KR20120003263U - Smart mono type detecting device - Google Patents

Abstract

The present invention relates to a fire detector, and more particularly, to a smart single fire detector installed in a building such as a single house.
In the smart stand-alone type fire detector installed in the house according to the present invention, the fire detection unit is fixed to one side of the ceiling or the wall of the house is installed to detect the fire, fire detection including a fire alarm to determine the presence of the fire according to the fire alarm And a fire detection cap coupled with the fire detection housing to protect the internal circuitry so as to detect the fire in the fire alarm section.
According to this aspect of the present invention, it is possible to transmit and receive the fire-related information by low-band communication between the smart stand-alone fire apparatus installed on the ceiling or wall of a plurality of houses.

Description

Smart mono type detecting device

The present invention relates to a fire detector, and more particularly, to a smart single fire detector installed in a building such as a single house.

In general, a fire detector installed inside a building to detect a fire detects a temperature change and smoke inside the building to notify people in the building that a fire has occurred through a buzzer. Such a fire detector receives power from a battery provided therein and detects a fire and outputs a fire buzzer accordingly. Such a battery is usually a primary battery (9V), and since the power charged in the battery is consumed little by little even when the fire detector is not operated, it is difficult to continuously maintain the fire detection function of the fire detector. In order to continuously maintain the fire detection function of the fire detector, there is a problem that the user needs to replace the battery periodically. In addition, since a conventional fire detector notifies that a fire has occurred only through a buzzer when a fire occurs, a fire occurrence report is received by a person in the building where the fire occurred or by a person who directly witnessed the fire. Is done. Therefore, there is a problem that the initial suppression caused by the fire is delayed.

In addition, a smoke detector installed in a single-family building, such as a detached house, cannot communicate with smoke detectors in a house or building adjacent to the detached house. Therefore, even if a fire occurs in a single house in a residential area where single houses are concentrated, people in adjacent buildings may not know that the fire has occurred and may not be evacuated quickly, which may cause damage to life and property.

The present invention aims to solve such a problem, and aims to perform fire-related data communication between smart single fire detectors installed in a building where a small number of households live, such as a single house.

Furthermore, an object of the present invention is to provide a smart stand-alone fire detector that does not need a separate power supply by supplying power using a solar cell.

The above technical problem is achieved by the characteristic aspects of the present invention described below. In the smart stand-alone type fire detector installed in the house according to the present invention, a fire detection unit that is fixed to one side of the ceiling or the wall of the house is installed and detects the fire, and determines the presence or absence of the fire according to the fire alarm including a fire alarm unit And a fire detection cap coupled with the fire detection housing to protect the internal circuitry so as to detect the fire in the fire alarm section.

According to a further aspect of the present invention, the fire alarm unit detects a fire, a wireless communication unit transmitting and receiving fire related information with an external device or another smart standalone fire detector, and an output from the detection sensor according to a predetermined condition. A fire occurrence determination unit that determines whether a fire has occurred by measuring a level of a fire detection signal, and a fire-related device from at least one smart stand alone fire detector according to a determination result of the fire occurrence determination unit or another smart stand alone fire detectors When the information is received, the first fire notification unit outputs a fire buzzer sound through the speaker for a preset time, and after the fire buzzer sound is output for a preset time, the voice is transmitted through the speaker using voice information previously stored in the memory. And a second fire notification unit for outputting a fire occurrence.

According to a further aspect of the present invention, the wireless communication unit transmits and receives fire related information with an external device or another smart standalone fire detectors at a low band frequency of 400 MHz.

According to a further aspect of the present invention, the memory further includes identification information of the smart stand alone fire detector, the fire alarm unit according to the determination result of the fire occurrence determination unit, the external device or another smart stand alone fire detectors through the wireless communication unit And a fire generation processor for transmitting fire related information including identification information, and a battery for supplying precharged power or power charged through a solar cell to the fire alarm unit.

According to this aspect of the present invention, it is possible to transmit and receive the fire-related information by low-band communication between the smart stand-alone fire devices installed on the ceiling or wall of a plurality of houses, and to transmit the electrical energy supplied from the solar cell to the battery By charging and supplying power to the fire alarm unit, fire detection in the fire alarm unit can be normally performed without separate management such as periodic battery replacement.

