KR101725180B1 - Submarine Rescue Suit - Google Patents

Abstract

A submarine lifebuoy designed as a complete garment with a hood covering the wearer's head is provided with means for reducing the rate of rise and means for controlling the gas pressure in the hood.

Description

Submarine Rescue Suit

The present invention relates to a submarine lifeboat having the configuration listed in the preamble of claim 1.

For example, such submarine lifeboats that allow emergency escape from a damaged submarine at depths exceeding 80 m are known from DE 10 2010 023 518 A1 and GB 2 441 959 A. They are usually designed as complete garments with air-filled collar as a hood and float to cover the user's head. The hood of the submarine lifeboat is also filled with air and serves as a respiratory air reservoir as well as an additional float.

During an emergency escape from a submarine, a person using a submarine lifeboat climbs to the surface at a speed of about 2.7 meters per second. During climbing towards the surface, the air expands in the cola and hood, where a portion of the air in the cola is released to the hood through the valve to equalize the pressure, and a portion of the air in the hood is vented Through the submarine life jacket.

Although submarine lifeboats significantly increase opportunities for crew rescue on submarines under damaged diving voyages, emergency escape at deeper water depths is a bad consequence of a fatal decompression accident, , Because decompression stops can not be incorporated during an emergency escape in a submarine's life jacket.

It is an object of the present invention to improve a submarine lifeboat which enables an improved emergency escape from a submarine during a diving voyage in terms of reduced pressure.

This object is achieved by a submarine lifejacket having the configurations specified in claim 1. Other enhancements of this submarine lifeboat are described in the dependent claims and can be understood from the detailed description and drawings. According to the invention, the configurations claimed in the dependent claims can be further characterized by the solution of claim 1 by independent or technical combination

The submarine life jacket according to the present invention is designed as a complete garment having a hood covering the head of the user. This complete garment here is preferably composed entirely of hermetically sealed gloves in addition to the sealed hood, and hermetically sealed socks to the legs. Gloves and socks may be omitted, in which case the submarine life jacket has a sealing gait on the arms and legs. The hood forms a respiratory gas reservoir for the user of the submarine life jacket.

It is an object of the present invention to extend the decompression time during an emergency escape from a damaged submarine at a depth of up to 300 meters, thereby preventing, or at least significantly reducing the risk of, decompression accidents, if at all possible. As described below, the submarine lifebuoy according to the present invention comprises means for reducing the rate of rise and means for controlling the gas pressure in the hood.

It is best not to use the means to reduce rate of rise during full rise towards the surface. Quite the contrary, the theoretical model suggests that this submarine's life jacket, the rise from a damaged submarine to the surface of the water, occurs more rapidly at a depth of 30 meters compared to previous known submarine life suits, As such, the means of reducing the rate of increase suggests that such improvements, such as being operated only at a depth of 30 meters, are additionally improved.

Design measures that allow for a faster rise in the early stages of climbing until reaching a depth of 30 m are thus more effective in reducing the flow resistance of the submarine lifeboat and / or the submarine lifeboat compared to this type of lifeboats already known by the improved shape of the submarine lifeboat. In this regard, it may include improving the surface structure of the shell of the improved submarine lifeboat. Another measure to increase the rate of rise may be to increase the float formed on the submarine lifeboat and / or to install the forwarding means on the submarine lifeboat.

The means for controlling the gas pressure in the hood is preferably constructed in such a way as to maintain a pressure in the hood or inside the submarine's lifeboat above about 0.3 to 0.5 bar atmospheric pressure on the surface. The means for controlling the gas pressure on the surface of the water is used to maintain a pressure such that the pressure inside the hood coincides with the level at depths of 3-5 m. Divers routinely make their final decompression stop at this depth every day. Computationally, the overpressure in the hood needs to be maintained for only two minutes after reaching the surface during the emergency escape from the depth of water up to 300 m.

In order to maintain the overpressure associated with atmospheric pressure on the surface of the water on the surface of the water, the submarine life jacket is typically of a closed design. In this connection, it is advantageous that the hood has a structure which forms a closed member together with the remaining submarine lifejackets. Suitable sealing is best, for example, as edge sealing, but it is best to use a seal lock for the opening formed on the hood, for example a zip lock, but also other locks for openings formed on the submarine life- have.

The submarine lifebuoy according to the invention advantageously constitutes at least one gas discharge valve for equalizing its outside environment and pressure. The at least one gas discharge valve is preferably located at the lower end of the hood in the ascending direction. This gas discharge valve is typically designed as a one-way valve that allows the flow of breathing gas from the interior of the hood to the environment of the submarine's lifeboat, but prevents water from flowing into the hood or into the submarine's lifeboat . The gas discharge valve is preferably kept open to a water depth of 3 to 5 m or to an ambient pressure of 1.3 to 1.5 bar to allow respiratory gas in the hood, which expands in order to escape from the hood by decreasing water depth . The gas discharge valve is then closed to maintain the desired excess pressure within the hood.

