KR20200051128A - Air bag with an air pump to prevent sinking - Google Patents

Abstract

In the present invention, an air suction part of an air pump floats on water by a buoyant means, or the air pump is positioned on the water by the buoyant means. Air sprayed by the air pump is formed into an air bag part in which an air bag attached to an air pump discharge pipe to be connected is attached or fixed to one side of a floor surface of a cabin and which fills the air bag so that buoyancy is provided to the sinking cabin. Therefore, the air bag can prevent sinking.

Description

Air bag with an air pump to prevent sinking

The technical field of the present invention is a water sensor using compressed air and an air compressor and a float switch, or a water sensor without a float switch, an air bag, a carbon nanotube, and a servo motor.

Air compressor

[air compressor, 空氣 壓縮機]

A machine that compresses air in a closed container with power to increase its pressure. Electric power, steam engines, and internal combustion engines are used as power. The mechanism includes a reciprocating type by a reciprocating motion of a piston, a rotating type by a rotation of a rotor, a centrifugal type using a centrifugal force of a high-speed rotary vane, a rotary type, and the like.

Compressed air

[compressed air, 壓縮空氣]

summary

Point the air under high pressure by reducing the volume by applying pressure. The high pressure air is used to perform various tasks using the power when it becomes low pressure, and it is often used in everyday life. For example, compressed air with a pressure of 0.1 kg / cm 2 is used for ventilation of subways, mines, and buildings.

The high pressure air is used to perform various tasks using the power when it becomes low pressure, and it is often used in everyday life. 0.1kg / cm2 pressure for ventilation of subways, mine tunnels, buildings, 0.5 ~ 1kg / cm2 for combustion of coke in steel mills and foundry factories, powders such as cement or pulverized coal, and 0.5 to 1 kg / cm2 for transportation of grain in sealed pipes, about 7 kg / cm2 for air hammers or air drills, rivet hammers, etc., 7 kg for brakes of railroad cars or operation of door engines. / Cm2, compressed air of about 50kg / cm2 is used for fuel injection of diesel engines.

As a special one, compressed air of 100 to 150 kg / cm 2 is used for submarine submersion. The prime mover using compressed air does not ignite and is used in coal mines or chemical plants where there is a risk of explosion. Types include steam engine type, star type crank rotation type, mold cylinder rotation type, gear type, and rotating movable wing type.

A sensor that detects water is called a leak sensor.

It is a sensor that detects the presence or absence of leaks.

Leak Sensor is the frequency that is normally sent to the floor

It detects that the frequency changes when there is water

This is the principle of generating a signal.

Servo motor

[servomotor]

summary

A device for driving a load by a control signal as a control unit of a servo mechanism.

Depending on the power source of the servo motor, there are electric (servo motor), pneumatic (air servo motor), hydraulic (hydraulic motor), etc. In general, the servo motor often refers to the servo motor.

The servo motor is a control motor with a fast response and a wide range of speed control, and is classified into a DC servo motor and an AC servo motor according to its power source. Most of AC servomotors are three-phase servomotors.

Since these repeat operations such as stop, start, and reverse, the design is considered to improve the heat dissipation effect or to speed up the change of operation. The servo motor is operated according to the control signal, and in order to do this, a device that receives the control signal and amplifies it to drive the servo motor is required, which is called a servo amplifier.

pressure gauge

[manometer, 壓力計]

summary

Instrument for measuring the pressure of a gas or liquid.

Manometer

There are several types of applications, including barometers, pressure differentials, high pressure gauges and vacuum gauges, and the structure is diverse.

According to the principle of measurement, ① measure the pressure by equilibrating with the weight of an object (for example, 液柱), ② measure the size of the elastic body under pressure, ③ measure the pressure It is divided into using some kind of physical property that changes by.

Liquid main pressure gauge

A typical U-shaped pressure gauge with water, mercury and alcohol in a glass tube is typical. When one end of the pipe is connected to the pressure part to be measured, the liquid level rises and falls to the point where it is balanced with the pressure difference applied at both ends of the pipe. It is possible to measure the difference in pressure across the tube. There are open-ended and closed-open types, and the range of pressures that can be measured is wide.

The mercury barometer is not a U-shaped tube, but in principle it is a closed-pipe liquid pressure gauge like this. In the industrial aspect, a floating buoy is placed on the liquid level, and it is also used to enlarge the movement of the machine with a machine, or to convert it to an electric quantity to indicate it.

