The present invention is related to a fall protection device, and more particularly related to a rope based fall protection device which is adapted for operators working aloft.
In recent years, labor safety has gradually received attention. When working aloft, for instance, a worker is required to wear a fall protection device that includes a safety belt. The fall protection device is secured to a support, one end of the safety belt is secured to the fall protection device, and the other end of the safety belt is fastened to the worker. If the worker accidentally falls from heights, it ensures the worker's safety by preventing the worker from keeping falling or by slowing down the worker's falling speed.
A conventional rope based fall protection device includes a rotation unit, a volute spring, a brake unit, and a rope. The brake unit is connected to the rotation unit for restricting the rotation of the rotation unit. An end of the rope is connected to the rotation unit and wound around the rotation unit, while the other end thereof is fastened to a worker. An inner end of the volute spring is connected to the rotation unit to retract the rope for keeping the rope being wound around the rotation unit. When the worker moves at heights, the rope is pulled and released from the rotation unit, and simultaneously drives the volute spring, the brake unit and the rotation unit to rotate coaxially. If the worker accidentally falls from heights, the brake unit can immediately lock the rotation unit to slow down the rotation so as to prevent the rope from releasing from the rotation unit and stop the worker falling quickly.
However, when the worker moves at heights, the rope may have been completely released by the rotation unit. If the worker inadvertently falls at that time, the brake unit cannot be driven by the rope to slow down the rotation of the rotation unit. Although the other end of the conventional rope based fall protection device is tightly fastened to the worker, the worker is likely to be injured by the short free fall and the pulling force caused by the rope.
Therefore, the conventional rope based fall protection device still has the problem to be solved and room for improvement.
In view of the above, an objective of the present invention is to provide a rope based fall protection device which prevents a rope from completely releasing from a rotation unit when a worker moves at heights. If the worker inadvertently falls, a brake unit can be driven by an unreleased rope to slow down the rotation of the rotation unit, thereby preventing the worker from being injured by the short free fall and the pulling force caused by the rope.
To achieve the object mentioned above, the present invention provides a rope based fall protection device including a rotation unit, a brake unit, and a rope. The rope is wound around the rotation unit, and the brake unit is connected to the rotation unit and configured to restrict the rotation of the rotation unit. A first end of the rope is connected to the rotation unit, the first end of the rope rotates as the rotation unit rotates so that the rope is wound around the rotation unit, and a second end of the rope is a free end.
The rope from the first end to the second end at least sequentially includes a plurality of third rope loops, a first rope loop, and a second rope loop that are wound around the rotation unit. The first rope loop is between the plurality of the third rope loops and the second rope loop. And, a retaining ring includes a first retaining portion and a second retaining portion adjacent to each other. The first retaining portion is sleeved on the first rope loop and the second retaining portion is sleeved on the second rope loop, such that the rope forms a rope section which has a fixed length between the second retaining portion and the first end and is wound around the rotation unit. When the free end of the rope is pulled by an external force to release the rope wound around the rotation unit in a direction away from the rotation unit, the retaining ring is broken to release the rope section of the rope. By releasing the rope section of the rope, the rotation unit rotates and simultaneously drives the brake unit to rotate. The external force is greater than or equal to a pulling force generated by a user's free fall.
An advantage of the present invention is that the rope forms the rope section which has the fixed length between the second retaining portion and the first end and is wound around the rotation unit. If the worker falls accidentally from heights, the free end of the rope fastened to the worker is pulled by the external force, the retaining ring is broken due to the external force and the rope section of the rope is released. By releasing the rope section of the rope, the rotation unit rotates and simultaneously drives the brake unit to rotate so as to slow down the rotation of the rotation unit and prevent the worker from being injured by the short free fall and the pulling force caused by the rope.
The present invention will be best understood by referring to the following detailed description of some illustrative embodiments in conjunction with the accompanying drawings, in which
The following illustrative embodiments and drawings are provided to illustrate the disclosure of the present invention, these and other advantages and effects can be clearly understood by persons skilled in the art after reading the disclosure of this specification.
As illustrated in
A first end of the rope 20 is connected to the rotation unit 14, and the first end of the rope 20 rotates as the rotation unit 14 rotates so that the rope 20 is wound around the rotation unit 14. A second end of the rope 20 is a free end.
