KR102613942B1 - A Fire Detection System Adopting Self Generation By Fire Heat - Google Patents

Abstract

The present invention relates to a fire detection system that generates electricity using heat generated during a fire (thermoelectric element) and can detect a fire using this. The present invention relates to a power generation unit including a thermoelectric element that detects heat generated from the fire in the event of a fire and generates an electrical signal, an electric-optical conversion unit that receives the electrical signal generated from the power generation unit and converts it into a light signal, and an electric-optical conversion unit. A photoelectric conversion unit that receives the light signal and converts it into an electrical signal. The receiver receives the electrical signal generated from the photoelectric conversion unit, and if the size of the electrical signal is above a certain value, a fire alarm is generated or a fire evacuation broadcast is made. or a control unit that controls to transmit a fire signal to cut off electricity or activate fire extinguishing equipment, and the electric-to-light conversion unit and the photoelectric conversion unit are mounted in a sealed dark room so that external light cannot penetrate into the interior, Power generated from the power generation unit can be supplied directly or external power can be supplied to one or more of the control unit, fire alarm unit, fire evacuation broadcast unit, electric cutoff switch, and fire extinguishing equipment operating unit.

Description

Fire detection system adopting self-generation technology by fire heat {A Fire Detection System Adopting Self Generation By Fire Heat}

The present invention relates to a fire detection system that applies self-generation technology using fire heat. More specifically, a fire detection system that generates electricity using the heat generated during a fire (thermoelectric element) and can detect a fire using this. It's about.

Recently, fires have occurred in large buildings, apartments, large shopping malls, department stores, and large logistics warehouses, causing significant casualties and property damage. When a fire breaks out, it is important to respond quickly and extinguish it. There is a strong demand for a system that can actively detect fires in the early stages. In response to this, real-time fire detection methods are being proposed. Most of them only suggest methods for detecting fire through carbon dioxide sensors, temperature sensors, smoke sensors, video cameras, etc.

After repeated research to solve the above problem, we focused on the fact that self-power generation can be generated due to the heat of the fire if a fire occurs without supplying power from outside, and a fire detection system was developed using the heat generated during a fire. It was confirmed that this was possible and the present invention was completed.

1. Registered Patent Publication No. 10-1339405 (2013.12.03.) 2. Registered Patent Publication No. 10-2358776 (2022.01.28.)

The present invention seeks to provide a fire detection system that generates electricity (thermoelectric element) using the heat generated during a fire and can detect a fire using this.

The first aspect of the present invention to solve the above problem is a power generation unit including a thermoelectric element that detects heat generated from the fire in the event of a fire and generates electricity, and receives the electrical signal generated from the power generation unit and converts it into a light signal. An electro-optical converter that receives the light signal generated from the electro-optical converter and converts it into an electric signal. The receiver receives the electric signal generated by the photoelectric converter, and a fire occurs if the size of the electric signal exceeds a certain value. It includes a control unit that controls to transmit a fire signal to generate an alarm, make a fire evacuation announcement, cut off electricity, or activate fire extinguishing equipment, and the electric-optical conversion unit and the photoelectric conversion unit allow external light to penetrate into the interior. It is installed in a sealed dark room so that power generated from the power generation unit can be supplied directly or external power to one or more of the control unit, fire alarm unit, fire evacuation broadcast unit, electric cutoff switch, and fire extinguishing equipment operating unit. It may be a fire detection system that applies self-generation technology using fire heat.