Elastic pressure gauge

It is relatively widely used for industrial purposes, and measures pressure by mechanically expanding the deformation occurring in a hydraulic body made of metal or the like. There are Bourdon tube type pressure gauges, diaphragm type pressure gauges, valo type pressure gauges, and air pressure type pressure gauges (an anoid barometer). In general, it is easy to handle and has a wide measuring range, but the elasticity of the hydraulic material is somewhat hysteresis, and the deformation is not constant with respect to pressure. Etc. There are common drawbacks.

vacuum gauge

It is a pressure gauge for measuring a pressure lower than atmospheric pressure. In addition to a liquid main pressure gauge or an elastic pressure gauge, gas for a change in pressure, such as a cloud gauge, a pyrani gauge, an ionization vacuum gauge, etc. A special pressure gauge is used to measure the change in the thermal conductivity and the conductivity of the gas.

Weight type pressure gauge

It is a kind of high pressure meter that measures pressure by weight. Other high pressure gauges that measure large pressures in fluids include compression pressure gauges, resistance pressure gauges, and Bourdon tubes.

Measure by balancing the weight of the piston and the weight placed on it by drawing oil from kerosene into a cylinder equipped with a piston and pushing the bottom surface of the piston. It is used not only to measure high pressures that cannot be measured with a liquid main pressure gauge, but also to calibrate other pressure gauges.

The problem to be solved by the present invention is to provide one of the fundamental alternatives to this cause, there may be a number of causes in the case of sinking passenger ships.

In the case of the Sewol sinking on April 16, 2014, the interviews with experts

According to the story of the accident ship, it started to tilt from the left, and then it was completely upside down. When I say this, what kind of accident should this big ship be upside down in this way?

I can check it for three reasons. Once I got the drawing and looked at it, there are several watertight bulkheads in the space across the ship. So, in fact, even if only one space is flooded, it does not lose stability. However, in order to cause an accident, it is possible that several spaces were torn at the same time and many spaces were flooded .

1) To provide a fundamental solution to the case where a lot of space is flooded because the space is torn at once

Another condition is that some spaces may have such a space that there is a passage through which water can move. Current figures in a few places now gotta space is connected to the stairs. Such a space can cause water to rise upwards if that space is damaged.

2) To present a fundamental alternative when there is a passage through which water can move to the upper floor

Third, there is a space where the reef hits the side and is loaded with a vehicle on the side with some upper deck. Such a space is a very large space, and it is not divided into partitions. In such a case, even a small damage can significantly reduce the recovery rate.

3) To present a fundamental alternative when not divided into bulkheads

Of course, it hasn't been deep enough yet, so even if it is turned over, if the air is pushed upwards, there will be space for people to survive. However, in fact, the biggest human injury here seems to be caused by the sudden inclination of some people and the lack of time to evacuate .

4) To provide a fundamental alternative to give time to evacuate

As a cause of this, most of these passenger ships and passenger ships are not divided by price, and the space is wide. In addition, the space for loading or loading cargo is also wide open in one , so if the water is flooded there , it can tilt faster and lose balance and overturn than other commercial ships.

3) To present a fundamental alternative when not divided into bulkheads

These 1), 2), 3), 4) are problems to be solved by the present invention.

Water sensor by compressed air and air compressor and float switch, or water sensor without float switch, air bag, carbon nanotube, servo motor, etc. The compressed air in the compressed air tank is injected, and the compressed air that has been injected fills the air bag, so that the vessel is not sinking and buoyed by buoyancy formed by air in the air bag.

The effects of the present invention are 1) when the space is torn at a time and many spaces are flooded, 2) when the space has a passage through which water can move, and 3) when it is not divided into partitions 4) when there is no time to evacuate Can be a fundamental alternative.

1 is a perspective view of the present invention.
2 is a cross-sectional view of an embodiment applied to the submarine of the present invention.
3 is a cross-sectional view of an embodiment applied to the ship of the present invention.

1 is a perspective view of the present invention when the pressure is below a certain pressure by a pressure gauge in the compressed air tank, the switch is operated, and the compressed air tank and air are operated by the air compressor. It is compressed and stored at a constant pressure, and when the ship starts to fill up due to a collision with the reef, a water sensor by a float switch or a water sensor without a float switch detects that the water is full. When the switch is turned on, the servomotor, etc. of the valve that is opened by the servomotor of the compressed air tank is rotated to open the valve of the compressed tank, the air inside the compressed tank is injected, and the injected air fills the air bag. It provides buoyancy to the cabin that is immersed in water to prevent sinking. The outside of the air bag has an outer shell formed of carbon nanotubes, and is configured to prevent the air bag from being damaged by internal items or objects. On the other hand, when the water sensor detects that the water is full, the switch of the air compressor is turned off, preventing the air compressor from operating against the pressure change of the compressed air tank, and a net is formed on the outside of the air bag or outside the carbon nanotube in an emergency. You can move by grabbing the net.