As illustrated in
It is worth mentioning that the rotation unit 14 of the rope based fall protection device 1 can be driven by a retracting force in a state of not being pulled by an external force, so that the rope 20 keeps retracted on the rotation unit 14. In practice, the rotation unit 14 can be connected to a volute spring (not shown in figure). The retracting force is provided by the volute spring and drives the rotation unit 14 to rotate, so that the rope 20 keeps retracted on the rotation unit 14. As illustrated in
In the current embodiment, the free end of the rope 20 is fastened to a user (such as a worker at heights). In a normal moving condition, the rope 20 forms the rope section which has the fixed length between the second retaining portion 30b of the retaining ring 30 and the first end of the rotation unit 14 and is wound around the rotation unit 14. That is, between the second retaining portion 30b and the first end, the rope section of the rope 20 keeps wound around the rotation unit 14 and not released from the rotation unit 14 under normal use. In other words, the third rope loops 20c, the first rope loop 20a, and the second rope loop 20b keep wound around the rotation unit 14 but not released from the rotation unit 14 under normal use. The rope 20 between the second retaining portion 30b of the retaining ring 30 and the second end fastened to the user can be released from the rotation unit 14 as the user moves; that is, the fourth rope loop 20d wound around the rotation unit 14 is freely released from the rotation unit 14 as the user moves. In
When the free end of the rope 20 is pulled by a strong external force and then the rope 20 wound around the rotation unit 14 is released in a direction away from the rotation unit 14, the retaining ring 30 is broken to release the rope section of the rope 20. By releasing the rope section of the rope 20, the rotation unit 14 rotates and simultaneously drives the brake unit 12 to rotate so as to slow down the rotation speed of the rotation unit 14. In the current embodiment, the strong external force is greater than or equal to a pulling force generated by a user's free fall.
In the current embodiment, when the retaining ring 30 is broken, the first retaining portion 30a and the second retaining portion 30b of the retaining ring 30 are separated from each other to release the rope section of the rope, so that the rotation unit 14 rotates and simultaneously drives the brake unit 12 to rotate.
In another embodiment, when the retaining ring 30 is broken, at least one of the first retaining portion 30a and the second retaining portion 30b of the retaining ring 30 is broken, causing the rope 20 disengaged from at least one of the first retaining portion 30a and the second retaining portion 30b to release the rope section of the rope 20, so that the rotation unit 14 rotates and simultaneously drives the brake unit 12 to rotate. For example, when the retaining ring 30 is broken, the first retaining portion 30a of the retaining ring 30 is broken, causing the rope 20 disengaged from the first retaining portion 30a; alternatively, when the retaining ring 30 is broken, the second retaining portion 30b of the retaining ring 30 is broken, causing the rope 20 disengaged from the second retaining portion 30b; or, when the retaining ring 30 is broken, the first retaining portion 30a and the second retaining portion 30b of the retaining ring 30 are broken, causing the rope 20 disengaged from the first retaining portion 30a and the second retaining portion 30b.
In another embodiment of the present invention, at least one of the first retaining portion 30a and the second retaining portion 30b of the retaining ring 30 has a slit (not shown in figures). When the retaining ring 30 is broken, the rope 20 is disengaged from at least one of the first retaining portion 30a and the second retaining portion 30b through the slit to release the rope section of the rope 20, so that the rotation unit 14 rotates and simultaneously drives the brake unit 12 to rotate. For example, when the first retaining portion 30a has the slit and the retaining ring 30 is broken, the rope 20 is disengaged from the first retaining portion 30a through the slit; alternatively, when the second retaining portion 30b has the slit and the retaining ring 30 is broken, the rope 20 is disengaged from the second retaining portion 30b through the slit; or, when the retaining ring 30 has two slits located respectively in the first retaining portion 30a and the second retaining portion 30b and the retaining ring 30 is broken, the rope 20 is disengaged through the two slits from the first retaining portion 30a and the second retaining portion 30b.
As illustrated in
In
The brake unit 12 includes three brake member 122 symmetrically disposed on the block plate 124 and includes a friction surface 126 located on the other side of the block plate 124 opposite the brake members 122. In the current embodiment, the friction pad 44 which is between the fixed member 42 and the friction surface 126 of the brake unit 12 is in close contact with the friction surface 126 of the brake unit 12.
As illustrated in
In
It can be seen that when the user fastened by the free end of the rope 20 accidentally falls from heights, the pulling force generated by the user's free fall causes the retaining ring 30 to break to release the rope section of the rope 20, so that the rotation unit 14 rotates and simultaneously drives the brake unit 12 to rotate to slow down the rotation speed of the rotation unit 14, thereby preventing the user from being injured by the short free fall and the pulling force caused by the rope 20.
As illustrated in
As illustrated in
As illustrated in
In addition, as illustrated in
With the design of the present invention, the retaining ring of the rope based fall protection device is sleeved on the rope, such that the rope forms the rope section which has the fixed length between the second retaining portion and the first end is wound around the rotation unit. If the worker falls accidentally from heights, the free end of the rope fastened to the worker is pulled by the external force, the retaining ring is broken due to the external force and the rope section of the rope is released. By releasing the rope section of the rope, the rotation unit rotates and simultaneously drives the brake unit to rotate so as to slow down the rotation of the rotation unit and prevent the worker from being injured by the short free fall and the pulling force caused by the rope.
It must be pointed out that the embodiments described above are only some embodiments of the present invention. All equivalent structures which employ the concepts disclosed in this specification and the appended claims should fall within the scope of the present invention.
Number | Date | Country | Kind |
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108122170 | Jun 2019 | TW | national |