JP2019005260A - Safety device - Google Patents

Abstract

To provide a safety device 2 excellent in workability and safety in a work at a high place or the like.SOLUTION: A safety device 2 includes: a frame body 4; first and second bearing rollers 6, 8 engageable with a main rope R installed in the frame body 4; first and second pressing links 10, 12 rotatably pivoted on the frame body 4; and a connection tool 14 connected to one end side of each pressing link. Each pressing link has main rope pressing parts 34, 36 at the other end side. When pulling force acts on the connection tool 14, the first pressing link 10 rotates in a direction in which the main rope pressing part 34 presses the main rope R to the first bearing roller 6, and the second pressing link 12 rotates in a direction in which the main rope pressing part 36 presses the main rope R to the second bearing roller 8. When the pulling force is released, both pressing links 10, 12 rotate in a direction in which the main rope pressing parts 34, 36 are each separated from the main rope.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a safety device. More specifically, the present invention relates to a safety device for preventing a worker who performs an aerial work from falling, and more particularly, to a safety device for connecting the worker to a so-called parent rope. is there.

  Workers who work at high places in construction sites, electric wire construction, etc. often use safety devices to prevent falling. This safety device connects a worker's body in a movable state to a rope (also called a tension rope, a master rope, etc.) stretched within a working range of a high place. The safety device is attached to the worker's body by, for example, a rope (called a lifeline, a child rope, or the like). Even when the worker steps off the foot from the hill, the worker is suspended through the child rope, the safety device, and the parent rope, and the fall is prevented. Moreover, since the worker is connected to the master rope in a movable state by the safety device, the worker can usually move along the master rope. However, when a heavy load is applied to the safety device, such as when an operator steps off and falls, the safety device exhibits a function of gripping the master rope.

  An example of such a safety device is described in Japanese Utility Model Publication No. 49-28698. When a large tensile load is applied to the sliding plate 8, the safety device grips the tension rope a with the groove wheel 4 and the claw metal 10. However, the two ropes 10 are gripping the tension rope so that both of the two claws 10 press substantially diagonally from below with respect to one grooved wheel 4. With this configuration, it cannot be expected to generate a large gripping force efficiently.

Moreover, in this safety device, since only one grooved wheel is installed, it is difficult to maintain a substantially vertical posture with respect to the master rope stretched horizontally. When the worker moves, the safety device is greatly inclined in the horizontal direction, which is the direction in which the master rope is extended, and therefore it may be difficult for the worker to move smoothly. Further, since the safety device is substantially suspended from the master rope at one point, it is easily twisted around a vertical line passing through the support point. Therefore, it may be difficult for the operator to move smoothly .

Another example of the safety device is described in Japanese Utility Model Publication No. 64-4263. In this safety device, the two sliding rollers 21 are largely separated from each other. The pressing member 4 of the rotation links 5 and 6 presses a portion between the sliding rollers 21 of the metal power transmission line. In this configuration, the transmission line is held between the pressing member 4 and the ceiling of the holding body 3. Since the object to be gripped by the safety device is a highly rigid metal power transmission line, it is hardly bent. For this reason, the operator can move smoothly. However, when this safety device is used for a master rope made of fiber rope stretched with a relatively loose tension, it cannot be expected to generate a large gripping force efficiently. Furthermore, resistance can be generated against normal movement of the worker.
Japanese Utility Model Publication No. 49-28698 Japanese Utility Model Publication No. 64-4263

  The present invention has been made in view of these problems, and is provided with a safety device that has excellent ability to grip a gripping target such as a master rope and that does not hinder the smooth movement of an operator along the gripping target. Is the purpose.

The safety device according to the present invention is:
A safety device that can be movably connected to the master rope,
A frame,
A first support roller and a second support roller, which are installed in the frame body and can engage with the master rope,
A first pressing link and a second pressing link pivotally supported by the frame body;
A connecting tool connected to one end side of each pressing link;
Each pressing link has a master rope pressing part on the other end side,
When a tensile force acts on the connector, the first pressing link rotates in a direction in which the master rope pressing portion presses the master rope to the corresponding first support roller, and the second pressing link is When the master rope pressing portion rotates in a direction to press the master rope against the corresponding second support roller and the pulling force is released, the two press links are separated from the master rope press portions. It is configured to rotate in the direction.

Preferably, the pressing position, which is the position of the master rope pressing portion that presses the master rope against the corresponding bearing roller, is located on the side opposite to the position of the other bearing roller with respect to the center position of the corresponding bearing roller. Configured to
It is comprised so that the pressing direction of the master rope press part which is pressing the master rope with respect to the corresponding support roller may contain the component of the direction which faced the other support roller.

