire occurs.

In this embodiment, an optical element module 110 for generating a laser light source may be provided inside the mist detection main body 100.

In this embodiment, a plurality of through holes 120 may be formed on the outer wall of the mist detection main body 100, as shown in FIG.

2, the direction designation module 200 is provided in the mist detection main body 100 and guides the laser light source generated in the optical module 110 to the outside.

3, the direction indicating module 200 includes a body 210 coupled to the mist sensing body 100 and having one side bendable, a cap 210 coupled to the body 210, And a light guide member 230 provided inside the body 210 and guiding the light transmitted from the optical device module 110 to the image providing unit 800.

3, the body 210 of the direction designation module 200 includes a body bending portion 211, a cap assembly 220 coupled to the body bending portion 211, A body hollow 213 provided in the cap assembly 212 and an assembly protrusion 214 provided on the outer wall of the cap assembly 212. [

The cap 220 of the direction indicating module 200 is provided with a cap hollow 221 through which the laser passes, an assembling groove 222 into which the assembling protrusion 214 is engaged, An insertion groove 224 into which the image providing part 800 is inserted and a cap inclined surface 225 which limits the entry depth of the cap assembling part 212 are provided.

8, the light guide member 230 of the direction indicating module 200 transmits the laser, which is the light transmitted from the optical device module 110, to the image providing unit 800.

In this embodiment, the light guide member 230 includes an optical fiber.

The body rotation part 300 is coupled to the ceiling or the inner wall of the building and the other part is coupled to the mist detection body 100 to control the mist detection body 100 in a direction different from the fire direction It rotates.

In this embodiment, the main body rotation part 300 includes a housing coupled to a ceiling or an inner wall of a building, and a motor provided on the housing, one side of which is connected to the mist sensing body 100 to rotate the mist sensing body 100 do.

In this embodiment, the motor may be bolted or keyed to the mist detection main body 100, and may be supplied to the emergency power supply unit 700 in case of fire to be supplied with power.

The fog detection sensor 400 is provided in the fog detection main body 100 to detect whether or not there is a fire.

In this embodiment, the smoke detection sensor 400 may be a smoke detection type that detects smoke entering through the through hole 120 provided in the smoke detection main body 100 and detects the fire.

The flame detection sensor 500 is provided in the mist detection main body 100 to sense a direction in which the flame occurs when a fire occurs and a signal detected by the flame detection sensor 500 is supplied to the control unit 900. The control unit 900 may operate the main body rotation unit 300 based on a signal sensed by the flame detection sensor 500. [

The diffractive optical element 600 is fitted or bolted to the front of the optical element module 110 which is the interior of the mist sensing body 100 so that the light generated from the optical element module 110 is guided to the plurality of light guide members 230 ). To this end, a plurality of reflection plates may be provided inside the mist detection body 100.

The emergency power supply unit 700 is detachably coupled to the fire detection main body 100. When the supply of the main power or the emergency power is interrupted when a fire occurs, the emergency power supply unit 700 itself includes the optical element module 110 and the main body rotation unit 300 Power can be supplied.

In this embodiment, the emergency power supply unit 700 includes a battery, which can be charged by itself using a power supply normally supplied from the main power supply.

The image providing unit 800 serves to provide images or shades to the laser to be passed, as shown in Fig.

In the present embodiment, the image providing part 800 may be fitted to the mounting groove 222 shown in FIG.

Also, in this embodiment, a nano-coating layer is provided on the surface of the image providing part 800 so that the loss of light (laser) guided by the light guide member 230 is minimized, and the design 810 can be made clear.

The control unit 900 is provided in the mist detection main body 100 and operates the main body rotation unit 300 based on a signal detected by the flame detection sensor 500 in the event of a fire, And supplies power of the emergency power supply unit 700 to the optical module 110 and the main body rotation unit 300 to stably display the escape route.

In the present embodiment, the control unit 900 may prioritize the flame detection so that when the smoke and the flame are detected at the same time, the escape path may be guided in a direction different from the flame.

As described above, according to the present embodiment, the control unit operates the main body rotation part on the basis of the flame detected by the flame detection sensor in the event of a fire, rotates the main body of the mist detection body in a direction different from the flame direction to guide the escape path, .

Also, the exit path can be clearly displayed through the diffractive optical element and the nano-coated image providing unit.

Further, the emergency power supply unit can supply power to the optical element module and the main body rotation unit stably regardless of whether the main power supply or the emergency power supply is shut off.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

1: Mist detection system with diffractive optical element and nanotechnology
100:
200: direction indicating module
300:
400: Mist detection sensor
500: Flame detection sensor
600: diffractive optical element
700: Emergency power supply
800: image offerer
900:

Claims (5)

A mist detection body provided with an optical element module for generating a laser light source;
A direction indication module provided in the mist detection body and indicating an escape route through a laser light source generated by an applied power source;
A main body rotating part provided on one side of the mist sensing body and on the other side of the ceiling or wall to rotate the mist sensing body;
A mist detection sensor provided in the mist detection body for detecting a mist generated during a fire;
A flame detection sensor provided in the mist detection body and detecting a flame generated in a fire;
A diffractive optical element provided in the mist detection body;
An emergency power supply unit provided in the mist detection body and supplying power to the optical module when power is cut off;
A nano-coated image providing unit provided in the direction indicating module and providing an escape image by a laser light source provided in the optical device module; And
And a control unit for controlling the main body rotation unit to rotate the main body in a direction different from the flame direction by operating the main body rotation unit on the basis of a signal detected by the flame detection sensor in the event of a fire, And a controller for supplying the optical element module and the main body rotating part,
The direction indicating module includes a body coupled to the mist sensing body and having one side bent to be bendable, a cap coupled to the body, and a light guide provided inside the body, for guiding light transmitted from the optical element module to the image providing unit And a guide member,
The body includes a body bending part bent by an external force, a cap assembly part integrally formed with the body bending part and detachably coupled to the cap, a body hollow provided in the cap assembly part, and an outer wall of the cap assembly part And an assembling protrusion,
The cap includes a cap hollow through which a laser is passed, an assembly groove provided on an inner wall of the cap, the assembly groove being engaged with the assembly projection, a cap hole through which the laser passes through the image supply unit, And a cap inclined surface that limits an entry depth of the cap assembly,
The main body rotation part includes a housing coupled to a ceiling or an inner wall of a building, and a motor provided at the housing, the motor part connected to a mist detection body to rotate the mist detection body,
The motor may be connected to an emergency power supply during a fire to be supplied with power,
Wherein the control unit prioritizes flame detection to guide the escape path in a direction different from the flame by rotating the flame detection body in a direction different from the flame when smoke and flame are simultaneously detected. delete delete delete delete

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