The second aspect of the present invention is a power generation unit including a thermoelectric element that detects heat generated from the fire in the event of a fire and generates electricity, an electro-optical conversion unit that receives the electrical signal generated from the power generation unit and converts it into a light signal, The optical transmitter receives the light signal generated from the converter and transmits the light signal as is. The receiver receives the light signal generated from the optical transmitter and generates a fire alarm when the size of the light signal is above a certain value. , a control unit that controls to transmit a fire signal to make a fire evacuation announcement, cut off electricity, or activate fire extinguishing equipment, and the electric-to-light conversion unit and optical transmission unit are sealed so that external light cannot penetrate into the interior. It is installed in a dark room and supplies power generated from the power generation unit directly or supplies external power to one or more of the control unit, fire alarm unit, fire evacuation broadcast unit, electric cutoff switch, and fire extinguishing equipment operation unit, and magnetic field generated by fire heat is supplied. It may be a fire detection system using power generation technology.

The third aspect of the present invention is a power generation unit that includes a thermoelectric element that detects heat generated from the fire in the event of a fire and generates electricity, and the reception unit receives the electrical signal generated from the power generation unit, so that the size of the electrical signal is maintained at a certain value. If it is above, it includes a control unit that controls to transmit a fire signal to generate a fire alarm, make a fire evacuation broadcast, cut off electricity, or activate fire extinguishing equipment, and includes a control unit, a fire alarm unit, a fire evacuation broadcast unit, It may be a fire detection system that applies self-generation technology using fire heat, supplying power generated from the power generation unit directly or supplying external power to one or more of the electric cutoff switch and the fire extinguishing equipment operating unit.

For example, the power generation unit includes a collection unit, a thermoelectric element unit, and a cooling unit arranged sequentially, the collection unit collects fire heat and transfers it to the thermoelectric element unit, the thermoelectric element unit generates electricity using heat, and the cooling unit uses thermoelectric energy. It may include a heat sink that receives heat generated from the device and a cooling module that radiates heat to the outside through a heat medium.

For example, an additional fire detection sensor is installed at the place where a fire occurs, and the control unit receives a fire signal from a fire monitoring sensor to generate a fire alarm, make a fire evacuation announcement, cut off electricity, or It can be controlled to transmit a fire signal to activate fire extinguishing equipment.

For example, the fire detection sensor is directly connected to one or more of the fire alarm unit, fire evacuation broadcast unit, electric cutoff switch, and fire extinguishing equipment operation unit, and can independently transmit a fire signal in the event of a fire.

For example, the fire detection sensor may include one or more of a heat sensor, a temperature sensor, a smoke sensor, and a light sensor.

According to the present invention, it is intended to provide a fire detection system that generates electricity (thermoelectric element) using the heat generated during a fire and can detect a fire using this.

1 is a schematic diagram of a fire detection system according to the first aspect of the present invention.
Figure 2 is a schematic diagram of a fire detection system according to the second aspect of the present invention.
Figure 3 is a schematic diagram of a fire detection system according to the third aspect of the present invention (wired communication).
Figure 4 is a schematic diagram of a modified example of a fire detection system according to the third aspect of the present invention (wireless communication).
Figure 5 is a schematic diagram schematically showing the structure of the power generation unit in the fire detection system of the present invention.
Figure 6 is a schematic diagram illustrating the arrangement of thermoelectric elements within the thermoelectric element unit in the fire detection system of the present invention.
Figures 7 and 8 are schematic diagrams of a power supply capable of self-supplying the power of various facilities in the fire detection system of the present invention.
Figure 9 is a schematic diagram of applying the fire detection system of the present invention to a fire-resistant infill structure.

Hereinafter, preferred embodiments of the present invention will be described with reference to the attached drawings. Embodiments of the present invention may be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. Embodiments of the present invention are provided to more completely explain the present invention to those skilled in the art. Accordingly, the shapes and sizes of elements in the drawings may be exaggerated for clearer explanation, and elements indicated by the same symbol in the drawings are the same element. In the present invention, the expression first or second does not mean order or importance, but is simply used to distinguish components.

The present invention relates to a fire detection system that generates electricity using heat generated during a fire (using a thermoelectric element) and can detect a fire using this.

