Patent Grant
12246202
The present disclosure relates to a screen-type fire suppression system for an electric vehicle, and more particularly, to a screen-type fire suppression system for an electric vehicle which, in the event of a fire in a parked electric vehicle, unfolds a screen on the sides of the electric vehicle to prevent the spread of the fire and simultaneously increase the concentration of water sprayed onto the electric vehicle, thereby maximizing fire suppression efficiency.
In recent years, electric vehicles have been rapidly adopted, and the number of electric vehicle charging stations has gradually increased. However, electric vehicles often catch fire during charging at charging stations, which has become a social issue. In particular, if a fire breaks out in an underground parking garage, the rapidly increasing toxic gases and the spread of fire in a confined space may pose a deadly threat to residents.
For a fire in an electric vehicle, it is impossible to extinguish the fire by using a conventional automatic fire extinguishing system (sprinkler) or fire extinguisher due to the rapid occurrence of flashover and the inability of a fire extinguishing agent to reach a battery mounted on a lower portion of a vehicle body.
To resolve these issues, Korean Patent No. 10-2431474 proposes a method for extinguishing a fire, which involves forming a water tank and immersing the battery in water filled within the water tank. However, the conventional water tank formation apparatus has a complex installation structure, resulting in high production costs. In addition, a large quantity of water is required to fill an entire tube, leading to further cost issues. Furthermore, the time taken to fill the water tank to immerse the battery makes the conventional apparatus ineffective.
The present disclosure relates to a screen-type fire suppression system for an electric vehicle, and more particularly, to a screen-type fire suppression system for an electric vehicle which, in the event of a fire in a parked electric vehicle, unfolds a screen on the sides of the electric vehicle to prevent the spread of the fire and simultaneously increase the concentration of water sprayed onto the electric vehicle, thereby maximizing fire suppression efficiency.
The screen-type fire suppression system for an electric vehicle according to the present disclosure includes: a frame positioned to have a predetermined height in a vertical direction from a ground surface of a parking area; a screen coupled to the frame and configured to be unfolded downward in the vertical direction; and a cooler positioned above the frame in the vertical direction, wherein when a fire breaks out in an electric vehicle parked in the parking area, the screen is unfolded to surround both sides of the electric vehicle and water is sprayed through the cooler to suppress the fire in the electric vehicle.
In addition, in the screen-type fire suppression system for an electric vehicle according to the present disclosure, the screen is unfolded to surround both sides and front and rear portions of the electric vehicle.
In addition, the screen-type fire suppression system for an electric vehicle according to the present disclosure further includes a tube embedded in the ground surface of the parking area; when a fire breaks out in the electric vehicle parked in the parking area, the tube expands and surrounds both sides of the electric vehicle.
In addition, in the screen-type fire suppression system for an electric vehicle according to the present disclosure, water is controlled to be sprayed through the cooler after the tube expands and surrounds both sides of the electric vehicle.
In addition, in the screen-type fire suppression system for an electric vehicle according to the present disclosure, the tube is embedded in a step vertically recessed downward from the ground surface of the parking area.
In addition, in the screen-type fire suppression system for an electric vehicle according to the present disclosure, the frame is fixed, through a bolt, to a ceiling of the parking area.
In addition, in the screen-type fire suppression system for an electric vehicle according to the present disclosure, the frame is fixed, through a bolt, to a structure formed on the ground surface of the parking area and configured to extend in the vertical direction.
The present disclosure enables the most effective fire suppression method to be established by spraying water directly onto the electric vehicle in which a fire breaks out.
In addition, the present disclosure creates a configuration similar to spraying water into a partition wall formed by the screen, resulting in the concentrated spraying of water onto the electric vehicle and the blocking of oxygen by the partition wall, thereby boosting fire suppression efficiency.
In addition, the present disclosure forms a double partition wall through the tube and the screen to minimize water outflow, thereby enhancing fire suppression concentration. In addition, unlike a conventional system, the double partition wall effect eliminates the need to manufacture the tube to expand to a height of a vertical end of the electric vehicle, thereby reducing costs.
In addition, miniaturization is achievable, and the fire suppression system according to the present disclosure does not require much space for installation in an actual parking area, thereby demonstrating practicality.
Various embodiments of the present disclosure will be described in detail below with reference to the accompanying drawings.
A fire suppression system according to the present disclosure includes a first suppressor 100, a cooler 200, and a third suppressor 400.
First, the fire suppression system according to the present disclosure is installed in an electric vehicle parking area. In the electric vehicle parking area, a charger is typically installed and as described above, a fire may break out.
The first suppressor 100, in turn, includes a frame 110, a support 120, an auxiliary frame 130, and a screen 140.
The frame 110 is positioned to have a predetermined height in a vertical direction from the ground surface 1. In this case, the auxiliary frame 130 is formed to extend from an upper portion of the frame 110, and the auxiliary frame 130 is preferably installed by being fixed, through a bolt 600, to the ceiling 2. The bolt 600 may be, for example, an anchor bolt. This allows the frame 110 to be installed by using only the bolt 600, without an additional installation member, thereby reducing the installation difficulty for an operator.
