KR102403758B1 - Energy storage system - Google Patents

Abstract

The present invention relates to an energy storage system including first and second fire extinguishing devices that detect a fire occurring inside an enclosure containing plurality of battery packs and firstly and secondly extinguish the fire and a plurality of anti-seismic devices capable of absorb vibration transmitted in various directions. According to an embodiment of the present invention, the energy storage system comprises: an enclosure of an energy storage system; a first fire extinguishing device disposed on an inner ceiling of the enclosure to extinguish the fire occurring inside the enclosure by spraying first fire fighting water; a second fire extinguishing device disposed on a side surface of the enclosure to introduce or discharge second fire fighting water into or out of the enclosure to further extinguish the fire; a fire alarm buzzer disposed outside the enclosure a fire detection sensor disposed inside the enclosure to detect the fire; and a processor receiving a fire detection signal detected by the fire detection sensor and controlling the operation of the first fire extinguishing device based on the fire detection signal and the operation of the fire alarm buzzer.

Description

energy storage system

Various embodiments of the present invention relate to an energy storage system (ESS) comprising first and second fire extinguishing devices for extinguishing a fire and a plurality of seismic devices for absorbing vibrations.

In general, an energy storage system (ESS) refers to a device that receives and stores external power from an external power source, for example, a power plant, and transmits it to a place when power is needed. That is, the energy storage system is a large-capacity power storage device including a battery for power storage, and is a storage device that stores power and supports it to be used at a necessary place and time. Accordingly, it is currently in the spotlight as a renewable energy storage device.

For example, the energy storage system is not only used as a storage device that stores excess power and transmits power when insufficient power occurs, but also is used to stabilize the output when generating new and renewable energy such as solar and wind power, but in case of an emergency such as a power outage In addition, it can be used for the core infrastructure for the dissemination of electric vehicles.

In contrast, although the energy storage system is in the spotlight as a new and renewable energy storage device, in the energy storage system, since a plurality of battery packs are connected to each other and intensively disposed, deterioration or heat may occur in the plurality of battery packs, This caused a fire problem.

In addition, the plurality of battery packs of the energy storage system has a disadvantage in that a fire occurs secondary due to residual fire remaining after the fire is extinguished.

In addition, such a conventional energy storage system is very vulnerable to earthquakes or vibrations, and although seismic application standards are provided, reinforcement work for facilities is not performed. Therefore, when an earthquake or vibration occurs, a power outage may occur. In this case, the energy storage system may be used as a spare battery in preparation for such a blackout state.

However, the conventional energy storage system has a problem in that it is vulnerable to earthquakes or vibrations and cannot respond to vibrations transmitted to the inside. In addition, the conventional energy storage system is weak in corrosion and durability, which can cause deformation and damage, which has a disadvantage in that a malfunction of the product occurs.

As a prior document related to the present invention, there is Republic of Korea Patent Publication No. 10-2016-0094216 (published on Aug. 8, 2016), and in the prior document, a technology for “ESS battery PACK” has been disclosed.

In various embodiments of the present invention, it is possible to first suppress the fire by detecting the occurrence of a fire occurring inside the enclosure in which a plurality of battery packs are embedded, and to transmit the fire in the enclosure to the outside through a warning light and an alarm sound generating unit. The purpose is to provide an energy storage system (ESS) including a fire extinguishing device that allows the user to secondarily suppress a fire by introducing waterproof water into the interior of the enclosure.

In addition, energy including a plurality of seismic devices capable of absorbing external vibrations (eg, earthquakes) transmitted to the housing to prevent deformation and damage of the housing due to the vibrations and at the same time protect the housing from the vibrations It is to provide a storage system (ESS).

However, the technical problems to be achieved by the various embodiments of the present invention are not limited to the above technical problems, and other technical problems may exist.

According to various embodiments of the present disclosure, an energy storage system (ESS) includes: an enclosure of the energy storage system; a first fire extinguishing device disposed on the inner ceiling of the housing and suppressing the fire by spraying a first fire fighting water to the fire generated inside the housing; a second fire extinguishing device disposed on the side of the housing and for introducing or discharging a second fire water into the interior of the housing to further extinguish the fire; a fire alarm buzzer disposed outside the enclosure; a fire detection sensor disposed inside the housing and detecting the fire; and a processor that receives the fire detection signal detected by the fire detection sensor, and controls the operation of the first fire extinguishing device based on the fire detection signal and controls the operation of the fire alarm buzzer. When the fire alarm buzzer operates under the control of the processor, the second fire fighting device may be connected to an external fire hose by a user to introduce the second fire water into the interior of the housing.

According to various embodiments of the present invention, the enclosure may include a container-type enclosure.

