KR200394972Y1 - Mono type fire detecting device - Google Patents

Abstract

The present invention relates to a stand-alone fire detector, and more particularly, to a stand-alone fire detector using a solar cell that converts light energy into electrical energy and outputs it to detect a fire occurrence without a separate power supply. .

Single fire detector according to the present invention is fixed to one side of the ceiling or wall of the building, and detects the heat transmitted therein to determine the presence of a fire and a fire alarm unit to alert the fire when the determination result, the side circumference A base having a plurality of solar cells configured to convert light energy incident on the light into electrical energy and output the electrical energy;

It is coupled to the base to protect the internal circuit, the heat sensing cap for transmitting the heat applied to the fire alarm; characterized in that it comprises a.

Description

Mono type fire detecting device

The present invention relates to a stand-alone fire detector, and more particularly, to a stand-alone fire detector using a solar cell that converts light energy into electrical energy and outputs it to detect a fire occurrence without a separate power supply. .

In general, the interior of the building is provided with a variety of detection means for detecting the occurrence of fire. A typical example is a fire detection device attached to the ceiling of a building. Such a fire detection device detects a temperature change detected by a fire in a room and determines that a fire occurs when the detected temperature rises above a predetermined level, and transmits a fire occurrence signal to a disaster prevention system connected by wire.

The disaster prevention system alerts the building in response to a fire occurrence signal transmitted from a fire detector, while attempting to extinguish using early extinguishing means such as, for example, sprinklers and firewalls, and notifies organizations such as fire stations.

The fire protection system described above is mainly used in a large building in which many people live, such as a building or an apartment, and a single fire detector is mainly used in a private house. Such a single type fire detector, when a fire is detected by the detection means and the detection means for detecting a fire therein, a buzzer or an electronic sound to notify the user that the fire has occurred.

However, such a conventional stand-alone fire detector is driven by using a battery provided therein, or is driven by connecting a power applied into the house. The battery is consumed and discharged even if it does not occur when it is driven by a battery. Therefore, the battery needs to be replaced to maintain its function continuously. If the battery is not replaced, it will function if a fire occurs. There is a disadvantage that can not exert. In addition, there is a disadvantage in that a separate wiring work according to its installation when used by connecting the power applied to the house.

The present invention was devised to solve such a problem, and an object thereof is to provide a single type fire detector that does not need a separate power supply source by supplying driving power using a solar cell.

Furthermore, it is possible to transmit a fire occurrence signal through a wireless communication in the event of a fire, to provide a stand-alone fire detector that can be extended in connection with the existing disaster prevention system.

Single fire detector according to the present invention described above is fixed to one side of the ceiling or wall of the building, and detects the heat transmitted therein to determine the presence of a fire and a fire alarm unit for alarming when a fire occurs as a result, The base is provided with a plurality of solar cells for converting the light energy incident to the circumference of the side into electrical energy and output, and a heat sensing cap coupled to the upper base to protect the internal circuit, but transmits the applied heat to the fire alarm It is configured to include.

The fire alarm unit detects heat applied from the heat sensing cap and outputs a detection signal, a battery that supplies power for driving the device, and a battery that charges the battery with electrical energy converted and supplied by the solar cell. The controller controls the charging unit and the entire apparatus, and determines whether there is a fire according to a detection signal output by the heat detection sensor, and as a result, receives a fire generation signal output from the controller and a control unit that outputs a fire occurrence signal when the fire occurs. It includes a fire alarm output to notify the occurrence of the fire.

Accordingly, the stand-alone fire detector according to the present invention absorbs light emitted from a fluorescent lamp and a light bulb used in a building or a house and converts the solar energy into electrical energy, and charges the converted electrical energy into the battery through the battery charging unit. The battery is fully charged.

Therefore, by absorbing light through the solar cell to charge the battery, there is an advantage that can be used semi-permanently without the need for unnecessary power wiring work during the periodic battery replacement or installation for driving power supply of the fire detector.