More specifically, the frame 110 is preferably configurated as a square frame with a hollow portion formed therein. Thus, the frame 110 is preferably formed in a configuration that surrounds both sides and front and rear portions of an electric vehicle 10 in the parking area (strictly speaking, a configuration in which the screen 140 extending from a lower portion of the frame 110 surrounds both sides and front and rear portions of the electric vehicle 10).
The support 120 is located on the frame 110, and the screen 140 is formed between the frame 110 and the support 120. Thus, an upper portion of the screen 140 is coupled to the frame 110, and a lower portion of the screen 140 is coupled to the support 120.
In this case, the support 120 may descend in a vertical direction with respect to the frame 110.
At each corner of the frame 110, a connector 111 is formed to extend downward in a vertical direction and protrude therefrom, and a spring 112 is positioned in the connector 111. An upper end of the spring 112 is coupled to the frame 110, and a lower end of the spring 112 is coupled to the support 120. Thus, before the screen 140 is unfolded, the connector 111 and the support 120 are coupled (illustrated as being spaced apart a certain distance from each other in
In this case, the connector 111 and the support 120 are magnetically coupled. In addition, as will be described later, the magnetic coupling is adjusted to an on/off state, and in an off state, the support 120 is detached from the connector 111.
Due to the contraction of the spring 112 described above, a pulling force is generated in a vertical direction from downward to upward, which enhances a coupling strength between the connector 111 and the support 120, thereby minimizing the occurrence of unfolding of the screen 140 due to a malfunction before the screen 140 is intended to unfold.
As an example of magnetic coupling, the support 120 may be made of a magnetic material, and a control structure that may regulate an electrical flow may be formed in the connector 111 to establish a coupling configuration.
Thus, when a fire detection sensor (not illustrated) detects a fire in an electric vehicle, the electrical flow is controlled to be cut off and switches from an on state to an off state, thereby causing the support 120 to be detached from the connector 111. In this case, the support 120 descends in a vertical direction by gravity, and the screen 140, which has been folded, is unfolded to form a shape shown in
In this case, the spring 112 performs a role as a damper to prevent a rapid descent of the screen 140, thereby minimizing the probability of the support 120 colliding with the ground surface 1 and being damaged. This is because, without the role as a damper, the support 120 may collide with the ground surface 1 and be damaged, and the structure in which the screen 140 surrounds the electric vehicle 10 may not be established.
As described above, when the screen 140 is unfolded, the screen 140 is formed to surround both sides and front and rear portions of the electric vehicle 10 in which a fire breaks out. Thus, the screen 140 may quickly prevent the fire from spreading beyond the parking area, and may block the airflow to prevent the flames from intensifying. The screen 140 is preferably made of, for example, a flame-retardant, fire-resistant material.
In addition, water is sprayed from the cooler 200 to suppress the fire.
The cooler 200 includes a pipe 210 and a nozzle 220. The pipe 210 is preferably formed to extend along the ceiling 2, and is preferably interconnected with an external water tank to receive water. The pipe 210 may be fixed, through the bolt 600, to the ceiling 2.
A plurality of the nozzles 220 are coupled at a plurality of points of the pipe 210, respectively. As a result, water W flowing into the pipe 210 is sprayed, through the nozzle 220, downward in the vertical direction. More specifically, the nozzle 220 is positioned upward in a vertical direction of the frame 110, but is preferably positioned to spray the water W into the frame 110. The spraying of the water W is preferably turned on/off through the fire detection mechanism described above.
In this case, an exhaust outlet 800 may be coupled at one point of the auxiliary frame 130. Smoke produced in the event of a fire, or smoke produced after fire suppression may be discharged through the exhaust outlet 800. The exhaust outlet 800 is preferably designed to communicate with a building's exhaust outlet (not illustrated) such that smoke may be discharged to the outside. The exhaust outlet 800 may be, for example, in the form of bellows, which enables easy shape adjustment and reduces limitations on the installation location of the exhaust outlet 800.
Such a configuration has the following effects.
First, the most effective fire suppression method may be established by spraying water directly onto the electric vehicle 10 in which a fire breaks out.
Next, the water is sprayed into the frame 110 as described above, and the sprayed water is also sprayed into a partition wall formed by the screen 140, thereby creating a configuration similar to spraying water into a water tank formed by the screen 140 and resulting in the concentrated spraying of water onto the electric vehicle 10 (e.g., the water reflected from the screen 140 is directed back to the electric vehicle 10, thereby maximizing fire suppression efficiency).
Finally, as will be described later, the suppression effect is maximized through the synergistic effect with the third suppressor 400, which will be described later.
Next, the third suppressor 400 will be described.
The third suppressor 400 includes a tube 410.