According to various embodiments of the present invention, the housing may include an open opening formed in front of the housing; an enclosure door rotatably coupled to the opening and rotating by a hinge to open and close the opening; a battery accommodating member disposed inside the housing and accommodating a plurality of battery packs; first and second exhaust fans disposed on the side and rear surfaces of the housing; and a plurality of ring members disposed on the upper surface of the housing and caught on or released from an external hook member in order to move the housing.

According to various embodiments of the present invention, the first fire extinguishing device may include a sprinkler or a fire extinguisher.

According to various embodiments of the present disclosure, the fire detection sensor may include a smoke detection sensor or a temperature detection sensor.

According to various embodiments of the present disclosure, the second fire extinguishing device may include: a water supply member disposed on a side surface of the housing and connected to the external fire hose to introduce the second fire water into the interior of the housing; a drainage member disposed at a position adjacent to the water supply member and discharging the second fire water introduced into the housing to the outside; and a connection member disposed at one end of the water supply member to connect or separate the water supply member and the external fire hose.

According to various embodiments of the present invention, a level switch for detecting the water level of the first and second fire fighting water is disposed on the inner upper side of the housing to discharge the first and second fire extinguishing water filled in the housing to the outside of the housing, The processor may receive the water level detection signals of the first and second firefighters, and control to display the water levels of the first and second firefighters on a monitor based on the water level detection signals of the first and second firefighters.

According to various embodiments of the present disclosure, the fire alarm buzzer may include a warning light and an alarm sound generator.

According to various embodiments of the present invention, the outer side of the housing further includes a level water level structure that displays to the outside to notify the water level of the first and second firefighters filled in the interior of the housing, and the level water level structure is, a first level water pipe that penetrates and is coupled to the interior of the housing on the upper portion of the housing; a second level water pipe connected to the lower portion of the housing through penetrating the interior of the housing; a level side tube connected to one end of the first and second level tubes, at least a portion of which forms a level water level opening opened along the longitudinal direction; a transparent level hose disposed on the level side tube and exposed to the outside through the level water level opening, one end connected to the first level water level tube, and a tile end connected to the second level water level tube; and a level water level buoy disposed inside the transparent level hose and ascending or descending in the longitudinal direction according to the water level of the first and second firefighters to indicate the water level of the first and second firefighters. have.

According to various embodiments of the present disclosure, a discharge valve for discharging the first and second fire-fighting water filled in the interior of the housing to the outside of the housing by being opened and closed according to rotation may be disposed at the lower portion of the housing.

According to various embodiments of the present disclosure, a plurality of earthquake-resistant devices disposed under the housing and absorbing the vibration to prevent external vibration from being transmitted to the housing may be further included.

According to various embodiments of the present invention, the plurality of seismic devices may include: a first support portion disposed under the housing; a second support part disposed below the first support part and disposed on the upper surface of the vibrating part in which vibration is generated; an elastic member disposed between the first support part and the second support part and preventing external vibration from being transmitted to the housing; a fixing part protruding from the center of the second support part and penetratingly coupling the elastic member and the first support part; and a plurality of gap maintaining structures arranged to maintain a set distance between the first support part and the second support part; The first and second support parts, the elastic member, and the fixing part are prevented from being continuously exposed from the load of the housing by maintaining a set distance between the second support parts, and the plurality of spacing maintaining structures are more than the set range. When vibration occurs, the set interval may be changed so that the housing is supported by the first and second support parts, the elastic member, and the fixing part.

According to various embodiments of the present invention, a fire generated inside the enclosure is detected by a fire detection sensor, and the processor operates the first fire extinguishing device according to the fire monitoring signal to spray the first fire water to the fire at the same time as suppressing the fire, the processor operates the fire alarm buzzer so that the user recognizes the warning light generated from the warning light of the fire alarm buzzer and the alarm sound generated from the alarm sound generating device, and the recognized user uses the external fire hose By connecting to the second fire extinguishing device and secondarily suppressing the fire by introducing a second fire water into the interior of the enclosure, the first and second fire extinguishing devices primarily suppress the fire generated in the box at the beginning, and the fire After the initial suppression, the remaining residual fire can be suppressed secondarily. Accordingly, the first and second fire extinguishing devices can facilitate the initial suppression of the fire and suppression of the remaining residual fire, thereby preventing the enclosure from re-igniting and spreading by the residual fire.

In addition, a plurality of seismic devices disposed under the housing are configured to absorb external vibrations (eg, earthquakes, etc.) transmitted to the housing, thereby preventing and protecting the housing from deformation and damage.

In addition, by arranging a plurality of spacing structures to maintain a set distance between the first support and the second support included in the seismic device, the plurality of spacing structures are transmitted to the enclosure by external (eg earthquake) vibrations. When this does not occur, it is possible to prevent continuous exposure of the first and second support parts, the elastic member, and the fixing part to the load of the housing by maintaining a set distance between the first and second support parts, thereby It is possible to prevent damage to the first and second support parts, the elastic member, and the fixing part.

