KR101531990B1 - Inflatable rescue system for saving life on the water - Google Patents

Abstract

The present invention relates to an inflatable rescue system to save human lives in water. The inflatable rescue system is airdropped to easily be spread out on a surface of the water. In case of a big accident, a large number of people may hang on from the inflatable rescue system to wait for being rescued until a rescue ship arrives. Therefore, a large number of people may be rescued once, and it may be possible to effectively cope with a big accident. The inflatable rescue system comprises: a bag which has a through-hole formed on an upper part thereof, and has an open lower part thereof; a fixing rope which has an upper end connected to a helicopter, and a lower end included inside the bag through the through hole; a supporting plate which is the lower part of the fixing rope included inside the bag and has a coupling ring attached to a top surface thereof, and the connecting ring being connected with the lower end of the fixing rope; a gas tank which is mounted on the top surface of the supporting plate, allowing gas to be stored therein, and has an upper end connected with a gas injecting pipe; a floating body which is attached to a periphery of the top surface of the supporting plate, and is made of a floatable material; a plurality of air tubes which are mounted on the lower end of the floating body, connected with the gas injecting pipe having inserting rings formed on the upper ends thereof respectively, and are included in the periphery of the floating body while making a radial shape; and a supporting rod which is mounted on the interior upper part of the bag in such a manner that the supporting rod can vertically be extended, wherein the supporting rod is inserted into the inserting rings in such a manner that the inserting rings can be separated from the supporting rod.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to an inflatable rescue system,

More particularly, the present invention relates to a structural system for life rescue structure. More particularly, the present invention relates to a rescue system for rescue water rescue, and more particularly, And more particularly, to an air-infiltrating structural system for rescue water rescue which enables a person to be rescued simultaneously and effectively cope with a large-scale accident.

The number of people using airplanes and ships to transport through the sky and water is increasing, and it is necessary to rescue as many people as possible when a disaster occurs at sea during the transportation of such persons.

In addition, environmental disasters can cause many people to suffer distress and disaster at sea, and urgent structures are required in case of such disasters. Conventional helicopter-based rescue systems, which can use helicopters, are usually concentrated on the rescue of a small number of people, and lifeboats or rubber boats An example is a boat.

Conventional rubber boats and lifeboats are known from International Patent PCT / JP2012 / 08055. The above-mentioned international patent relates to a new type of helicopter-based air-inflating structural system for rescue personnel. In this case, the inflatable spiral shape is dropped. It spreads widely over the surface of the water, It is constructed so as not to drown.

Spiral air hoses made of plastic having a length of several hundred meters are filled with air or gas, but the spiral shape of the air hose can not be stably maintained in water. Rather, each component is twisted to form a knot so that this type of air-filled hose is not considered for large scale water structures.

Japanese Laid-Open Patent Application No. 2004-122967 discloses a rope having a floating body that can be dropped from a helicopter into water and caught by an accident victim. The rope has a loop device that allows people floating in the water to enter the arm in the loop to protect them from slipping off. At this time, the rope also lifts people directly to the helicopter. The rescue equipment is provided only when the number of people is small and is not suitable for rescue from drowning when a large number of people are floating in the water.

International Patent PCT / JP2012 / 08055 Japanese Patent Application Laid-Open No. 2004-122967 A

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art,

It is an object of the present invention to provide a method and apparatus for disassembling a large number of people at the same time while waiting for a rescue ship to arrive, Which is capable of effectively coping with the above-mentioned problems.

It is another object of the present invention to provide a bag for a life history structure in which the lower part of the bag can be kept closed and can be opened when necessary so that the storage, An inflatable structural system.

Another object of the present invention is to provide an air-inflated structural system for a water-life structure in which operation of separating or discharging parts through wireless operation is performed to improve operational convenience.

It is another object of the present invention to provide an air-inflated structural system for a water-life structure in which parts are separated or discharged by manual operation by an operating rope, thereby simplifying manufacture and improving operational stability.

