VERTICALLY RAISING SAFETY RAIL

Abstract

A vertical raising safety rail having a moveable top rail, a base, a movable center rail assembly positioned above the base and below the top rail, a drive shaft, and a motor that provides rotational power to the drive shaft. The safety rail further includes a pair of spaced apart lower linkage arm assemblies that is operatively connected to the base and to the center rail assembly and configured to raise or lower the center rail assembly relative to the base when a rotational force is applied to the drive shaft. The safety rail also includes a pair of spaced apart upper linkage arm assemblies that is operably connected to the center rail assembly and to the top rail. The upper linkage aim assemblies are operably connected to corresponding lower linkage assemblies and are configured to move the upper rail relative to the center rail assembly. When the rotational force is reversed, the safely rail collapses into a compact footprint.

Claims

1. A vertically raising safety rail comprising: a moveable top rail; a base; a moveable center rail assembly positioned above the base and below the top rail; a drive shaft; a motor that provides rotational power to the drive shaft; a pair of spaced apart lower linkage arm assemblies that is operably connected to the base and to the center rail assembly; said pair of lower linkage arm assemblies being movable relative to the base and the center rail assembly when a rotational force is applied to the drive shaft and configured to move the center rail assembly relative to the base; and a pair of spaced apart rotating upper linkage assemblies that is operably connected to the center rail assembly and the upper rail; said pair of upper linkage assemblies operably movable to the lower linkage assemblies to move the upper rail relative to the center rail assembly.

2. The safety rail of claim 1 wherein each lower linkage arm assembly is connected to its corresponding upper linkage assembly at a midpoint mesh gear assembly.

3. The safety rail of claim 1 wherein the center rail assembly includes a tubular center rail and is received into at least one slidable guide tube.

4. The safety rail of claim 2 wherein the center rail assembly includes a tubular center rail and received into at least one slidable guide tube and to which the midpoint mesh gear assembly is attached.

5. The safety rail of claim 1 wherein the drive shaft is operably connected to the base.

6. The safety rail of claim 1 wherein the rotational force from the drive shaft is transferred to linear motion to each lower linkable arm assembly through a worm gear, a corresponding threaded shaft, a drive shaft coupling, and a pillow support bracket.

7. The safety rail of claim 1 wherein the rotational force from the drive shaft is transferred to linear motion to each lower linkage arm assembly through an arm plate and fork bracket including a slot, said fork bracket operably connected to a ball screw and threaded nut assembly.

8. The safely rail of claim 1 wherein the rotational force from the drive shaft is transferred to linear motion to each lower linkage assembly through an arm plate, linkage arm, and a short drag linkage arm operably connected to a ball screw and a threaded nut assembly.

9. The safety rail of claim 1 wherein the rotational force form the drive shaft is transferred to linear motion to each lower linkage assembly through a short telescoping member attached to a fork bracket to which a ball screw and threaded nut assembly is operably connected.

10. The safely rail of claim 5 further comprising one or more rail stops that are positioned along the center rail to form a barrier along the center rail to the at least one slidable guide tube.

11. The safety rail of claim 1 wherein the motor may be from one of the following: pneumatic, electrical, hydraulic, or magnetic.

12. The safety rail of claim 1 wherein the drive shaft comprises two separate drive shaft members.

13. The safety rail of claim 1 further comprising one or more speed reducers.

14. The safety rail of claim 1 that collapses into a compact footprint when the rotational force is reversed.

15. A vertically raising safety rail comprising: a moveable top rail; a base; a moveable center rail assembly positioned above the base and below the top rail; a drive shaft; a motor that provides rotational power to the drive shaft; a pair of spaced apart lower linkage arm assemblies that is operably connected to the base and to the center rail assembly; said pair of lower linkage arm assemblies being movable relative to the base and center rail assembly when a rotational force is applied to the drive shaft; a pair of spaced apart rotating upper linkage assemblies that is operably connected to the center rail assembly and the upper rail; said pair of upper linkage assemblies operably movable to the lower linkage assemblies; and means for transmitting a rotational force to the pair of lower linkage arm assemblies.

16. The safety rail of claim 15 wherein each lower linkage arm assembly is connected to its corresponding upper linkage assembly at a midpoint mesh gear assembly.

