The present invention relates generally to a fall arrest device, and more particularly to a fall arrest device having a dual locking system.
Nowadays, buildings are built higher and higher, so that the safety risks that a builder, a worker cleaning an exterior wall, and a worker painting the exterior wall takes are increased. Therefore, the worker who works at a high place needs to use a safety device equipped with a fall arrest device. By fixing the fall arrest device to a fixed place and tightening the safety belt connected to the fall arrest device to the worker, the fall arrest device could prevent the worker from falling from height and ensure the safety of the worker.
A conventional fall arrest device includes a rotating drum, a safety belt, and a braking device, wherein an end of the safety belt is connected to the rotating drum and winds around the rotating drum. The braking device includes a braking plate, a braking part, and a stopper. The braking plate connected to the rotating drum rotates simultaneously with the rotating drum. The braking part is pivotally connected to the braking plate, so that a centrifugal force generated when the braking plate rotates rapidly leads the braking part to swing outwardly to engage with the stopper, thereby stop a rotation of the rotating drum. When the worker working at height falls accidentally, the braking device could immediately lock to stop the rotation of the rotating drum, thereby preventing the worker from falling.
However, most of the conventional fall arrest devices only have one single set of braking parts. When the braking part is rotated to different positions (such as the highest point or the lowest point), a gravitational force of the braking part or resilience for pulling the braking part could offset the centrifugal force of the braking plate, so that the braking part is unable to engage with the stopper and the rotating drum could keep rotating to allow the worker to fall. In such a situation, the worker can still be hurt due to the fall.
Additionally, the worker usually works at a place full of dust. Dust easily adheres to the fall arrest device, especially to a pivot site of the braking part. The braking part may be unable to swing outwardly resulting from the pivot site of the braking part being stuck, so that the rotation of the rotating drum cannot be stopped in time.
To avoid the fall arrest device being affected by dust, a fall arrest device with a shell for isolating the dust is developed. However, the isolating effect of the shell is limited. The dust can adhere to the safety belt exposed outside, and the dust can enter into the shell when the safety belt outside is retracted back to the shell. After the dust enters into the shell, the dust can adhere to the pivot site of the braking part such that the braking part gets stuck.
In view of the above, a primary objective of the present invention is to provide a fall arrest device, wherein a user could pull a safety belt of the fall arrest device before use, and oscillations of pawls caused by pivoting could inform the user that the pawls are not stuck and can function normally. The fall arrest device provided by the present invention includes a plurality of pawls. When the pawls rotate to the different positions, such as the highest point or the lowest point, a force that make the pawls tilt or the gravitational force of the body portion could be in the same direction with a centrifugal force. Either the force that makes the pawls tilt or the gravitational force of the body portion and the centrifugal force could jointly lead the pawls to tilt, so that each of the pawls could indeed engage the braking device to stop the rotation of the rotating member, thereby stopping or decelerating speed of falling to save the life of the user.
The present invention provides a fall arrest device including a frame, a rotating member, and a braking device. The frame has a first arm and a second arm. The rotating member is pivotally connected to the frame and located between the first arm and the second arm. The main body has a mounted portion and a receiving portion. The receiving portion is adapted to be winded up by a flexible long strip body. Each of the plurality of pawls has an abutting portion and a pivot, wherein the pawls are pivotally connected to the mounted portion via the pivot. When a rotation speed of the rotating member is greater than or equal to a predetermined rotation speed, the abutting portions of the pawls pivot from a first position to a second position. When the pawls are in the second position and rotate as the rotating member rotates, the abutting portions of the pawls move along a rotational pathway. When the pawls are in the second position and rotate as the rotating member rotates, the abutting portions of the pawls move along a rotational pathway. The braking device has a protrusion and is engaged with the first arm via the protrusion, wherein the braking device is located between the first arm and the mounted portion of the rotating member. The braking device further includes a plurality of abutted portions which are disposed on the rotational pathway of the abutting portions in the second position, so that the abutted portions could be abutted by the abutting portion to stop a rotation of the rotating member. Each of the pawls further includes a body portion which is located at a side of the pivot, and the abutting portion is located at another side of the pivot which is opposite to the side with the body portion. When the rotation speed of the rotating member is smaller than the predetermined rotation speed, the body portion of each of the pawls touches a portion of a periphery of the plurality of abutted portions and swings as an outer diameter of the abutted portion of the braking device changes.
With the aforementioned design, the user could pull the safety belt of the fall arrest device before use, and the oscillations of the pawls caused by pivoting could inform the user that the pawls are not stuck and could function normally. The fall arrest device provided by the present invention includes the plurality of pawls. When the pawls rotate to the different positions, such as the highest point or the lowest point, the force that make the pawls tilt or the gravitational force of the body portion and the centrifugal force. Either the force that makes the pawls tilt or the gravitational force of the body portion and the centrifugal force could jointly lead the pawls to tilt, so that each of the pawls could indeed engage the braking device to stop the rotation of the rotating member, thereby stopping or decelerating speed of falling to save the life of the user.