In order to achieve the above-mentioned object, the "air intake structure system for water life structure" according to the present invention comprises: a bag having a through hole formed therein and having an open bottom; A stationary rope having an upper end connected to the helicopter and a lower end disposed inside the bag through the opening; A support plate provided on an inner side of the bag at a lower portion of the fixed rope and having a connection ring to be detachably connected to a lower end of the fixed rope; A gas pipe mounted on the upper surface of the support plate, the gas pipe having a high pressure gas stored therein and a gas injection pipe connected to the upper end thereof; A float attached to an upper surface of the support plate and made of a floating material; A plurality of air tubes radially disposed around the float, a bottom end connected to the float, a gas inlet tube connected to the float, A support rod mounted on an inner upper portion of the bag so as to be vertically extended, the support ring being detachably fitted to the fitting ring; .

In addition, the bag of the " air intake structure system for water life saving structure "according to the present invention includes a plurality of fitting holes formed around an opened lower portion, And a closure rope that closes the closure rope.

Further, the bag of the " inflatable life structure type inflatable structural system "according to the present invention is mounted on the lower end outer surface thereof and is capable of releasably fixing the other end of the closed rope, And a rope releasing mechanism for releasing the rope releasing mechanism.

Further, the fixed rope of the " air intake structure system for life saving structure "according to the present invention further includes a hook mounted on the lower end of the fixed rope and hooked to the connection ring.

Further, the support plate of the " air intake structure system for water life structure "according to the present invention further includes a fixed rope separator mounted on the connection ring and separating the lower end of the fixed rope from the connection ring by a user's operation And the gas cylinder further comprises an injection irrigation bug mounted on the gas injection tube and opening the gas injection tube by a user's operation.

The fixed rope separator and the irrigation irrigation device of the " air injection structure system for water life structure "according to the present invention are wireless automatic actuators that are automatically operated upon receiving a radio signal transmitted by a user's remote operation do.

The fixed rope separator and the irrigation irrigation device in the " air intake structure system for water life saving structure "according to the present invention are manual actuators operated by manual operation, And is connected to the rope separator and connected to the injection irrigation bumper at an upper portion thereof and connected to the upper portion of the bag while being fixed to the bag inside the through hole and is connected to the injection irrigation bumper and the fixed rope separator An operating rope to be operated sequentially; And further comprising:

Further, the support rod of the " air injection structure system for water life saving structure "according to the present invention includes a support rod separator mounted on one end of the support rod for separating one end of the support rod by user's operation so that the fitting ring is disengaged from the support rod , Further comprising:

Further, the support rod separator of the " air injection structure system for water life saving structure "according to the present invention is characterized in that it is a wireless automatic actuator which is automatically operated upon receiving a wireless signal transmitted by a user's remote operation.

Further, the support rod separator of the " pneumatic inflatable structure system for water life saving structure "according to the present invention is a manual actuator operated by manual operation, and the structure for pneumatic inflatable structure for aquatic life structure has an upper end connected to the support rod separator, A lower end connected to the float, a working rope for pulling the support rod separator together with the fall of the float to operate it; And further comprising:

Further, according to the present invention, a " air intake structure system for water life structure "includes a time anchor provided inside the lower surface of the support plate and connected to a lower portion of the support plate by a connection, and fixing the support plate to the water surface. The supporting plate further includes a time anchor outlet provided at one side thereof for discharging the time anchor, which is accommodated in a lower portion of the support plate, by a user's operation.

Further, in the "air intake structure system for water life saving structure" according to the present invention, the time anchor outlet is a wireless automatic actuator that is automatically operated upon receiving a radio signal transmitted by a remote operation of a user.

Further, in the "air intake structure system for water life saving structure" according to the present invention, the time anchor outlet is a manual actuator operated by manual operation, the upper end of which is connected to the operating rope, And an auxiliary rope connected to the discharge port and operating the hour anchor discharge port by pulling the operating rope.

Further, in the "air intake structure system for water life structure" according to the present invention, the air tube further comprises a connection tube for connecting the central portion of the air tube radially provided to communicate with each other.

In addition, the air tube of the air intake structure system for water life structure according to the present invention further comprises a central mesh installed between the inside of the connection tube and the center of the air tube.

Further, in the "air intake structure system for water life structure" according to the present invention, the air tube further includes a plurality of life ropes provided on an outer surface of the air tube outside the connection tube.