Preferably, an engagement groove that can be engaged with the master rope is formed along the circumferential direction on the outer peripheral surface of each of the support rollers.
The movement trajectory of the pressing point in the master rope pressing portion accompanying the rotation of each pressing link has an arc shape passing through the range of the groove diameter portion of the corresponding support roller,
The said press point is a site | part which presses a master rope early compared with the other site | part of a master rope press part with rotation of a press link.

More preferably, an engagement groove that can be engaged with the master rope is formed along the circumferential direction on the outer peripheral surface of each of the support rollers.
With the rotation of each pressing link, the direction in which the pressing point of the master rope pressing portion at the pressing position presses is within the range of the groove diameter portion of the corresponding support roller,
The pressing direction is a direction perpendicular to a straight line passing through the pressing point and connecting the pivot point of the pressing link and the pressing point,
The said press point is a site | part which presses a master rope early compared with the other site | part of a master rope press part with rotation of a press link.

Preferably, the frame includes a front support member, a rear support member, and a lid member,
The first bearing roller is pivotally supported by the first spindle, the second bearing roller is pivotally supported by the second spindle, and both the first pressing link and the second pressing link are pivotally supported by the third spindle. ,
The first support shaft and the second support shaft are spanned between the front support member and the rear support member,
The lid member is pivotally supported at the tip of any one of the first support shaft, the second support shaft, and the third support shaft so as to be rotatable between an open position and a closed position;
When the lid member is in the open position, the master rope is made detachable from the two support rollers, and when the lid member is in the closed position, the master rope is made non-detachable from the two support rollers. .

More preferably, the lid member is pivotally supported at the tip of one of the first support shaft and the second support shaft,
The lid member includes a guide slot that can be engaged with the other tip of the first support shaft and the second support shaft so as to be relatively movable, and a locking notch portion that can be locked to the third support shaft. And are formed,
The guide long hole has a circular hole shape corresponding to an angle range from the closed position to the open position of the lid member,
The locking notch is adapted to lock to the third spindle in the closed position,
The third support shaft is provided with a lock device that presses and locks the locked lid member to the front surface of the front support member.

  The safety device according to the present invention contributes to workability during normal work, exhibits excellent gripping ability for gripping a gripping object in an emergency, and contributes to worker safety.

FIG. 1 is a perspective view showing a state where a lid member of a safety device according to an embodiment of the present invention is closed. FIG. 2 is a perspective view showing a state where the lid member of the safety device of FIG. 1 is opened. FIG. 3 is a front view of the safety device of FIG. 1 showing a state where the lid member is opened and the master rope is not gripped. FIG. 4 is a right side view of the safety device of FIG. 3. FIG. 5 is a front view showing main parts of the safety device of FIG. 1. FIG. 6 is a front view of the safety device of FIG. 1 in a state where the lid member and the front support member are removed and the master rope is not gripped. FIG. 7 is a front view showing a state where the lid member and the front support member are removed and the master rope is gripped in the safety device of FIG. 1. FIG. 8A, FIG. 8B, and FIG. 8C are front views illustrating the form of the master rope pressing portion, respectively. FIG. 9 is a front view illustrating the locus of the safety device that is displaced in the direction in which the parent rope pressing portion of the pressing link presses the parent rope. FIG. 10 is a front view illustrating the direction of pressing the master rope of the master rope pressing portion of the press link in the safety device. FIG. 11 is a perspective view showing a state where a lid member of a safety device according to another embodiment of the present invention is closed. 12 is a perspective view showing a state where the lid member of the safety device of FIG. 11 is opened. FIG. 13 is a perspective view showing a state in which a lid member of a safety device according to still another embodiment of the present invention is closed. FIG. 14 is a perspective view showing a state where the lid member of the safety device of FIG. 13 is opened. FIG. 15 is a front view illustrating a state in which a lid member of a safety device according to still another embodiment of the present invention is opened and closed.

  Hereinafter, the present invention will be described in detail based on preferred embodiments with appropriate reference to the drawings.

  The safety device 2 shown in FIG. 1 to FIG. 7 is rotatable to the frame 4, the first support roller 6 and the second support roller 8 installed in parallel to the frame 4, and the frame 4. The first pressing link 10 and the second pressing link 12 pivotally supported by each other, and a connecting tool 14 connected to one end side of each pressing link 10, 12. The frame body 4 includes a front support member 16, a rear support member 18, and a lid member 20 each having a plate shape. In the present embodiment, the front support member 16, the closed lid member 20, and the rear support member 18 are parallel. 6 and 7 both show a state in which the lid member 20 and the front support member 16 are removed in order to facilitate the understanding of the movement of the safety device 2. As shown in FIG. 1, the front view shape formed by the front support member 16 and the closed lid member 20 is substantially the same as the front view shape of the rear support member 18. Further, in the front portion of the frame body 4, the lid member 20 occupies the upper half, and the front support member 16 occupies the lower half. Here, the up / down / left / right directions related to the safety device 2 mean the up / down / left / right directions in FIGS. The front-rear direction means the left-right direction in FIG.

