The present invention relates to a releasable sling device.
Occasionally, climbers or hikers experience accidents and a rescue operation must be performed in order to transport the person out from a steep mountain. Typically such an operation is performed by lowering a rescuer down from the top of the mountain. The rescuer will supply first aid to the person and put the person on a stretcher. A rescue helicopter is used to lift the stretcher up into the helicopter by means of a winch and a helicopter wire, while the rescuer is waiting. While waiting, the rescuer will for safety reasons be secured to the mountain by means of a climbing harness and a climbing bolt fixed to the mountain. Finally, the rescue helicopter is used to lift the rescuer up into the helicopter.
The rescuer now has to release the climbing harness from the bolt and connect the climbing harness to the helicopter wire that is lowered from the helicopter. The rescuer is under no circumstance allowed to secure the climbing harness to the climbing bolt and the helicopter wire at the same time, since this in reality will be to secure the helicopter to the mountain. The helicopter must have the freedom to maneuver if turbulence or severe weather conditions are present.
Hence, there will be situations where the rescuer is decoupled from both the helicopter and mountain bolt, and hence without fall protection.
There have been situations where the rescuer has passed out due to exhaustion, static electricity, injuries due to falling rocks etc, and where a separate rescue operation had to be performed for the rescuer. In such situations, it is preferable if the rescuer is secured to the helicopter wire, because the helicopter may then lift the rescuer into the helicopter.
US 2011/0042984 describes a device for securing rescue operations by helihoisting that comprises three attachment means, a first for the helicopter, a second for the rescuer and a third for the belay tether. Hence, it is here possible for the rescuer to be connected to the helicopter and to the belay tether at the same time. If the helicopter needs to maneuver away from the mountain, the connection between the device and the belay tether will be automatically released when a pulling force from the helicopter exceeds a predetermined threshold.
The disadvantage of this device is that it is rather complex with many relatively small parts, where snow and ice may prevent the device from functioning. It has also been discussed if this device will release when the helicopter is pulling in a direction perpendicular out from the mountain, which may be the case if the helicopter falls suddenly due to turbulence etc. Moreover, it is not possible to adjust the force required to release this device.
US 2004/050343 describes a method for providing fall protection for human and non-human loads in elevated environments. The load is equipped with a safety harness and lanyard apparatus having first and second lanyards attached thereto. The method includes the steps of: (1) connecting a safety lanyard apparatus to the load, said safety lanyard apparatus including first and second lanyards, each of said first and second lanyards having one end connected to the load and an opposing connectable free end, said first lanyard incorporating a means for automatic release of said connectable free end thereof in response to a predetermined tensional force; (2) connecting said first lanyard connectable free end to the aerial lift vehicle; (3) connecting said second lanyard connectable free end the structure, whereby the application of a tensional force, greater than or equal to a predetermined force, to said first and second lanyard ends results in activation of said means for automatic release thereby separating said connectable free end of said first lanyard from said safety lanyard apparatus thereby leaving said load suspended from said structure.
The main object of the present invention is to provide a device where it is possible for a person to be anchored to the helicopter and to the mountain at the same time, and where a safe release of the helicopter from the mountain is possible. Moreover, it is an object of the invention that the person should follow the helicopter upon such a release, i.e. the person should also be released from the mountain.
A further object is that the device should be reliable, it should be possible to perform a visual control of the status of the device and it should function even during bad weather conditions.
When a rescuer is lowered down from a helicopter, the rescuer never knows if there is a need to anchor himself to the mountain. A further object of the present invention is to provide a device where it is possible to do so in an easy way, without the need of a lot of extra equipment.
The present invention is defined in the dependent claim 1. Preferred embodiments are defined in the independent claims.
Embodiments of the invention will now be described in detail with reference to the enclosed drawings, where:
It is now referred to
It is now referred to
In the first embodiment, the first, second and third attachment devices 10, 12 and 14 are carabiner hooks. Alternatively, other types of safety hooks, links or connectors can be used.
The releasable sling device 1 further comprises a fall energy absorbing device 20 connected between the first attachment device 10 and the second attachment device 12. A first end 20a of the device 20 is connected to the first attachment device 10 and a second end 20b of the device 20 is connected to the second attachment device 12.