According to a further aspect of the present invention, the stand-alone fire detector according to the present invention further includes a wireless communication unit for transmitting a fire generation signal output from the control unit to a wirelessly connected disaster prevention system. When the fire occurrence signal is output from the control unit, the wireless communication unit receives it and outputs it to the repeater of the disaster prevention system connected through wireless communication.

The repeater receives this and transmits the corresponding fire occurrence signal to the host device of the disaster prevention system, and the disaster prevention system attempts to extinguish using an early extinguishing means such as a sprinkler or a firewall, for example, and fires at an institution such as a fire station. Inform.

Therefore, the stand-alone fire detector according to the present invention has an advantage that can be easily connected to the disaster prevention system provided in the building in advance without a separate network connection work.

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

1 is a perspective view schematically showing a conventional stand-alone fire detection device. As shown, the conventional stand-alone fire detection device 20 includes a fire detection circuit therein, the main body 21 is attached to the ceiling or wall and the fire detection circuit provided in the main body 21 It is configured to include a cover 22 for protecting, and transmitting the heat applied by the fire to the detection circuit, when heat is applied to the cover 22, the fire detection circuit inside the main body 21 detects the fire Alarm the occurrence. Since the stand-alone fire detection apparatus 20 having the above-described configuration is a well known technique, its detailed description is omitted.

A battery is used as a power source for driving the conventional stand-alone fire detection device 20, and the battery is mainly used as a primary battery. Therefore, even if the stand-alone fire detection device 20 is not driven, the battery is consumed and discharged, so the battery must be replaced to maintain its function continuously.

In addition, when using the commercial power supplied to the drive power in the building, the place where the stand-alone fire detection device 20 is installed is limited to the place where the power terminal is located, in order to install in the place without the power terminal, a new wiring construction Required.

2 is a perspective view schematically showing a stand alone fire detector according to an embodiment of the present invention, Figure 3 is an exploded perspective view schematically showing a stand alone fire detector according to FIG. As shown, the single type fire detector 10 according to a preferred embodiment of the present invention is fixed to one side of the ceiling or wall of the building, by detecting the heat transmitted therein to determine the presence of fire and the result of the fire It includes a fire alarm unit 110 for alarming when it occurs, the base 100 is provided with a plurality of solar cells for converting the light energy incident around the side surface into electrical energy and outputs, coupled to the base 100 It protects the internal circuit, but is configured to include a heat sensing cap 200 for transferring the heat applied to the fire alarm unit (110).

The base 100 is formed of a metal material resistant to heat and external pressure, and one side is bolted to the electric field or the wall using, for example, a screw. The interior of the base 100 is formed to have a sufficient internal space so that the fire alarm 110 is provided.

The outer circumference of the base 100 is provided with a solar cell, which is a semiconductor device that converts the incident light energy into electrical energy and outputs the electrical energy. Solar cells, also known as solar cells, are classified into three types, depending on the crystalline state: monocrystalline silicon solar cells, multicrystalline silicon solar cells, and amorphous silicon solar cells.

Looking at the structure and principle of a general solar cell, a single crystal silicon solar cell is a p-n coupling structure made of a p-type semiconductor made by impregnating silicon with phosphorus, arsenic, antimony, and the like. As such, when the p-type semiconductor and the n-type semiconductor are bonded to one single crystal, surplus electrons of the n-type semiconductor diffuse into the p-type semiconductor due to the difference in concentration of impurities, and conversely, the holes are p-type. Diffuses into n-type at.

As a result, the energy of electrons in the conduction band of the p-type semiconductor becomes narrower than that of the n-type semiconductor, and the energy of holes in the valence band of the n-type semiconductor becomes higher than that of the p-type semiconductor, thereby causing an internal potential difference to occur. do.

At this time, when light energy of more than the prohibited band is absorbed, the electrons in the valence band are excited to move to the conduction band by skipping the prohibited band. Due to such an excitation situation, the electrons in the valence band are vacant to form holes that act like positive charges, thereby creating a pair of positive charges (holes) and negative charges (electrons).

The electron-hole pairs generated in this way move electrons to n-type and holes to p-type by the concentration difference and the potential difference, respectively, so that current flows through the external circuit. In general, a cell refers to a semiconductor device that generates electricity when irradiated with solar radiation energy, and a module refers to a power generation unit of the smallest unit that is electrically connected to a plurality of solar cells and manufactured in consideration of the durability.