The air tube of the air intake structure system for water life structure according to the present invention comprises a pair of air pipes adjoining each other and attached to the ends of the air tubes so that the ends of two adjacent air tubes are connected to each other , Further comprising:

The air tube of the air intake structure system for water life structure according to the present invention comprises an inner mesh network provided inside the pair of adjacent air tubes and provided in the form of a mesh between the connection tube and the connection hole, .

The air tube of the air intake structure system for water life structure according to the present invention is disposed between the outer side of the connection tube and the inner side of the air tube and is disposed in the form of a net, And an outer circular network.

In addition, the "air injection structure system for aquatic life structure" according to the present invention is installed on the outside of the float, and is turned on according to a water sensing signal inputted through a water sensor installed on a lower surface of the float A lighting device for irradiating light toward the air tube; And further comprising:

Further, the "air intake structure system for water life structure" according to the present invention comprises: a position transmitter installed on the upper surface of the support plate, for deriving a current position of the support plate via GPS and transmitting the derived position to outside; And further comprising:

As described above, according to the present invention, a large number of people are hanged at the same time in a large accident while being easily spread on the water surface through air dropping, so that they can wait until a rescue ship arrives so that dozens to hundreds of people can be simultaneously rescued, It is possible to effectively cope with a large-scale accident, and accordingly, the life span can be structured smoothly at the time of a large-scale water accident, thereby minimizing loss of life.

Further, the present invention has an effect that the lower part of the bag can be kept closed and opened when necessary, so that the storage, handling, and maintenance of all parts accommodated in the bag can be easily performed.

Further, the present invention has an effect that the operation of separating or discharging the parts through wireless operation is performed, thereby improving the operational convenience.

Further, the present invention has the effect that the parts are separated or discharged by manual operation by the operating rope, so that the manufacturing is simple and the operational stability is improved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic vertical cross-sectional view of a pneumatic inflatable structural system for life saving structure according to the present invention;
FIG. 2 is a schematic vertical sectional view showing the lower part of the pneumatic inflatable structural system for life saving structure according to the present invention in an opened state;
FIG. 3 is a schematic front view showing a state in which a pneumatic inflatable structural system for life safety structure according to the present invention is dropped from a helicopter,
FIG. 4 to FIG. 8 are schematic diagrams showing an operating state of a pneumatic inflatable structural system for life safety structure according to the present invention,
FIG. 9 is a schematic plan view showing another embodiment of an air tube of a pneumatic inflatable structural system according to the present invention,
10 is a schematic plan view showing yet another embodiment of an air tube of a pneumatic inflatable structural system according to the present invention,
11 is a schematic vertical cross-sectional view of a pneumatic inflatable structural system for aquatic life structure according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be understood, however, that the invention can be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

FIG. 1 is a schematic longitudinal sectional view showing a structure for pneumatic inflatable structural system according to the present invention, and FIG. 2 is a schematic vertical sectional view showing a lower structure of an inflatable structural system for aquatic life structure according to the present invention, FIG. 3 is a schematic front view showing a state in which a pneumatic inflatable structure system for aqueduct life structure according to the present invention is dropped on a helicopter, and FIGS. 4 to 8 are views schematically showing operation states of an air inflatable structural system for aquatic life structure according to the present invention Fig.

As shown in the drawings, the structure for pneumatic inflatable structure for life saving structure according to the present invention comprises a bag 10, a fixed rope 20 provided inside the bag 10 from the outside, A gasket 40 provided on the upper surface of the support plate 30 and a float 50 mounted around the support plate 30 and connected to the support plate 30, A plurality of air tubes 60 provided around the float 50 and a support rod 70 connected to an upper end of the air tube 60 and installed in the upper portion of the inside of the bag 10 .

The bag 10 has a through hole 11 formed at an upper portion thereof and a lower portion thereof opened to provide a place for accommodating various parts including the support plate 30 and to protect them. The through hole (11) serves to provide a passage through which the fixed rope (20) penetrates to the upper part of the bag (10).

The bag 10 includes a plurality of insertion holes 12 formed around an opened lower portion and a plurality of insertion holes 12 formed at one end of the insertion hole 12 so as to be tied to the lower opened portion of the bag 10 And a closing rope (13).