  A first support shaft 22, a second support shaft 24, and a third support shaft 26 are erected on the rear support member 18 in parallel with each other. The first support shaft 22 and the second support shaft 24 are stretched over the lid member 20, and the third support shaft 26 is stretched over the front support member 16. The third support shaft 26 penetrates the front support member 16 and protrudes outward. A locking device 58 to be described later is attached to the protruding portion of the third support shaft 26. Between the front support member 16 and the rear support member 18, a pair of elastic body attachment shafts 28 and a pair of connector guide shafts 30 are further spanned. The front support member 16 and the rear support member 18 are fixedly coupled in parallel and spaced apart from each other by a third support shaft 26, an elastic body mounting shaft 28, and a connector guide shaft 30.

  The first support roller 6, the second support roller 8, the first pressing link 10, the second pressing link 12, and the coupling tool 14 are disposed between the rear support member 18, the front support member 16, and the lid member 20. ing. However, a portion of a connecting hole 42 to be described later of the connector 14 is exposed downward from this internal space.

The first support roller 6 is pivotally supported on the first support shaft 22, and the second support roller 8 is pivotally supported on the second support shaft 24. Engagement grooves 32 with which the master rope R can be engaged are formed along the circumferential direction on the outer peripheral surfaces of the respective support rollers 6 and 8. The radius of curvature of the engagement groove 32 in a side view (see FIG. 4) is preferably larger than the radius of the cross section of the master rope R from the viewpoint of effective engagement of the master rope R. As shown in FIGS. 3, 6 and 7, the two support rollers 6, 8 are spaced apart from each other so as not to interfere with each other's movement. The safety device 2 is supported at two points separated by the master rope R. As shown in FIGS. 6 and 7, the portion of the master rope R between the two support points can maintain a substantially horizontal state regardless of whether or not the connector 14 is pulled downward. Therefore, taking this safety device 2, like a conventional safety device having only a single grooved pulley described above, a possibility that is twisted in the vertical line around it can be said that no. The lid member 20 is pivotally supported by the tip end portion of the first support shaft 22 so as to be rotatable. The lid member 20 will be described later. Both the first pressing link 10 and the second pressing link 12 are pivotally supported by the third support shaft 26. The first pressing link 10 and the second pressing link 12 are symmetrically shaped and arranged with respect to the following center line CL passing through the pivotal support position in a front view.

  A straight line connecting the axis of the first support shaft 22 and the axis of the second support shaft 24 shown in FIG. 7, that is, a straight line connecting the centers of the two support rollers 6 and 8, is called a center coupling line LL. . Further, a straight line passing through the center of the center coupling line LL in the vertical direction corresponds to the center line CL of the safety device 2. The third support shaft 26 is provided such that its center is located on the center line CL. In the present embodiment, the center line CL coincides with the vertical center line of the connector 14. The pair of elastic body attachment shafts 28 and the pair of connector guide shafts 30 are both arranged symmetrically with respect to the center line CL in a front view.

  On the one end side of each pressing link 10, 12, long connecting holes 38, 40 for connecting to the connector 14 are formed. A first engagement convex portion 48 of the connector 14 described later is engaged with the first connection long hole 38, and a second engagement convex portion 50 is engaged with the second connection long hole 40. A first parent rope pressing portion 34 is formed on the other end side of the first pressing link 10, and a second parent rope pressing portion 36 is formed on the other end side of the second pressing link 12. A large number of protrusions are formed in the width direction on the surfaces of the master rope pressing portions 34 and 36 so that the master rope R can be firmly held by the corresponding support rollers 6 and 8. The corresponding bearing roller is the first bearing roller 6 for the first pressing link 10 and the second bearing roller 8 for the second pressing link 12. The same applies hereinafter. Each of the pressing links 10 and 12 has a “<” shape. That is, the central axis of each pressing link 10, 12 is bent at the pivot point. Therefore, the direction in which the pressing links 10 and 12 are pulled by the connector 14 and the direction in which the master rope R is pressed are inclined with respect to each other.