This gas discharge valve, which is arranged on the hood, can be basically manually operated for this purpose, in which case the user of the submarine's lifeboat, in the suitably provided for this purpose, preferably has a water depth of 3 to 5 meters The water depth should be carefully monitored with a water depth detector so that the gas discharge valve can be closed by operating the water level sensor.

However, it is more desirable that the gas discharge valve is automatically closed at such depth for emergency escape which is already tense from the damaged submarine. For this reason, it is preferably provided that the gas discharge valve is designed to be pressure-dependent controlled. In this connection, for example, the gas discharge valve can be designed as a pressure-addition valve, which remains open until such time as the pressure value set on the pressure-addition valve is present, and the pressure- When the value is reached, it automatically closes itself. This pressure-adding valve may be signal-connected to a pressure sensor communicating with the environment of the submarine's life jacket, or a corresponding pressure switch may be formed on the pressure-adding valve.

As can be seen, the object of using the submarine lifejacket according to the present invention is to maintain the desired excess pressure in the hood for at least several minutes when the user of the submarine lifejacket is already on the surface. In order to ensure even a very small leak in a submarine lifejacket, the submarine lifejacket according to the invention advantageously has a respiratory gas source connected by the interior of the hood and the line. This breathing gas source is used to re-supply the amount of breathing gas exiting the submarine life jacket or hood due to leakage.

To quickly respond to pressure reduction in the hood, a locking device for the breathing gas source is typically operated as a function of the gas pressure in the hood. A pressure sensor or pressure switch can advantageously be arranged in the hood here, which allows the locking device for the breathing gas source to open when the pressure inside the hood is too low through the adjustment means located on the locking device, As soon as the pressure of the breathing gas is restored.

As already mentioned, it is particularly advantageous that the means of reducing the rate of rise operate at a depth of only 30 m. If these measures are designed to fit together, they can be operated manually. From the perspective of the stress to the person using the submarine life jacket, it is also a further advantage that the means for reducing the rate of increase is automatically operated at the desired depth. It is also advantageously provided that the means for reducing the rate of rise is controlled as a function of the diving depth. Along with this, a triggering device for actuating the means for reducing the rate of rise can be typically signal-connected to a pressure sensor for measuring the pressure. If necessary, the pressure sensor may be a pressure sensor used to control the gas discharge valve disposed on the hood.

In order to reduce the rate of climb, the submarine lifebuoy according to the invention may advantageously have at least one inflatable decelerating wing. This deceleration wing may be part of the submarine life jacket or it may be a part located on the submarine life jacket, which rises in the first operating state, if any, which may have negligible effect and, in the second operating state, Lt; RTI ID = 0.0 > resistance < / RTI > For example, the decelerating blade can be made very close to the outer surface of the submarine lifejacket in the first operating state and switched therefrom to a second operating state projecting laterally in the up direction on the submarine lifejacket. The otherwise conceivable reduction wing structure is formed by the portion of the submarine lifejacket that can be filled with fluid, which increases the surface area of the submarine lifeboat through which water flows from it as soon as the fluid is filled. This part of the submarine lifebath that forms this deceleration wing can be filled with air for the purpose of its expansion, or an initial low pressure is present in this part of the submarine lifeboat and allows water to flow into this part It is conceivable that the deceleration fluid is operated by opening the valve.

As an alternative to an increase rate or as an additional measure, a submarine lifeboat according to another advantageous structure may constitute a decelerated parachute. This slowing parachute can basically coincide with the deceleration parachutes used to decelerate the aircraft and the cars, and the submarine's life jacket from the folded, You can move to the position below.

The submarine lifeboat according to the present invention has the effect of enabling an enhanced emergency escape from a damaged submarine during a diving voyage in terms of reduced pressure.

1 is a schematic diagram of a very simplified submarine life jacket,
Figure 2 is a schematic representation of a submarine lifebuoy with greatly simplified inflated deceleration wings, and
FIG. 3 is a model diagram of a submarine lifeboat with a highly simplified activated decelerated parachute.

Hereinafter, the present invention will be described in more detail based on the embodiments shown in the drawings with reference to the drawings.

The submarine lifejackets 2 'shown in FIG. 3 as well as the submarine lifejackets 2 shown in FIGS. 1 and 2 are each designed with complete garments completely surrounding the user. The hood 4, which surrounds the user's head, respectively, forms part of the submarine lifejackets 2 and 2 '. This hood 4 is provided with a viewing window 6 for the user and is an essential component of the submarine lifejacket 2 or 2 'and for this reason forms the enclosed device mentioned later. The inner space of the hood 4 serves as a respiratory gas reservoir for the submarine lifeboat (2 or 2 ') user during an emergency escape from an injured diving submarine, thus allowing the respiratory gas reservoir (2 or 2' Gas. In order to wear the submarine lifejackets 2 or 2 ', the hood 4 has an opening which can be sealed by a zip fastener 8. This opening, which can be sealed by the zip fastening device 8, is sealed by a sealant not shown in the figure so as not to leak gas.

