The invention relates to a pulley device.
In mountaineering, when a fellow climber has fallen into a crevasse, or in a more general manner when a person is stuck on a rope strand, it is important to be able to lift the person in distress in order to improve his/her situation.
Pulley techniques are commonly used as they enable the force applied to be multiplied enabling a large weight to be lifted in an environment that is not always suitable for this.
The pulley technique commonly uses one or more pulleys enabling a mechanical advantage to he had, and a self-locking device to facilitate the operation.
This situation happens very rarely, but it is particularly stressful. This situation does in fact happen unexpectedly (falling into a crevasse, accident) and the person who has to provide assistance for the person in distress at the same time has to ensure his/her own safety and economise his/her energy in order to avoid making the situation even worse. When these extraordinary situations arise, the person to be rescued may quite often be injured or even unconscious which makes him/her incapable of taking any part in his/her own rescue operation.
The person performing the rescue operation therefore has to have a perfect mastery of the pulley technique and also enough self-control to handle this situation.
It is observed that a requirement exists to provide a pulley device that is ready-to-use and easily transportable.
This requirement tends to be met by means of a pulley device which comprises:
Other advantages and features will become more clearly apparent from the following description of particular embodiments of the invention, given for non-restrictive example purposes only and represented in the appended drawings, in which:
The pulley device comprises first and second fixing means 1a and 1b advantageously comprising and/or formed by first and second pulleys. First pulley 1a is designed to be mechanically connected to a fixed point. Second pulley 1b is designed to be mechanically connected to the person to be rescued.
In a first situation, first pulley 1a is connected directly or indirectly to a fixed relay or point. Second pulley 1b is connected to the rope which is securing the person to be rescued. In this configuration, the person to be rescued is lifted by pulling on the rope which is securing him/her. This scenario can occur when the person has fallen into a crevasse or when a second climber is blocked.
In a second situation, first pulley 1a is connected directly or indirectly to a relay by means of the rope which initially secures the person to be rescued. Second pulley 1b is connected directly or indirectly to the person to be rescued. The person to be rescued is then supported by the pulley device which enables displacement of the person to be rescued to be organised for example on another rope.
The two situations indicated above are given for example purposes. Other situations can be envisaged.
First pulley 1a comprises a first sheave 2a and preferably a first set of at least two sheaves 2a mounted side by side. Second pulley 1b comprises a second sheave 2b and preferably a second set of at least two sheaves 2b also mounted side by side. What is meant by mounted side by side is that the two sheaves are laterally offset along the axis of rotation of the two sheaves. In advantageous manner, the pivot-pins of sheaves 2a and 2b are coaxial. It can also be envisaged to provide for the two sheaves 2a and/or 2b not to share the same axis and for them to be perpendicularly offset with respect to the axis of rotation, but this configuration is less advantageous as it is less compact. What is meant by sheave is a wheel with a groove, i.e. the mobile part in which a rope is wound.
The two pulleys 1a and 1b are connected by means of a rope 3 or a wire connector. Rope 3 is advantageously fixed to one of the pulleys 1 to achieve a gain in compactness so that the fixed connection on the fixing means defines one end of the rope. Advantageously, the rope is knotted to an aperture of one of the pulleys. In preferential manner, the aperture is made in a fixed flange-plate of the pulley.
Rope 3 passes through the sets of sheaves 2. The path taken by rope 3 is such that it moves alternately from one of the fixing means to the other fixing means. In the embodiment illustrated in
Rope 3 can take any path between the different sheaves so long as a pull on rope 3 translates into a movement of the two pulleys 1a and 1b towards one another. In this way, a pull exerted on rope 3 results in the two pulleys 1a and 1b being moved towards one another.
In advantageous manner, first and/or second pulley 1a and 1b comprise a self-locking part 4. Self-locking part 4 is configured to allow the two pulleys 1a and 1b to move towards one another and to prevent them from moving away from one another. In this way, a pull exerted on rope 3 will result in movement of the second pulley with respect to first pulley 1a which enables for example the person to be rescued to be lifted. If the rescuer lets go of rope 3 deliberately or involuntarily, the distance between the two pulleys 1a and 1b is maintained so long as self-locking part 4 is not deactivated.
In a particularly advantageous embodiment illustrated in
In a preferential configuration, first and second pulleys 1a and 1b comprise a pass-through opening 5a/5b for a karabiner (not represented) to pass through. This configuration is particularly advantageous as it enables the karabiner to be changed quickly for another karabiner having a size and/or shape that is more suitable for the specific requirements of the user. As a variant, it is also possible to provide an attachment system fitted on the pulleys, but this configuration is less practical. The karabiner can be replaced by any other removable connector, for example a chain link, a shackle and possibly a strap.
