SE526233C2 - System for supplying a diver with breathing gas - Google Patents

Abstract

The invention concerns a system and a method for supplying breathing gas to a diver. The system is of the open circuit type and comprises a gas source consisting of a pressurized container ( 1 ), which is intended to be placed at a distance from the diver and which delivers breathing gas under a high pressure, a breathing apparatus ( 4 ) which is intended to be carried by the diver and a flexible tube ( 3 ), which connects the gas source with the breathing apparatus. The flexible tube is of the high-pressure type, the gas is conducted through the flexible tube under a pressure, which is essentially equal to the pressure delivered from the gas source, and the gas source is arranged to be able to deliver breathing gas at a pressure, which exceeds approx. 30 bars.

Description

30 526 233 2 ~ Hose diving is therefore often used for long-term and complicated work, such as underwater repairs and rescue work in smoke-filled rooms. Even in rescue operations in other environments, for example in caves with a toxic or otherwise dangerous atmosphere, tubing diving systems are often used.

In order for a tubed diver to be able to perform a good and efficient job, it is therefore crucial that the diver's mobility is hindered as little as possible. It is also important that the equipment the diver carries with him weighs as little as possible and is easy to handle. Another important aspect, especially in rescue operations, is that the entire system is easy to transport, even in rugged terrain. In addition, it is of great importance that the system is put into operation quickly and that the diver can quickly and unhindered get from the parking place where the gas source is located to the area where the rescue operation is to be performed. Another important aspect is that the system has high reliability and contains as few components as possible, which can be subject to breakdown or malfunction. in known tubing systems, the gas source is often a pressurized gas container. The container is usually, when it is completely filled with breathing gas, pressurized to a maximum of about 300 bar.

A first pressure regulator is arranged in direct connection with the container. A breathing device carried by the diver comprises a breathing valve with a nozzle, through which the diver breathes. The first pressure regulator is arranged to reduce the pressure from the container, so that the pressure in the hose between the first pressure regulator and the breathing device is about 10 bar plus about 1 bar above the diver's current ambient pressure. Often the breathing device also comprises a second pressure regulator, for fine adjustment of the pressure between this second pressure regulator and the breathing valve. The breathing valve finally reduces the pressure to a breathing pressure that is approximately equal to the ambient water or atmospheric pressure.

Since the breathing gas is passed from the first pressure regulator via the hose to the breathing device under a reduced pressure of about 10 bar plus about 1 bar above the diver's ambient pressure, a certain minimum internal cross-sectional area of the hose is required to ensure a sufficient flow of breathing gas through the hose. Especially with long hoses, this causes considerable problems because the hose must be designed with a relatively large internal cross-sectional area. This means that the hose must be made relatively thick, which in turn leads to the hose becoming heavy and awkward to handle. In addition, such a thick hose constitutes a considerable wind trap when used outdoors on land, which of course makes it difficult for the diver to move freely. This problem is even worse for underwater divers because a thick hose constitutes a large body of water and because the impact of the water on the hose results in large, difficult-to-handle forces that must be mastered and parried by the diver. It is particularly unfavorable and even dangerous to use a thick hose in water with underwater currents, as such currents can pull the hose with such force that the diver cannot parry but instead is pulled away from the working area.

Object of the invention An object of the invention is therefore to provide a system of the type indicated in the introduction, which substantially increases the diver's freedom of movement.

Another object is to provide such a system which is reliable and where the number of components is minimized.

A further object is to provide such a system in which a relatively thin and light hose can be used other than u.

° I 0 o n o q u ° 'o o o on n g. 526 233 4' - to minimize the negative impact of the hose on the diver's freedom of movement.

Brief description of the invention These and other objects are achieved according to the invention with a system of the type specified in the first paragraph of this description, characterized in that the hose is of high pressure type and that the breathing gas is led through the hose from the gas source to substantially the pressure given from the gas source. .

As the breathing gas is passed through the hose under the high pressure delivered from the gas source, a sufficiently large gas flow through the hose can be ensured even if the hose is designed with a relatively small internal cross-sectional area. With a suitable choice of hose material, the outer circumference of the hose can then also be kept small, whereby the hose during use constitutes a significantly smaller wind resp. water capture than has previously been possible. The hose's small cross - sectional dimension also reduces the hose's weight, which facilitates the diver's work on site as well as transport, installation and commissioning of the system. A hose with a small cross-sectional dimension is also more flexible and easier to handle, which also facilitates the diver's work on site as well as the removal and hauling in of the hose. Another advantage of the system according to the invention is that the number of components can be kept to a minimum, since no pressure regulator is necessary at the gas source. The risk of malfunction of the system is thus reduced.

Further advantages of the invention appear from the dependent claims. The hose can, for example, be wholly or partly made of polyamide fibers, such as Kevlar. Such a high-strength material ensures that the hose can withstand the high pressures of up to 526 233 5 700 bar or 300 bar supplied by the gas source. In addition, if the hose is made of such a material, in addition to serving as a gas line, it can also be designed to constitute a lifeline with which the diver can, for example, be pulled up to the surface or out of a smoke-filled room in the event of an accident. This eliminates an otherwise necessary separate lifeline.