  As apparent from FIGS. 1, 2, and 4, the widths of the master rope pressing portions 34 and 36 are set to dimensions close to the distance between the front support member 16 and the rear support member 18. On the other hand, the width of the portions other than the master rope pressing portions 34 and 36 (hereinafter also referred to as base portions) of the respective pressing links 10 and 12 is set to about 1/3 of the width of the master rope pressing portions 34 and 36. This is because the two pressing links 10 and 12 and the connector 14 are pivotally supported by the same third support shaft 26. That is, in the periphery of the third support shaft 26, the base portions of the two pressing links 10, 12 are overlapped so that the connector 14 is sandwiched in the middle. With such a configuration, many parts are compactly accommodated between the front support member 16 and the rear support member 18. In the drawing, the base of the first pressing link 10 is on the front side of the connector 14, and the base of the second pressing link 12 is on the rear side.

  As is apparent when referring also to FIG. 5, in this embodiment, the connector 14 has a plate-like shape that is substantially T-shaped when viewed from the front. This connector 14 is arrange | positioned between the base parts of both the press links 10 and 12 in the front-back direction. A connecting hole 42 for connecting to a lifeline or the like is formed in the lower center of the connector 14. A locking projection 44 for locking one end of a pair of restoring coil springs 52 as a restoring elastic body is formed slightly above the coupling hole 42. An engagement long hole 46 is formed slightly above the locking projection 44. The long axis of the engaging long hole 46 is along the vertical center axis of the connector 14. The third support shaft 26 passes through and engages with the engaging long hole 46. The connector 14 can move up and down within the range of the length of the engaging slot 46. The pair of connecting tool guide shafts 30 described above are provided so as to project at positions close to the left and right outer surfaces of the connecting tool 14. From the above configuration, the vertical movement of the connector 14 is effectively guided by the engagement long hole 46, the third support shaft 26, and the connector guide shaft 30.

  A first engaging convex portion 48 protrudes from the right front surface of the engaging long hole 46. On the rear surface on the left side of the engaging long hole 46, a second engaging convex portion 50 is projected. The first engaging convex portion 48 engages with the first connecting elongated hole 38. The second engaging convex portion 50 engages with the connecting long hole 40 of the second pressing link 12. Therefore, when the user of the safety device 2 is dropped or the like, and the connecting tool 14 is pulled downward, both the pressing links 10 and 12 rotate around the pivot point (the position of the third spindle 26), The parent rope pressing portions 34 and 36 rotate upward. And each master rope press part 34 and 36 can pinch the master rope R with the corresponding bearing rollers 6 and 8. In the present embodiment, when the connecting tool 14 moves within the length range of the engagement slot 46, the pressing links 10, 12 are rotated by an angle of about 45 °. However, it is not limited to this range.

  As shown in FIGS. 3, 6, and 7, the restoring coil spring 52 urges the connector 14 upward, that is, the master rope pressing portions 34, 36 are moved from the support rollers 6, 8. It is installed to urge in the direction of separation. In other words, the safety device 2 has a function of restoring the master rope R to the open posture. Specifically, one end of each restoring coil spring 52 is locked to the locking convex portion 44 of the connector 14. The other end of one restoring coil spring 52 is locked to the left elastic body mounting shaft 28, and the other end of the other restoring coil spring 52 is locked to the right elastic body mounting shaft 28. In the present embodiment, both restoring coil springs 52 are installed in front of the connector 14. The position of the locking projection 44 is below the position of both elastic body mounting shafts 28. Both restoring coil springs 52 are attached in a slightly stretched state. Accordingly, the connector 14 is biased upward by the two restoring coil springs 52. When the connector 14 is pulled downward, the upward biasing force (restoring force) of the restoring coil spring 52 increases. When the downward pulling force on the connector 14 is released, the parent rope opening action is achieved at once. As shown in FIG. 4, the locking convex portion 44 protrudes from both the front surface and the rear surface of the connector 14. Therefore, it is also possible to install one restoring coil spring 52 in front of the connector 14 and install the other restoring coil spring 52 in the rear. It is also possible to install both restoring coil springs 52 behind the connector 14.

  A preferred shape structure of the safety device 2 will be described with reference to FIGS. 6, FIG. 7, FIG. 9 and FIG. 10 show a state where the lid member 20 and the front support member 16 are removed in order to facilitate understanding of the movement of the safety device 2. FIG. FIG. 6 shows a state (open state) in which both the pressing links 10 and 12 do not hold the master rope R. FIG. 7 shows a state (gripping state) in which both pressing links 10 and 12 grip the master rope R.

  As shown in FIG. 6, in the safety device 2, the distance between the upper ends of the two pressing links 10, 12 and the upper ends of the coupling tools 14 and the lower ends of the both supporting rollers 6, 8 is larger than the outer diameter of the master rope R. Has been. Therefore, the safety device 2 can be easily attached to and detached from the master rope R. In one example, the distance is set to 18 mm with respect to the master rope R having a commonly used outer diameter of 12 mm.