Preferably, the ground surface 1 of the parking area on which the screen-type fire suppression system for an electric vehicle according to the present disclosure is to be installed is preferably pre-constructed such that a vertically recessed groove 1a is formed to form a step on the ground surface 1. The groove 1a is preferably formed along both sides of the parking area, and the tube 410 is embedded in the groove 1a. In addition, although not illustrated, a temporary cover is preferably coupled to an upper portion of the tube 410.
In addition, the screen 140 and the tube 410 are preferably installed to be arranged in the sequence of the screen 140 followed by the tube 410 from the outside to the inside, when the screen 140 described above descends. As the support 120 coupled to the lower portion of the screen 140 may ultimately not be coupled to the ground surface 1, a gap inevitably appears between the support 120 and the ground surface 1. Thus, water may be lost during the fall.
Thus, fire suppression concentration may be maximized by first confining water through the tube 410 and allowing the screen 140 to assist in preventing the outflow of falling water from the outside of the tube 410.
As described above, when a fire in the electric vehicle 10 is detected, the tube 410 is preferably controlled to expand. The tube 410 is vertically raised and expands to surround both sides of the electric vehicle 10. In the process, the temporary cover is removed due to an expansion force.
In this case, through controlling, water is preferably controlled to be sprayed after the tube 410 expands to surround both sides of the electric vehicle 10. When the tube 410 expands to form a predetermined partition wall and then water is sprayed, the outflow of water may be minimized, thereby increasing fire suppression concentration.
As described above, the present disclosure increases fire suppression concentration by minimizing the outflow of water being sprayed through the combination of the tube 410 and the screen 140. Thus, since a two-layer partition is established, there is no need to build the tube 410 to match a full vertical height of an electric vehicle, as in a related art. Thus, cost reduction is achieved compared to the related art. In addition, fire suppression concentration may be increased.
In addition, as described above, the first suppressor 100 and the cooler 200 are installed on the ceiling 2, and thus not pose any risk of obstructing the movement of the electric vehicle 10 parked in the parking area. The third suppressor 400 is embedded in a groove recessed in the parking area under normal conditions, and thus does not pose any risk of obstructing the movement of the electric vehicle 10 either. Thus, miniaturization is achievable, and the fire suppression system according to the present disclosure does not require much space for installation in an actual parking area, thereby demonstrating practicality.
A fire suppression system according to yet another embodiment of the present disclosure includes a configuration of the fire suppression system according to the one embodiment, wherein an auxiliary tube 420 is formed to extend from an inner side of the tube 410. The auxiliary tube 420 is further formed on the inner side of the tube 410 toward the electric vehicle 10, wherein after an upward movement of the tube 410, the auxiliary tube 420 preferably further expands from the inner side of the tube 410, as shown in
According to yet another embodiment, a space for accommodating the water W through a tube becomes smaller than in the one embodiment. Accordingly, a smaller amount of the water W flows into the space than in the one embodiment, and thus, the space may be filled with the water W more quickly than in the one embodiment. The principle of fire suppression involves filling the tube with the water W sequentially from the bottom to the top in the vertical direction until the water W comes into contact with a battery. Thus, the faster the water W fills the tube, the faster the water W comes into contact with the battery, thereby accelerating fire suppression. In addition, the amount of the water W required for fire suppression is smaller than in the one embodiment, thereby facilitating energy saving.
In this case, more preferably, the auxiliary tube 420 expands to have a lower height in the vertical direction than the tube 410, such that a stepped space in the vertical direction is formed between the tube 410 and the auxiliary tube 420. Thus, the auxiliary tube 420 and the wheels of the electric vehicle become spaced apart from each other to secure a space therebetween, thereby forming a flow path through which the falling water W may be quickly supplied to the electric vehicle 10 without being blocked by the auxiliary tube 420.
In addition, although preferred embodiments of the present disclosure have been illustrated and described above, the present disclosure is not limited to the specific embodiments described above, and various modifications may be made by those skilled in the art to which the present disclosure pertains without departing from the gist of the present disclosure as claimed in the claims. Furthermore, such modifications should not be understood individually apart from the technical spirit or perspective of the present disclosure.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10-2023-0134763 | Oct 2023 | KR | national |
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| Number | Date | Country |
|---|---|---|
| 102714492 | Mar 2020 | KR |
| 20230111779 | Jan 2022 | KR |
| 20230123542 | Feb 2022 | KR |
| 10-2431474 | Aug 2022 | KR |
| 102503331 | Oct 2022 | KR |
| 20240098370 | Dec 2022 | KR |
| 20240101235 | Dec 2022 | KR |
| 20240124461 | Feb 2023 | KR |
| 20240132646 | Feb 2023 | KR |
| 102681724 | Mar 2023 | KR |
| 102669826 | Jun 2023 | KR |
| 10-2565044 | Aug 2023 | KR |
| 10-2023-0138746 | Oct 2023 | KR |
| WO-2018222046 | Dec 2018 | WO |