The system also allows flexibility in how the breathing gas is connected to the conventional breathing device carried by the diver. According to one embodiment, for example, the hose can be connected to the breathing device so that the breathing gas supplied from the gas source can be used to fill a spare gas container under high pressure carried by the diver.

Description of Preferred Embodiments Various exemplary embodiments are described below with reference to the accompanying figures, in which: Fig. 1 shows a schematic sketch of a first embodiment of the invention.

Fig. 2 shows a corresponding schematic sketch of a second embodiment.

Fig. 1 shows a first embodiment of a system according to the invention. The system comprises a gas source in the form of a pressurized container 1 which contains the breathing gas, for example air. The container is normally, when full, pressurized to about 300 bar, but in some applications container pressures as high as 700 bar can be used. The container is connected via a shut-off valve 2 to a high-pressure hose 3.

The shut-off valve 2 is open during normal use, so that the pressure prevailing in the container 1 also prevails in the hose 3.

The shut-off valve closes, for example, when replacing the container 1, in order to maintain the high pressure in the hose 3 and after completion of work, when the system is dismantled. The hose 3 is made of a high-strength material and designed to withstand the high container pressures. I.e. the high pressure hose 3 is designed and manufactured to be able to withstand good pressures of 300 bar with a good margin and in some applications 700 bar without there being a risk that the high pressure will damage the hose. The hose 3 may for instance comprise an inner gas-tight layer, an intermediate pressure-absorbing layer and an outer wear-resistant layer. The intermediate layer may, for example, consist of, or contain carbon fibers, such as Kevlar or spun metal.

The hose 3 is at its other end, via a non-return valve 3a, connected to a breathing device 4 carried by the diver (not shown).

The breathing device 4 comprises a nozzle 5, through which the diver breathes, a breathing valve 6, a pressure reducing valve 7, a shut-off valve 8 and a spare gas container 9.

During use, the breathing gas is passed from the container 1 during so-called unregulated container or bottle pressure via the hose 3 to the breathing device 4. Ie. the pressure which in each case prevails in the container 1 also prevails in the hose 3.

The shut-off valve 8 of the respirator 4 is normally closed.

The unregulated bottle pressure also prevails in the line 10 between this shut-off valve 8 and the pressure reducing valve 7.

The pressure reducing valve 7 is arranged to independently of the pressure upstream thereof, i.e. in the container 1, the hose 3 and the line 10 keep the pressure in the line 11 at about 10 bar.

This pressure is further reduced by the breathing valve 6, so that the pressure prevailing in the nozzle is approximately the same as or slightly higher than the ambient water or atmospheric pressure. 10 15 30 526 253 7 During use of the system, the pressure in the container 1 gradually decreases as the breathing gas is consumed. When the container pressure falls below a certain value, a sufficient flow through the hose can no longer be ensured due to the pressure drop across the hose. Personnel at the container 1 then close the shut-off valve 2, whereby the pressure in the system downstream of this valve 2 is kept controlled, so that the container 1 can be replaced. During the time it takes to change the container, the amount of breathing gas present in the hose is sufficient to supply the diver. When the container 1 is replaced, the valve 2 is opened again, whereby the hose 3 is again pressurized to the unregulated bottle pressure.

In the event of, for example, a rupture of the high-pressure hose 3 or if the supply of breathing gas from the container 1 should cease for any other reason, the non-return valve 3a ensures that the pressure in the breathing device does not drop uncontrolled.

The diver can then open the shut-off valve of the breathing device 4, whereby breathing gas is obtained from the spare container 9.

In the embodiment shown in Fig. 1, it is also possible to fill the spare container 9 during the work. Hereby the shut-off valve 8 of the breathing device 4 is opened, whereby the high unregulated container pressure in the hose 3 and the line 10 overcome fill the spare container 9.

Fig. 2 shows an alternative embodiment. The components having a counterpart in Fig. 1 have the same reference numeral also in Fig. 2. The embodiment shown in Fig. 2 differs from that in Fig. 1 in that the breathing gas from the container 1 is supplied to a breathing device 4 downstream of the pressure reducing valve 7 of the breathing device 4. For this purpose, a further pressure reducing valve 12 is arranged at the end of the high-pressure hose 3 at or near the breathing device 4. This pressure-reducing valve 12 is arranged to keep the pressure in the line 11 at the pressure 11 independently of the pressure in the container 1 and the hose 3. about 10 bar. A non-return valve 13 is arranged between this pressure regulator 12 and the line 11, in order to prevent uncontrolled pressure drop in the breathing device 4 in the event of, for example, a rupture of the hose 3. Alternatively, the pressure reducing valve 12 and the non-return valve 13 may consist of one and the same component.

