The present disclosure pertains to a rope arresting apparatus for use with weighted ropes that more automatically assists the user in setting and releasing the apparatus. Previous designs in the industry often require the user to manually set an arresting mechanism in order to prevent free-fall of a weighted rope. This may be difficult for the user because he or she must continue to hold the weighted rope while the arresting mechanism is engaged. This complicates operation and reduces reliability of the arresting mechanism as well as its overall ease-of-use. The disclosed rope arresting apparatus addresses these and other problems of previous designs by aiding user efficiency.
Accordingly, an object of the disclosure is to provide a rope arresting apparatus for securing a weighted rope.
A further object of the disclosure is to provide a rope arresting apparatus that secures the rope independent of any user action or inaction.
A further object of the disclosure is to provide a rope arresting apparatus that releases the rope due to an action by the user.
A further object of the disclosure is to provide a rope arresting apparatus that is simple and convenient to use.
A further object of the disclosure is to provide a rope arresting apparatus that is simple and convenient to manufacture.
To achieve the above objects and others, a rope arresting apparatus comprises a cam portion, a pinching portion, and a pinching point. The pinching point is formed when the cam portion at the pinching position engages the rope against the pinching portion. Frictional contact at the pinching point secures the weighted rope and prevents further free fall.
a depicts an embodiment of the rope arresting apparatus forming a pinching point with the pinching portion at a first pinching portion position.
b depicts an embodiment of the rope arresting apparatus forming a pinching point with the pinching portion at a second pinching portion position.
The rope arresting apparatus is particularly suited for use in systems with weighted ropes, as typically found in lifting apparatuses for flags and the like. The rope arresting apparatus comprises at least a cam portion, a pinching portion, and a pinching point. The cam portion is configured to exert frictional force on the rope. The cam portion has a resting position and a pinching position. At the resting position, the cam portion is configured to be in frictional contact with the rope. At the pinching position, the cam portion is configured to cooperate with a pinching portion to form a pinching point when the cam portion at the pinching position engages the rope against the pinching portion.
In an exemplary embodiment depicted in
The cam portion of the current exemplary embodiment will now be described. The cam portion 10 is arranged to traverse the cam ramp 20 while remaining within the housing 2. The cam portion 10 has a width less than the inner width of the housing 2 but greater than the width of the cam ramp 20. In further embodiments, the cam portion may be an unsecured roller, tube, cylinder, or other shape suitable for traversing the cam ramp and for forming a pinching point with the pinching portion. In still further embodiments, the cam portion may include a set of surface protrusions of a predetermined size and length for exerting frictional force on the rope. The surface protrusions may be arranged in a manner that does not damage the rope while exerting frictional force. The cam portion surface protrusions may be arranged on the cam portion longitudinally, laterally, or in any orientation in between, to provide the appropriate frictional force for securing the rope. The surface protrusions themselves may be formed by knurling or other known manufacturing processes.
The cam ramp of the current exemplary embodiment will now be described. The cam ramp 20 is secured in the housing 2 and includes a proximate end 21 and a remote end 22 as shown in
The pinching portion of the current exemplary embodiment will now be described. The pinching portion 30 is mounted in the housing 2 so that a pinching point 40 is formed with the cam portion 10 when the cam portion 10 is at the pinching position. In the current embodiment, the pinching portion 30 is mounted in an oblong mounting point to facilitate installation. The pinching portion 30 of this embodiment is removed when attaching the housing 2 to the mounting surface and when inserting the rope into the rope arresting apparatus. The pinching portion 30 is then inserted into the oblong mounting point. The oblong mounting point provides extra lateral space so that the pinching portion 30 may be easily inserted without interfering with the other components of the rope arresting apparatus. In the current embodiment, the pinching portion 30 will always move to the far end of the oblong mounting point away from the cam portion 10 after the cam portion 10 has engaged with the rope and the pinching portion 30. In further embodiments, the pinching portion may be a pin, a roller, or other structures known in the art suitable for providing a corresponding surface to the cam portion to form a pinching point. In further embodiments, the mounting point may be formed in another shape that also provides adequate lateral space so that the pinching portion 30 may be easily inserted during assembly. In still further embodiments, the pinching portion may include a set of surface protrusions of a predetermined size and length that are arranged on the pinching portion longitudinally, laterally, or in any orientation in between. The pinching portion surface protrusions may be arranged to provide the appropriate amount of frictional force for securing the rope while not damaging the rope. The pinching portion surface protrusions may be formed by knurling or other known manufacturing processes.
The pinching point in the current exemplary embodiment will now be described. The pinching point 40 is where the cam portion 10 and the pinching portion 30 cooperate to secure the rope and prevent the rope from sliding further towards the weighted second end of the rope. The pinching point 40 is formed when the cam portion 10 is urged towards the weighted second end of the rope while tension on the second end of the rope is greater than tension at the first end of the rope, as depicted in
The mode of operation of the current exemplary embodiment will now be described. The cam portion 10 at the resting position remains in frictional contact with the rope at approximately the proximate end 21 of the cam ramp 20. The cam portion 10 maintains the resting position while tension on the weighted second end of the rope is less than or equal to tension on the first end of the rope. As tension on the weighted second end of the rope increases and becomes greater than tension on the first end of the rope, the rope's movement towards the weighted second end causes the cam portion 10 to transition from the resting position at approximately the proximate end 21 of the cam ramp 20, depicted in
Typical use of an exemplary embodiment of the rope arresting apparatus will now be described. A user will first apply tension to the first end of the rope so that tension on the first end of the rope is greater than tension on the second end of the rope. This tension applied by the user displaces the second end of the rope from an initial position. If the apparatus had previously secured the rope with the pinching point 40, the user applying appropriate tension to the first end of the rope will unform the pinching point 40 and release the rope, as described later.
