The invention relates to a self-clamping pulley descender with improved operation and more particularly to a self-clamping pulley descender able to support heavy loads in the form of a self-clamping pulley.
In mountaineering and other mountain activities, it is commonplace to have a clamping pulley that can be used in the event of a fall into a crevasse or to hoist any heavy load. Such a clamping pulley has to have a good efficiency when it is used as a pulley and also the ability to clamp the rope efficiently. Finally, the blocking pulley has to be lightweight and compact as the equipment is always at hand in the rucksack and is very seldom used.
In professional fields, and in particular for rescue operations, it is also necessary to have a clamping pulley at hand. The constraints on use are different as the pulley is used more regularly on much heavier loads. Furthermore, when performing a rescue operation, it is particularly advantageous to also have the possibility of lowering a victim who has previously been raised. It is advantageous to use a self-clamping descender with a pulley.
Under these conditions, the use of a clamping pulley such as the one presented in the document U.S. Pat. No. 9,120,654 is not suitable.
For professional use, it is known to use a pulley descender marketed under the tradename “MAESTRO” by the applicant. Such a descender comprises a pulley configured to only rotate in one direction around its spindle. The descender also comprises a rotary cam configured to clamp the rope when the movement of the rope is designed to generate a rotation of the pulley in the second direction of rotation.
In this configuration, the cam is in permanent or almost permanent contact with the rope so that the movement of the rope to generate the second direction of rotation of the pulley results in rotation of the cam to a clamping position.
The inventors observed that the speed of clamping varies in non-negligible manner with the surface quality of the rope and with the temperature of the descender.
An identical finding can be drawn from the pulley with descender marketed by the CMC company under the tradename CSR2 PULLEYS and presented in the document U.S. Pat. No. 7,419,138. This solution is not suitable as it does not enable heavy loads to be supported on the rope so that slipping may occur leading to heating of the pulley resulting in a drop of the friction coefficient between the pulley and the rope.
It is also apparent that the device marketed by the CMC company under the tradename MPD™ Multi Purpose Device does not provide a satisfactory result. Such a product is presented in the document U.S. Pat. No. 7,658,264 and has a pulley fitted movable around a spindle. The pulley is associated with a cam also fitted movable around the spindle. The pulley is configured so as to only allow one direction of rotation. When a traction is exerted on a rope strand in the second direction of rotation, this results in clamping of the pulley. The friction between the rope and pulley makes the pulley rotate until the rope is clamped by means of the cam. It is necessary to have a sufficient friction to counteract the force provided by a resistance spring that places the cam in a position preventing any clamping of the rope.
As indicated in the document U.S. Pat. No. 7,658,264, clamping of the rope is largely dependent on the friction between the rope and pulley which results in a large variability of the quality of clamping depending on the state of wear of the rope and of the pulley.
One object of the invention is to remedy these shortcomings by proposing a descender with a pulley that improves clamping of the rope, in particular by means of a configuration in which the variation of the friction coefficient presents a lesser importance in clamping of the rope.
For this purpose, the pulley descender comprises:
The self-clamping pulley descender is remarkable in that:
Advantageously, the spring is arranged to apply a force urging the cam towards the rope clamping area. In a preferential embodiment, the spring is arranged so as to move the first axis of rotation to a first position. Application of a force on the rope to obtain rotation of the pulley in the first direction of rotation results in the first axis of rotation being moved away from the first position.
In one development, the first axis of rotation is fitted movable in rotation with respect to the first flange around the second axis of rotation, the first axis of rotation being movable in the first direction of rotation and the second direction of rotation with respect to the second axis of rotation, clamping of the pulley in the second direction of rotation resulting in movement of the first axis of rotation and of the pulley in the second direction of rotation around the second axis of rotation.
Preferentially, the first axis of rotation is offset from the second axis of rotation so that application of a force on the rope to make the pulley rotate in the first direction of rotation generates a moment tending to move the cam away from the clamping area and relaxation of said force results in movement of the cam towards the clamping area.