Figure 1 shows a schematic diagram of a fire detection system according to the first aspect of the present invention. Figure 2 shows a schematic diagram of a fire detection system according to the second aspect of the present invention. Figure 3 shows a schematic diagram of a fire detection system according to the third aspect of the present invention (wired communication). Figure 4 shows a schematic diagram of a modified example of the fire detection system according to the third aspect of the present invention (wireless communication). Figure 5 schematically shows the structure of the power generation unit in the fire detection system of the present invention. Figure 6 exemplarily shows the arrangement of thermoelectric elements within the thermoelectric element unit in the fire detection system of the present invention. Figures 7 and 8 show a schematic diagram of a power supply capable of self-supplying the power of various facilities in the fire detection system of the present invention. Figure 9 shows a schematic diagram of applying the fire detection system of the present invention to a fire-resistant filled structure.

Hereinafter, the present invention will be described with reference to the drawings.

Referring to FIGS. 1, 5, and 6, the first aspect of the present invention is a power generation unit 10 including a thermoelectric element that generates electricity by detecting heat generated from the fire in the event of a fire, and An electro-optical converter 41 that receives an electrical signal and converts it into a light signal, a photoelectric converter 42 that receives a light signal generated from the electro-optical converter 41 and converts it into an electric signal, and a photoelectric converter in the receiving module 31. Receives an electrical signal generated from the converter 42, and when the size of the electrical signal is above a certain value, a fire alarm is generated, a fire evacuation broadcast is made, electricity is cut off, or fire extinguishing equipment is activated. It includes a control unit 30 that controls signal transmission, and the electro-optical conversion unit 41 and photoelectric conversion unit 42 are mounted in a sealed dark room 40 so that external light cannot penetrate into the interior, and the control unit ( 30), self-generation by fire heat that directly supplies power generated in the power generation unit (10) or supplies external power to one or more of the fire alarm unit, fire evacuation broadcast unit, electric cutoff switch, and fire extinguishing equipment operating unit. It may be a fire detection system using technology.

In the event of a fire, the power generation unit 10 may detect heat generated from the fire and generate an electrical signal. In the power generation unit 10, a collection unit 11, a thermoelectric element unit 12, and a cooling unit 15 may be sequentially arranged from a heat source.

The collecting unit 11 can collect fire heat and transfer it to the thermoelectric element unit 12. The heat collecting unit 11 can generally be made of metal, organic material, inorganic material, or organic-inorganic composite material in the form of a heat collecting plate with excellent thermal conductivity. The heat collecting plate can have various shapes such as flat, fin, or curved surface. The heat collecting part 11 may be mounted in contact with the high temperature part of the thermoelectric element part 12.

When a plurality of thermoelectric elements 121 are mounted on the thermoelectric element unit 12, the heat collection unit 11 can evenly transfer heat to each thermoelectric element 121. If the heat transferred to each thermoelectric element 121 is significantly different, it is not easy to configure circuits such as series/parallel connections to obtain the desired voltage and current, and the lifespan of each thermoelectric element 121 is different, so the overall product quality is low. Lifespan characteristics may deteriorate.

The thermoelectric element unit 12 can generate electricity using heat. A thermoelectric element 121 (or Peltier element) can be used to generate electricity using heat. The thermoelectric element unit 12 may include a plurality of thermoelectric elements 121. A plurality of thermoelectric elements 121 can be adjusted to generate a desired voltage and current through series connection, parallel connection, or a combination of series and parallel connection (see FIG. 6).

The thermoelectric element 121 is a component that utilizes the Seebeck Effect, which generates electromotive force when two different metals or n-type/p-type semiconductors are placed in parallel and a temperature difference is added to both ends. The thermoelectric element 121 has a high temperature part disposed close to the heat source and a low temperature part opposite to it. The larger the temperature difference between the high-temperature section and the low-temperature section, the greater the voltage and current may increase. For this reason, by providing the cooling part 15 in the low temperature part, the temperature difference between the high temperature part and the low temperature part can be increased, and thus a higher voltage and current can be obtained. The voltage and current generated can be adjusted by controlling the temperature difference between the high and low temperature parts.