The fire alarm unit 110 detects heat transmitted from the heat detection cap 200 to determine whether a fire has occurred, and when it is determined that the fire has occurred, notifies the user of a fire through an alarm. The description of such a fire alarm unit 110 will be described later.

The heat sensing cap 200 is coupled to the upper portion of the base 100, and protects the fire alarm unit 110 provided in the base 100, and transmits heat that is heated when a fire occurs to the fire alarm unit 110. The heat sensing cap 200 is preferably formed of a metal material having excellent thermal conductivity for more effective heat sensing.

Figure 4 is a block diagram schematically showing a fire alarm of the stand-alone fire detector according to an embodiment of the present invention. As shown, the fire alarm 110 of the stand-alone fire detector 10 according to the present invention is a heat detection sensor 111 for detecting the heat applied from the heat detection cap 200 and outputting a detection signal, and the device A battery 112 for supplying power required for driving, a battery charger 113 for charging the battery 112 with electrical energy converted and supplied by a solar cell, and controlling the overall apparatus, and a thermal sensor 111 It is determined whether or not a fire has occurred according to the detection signal output by the control unit, and a fire that receives a fire occurrence signal output from the control unit 114 and a fire occurrence signal output from the control unit 114 to determine the fire occurrence as a result of the determination. It is configured to include an alarm output unit 115.

The thermal sensor 111 detects a change in heat transmitted from the thermal cap 200 and outputs a detection signal to the controller 114. The detection signal output from the thermal sensor 111 may be a digital signal suitable for processing by the controller 114, for example, according to a level of temperature.

The battery 112 is implemented as a secondary battery that can be charged by the battery charger 113, and supplies driving power of the stand-alone fire detector 10. The battery charger 113 receives electrical energy converted and output from the solar cell and charges the battery 112.

The control unit 114 controls the overall fire alarm unit 110, and receives a detection signal output from the heat detection sensor 111 to determine the presence of a fire, if the detection signal is determined to be a fire fire output unit A fire occurrence signal is output to 115. When the digital signal output from the heat sensor 111 is received and compared with a reference value at the time of a fire, and a detection signal according to a value thereof is received, the controller 114 sends a fire signal to the fire alarm output unit 115. Output

The fire alarm output unit 115 is reproduced from an audio reproducing means (not shown) and an audio reproducing means (not shown) for receiving a fire occurrence signal output from the control unit 114 and reproducing and outputting an alarm sound or a buzzer sound. It may be configured to include a speaker (not shown) for converting the output alarm sound or the buzzer sound to an audible sound.

The audio reproducing means (not shown) includes, for example, a sound source reproducing chip such as a YAMAHA chip for reproducing a sound source, or a DSP (Digital Signal Processor) chip, and reproduces from various sound sources and outputs them to a speaker (not shown). The speaker (not shown) outputs various reproduction sounds such as an alarm sound or a buzzer sound reproduced from the audio reproduction means (not shown) according to a control signal output from the control unit 114.

In addition, the fire alarm unit 110 according to the present invention may detect the occurrence of fire by using the conduction of two contacts other than the heat sensor 111. Accordingly, the heat sensing cap 200 is provided with a copper plate 210 of a thin film form therein. When a fire occurs and the heat sensing cap 200 is heated, the air between the heat sensing cap 200 and the copper plate 210 is expanded. Therefore, the expanded air pushes the copper plate 210 toward the fire alarm unit 110, the pushed copper plate 210 allows the two contacts of the fire alarm unit 110 to conduct, and the control unit 114 conducts the two contacts. Determine the fire by checking.

According to an additional aspect of the present invention, the stand-alone fire detector 10 according to the present invention can transmit a fire occurrence signal without any network configuration through wireless communication with the disaster prevention system installed in a building. Accordingly, the stand-alone fire detector 10 further includes a wireless communication unit 116 for transmitting the fire generation signal output from the control unit 114 to the disaster prevention system connected wirelessly.