In a preferential embodiment, when the pulley moves in the first direction of rotation, the pulley is in a first position that is farther away from the rope clamping area than a second position representative of clamping of the rope.
Advantageously, rotation of the pulley and of the first axis of rotation in the second direction of rotation results in rotation of the cam around the second axis of rotation to move the cam towards the clamping area.
It is advantageous to provide for the cam to be fitted in fixed manner on the second axis of rotation or on the first axis of rotation.
In preferential manner, the first flange comprises a first groove. The pulley and second axis of rotation are mounted on a support associated with a first pin passing through the first groove. Movement of the first pin along the first groove results in rotation of the support in the first direction of rotation. The descender is provided with a handle comprising a stop arranged to come into contact with the first pin, rotation of the handle in the first direction of rotation resulting in rotation of the first pin in the first direction of rotation.
It is also possible to provide for the first flange to comprise a second groove. The support is associated with a second pin passing through the second groove, a spring being attached to the first flange to move the second pin in the second direction of rotation.
In another embodiment, the spring is fitted around the second axis of rotation.
Preferentially, the pulley comprises a ratchet wheel associated with at least one clamp and with a blocking spring. The ratchet, the at least one clamp and the blocking spring are arranged to allow rotation of the pulley in the first direction of rotation and to prevent rotation in the second direction of rotation.
In a preferential embodiment, the pulley comprises a plurality of flat spots arranged in a groove of the pulley so as to define constrictions in the groove.
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:
Descender 1 comprises a pulley 2 that is fitted in rotary manner with respect to first flange 3. Pulley 2 rotates around a first axis of rotation A. Pulley 2 is fitted on a first shaft 26 which defines first axis of rotation A. Shaft 26 is illustrated in
Pulley 2 is configured to only rotate in one direction of rotation. In other words, pulley 2 presents an autorotation and is configured to rotate in a first direction of rotation noted + and is configured to be blocked when a rotation is to be performed in the second direction of rotation noted −, opposite from the first direction of rotation.
In this way, when the user pulls on a first strand of rope 4, pulley 2 rotates in the first direction of rotation. On the contrary, when the user pulls on the second strand of rope 4, pulley 2 is blocked.
In addition to being fitted movable in rotation around first axis of rotation A, pulley 2 is also fitted movable with respect to first flange 3 to move between first and second positions.
When the second strand of rope 4 (right-hand strand in
This embodiment is particularly advantageous on account of the fact that rope 4 is in direct contact with pulley 2 thereby increasing the contact surface used to move to the clamping position. The increased contact surface between pulley 2 and rope 4 facilitates movement of pulley 2 to the clamping position. Due to the fact that pulley 2 is stationary as it is unable to rotate in the second direction of rotation, the friction of rope 4 on pulley 2 is used to reach the threshold clamping position.
In configurations of the prior art, the pulley is only fitted movable in rotation around its spindle so that the tension applied on the second strand of the rope clamps the pulley. Once the pulley has been clamped, movement of the rope generates a friction force against a spring to move a cam and to reach the clamping position of the rope. As the cam has a small surface, it is more difficult to achieve a sufficient friction of the rope on the cam for the cam to reach the clamping position. It is also difficult to have a sufficient friction between the rope and pulley to counteract the effect of the spring and to ensure adequate triggering of clamping. If the force generated by the spring is too weak, this can clamp the rope inadvertently. It is also known to have a configuration without a cam with the pulley performing clamping of the rope. In the latter configuration, clamping is limited as the movement of the pulley spindle is necessarily small. The latter solution does not enable high clamping forces to be produced and is greatly dependent on the quality of the contact between the rope and pulley.
Movement of pulley 2 can be of any kind to reach the threshold clamping position. It is possible to use a translational movement, a rotational movement or a combination of these two movements. In particularly advantageous manner, a rotational movement is preferred as this enables the force applied on pulley 2 to be better controlled as regards the tension present in rope 4.
