KR20230163215A - Smart Control System of Fire-fighting Pump using Battery - Google Patents

Abstract

The fire pump smart control system using a battery according to one aspect of the present invention is detachable from the motor pump 100 that supplies fire water and the frame 200 that secures the motor pump 100, and the motor. It communicates with the battery pack 300 and the motor pump 100 that supply power to the pump 100 and at least one battery pack 300, and selects the battery pack 300 to supply power to the motor pump 100. It is equipped with a control server 400 to control, and the frame 200 is formed on the battery box 230 and the battery box 230 to which at least one battery pack 300 is coupled, and is grounded with the battery pack 300. It is provided with a grounding member 233 that supplies current to the motor pump 100, and the battery pack 300 accommodates a battery 310 in which current is stored and a plurality of batteries 310, and is placed in a battery box 230. It is formed on the fastened case 320 and the case 320, and is connected to a detection sensor 330 that detects one or more selected from the charge amount, volume, temperature, and gas amount of the battery 310, and is connected to the control sensor 330. It may include a control device 340 that communicates with the server 400.

Description

Smart Control System of Fire-fighting Pump using Battery}

The present invention relates to a smart control system for a fire pump using a battery. More specifically, it is controlled by an external control server to use multiple batteries, and prevents the failure and explosion of the battery used as emergency power for the motor pump in the event of a fire. This is about a fire pump smart control system using a battery that can detect and prevent secondary damage.

In general, fire trucks used for fire suppression, lifesaving, and drainage work in flooded areas are equipped with a fire pump device to draw water from a water source and store the water in a water tank or directly discharge it.

This fire pump device includes a priming means to depressurize the internal air for initial pumping, a water tank to store the pumped water, a check valve to prevent backflow, and a fire pump to emit water. It is composed.

Usually, a fire pump consists of a motor pump (main pump) driven by electric current and an engine pump (auxiliary pump) driven by power generated by the engine when power is cut off during a fire.

At this time. Engine pumps are widely used for firefighting purposes to supply firefighting water necessary for fire extinguishing because they have a simpler device configuration than ordinary motor pumps and can achieve high lift and large capacity.

Since these firefighting engine pumps are usually installed in the basement of a multi-story building and have to pump firefighting water to each floor, it is essential to be equipped with a high-output engine pump.

And because it must operate accurately in the event of a fire to minimize damage, reliability of operation is very important.

However, in the conventional engine pump, the main pump and the engine that drives it are integrated so that the main pump operates at 100% in the event of a fire, so a pump with a large capacity and an engine with a corresponding capacity are required, and the main pump In case of failure, it will not function as a fire pump.

In addition, the conventional engine pump is a casting method, so the surface of the rotary car is rough, so the efficiency is low by 20 to 30%, so a high-output engine is required, and due to the characteristics of the engine, it can only be installed horizontally, which requires a large installation area in the underground machine room. There are restrictions on space utilization, such as taking up space.

Also, in the case of conventional engine pumps, they are made of gray cast iron or bronze and are operated only in case of fire, so there is a problem of rust occurring if not used for a long period of time. As a result, it is not practical to start due to sticking of the rotating car, etc., so it does not play a role in extinguishing fire. Failure to do so may result in significant property damage.

To overcome this, batteries, storage batteries, etc. can be used to utilize engine pumps or motor pumps. However, batteries or storage batteries have the problem that when a fire occurs, they explode due to high temperature, which can cause a secondary fire.

Republic of Korea registered patent 10-0955704 B1 (April 23, 2010)

The present invention was created to solve the above problems, and the purpose of the present invention is to detect the failure and explosion of the battery used as emergency power for the motor pump in the event of a fire and to prevent secondary damage by using a battery. This is about a fire pump smart control system.

Another object of the present invention relates to a fire pump smart control system using a battery that can sequentially control a plurality of battery packs and supply current to the motor pump until the fire is extinguished.