  As shown in FIG. 7, the positions of the master rope pressing portions 34 and 36 when the master rope R is actually pressed and held between the engagement grooves 32 are referred to as pressing positions. More specifically, the pressing position can apply the strongest pressing force to the parent rope R among the surfaces of the parent rope pressing portions 34 and 36 pressing the parent rope R (hereinafter referred to as a pressing point). 35 position. The pressing point 35 will be described later with reference to FIG. It is preferable that the pressing position is configured to be a position opposite to the position of the other support rollers 8 and 6 with respect to the center position of the corresponding support rollers 6 and 8. In other words, the pressing position is preferably configured to be a position on the opposite side of the other supporting rollers 8 and 6 with respect to the straight line VL passing through the center of the corresponding supporting rollers 6 and 8 in the vertical direction. That is, the pressing force by the pressing links 10 and 12 includes a force component that presses the master rope R toward the center line CL, in other words, parallel to the center coupling straight line LL of the both support rollers 6 and 8 and the other. The force component in the direction facing the bearing roller is included. With this configuration, the master rope pressing portions 34 and 36 press the master rope R toward the corresponding support rollers 6 and 8 inward and upward. Accordingly, the master rope R is bent at the pressing position and is not linear, and inadvertent movement of the safety device 2 on the master rope R is suppressed. Such a configuration is based on the distance between the first support shaft 22 and the second support shaft 24, and the pivot point (the center of the hole penetrating the third support shaft 26) in each pressing link 10, 12. , 36 can be easily realized by adjusting the length up to 36. The straight line VL extends perpendicularly to the central coupling line LL.

  FIG. 8 illustrates three examples of the pressing point 35 in the first pressing link 10. In the case of a pressing point in the second pressing link 12 (not shown), the first pressing link 10 is substantially the same as the first pressing link 10 shown in FIG. The pressing point 35 is a point where the strongest pressing force can be applied to the parent rope R in the pressing portion 34. FIG. 8A shows an example in which the longitudinal end portion of the pressing portion 34 functions as the pressing point 35. In this configuration, when the pressing portion 34 approaches the master rope R, the protrusion at the tip of the plurality of protrusions of the pressing portion 34 is the most of the main groove R and the engagement groove 32 of the first support roller 6. Located near the bottom of the groove. Therefore, the protrusion at the tip can press the master rope R earlier than the other protrusions. As a result, the parent rope R can be pressed most strongly.

  FIG. 8B shows an example in which the longitudinal intermediate portion of the pressing portion 34 functions as the pressing point 35. In this configuration, the ridge at the intermediate portion among the plurality of ridges of the pressing portion 34 is located closest to the groove bottom of the engagement groove 32 of the master rope R and the first support roller 6. The intermediate protrusion can press the master rope R earlier than the other protrusions. As a result, the parent rope R can be pressed most strongly.

  FIG. 8C shows an example in which the base end portion in the longitudinal direction of the pressing portion 34 functions as the pressing point 35. In this configuration, the ridge at the base end portion of the plurality of ridges of the pressing portion 34 is closest to the groove bottom of the engagement groove 32 of the master rope R and the first support roller 6. The protrusion at the base end can press the master rope R earlier than the other protrusions. As a result, the parent rope R can be pressed most strongly.

  FIG. 9 shows a movement locus S0 of the pressing point 35 accompanying the rotation of the first pressing link 10. Here, the first support roller 6 and the first pressing link 10 on the left side of the figure will be described as an example. In the case of the second supporting roller 8 and the second pressing link 12, the first supporting roller 6 and the first pressing link 10 are substantially the same except that the left and right are reversed. Moreover, as the pressing point 35, what was formed in the longitudinal direction front-end | tip part of the press part 34 shown by Fig.8 (a) is employ | adopted. The movement locus S0 of the pressing point 35 is a circle whose radius is the length of the straight line (arm length of the first pressing link 10) AL extending from this center to the pressing point 35 with the center of the third support shaft 26 as the center. Draw. This movement locus S0 can be said to be a pressing direction by the pressing point 35 at each time point.