As described above, the smart single fire detector according to the present invention may perform fire-related data communication between smart single fire detectors installed in a single house by installing a few households such as a single house. Therefore, even if a fire occurs next door, the smart standalone fire detector installed in the home receives fire related information from the smart standalone smoke detector installed in the house where the fire occurred and the people are not active. Even in the early morning, household members can recognize that a fire has occurred in the house next door and promptly follow up or evacuate.

In addition, the smart stand-alone fire detector according to the present invention by charging the battery with electrical energy supplied from the solar cell to supply the power to the fire alarm unit, it is possible to detect the fire in the fire alarm unit without separate management such as periodic battery replacement There is an effect that can be achieved normally.

1 is a perspective view schematically showing a conventional stand-alone fire detection device,
2 is a perspective view of a smart stand alone fire detector according to an embodiment of the present invention,
3 is an exploded perspective view of a smart stand alone fire detector according to an embodiment of the present invention,
4 is a block diagram of a fire alarm unit according to an embodiment of the present invention.

The foregoing and further aspects of the present invention will become more apparent through the following examples. Hereinafter, with reference to the preferred embodiments described with reference to the accompanying drawings of the present invention will be described in detail so that those skilled in the art can easily understand and reproduce.

1 is a perspective view schematically showing a conventional stand-alone fire detection device.

As shown, the conventional stand-alone fire detection device 100 is composed of a main body 110 for receiving a fire detection circuit for detecting a fire therein and a cover 120 coupled with the main body 110. One side of the main body 110 for accommodating the fire detection circuit for detecting the fire is attached to the ceiling or wall, the cover is coupled to another side of the main body 110 to protect the fire detection circuit from the outside. On the other hand, the fire detection circuit accommodated in the main body 110 of the stand-alone fire detection device 100 receives power from the battery mounted in the stand-alone fire detection device 100 to perform a fire detection. Since the battery mounted in the stand-alone fire detection device 100 typically uses a primary battery, even if a fire detection circuit for detecting a fire is not driven, power in the battery is consumed little by little and eventually discharges. There is a problem in that the battery needs to be replaced frequently to maintain its function.

However, since the conventional stand-alone fire detection device 100 does not have a function of notifying the outside even when the power of the battery is discharged, people cannot know at all whether the stand-alone fire detection device 100 normally performs fire detection. . As a result, in order for the standalone fire detection device 100 to normally perform a fire detection through a fire detection circuit, the user needs to periodically replace a battery mounted in the standalone fire detection device 100.

In addition, the stand-alone fire detection device 100 installed in a single house in one building, such as a single house is unable to communicate with the stand-alone fire detection device 100 installed in another single house. Therefore, when a fire occurs in a single house, evacuation of the people living in the detached house adjacent to the detached house is delayed due to the fire, there is a problem that can spread the damage to life and property. So far, the conventional stand-alone fire detection apparatus 100 has been described. Hereinafter, a smart stand-alone type fire detector 200 installed in a house according to the present invention will be described in detail with reference to FIGS. 2 to 4.

2 is a perspective view of a smart stand alone fire detector according to an embodiment of the present invention, Figure 3 is an exploded perspective view of a smart stand alone fire detector according to an embodiment of the present invention.

As shown, the smart single fire detector 200 according to a preferred embodiment of the present invention is installed in a building where one or two households live in a building, such as a single house. The smart stand alone fire detector 200 includes a fire detection housing 10 and a fire detection cap 20. The fire detection housing 10 is fixedly installed at one side of a ceiling or a wall of a building such as a single house, and is preferably formed of a metal material resistant to heat and external pressure. In addition, the surface in contact with the ceiling or wall surface can be firmly fixed by bolting through the screw. Such a fire detection housing 10 accommodates a fire alarm unit 30 that detects a fire and determines the presence or absence of a fire, thereby informing a fire alarm.

