The present invention relates to an inflatable floatable unit for life-saving equipment comprising at least a first inflatable flotation tube layer having an upper and a lower side with a distance between the upper side and the lower side, a second inflatable flotation tube layer having an upper and a lower side with a distance between the upper and lower sides, the first and second flotation tube layers being adapted to be arranged substantially above each other so that the upper side of the first tube layer is opposite the lower side of the second tube layer, the inflatable tube layers extending circumferentially for providing a substantially ring-shaped area, and a bottom element adapted to provide a bottom to the substantially ring-shaped area.
The term “ring-shaped area” is, in this context, to be construed as the tubes defining the outer periphery of the life raft, i.e. the hull sides. The ring-shaped area is the area wherein the evacuated people are located while they are present in the life raft. The configuration of the ring-shaped area may be round, elliptic, rectangular, pentagonal, hexagonal, octagonal, or be otherwise shaped as long as the flotation layers completely surround the ring-shaped area.
In chapter III, SOLAS determines that certain types of vessels must carry life rafts on board which are automatically self-righting so that the life rafts upon inflation, in case the vessel is sinking, will automatically turn to the designed position when they inflate. The specific requirements applying to the function and testing of automatically self-righting life rafts are set out in the IMO resolution MSC.48(66) and MSC.81(70), according to which automatically self-righting life rafts should inter alia be self-draining. Furthermore, for all inflatable life rafts it is required that the bottoms of the life rafts shall be made with a type of insulation, and that the necessary bollard pull required to tow the rafts at a speed of 2 and 3 knots, respectively, must be determined by means of testing and be stated on the life raft certificate. The latter requirement results from the life rafts having to be towable from a sinking vessel by means of the MOB/FRC boats of the vessel or by the lifeboats. This means that the authority approving the evacuation equipment of the vessel must ensure that the lifeboats may exhibit the bollard pull required to tow the biggest life raft on the vessel. Especially in the case of large life rafts, a high bollard pull is required, meaning that the MOB/FRC boats must be designed with large engine powers in order to ensure compliance with the requirements.
Hence, there is a need for an inflatable floatable unit which meets all the above statutory requirements as well as other requirements.
It is an object of the present invention to wholly or partly overcome the above disadvantages and drawbacks of the prior art. More specifically, it is an object to provide an improved inflatable floatable unit, which is self-draining, which has a low bollard pull as well as a bottom of the inflatable unit which is isolated from direct contact with the seawater.
The above objects, together with numerous other objects, advantages, and features, which will become evident from the below description, are accomplished by a solution in accordance with the present invention by an inflatable floatable unit for life-saving equipment comprising at least a first inflatable flotation tube layer having an upper and a lower side with a distance between the upper side and the lower side, a second inflatable flotation tube layer having an upper and a lower side with a distance between the upper and lower sides, the first and second flotation tube layers being adapted to be arranged substantially above each other so that the upper side of the first tube layer is opposite the lower side of the second tube layer, the inflatable tube layers extending circumferentially for providing a substantially ring-shaped area, and a bottom element adapted to provide a bottom to the substantially ring-shaped area, wherein the bottom element comprises a first bottom layer and a second bottom layer, both bottom layers substantially covering the entire ring-shaped area, the first bottom layer being connected with the inflatable unit between the first and second flotation tube layers, the second bottom layer being connected with the lower side of the first flotation tube layer, and both bottom layers being connected with each other at least at a centre point of the ring-shaped area, the first and second bottom layers having a mutual distance at the centre point being less than the distance between the upper and lower sides of the first flotation tube layer so that at least the second bottom layer has an inclined extension from the lower side of the first flotation tube layer to the centre point.
Hereby, a floatable unit is obtained where the bottom is elevated in relation to the sea level, so that the bottom will not be in contact with the sea even when the evacuated persons by means of their weight force the bottom downwards. Thus, it is avoided that the evacuated persons present in the floatable unit will be directly cooled by the sea, hence minimising the risk of hyperthermia in the evacuated persons. Furthermore, by inclining the second bottom layer, the overall resistance coefficient (i.e. Cd) of the floatable unit in the water is reduced considerably in relation to other floatable units having an elevated bottom, and thereby also the towing force or bollard pull of the floatable unit is reduced. It is then possible to tow the floatable unit away from the vessel or ship with less force, allowing smaller boats having less power to assist in such towing. Additionally, an inflatable floatable unit is obtained which fulfil the statutory requirements and which is still inexpensive to manufacture.
In one embodiment, the first bottom layer may have an inclined extension from the upper side of the first flotation tube layer to the centre point, so that fluid present inside the floatable unit may flow towards the centre point, the inclined extension being less steep than the inclined extension of second bottom layer.
In another embodiment, a drain may be arranged at the centre point between the first and second bottom layers so that fluid present inside the floatable unit can be drained out of the floatable unit. Hereby, it is possible to drain the floatable unit so that the floatable unit becomes dry, and consequently the evacuated persons present inside the floatable unit may be kept dry, reducing the risk of hyperthermia to a minimum.
Further, the drain may have an inlet and an outlet, the outlet being positioned above sea level. Moreover, the drain may manually be closed for instance in circumstances where the floatable unit has been emptied from fluid.
Also, the drain may comprise a one-way valve.
Additionally, the first bottom layer may be above sea level.
Moreover, an area of the second bottom layer positioned around the centre point of the ring-shaped area may be positioned above sea level.
In one embodiment, the mutual distance between the first and second bottom layers at the centre point of the ring-shaped area may be at least 0.02 m, preferably above 0.05 m.
In another embodiment, the ring-shaped area may be divided into a plurality of sections, each section having a centre point at which the first and second bottom layers are connected, a drain being arranged in connection with each centre point.