A fire pump smart control system using a battery according to one aspect of the present invention to achieve the above object includes a motor pump (100) for supplying fire water; A frame 200 for fixing the motor pump 100; A battery pack 300 that is detachable from the frame 200 and supplies power to the motor pump 100; A control server 400 that communicates with the motor pump 100 and at least one battery pack 300 and selects and controls the battery pack 300 to supply power to the motor pump 100; , the frame 200 includes a battery enclosure 230 to which at least one battery pack 300 is coupled; A grounding member 233 is formed in the battery housing 230 and is grounded with the battery pack 300 to supply current to the motor pump 100, wherein the battery pack 300 stores current. battery 310; A case 320 that accommodates a plurality of the batteries 310 and is fastened to the battery housing 230; A detection sensor 330 formed in the case 320 and detecting one or more of the charge amount, volume, and temperature of the battery 310; A control device 340 is connected to the detection sensor 330 and communicates with the control server 400.

The motor pump 100 includes a discharge pump 120 that introduces and discharges firefighting water; It may be provided with a discharge motor 110 that is formed to be spaced apart from the discharge pump 120 and rotates by power to discharge firefighting water.

The discharge motor 110 includes a cylindrical motor housing 111; A rotation shaft 112 formed through the inside of the motor housing 111 and rotated by power; An impeller 113 is coupled to one surface of the rotation shaft 112 and changes the position of the firefighter as it rotates.

The frame 200 is formed at the lower end of the motor pump 100 and includes a fixed frame 210 that fixes the discharge pump 120 and the discharge motor 110; It may be provided with a buffer frame 220, which is formed at the lower part of the fixed frame 210 and absorbs vibration occurring in the motor pump 100.

The battery housing 230 includes a combined housing 231 coupled to the frame 200; A cover 232 is formed on the upper part of the coupling housing 231 and protects the battery pack 300 when opened and closed.

A temperature sensor 331 formed on the detection sensor 330 and measuring the temperature inside the case 320; A pressure measurement sensor 332 that detects the volume of the battery 310 by measuring the pressure inside the case 320; A gas measurement sensor 333 that measures the flammable gas concentration inside the case 320 may be provided.

The case 320 includes a suction device 326 for sucking the air inside; The suction device 326 is coupled, and a vacuum valve 327 through which air inside the case 320 passes may be provided.

The control device 340 includes a communication unit 341 that communicates with the control server 400; It may be provided with a current control unit 342 that supplies and blocks current from the battery 310 to the motor pump 100 according to information received from the control server 400.

The control server 400 may be configured to supply current to at least one battery pack 300 when commercial power is cut off in the event of a fire.

The control server 400 includes a supply server 420 that controls each of the plurality of battery packs 300 to sequentially supply and block current from the plurality of batteries 310 to the motor pump 100; A warning server 430 that warns of danger depending on the state of the battery 310 may be provided.

According to the fire pump smart control system using a battery according to the present invention, it is possible to prevent power from being cut off to the motor pump before extinguishing a fire by controlling a plurality of battery packs.

In addition, by monitoring the status of the battery at all times and alerting the manager if something goes wrong with the battery, secondary damage due to battery explosion can be prevented.

1 is an exemplary diagram showing a battery alarm system for a fire pump according to an embodiment of the present invention.
Figure 2 is a cross-sectional view showing the fire pump shown in Figure 1.
Figure 3 is a cross-sectional view showing a battery enclosure according to an embodiment of the present invention.
Figure 4 is a perspective view showing a battery pack according to an embodiment of the present invention.
5 to 6 are cross-sectional views showing a battery pack according to an embodiment of the present invention.
Figure 7 is a cross-sectional view showing a detection sensor according to an embodiment of the present invention.
Figure 8 is an exemplary diagram showing a control server according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings. However, it goes without saying that the present invention is not limited to these embodiments and can be modified into various forms.

In the drawings, parts not related to the description are omitted in order to clearly and briefly explain the present invention, and identical or extremely similar parts are denoted by the same drawing reference numerals throughout the specification. In addition, in the drawings, the thickness, area, etc. are enlarged or reduced in order to make the explanation a little clearer, and the thickness, area, etc. of the present invention are not limited to what is shown in the drawings.

And when a part is said to “include” another part throughout the specification, it does not exclude other parts and may further include other parts, unless specifically stated to the contrary.

Figure 1 is an exemplary diagram showing a battery alarm system for a fire pump according to an embodiment of the present invention, and Figure 2 is a cross-sectional view showing the fire pump shown in Figure 1.