Figure 2 is a cross-sectional view of an embodiment applied to a submarine of the present invention to form a float switch or the like to drain the seawater between the interior and exterior of the hull inside the cabin formed by the partition wall or water is not normally drained to a normal level Inside the cabin formed with a partition wall

When the sensor is turned on by the float switch, which detects that water is filled, and when the electricity is turned on by the float switch, when the door to the bulkhead lamp is closed automatically, or after closing the door to the bulkhead lamp, turn on the switch or switch to the switch formed in the navigation instrument room. Elastic air connected to the ballast tank and the air injector that causes the compressed air to be injected by opening the valve of the ballast tank by operating the servomotor or the like by a ballast tank that can compress and inject air by an air compressor and a servomotor. The bag is expanded and formed as a discharge part of water that discharges the water flowing inside the partition wall.

Figure 3 is a cross-sectional view of an embodiment applied to the ship of the present invention to form a float switch, etc. in the ship, the air except the bilge wells, such as fuel tanks or fresh water tanks, and sewage tanks that are divided into the interior of the bulkhead or the ship. Where

When the sensor is turned on by the float switch, which detects that water is filled, and when the electricity is turned on by the float switch, when the door to the bulkhead lamp is closed automatically, or after closing the door to the bulkhead lamp, turn on the switch or switch to the switch formed in the navigation instrument room. Elastic air connected to the ballast tank and the air injector that causes the compressed air to be injected by opening the valve of the ballast tank by operating the servomotor or the like by a ballast tank that can compress and inject air by an air compressor and a servomotor. The pocket is expanded to be formed as a discharge portion of water that discharges water introduced into the partition wall.

1: Compressed air tank 2: Air compressor
3: Servo motor operated valve 5: Air bag
10: water sensor 11: net
15: fixing frame 20: carbon nanotube
21: bulkhead 22: ship
25: air flow 30: Cabinet
31: submarine 32: horizontal rudder
35: outer shell 50: water flow
51: water pump 52: buoyancy means

Claims (15)