  A firm grip of the master rope R is achieved by clamping pressure between the master rope pressing portion 34 centered on the pressing point 35 and the groove bottom of the engagement groove 32 of the support roller. Therefore, it is preferable that the movement trajectory S0 of the pressing point 35, which can be said to be the center of pressing by the master rope pressing portion 34, passes through the groove diameter portion of the support roller 6. The groove diameter portion can be said to be a circular cross-sectional portion of the engagement groove 32 and can be said to be in the range of the diameter of the groove bottom. In other words, in FIG. 9, the pressing point 35 is preferably located between the outer circle S1 and the inner circle S2 centered on the center of the third support shaft 26. The outer circle S1 is a circle that passes through a portion of the groove bottom of the engagement groove 32 that is farthest from the center of the third support shaft 26. The inner circle S <b> 2 is a circle that passes through a portion of the bottom of the engagement groove 32 that is closest to the center of the third support shaft 26. Thus, the radius (AL) of the movement trajectory S0 is preferably equal to or smaller than the radius of the outer circle S1 and equal to or larger than the radius of the inner circle S2. Such a configuration adjusts the length of each pressing link 10, 12, adjusts the distance from the third support shaft 26 to the first and second support shafts 22, 24, and the first and second support shafts. This can be realized by adjusting the distance between the shafts 22 and 24.

More preferably, as indicated by an arrow in FIG. 10, the pressing direction of the pressing point 35 at the pressing position passes through the aforementioned groove diameter portion (circular cross section of the engaging groove 32). That is. As shown in the figure, this pressing direction is a direction that passes through the pressing point 35 and is perpendicular to the straight line AL, and is directed to the corresponding bearing roller. The pressing direction is preferably closer to the center of the groove diameter portion (the center of the support roller 6). The pressing position of the pressing point 35 is specified from the position of the pressing point 35 in the first pressing link 10, the movement locus S0 of the pressing point 35 with respect to the groove diameter part, the outer diameter and material of the parent rope that is a safety device installation target. Can do. The outer diameters of ropes generally used as parent ropes are 12 mm, 14 mm, and 16 mm . In the case of a fiber rope that is usually used as a master rope, when it is pinched by a master rope press portion having a general shape as shown in FIG. 8, the outer diameter in the pressing direction decreases from 40% to about 60%. .

  The lid member 20 is pivotally supported at the tip end portion of the first support shaft 22 so as to be rotatable between a closed position and an open position. The closed position is shown in FIG. 1, and the open position is shown in FIGS. The lid member 20 is formed with an arcuate elongated guide hole 54. The leading end of the second spindle 24 is engaged with the guide slot 54 so as to be relatively movable. The guide long hole 54 is formed in an angle range corresponding to the position from the closed position of the lid member 20 to the open position. Further, the lid member 20 is formed with a locking notch 56 that extends from the periphery to the inside. As shown in FIG. 1, the third support shaft 26 is locked to the locking notch 56 when the lid member 20 is rotated to the closed position.

  A spring-type locking device 58 that locks the lid member 20 in the closed position is attached to the protruding portion of the third support shaft 26. As shown in FIG. 4, the locking device 58 is a device that presses and fixes the lid member 20 to the front support member 16 by a built-in locking coil spring 60. Specifically, a locking coil spring 60 is fitted on the third support shaft 26, and a cylindrical container 62 is fitted so as to cover the outer peripheral surface thereof. The locking coil spring 60 is disposed between the flange 64 formed on the distal end side of the third support shaft 26 and the bottom portion of the cylindrical container 62. The cylindrical container 62 moves toward the front support member 16 by the restoring force of the compressed coil spring 60 for locking. Through the bottom of the cylindrical container 62, the outer peripheral extension of the locking notch 56 of the lid member 20 is pressed against the front support member 16. By this action, the lid member 20 is locked in the closed position. To release this lock, the cylindrical container 62 may be pulled against the compressive force of the locking coil spring 60 (see arrows in FIGS. 2 and 4). When the lid member 20 is in the open position, the master rope R can be attached to and detached from the support rollers 6 and 8, and when the lid member 20 is in the closed position, the master rope R cannot be attached to and detached from the support rollers 6 and 8. Configured to be

  11 and 12 show a safety device 72 according to another embodiment. 13 and 14 show a safety device 92 according to still another embodiment. These safety devices 72 and 92 are different from the safety device 2 described above mainly in the structure of the lid member, and the main internal structure and the movement thereof are the same. In addition, some of the front support member 16 and the rear support member 18 are different from the safety device 2 described above. Accordingly, parts and structures having the same configurations as those of the safety device 2 described above are denoted by the same reference numerals and description thereof is omitted.

  Also in the safety device 72 shown in FIGS. 11 and 12, the shape of the front view formed by the front support member 16 and the closed lid member 76 is substantially the same as the shape of the rear support member 18 in front view. Further, in the front portion of the frame body 74, the lid member 76 occupies the upper half, and the front support member 16 occupies the lower half. The lid member 76 is pivotally supported at the tip end portion of the third spindle 26 so as to be rotatable. The lid member 76 can rotate between a closed position (FIG. 11) and an open position (FIG. 12). Specifically, a locking hole 78 is formed at each of the positions corresponding to the first and second support shafts 22 and 24 of the lid member 76 in the closed state, and at a position corresponding to the third support shaft 26. A pivot hole 80 is formed. An engagement groove 82 is formed on the upper surface of the tip of the first and second support shafts 22 and 24. A male screw (not shown) is formed at the tip of the third support shaft 26. A screw lock member 84 formed with a female screw (not shown) such as a nut can be screwed onto the male screw as shown.