As shown in Figures 1 and 2, the fire pump smart control system using a battery according to an embodiment of the present invention is capable of supplying fire water in the event of a fire and is installed on a motor pump driven by current to block commercial power. By externally controlling the plurality of batteries 310 used as emergency power, it is possible to prevent power from being cut off before a fire is extinguished.

In general, fire pumps consist of a main pump that supplies firefighting water by a motor whose power source is formed by electric current, and an auxiliary pump that supplies firefighting water by an engine that uses the power source of an internal combustion engine when the motor does not run during a power outage, such as a power outage. is formed At this time, the auxiliary pump is formed as an engine pump and supplies fire water by an engine applied to an emergency generator, but since the main pump and the auxiliary pump are installed at the same time, there is a problem of restrictions on installation cost and installation space. To overcome this, a battery 310 is installed to supply firefighting water in the event of a power outage, such as a power outage, but when the fire is extinguished for a long time, there is a problem in which the operation of the motor pump 100 is stopped due to insufficient charge of the battery 310.

In the fire pump smart control system using the battery of the present invention, a plurality of battery packs 300 are installed in the fire pump, and when one battery pack 300 is discharged, current from the other battery pack 300 is supplied, thereby causing a fire. This prevents the motor pump 100 from stopping before extinguishing the fire. It is removable from the motor pump 100 that supplies firefighting water and the frame 200 that secures the motor pump 100, and the motor The battery pack 300 that supplies power to the pump 100 communicates with the motor pump 100 and at least one battery pack 300, and selects the battery pack 300 to supply power to the motor pump 100. A control server 400 that controls the system can be provided.

The fire pump smart control system using such batteries has at least one removable battery pack 300 to receive emergency power in the event of a power outage, such as a power outage. The battery 310 of the battery pack 300 is always fully charged. It can be maintained as is.

The motor pump 100 is driven using commercial power when commercial power is maintained due to a disaster such as a fire, and includes a discharge motor 110 and a discharge pump 120 that rotate by power to discharge firefighting water. It is formed to be spaced apart from and is equipped with a discharge pump 120 that introduces and discharges firefighting water.

At this time, the discharge motor 110 is formed by penetrating the cylindrical motor housing 111 and the inside of the motor housing 111, and is coupled to the rotating shaft 112 and one surface of the rotating shaft 112, which rotate by power. As a result, an impeller 113 that changes the position of the firefighter is formed.

The motor housing 111 can be formed in various shapes, and as a coil is formed inside, the rotation shaft 112 is rotated by current. And a cooling device is formed on the rear of the motor housing 111 to cool the internal coil when it generates heat by current.

And the rotation shaft 112 formed inside the motor housing 111 extends through one end of the motor housing 111 to the discharge pump 120, and the impeller 113 is coupled to the end of the rotation shaft 112. It is formed in various shapes, and after suctioning fire-fighting water from one end, it is discharged by pressure by changing the position of the fire-fighting water.

This impeller 113 is accommodated in the discharge pump 120, and the discharge pump 120 is formed to be perpendicular to the inlet 121 and the inlet 121 through which fire-fighting water flows, and the discharge portion 122 through which fire-fighting water is discharged. ) and between the inlet portion 121 and the discharge portion 122, and a variable portion 123 where the impeller 113 is located is formed.

In this way, the motor pump 100 supplies firefighting water by accurately controlling the flow rate and flow rate of the firefighting water as the rotation shaft 112 rotates due to current, and commercial power is not supplied when power is cut off such as a power outage due to a fire or various disasters. Otherwise, it is driven by receiving current from a power supply device.

And the frame 200 formed at the bottom of the motor pump 100 to separate the motor pump 100 from the ground includes a fixed frame 210 and a fixed frame 210 that fix the discharge pump 120 and the discharge motor 110. ), and a buffer frame 220 is formed at the lower part of the motor pump 100 to absorb vibration occurring in the motor pump 100.

The fixing frame 210 is formed at the lower part of the discharge pump 120 and the discharge motor 110, and fixes the discharge pump 120 and the discharge motor 110 with fixing hardware such as bolts. In addition, as a buffer frame 220 is formed at the bottom of the fixed frame 210, the motor pump 100 and the battery pack 300 can be protected from vibrations such as earthquakes and shocks. This buffer frame 220 is formed of an elastic spring.