The wireless communication unit 116 outputs a fire generation signal output from the control unit 114 to a repeater of the disaster prevention system provided in the building in advance through wireless communication. Such a stand-alone fire detector 10 and the repeater of the disaster prevention system, for example, can communicate by wireless communication protocols such as RF, Bluetooth, WLAN, and other wireless communication protocols existing or coming out in addition to the wireless communication protocols described above. Includes everything.

Referring to the operation of the fire occurrence of the stand-alone fire detector 10 according to the present invention with reference to Figures 2 to 4, the heat applied according to the fire occurs through the heat detection cap 200 of the base 100 It is transmitted to the alarm unit 110. The heat detection sensor 111 of the fire alarm unit 110 detects the heat change transmitted by the heat detection cap 200 and outputs a digital signal to the control unit 114.

The control unit 114 receives the digital signal output from the heat detection sensor 111 and compares it with the reference value at the time of fire occurrence, and when a detection signal according to the value of the image is received, sends a fire occurrence signal to the fire alarm output unit 115. Output

The fire alarm unit 110 receives the fire generation signal output from the control unit 114 and reproduces and outputs an alarm sound or a buzzer sound according to the fire occurrence to notify the user of the fire occurrence.

In addition, the controller 114 outputs a fire occurrence signal to the wireless communication unit 116. The wireless communication unit 116 receives this and outputs it to the repeater of the disaster prevention system connected through wireless communication. The repeater receives this and transmits the corresponding fire occurrence signal to the host device of the disaster prevention system, and the disaster prevention system attempts to extinguish using an early extinguishing means such as a sprinkler or a firewall, for example, and fires at an institution such as a fire station. Inform.

As described above, the stand-alone fire detector according to the present invention absorbs light through the solar cell to charge the battery, thereby eliminating unnecessary power wiring work during periodic battery replacement or installation for driving power supply of the fire detector. It has the advantage that it can be used permanently.

In addition, the stand-alone fire detector according to the present invention has the advantage that can be easily used in conjunction with the disaster prevention system provided in advance in the building without a separate network connection work.

On the other hand, the present invention has been described with reference to the embodiments shown in the drawings but this is only exemplary, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. . Therefore, the true technical protection scope of the present invention should be determined only by the attached utility model registration claims.

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

2 is a perspective view schematically showing a stand-alone fire detector according to an embodiment of the present invention.

3 is an exploded perspective view schematically showing a stand alone fire detector according to FIG.

Figure 4 is a block diagram schematically showing a fire alarm of the stand-alone fire detector according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

10. Standalone Fire Detector 20. Standalone Fire Detector

21. Body 22. Cover

100. Base 110. Fire alarm

111. Thermal sensor 112. Battery

113. Battery charging unit 114. Control unit

115. Fire alarm output unit 116. Wireless communication unit

120. Solar cell 200. Heat sensing cap

210. Copper Plate

Claims (3)

In the standalone fire detector, One side is fixed to the ceiling or wall of the building, and includes a fire alarm to detect the presence of fire by detecting the heat transmitted therein and to alert the fire when the result of the determination, electrical energy to the light energy incident around the side A base provided with a plurality of solar cells which are converted to and outputted to each other; A heat sensing cap coupled to an upper portion of the base to protect an internal circuit and transferring heat applied to the fire alarm; Stand-alone fire detector comprising a. The fire alarm system of claim 1, wherein the fire alarm unit: A thermal sensor for sensing heat applied from the thermal cap and outputting a detection signal; A battery for supplying power for driving the device; A battery charger configured to charge the battery with electrical energy converted and supplied by the solar cell; A control unit which controls the overall apparatus, determines whether a fire occurs according to a detection signal output by the heat detection sensor, and outputs a fire occurrence signal when a fire occurs as a result of the determination; A fire alarm output unit configured to receive a fire occurrence signal output from the controller and notify a fire occurrence; Stand-alone fire detector comprising a. The fire alarm system according to claim 1 or 2, wherein the fire alarm unit: Single fire detector, characterized in that it further comprises a wireless communication unit for transmitting a fire generating signal output from the control unit to a wirelessly connected disaster prevention system.