The fitting hole (12) allows the closed lower portion of the bag (10) to be bundled and closed by fitting the closed rope (13). The closed rope 13 serves to openably close the open bottom of the bag 10.

The bag (10) further includes a rope releasing tool (14) mounted on the lower outer surface thereof. The rope releasing tool 14 serves to decomposably secure the other end of the closed rope 13 and release the fixing of the closed rope 13 by user's operation. That is, the rope releasing tool 14 can be removed from the fitting hole 12 by separating one end of the closed rope 13 fixed to the bag 10 by a user's operation So that the lower portion of the bag 10 can be opened again.

The upper end of the fixed rope 20 is connected to a helicopter and the lower end of the fixed rope 20 is provided inside the bag 10 through the through hole 11. The lower end of the fixed rope 20 is connected to the bag 10, So that it can be supported by a helicopter.

The fixed rope 20 further includes a hook 21 mounted at its lower end. The hook 21 is easily engaged with the connection ring 31 of the support plate 30 in a disassembled state so that the fixing rope 20 can be easily fixed to or separated from the support plate 30.

The support plate 30 is attached to the upper surface of the bag 10 at a lower portion of the fixed rope 20 and has a connection ring 31 which is detachably connected to the lower end of the fixed rope 20 And provides a place where the fixed rope 20 is connected through the connecting loop 31 while providing a space for mounting the gas cylinder 40 and float 50 to the inside of the bag 10 do.

The gas pipe 40 is mounted on the upper surface of the support plate 30 and stores a high pressure gas therein and a gas injection pipe 41 is connected to the upper end of the gas pipe 40 to inject gas into the air tube 60 do. The gas used in the gas cylinder 40 is usually a gas such as carbon dioxide which is lighter than air.

The gas injection pipe 41 is a pipe connecting between the gas pipe 40 and the air tube 60 and serves to provide a passage through which the gas of the gas pipe 40 is injected into the air tube 60 .

The float (50) is attached to the upper surface of the support plate (30) and is made of a floating material. The float (50) floats itself on the water surface while providing a place where a plurality of the air tubes .

The air tube 60 has a lower end connected to the float 50 and the gas injection pipe 41 connected to the air tube 60. A fitting ring 61 is formed at each upper end of the air tube 60, So that it can be floated on the water surface while the high-pressure gas is injected into the gas cylinder 40 while being accommodated in a state of being wound around the inside of the bag 10, And holding the air tube 60 to wait for the structure.

The fitting ring 61 is formed in each of the plurality of air tubes 60 so that an end of the air tube 60 can be fitted in the supporting rod 70.

The air tube (60) further includes a connection tube (62) for communicably connecting a central portion of the air tube (60) provided in a radial direction. The connection tube 62 serves to interconnect the central portions of the air tube 60, which are provided in a radially expandable manner.

The air tube 60 further includes a central mesh 63 installed between the inner side of the connection tube 62 and a mesh. The central mesh 63 is installed at the central portion of the air tube 60 inside the connection tube 62 so that people who have suffered a water accident can be lifted up or easily grasped to wait for the structure.

The support rod 70 is mounted vertically on the upper part of the inside of the bag 10 so that the fitting ring 61 can be detachably fitted and fixed. When the support rod 70 is pulled downward from the inside of the bag 10, the support rod 70 is stretched downward to a predetermined length and then one side is separated and the fitting ring 61 is discharged to the outside, So that it can be spread smoothly.

The support plate (30) further includes a fixed rope separator (32) mounted on the linking ring (31). The fixed rope separator 32 separates the lower end of the fixed rope 20 from the connection ring 31 by a user's operation.

The fixed rope separator 32 may be a wireless automatic actuator. The fixed rope separator 32 of the wireless auto actuator type may be a wireless rope separator such as a wireless signal transmitted by a user on a helicopter, And the hook 21 at the lower end of the fixed rope 20 is separated from the connecting loop 31 while being automatically operated.

The gas cylinder (40) further includes an injection irrigation bug (42) mounted on the gas injection pipe (41). The injection irrigation bug 42 functions to open the gas injection pipe 41 by the user's operation.