The gas discharge valve 10 is located in the lower end region of the hood 4. [ This gas discharge valve is designed as a one-way valve which can be controlled in pressure, and is used for controlling the gas pressure in the hood 4, which will be described in more detail below. Each of the submarine lifejackets 2 and 2 'shows the breathing gas source 12 as another means for controlling the gas pressure in the hood 4. This breathing gas source 12 is formed by a compressed air cylinder.

The submarine lifejacket 2 has two decelerating blades 14. They consist of two pockets that can be filled with fluid and are located between the inside of the sleeves of the submarine lifejackets 2 and the body area of the submarine lifejackets 2 lying opposite the inside. When the pockets are filled with a fluid such as air or water, they essentially extend into triangular reduction wings 14, where the arms of the user of the submarine lifejacket 2 are forced into a horizontal position.

The submarine lifejacket 2 'shown in FIG. 3 differs from the submarine lifejacket 2 shown in FIGS. 1 and 2 in that there are no decelerating blades but instead a decelerated parachute 16 for reducing the rate of climb. The decelerated parachute 16 can be moved from an unillustrated retracted position located in an area covering the torso of the user on the outer side of the submarine lifejackets 2 'to an operating position below the submarine lifejackets 2' .

The operation of the submarine lifejackets 2 and 2 'according to the present invention is as follows:

If a person in submarine lifejackets 2 and 2 'escapes a damaged submarine located at a water depth between 150 and 300 meters, for example, to avoid the complexity of the figure, an air-filled collar Gives buoyancy to the submarine lifejacket which causes the submarine lifejackets 2 and 2 'to rise at a speed of about 2.7 m / s or more in the water surface direction together with the hood 4 filled with air as breathing gas. The deceleration wings 14 of the submarine lifejacket 2 and the decelerated parachute 16 of the submarine lifejacket 2 'are not yet operated here.

During climbing to the surface, the air in the cola and hood expands due to the water pressure becoming weaker as the water depth decreases. This excess air in the cola is converted to the hood 4 through an excess pressure valve formed on the cola and is switched from there to the outside environment of the submarine lifejackets 2 and 2 'through the open gas discharge valve 10.

As soon as the water depth reaches about 30 m, the decelerating wings 14 of the submarine lifejackets 2 or the decelerating parachute 16 of the submarine lifejackets 2 'are operated. Both the decelerating wings 14 and the decelerated parachute 16 are controlled as a function of diving depth. Consequently, sensors (not shown) are provided on the submarine lifejackets 2 and 2 'to detect the water pressure and the water depth therefrom, and a controller for operating the deceleration wings 14 or the deceleration parachute 16 It stimulates. Operating the decelerating blades 14 or the decelerating parachute 16 significantly slows the rate of rise by the submarine lifejackets 2 and 2 '.

As soon as the water depth reaches approximately 5 m, an excess pressure of approximately 0.5 bar is controlled in the hood 4 until the water can not escape from the hood at the water depth of 5 m and reaches the water surface, The gas discharge valve 10 is closed. The air pressure in the hood is sensed by a pressure sensor (not shown) disposed therein.

If the pressure sensor determines that the pressure inside the hood 4 is decreasing, the locking device for the breathing gas source 12 connected by the line together with the hood 4 is returned to the state where the pressure inside the hood 4 is again So that the air stored in the breathing gas source 12, which allows the air to flow upward into the hood 4, is opened. As soon as a desired pressure is reached within the hood 4, the respiratory gas source 12 is again sealed by its locking device.

2, 2 ': Submarine life jacket 4: Hood
6: view window 8: zip lock
10: gas discharge valve 12: breathing gas source
14: Deceleration Wings 16: Reduced Chute

Claims (9)

A hood (4) covering the head of a user, the hood (4) being designed as a complete garment forming a respiratory gas reservoir for a user, characterized in that the submarine lifejackets (2 and 2 ''Have means for controlling the gas pressure in the hood 4 and means for reducing the rate of rise,
The submarine lifejackets 2 and 2 'have at least one gas discharge valve 10 for equalizing its outside environment and pressure and a breathing gas source 12 connected by a line inside the hood 4 Respectively,
Characterized in that the locking device for the breathing gas source (12) is operated as a function of the gas pressure in the hood (4). The submarine lifebuoy according to claim 1, characterized in that the hood (4) together with the remainder of the submarine lifejackets (2 and 2 ') forms a gas-tight member. The submarine lifebuoy according to claim 1, characterized in that the gas discharge valve (10) is designed to be pressure controlled in a dependent manner. A submarine lifebuoy as claimed in any one of claims 1 to 3, characterized in that the means for reducing the rate of rise is controlled as a function of diving depth. 4. A submarine lifejacket according to any one of claims 1 to 3, characterized in that the submarine lifejacket (2) comprises at least one inflatable reduction wing (14). 4. The submarine life jacket according to any one of claims 1 to 3, wherein the submarine lifejacket (2) is provided with a deceleration chute. delete delete delete

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