In the illustrated embodiment, first axis of rotation A is fitted movable in rotation with respect to first flange 3 around a second axis of rotation B different from first axis of rotation A. First axis of rotation A is movable in first direction of rotation + and in second direction of rotation − with respect to second axis of rotation B. Clamping of pulley 2 in second direction of rotation − results in movement of first axis of rotation A and pulley 2 in the second direction of rotation around second axis of rotation B so that the distance between pulley 4 and side wall 3a of first flange 1 decreases up to the threshold position where clamping takes place. On the contrary, rotation of pulley 2 can result in movement of first axis of rotation A away from a clamping position of rope 4.
To gain in efficiency when rotation of the pulley takes place, when pulley 2 moves in first direction of rotation +, pulley 2 is outside the second position and preferably in the first position that is farther from side wall 3a than the second position. In this way, when rotation of pulley 2 takes place, rope 4 does not have to overcome a high friction force which enables a high level of performance to be kept when hoisting a load fixed to the second strand. As illustrated in
The inner wall of the rope channel defines a semi-circle that corresponds to half of the pulley. The weight of the load to be supported is completely taken up by the pulley and the rope can run in the descender following rotation of the pulley in a semi-circle thereby preventing the formation of slipping areas and therefore of friction. The rope channel defines a semi-circle by means of the pulley. The rope is in contact with the pulley over half of the pulley. In advantageous manner, the outer wall of the pulley is devoid of overlap over more than half of the perimeter of the pulley thereby making it possible to have an almost total take-up of the force by the pulley. Take-up of the force by the pulley takes place whatever the position of the pulley between the first position and second position.
In comparison, document US 2014/0262611 proposes a configuration with a movable cam a part of the support wall of which is formed by a pulley so as to modulate the friction force according to the speed of translation of the rope. The rest of the support wall is formed by a friction area present on each side of a diameter of the pulley to provide the friction between the rope and clamping system. When the speed of translation is high, the pulley is clamped thus increasing the friction and resulting in rotation of the cam.
Descender 1 possesses a cam 5 or pad to perform clamping of rope 4 against side wall 3a of first flange 3. Rotation of pulley 2 and first axis of rotation A in the second direction of rotation results in a force inducing rotation of cam 5 around second axis of rotation B with a reduction of the distance between cam 5 and the clamping area until a threshold position representative of clamping of the rope is reached. Rotation of pulley 2 and first axis of rotation A in the first direction of rotation results in a force inducing rotation of cam 5 around second axis of rotation B with an increase of the distance between cam 5 and the clamping area to exit the clamping position of rope 4.
The use of a movable cam 5 distinct from pulley 2 and salient from pulley 2 ensures improved clamping of rope 4 between cam 5 and side wall 3a. Movement of pulley 2 moves cam 5 toward the clamping position thereby making it easier to achieve clamping of rope 4. Movement of pulley 2 advantageously enables cam 5 to be moved in order to increase the tension applied by cam 5 on rope 4 by moving the cam towards side wall 3a thereby making it easier to obtain a threshold friction force ensuring self-clamping of rope 4.
Cam 5 is fitted movable in rotation around a second shaft 26 that defines a second axis of rotation B distinct from first axis of rotation A. Cam 5 is fitted in rotary manner around second axis of rotation B so that the position of cam 5 with respect to the clamping area is linked to the position of first shaft 25.
As illustrated in
The offset between the two spindles A and B results in generation of a torque when the first strand of rope 4 or the second strand of rope 4 is pulled. It is particularly advantageous to use this torque to move cam 5 or to generate a force for the purposes of moving cam 5. As illustrated in
In a particular configuration, first axis of rotation A and second axis of rotation B are placed so that the weight of pulley 2 makes cam 5 leave the rope clamping position.
In a particular configuration, first axis of rotation A and second axis of rotation B are placed so that when the first rope strand is pulled, pulley 2 and cam 5 move away from the clamping position before pulley 2 starts to rotate around first axis of rotation A.