17. The safety rail of claim 15 wherein the motor may be from one of the following: pneumatic, electrical, hydraulic, or magnetic.

18. A method of creating a vertically rising safety barrier, the method comprising: providing a collapsible safety rail apparatus in a collapsed position with the collapsible safety rail application apparatus comprising a moveable top rail, a base, a moveable center rail assembly positioned above the base and below the top rail, a drive shaft, a motor that provides rotational power to the drive shaft, a pair of spaced apart lower linkage arm assemblies that is operably connected to the base and to the center rail assembly wherein said pair of lower linkage arm assemblies being movable relative to the base and center rail when a rotational force is applied to the drive shaft, and a pair of spaced apart rotating upper linkage assemblies that is operably connected to the center rail assembly and the upper rail; said pair of upper linkage assemblies operably movable to the lower linkage assemblies; applying a rotational force to the drive shaft, which, in turn, applies a force to raise the pair of lower linkage arm assemblies, which raises the center rail assembly and the pair of upper linkage arm assemblies, which, in turn, raises the top rail.

19. The method of claim 18 wherein each lower linkage arm assembly is connected lo its corresponding upper linkage assembly at a midpoint mesh gear assembly.

20. The method of claim 18 wherein the motor may be from one of the following; pneumatic, electrical, hydraulic, or magnetic.

21. The safety rail of claim 1 wherein the rotational force from the drive shaft is transferred to linear motion to each lower linkage assembly through an arm plate and a double tapered bearing assembly, linkage arm, and a short drug linkage arm operably connected to a ball screw and a threaded nut assembly.

22. The safety rail of claim 3 further comprising one or more rail springs positioned between the guide tube and the at least one rail stop.

23. The safety rail of claim 1 further comprising a kick plate operatively connected to the base.

24. The safety rail of claim 1 further comprising a raisable safety curtain having an upper end and a bottom end where the upper end of the safety curtain is operably interconnected to the top rail and the bottom end of the curtain is interconnected to the base of the safety rail.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0006] The accompanying figures, which are incorporated in and constitute a part of this specification, illustrate various exemplary embodiments.

[0007] FIG. 1 is a rear isometric view of a vertically raising safety rail system of the present invention in the raised position; the safety rail system illustrating a top rail; a center rail assembly having a center rail, one or more optional slidable rail guide tube that receives and supports the center rail, and one or more optional rail stops; a base support; at least one drive shaft; and a pair of upper and lower linkage arm assemblies;

[0008] FIG. 2 is a rear view of the safety rail system of FIG. 1;

[0009] FIG. 3 is a front view of the safety rail system of FIG. 1;

[0010] FIG. 4 is a top view of the safety rail system of FIG. 1;

[0011] FIG. 5 is a bottom view of the safety rail system of FIG. 1;

[0012] FIG. 6 is a left side view of the safety rail system of FIG. 3;

[0013] FIG. 7 is a right side view of the safety rail system of FIG. 1;

[0014] FIG. 8 is an enlarged rear view of a first embodiment lower linkage arm assembly in a raised position illustrating a worm gear in mating connection with a threaded shaft to obviate the need for a threaded nut and ball screw;

[0015] FIG. 9 is the same as FIG. 8 except illustrating the lower linkage arm assembly in the fully collapsed position;

[0016] FIG. 10 is an enlarged rear perspective view of the worm gear;

[0017] FIG. 11 is an enlarged rear view of a second embodiment lower linkage arm assembly in a raided position with an arm plate and fork bracket connected to a threaded nut/ball screw assembly;

[0018] FIG. 12 is a rear perspective view of a third embodiment lower linkage arm assembly in a partially raised position illustrated with a drag linkage arm attached to the threaded nut/ball screw assembly;

[0019] FIG. 13 is an exploded rear perspective view of the safety rail better illustrating the mesh gear assembly:

[0020] FIG. 14 is a side view of the exploded safety rail of FIG. 13;

[0021] FIG. 15 is a rear view of the safety rail in the fully collapsed position;

[0022] FIG. 16 is a rear perspective view of the safety rail in a slightly raised position;

[0023] FIG. 17 is a rear view of the safety rail in a partially raised position;

[0024] FIG. 18 is a rear view of the safety rail in the fully raised position;