As the sheaves are securedly fixed to the pulley, a single anchoring point is used for each of pulleys 1a/1b which enables a maximum efficiency to be had as the two groups of sheaves are facing one another. The path taken by rope 3 is then natural and devoid of any friction point.
The pulley device also comprises an enclosure 6. Enclosure 6 is configured to be fixed to first and second pulleys 1a and 1b. Advantageously, enclosure 6 is configured to be mounted in removable manner which allows access to the inside of the pulley device. Enclosure 6 is configured so as to cover the path of rope 3 between sheaves 2a/2b and to allow the end used to perform pulling of rope 3 to exit.
The pulley device being designed to only be used in exceptional cases, the device is stored in a bag with the rest of the equipment. It has been discovered that enclosure 6 connecting the two pulleys 1a/1b and defining a sheath around the multiple paths of rope 3 prevents knots from forming. When the device is not used and in the absence of enclosure 6, it has been observed that knots may occur or that the different rope paths get tangled up. Under these conditions, the pulley device is unusable, and the different constituent parts then have to be disassembled which is particularly nerve-racking.
The use of enclosure 6 enables the arrangement of the pulley device and more particularly the different passages of rope 3 between sheaves 2a and 2b to be imposed.
As illustrated in
Enclosure 6 is advantageously flexible in another direction in order to enable the device to be easily stowed away. This freedom of movement in several directions does not hamper operation of the device while at the same time resulting in a drastic reduction of the risks of knots or tangling of the rope. In operation, the device is stretched taut and therefore linear.
This configuration for example enables the pulley device to be folded in order to save space. This also allows a torsion of the central part of the device when the latter is stored.
Enclosure 6 can be formed by a continuous material drilled with holes, by a material drilled with holes or by an assembly of these two materials. Enclosure 6 is advantageously made from a material of textile type which enables a good malleability with a negligible extra weight. Enclosure 6 is at least partially formed from a compressible material so as not to create a force opposing movement of the two fixing means towards one another when a pull is exerted on rope 3. The continuous material can be a fabric which enables the inside of the device to be protected and reduces the amount of dirt penetrating therein.
The material drilled with holes is for example a netting which enables wear of the rope inside the pulley device or of another element to be quickly detected for enhanced safety. Advantageously, the netting is made from a polymer material which facilitates drying, for example from a material of elastane type.
In a particularly advantageous configuration, the portion of enclosure 6 in contact with first and/or second pulleys 1a/1b is made from a more rigid material than that used to surround the multiple passages of rope 3. These portions in contact with the two pulleys 1a/1b advantageously form the ends of enclosure 6. Formation of a more rigid enclosure 6 at the ends enables a better operation of the device as it reduces the risk of deformation of the enclosure in the proximity of the sheaves which prevents undesirable blocking. In advantageous manner, the material forming the ends of the enclosure is a more rigid material, for example leather or an injected flexible plastic material, a coated fabric advantageously of PVC or polyurethane type. The increased rigidity can be obtained by providing a thicker material. Increasing the rigidity at the ends reduces the risks of the enclosure deforming around the sheaves and of jamming between a sheave and the rope.
Preferably, the portions in contact with fixing means 1a/1b are fixed to said fixing means which prevents undesired movement of enclosure 6 in the course of use and limits the risks of jamming in the sheaves. In a particular configuration, the portions in contact with pulleys 1a/1b comprise an aperture which operates in conjunction with aperture 5 present in pulleys 1a and 1b. In this way, the karabiner performs fixing of enclosure 6 with pulley 1a/1b. It is then possible to easily dismantle pulley 1a/1b by removing the karabiners. The extra weight is limited as there are no superfluous parts.
In the embodiment illustrated in
The pulley with integrated clamp presents reduced overall dimensions and an ease of use which are particularly advantageous.
As illustrated in
The two pivot-pins 8, 10 are fixed and advantageously extend in parallel manner to one another in a direction perpendicular to first flange-plate 7. Cylindrical roller 9 is mounted rotating freely around first pivot-pin 8 and is provided at its periphery with an annular groove for guiding rope 3 in the sheave.
Pivoting trigger 11 is provided with a braking surface designed to press rope 3 against roller 9 to form an integrated clamp in the space between the two pivot-pins 8, 10. The braking surface comprises a plurality of inclined dots designed to enhance the blocking effect of the rope when the clamp is active. A spring 12 biases trigger 11 towards roller 9.