The infusion irrigation bug 42 may be a wireless automatic operation device. The infusion irrigation bug 42 of the wireless auto-actuator type may be implemented by a wireless signal The gas injection pipe 41 is opened while the gas in the gas pipe 40 is automatically injected into the air tube 60 through the gas injection pipe 41. [

As shown in the figure, the fixed rope separator 32 and the injection irrigator 42 may be manual actuators operated by manual operation, and the system is connected to the fixed rope separator 32 at the lower end thereof And an operating rope 80 connected to the infusion irrigator 42 at the top thereof and leading to the top of the bag 10 while being fixed to the bag 10 inside the through-hole 11.

The operating rope 80 is adapted to allow a user of the helicopter to pull it to sequentially operate the infusion irrigation baffle 42 and the fixed rope separator 32. That is, when the user pulls the operating rope 80 while aboard the helicopter, the infusion irrigation device 42 is operated first, and the gas injection pipe 41 is opened. Thereafter, when the user operates the operating rope 80 The fixed rope separator 32 is operated and the fixed rope 20 is separated from the connection ring 31. [

The support bar 70 further includes a support bar separator 71 mounted at one end thereof. The support rod separator 71 separates one end of the support rod 70 by a user's operation so that the fitting ring 61 is disengaged from the support rod 70.

The support bar separator 71 may be a wireless auto-operation device that is automatically activated by receiving a wireless signal transmitted by a user's remote operation. The support rod separator 71 of the wireless auto-actuator type is automatically operated by receiving a radio signal transmitted by a user on a helicopter through a wireless controller such as a remote controller, and one end of the support rod 70 is separated, The fitting ring 61 engaged with the supporting rod 70 is disengaged from the supporting rod 70 and the air tube 60 is unfolded.

The supporting rod separator 71 may be a manually operated actuator operated by a manual operation as shown in the drawing. The air injection structure system for aquatic life structure has an upper end connected to the support rod separator 71, And an operating rope (90) connected to float (50).

The operation rope 90 is connected to the support rod separator 71 by a predetermined length between the support rod separator 71 and the float 50 to pull the support rod separator 71 together with the fall of the floating fluid 50 .

The structure for pneumatic inflatable structure for water rescue structure further includes a time anchor 100 provided inside the lower surface of the support plate 30 and connected to a lower portion of the support plate 30 by a connection rope 101. The temporal anchor 100 is spaced apart from the support plate 30 by the connection rope 101 so that the float 50 including the support plate 30 is floated on the water surface And serves to fix the support plate 30 to the water surface so as to prevent it from being moved in the wind.

The support plate 30 further includes a time anchor ejector 33 installed at one side thereof. The time anchor ejector 33 discharges the time anchor 100, which is accommodated in the lower portion of the support plate 30, by the user's operation.

The time anchor ejector 33 may be a wireless automatic actuator that is automatically activated by receiving a radio signal transmitted by a user's remote operation. The time anchor ejector 33 of the wireless auto-actuator type receives the radio signal transmitted from the user via the wireless controller such as a remote controller, and automatically operates to open the lower portion of the support plate 30 The time anchor 100 is discharged to the lower surface of the support plate 30 to the water surface.

The anchor ejector 33 may be a manual operation unit operated by manual operation and the operation rope 80 is connected to the operation rope 80 at its upper end and the lower end is connected to the anchor ejector 33 And an auxiliary rope (81) connected to operate the hour anchor ejector (33) by pulling the operating rope (80).

The auxiliary rope 81 is connected to the actuating rope 80 by a predetermined length between the time anchor ejector 33 and the actuating rope 80. When the actuating rope 80 is pulled upward by the user, The auxiliary rope 81 is pulled and the anchor ejector 33 is operated.

1 to 8, the operation of the air intake structure system of the present invention will be described. First, as shown in FIG. 1, the bag 10 is loaded on a helicopter in a state where the bag 10 is closed, and the bag 10 is moved to the helicopter at a point where an accident occurs.

After the helicopter arrives at the point of the accident, the user operates the rope releasing tool 14 to release the closed rope 13 from the bag 10, As shown in FIG.

In this state, the user drops the bag 10 from the helicopter H toward the surface of the water as shown in FIG.