In an advantageous configuration, cam 5 is mounted fixed on first shaft 25, this configuration making it possible for example to have a rotation of cam 5 in identical manner to the rotation of second axis of rotation B.
It is also advantageous to provide an embodiment wherein first flange 3 comprises a first groove 6 and wherein the position of pulley 2 is represented by the position of an indicator in first groove 6. It is then possible to quickly determine whether clamping of rope 4 results from the position of pulley 2 or of another part. If the indicator operates in conjunction with a handle 12, the position of handle 12 provides an indication on the position of the indicator.
In advantageous manner illustrated in
Preferentially, first flange 3 defines a second groove 9. The position of pulley 2 with respect to first flange 3 is represented by the position of the second indicator in second groove 9. Support 7 is associated with a second pin 10 passing through second groove 9. It is particularly advantageous to use a spring 11 fixed to first flange 3 to move pulley 2 to the second position, i.e. to move second pin 10 to facilitate clamping on rope 4. In the illustrated embodiment, spring 11 is configured to move pulley 2 in second direction of rotation − and to urge towards the clamping position of rope 4.
It is particularly advantageous to provide for spring 11 to be fixed to the second indicator, here second pin 10, so as not to interfere with the rotation of pulley 2 and with running of rope 4.
In the embodiment illustrated in
It is particularly advantageous to provide for spring 11 to be fitted around second axis of rotation B in order to gain in compactness.
In a particular embodiment, descender 1 comprises a handle 12 as illustrated in
This embodiment is particularly advantageous when second pin 10 is associated with spring 11. Spring 11 is arranged to move pulley 2 to the clamping position.
Rotation of handle 12 from a standby position places stop 12a in contact with first pin 8. When handle 12 rotates, stop 12a presses on first pin 8 which then moves. Handle 12 exerts a force 12 opposing the force applied by the spring which moves pulley 2, and cam 5 if applicable. The stress applied on rope 4 decreases thereby enabling sliding of rope 4. Movement of handle 12 enables the distance between pulley 2/cam 5 and side wall 3a to be adjusted thereby enabling the intensity of the friction force and therefore the running speed of rope 4 in descender 1 to be adjusted.
In more general manner, it is advantageous to provide for spring 11 to move cam 5 to the clamping area, i.e. to move cam 5 to a clamping position of the rope so that, by default, cam 5 clamps rope 4 regardless of the intensity of the friction between rope 4 and pulley 2.
In this configuration, cam 5 is by default in a position clamping rope 4. By pulling on the first strand of rope 4, the torque generated opposes the spring thereby enabling movement of the pulley and movement of the cam. The cam no longer clamps the rope which can be pulled taking advantage of the rotation of the pulley to obtain a high level of performance when pulling.
In the embodiment illustrated in
Advantageously, pulley 2 comprises a plurality of flat spots 16 arranged in the groove of pulley 2 so as to define constrictions in the groove. These multiple reductions of the cross-section of the groove of pulley 2 form preferential friction areas when rope 4 has to slide along pulley 2. It is also possible to provide for the use of a smooth sheave or a faceted sheave. In one embodiment, the sheave can define a groove with a more or less pronounced V-shaped cross-section in order to define the friction force.
In advantageous manner, first flange 3 is associated with a second flange 17 that is fitted movable with respect to first flange 3. In advantageous manner, second flange 17 is fitted movable in rotation around a third spindle C. Rotation of second flange 17 enables descender 1 to be opened or closed as illustrated in
First flange 3 and second flange 17 each define a fixing opening 18. The two fixing openings 18 are placed facing one another so as to collaborate with a connector (not shown), for example a karabiner enabling descender 1 to be secured to a fixed point.
First flange 3 also defines a second fixing opening 19 for attaching a karabiner for example.
First flange 3 comprises a blocking stop 20 configured to prevent progression of second flange 17 to its closed position closing descender 1.