The cam portion 10 remains in frictional contact with the rope as the user applies tension on the first end of the rope. After the user ceases to apply tension to the first end of the rope, tension on the second end of the rope may be greater than tension on the first end of the rope. The cam portion 10, which remained in frictional contact with the rope, is moved from a resting position, depicted in
A second exemplary embodiment will now be described. In the second exemplary embodiment, depicted in
The pivot point 50 connects the housing 6, the cam portion 15, and the pinching portion 35 together at a single point. The cam portion 15 and the pinching portion 35 are arranged to rotate around the pivot point 50 freely and independently while remaining attached to the housing 6.
The cam portion 15 is arranged to freely rotate about the pivot point 50, independent of the pinching portion 35. The cam portion 15 has a width less than the inner width of the pinching portion 35. The cam portion 15 includes a resting protrusion 16 arranged to allow the cam portion 15 at the resting position to maintain frictional contact with the rope. The cam portion 15 is at a resting position when the resting protrusion 16 rests against an inner surface of the housing 6, as depicted in
The pinching portion 35 is arranged to freely rotate about the pivot point 50, independent of the cam portion 15. The pinching portion 35 is arranged within the housing 6 and has an outer width less than the inner width of the housing 6. The pinching portion 35 rotates freely about the pivot point 50 until its edges make contact with the inner wall of the housing 6, defining the first pinching portion position, shown in
The pinching point in the current exemplary embodiment will now be described. The pinching point 45 secures the rope and prevents the rope from sliding further towards the weighted second end of the rope. The pinching point 45 is formed when the cam portion 15 is urged towards the weighted second end of the rope while tension on the second end of the rope is greater than tension at the first end of the rope. The pinching portion 35 is arranged to provide a corresponding inner surface 36 to the cam portion 15. The inner surface 36 provides a surface against which the rope may be secured by the cam portion 15, forming the pinching point 45. The inner surface 36 and the cam portion 15 are both configured to provide sufficient frictional force to secure the rope at the pinching point 45. The cam portion 15 is released when the user lifts the pinching portion 35 to a third pinching portion position so that frictional contact between the rope and the cam portion 15 is broken.
The mode of operation of the current exemplary embodiment will now be described. The cam portion 15 at the resting position remains in frictional contact with the rope. The pinching portion 35 will rotate counterclockwise and make contact with the rope and cam portion 15, as shown in
Typical use of a second exemplary embodiment of the rope arresting apparatus will now be described. A user will first apply tension to the first end of the rope so that tension on the first end of the rope is greater than tension on the second end of the rope. This tension applied by the user at the first end of the rope displaces the second end of the rope from a resting position. If the apparatus had previously secured the rope, the user must first release the rope, as described later.
The cam portion 15 remains in frictional contact with the rope as the user applies tension on the first end of the rope. After the user has positioned the second end of the rope or when the user otherwise ceases to apply tension to the first end of the rope, tension on the second end of the rope may be greater than tension on the first end of the rope. The pinching portion 35 rotates about the pivot point 50 and makes contact with the rope at the first pinching point position. The pinching point 45 is formed when the cam portion 15 frictionally secures the rope against the pinching portion 35. The movement of the rope towards the weighted second end rotates the cam portion 15 and the pinching portion 35 clockwise around pivot point 50. The pinching point 45 also rotates around the pivot point 50 with the cam portion 15 and the pinching portion 35. The pinching portion 35 continues to rotate until it makes contact with the housing 6, thus arriving at the second pinching portion position and preventing further rotation of the pinching portion 35. The rope is secured when the pinching point 45 is formed at the second pinching portion position.
The user may then release the rope from the pinching point 45 formed by the cam portion 15 at a pinching point and the pinching portion 35 at the second pinching portion position by lifting the rope. As the rope is lifted, the rope is pressed against the inner surface 36, causing the pinching portion 35 to move to a third pinching portion position. As the pinching portion 35 moves to the third pinching portion position, frictional contact between the rope and the cam portion 15 is broken, thus unforming the pinching point 45 and releasing the rope. The cam portion 15 then rotates about the pivot point 50 and returns to a resting position as depicted in
The principles, exemplary embodiments, and mode of operation of the rope arresting apparatus have been described in the foregoing specification. The disclosure is not to be construed as limited to the particular embodiments disclosed. The embodiments described herein are to be regarded as illustrative rather than restrictive. Modifications, derivations, alterations, and equivalents will be readily apparent to those skilled in the art and are included in the scope of the disclosure, the following claims, and preceding drawings.
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Number | Date | Country | |
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20140144729 A1 | May 2014 | US |