In addition, the plurality of spacing maintaining structures deform the set interval so that when external (eg, earthquake) vibration transmitted to the housing occurs, the housing is supported by the first and second support parts, the elastic member and the fixing part. can do it Therefore, by absorbing the vibration transmitted to the housing in multiple directions, the first and second support parts, the elastic member and the fixing part can prevent and protect the product from being deformed and damaged by the vibration, as well as protect it, Due to this, the function of the product can be further improved.

1 is a front view showing an energy storage system (ESS) including a fire extinguishing device and an earthquake resistant device according to various embodiments of the present invention.
2 is a side view illustrating an energy storage system (ESS) including a fire extinguishing device and an earthquake resistant device according to various embodiments of the present disclosure.
3 is a cut-away front view showing the configuration of an energy storage system (ESS) including a fire extinguishing device and an earthquake resistant device according to various embodiments of the present invention.
4 is an enlarged and cut front view of part A of FIG. 3 , and is a view showing the configuration of a second fire fighting device among the configurations of an energy storage system (ESS) including a fire extinguishing device and an earthquake resistant device.
FIG. 5 is an enlarged and cut front view of part B of FIG. 3 , and is a view showing the configuration of a plurality of earthquake-resistant devices among the configurations of an energy storage system (ESS) including a fire extinguishing device and an earthquake-resistant device.
6 is a cut-away side view showing the configuration of an energy storage system (ESS) including a fire extinguishing device and an earthquake resistant device according to various embodiments of the present disclosure.
FIG. 7 is an enlarged cutaway side view of part C of FIG. 6 , and is a view showing the configuration of a plurality of earthquake-resistant devices among the configurations of an energy storage system (ESS) including a fire extinguishing device and an earthquake-resistant device.

Since the present invention can have various changes and can have various embodiments, some embodiments will be described in detail with reference to the drawings. However, this is not intended to limit the present invention to specific embodiments, and it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention.

Terms including ordinal numbers such as 'first' and 'second' may be used to describe various elements, but the elements are not limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component. The term 'and/or' includes a combination of a plurality of related listed items or any of a plurality of related listed items.

In addition, relative terms described based on what is shown in the drawings, such as 'front', 'rear', 'top', 'bottom', etc., may be replaced with ordinal numbers such as 'first' and 'second'. In ordinal numbers such as 'first' and 'second', the order is the mentioned order or arbitrarily determined, and may be arbitrarily changed as necessary.

Terms used in the present invention are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present invention, terms such as "comprises" or "have" are intended to designate that the features, numbers, steps, operations, components, parts, or combinations thereof described in the specification exist, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in the present invention, should not be interpreted in an ideal or excessively formal meaning. does not

The energy storage system 10 (ESS) including a fire extinguishing device and an earthquake-resistant device according to various embodiments of the present invention detects the occurrence of a fire occurring inside the enclosure 20 in which a plurality of battery packs C1 are embedded. It may be a combination of one or more of various fire extinguishing devices capable of first suppressing the fire and secondarily suppressing the fire after suppressing the fire, and also absorbs the vibration transmitted to the housing 20 It may be a combination of one or more of the various seismic devices available.

1 is a front view showing an energy storage system 10 according to various embodiments of the present invention, FIG. 2 is a side view showing an energy storage system 10 according to various embodiments of the present invention, and FIG. 3 is the present invention is a cut-away front view showing the configuration of the energy storage system 10 according to various embodiments of the FIG. 5 is an enlarged and cut front view of part B of FIG. 3 , and is a view showing the configuration of a plurality of seismic devices among the configurations of the energy storage system 10 , and FIG. 6 is various embodiments of the present invention A cutaway side view showing the configuration of the energy storage system 10 according to an example, and FIG. 7 is an enlarged cutaway side view of part C of FIG. 6 , showing the configuration of a plurality of seismic devices among the configurations of the energy storage system 10 . to be.

1 to 7 , the energy storage system 10 (ESS) includes an energy storage system enclosure 20 , first and second fire extinguishing devices 30 and 40 , a fire alarm buzzer 50 , and a fire detection sensor. 60 , a processor 70 and a plurality of seismic devices 90 may be included. For example, the housing 20 may include a box-shaped container-type housing 20 .

The housing 20 may include an opening 21a, an enclosure door 21, a battery accommodating member 22, an intake fan 23, an exhaust fan 24, and a plurality of ring members 25. For example, the open opening 21a may be formed in the front of the housing 20, and the housing door 21 rotates about the hinge axis of the hinge part 21b to open and close the opening 21a. to be rotatably coupled to the opening 21a. In addition, a second locking hole 21c facing the first locking hole 20a disposed in the housing 20 may be disposed in the housing door 21 . For example, when the housing door 20 closes the opening 21a of the housing 20 , the second locking hole 21c of the housing door 21 and the first locking hole 20a of the housing 20 are ) face each other, and by fastening the locking member E1 to the first and second locking holes 20a and 21c facing each other, it is possible to maintain the closed state of the housing door 21 to the housing 20 . For example, the first and second locking holes 20a and 21c may be fastened to the locking member E1 , and at the same time, the door 21 may maintain a locked state in the housing 20 . Accordingly, the enclosure 20 can be prevented from being opened by anyone other than the person concerned.

