JP2020044158A - Shock absorber for safety belt and fall stop equipment using the same - Google Patents

Abstract

To provide a shock absorber having a stable loading characteristic which is not influenced by a use environment at an emergency, and to provide compact fall stop equipment using the same.SOLUTION: In a shock absorber for a safety belt for alleviating an impact acting on a worker at an emergency via a belt 3, the belt 3 is wound around an external periphery of a spool 31 which is sandwiched by opposing bases 12 and rotatably held thereto, and locked to one end part of the spool 31 so that one lock end part 30b of a torsion bar 30 co-rotates. The other lock end part 30b of the torsion bar 30 is locked so as not to rotate to one base 12, and a shaft part 30a of the torsion bar 30 is twisted by a withdrawal force of the belt 3 from the spool 31 at the emergency, thus alleviating the impact.SELECTED DRAWING: Figure 2

Description

  BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a shock absorber for a safety belt, which is worn by an operator to prevent a fall when working at heights, and a fall-stopping device using the same.

  Safety belts worn by workers working on high places such as construction sites include a shock that acts on workers via lanyard straps and ropes when the fall is stopped in an emergency when the worker falls down accidentally. In general, a shock absorber for reducing the pressure is provided.

  As such a shock absorber, for example, as described in Patent Literatures 1 and 2 below, upper and lower belts woven with synthetic fibers such as nylon and polyester are overlapped, and the polymerized portion is woven with twine yarn. In a folded state, a cover is generally used, which is covered with a tube, and when an operator falls and an impact is applied to the belt, the warp yarns interwoven at the overlapping portion are sequentially cut to reduce the impact.

JP-A-58-220845 Registered Utility Model No. 3082515

  However, in the shock absorbers described above, the belt tends to stretch when the temperature or humidity is high, and the belt and yarn deteriorate due to long-term outdoor use. May not be mitigated as expected.

  In addition, when combined with a winder that prevents the strap from being pulled out in an emergency, the operator may feel bulky and troublesome.

  Therefore, an object of the present invention is to provide a shock absorber having a stable load characteristic that is not affected by the use environment in an emergency, and to provide a compact fall-stopping device using the same.

In order to solve the above-described problems, the present invention is provided in a safety band for a safety band that is provided to a worker who performs work at a high place, and that absorbs a shock acting on the worker in an emergency via a belt,
The belt is wound around the outer periphery of a spool rotatably held between opposed bases, and is locked at one end of the spool so that one locking end of a torsion bar rotates together. The other locking end of the torsion bar is locked so as not to rotate on one of the bases,
In an emergency, the pulling force of the belt from the spool causes the shaft of the torsion bar to be twisted, thereby reducing the impact acting on the worker.

In the shock absorber, the end of the belt is not fixed to the inside of the spool, but penetrates a radial through hole formed in the spool, and is double-wound around the outer periphery of the spool,
In an emergency, the belt may be simultaneously drawn in both directions from the spool as the spool rotates.

Further, a winder is provided integrally with the shock absorber, and the winder is urged in a winding direction so that the wound strap can be pulled out at any time, and in a case of emergency, the feeding of the strap is prevented by a lock mechanism. Safety device with a winder
A spool for winding the strap of the winder is sandwiched between opposed bases shared with the shock absorber, and is held rotatably.
The strap pin to which the end of the strap is fastened is held inside the spool, but does not become a rotation support shaft of the spool,
The strap is wound around the outer circumference from the strap pin via the inside of the spool.

  Further, the spool of the winder and the shock absorber is held in the thrust direction by being fastened with the opposed bases being maintained at an interval.

  In the shock absorber for safety belt according to the present invention, the impact is not reduced by the twist of the torsion bar made of a metal such as steel, but the impact is not relieved by the breakage of the entangled yarn interwoven with the overlapping portion of the belt. Since the load is relaxed, a stable load characteristic can be obtained according to the set value without being affected by the use environment.