The fire detection cap 20 is coupled to a surface corresponding to a surface fixed to one side of the ceiling or wall of the fire detection housing 10. Therefore, the fire alarm unit 30 accommodated in the fire detection housing 10 may be protected from the outside. As such, the fire detection cap 20, which is combined with the fire detection housing 10 to protect the fire alarm unit 30 from the outside, has an internal heat in order to accurately detect the internal temperature of the building in the fire alarm unit 30. It is excellent in conductivity and can be formed of a metal material resistant to external pressure. However, the present invention is not limited thereto, and the fire alarm unit 30 may detect not only the temperature inside the building but also gas leakage, and a plurality of holes having a predetermined size may be formed in the center of the fire detection cap 20. . Therefore, the fire alarm unit 30 may more accurately sense not only the temperature inside the building but also the gas leakage.

In addition, the inside of the fire detection cap 20 according to the present invention is provided with a thin film copper plate 40. Therefore, when a fire occurs and heat is applied around the fire detection cap 20, the air expands between the fire detection cap 20 and the copper plate 40. Therefore, the thin copper plate 40 is moved to the fire alarm unit 30 by the expanded air. By the copper plate 40 moved to the fire alarm unit 30 side, the two contacts of the fire alarm unit 30 become conductive, so that the fire alarm unit 30 is abnormally detected due to an abnormality in the detection sensor for detecting a fire. Even the fire can be detected accurately.

On the other hand, the outer periphery of the fire detection housing 10 coupled with the fire detection cap 20 is provided with a solar cell 50 for converting the incident light energy into electrical energy to output. The solar cell 50 called a solar cell is charged with a battery 450 to be described later, so that the power in the battery 450 may be always charged for a predetermined amount or more. On the other hand, the fire alarm unit 30 accommodated in the fire detection housing 10 to detect a fire may be configured and operate as shown in FIG.

4 is a block diagram of a fire alarm unit according to an embodiment of the present invention.

As shown, the fire alarm unit 30 includes a sensor 200, a wireless communication unit 210, the control unit 220. The detection sensor 200 is a sensor for detecting a fire and detects a temperature inside a building such as a single house, or detects a gas leak and outputs a monitoring signal accordingly. The wireless communication unit 210 transmits and receives fire-related information with an external device of a disaster prevention agency or another smart standalone fire detector in charge of fire suppression or post-processing. The wireless communication unit 210 preferably transmits and receives fire related information with an external device or another smart standalone fire detector at a low band frequency of 400 MHz. That is, a general wireless communication device transmits and receives data at a high band frequency of about 2.4 GHz through wireless communication such as Bluetooth. Accordingly, the smart standalone fire detector according to the present invention can transmit and receive fire related information more safely and quickly by transmitting and receiving fire related information with an external device or another smart standalone at a low band frequency of 400 MHz.

The control unit 220 performs a fire command according to the detection signal of the detection sensor 200, and at the same time, transmits the fire related information to the external device or another smart stand alone fire detectors through the wireless communication unit 210 or Receives fire related information from other smart standalone fire detectors and controls them to perform a fire order. The control unit 220 may be achieved through the fire occurrence determination unit 221, the primary fire notification unit 222, the secondary fire notification unit 223, and the fire generation processing unit 224.

The fire occurrence determination unit 221 determines the fire occurrence by measuring the level of the fire detection signal output from the detection sensor 200 according to a preset condition. If it is determined that a fire has occurred as a result of determining whether a fire has occurred according to the measurement of the level of the fire detection signal from the fire occurrence determination unit 221, the primary fire notification unit 222 fires with a buzzer sound through the speaker 230 for a preset time. Notify the occurrence. In addition, when the fire related information is received from at least one of the smart single fire detectors among the other smart single fire detectors, the primary fire alarm 222 fires with a buzzer sound through the speaker 230 for a preset time. Notify the occurrence. For example, the primary fire alarm unit 222 may output a buzzer sound indicating that a fire has occurred through the speaker 230 at intervals of 10 seconds for 5 minutes.

As such, when a fire occurrence buzzer sound is output for a preset time through the primary fire alarm 222, the secondary fire alarm 223 uses the voice information previously stored in the memory 240 to operate the speaker 230. Voice alerts you that a fire has occurred. Accordingly, people who are in a building, such as a single house, can quickly escape from the building after hearing the buzzer sound or the sound of fire generated through the speaker 230.