The battery accommodating member 22 may be disposed inside the housing 20 to accommodate the plurality of battery packs C1 . For example, the plurality of battery packs C1 may store supplied power, and the plurality of battery packs C1 may supply the stored power to the outside as needed. For example, the plurality of battery packs C1 may store excess power and transmit power when insufficient power occurs. In addition, the plurality of battery packs (C1) are used to stabilize the output when generating new and renewable energy such as solar power and wind power, but can also be used in an emergency such as a power outage.

The intake fan 23 may be disposed on a side surface of the housing 20 , and the exhaust fan 24 may be disposed on the side surface of the housing 20 and adjacent to the intake fan at the same time. For example, the intake fan 23 may keep the internal temperature of the housing 20 constant by introducing the external air of the housing 20 into the inside of the force body. In addition, the exhaust fan 24 may ventilate the interior of the housing 20 by discharging the internal air of the housing 20 to the outside.

The plurality of ring members 25 may be disposed on the upper surface of the housing 20 . The plurality of ring members 25 may be caught on an external hook member (not shown) to easily move the housing 20 . The plurality of ring members 25 may release the jamming from the hook member of the concave portion after the movement of the housing.

Accordingly, the plurality of ring members 25 may not only facilitate movement of the housing 20 , but also freely install the housing 20 .

In addition, the housing 20 may include a battery management system (BMS) (not shown), a power conversion system (PCS) (not shown), and a universal power supply (UPS) (not shown). For example, the BMS is a device that monitors a plurality of batteries and controls charging and discharging of power, and the PCS is a device that receives power from a power source and changes characteristics of electricity to store it in a plurality of batteries or discharge it to the system. And, the UPS is an uninterruptible power supply device that regulates power supply, and is a device that controls when the voltage of an electric circuit is cut off or suddenly rises or falls.

In addition, an air conditioner frame 26 for arranging an air conditioner may be disposed outside the housing 20 , and a pipe hole 26a through which an air conditioner pipe connected to the air conditioner passes may be formed in the housing. A fire-fighting construction frame 26-1 for fire-fighting construction may be disposed in an adjacent position of the air conditioner frame 26, and an electrical construction frame 26-2 for electrical construction is adjacent to the fire-fighting construction frame. This can be arranged. A cable hole (not shown) through which an electrical construction cable passes may be formed in the housing 20 .

The first fire extinguishing device 30 may be disposed on the inner ceiling of the housing 20 . For example, the first fire extinguishing device 30 may extinguish the fire generated inside the housing 20 by spraying the first fire fighting water A1. The first fire extinguishing device 30 may be connected to an external water tank (not shown) to supply the first fire water A1. The first fire extinguishing device 30 may be operated by a fire detection sensor 60 and a processor 70 to be described later.

According to various embodiments, the first fire extinguishing device 30 may include a sprinkler capable of spraying the first fire water A1 and a fire extinguisher.

The second fire extinguishing device 40 may be disposed on a side surface of the housing 20 . For example, the second fire extinguishing device 40 may introduce or discharge the second fire water A2 into or out of the housing 20 in order to further suppress the fire generated inside the housing 20 . . When the fire alarm buzzer 50 to be described later operates under the control of the processor 70 , the second fire extinguishing device 40 is configured to introduce the second fire water A2 into the housing 20 . It is possible to connect the external fire hose 1 by the user. For example, the second fire fighting device may include a water supply member 41 , a drain member 42 , and a connection member 43 . For example, the water supply member 41 may be disposed on a side surface of the housing 20 . The water supply member 41 may be connected to the external fire hose 1 to introduce the second fire water A2 into the housing 20 . The drain member 42 may be disposed adjacent to the water supply member 41 , and may discharge the second fire water A2 introduced into the housing 20 to the outside.

For example, the water supply member 41 and the drain member 42 may be disposed on the upper side of the housing 20 . Accordingly, the drain member 42 may automatically discharge the second fire-fighting water A2 to the outside when the second fire-fighting water A2 flows into the upper portion of the housing 20 .

The connection member 43 may be disposed at one end of the water supply member 41 . For example, the connecting member 43 may be connected to or separated from the external fire hose 1 . The connecting member 43 may connect the water supply member and the external fire hose 1 to introduce a second fire fighting water into the housing. When the inflow of the second fire water into the housing 20 is completed, the connection member 43 may separate the water supply member 41 from the external fire hose 2 .