A cooling unit 15 may be provided in the low temperature part of the thermoelectric element unit 121. The heat generated in the thermoelectric element 12 can be discharged to the outside through the cooling unit 121 to maintain the durability of the thermoelectric element 12 and prevent performance degradation. The cooling unit 15 may include a heat sink 13 and a cooling module 14. The heat sink 13 may be in contact with the low temperature portion of the thermoelectric element 12 to transfer heat generated in the thermoelectric element 12 to the cooling portion 15. The heat sink 13 may be made of a material with excellent thermal conductivity. This is not limited to metals, and may include organic materials, inorganic materials, and organic-inorganic composite materials.

The cooling module 14 is for rapid heat dissipation and can use a fan, refrigerant, etc. The cooling module 14 may radiate heat to the outside through a heat medium. In the case of air cooling using air as the heating medium, a fan can be used. In addition, liquid, solid, etc. can be used as a refrigerant, and the liquid is preferably one that has high specific heat or volatility, and the solid is preferably one that can be melted at an appropriate temperature.

The power required to drive a fan, etc. can be supplied by the power generated by the power generation unit 10. In this case, the configuration can be simplified as there is no need for an external power source. However, in case of a breakdown, you can connect an external power source and use the external power source in an emergency.

The electro-optical conversion unit 41 may receive an electrical signal generated from the power generation unit 10 and convert it into a light signal. Light generated from the electric-light conversion unit 41 may include light in all wavelength ranges, such as infrared light, visible light, and ultraviolet light. The power required for the operation of the electric-optical conversion unit 41 can be supplied by the power generated by the power generation unit 10. However, in case of a breakdown, you can connect an external power source and use the external power source only in an emergency.

The photoelectric conversion unit 42 can receive the light signal generated by the electro-optical conversion unit 41 and convert it into an electrical signal. This can be done using any electronic component that applies the principle of the photoelectric effect. For example, a variety of optical sensors can be used. The power required for the operation of the photoelectric conversion unit 42 can be supplied by the power generated by the power generation unit 10. However, in case of a breakdown, you can connect an external power source and use the external power source in an emergency.

The electro-light conversion unit 41 and the photoelectric conversion unit 42 may be mounted in a sealed dark room 40 so that external light cannot penetrate into the interior. This is to block electromagnetic interference such as light from the outside and prevent malfunction due to noise entering the device.

The control unit 30 may include a receiving module 31 and a transmitting module. The receiving module 31 may receive an electrical signal generated from the photoelectric conversion unit 42. The receiving module 31 may recognize the received electrical signal as voltage-current or convert it into temperature data. The transmission module can transmit a control signal to each operating facility under the control of the control unit 30. If the size of the electrical signal generated from the photoelectric conversion unit 42 received by the receiving module 31 is greater than a certain value, the control unit 30 generates a fire alarm, broadcasts a fire evacuation, cuts off electricity, or Alternatively, the fire signal that causes the fire extinguishing equipment to operate can be controlled to be transmitted from the transmission module to each operating equipment. In Figure 1, etc., it is indicated as an electric cutoff switch (S/W), fire extinguishing equipment operation transmitter, fire information transmission wired and wireless transmitter, evacuation broadcast transmitter, etc.

The power required for the operation of the control unit 30 (receiving module 31 and transmitting module) can be self-sufficient with power generated by the power generation unit 10. However, in case of a breakdown, you can connect an external power source and use the external power source only in an emergency.

In addition to the control unit 30, in the case of the fire alarm unit, fire evacuation broadcast unit, electric cutoff switch, and fire extinguishing equipment operation unit, the power required for the operation can be self-sufficient with the power generated in the power generation unit 10. The power generated in the power generation unit 10 may be directly supplied to various operating facilities, or may be supplied to various operating facilities after passing through an inverter or the like (see FIGS. 7 and 8). However, in case of a breakdown, you can connect an external power source and use the external power source in an emergency.