  In addition, when the spool is combined with a winder rotatably held by an opposing base and integrated, a compact fall-stopping device that is not bulky can be configured.

Exploded perspective view of a first embodiment of a shock absorber for a safety belt according to the present invention. Perspective view showing the assembled state with the case on one side opened. Cross-sectional plan view in the middle part in the thickness direction Longitudinal side view with the case closed Cross-sectional plan view showing the state after the torsion bar is twisted Cross-sectional plan view in the middle part in the thickness direction showing another embodiment of the same spool Cross-sectional plan view showing the state after the torsion bar is twisted FIG. 7 is a perspective view showing an assembled state of the second embodiment of the shock absorber for a safety belt according to the present invention with one case opened. Cross-sectional plan view in the middle part in the thickness direction FIG. 2 is a perspective view showing an assembled state in which a case on one side is opened in the first embodiment of the safety device according to the present invention, in which a shock absorber and a winder are integrated. Cross-sectional plan view in the middle part in the thickness direction Longitudinal side view with the case closed FIG. 3 is a perspective view showing an assembled state of the second embodiment of the safety device for preventing a fall of a safety belt according to the second embodiment with one case opened.

  First, a first embodiment of a shock absorber will be described with reference to FIGS.

  As shown in FIGS. 1 to 4, this shock absorber has a configuration in which components are housed inside a pair of cases 41 and has hexagonal locking ends 30 b at both ends of a cylindrical shaft portion 30 a. The main components are a torsion bar 30 made of steel, a spool 31 around which the belt 3 is wound, and two plate-like bases 12 sandwiching the spool 31.

  The spool 31 is an integrally molded product formed by die-casting of an aluminum alloy, a zinc alloy, or the like. The spool 31 has flanges 31b at both ends of a winding drum 31a around which the belt 3 is wound around the outer periphery, and is fitted to the outer surface of the flange 31b. The portion 31c has a protruding shape. The outer periphery of the fitting portion 31c is a cylindrical surface having a smaller diameter than the flange 31b.

  An axial core hole 31d into which the torsion bar 30 is inserted with a gap is formed in the winding drum portion 31a. Inside one end (the lower end in FIGS. 1 and 4) of the core hole 31d, a locking recess 31e which is depressed in a hexagonal shape by bulging the end wall of the spool 31 outward is formed. 1 and the upper end in FIG. 4) are open.

  The locking end 30b on one side (lower in FIGS. 1 and 4) of the torsion bar 30 is fitted into the locking recess 31e, and the center of one end of the spool 31 (the center of the lower end in FIGS. 1 and 4). Part).

  The bobbin trunk 31a has a through hole 31f extending from one side of the outer periphery to the other side of the outer periphery via the core hole 31d. The width of the entrance portion at one end of the core hole 31d is set to be slightly larger than the diameter of the belt pin 32 to which the end of the belt 3 is folded and fixed, and the width on the communication side with the core hole 31d is larger than the diameter of the belt pin 32. Is also set small.

  Then, the belt 3 is inserted into the inside of the spool 31 from the entrance of one end of the inner through hole 31f, and the folded terminal is stopped from the spool 31 with the folded terminal fastened to the belt pin 32, and the core hole 31d After being pulled out from the other end of the through hole 31f through the inside of the inside of the winding hole 31f, it is wound around the outer periphery of the winding drum 31a.

  The base 12 is made of steel harder than the spool 31, has a round hole-shaped fitting hole 12 c, and fitting portions 31 c at both ends of the spool 31 are fitted with the two bases 12 via the frame ring 33. The spool 31 is rotatably held by being fitted into the mating hole 12c.

  One (upper in FIGS. 1 and 4) base 12 has a receiving plate portion 12d protruding from one end side so as to cover the fitting hole 12c, and the receiving plate portion 12d has a hexagonal locking hole 12e. Is formed, and an end plate member 34 is attached with a screw 35 so as to cover the locking hole 12e.