On the other hand, the memory 240 in which the fire-related voice information is stored further includes identification information of the smart stand-alone fire detector 200, the fire occurrence processing unit 224 according to the determination result of the fire occurrence determination unit 221, The wireless communication unit 210 transmits the fire related information including its identification information previously stored in the memory 240 to an external device such as a server of the disaster prevention agency or another smart standalone fire detector. Accordingly, the disaster prevention agency personnel can recognize that a fire has occurred in a building in a certain area and dispatch it to the corresponding point to promptly extinguish fire and post-processing, and another smart stand-alone fire detector that receives fire related information. They also report a fire, so people living in buildings adjacent to the fire can expedite the evacuation.

On the other hand, according to an additional aspect of the present invention, the fire alarm unit 30 further includes a battery 250 for supplying the charged power through the pre-charged power or solar cell 50 so that each of the above-described components can operate. do. That is, the battery 250 supplies the pre-charged power so that each of the above-described components can perform the fire detection and its operation normally, and checks the amount of power charged in the battery 250 to be less than the threshold value. It self-charges through a solar cell 50 called a cell. As described above, the solar cell 50 is installed around the outer periphery of the fire detection housing 10 coupled with the fire detection cap 20 to collect the incident light energy, and is converted into electrical energy. Accordingly, when the battery 250 checks the amount of power charged in the battery 250 and is less than the threshold value, the battery 250 charges the electric energy converted from the solar cell 50 into the battery 250, so that the power in the battery 250 is discharged. Each component that is always charged for a certain amount or more to perform fire detection and its operation may operate normally.

The present invention has been described with reference to the preferred embodiments.

Those skilled in the art will understand that the present invention can be implemented in a modified form without departing from the essential characteristics of the present invention. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is shown in the utility model registration claims rather than the foregoing description, and all differences within the equivalent scope will be construed as being included in the present invention.

10: fire detection housing 20: fire detection cap
30: fire alarm unit 40: copper plate
50: solar cell 100: stand-alone fire detection device
110: body 120: cover
200: smart stand alone fire detector 400: detection sensor
410: wireless communication unit 420: control unit
421: fire occurrence determination unit 422: primary fire notification unit
423: second fire notification unit 424: fire generation processing unit
430: speaker 440: memory
450: battery

Claims (4)

In the smart stand-alone smoke detector installed in the house,
A fire detection housing fixed to one side of the ceiling or wall of the house to detect a fire, and to determine whether there is a fire and a fire alarm to notify a fire alarm;
A fire detection cap coupled to the fire detection housing to protect an internal circuit so that the fire alarm can detect a fire;
Smart stand alone fire detector comprising a.
The fire alarm system of claim 1, wherein the fire alarm is:
A detection sensor detecting a fire;
A wireless communication unit for transmitting and receiving fire related information with an external device or another smart standalone fire detector;
A fire occurrence determination unit determining a fire occurrence by measuring a level of a fire detection signal output from the detection sensor according to a preset condition;
When the fire related information is received according to the determination result of the fire occurrence determining unit or from at least one smart single fire detector among the other smart single fire detectors, 1 that outputs a fire buzzing sound through a speaker for a preset time. A car fire alarm unit;
A second fire alarm unit outputting a fire occurrence by voice through the speaker by using the voice information pre-stored in a memory after the fire occurrence buzzer sound is output for the preset time;
Smart stand alone fire detector comprising a.
The method of claim 2, wherein the wireless communication unit:
Smart stand-alone fire detector, characterized in that for transmitting and receiving the fire-related information with the external device or the other smart stand-alone fire detector at a low band frequency of 400MHz.
The memory of claim 2, wherein the memory is:
Further comprising identification information of the smart stand-alone fire detector,
The fire alarm unit
A fire generation processor for transmitting the fire related information including the identification information to the external device or another smart standalone fire detector according to a determination result of the fire occurrence determination unit;
A battery for supplying charged power or charged power through a solar cell to the fire alarm unit;
Smart stand-alone fire detector, characterized in that it further comprises.

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