  In the lid member 76 in the closed state, the edges of the pair of locking holes 78 are engaged with the engaging grooves 82 of the first and second support shafts 22 and 24. When the screw lock member 84 is tightened in this state, the lid member 76 is clamped between the front support member 16 and the screw lock member 84 and locked in the closed position. When the lid member 76 is opened, as shown in FIG. 12, the screw lock member 84 is loosened, the lid member 76 is lifted and removed from the engaging groove 82 and rotated downward. The screw lock member 84 is not limited, and the spring-type lock device 58 described above may be employed. On the other hand, the screw lock member 84 can be used in place of the spring-type lock device 58 for the safety device 2 described above.

  The safety device 92 shown in FIGS. 13 and 14 is configured such that the upper half of the frame 94 is opened and closed relative to the lower half. In other words, the upper half of the frame 94 constitutes a lid member 96 that can rotate with respect to the lower half. The lower half of the frame 94 is composed of a front support member 98 and a rear support member 100 that are parallel to each other. Between the front part support member 98 and the rear part support member 100, the 1st press link 10, the 2nd press link 12, and the connector 14 are arrange | positioned. The lid member 96 includes a plate-like front plate portion 102 and a rear plate portion 104 that are parallel to each other. Between the front plate portion 102 and the rear plate portion 104, the first support shaft 22 and the second support shaft 24 are suspended. The front plate portion 102 and the rear plate portion 104 are fixed and integrated by the first support shaft 22 and the second support shaft 24.

  The front plate portion 102 and the front support member 98 have a flat hinge structure, and the rear plate portion 104 and the rear support member 100 have a flat hinge structure. Cylindrical locking tube portions 106 are formed in the center portion of the lower end edge of the front plate portion 102 and the center portion of the lower end edge of the rear plate portion 104, respectively. Cylindrical support tube portions 108 are formed at both ends of the upper end edge of the front support member 98 and at both ends of the upper end edge of the rear support member 100, respectively. A connecting pin 110 is inserted into the locking tube portion 106 and the support tube portion 108 that are arranged coaxially with each other. As shown in FIG. 13, the lid member 96 cannot be opened and closed when the pin 110 is inserted into any of the front and rear flat hinge structures. The lid member 96 is locked in the closed position. As shown in FIG. 14, when one of the pins 110 is removed, the lid member 96 can rotate around the other pin 110, that is, can be opened and closed. A bolt may be adopted as the pin 110. And it is preferable to form the internal thread which can be screwed with this volt | bolt in one internal peripheral surface of the support pipe part 108 formed in the said both ends. With this configuration, the pins 110 can be prevented from being accidentally dropped.

  A lid member 114 as shown in FIG. 15 may also be employed. The lid member 114 has a pair of lid parts 116 and 118 that are symmetrical with respect to the center line CL of the safety device 112 and are symmetrically arranged. Each lid component 116, 118 is pivotally supported at the tip of the elastic body mounting shaft 28 described above. Although not shown, it may be pivotally supported at the tip of the connector guide shaft 30. The tip of the elastic body mounting shaft 28 that pivots passes through the front support member 16 and protrudes outward. The upper front support member 120 and the lower front support member 16 are separated from each other in the vertical direction, and a gap through which the master rope R can pass is formed. Locking notches 122 and 124 are formed at the ends of the lid parts 116 and 118 opposite to the pivot positions. As indicated by a two-dot chain line in the drawing, the locking notch 122 of one lid part 116 is locked to the tip of the first support shaft 22, and the locking notch 124 of the other lid part 118 is The second support shaft 24 is locked to the tip. This state is the closed state of the lid member 114. Each tip of the first support shaft 22 and the second support shaft 24 penetrates the front support member 16 and protrudes outward. Then, a locking nut 126 is screwed onto the male screw formed at each end of the first support shaft 22 and the second support shaft 24. If the lock is removed, the locking notches 122 and 124 are removed from the locked shaft, and the lid parts 116 and 118 are rotated and positioned downward as shown by the solid lines in the figure, it is safe. The vessel 112 is opened.

  The pair of lid parts 116 and 118 may be pivotally supported by the first support shaft 22 and the second support shaft 24 so as to be rotatable. The locking notches 122 and 124 may be configured to be locked to the distal end of the elastic body mounting shaft 28 or the distal end of the connector guide shaft 30.