And referring to FIG. 3, the frame 200 has a battery housing 230 formed at the top into which the battery pack 300 is inserted, and the battery housing 230 includes a coupling housing 231 coupled to the frame 200 and A cover 232 is formed on the upper part of the coupling housing 231 and protects the battery pack 300 as it is opened and closed, and a grounding member 233 is formed inside the coupling housing 231 and is grounded with the battery pack 300. ) is formed.

The coupling housing 231 has an insertion space inside which one or more battery packs 300 are inserted, and a plurality of grounding members 233 are formed inside the insertion space to store at least one battery pack 300. When inserted, it comes into contact with a grounding device formed in the battery pack 300 and receives current. In addition, the cover 232 on the upper part of the coupling housing 231 protects the inserted battery pack 300 as it rotates or slides, which blocks water or fire from entering the battery pack 300 in the event of a fire. . In addition, a fixing device is formed in the insertion space of the coupling housing 231 to prevent the battery pack 300 from moving or coming off after it is inserted, and the fixing device is formed of a clamp, a leaf spring, etc. to secure the battery pack 300. Fix it.

Figure 4 is a perspective view showing a battery pack according to an embodiment of the present invention, and Figures 5 and 6 are cross-sectional views showing a battery pack according to an embodiment of the present invention.

As shown in Figures 4 to 6, the battery pack 300 according to an embodiment of the present invention accommodates a battery 310 that stores current and a plurality of batteries 310, and is fastened to the battery housing 230. A case 320 is provided.

At this time, the battery 310 is formed as a rechargeable battery 310 that is charged by a charging device, and the type of battery 310 is not limited. In addition, the battery 310 is accommodated in the receiving space 321 so as not to move or be separated from the inside of the case 320, and multiple batteries 310 are connected in series or parallel to provide effective power to the motor pump 100. It is provided.

In addition, the case 320 is formed to be accommodated in the battery enclosure 230, and after being accommodated in the battery enclosure 230, a grounding device is formed to enable effective grounding with the battery enclosure 230. In the case 320, as the separation member 322 is formed in the receiving space 321 for accommodating the battery 310, the plurality of batteries 310 are separated without contacting each other, and one battery 310 expands. Even if the battery 310 is damaged, the other batteries 310 can be protected from damage.

Additionally, the case 320 may be made of synthetic resin such as reinforced plastic. This is to prevent a short circuit from occurring when it is grounded with the battery case 230 when it is made of metal. In addition, the case 320 is formed with a reinforcing plate that protrudes outward in a grid or pattern, and the reinforcing plate prevents damage to the case 320 due to impact and cools the battery housing 230 by circulating air within it. The effect can be increased.

In addition, the case 320 is formed in a vacuum state to improve the performance of the battery 310, and a suction device such as a compressor that sucks the internal air to form the inside of the case 320 in a vacuum state. 326 and the suction device 326 are combined to form a vacuum valve 327 that discharges the air inside the case 320. The vacuum valve 327 is formed in plural to effectively discharge the air inside the case 320, and the vacuum valve 327 is a check to prevent the inflow of air when the suction device 326 is separated after the air is discharged. It is preferably formed as a valve. In this way, as the inside of the case 320 is formed into a vacuum, even if the battery 310 is short-circuited or left for a long time and explodes, the fire is prevented from spreading due to lack of oxygen and the temperature and humidity of the battery 310 are effectively maintained at all times. It is possible.

In addition, a detection sensor 330 is formed inside the case 320 to measure the charge amount, volume, temperature, humidity, etc. of the battery 310. Referring to FIG. 7, the detection sensor 330 is a temperature sensor 331. ) and a humidity sensor to prevent the battery 310 from being damaged by external temperature. Specifically, the battery 310 has a risk of explosion or failure due to increased temperature or moisture, and the performance of the battery 310 may deteriorate depending on temperature and humidity, so the battery 310 may be damaged depending on the temperature and humidity inside the case 320. The state of (310) can be expressed externally. Also, if it is determined that there is a problem with the battery pack 300, it can be removed from the battery housing 230 and replaced with a new battery pack 300, and the defective battery pack 300 can be repaired or replaced externally.