Fire detection sensors can be additionally installed at the location of the fire. The fire detection sensor may include one or more of a heat sensor, a temperature sensor, a smoke sensor, and a light sensor. It can recognize that a fire has occurred by detecting heat, temperature, smoke, and light.

The fire signal detected by the fire detection sensor may be transmitted to the control unit 30 by wire or wirelessly. The control unit 30 receives a fire signal generated from a fire monitoring sensor and controls the fire signal to be transmitted to generate a fire alarm, make a fire evacuation broadcast, cut off electricity, or operate fire extinguishing equipment. You can.

In contrast, the fire detection sensor may be directly connected to one or more of each operating facility, that is, a fire alarm unit, a fire evacuation broadcast unit, an electric cutoff switch, and a fire extinguishing facility operating unit, and may independently transmit a fire signal.

In short, the fire signal detected by the fire detection sensor may be transmitted to each facility through the control unit 30, or may be directly transmitted to each operating facility without going through the control unit 30. Or, they may be delivered simultaneously. In the event of a fire, damage to life and property is significantly significant, so dual fire signal transmission paths can be configured as a preventive measure in case of malfunction of either path.

Referring to FIG. 2, the second aspect of the present invention includes a power generation unit 10 including a thermoelectric element that generates electricity by detecting heat generated from the fire in the event of a fire, and an electrical signal generated from the power generation unit 10. An electro-optical converter 41 that receives the light signal and converts it into an optical signal, an optical transmitter 43 that receives the light signal generated by the electro-optical converter 41 and transmits the light signal as is, and an optical transmitter in the receiving module 31. By receiving the light signal generated at (43), if the size of the light signal is above a certain value, a fire alarm is generated, a fire evacuation broadcast is made, electricity is cut off, or a fire signal is sent to activate fire extinguishing equipment. It includes a control unit 30 that controls transmission from the transmission module, and the electric-to-light conversion unit 41 and the optical transmission unit 43 are mounted in a sealed dark room 40 so that external light cannot penetrate into the interior, and the control unit , one or more of the fire alarm unit, fire evacuation broadcast unit, electric cutoff switch, and fire extinguishing equipment operating unit is equipped with self-generation technology using fire heat, which directly supplies power generated from the power generation unit 10 or supplies external power. It may be an applied fire detection system.

In the first aspect, the electrical signal generated by the thermoelectric element is converted into a light signal within the dark room 40, converted back into an electrical signal, and then transmitted to the control unit 30, while in this aspect, the light signal is converted back into an electrical signal. The difference is that the light signal is transmitted to the control unit 30 as is, rather than converted into a signal. These differences are explained. Matters in common with the first aspect above are the same as the previous description.

The optical transmission unit 43 may receive the light signal generated by the electro-optical conversion unit 41 and transmit the light signal as is to the reception module 31 of the control unit 30. The optical transmission unit 43 may transmit an optical signal. The optical transmission unit 43 can generally use an optical fiber, that is, an optical cable. In the case of optical signals, there is almost no loss during signal transmission, so transmission efficiency is excellent. Optical fibers can be used singly or in bundles.

The control unit 30 can receive a light signal, determine that a fire has occurred if its size is greater than a certain value, and control the light signal to be transmitted to each facility, etc. Alternatively, the received light signal can be converted into an electric signal, and if the size of the electric signal is above a certain value, it is determined that a fire has occurred, and the fire signal can be controlled to be transmitted to each facility, etc.

The electric-light conversion unit 41 and the optical transmission unit 43 may be mounted in a sealed dark room 40 so that external light cannot penetrate into the interior. In particular, the light receiving part, which is the part where light enters the optical fiber, must be present in the dark room 40. This is to block electromagnetic interference such as light from the outside and prevent malfunction due to noise entering the device.