The connecting member 43 may include a comlock coupling (not shown). For example, the connection member 43 is described as an example of a comlock coupling (Comlock coupling), but is not limited thereto. For example, the connection member 43 may be variously applied as long as it connects or separates the water supply member 41 and the external fire hose 1 .

The fire alarm buzzer 50 may be disposed outside the housing 20 . For example, the fire alarm buzzer 50 may generate a warning light and an alarm sound to inform an external user (not shown) of a fire occurring inside the enclosure 20 .

According to various embodiments, the fire alarm buzzer 50 may include a warning light 51 emitting a warning light and an alarm sound generating device (not shown) generating an alarm sound.

The fire detection sensor 60 may be disposed inside the housing 20 to detect a fire generated inside the housing 20 . For example, the fire detection sensor 60 may include a smoke detection sensor 60 and/or a temperature detection sensor 60 .

The processor 70 receives the fire detection signal detected by the fire detection sensor 60, controls the operation of the first fire extinguishing device 30 based on the fire detection signal, and simultaneously controls the operation of the fire alarm buzzer ( 50) can be controlled.

In this state, when a fire occurs in the plurality of battery packs C1 disposed inside the enclosure 20, the fire detection sensor 60 disposed inside the enclosure 20 detects the fire and , can be signaled. In this case, the fire detection sensor 60 may transmit the fire detection signal to the processor 70 .

The processor 70 may receive the fire detection signal, and may primarily operate the first fire extinguishing device 30 based on the fire detection signal. The first fire extinguishing device 30 may primarily suppress the fire by spraying the first fire water A1 to the fire under the control of the processor 70 .

At the same time, the processor 70 may operate the fire alarm buzzer 50 . For example, the processor 70 may operate a warning light 51 and an alarm sound generating device (not shown) of the fire alarm buzzer 50 . The warning light 51 and the alarm sound generating device may generate a warning light and an alarm sound for the occurrence of a fire by the processor 70 .

At this time, the user may recognize that a fire will occur inside the housing 20 after confirming the generated warning light and alarm sound. The user who recognizes the fire may connect the external fire hose 1 to the water supply member 41 of the second fire extinguishing device 40 disposed on the side surface of the housing 20 .

In this state, the water supply member 41 may introduce the second fire water A2 into the interior of the housing 20 by the connected external fire hose 1 .

A check valve 44 for preventing a reverse flow of the second fire water A2 may be disposed on the water supply member 41 . For example, the check valve 44 may prevent the second fire-fighting water A2 flowing into the water supply member 41 from flowing in the reverse direction and being discharged to the outside of the housing 20 .

The water supply member 41 introduces the second fire water A2 supplied from the external fire hose 1 into the interior of the housing 20 and at the same time suppresses the residual fire remaining in the housing 20 secondarily. can

When the second fire-fighting water (A2) is introduced by the water supply member (41) and reaches the upper side of the inside of the housing (20), the second fire-fighting water (A2) is disposed on the side of the housing (20) It may be discharged to the drain member 42 .

At this time, when the first and second firefighters A1 and A2 introduced into the housing 20 are filled to form the water level of the first and second firefighters A1 and A2 to a predetermined height, the housing 20 ), a level switch 80 for detecting the water level of the first and second firefighters A1 and A2 may be disposed on the upper side of the inside.

The processor 70 receives the water level detection signals of the first and second firefighters A1 and A2, and based on the water level detection signals of the first and second firefighters A1 and A2, to a monitor (not shown). The water level of the first and second firefighters A1 and A2 may be controlled to be displayed. For example, the monitor may display the water level of the first and second firefighters A1 and A2 by the processor.

At this time, after the user checks the water level of the first and second firefighters A1 and A2 through the monitor, the first and second firefighters A1 and A2 are filled to a predetermined height in the interior of the housing 20 . can recognize that

According to various embodiments, on the outer side of the housing 20, a level water level structure ( 100) can be arranged. For example, the level water level structure 100 may include first and second level water level tubes 101 , 102 , a level side tube 103 , a transparent level hose 104 , and a level water level buoy 105 . The first level water pipe 101 may be disposed on the upper portion of the housing 20 to protrude at a predetermined height toward the outer direction of the housing 20 , and at the same time be penetrated and coupled with the interior of the housing 20 . .

The second level water pipe 102 may be disposed protruding from the lower portion of the housing 20 to a predetermined height toward the outside of the housing 20 and at the same time be coupled through the interior of the housing 20 .

The level side tube 103 may be connected to one end of the first and second level water pipes 101 and 102 . For example, the level side tube 103 may form a level water level opening 103a so as to arrange a transparent level hose 104 to be described later. The level water level opening 103a may be formed in at least a portion of the level side tube 103 , and may be opened along the longitudinal direction of the level side tube 103 . The level water level opening 103a may expose the transparent level hose 104 disposed in the level side tube 103 to the outside.