  The other (upper in FIGS. 1 and 4) locking end portion 30b of the torsion bar 30 is fitted into the locking hole 12e of the receiving plate portion 12d, and one (upper in FIGS. 1 and 4) of the receiving end portion 12d. The torsion bar 30 is locked so as not to rotate with respect to the base 12, and the torsion bar 30 is pressed by the end plate member 34 so as not to come off in the axial direction from the locking hole 12e.

  Also, as shown in FIGS. 1 to 4, on one side of the belt 3 between the two bases 12 from which the belt 3 is pulled out, two guide rollers 36a for sandwiching and guiding the belt 3 from both sides are provided with a rotating shaft 36b. And is rotatably held.

  The four corners of the two bases 12 are fastened by bolts 20a inserted into holes of one base 12 and screwed into screw holes of the other base, and sandwiched by a cylindrical spacer 20b through which the bolts 20a are inserted. The distance between the two bases 12 is maintained. Thus, the spool 31 is sandwiched between the two bases 12 and held in the thrust direction.

  Near the other side of the two bases 12, a connection pin 37 for locking the lanyard belt 4, rope, metal fittings, and the like is attached. Both ends of the connection pin 37 are inserted into holes near the other edges of the two bases 12.

  On the inner bottom surface of the one (lower in FIGS. 1 and 4) case 41, a base receiving portion 41b surrounded by a circular peripheral wall is provided, and the spool 31 bulges outward corresponding to the locking recess 31e. The portion is fitted inside the base receiving portion 41b and is in contact with the inner bottom surface of the base receiving portion 41b.

  Then, one case 41 is covered with the other case 41 (upper in FIGS. 1 and 4) so as to store the components assembled in this manner, and the cases 41 are connected to each other at four corners thereof. The screw 23 inserted into the hole of the case 41 is joined by screwing it into the screw hole of the other case 41, and the shock absorber is in an assembled state.

  If the worker wears a safety belt equipped with the above-described shock absorber and falls by mistake during work at a high place, the spool 31 is pulled by the belt 3 and tries to rotate. The locking end portion 30b also tries to rotate, but the other locking end portion 30b of the torsion bar 30 is locked to the one base 12 so as not to rotate. As a result, the belt 3 is pulled out with a constant load, and the impact is reduced.

  Then, as shown in FIG. 5, when the entire amount of the belt 3 is pulled out, the buffering ends. By adjusting the amount of winding of the belt 3 around the spool 31 and appropriately setting the stroke of the belt 3, the predetermined buffer performance can be obtained.

  In the shock absorber for a safety belt as described above, since the impact is reduced by the twist of the shaft portion 30a of the torsion bar 30, it is not affected by the use environment such as temperature, humidity, and aging due to long-term outdoor use. In addition, a stable load characteristic can be obtained according to the set value, and compactness can be achieved while ensuring sufficient cushioning.

  As shown in FIGS. 6 and 7, the spool 31 has two winding holes 31f in the chord direction from one side of the outer periphery to the other side with the core hole 31d interposed therebetween in the winding drum 31a. In the state where the terminal fixed to the belt pin 32 of the belt 3 is locked at the entrance of one end of one of the through holes 31f, the belt 3 is sequentially turned to the two through holes 31f. It may be inserted so as to be sewn and wound around the outer periphery of the winding drum 31a.

  Further, as in the second embodiment shown in FIGS. 8 and 9, the end of the belt 3 is not fixed to the inside of the spool 31 but passes through the radial through hole 31 f formed inside the spool 31. Then, the belt 3 may be double-wound around the outer periphery of the winding drum 31a of the spool 31, and the belt 3 may be simultaneously pulled out of the spool 31 in both directions as the spool 31 rotates in an emergency such as when an operator falls.

  In the second embodiment, the application portion is limited, but if the length of the shaft portion 30a of the torsion bar 30 is the same as that of the first embodiment, a double buffer stroke can be obtained. Even if the length of the shaft portion 30a is halved, the same buffer stroke as that of the first embodiment can be obtained, the size and weight can be reduced, and the belt pin can be eliminated.