At this time, the bag 10 is dropped by the fixed rope 20 while being supported by the helicopter H, and the operating rope 80 is also released from the helicopter H, Falls.

As shown in FIG. 4, while the bag 10 is falling on the helicopter H, the bag 10 is fixed to the operating rope 80, The float 50 and the support plate 30 fall down to the lower side together with the air tube 60 while the fitting ring 61 is held in the support rod 70. As a result, The air tube 60 wound inside is released.

At this time, the operating rope 80 pulls the infusion irrigation baffle 42 so that the infusion irrigation baffle 42 is activated and the gas infusion pipe 41 is opened to open the high pressure gas Is injected into the air tube (60) through the gas injection tube (41).

5, when the injection of the gas into the air tube 60 is almost completed, the support rod 70 is pulled downward by the air tube 60 so as to extend from the inner side of the bag 10 to the lower side thereof The operation rope 90 is stretched so that the float 50 pulls the operation rope 90 and the support rope separator 71 is operated so that one side of the support rope 70 And the fitting ring 61 is separated from the support rod 70 by being separated.

6, after the air tube 60 is detached from the support rod 70, the air tube 60 is continuously dropped to be placed on the water surface, and the support plate 30 and the float 50, Is floated on the surface of the water.

At this time, the user continues to pull the operating rope 90 to actuate the fixed rope separator 32 and the anchor ejector 33 so that the hooks (not shown) of the fixed rope 20 The time anchor 100 is discharged to the lower portion of the support plate 30 while being separated from the support plate 30 by the connection rope 101. As a result,

As shown in FIG. 7, after the air tube 60 is discharged from the bag 10 dropped from the helicopter H, the air tube 60 is spread radially on the water surface, The connection tube 62 connected between the main body 60 and the central network 63 also spreads on the water surface. As the air tube 60 spreads widely on the surface of the water as described above, it is possible to hang dozens to hundreds of searched eggs from the air tube 60 at the same time to wait for the structural line.

In addition, the anchor 100 is positioned in the water while being separated from the air tube 60 by the connecting rope 101.

8, the lower end of the operating rope 80 is disengaged and the lower end of the auxiliary rope 81 is also disengaged as shown in FIG. 8, and the commercial rope is separated from the helicopter The operating rope 80 and the bag 10 are collected together with the fixed ropes 20 already separated.

9 is a schematic plan view showing another embodiment of an air tube of a pneumatic inflatable structural system according to the present invention.

As shown, the air tube 60 of the present invention has a plurality of lifting ropes 64 provided on the outer surface of the air tube 60 outside the connecting tube 62, . The lifting rope 64 is installed on the outer surface of the air tube 60 so that people who have an accident can easily grasp it.

10 is a schematic plan view showing another embodiment of an air tube of a pneumatic inflatable structural system according to the present invention.

As shown in the figure, the air tube 60 of the present invention has two pairs of air tubes 60 adjacent to each other, and the air tube 60 is connected to the ends of two adjacent air tubes 60, And a connector 65 attached to an end of the connector body 65. [

The pair of air tubes 60 are provided adjacently to each other to form a space in which an accidental person can ride. The connector 65 connects the ends of the air tube 60 so that a pair of the air tubes 60 can have an integral structure.

The air tube 60 further includes an inner mesh 66 disposed between the connection tube 62 and the connection port 65 and disposed inside the pair of adjacent air tubes 60 and provided in a mesh form. The inner mesh 66 is intended to allow persons who have been injured to sit or lie down.

The air tube 60 is disposed between the outer side of the connection tube 62 and the inner side mesh 66 and the outer side of the air tube 60 and is provided in the form of a net, ). The outer circular net 67 serves to form a space in which people who have been accidently caught or boarded can rest.

FIG. 11 is a schematic longitudinal sectional view showing a pneumatic inflatable structural system for life saving structure according to another embodiment of the present invention.

As shown therein, the inflatable structural system according to another embodiment of the present invention further includes a lighting device 110 installed outside the float 50. The illuminating device 110 is turned on according to a water sensing signal input through a water sensor 111 installed on a lower surface of the float 50 and irradiates light toward the air tube 60 . Here, the water sensor 111 is a known moisture sensor for detecting the presence or absence of moisture, and turns on the illumination device 110 when water or water is sensed.