The transparent level hose 104 may be exposed to the outside through the level water level opening 103a while being disposed on the level side tube 103 . For example, one end of the transparent level hose 104 may be connected to the first level water level pipe 101 , and the tile end of the transparent level hose 104 may be connected to the second level water level pipe 102 . . The transparent level hose 104 is filled with the first and second firefighters A1, A2) can be introduced.

The level water level buoy 105 may be disposed inside the transparent level hose 104 . For example, the level water level buoy 105 rises or falls in the longitudinal direction according to the water level of the first and second firefighters A1 and A2 to indicate the water level of the first and second firefighters A1 and A2. can do.

For example, when the first and second firefighters A1 and A2 are filled in the interior of the housing 20 to a predetermined height, the first and second firefighters A1 and A2 are the second level water pipe 102 . It can be introduced into the transparent level hose 104 through. At this time, the first and second firefighters A1 and A2 flow into the transparent level hose 104 and at the same time the water level position of the first and second firefighters A1 and A2 filled in the housing 20 is the same. will rise sharply. At this time, the level water level buoy 105 disposed in the transparent level hose 104 may also rise according to the water level of the first and second firefighters A1 and A2.

Accordingly, the user can check the water level of the first and second firefighters A1 and A2 filled in the housing 20 by watching the rise of the level buoy 105 of the transparent level hose 104 . For example, the user can confirm that the first and second firefighters A1 and A2 are filled in the housing 20 by the raised level water level buoy 105 .

According to various embodiments, the lower portion of the housing 20 is opened and closed according to the rotation to discharge the first and second firefighters A1 and A2 filled in the housing 20 to the outside of the housing 20 . A discharge valve D1 may be arranged.

For example, a discharge pipe D2 may be disposed under the housing 20 , and a discharge valve D1 (eg, a rail valve) may be disposed in the discharge pipe D2 . In this state, the user opens the discharge pipe D2 by rotating the discharge valve D1 (eg, a rail valve) disposed on the discharge pipe D2 in the forward direction to open the first first filled in the housing 20 . , 2 fire water (A1, A2) can be discharged to the outside. At this time, when the first and second fire-fighting water (A1, A2) filled in the housing is discharged to the outside through the discharge pipe (D2), the user opens the discharge valve (D1) (eg, a rail valve). The discharge pipe D2 may be closed by rotating in a reverse direction opposite to the forward direction.

In this way, the fire detection sensor 60 detects a fire generated inside the enclosure 20, and the processor 70 operates the first fire extinguishing device 30 according to the fire monitoring signal to operate the first firefighter A1. ) to the fire to primarily suppress the fire, and at the same time, the processor 70 operates the fire alarm buzzer 50 so that the user is primarily a warning generated from the warning light 51 of the fire alarm buzzer 50 . Recognizing the light and the alarm sound generated by the alarm sound generating device, the recognized user (not shown) connects the external fire hose 1 to the second fire extinguishing device 40 to enter the interior of the enclosure 20 . The second fire water A2 may be introduced to secondarily suppress the fire. When the inside of the housing is filled with the second firefighter A2 over a predetermined level, the monitor may display the water level of the second firefighting water by the processor 70 . In this case, the user may check the water level of the second firefighting water through the monitor.

In addition, the level water level buoy 105 of the level water level structure 100 disposed outside the housing 20 may be raised by the first and second firefighters A1 and A2. At this time, the user can see the rise of the level water level buoy 105 from the outside and confirm that the water level of the first and second firefighters A1 and A2 inside the housing 20 rises.

At this time, the user rotates the discharge valve D1 (eg, a rail valve) disposed on the discharge pipe D2 of the lower portion of the housing 20 in the forward direction to open the discharge pipe D2 and The first and second fire fighting water A1 and A2 filled therein may be discharged to the outside of the housing 20 through the discharge pipe D2. At this time, when the first and second firefighters A1 and A2 filled in the housing 20 are discharged to the outside of the housing 20 through the discharge pipe D2, the user can use the discharge valve (D1) (eg, a rail valve) may be rotated in a reverse direction opposite to the forward direction to close the discharge pipe D2.

Therefore, the first and second fire extinguishing devices 30 and 40 can initially suppress the fire generated in the ship, and completely suppress the remaining fire after the initial fire suppression. The first and second fire extinguishing devices 30 and 40 can not only facilitate the initial suppression of a fire, but can also prevent a fire from being rekindled and spreading due to residual fire after the fire is extinguished.

According to various embodiments, as previously shown in FIGS. 5 and 7 , the plurality of seismic devices 90 may be disposed under the housing 20 . For example, the plurality of seismic devices 90 may absorb the vibration to prevent external vibration from being transmitted to the housing 20 .