In addition, a separate adapter is formed to measure the amount of charge of the battery 310, and a pressure measurement sensor 332 is used to measure the change in volume of the battery 310 when the battery 310 becomes old or expands when an abnormality occurs. is formed. The pressure measurement sensor 332 is preferably formed at a location in contact with the battery 310. In general, when a breakdown or rupture occurs, the battery 310 may expand and be damaged at the same time as the gas is discharged. Therefore, the pressure inside the case 320 generated as the battery 310 expands is measured to determine the size of the battery 310 in advance. It is possible to judge abnormalities.

And the detection sensor 330 is a gas measurement sensor 333 formed inside the case 320 to measure the flammable gas discharged from the battery 310 when the battery 310 ruptures to check whether the battery 310 is abnormal. It can prevent flammable gases from exploding due to electric current.

And when the case 320 is not formed in a vacuum, a control device 323 is formed inside or outside the case 320 to control the temperature and humidity inside the case 320, and the control device 323 is a fan. It can induce air to circulate inside the case 320. In addition, when the battery 310 is accommodated in the case 320, an insulating member 324 is formed to block heat from being conducted to the battery 310, and the outside of the insulating member 324 leaks into the case 320. A sealing member 325 is formed to prevent the occurrence of , and unlike the heat insulating member 324, the sealing member 325 is preferably formed of a silicon material.

And the case 320 is formed with a control device 340, and the control device 340 is formed with a communication unit 341 to communicate with the control server 400, so that the battery 310 inside each battery pack 300 The status can be determined by the control server 400. In addition, the control device 340 has a current control unit 342 that can supply and block the current from the battery 310 to the motor pump 100 according to information from the control server 400. Specifically, if the control server 400 determines that the charge level of the battery 310 or that an abnormality has occurred in the battery 310, information is transmitted to the control device 340 to block the current. And the control server 400 transmits information to the control device 340 formed inside another case 320 to supply current.

In addition, the case 320, which is formed by being inserted into the battery housing 230, can be charged from the outside when the battery 310 is discharged. The battery 310 is charged by a charging device, and the charging device is the case ( A wired charging device that supplies current as it passes through 320 and is connected to the battery 310 or a wireless charging device that is separately connected to the bottom of the case 320 and supplies current wirelessly is formed.

In this way, the battery pack 300 is formed to be removable from the motor pump 100, so that when the battery 310 is discharged in the event of a fire, a new battery pack 300 can be replaced, and the battery 310 can be replaced if left for a long time. Even when discharged, the battery 310 can be effectively replaced periodically, and in the event of a fire or power outage, such as a power outage, the power of the battery 310 can be used as an emergency power source to smoothly supply firefighting water.

Figure 8 is an exemplary diagram showing a control server according to an embodiment of the present invention.

As shown in FIG. 8, the control server 400 according to an embodiment of the present invention supplies current to at least one battery pack 300 according to the cutoff of commercial power when a fire occurs. If an abnormality occurs, it is possible to warn of danger and secondary damage caused by the explosion of the battery 310 to firefighters or managers extinguishing the fire.

This control server 400 controls the supply server 420 and the battery 310, respectively, to control the plurality of battery packs 300 to sequentially supply and block current from the plurality of batteries 310 to the motor pump 100. A warning server 430 is provided to warn of danger depending on the status.

And the control server 400 is formed as a communication server 410 that communicates with the communication unit 341 of the control device 340, and determines the status of the battery 310 received from the communication server 410 to determine the status of the battery 310. If the state is judged to be dangerous, a warning server 430 is formed to warn of the danger. At this time, the warning server 430 issues a warning to firefighters or managers around the motor pump 100 through sound, video, etc., and at the same time, sends a warning to the fire department, police station, etc. through the communication server 410 when an explosion of the battery 310 occurs. You can be warned that this may happen.

And when the battery 310 has a problem or is discharged, the supply server blocks the current of the battery pack 300 and controls the supply of current to the motor pump 100 from battery packs 300 that are adjacent to each other or have a large charge. (420) is formed.

In this way, the control server 400 determines the status of the battery 310 from the outside to reduce secondary damage and simultaneously controls a plurality of battery packs 300 sequentially to effectively supply current to the motor pump 100. has

In the above, a fire pump smart control system using a battery according to an embodiment of the present invention has been described, but the spirit of the present invention is not limited to the embodiments presented herein. Additionally, a person skilled in the art who understands the spirit of the present invention will be able to easily suggest other embodiments by adding, changing, deleting, or adding components within the scope of the same spirit, but this is also within the scope of the present invention. They will say it costs money.