When the illumination device 110 is turned on and illuminates the light, the position of the structural system can be easily identified even when the rescuer or the rescue line is at night or in bad weather, so that the life structure is more easily performed.

Although the illuminating device 110 is installed on the outer surface of the float 50, the illuminating device 110 is not limited thereto, and it is possible to allow the rescuer to easily identify the location of the air tube 60 at night And may be further provided on the upper surface of the air tube 60.

The air injection structural system further includes a position transmitter 120 installed on the upper surface of the support plate 30. The position transmitter derives the current position of the support plate 30 via GPS and transmits the derived position information to the outside.

Here, the GPS refers to a global positioning system, and refers to a system for locating an object (such as a ship or an aircraft) in a three-dimensional space using a satellite.

As described above, the position information of the present structural system transmitted through the position transmitter 120 is transmitted to a specific recipient such as a helicopter or a structural line inserted in the structure, and a rescuer or the like aboard the helicopter or the rescue line, The present position can be recognized in real time, so that the structure can be more easily structured even when the structural system drifts in the sea or water.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is clear that the present invention can be suitably modified and applied in the same manner. Therefore, the above description does not limit the scope of the present invention, which is defined by the limitations of the following claims.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention.

10: Bag
11: through hole 12:
13: Closure rope 14: Rope release mouth
20: Fixed rope
21: Hook
30: Support plate
31: connecting ring 32: fixed rope separator
33: City anchor ejector
40: Gas cylinder
41: gas injection tube 42: injection irrigator
50: float
60: air tube
61: fitting ring 62: connecting tube
63: Central mesh 64: Life rope
65: Connector 66: Inner mesh
67: outer circular netting
70: support rod
71: support rod separator
80: Working rope
81: auxiliary rope
90: Operation rope
100: City anchor
101: Connecting ropes
110: Lighting equipment
111: Water sensor
120: Position transmitter

Claims (21)