The plurality of seismic devices 90 may include first and second support parts 91 and 92 , an elastic member 93 , a fixing part 94 , and a plurality of spacing maintaining structures 95 . For example, the height adjustment part 98-1 is screwed onto the upper surface of the fixing part 94 protruding from the center of the second support part 92, and the height is adjusted while being coupled to the fixing part 94. The separation preventing member 99 may be disposed to face the upper surface of the portion 98-1. In this state, the fixing part 94 may be coupled to the fixing part 94 through a first through hole (not shown) formed in the center of the elastic member 93 . The elastic member 93 may be inserted into the housing 91-1 of the first support 91 to be coupled thereto. In this case, the coupling hole 91 - 2 formed in the center of the first support part 91 may penetrate through the fixing part 94 to be coupled.

For example, the elastic member 93 may be coupled to the opening 91a formed on one surface of the housing 91-1 included in the first support part 91 . In this case, the elastic member 93 may be accommodated by being inserted into the receiving space 91b formed in the opening 91a.

In this state, the anti-vibration pad 96 may be disposed on the upper surface of the first support plate 91 . For example, the fixing part 94 may be coupled through a pad hole (not shown) formed in the center of the anti-vibration pad 96 . A first support member 97 supporting the anti-vibration pad 96 may be disposed on an upper surface of the anti-vibration pad 96 . For example, the first support member 97 may be coupled to a member hole formed in the first support member 97 through the fixing part 94 .

In this state, a pair of first nuts 98 may be disposed on the upper surface of the first support member 97 . For example, the pair of first nuts 98 may be screwed onto the fixing part 94 and simultaneously fix the vibration-proof pad 96 and the first support member 97 .

In this state, a plurality of spacing structures 95 may be disposed between the first support part 91 and the second support part 92 . For example, as shown in FIG. 7 above, the plurality of spacing maintaining structures 95 may be disposed to maintain a set interval K1 between the first and second support parts 91 and 92 . The plurality of spacing maintaining structures 95 may include first and second support frames 95a and 95b and an elastic part 95c disposed between the first and second support frames 95a and 95b. .

The seismic device 90 assembled in this way may be arranged in plurality at the bottom edge portion of the housing 10 . For example, as previously shown in FIGS. 1 to 3 and 6 , the first support 91 of the earthquake-resistant device 90 may be disposed below the housing 10 . The second support part 92 may be disposed on the upper surface of the vibrating part 2 where the vibration is generated.

In this state, when the vibration does not occur, as shown in FIG. 7 above, the plurality of space maintaining structures 95 have a set interval K1 between the first support part 91 and the second support part 92 . to prevent the first and second support parts 91 and 92, the elastic member 93, and the fixing part 94 from being continuously exposed under the load of the housing 20. For example, the plurality of spacing maintaining structures 95 may be supported on the bottom surface of the housing 20 .

In this state, when the vibration occurs due to an earthquake, as shown in FIG. 7 above, the elastic part 95c included in the plurality of spacing maintaining structures 95 may be bent, and the elastic part 95c ) may be deformed by the bending of the set interval K1. For example, when the vibration occurs, the second support frame 95b included in the plurality of spacing structures 95 may be bent by the vibration in the first support frame 95a.

Accordingly, the set interval K1 may be changed while the second support frame 95b is bent.

In this case, the housing 20 may absorb vibrations by the first and second supporting parts 91 and 92 , the elastic member 93 and the fixing part 94 . At this time, since the first and second support parts 91 and 92 , the elastic member 93 , and the fixing part 94 absorb vibrations, it is possible to prevent the housing from being damaged by the vibrations.

According to various embodiments, when the earthquake is finished and the vibration does not occur, the plurality of spacing maintaining structures 95 may maintain the set interval K1 again. For example, the elastic part 95c disposed between the first and second support frames 95a and 95b may restore the bent second support frame 95b by an elastic force to restore the second support frame 95b to its original position.

In this way, by arranging a plurality of spacing structures 95 to maintain a set interval K1 between the first support part 91 and the second support part 92, the plurality of spacing maintaining structures 95 When the vibration does not occur, the first and second support parts 91 and 92, the elastic member 93 and the It is possible to prevent the fixing portion 94 from being continuously exposed under the load of the housing, thereby causing damage to the first and second support portions 91 and 92 , the elastic member 93 and the fixing portion 94 . can prevent In addition, when the vibration occurs, the plurality of space maintaining structures 95 are configured so that the housing is supported by the first and second support parts 91 and 92 , the elastic member 93 and the fixing part 94 . The set interval K1 may be modified. Accordingly, the first and second support parts 91 and 92, the elastic member 93, and the fixing part 94 absorb the vibration, thereby preventing the housing from being damaged by the vibration. , it is possible to protect the enclosure from the vibration.