The embodiment shown in Fig. 2 has i.a. the advantage that connection to the breathing device 4 is easier to perform, since the connection takes place on the low-pressure side of the breathing device.

According to an embodiment not shown, fastening means are arranged in the vicinity of the downstream end of the hose. These fastening means are designed to be fastened to, for example, a harness worn by the diver or to the diving suit. The fastening means also have reliefs so that the gas-conducting coupling between the hose and the breathing device is not loaded even if large forces arise between the hose and the diver. With the help of the fastening means, the diver is thus held securely to the hose, so that the hose can be used as a lifeline to, for example, hoist an underwater diver through the water or pull a smoke diver out of the smoke-filled room. In this way, a separate lifeline is completely eliminated, which otherwise for safety reasons should always be included in a tubing dive system. Fasteners with reliefs can of course also be arranged at the upstream end of the hose to secure the hose / lifeline from loosening.

In the examples shown, the maximum container pressure is about 300 bar and the full length of the hose is about 100 m. To ensure a sufficient gas flow through the hose to the diver, the high pressure hose has an inner diameter of about 3 mm. 10 15 0 O c n o: 526 233 9 -ï.f: ¿I; ÄHÅM§Û If the hose as in the example is made entirely of Kevlar, the outer diameter of the hose can be kept as small as 9 mm. This should be compared with conventional systems, where the pressure in the hose is reduced from 300 bar to about 10 bar plus about 1 bar above the diver's ambient pressure and where the inner diameter of the hose, at the same hose length, is usually about 9 mm to provide sufficient flow . This minimum permissible inner diameter gives a hose outer diameter of about 22 mm. With the system according to the invention it is thus possible to considerably reduce the cross-sectional dimension of the hose, which entails the advantages described above.

The embodiments described above are given by way of example and it will be appreciated that the invention may be varied within the scope of the appended claims. For example, the pressurized container that supplies breathing gas can be replaced with, for example, a compressor or other gas source that supplies breathing gas at a high pressure, such as, for example, 300 or 700 bar.

Furthermore, the spare containers 9 shown in the figures and the shut-off valves 8 can be dispensed with if deemed appropriate.

The breathing device can be designed in a variety of ways, as long as the system includes pressure reducing means carried by the diver and which reduces the pressure in the hose to a suitable breathing pressure. The breathing device may, for example, comprise a pressure regulator or a nozzle which on the upstream side is connected to the high-pressure hose and which on the downstream side is connected to a helmet, mask or hood worn by the diver or to a diving watch in which the diver is located.

Claims (8)

10 15 20 25 30 526 233 1o Patent claim A system for supplying a diver with breathing gas, the system being an open system comprising an external gas source in the form of a pressurized container (1), which is intended to be located at a distance from the diver and which supplies breathing gas under high pressure, a breathing device (4, 4 ') intended to be carried by the diver and a hose (3) connecting the gas source to the breathing device, characterized in that the hose is of the high pressure type and of a pressure reducing valve (7, 12) arranged at or near of the breathing device (4) and which reduces the pressure downstream of the valve from the pressure prevailing in the hose (3), the breathing gas being passed through the hose from the gas source to the breathing device (4) or the pressure reducing valve (12) arranged below it under substantially the pressure from the gas source. System according to claim 1, wherein the hose (3) is designed to transport the breathing gas under a pressure of up to 700 bar, preferably up to 300 bar. A system according to claim 1 or 2, wherein the hose (3) is of, or contains carbon fibers, preferably Kevlar. A system according to any one of claims 1 to 3, wherein the pressure reducing valve (7, 12) reduces the pressure to about 10 bar. A system according to any one of claims 1 to 4, wherein the breathing device (4) comprises a breathing valve (6), a first pressure reducing valve (7) arranged upstream of the breathing valve (6) and a spare gas container (9 arranged upstream of the first pressure reducing valve (7). ) and wherein the hose (3) is connected to the breathing device (4) between the pressure reducing valve (7) and the spare gas container (9). 10 15 000000 0 0 000000 0 0 00 00 0000 0 0 0000 000 0 0000 0000 0 0000 0 0 0000 0 0 0 0 0000 00 0 0 0 0 0 0 0 00 0 0000 0 0 0 0 0000 0000 0 0000 0 526 255 11 A system according to any one of claims 1 to 4, wherein the breathing device (4) comprises a breathing valve (6), a first pressure reducing valve (7) arranged upstream of the breathing valve (6) and a spare gas container (9 arranged upstream of the first pressure reducing valve (7). ) and wherein the hose (3), via a second pressure reducing valve (12), is connected to the breathing device (4) between the breathing valve (6) and the first pressure reducing valve (7). A system according to any one of claims 1 to 4, wherein the breathing device comprises a pressure reducing valve and is designed to supply breathing gas to a helmet, mask or hood which is intended to be worn by the diver. A system according to any one of claims 1 to 7, wherein the hose (3) comprises means for attaching to the diver, so that the hose can form a lifeline