A bag (10) having a through hole (11) formed in its upper portion and opened at its lower portion;
A fixed rope 20 connected to the helicopter at its upper end and a lower end provided inside the bag 10 through the through hole 11;
A support plate 30 provided on the upper side of the bag 10 at a lower portion of the fixed rope 20 and having a connection ring 31 detachably connected to a lower end of the fixed rope 20;
A gas cylinder 40 mounted on the upper surface of the support plate 30, in which a high-pressure gas is stored therein and a gas injection pipe 41 is connected to the upper end;
A float 50 attached to the upper surface of the support plate 30 and made of a floating material;
A lower end is mounted to the float 50 and the gas injection pipe 41 is connected to each of the float 50. A fitting ring 61 is formed at each upper end of the float 50, A plurality of air tubes (60);
A support rod (70) mounted vertically on the inner upper portion of the bag (10) and in which the fitting ring (61) is removably fitted;
Wherein the air intake structure structure for water life rescue. The method according to claim 1,
The bag (10)
A plurality of fitting holes 12 formed around the opened lower portion,
A closing rope (13), one end of which is fitted in the fitting hole (12) and ties the open lower portion of the bag (10)
Further comprising an inflatable structure system for rescue water rescue. 3. The method of claim 2,
The bag (10)
A rope releasing tool 14 mounted on the lower end outer surface thereof for releasably securing the other end of the closing rope 13 and releasing the fixing of the closing rope 13 by user's operation,
Further comprising an inflatable structure system for rescue water rescue. The method according to claim 1,
The fixed rope (20)
A hook (21) mounted on the lower end thereof and hooked on the linking ring (31)
Further comprising an inflatable structure system for rescue water rescue. The method according to claim 1,
The support plate (30)
Further comprising a fixed rope separator (32) mounted on said connecting loop (31) and separating the lower end of said fixed rope (20) from said connecting loop (31)
The gas cylinder (40)
Further comprising an injection irrigation device (42) mounted on the gas injection pipe (41) and opening the gas injection pipe (41) by a user's operation. 6. The method of claim 5,
The stationary rope separator 32 and the injection irrigator 42,
And a wireless automatic actuator for automatically receiving a wireless signal transmitted by a remote operation of a user. 6. The method of claim 5,
The fixed rope separator 32 and the injection irrigator 42 are manual actuators operated by manual operation,
The inflated structural system may include:
The lower end of the bag 10 is connected to the fixed rope separator 32 and connected to the injection irrigation bug 42 at an upper portion thereof and fixed to the bag 10 inside the through hole 11, And an actuating rope (80) which sequentially actuates the injection irrigation bumper (42) and the fixed rope separator (32) by the user's operation;
Further comprising an inflatable structure system for rescue water rescue. The method according to claim 1,
The support rod (70)
A support rod separator 71 for separating one end of the support rod 70 by a user's operation so that the fitting ring 61 is disengaged from the support rod 70,
Further comprising an inflatable structure system for rescue water rescue. 9. The method of claim 8,
The support bar separator (71)
And a wireless automatic actuator for automatically receiving a wireless signal transmitted by a remote operation of a user. 9. The method of claim 8,
The support bar separator 71 is a manual actuator operated by manual operation,
The airstream rescue air infusion rescue system,
The operation rope 90 is connected to the support rod separator 71 at its upper end and connected to the float 50 at its lower end and pulls the support rod separator 71 together with the fall of the float 50, ;
Further comprising an inflatable structure system for rescue water rescue. 8. The method of claim 7,
The inflated structural system may include:
A time anchor 100 provided inside the lower surface of the support plate 30 and connected to a lower portion of the support plate 30 by a connection rope 101 and fixing the support plate 30 to the water surface; Further included,
The support plate (30)
And a time anchor ejector (33) installed at one side thereof for ejecting the time anchor (100) accommodated in a lower portion of the support plate (30) by a user's operation to the lower portion. Structural system. 12. The method of claim 11,
The time anchor ejector (33)
And a wireless automatic actuator for automatically receiving a wireless signal transmitted by a remote operation of a user. 12. The method of claim 11,
The time anchor ejector 33 is a manual actuator operated by manual operation,
The operating rope (80)
An auxiliary rope 81 connected to the operating rope 80 at its upper end and connected to the time anchor ejector 33 and operated by the pulling of the operating rope 80,
Further comprising an inflatable structure system for rescue water rescue. The method according to claim 1,
The air tube (60)
A connection tube 62 for connecting a central portion of the air tube 60 radially provided to communicate with each other,
Further comprising an inflatable structure system for rescue water rescue. 15. The method of claim 14,
The air tube (60)
A central mesh 63 provided between the inside of the connection tube 62 and a mesh network,
Further comprising an inflatable structure system for rescue water rescue. 15. The method of claim 14,
The air tube (60)
A plurality of life ropes (64) provided on the outer surface of the air tube (60) outside the connection tube (62)
Further comprising an inflatable structure system for rescue water rescue. 16. The method of claim 15,
The air tube (60)
(65) which is attached to the end of the air tube (60) so that the two adjacent air tubes (60) are adjacently connected and the ends of the two adjacent air tubes (60)
Further comprising an inflatable structure system for rescue water rescue. 18. The method of claim 17,
The air tube (60)
An inner mesh 66 installed inside the pair of adjacent air tubes 60 between the connection tube 62 and the connection port 65 and provided in the form of a mesh,
Further comprising an inflatable structure system for rescue water rescue. 19. The method of claim 18,
The air tube (60)
An outer circular net 67 provided between the outer side of the connection tube 62 and the inner side net 66 and the outer side of the air tube 60 and provided in a net shape,
Further comprising an inflatable structure system for rescue water rescue. The method according to claim 1,
The inflated structural system may include:
And is installed on the outside of the float 50 and turned on according to a water sensing signal inputted through the water sensor 111 installed on the lower surface of the float 50, A lighting device (110) for irradiating light;
Further comprising an inflatable structure system for rescue water rescue. The method according to claim 1,
The inflated structural system may include:
A position transmitter 120 installed on the upper surface of the support plate 30 for deriving the current position of the support plate 30 via GPS and transmitting the derived position information to the outside;
Further comprising an inflatable structure system for rescue water rescue.

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