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
Referring to
The frame 10 has the first arm 12 and a second arm 14. The rotating member 20 is pivotally connected to the frame 10 and is located between the first arm 12 and the second arm 14.
The rotating member 20 includes a main body 21 and a plurality of pawls 22, wherein the main body 21 has a mounted portion 212 and a receiving portion 214. The receiving portion 214 is adapted to be winded up by a flexible long strip body (not shown). Each of the plurality of pawls 22 has an abutting portion 222 and a pivot 221, wherein the pawls 22 are pivotally connected to the mounted portion 212 via the pivot 221. When a rotation speed of the rotating member 20 is greater than or equal to a predetermined rotation speed, the abutting portions 222 of the pawls 22 pivot from a first position to a second position. When a rotation speed of the rotating member 20 is smaller than the predetermined rotation speed, the abutting portion 222 of each of the pawls 22 does not constantly abut against one of a plurality of abutted portions 302 of the braking device 30, so that the pawl 22 is in an unlocked state.
The braking device 30 has a protrusion 31 and is engaged with the first arm 12 via the protrusion 31, wherein the braking device 30 is located between the first arm 12 and the mounted portion 212 of the rotating member 20. When the pawls 22 are in the second position and rotate as a rotation of the rotating member 20, the abutting portions 222 of the pawls 22 move along a rotational pathway. The braking device 30 further includes the plurality of abutted portions 302 which are disposed on the rotational pathway of the abutting portions 22, so that the abutted portions 302 can be abutted by the abutting portion to stop the rotation of the rotating member 20.
As illustrated in
When the rotation speed of the rotating member 20 is smaller than the predetermined rotation speed, the body portion 224 of each of the pawls 22a, 22b touches a portion of a periphery of the plurality of abutted portions 302 and swings as an outer diameter of the abutted portion 302 of the braking device 30 changes.
The pawls 22a, 22b are symmetrically disposed on a surface of the mounted portion 212, so that the pawls 22a, 22b are symmetrical to each other about a center of the rotating member 20. In practice, a number of the pawls 22 could more than two, and the pawls 22 are arranged at an equal interval around the center of the rotating member 20. In such way, the pawls 22 could form a regular polygon and the center of the rotating member 20 is a center of gravity of the regular polygon.
In the current embodiment, a main body of each of the pawls 22a, 22b includes the body portion 224 and the abutting portion 222, and each of the pawls 22a, 22b includes an elastic member 226, wherein an end of the elastic member 226 is fixed to the main body of each of the pawls 22a, 22b, and another end of the elastic member 226 is fixed to the mounted portion 212 of the rotating member 20. Additionally, in the current embodiment, the end of the elastic member 226 is fixed to the body portion 224 of the main body of each of the pawls 22a, 22b, and the another end of the elastic member 226 is fixed to the mounted portion 212 of the rotating member 20, so that the body portion 224 is located between the pivot 221 and the elastic member 226. When the rotation speed of the rotating member 20 is smaller than the predetermined rotation speed, the elastic member 226 makes the body portion 224 of each of the pawls 22a, 22b touches a portion of the periphery of the abutted portions 302, and the body portion 224 swings as the outer diameter of the abutted portions 302 of the braking device 30 changes.
Additionally, when each of the pawls 22a, 22b swings as the diameter of the abutted portions 302 changes, the elastic member 226 provides each of the pawls 22a, 22b a resilience for swinging back, thereby avoiding the body portion 224 of each of the pawls 22a, 22b to repeatedly hit the periphery of the abutted portions 302 of the braking device 30, leading to the damage of the fall arrest device 1. The elastic member 226 provides an upward tension to the body portion 224 of the pawl 22b which is located at a lower part of the rotating member 20 for preventing the body portion 224 of the pawl 22b from dropping down to make the abutting portion 222 of the pawl 22b abuts against the abutted portion 302 of the braking device 30, thereby leading to an abnormal stop when the rotation speed of the rotating member 20 is smaller than the predetermined rotation speed.