Referring to FIGS. 3 and 4, the third aspect of the present invention is a power generation unit 10 including a thermoelectric element that generates electricity by detecting heat generated from the fire in the event of a fire, and a power generation unit in the receiving module 31. By receiving the electrical signal generated in (10), if the size of the electrical signal is above a certain value, a fire alarm is generated, a fire evacuation broadcast is made, electricity is cut off, or a fire signal is sent to activate fire extinguishing equipment. It includes a control unit 30 that controls transmission from the transmission module, and the power generated from the power generation unit is directly supplied to any one or more of the control unit, fire alarm unit, fire evacuation broadcast unit, electric cutoff switch, and fire extinguishing equipment operation unit or from an external source. It may be a fire detection system that applies self-generation technology using fire heat, which supplies power.

In the first aspect, the electrical signal generated in the power generation unit 10 is converted into a light signal in the dark room 40, converted back into an electrical signal, and then transmitted to the control unit, whereas in this aspect, the power generation unit 10 There is a difference in that the electrical signal generated in is not converted into a light signal but is transmitted as is to the control unit 30. The electrical signal generated in the power generation unit 10 may be transmitted to the control unit through wired or wireless communication (see FIGS. 3 and 4). Matters in common with the first aspect above are the same as the previous description.

Figure 9 shows a schematic diagram of the fire detection system of the present invention applied to the fire-resistant filling structure 50. When installing power equipment such as power cables, cable trays, booth ducts, and piping in a building, holes are drilled and installed in the fireproof wall 60, and a space is formed between the hole formed in the fireproof wall and the power equipment. Fire can spread through. To prevent the spread of fire, the space between the power equipment and the fireproof wall is filled with refractory material, and the structure formed in this way can be called a fireproof filled structure. Referring to FIG. 9, the collecting unit 11 of the power generation unit 10 may be exposed to the fire heat source.

The terms used in the present invention are intended to describe specific embodiments and are not intended to limit the present invention. Unless it is clear from the context, singular expressions should be considered to have a plural meaning. Terms such as “include” or “have” mean that the features, numbers, steps, operations, components, or combinations thereof described in the specification exist, but are not intended to exclude them.

The present invention is not limited by the above-described embodiments and the attached drawings, but is intended to be limited by the attached claims. Accordingly, various substitutions, modifications and changes may be made by those skilled in the art without departing from the technical spirit of the present invention as set forth in the claims, and these should also be considered to fall within the scope of the present invention. something to do.

10: Power generation department
11: Collection part
12: Thermoelectric element part
13: heat sink
14: cooling module
15: Cooling unit
16: Fire heat source
30: control unit
31: receiving module
40: Darkroom
41: Electric light conversion unit
42: Photoelectric conversion unit
43: Optical transmission unit
50: Fire-resistant filled structure
60: fire wall
121: thermoelectric element

Claims (7)