In the air bag using the air pump for preventing sinking, the air intake of the air pump is floated on the water by the buoyancy means or the air pump is placed on the water by the buoyancy means, and the air injected by the air pump is connected to the air pump discharge pipe. the bladder is attached is formed in connection is formed of a bladder portion is filled the bladder attached to one side or may be fixed, such as the cabin floor, characterized in that is provides buoyancy to the flooded cabin is prevented sink sinking prevention Air bag using air pump. According to claim 1, The air injected by the air pump is attached to the air pump discharge piping, and the air pocket formed by the connection is formed in the interior of the car, for example, in the trunk or in the rear part of the upper part of the rear seat of the car interior or bonnet. Using an air pump for preventing sinking, characterized in that the inside of the car is provided to provide buoyancy to a car that is flooded by filling an air bag attached or fixed to one side of the inside or between the front part of the driver's seat and the car window. A car with air pockets. According to claim 1, The air injected by the air pump is attached to the air pump discharge piping to form a connection air bag
When a ship or a car starts to fill up because the ship is sinking due to a collision with a reef or falls into the water, the sensor and water sensor that the water sensor detects when the water is filled are filled with water. When it detects that, the switch is turned on and the air pump part driven by the switch is turned on, the air of the air pump is injected, and the injected air is formed into an air bag part that fills the air bag or
When the water starts to fill the ship electric to the water sensor (water sensor) The electrical signal is the control that is to be input to the control unit for sensing that the water sensor and the sensor member which detects that the water difference between the car and the control unit is an air pump driven The signal is output, and the air pump part and the injected air, through which an operating mechanism for air injection by the air pump is formed, are formed into an air bag part that fills the air bag , thereby providing buoyancy to the flooded cabin and sinking. Vehicle equipped with an air bag using an air pump for preventing sinking, characterized in that to be prevented. The method according to claim 1 or 3,
In the ship, the water sensor is formed inside the bulkhead , or in the part where there is air except for the fuel tank, fresh water tank, and bilge well that stores sewage.
A water detection sensor unit for detecting that water is filled, a switch unit for operating the air pump when energized by the water sensor, or a switch unit formed on the outside of the bulkhead after closing the door to the bulkhead lamp or closing the door to the bulkhead lamp. by a switch unit formed turn on the switch and on the navigation instrument chamber or the like connected to the discharge pipe of the air pump switch unit is driven to the air pump flexible air air to the bag is expands discharging the flowing water inside the partition wall Vessel equipped with an air bag using an air pump for preventing sinking, characterized in that the discharge portion of the water by the bag portion is included. According to any one of claims 1 to 4, the outer side of the air bag includes an outer shell formed of carbon nanotubes, and the outer bag includes an outer bag configured to prevent the air bag from being damaged by internal items or objects. Air bag using the air pump for preventing sinking, characterized in that. The air pump for sinking prevention according to any one of claims 1 to 4, wherein a net is formed on the outside of the air bag or the outside of the carbon nanotube to allow the net to be caught and moved in an emergency. Air bag using. According to any one of claims 1 to 6 characterized in that it includes an emergency power supply unit with a built-in charger so that power is supplied so that the water sensor, etc. can be operated and the air pump is automatically operated even when the power is cut off in an emergency . Air bag using air pump to prevent sinking. According to claim 1, In the air bag using the air pump for preventing sinking, the air suction portion of the air pump is floated on the water by means that prevents water from being sucked by buoyancy means or air is provided with means for preventing water from being sucked An air bag using an air pump for preventing sinking, characterized in that the pump is positioned on the water by a buoyancy means. An airbag using an air pump for preventing sinking, characterized in that a pipe of an air pump leading to each cabin is formed for each cabin in which an air bag is formed, and an intake port of an air pump or a suction pipe of an air pump is formed on a deck. The air pump using the air pump for sinking prevention according to any one of claims 1 to 5 or 9, wherein at least one fixing frame on one side of the inside of the ship is formed and fixed to the fixing frame. It is formed integrally with the additional buoyancy means and is formed on one side of the hull or vehicle by a rotating hole that can be wound around the air pump suction pipe or air pump discharge pipe, so that the buoyancy means does not interfere with floating on the water surface during sinking. Air bag using the air pump for preventing sinking, characterized in that. When a submarine sinks due to a collision with a reef, etc.
In the rear main buoyancy tank or all main buoyancy tanks
Such as hitting the reef two euros water sensor (water sensor) the sensor unit that detects that the water difference and the water sensor is on the manual switch by the switching unit is formed such as navigation instruments room When detected that the water car or If this happened, the difference by the fault, the motor is such as compressed air tank portion and the servo motor switch is in the open to make the servo motor of the switch unit and a compressed air tank which can set, such as oN valve is formed by the water sensor is rotated By operating the valve opening and closing operation to open the valve of the compression tank and the air inside the compression tank is injected and the injected air is formed into an air bag portion that fills the air bag to provide buoyancy to the flooded cabin Dive equipped with a compressed air tank for preventing sinking, characterized in that to prevent sinking . The method of claim 11
A compressed air tank for preventing sinking is provided on the outside of the air bag, which includes an outer shell formed of carbon nanotubes and the like, and includes an outer bag of an air bag configured to prevent the air bag from being damaged by external and internal impacts. Equipped submarine. The method according to any one of claims 11 to 12, wherein the water sensor detects that the water is full, that is, a water sensor; The air compressor switch or water sensor prevents the air compressor from operating due to the pressure change in the compressed air tank by receiving a signal detected by the water sensor and operating a relay or motor to turn off the air compressor. When it detects that the water is full, that is, a water sensor; The signal detected by the water sensor is input to the control unit as an electric signal, and the control unit includes a switch unit of the air compressor that prevents the air compressor from operating in response to a pressure change in the compressed air tank by turning off the switch of the air compressor. Submarine equipped with compressed air tank for preventing sinking. According to any one of claims 11 to 13, Compressed air tank for preventing sinking is characterized in that it includes at least one fixed frame, etc. on one side of the interior of the ship, and includes an air compressor fixing portion to be fixed to the fixed frame. Submarine equipped with compressed air tank for preventing sinking. 15. The charger according to any one of claims 11 to 14, so that a power supply capable of operating a servo motor or the like is supplied so that the water sensor light is operated and the valve of the compressed air tank is opened even when the power is cut off in an emergency. Submarine equipped with a compressed air tank for preventing sinking, characterized in that includes an emergency power supply .

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