100: motor pump 110: discharge motor
111: motor housing 112: rotation shaft
113: Impeller 120: Discharge pump
121: inlet 122: discharge part
123: variable part 200: frame
210: fixed frame 220: buffer frame
230: Battery enclosure 231: Combined housing
232: Cover 233: Ground member
300: battery pack 310: battery
320: Case 321: Accommodating space
322: Separating member 323: Control device
324: insulation member 325: sealing member
326: suction device 327: vacuum valve
330: detection sensor 331: temperature sensor
332: Pressure measurement sensor 333: Gas measurement sensor
340: Control device 341: Communication department
342: Current control unit 400: Control server
410: Communication server 420: Supply server
430: Warning server

Claims (10)

A motor pump (100) that supplies firefighting water;
A frame 200 for fixing the motor pump 100;
A battery pack 300 that is detachable from the frame 200 and supplies power to the motor pump 100;
A control server 400 that communicates with the motor pump 100 and at least one battery pack 300 and selects and controls the battery pack 300 to supply power to the motor pump 100; ,
The frame 200 includes a battery enclosure 230 to which at least one battery pack 300 is coupled;
A grounding member 233 is formed in the battery housing 230 and is grounded with the battery pack 300 to supply current to the motor pump 100,
The battery pack 300 includes a battery 310 that stores current;
A case 320 that accommodates a plurality of the batteries 310 and is fastened to the battery housing 230;
A detection sensor 330 formed in the case 320 and detecting one or more selected from the charge amount, volume, and temperature of the battery 310;
A fire pump smart control system using a battery including a control device 340 that is connected to the detection sensor 330 and communicates with the control server 400.
According to clause 1,
The motor pump 100 includes a discharge pump 120 that introduces and discharges firefighting water;
A fire pump smart control system using a battery including a discharge motor 110 that is formed to be spaced apart from the discharge pump 120 and rotates by power to discharge fire water.
According to clause 2,
The discharge motor 110 includes a cylindrical motor housing 111;
A rotation shaft 112 formed through the inside of the motor housing 111 and rotated by power;
A fire pump smart control system using a battery including an impeller 113 that is coupled to one surface of the rotation shaft 112 and changes the position of the firefighter as it rotates.
According to clause 1,
The frame 200 is formed at the lower end of the motor pump 100 and includes a fixed frame 210 that fixes the discharge pump 120 and the discharge motor 110;
A fire pump smart control system using a battery including a buffer frame 220 formed at the lower part of the fixed frame 210 and absorbing vibration occurring in the motor pump 100.
According to clause 1,
The battery housing 230 includes a combined housing 231 coupled to the frame 200;
A fire pump smart control system using a battery including a cover 232 that is formed on the upper part of the coupling housing 231 and protects the battery pack 300 as it is opened and closed.
According to clause 1,
A temperature sensor 331 formed on the detection sensor 330 and measuring the temperature inside the case 320;
A pressure measurement sensor 332 that detects the volume of the battery 310 by measuring the pressure inside the case 320;
A fire pump smart control system using a battery including a gas measurement sensor 333 that measures the flammable gas concentration inside the case 320.
According to clause 1,
The case 320 includes a suction device 326 for sucking the air inside;
A fire pump smart control system using a battery including a vacuum valve 327 through which the suction device 326 is coupled and the air inside the case 320 penetrates.
According to clause 5,
The control device 340 includes a communication unit 341 that communicates with the control server 400;
A fire pump smart control system using a battery, including a current control unit 342 that supplies and blocks current from the battery 310 to the motor pump 100 according to information received from the control server 400.
According to clause 1,
The control server 400 supplies current to at least one battery pack 300 in response to the cutoff of commercial power when a fire occurs. A fire pump smart control system using a battery including a.
According to clause 1,
The control server 400 includes a supply server 420 that controls each of the plurality of battery packs 300 to sequentially supply and block current from the plurality of batteries 310 to the motor pump 100;
A fire pump smart control system using a battery, including a warning server 430 that warns of danger depending on the state of the battery 310.