A power generation unit including a thermoelectric element that generates electricity by detecting heat generated from the fire in the event of a fire;
An electro-optical conversion unit that receives the electrical signal generated from the power generation unit and converts it into a light signal;
a photoelectric conversion unit that receives the light signal generated by the electro-optical conversion unit and converts it into an electric signal;
The receiving module receives the electrical signal generated from the photoelectric conversion unit, and when the size of the electrical signal is above a certain value, a fire alarm is generated, a fire evacuation broadcast is made, electricity is cut off, or fire extinguishing equipment is activated. It includes a control unit that controls the fire signal to be transmitted from the transmission module,
The electro-optical conversion unit and the photoelectric conversion unit are mounted in a sealed dark room so that external light cannot penetrate into the interior,
Power generated by the power generation unit is directly supplied to one or more of the control unit, fire alarm unit, fire evacuation broadcast unit, electric cutoff switch, and fire extinguishing equipment operating unit, or external power is supplied,
A fire detection sensor is additionally installed at the place where a fire occurs, and the control unit receives a fire signal generated from the fire detection sensor and generates a fire alarm, broadcasts a fire evacuation, cuts off electricity, or extinguishes the fire. Controlling the transmission of a fire signal to activate the equipment,
The fire detection sensor is directly connected to one or more of the fire alarm unit, fire evacuation broadcast unit, electric cutoff switch, and fire extinguishing equipment operation unit, and independently transmits a fire signal in the event of a fire.
A fire detection system that applies self-generation technology using fire heat.
A power generation unit including a thermoelectric element that generates electricity by detecting heat generated from the fire in the event of a fire;
An electro-optical conversion unit that receives the electrical signal generated from the power generation unit and converts it into a light signal;
an optical transmission unit that receives the light signal generated by the electro-optical conversion unit and transmits the light signal as is;
The receiving module receives the light signal generated from the optical transmission unit, and when the size of the light signal is above a certain value, a fire alarm is generated, a fire evacuation broadcast is made, electricity is cut off, or fire extinguishing equipment is activated. It includes a control unit that controls the fire signal to be transmitted from the transmission module,
The electric-light conversion unit and the optical transmission unit are mounted in a sealed dark room so that external light cannot penetrate into the interior,
Power generated by the power generation unit is directly supplied to one or more of the control unit, fire alarm unit, fire evacuation broadcast unit, electric cutoff switch, and fire extinguishing equipment operating unit, or external power is supplied,
A fire detection sensor is additionally installed at the place where a fire occurs, and the control unit receives a fire signal generated from the fire detection sensor and generates a fire alarm, broadcasts a fire evacuation, cuts off electricity, or extinguishes the fire. Controlling the transmission of a fire signal to activate the equipment,
The fire detection sensor is directly connected to one or more of the fire alarm unit, fire evacuation broadcast unit, electric cutoff switch, and fire extinguishing equipment operation unit, and independently transmits a fire signal in the event of a fire.
A fire detection system that applies self-generation technology using fire heat.
A power generation unit including a thermoelectric element that generates electricity by detecting heat generated from the fire in the event of a fire;
The receiving module receives the electrical signal generated from the power generation unit, and when the size of the electrical signal is above a certain value, a fire alarm is generated, a fire evacuation broadcast is made, electricity is cut off, or fire extinguishing equipment is activated. It includes a control unit that controls the fire signal to be transmitted from the transmission module,
Power generated by the power generation unit is directly supplied to one or more of the control unit, fire alarm unit, fire evacuation broadcast unit, electric cutoff switch, and fire extinguishing equipment operating unit, or external power is supplied,
A fire detection sensor is additionally installed at the place where a fire occurs, and the control unit receives a fire signal generated from the fire detection sensor and generates a fire alarm, broadcasts a fire evacuation, cuts off electricity, or extinguishes the fire. Controlling the transmission of a fire signal to activate the equipment,
The fire detection sensor is directly connected to one or more of the fire alarm unit, fire evacuation broadcast unit, electric cutoff switch, and fire extinguishing equipment operation unit, and independently transmits a fire signal in the event of a fire.
A fire detection system that applies self-generation technology using fire heat.
According to any one of claims 1 to 3,
The power generation unit includes a collection unit, a thermoelectric element unit, and a cooling unit arranged sequentially, the collection unit collects fire heat and transfers it to the thermoelectric element unit, the thermoelectric element unit generates electricity using heat, and the cooling unit A fire detection system applying self-generation technology using fire heat, including a heat sink that receives heat generated from the thermoelectric element unit and a cooling module that radiates heat to the outside through a heating medium.
delete delete According to any one of claims 1 to 3,
The fire detection sensor is a fire detection system that applies self-generation technology by fire heat, including one or more of a heat sensor, a temperature sensor, a smoke sensor, and an optical sensor.