A movable second flange-plate 13 is fitted rocking on the end of first pivot-pin 8 between a closed position and an open position. The open position of second flange-plate 13 enables rope 3 to be fitted, after trigger 11 has been removed to the inactive position, moving it away from roller 9. In the closed position of second flange-plate 13, rope 3 is wound in a loop on roller 9 and is held captive in the transverse gap arranged between the advantageously parallel flange-plates 7, 13.
First flange-plate 7 comprises a first aperture 14 located near to second pivot-pin 10 and above rotary roller 9. Second flange-plate 13 is provided with a second aperture 15, which comes into alignment with first aperture 14 when the two flange-plates 7, 13 are positioned in the closed position. The two apertures partly define aperture 5a. It is then possible to insert a removable connector therein to secure flange-plates 7, 13 in this position preventing any undesirable rocking.
A block 17 fixed to first flange-plate 7 is located above first aperture 14, occupying the transverse gap between flange-plates 7, 13. Block 17 is equipped with a latch 18 designed to swivel around a pivot-pin 19 between a locked position and a released position. Pivot-pin 19 of latch 18 is advantageously parallel to second pivot-pin 10 of trigger 11.
A movable third flange-plate 20 is fitted rocking, advantageously on the end of first pivot-pin 8 between a closed position and an open position. A second cylindrical roller 21 is fitted rotating freely preferably around first pivot-pin 8, and is provided at its periphery with an annular groove for guiding the rope. Second roller 21 separates flange-plates 7 and 20.
A block 22 fixed to first flange-plate 7 is located above first aperture 14, occupying the transverse space between flange-plates 7 and 20. In this configuration, each surface of first flange-plate 7 is equipped with a block.
The open position of third flange-plate 20 enables the rope to be fitted in place. In the closed position of third flange-plate 20, the rope is wound in a loop on roller 21, and is held captive in the transverse gap arranged between flange-plates 7, 20. The third flange-plate is advantageously deformed in the area collaborating with block 22 so as to limit the protuberance formed by the block and to reduce the overall dimensions of first fixing means 1a.
Third flange-plate 20 comprises a first aperture 23 located above rotary roller 21. First aperture 23 of third flange-plate 20 comes into alignment with first aperture 14 when the two flange-plates 7 and 20 are in the closed position. Apertures 14, 15 and 23 define aperture 5a. It is then possible to insert a removable connector therein to secure flange-plates 7, 13 and 20 in this position preventing any undesirable rocking.
In the embodiment illustrated in
As illustrated in
Pivot-pin 25 is fixed and extends in a perpendicular direction to first flange-plate 24. Cylindrical roller 26 is mounted rotating freely around first pivot-pin 25, and is provided at its periphery with an annular groove for guiding the rope.
A mobile second flange-plate 27 is mounted rocking on the end of first pivot-pin 25 between a closed position and an open position. The open position of second flange-plate 27 enables the rope to be fitted in place. In the closed position of second flange-plate 27, rope 3 is wound on roller 26 and is held captive in the transverse gap arranged between flange-plates 24 and 27.
First flange-plate 24 comprises a first aperture 28 located above rotary roller 26. Second flange-plate 27 is provided with a second aperture 29 which comes into alignment with first aperture 28 when the two flange-plates 24 and 27 are positioned in the closed position. The two apertures partially define aperture 5b. It is then possible to insert a removable connector therein to secure flange-plates 24 and 27 in this position preventing any undesirable rocking.
A mobile third flange-plate 30 is mounted rocking, advantageously on the end of first pivot-pin 25 between a closed position and an open position. A second cylindrical roller 31 is mounted rotating freely preferably around first pivot-pin 25, and is provided at its periphery with an annular groove for guiding the rope. Second roller 31 separates flange-plates 24 and 30.
Second flange-plate 30 is provided with an aperture 32, which comes into alignment with first aperture 28 when the two flange-plates 24 and 30 are positioned in the closed position. The three apertures 28, 29 and 32 define aperture 5b. It is then possible to insert a removable connector therein to secure flange-plates 24, 27 and 30 in this position preventing any undesirable rocking.
A block 33 fixed to first flange-plate 24 is located above first aperture 28, occupying the transverse gap between flange-plates 24 and 27. Advantageously, block 33 is configured to occupy the transverse gap between flange-plates 24 and 30. In this configuration, each surface of first flange-plate 24 is equipped with a block.
The second and third flange-plates 27 and 30 are advantageously deformed in the area cooperating with block 33 so as to limit the transverse protuberance formed by block 33 and to reduce the overall dimensions of second fixing means 1b.
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