The energy storage system including the fire fighting device and the earthquake resistant device of various embodiments of the present invention described above is not limited by the above-described embodiments and drawings, and various substitutions, modifications and changes are possible within the technical scope of the present invention. will be apparent to those of ordinary skill in the art to which the present invention pertains.

10: energy storage system
20: enclosure 30, 40: first and second fire extinguishing devices
50: fire alarm buzzer 60: fire detection sensor
70: processor 80: level switch
90: seismic device
A1, A2: 1st and 2nd firefighters

Claims (12)

the enclosure of the energy storage system;
a first fire extinguishing device disposed on the inner ceiling of the housing and suppressing the fire by spraying a first fire fighting water to the fire generated inside the housing;
a second fire extinguishing device disposed on the side of the housing and configured to introduce or discharge a second fire water into or out of the housing to further extinguish the fire;
a fire alarm buzzer disposed outside the enclosure;
a fire detection sensor disposed inside the housing and detecting the fire; and
A processor for receiving the fire detection signal detected by the fire detection sensor, and controlling the operation of the first fire extinguishing device based on the fire detection signal and controlling the operation of the fire alarm buzzer;
When the fire alarm buzzer operates under the control of the processor, the second fire fighting device is connected to an external fire hose by a user to introduce the second fire water into the interior of the housing,
A level switch for detecting the water level of the first and second fire extinguishers is disposed on the upper inner side of the housing to discharge the first and second fire extinguishers filled in the housing to the outside of the housing, and the processor is configured to operate the first and second fire extinguishers The energy storage system, characterized in that receiving a water level detection signal of the first and second firefighters and controlling to display the water level of the first and second firefighters on a monitor based on the water level detection signals of the first and second firefighters.
The energy storage system of claim 1 , wherein the enclosure comprises a container-type enclosure.
According to claim 1, wherein the housing,
an open opening formed in the front of the housing;
an enclosure door rotatably coupled to the opening and rotating by a hinge unit to open and close the opening;
a battery accommodating member disposed inside the housing and accommodating a plurality of battery packs;
first and second exhaust fans disposed on the side and rear surfaces of the housing; and
The energy storage system comprising a; a plurality of ring members disposed on the upper surface of the housing, caught on or released from the hook member on the outside in order to move the housing.
The energy storage system of claim 1, wherein the first fire extinguishing device comprises a sprinkler or a fire extinguisher.
The energy storage system of claim 1, wherein the fire detection sensor comprises a smoke detection sensor or a temperature detection sensor.
According to claim 1, wherein the second fire extinguishing device,
a water supply member disposed on a side surface of the housing and connected to the external fire hose to introduce the second fire water into the housing;
a drainage member disposed at a position adjacent to the water supply member and discharging the second fire water introduced into the housing to the outside; and
and a connection member disposed at one end of the water supply member to connect or separate the water supply member and the external fire hose.
delete The energy storage system of claim 1, wherein the fire alarm buzzer includes a warning light and an alarm sound generator.
According to claim 1, wherein the outer side of the housing further comprises a level water level structure to indicate to the outside the water level of the first and second firefighters filled in the interior of the housing,
The level water level structure is,
a first level water pipe connected to the upper portion of the housing through penetration with the interior of the housing;
a second level water pipe connected to the lower portion of the housing through penetrating the interior of the housing;
a level side tube connected to one end of the first and second level tubes, at least a portion of which forms a level water level opening opened along the longitudinal direction;
a transparent level hose disposed on the level side tube and exposed to the outside through the level water level opening, one end connected to the first level water level tube, and a tile end connected to the second level water level tube; and
and a level water level buoy disposed inside the transparent level hose and ascending or descending in the longitudinal direction according to the water level of the first and second firefighters to display the water level of the first and second firefighters. energy storage system.
The energy storage system according to claim 1, wherein a discharge valve for discharging the first and second fire-fighting water filled in the interior of the housing to the outside of the housing by being opened and closed according to rotation is disposed at a lower portion of the housing.
The energy storage system of claim 1, further comprising: a plurality of earthquake-resistant devices disposed under the housing and absorbing the vibrations to prevent external vibrations from being transmitted to the housing.
The method of claim 11, wherein the plurality of seismic devices,
a first support portion disposed under the housing;
a second support part disposed below the first support part and disposed on the upper surface of the vibrating part in which vibration is generated;
an elastic member disposed between the first support part and the second support part and preventing external vibration from being transmitted to the housing;
a fixing part protruding from the center of the second support part and penetratingly coupling the elastic member and the first support part; and
Includes;
When the vibration does not occur, the plurality of gap maintaining structures maintain a set distance between the first support part and the second support part to maintain the first and second support parts, the elastic member, and the fixing part under the load of the housing. to prevent continuous exposure,
The plurality of spacing maintaining structures are energy storage systems, characterized in that when vibrations exceeding a set range occur, the set spacing is deformed so that the housing is supported by the first and second support parts, the elastic member, and the fixing part.

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