  Further, the shock absorber described in the first embodiment is arranged in series with a winder as shown in FIGS. 10 to 12, for example, and constitutes a fall restraining device integrated by a base 12. You can also.

  In the winder according to the first embodiment of the fall stop device, when the wound belt is urged in the winding direction so that the belt can be pulled out at any time, the worker falls from a high place and the strap 1 is rapidly fed out. The unwinding of the strap 1 is prevented by a lock mechanism having a swinging pawl 14. The spool 11 for winding the strap 1 is rotatably held by the opposing base 12, and the end of the strap 1 The strap pin 13 to be fixed is held inside the spool 11, but does not become a rotation support shaft of the spool, and the strap 1 is wound around the outer circumference via the inside of the spool 11.

  Such a fall-stopping device can share parts for the wind-up device and the shock absorber, so it has a compact size that is easy to handle while having each function, and a stable load that is not affected by the usage environment etc. It has characteristics.

  Further, as in the second embodiment of the fall restraint device shown in FIG. 13, the winder has two spools 11 arranged in parallel, and the winder and the shock absorber are integrated by a base 12. May be stored in the case 41.

  With this configuration, when the worker travels a long distance, before removing the hook at the tip of the strap 1 pulled out from one spool 11 from the structure, the strap 1 pulled out from the other spool 11 is removed. Since the hook at the distal end can be hooked at a position distant in the moving direction of the structure, safety can be improved while achieving compactness.

1 Strap 3, 4 Belt 11 Spool 12 Base 12c Fitting Hole 12d Receiving Plate 12e Locking Hole 13 Strap Pin 14 Paul 20a Bolt 20b Spacer 23 Screw 30 Torsion Bar 30a Shaft 30b Locking End 31 Spool 31a Winding Body 31b Flange 31c Fitting portion 31d Core hole 31e Locking recess 31f Inside through hole 32 Belt pin 33 Frame ring 34 End plate member 35 Screw 36a Guide roller 36b Rotating shaft 37 Connection pin 41 Case 41b Base receiving portion

Claims (4)

A safety belt shock absorber that is provided on a safety belt worn by workers who perform work at height and that reduces the impact acting on the worker in an emergency via the belt (3),
The belt (3) is wound around the outer circumference of a spool (31) rotatably held between opposed bases (12), and one end of the spool (31) has one end of a torsion bar (30). The locking end (31b) of the torsion bar (30) is locked so as to rotate together, and the other locking end (30b) of the torsion bar (30) is one of the bases (12). Is locked so that it does not rotate,
In an emergency, the pull-out of the belt (3) from the spool (31) reduces the impact acting on the worker by twisting the shaft (30a) of the torsion bar (30). Shock absorber for safety belt. The shock absorber for a safety belt according to claim 1, wherein the belt (3) has a radial through hole formed in the spool (31) without a terminal being fixed inside the spool (31). (31f), it is double wound around the outer periphery of the spool (31),
In an emergency, the belt (3) is simultaneously pulled out of the spool (31) in both directions as the spool (31) rotates. 3. A winder integrated with the shock absorber according to claim 1 or 2, wherein the winder is urged in a winding direction so that the wound strap (1) can be pulled out at any time. (1) equipped with a winder in which the feeding is prevented by the lock mechanism,
A spool (11) for winding the strap (1) of the winder is sandwiched between opposed bases (12) shared with the shock absorber, and is held rotatably.
The strap pin (13) to which the end of the strap (1) is fixed is held inside the spool (11), but does not become a rotation support shaft of the spool (11),
The fall prevention device for a safety belt, wherein the strap (1) is wound around the outer circumference from the strap pin (13) through the inside of the spool (11).   The spool (11, 31) of the winder and the shock absorber is held in the thrust direction by being fastened with the opposed bases (12) being maintained at an interval. The crash stop device for a safety belt according to the item.

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