As illustrated in
As illustrated in
Therefore, when the rotation speed of the rotating member 20 is smaller than the predetermined rotation speed, the body portion 224 of the pawl 22a located above hits one of the abutted portions 302 to tilt in a direction away from the protrusion 31 (namely upwardly) and to resist a gravitational force of the body portion 224 in a downward direction. Compare to the pawl 22b located lower, a movement of the body portion 224 of the pawl 22a located higher generated by hitting one of the abutted portions 302 is greater than a movement of the body portion 224 of the pawl 22b located lower generated by hitting one of the abutted portion 302, as illustrated in
In such way, in the current embodiment, the fall arrest device 1 could avoid malfunction resulting from dust and sand stuck in the pawls 22a, 22b to enhance a safety and a reliability of the fall arrest device 1. Additionally, in a normal situation, the body portion 224 of the pawl 22a located above touches a portion of the periphery of the abutted portions 302 and swings as an outer diameter of the portion of the abutted portions 302 of the braking device 30 changes. The body portion 224 of the pawl 22b located below touches another portion of the periphery of the abutted portions 302 and swings as an outer diameter of the another portion of the abutted portions 302 of the braking device 30 changes. When the rotation speed of the rotating member 20 is greater than or equal to the predetermined rotation speed, the body portion 224 of the pawl 22a located above collides a portion of the periphery of the abutted portions 302 to tilt in the direction away from the protrusion 31 and to resist the gravitational force of the body portion 224 in a downward direction. At the same time, a force that makes the body portion 224 of the pawl 22a located above tilt in the direction away from the protrusion 31 and a centrifugal force of the rotating member 20 are in the same direction, and a sum of the force that makes the pawl 22a tilt and the centrifugal force is greater than the resilience provided by the elastic member 226 to the body portion 224 of the pawl 22a, thereby leading the body portion 224 of the pawl 22a located above to pop up. At this time, the abutting portion 222 of the pawl 22a located above is moved from the first position to the second position and abuts against one of the abutted portions 302 to stop the rotation of the rotating member 20.
On the other hands, the body portion 224 of the pawl 22b located below is pulled by a gravitational force which is in the same direction with the centrifugal force of the rotating member 20, and a sum of the gravitational force and the centrifugal force is greater than the resilience provided by the elastic member 226, thereby making the body portion 224 of the pawl 22b below pop up. At this time, the abutting portion 222 of the pawl 22b below abuts against one of the abutted portions 302 of the braking device 30 to stop the rotation of the rotating member 20. With such design, an abutment between the pawls 22a, 22b and the abutted portions 302 of the braking device 30 could be ensured to perform a braking or stopping function, thereby avoiding a user to fall and to endanger life.
In the current embodiment, the body portion 224 of each of the pawls 22a, 22b includes a roller 225, wherein the roller 225 is used to touch the periphery of the abutted portions 302 to make the body portion 224 smoothly move along the periphery of the abutted portions 302, thereby preventing the body portion 224 of each of the pawl 22a, 22b from repeatedly hitting the periphery of the abutted portions 302 of the braking device 30 to damage the fall arrest device 1.
With such design, the user could pull the safety belt of the fall arrest device before use, and the oscillations of the pawls caused by pivoting could inform the user that the pawl is not stuck and could function normally. The fall arrest device provided by the present invention includes the plurality of pawls. When the pawls rotate to the different positions, such as the highest point or the lowest point, the force that make the pawls tilt or the gravitational force of the body portion could be in the same direction with the direction of the centrifugal force to jointly lead the pawls to tilt, so that each of the pawls could indeed engage the braking device to stop the rotation of the rotating member, thereby stopping or decelerating speed of falling to save the life of the user.
It must be pointed out that the embodiment described above is only a preferred embodiment 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 | Name | Date | Kind |
---|---|---|---|
3760910 | Koshihara | Sep 1973 | A |
4520998 | Flaig | Jun 1985 | A |
6279682 | Feathers | Aug 2001 | B1 |
9132301 | Jones | Sep 2015 | B2 |
20090211848 | Parker et al. | Aug 2009 | A1 |
20120031701 | Jones | Feb 2012 | A1 |
20120118670 | Olson et al. | May 2012 | A1 |
20160096048 | Fegley | Apr 2016 | A1 |
20180015312 | Jones | Jan 2018 | A1 |
Number | Date | Country |
---|---|---|
211357505 | Aug 2020 | CN |
114306974 | Apr 2022 | CN |
2771076 | Mar 2018 | EP |
M421128 | Jan 2012 | TW |
M612644 | Jun 2021 | TW |
2016120614 | Aug 2016 | WO |
Entry |
---|
Search report for TW109147102, dated Jun. 1, 2021, Total of 1 page. |
English abstract for TWM421128, Total of 1 page. |
Search Report for CN202110016397.3, dated Sep. 26, 2022, Total of 2 pages. |
Translation of Abstract of CN211357505, Total of 1 page. |
Translation of Abstract of TWM612644, Total of 1 page. |
Translation of Abstract of CN114306974, Total of 1 page. |
Number | Date | Country | |
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20220273972 A1 | Sep 2022 | US |