Hence, if the person is falling from the mountain when being attached to the helicopter wire AB, then the fall energy absorbing device 20 may absorb the fall energy and the risk of injuries is reduced. The fall energy absorbing device 20 is considered to be known per se and will not be described further in detail here. The fall energy absorbing device 20 may for example be a Petzl Absorbica (see http://www.petzl.com/en/Professional/Lanyards-and-energy-absorbers/ABSORBICA) or a corresponding product from Petzl or other producers.
The releasable sling device 1 further comprises a securing device 22. As indicated in
The releasable sling device 1 further comprises a releaser element 24 connected between the first attachment device 10 and the releasable connection device 30. The releaser element 24 may be any type of web, rope, wire etc. The releaser element is preferably flexible.
As indicated in
The releasable connection device 30 is configured to release the third attachment device 14 from the securing device 22 when the releaser element 24 is pulled away from the releasable connection device 30 with a predetermined force threshold.
It is now referred to
In the present embodiment, the releasable connection device 30 is a three-ring release system, as shown in
In the enlarged view of
A semi-rigid cable of the three-ring release system is indicated by reference number 34 in
As shown in
In the present embodiment, the second end 24b of the releaser element 24 comprises a loop 24c, through which the semi-rigid cable 34 is guided, as illustrated schematically in
The releasable connection device 30 further comprises a weak link device 36 connected between loop 24c and the second end 22b of the securing device 22, as indicated in
The releasable connection device 30 is configured to release the third attachment device 14 from the securing device 22 when the releaser element 24 is pulled in a direction towards the first attachment device 10.
The releasable sling device 1 is now used in the situation of
It is now referred to
The person is now released from the mountain, and the helicopter is free to maneuver away from the mountain, with the person hanging in the helicopter wire AB under the helicopter.
It is now referred back to
In a test of a prototype, one snap ring 36 have been used, having a predetermined snap threshold of 431 N (corresponding to a weight of 44 kg). Of course, the snap rings may be replaced by other types of weak links having other snap thresholds. It should be noted that in the final product, the plan is to use two such snap rings 36 in order to increase the snap threshold.
It is now referred to
The first attachment device 10 was connected to a crane, where a weight measurement device in the form of a weight cell was connected to the crane wire in order to measure the pulling weight from the crane. The weight cell was sampling measurements each 1/30 of a second. The pulling direction was ca 25° in relation to the vertical direction, out from the wall.
In the beginning, the person is hanging from the wall, and the pulling weight is gradually increasing.
In the area around sample number 485, there is a flattened area caused by the pulling weigh becoming equal to the person weight. The person is here gradually being lifted by the crane.
As the pulling weight increases, the releaser element 24 is gradually pulled away from the releasable connection device 30.
When the pulling weight reaches about 143 kg, the snap rings 36 are snapping and the releasable connection device 30 is released. The person is now no longer attached to the wall, and the person is swinging back and forth under the crane. There are some fluctuations in the pulling weight which are gradually dampened around the person weight. The pulling weight of 143 kg corresponds to the sum of the person weight (ca 78 kg), the snap ring threshold (44 kg) and an additional weight of ca 21 kg assumed to be caused mainly by the pulling angle and friction.
Alternative embodiments
It should be noted that the helicopter A may be another type of elevating device, for example a lift, a crane, a pulley system etc. It should also be noted that the person B may be another type of objects, for example a load in the form of tools, building materials, a container etc. It should also be noted that the mountain C may be another type of structure, for example a tall building, a part of an offshore oil and/or gas platform, a part of a vessel etc.
In
It should be noted that the first end 24a of the releaser element 24 may be connected to the first end 20a of the fall energy absorbing device 20, i.e. in this case the releaser element 24 will be indirectly connected to the first attachment device 10.
In similar ways, it is possible that the first end 20a is connected to the first end 24a and hence the device 20 is indirectly connected to the first attachment device 10.
It should be mentioned that another type of connection element may be used between the first attachment device 10 and the second attachment device 12. It would be possible to use a web, a climbing rope, or other types of connection elements instead of the fall energy absorbing device 20. A fall energy absorbing device 20 could for example be connected between the helicopter wire and the first attachment device 10. Alternatively, during some operations, a fall energy absorbing device 20 is not required at all.
Number | Date | Country | Kind |
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20141160 | Sep 2014 | NO | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2015/072082 | 9/25/2015 | WO | 00 |