[0025] FIG. 19 is rear view of a fourth embodiment lower linkage arm assembly in a raised position with an arm plate and telescoping member and solid fork bracket connected to the threaded nut/ball screw assembly;

[0026] FIG. 20 is a rear isometric view like FIG. 1 except illustrating optional springs between the optional slidable guide rails and optional rail stops and illustrating a fifth embodiment lower linkage arm assembly in raised position with rail bearing assembly, linkage arm, and threaded nut/ball screw assembly;

[0027] FIG. 21 is a rear view of FIG. 20;

[0028] FIG. 22 is an enlarged rear view of the fifth embodiment lower linkage arm assembly in the nearly collapsed position;

[0029] FIG. 23 is an enlarged rear view of the fifth embodiment lower linkage arm assembly in the nearly fully raised position;

[0030] FIG. 24 is a front view of the safety rail of FIG. 20; and

[0031] FIG. 25 is a is a side view illustrating an optional kick plate operably connected to the base and an optional curtain that is operably connected to a portion of the base and the top rail and raises and lowers when the safety rail is raised or lowered.

DETAILED DESCRIPTION OF THE INVENTION

[0032] Referring to FIGS. 1-7, a collapsible safety rail 10 has a moveable top rail 12, a moveable center rail 14, a base 16 supporting a drive shaft 18 positioned between two threaded shafts 20, a pair of spaced apart rotating upper linkage assemblies 22, and a pair of spaced apart rotating lower linkage arm assemblies 24. Each upper linkage assembly 22 is operably connected to its corresponding lower linkage arm assembly 24 at a midpoint and is further connected to a slidable rail guide tube 28 that receives the center rail 14.

[0033] Referring now to FIGS. 8, 9, and 10, a first embodiment lower linkage assembly includes a lower linkage arm 30 that is connected to a worm gear 32. The worm gear travels along its corresponding threaded shaft that is bordered by a drive shaft coupling 36 and a pillow support bracket 38. Rotational force is transferred to linear motion via the threaded shaft and the worm gear attached to the lower linkage arm.

[0034] Referring now to FIG. 11, a second embodiment lower linkage assembly includes an arm plate 40 that is connected to a fork bracket 44 that allows the shortened link arm to travel along the length of a slot 46 within the fork bracket 44. The fork bracket is connected to a ball screw and threaded nut assembly 48 that is capable of travelling the length of the unbounded threaded shaft 20. Each ball screw and threaded nut assembly 48 can travel up to 16 inches along the threaded shaft 20 with a preferred travel span of 12 inches. Here, rotational force is transferred to linear motion via the threaded shaft to the ball screw/threaded nut assembly to the fork bracket, arm plate and connected lower linkage arm.

[0035] Referring now to FIG. 12, a third embodiment lower linkage assembly includes the arm plate 40 and linkage arm 30 as discussed above, but also includes a short drag linkage arm 42 that is connected to the ball screw/threaded nut assembly 48, also as discussed above. Here, rotational force is transferred to linear motion via the threaded shaft to the ball screw/threaded nut assembly to the short drag linkage arm to the arm plate and connected lower linkage arm.

[0036] Referring now to FIG. 19, a fourth embodiment lower linkage arm assembly includes an arm plate 40 connected to a linkage arm 30 as discussed above. But instead of a short drag linkage arm 42 or slotted fork bracket 44 of FIGS. 12 and 11, respectively, the arm plate is connected to a short telescoping member 66 attached to a solid fork bracket 68 that is attached to the ball screw/threaded nut assembly 48.

[0037] Referring now to FIGS. 20-24, a fifth embodiment lower linkage arm assembly includes an arm plate 40 connected to a linkage arm 30 as discussed above and also includes a short drag linkage arm 42 that is attached the ball screw/threaded nut assembly 48. Here, though, the rotation function is effectuated though a double tapered bearing 41 that is integrated into lower linkage arm assembly.

[0038] Referring again to FIGS. 1-7, as well as FIGS. 13, 14, 20, 21, and 24, each lower linkage arm 30 is attached to its corresponding upper linkage assembly through a midpoint mesh gear assembly 50, which includes two meshed gears: a lower mesh gear 52, and an upper mesh gear 54, as well as a gear plate 55. As best illustrated in FIG. 14, each set of two gears 52, 54 and corresponding gear plate 55 is positioned about and connected to a corresponding rail guide tube 28 in which the center rail 14 is support and lifted when the linkages arms rotate.