As illustrated in
In advantageous manner, cam 5 is fixed on support 7 by means of a fixing part 22 extending through first opening 6 to form first pin 8. Preferentially, fixing part 22 passes through support 7 until it reaches a second support 23. Second support 23 is fixed to first support 7. First support 7 and second support 24 are separated by pulley 2 and by cam 5. Cam 5 is fitted in fixed manner on support 7.
Preferentially, first pin 8 is surrounded by one or more bearings 24 to improve sliding in first groove 6.
Spindle A is advantageously defined by a shaft 25. Shaft 25 comprises a first through hole aligned with a first through hole of support 7 so as to be able to inserted in a second shaft 26 forming second axis of rotation B. In advantageous manner, second support 23 comprises a first hole aligned with the first hole of shaft 25 thus enabling rotation shaft 25, first support 7 and second support 23 to be fixed by means of second shaft 26.
In advantageous manner, shaft 25 also comprises a second through hole aligned with a second through hole of support 7 and possibly a second through hole of second support 23. A second rod forming pin 10 passes through the second through holes. The use of two series of through holes ensures that the movement applied on support 7 results in the same movement on shaft 25 and therefore on the first axis of rotation and on cam 5.
In a preferential embodiment, shaft 25 is separated from support 7 by a bearing 27 enabling rotation of shaft 25 with respect to support 7 to be improved thereby improving rotation of pulley 2 with respect to support 7.
Pulley 2 is of circular cross-section and presents a groove for rope 4 to run in. Pulley 2 is in the form of a ring in order to be able to fit first axis of rotation A in the centre of pulley 2. Pulley 2 advantageously defines a ratchet 13.
Ratchet 13 collaborates with clamps 14 fitted on shaft 25 and with springs 15 pressing on clamps 14, so as to offset clamps 14 to the outside and the teeth of ratchet 13.
In the illustrated embodiment, pulley 2 is mounted rotating by means of a bearing 21, for example a ball bearing inserted between pulley 2 and shaft 25. Shaft 25 defines first axis of rotation A and bearing 21 facilitates rotation of pulley 2 with respect to shaft 25.
The use of descender 1 can be described in the following manner. A self-clamping descender 1 according to one of the multiple embodiments described in the foregoing is provided. Rope 4 is fitted in descender 1.
The user pulls on the first strand of rope 4 which makes pulley 2 rotate in first direction of rotation +. The load attached to the second strand of rope 4 is hoisted.
The second strand of rope 4 is pulled to make pulley 2 rotate in second direction of rotation − which results in clamping of pulley 2. Pulley 2 moves in the direction of a side wall until clamping of rope 4 is achieved.
In the illustrated exemplary embodiment, the force applied on the second rope strand causes movement of support 7, here a rotational movement with a rotational movement of cam 5.
In a particular configuration, spring 11 moves support 7 to the clamping position so that descender 1 clamps rope 4 by default. When a tension is applied on the first strand of rope 4, pulley 2 moves so as to release clamping of rope 2 and allow rotation of pulley 2 and enhance the performance when hoisting the load present on the second strand of rope 4.
Once the tension on the first strand of rope 4 has been released, support 7 returns to the clamping position.
In the illustrated embodiment, the handle 12 is mounted movable around shaft 28 defining axis of rotation C.
Number | Date | Country | Kind |
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18 56877 | Jul 2018 | FR | national |
Number | Name | Date | Kind |
---|---|---|---|
6068242 | Kingery | May 2000 | A |
7419138 | Mauthner | Sep 2008 | B1 |
7658264 | Mauthner | Feb 2010 | B2 |
8596615 | Kommer | Dec 2013 | B2 |
9120654 | Chaumontet | Sep 2015 | B2 |
20140262611 | Oddou et al. | Sep 2014 | A1 |
20160296771 | Malcolm | Oct 2016 | A1 |
20190030376 | Malcolm | Jan 2019 | A1 |
Number | Date | Country |
---|---|---|
2 137 519 | Sep 1999 | RU |
2016164613 | Oct 2016 | WO |
Number | Date | Country | |
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20200031638 A1 | Jan 2020 | US |