Said sections may be defined by stiffening elements extending in a transverse direction of the inflatable floatable unit.
Moreover, a one-way valve may be arranged in the first bottom layer enabling air to escape from the space, for instance during packing of the floatable unit in a deflated state.
Further, an anti-vacuum system may be arranged in connection with the bottom element, enabling air to pass to and from a space between the first and second bottom layers. Hereby, it is obtained that air may pass into the space between the two bottom layers during the inflating of the floatable unit. Furthermore, the anti-vacuum system allows air to freely pass in and out of the space between the two bottom layers in an inflated state of the floatable unit and depending on the motions of the floatable unit on the water. The anti-vacuum system also ensures that water entering the unit during the inflating will not enter the space.
In one embodiment, the floatable unit may be arranged to be self-righting.
In another embodiment, ballast means may be arranged below the first flotation tube layer.
Furthermore, the inflatable tubes and/or bottom element may be made of a polymeric material, such as natural rubber (NR), polyurethane (PU), thermoplastic polyurethane (TPU), butyl rubber (BR), polyvinylchloride (PVC), polychloroprene (CR), polyethylene (PE), or a combination thereof.
The invention and its many advantages will be described in more detail below with reference to the accompanying schematic drawings, which for the purpose of illustration show some non-limiting embodiments and in which
All the figures are highly schematic and not necessarily to scale, and they show only those parts which are necessary in order to elucidate the invention, other parts being omitted or merely suggested.
The flotation tube layers 2, 5 extend circumferentially for providing a substantially ring-shaped area (not shown). The inflatable floatable unit 1 furthermore comprises a bottom element 8 adapted to provide a bottom to the substantially ring-shaped area. The bottom element 8 comprises a first bottom layer 9 and a second bottom layer 10, both bottom layers 9, 10 substantially covering the entire ring-shaped area. The first bottom layer 9 is connected with the inflatable floatable unit 1 between the first and second flotation tube layers 2, 5, and the second bottom layer 10 is connected with the lower side 4 of the first flotation tube layer 2. Both bottom layers 9, 10 are connected with each other at least at a centre point 11 of the ring-shaped area, and the first and second bottom layers 9, 10 have a mutual distance at the centre point 11 being less than the distance between the upper and lower sides 3, 4 of the first flotation tube layer 2 so that at least the second bottom layer 10 has an inclined extension from the lower side 4 of the first flotation tube layer 2 to the centre point 11.
The inflatable floatable unit 1 also comprises inflatable canopy support members 12 which extend upwards from one side of the second flotation tube layer 5 to another side, substantially in a “flattened” circle shape. The inflatable support members 12 also extend slightly outwards so that the support members 12 have a larger width than the flotation tube layers 2, 5, allowing the inflatable floatable unit 1 to be self-righting, i.e. the inflatable floatable unit 1 is capable of turning itself to the designed correct position (the first flotation tube layer 2 closest to the water), even though it is being inflated upside down. Since the support members 12 have a larger width than the rest of the inflatable floatable unit 1, the design and buoyancy of the support members 12 will facilitate the turning of the inflatable floatable unit 1 when it is placed upside down in the water.
In
Furthermore, a drain 14 is arranged at the centre point 11 between the first and second bottom layers 9, 10 so that fluid present inside the floatable unit 1 can be drained out of the floatable unit 1. The drain 14 will be described in more detail in connection with
Below the first flotation tube layer 2, ballast means 15 is arranged around the extension of the tube layer 2. The ballast means 15 may for instance be bags having holes so that water may flow into the bag when the bag is submerged in the water. Hence, the bag is filled with water, allowing the bag to function as ballast for the floatable unit 1.
In
Further an anti-vacuum system 35 is shown, which comprises anti-vacuum tubes arranged along the periphery of the bottom element, said anti-vacuum tubes preferably being rubber tubes having a diameter of approximately 10 cm and being elevated approximately 30 cm from the bottom in such a manner that a vacuum cannot be established beneath the inflatable floatable unit. The anti-vacuum system also secures that air may pass between the first and second bottom layers 9, 10 during the inflating of the inflatable unit. At the same time it secures that no water will be able to flow into the space 31 between the two bottom layers 9, 10.
In connection with the first bottom layer 9 an additional one-way valve 30 is arranged for letting air out of the space 31 between the first and second bottom layers 9, 10. Hereby, packing of the deflated unit is facilitated.
Although the invention has been described in the above in connection with preferred embodiments of the invention, it will be evident for a person skilled in the art that several modifications are conceivable without departing from the invention as defined by the following claims.
Number | Date | Country | Kind |
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2011 70257 | May 2011 | DK | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2012/059565 | 5/23/2012 | WO | 00 | 11/22/2013 |
Publishing Document | Publishing Date | Country | Kind |
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WO2012/160081 | 11/29/2012 | WO | A |
Number | Name | Date | Kind |
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2399494 | Manson et al. | Apr 1946 | A |
3843983 | Tangen | Oct 1974 | A |
4462331 | McCrory | Jul 1984 | A |
4517914 | Geracitano | May 1985 | A |
4828520 | Baughman et al. | May 1989 | A |
5733158 | Higginbotham et al. | Mar 1998 | A |
6206743 | Martin | Mar 2001 | B1 |
Number | Date | Country |
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9702177 | Jan 1997 | WO |
9730891 | Aug 1997 | WO |
Entry |
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International Searching Authority, Search Report and Written Opinion issued in corresponding International Application No. PCT/EP2012/059565 dated Aug. 1, 2012, 9 pages. |
Number | Date | Country | |
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20140087610 A1 | Mar 2014 | US |