  As described above, the safety devices 2, 72, and 92 contribute to workability during normal work, and contribute to the safety of workers in an emergency.

  The safety device described above can be used for various work in high places.

2, 72, 92, 112 ... Safety device 4, 74, 94 ... Frame 6 ... First bearing roller 8 ... Second bearing roller 10 ... First pressing link 12 ... Second pressing link 14 ... Connector 16, 98, 120 ... Front support member 18, 100 ... Rear support member 20, 76, 96, 114 ... Lid member 22 ... First support Axis 24 ... second support shaft 26 ... third support shaft 28 ... elastic body mounting shaft 30 ... coupling tool guide shaft 32 ... engagement groove 34, 36 ... master rope pressing portion 35 ... Pressing point 38, 40 ... Long hole for connection 42 ... Hole for connection 44 ... Convex protrusion 46 ... Elongation hole 48 ... First engagement protrusion 50 ... Second engaging convex portion 52 ... Restoring coil spring 54 ... Guide slot 56 ... Locking notch 58 ... Locking device 60 ... Coil spring for locking 62 ... Cylindrical container 64 ... ７８ 78 ... Locking hole 80 ... Pivoting hole 82 ... Engaging groove 84 ... Screw lock member 102 ... Front plate portion 104 ... Rear plate portion 106 ... Locking tube portion 108 ... Support tube portion 110 ... Pins 116, 118 ... Cover parts 122, 124 ... Notch portion 126 for locking ···nut

Claims (6)

A safety device that can be movably connected to the master rope,
A frame,
A first support roller and a second support roller, which are installed in the frame body and can engage with the master rope,
A first pressing link and a second pressing link pivotally supported by the frame body;
A connecting tool connected to one end side of each pressing link;
Each pressing link has a master rope pressing part on the other end side,
When a tensile force acts on the connector, the first pressing link rotates in a direction in which the master rope pressing portion presses the master rope to the corresponding first support roller, and the second pressing link is When the master rope pressing portion rotates in a direction to press the master rope against the corresponding second support roller and the pulling force is released, the two press links are separated from the master rope press portions. A safety device configured to rotate in a direction. The pressing position, which is the position of the master rope pressing portion that presses the master rope against the corresponding bearing roller, is positioned opposite to the position of the other bearing roller with respect to the center position of the corresponding bearing roller. Configured,
The safety device according to claim 1, wherein the pressing direction of the master rope pressing portion that presses the master rope against the corresponding support roller includes a component in a direction facing the other support roller. An engagement groove that can be engaged with the master rope is formed along the circumferential direction on the outer peripheral surface of each of the support rollers.
The movement trajectory of the pressing point in the master rope pressing portion accompanying the rotation of each pressing link has an arc shape passing through the range of the groove diameter portion of the corresponding support roller,
The safety device according to claim 2, wherein the pressing point is a part that presses the master rope earlier than the other parts of the master rope pressing part as the pressing link rotates. An engagement groove that can be engaged with the master rope is formed along the circumferential direction on the outer peripheral surface of each of the support rollers.
With the rotation of each pressing link, the direction in which the pressing point of the master rope pressing portion at the pressing position presses is within the range of the groove diameter portion of the corresponding support roller,
The pressing direction is a direction perpendicular to a straight line passing through the pressing point and connecting the pivot point of the pressing link and the pressing point,
4. The safety device according to claim 2, wherein the pressing point is a part that presses the master rope earlier than the other parts of the master rope pressing portion as the pressing link rotates. The frame includes a front support member, a rear support member, and a lid member,
The first bearing roller is pivotally supported by the first spindle, the second bearing roller is pivotally supported by the second spindle, and both the first pressing link and the second pressing link are pivotally supported by the third spindle. ,
The first support shaft and the second support shaft are spanned between the front support member and the rear support member,
The lid member is pivotally supported at the tip of any one of the first support shaft, the second support shaft, and the third support shaft so as to be rotatable between an open position and a closed position;
When the lid member is in the open position, the master rope is made detachable from the two support rollers, and when the lid member is in the closed position, the master rope is made non-detachable from the two support rollers. The safety device according to any one of claims 1 to 4. The lid member is pivotally supported rotatably at the tip of one of the first support shaft and the second support shaft;
The lid member includes a guide slot that can be engaged with the other tip of the first support shaft and the second support shaft so as to be relatively movable, and a locking notch portion that can be locked to the third support shaft. And are formed,
The guide long hole has a circular hole shape corresponding to an angle range from the closed position to the open position of the lid member,
The locking notch is adapted to lock to the third spindle in the closed position,
The safety device according to claim 5, wherein the third support shaft is provided with a locking device that presses and locks the locked lid member to the front surface of the front support member.

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