[0039] Referring also to FIGS. 15-18, each upper linkage arm 22 includes an upper linkage arm 58 that is connected to upper mesh gear 54 at a lower end of the upper linkage arm. An upper end of the linkage arm 58 is connected to top rail 12. In use, the mesh gear assembly 50 functions like an elbow respective to upper linkage arm 58 and lower linkage arm 30 that allows the upper and lower linkage arms to form an angle that ranges from 0 degrees (fully collapsed position) to 150 degrees (fully raised position) or any position therebetween. The mesh gear assembly maintains chocking of the upper and lower linkage arms and the level nature of the top and center rail.

[0040] Any rotational force in one direction (e.g., clockwise) may be applied to the drive shaft, which will transfer torque to the threaded shaft, and thereby to the threaded screw. In this manner, the ball screw turns rotational motion to linear motion via the threaded nut. The threaded screw will rotate the nut to move in a linear direction. The nut moves the short linkage arm which rotates (and raises) the lower linkage arm 30. This raising of the lower linkage arm will also simultaneously turn lower mesh gear 52, which is joined and attached to upper mesh gear 54. This will force angle between the linkage arms to increase. The movement of the mesh gear assembly, which is connected to slidable rail guide tube 28, forces the rail guide lube to move inwardly along center rail 14. Rail stops 56 are positioned along center rail to stop the rail guide tube from moving too far and causing rail instability. Upper linkage arm 50 rotates upwardly as upper mesh gear 54 is turned, which raises upper rail 12 as the outer end of the upper linkage arm Is attached to upper rail 12 via pins or other fasteners.

[0041] As illustrated in FIGS. 20, 21, and 24 optional rail springs 51 may be positioned between the rail guide tube and the rail stop to put tension on the rail guide tube and upper and lower linkage arm assemblies to better hold a vertically upright position. The rail springs keep the center rail aligned with the top rail to prevent walking back and forth during motion.

[0042] A rotational force in the other direction (e.g., counter clockwise) will rotate the threaded shaft and, therefore the ball screw and threaded nut and all connected linkages, in the reverse direction. The ball screw and threaded nut will move the worm gear and move the short linkage arm 42, and rotate the lower linkage arm 30 so that the lower mesh gear moves in the reverse direction with the upper mesh gear. This action decreases angle a so that the top rail and center rail lower as much as desired. When the rotational force stops, the safely rail maintains its position as of that time. When the safety rail is fully collapsed, the center rail is tucked under the top rail, such as illustrated in FIG. 16, for storage purposes.

[0043] In one form of the invention, a motor 60 is added to drive shaft 18. Drive shaft 18 may be in two pieces as illustrated in FIGS. 1-7 with the motor being placed therebetween to rotate each drive shaft. The motor may be pneumatic (e.g., an air motor), electrical, hydraulic, or magnetic.

[0044] The invention is adaptable for explosion proof applications, such as painting in a large manufacturing facility. Air motors, (such as explosion proof C1D1 air motors) are particularly suited for explosion proof applications, such as painting airplane parts. An operator with a manual pneumatic valve delivers air pressure to two inputs (orifices) on the air motor. Air pressure to the first input raises the safety rail as described above. Air pressure to the second input lowers the safety rail as described above. In such an air motor application, a rotating air motor shaft transfers rotational force to a drive belt through two cogged pulleys and a cogged belt (not illustrated). Rotational force is transferred 10 the drive shaft (or drive shafts) via a second cogged pulley (also not illustrated).

[0045] An optional speed reducer 62 may be added. A pair of reducer couplers 64 may be positioned between the speed reducer 62 and the two drive shafts (as illustrated in FIGS. 1 and 2).

[0046] Referring to FIG. 25 an optional kick plate 66 make be added to the base. The kick plate will rotate or slide vertically during employment. Further, an optional raisable safety curtain 68 may be interconnected to base 16, such as through a box 70 attached to base 16. The safety rail is curled up in the box and unrolls out through a slot and is attached to the top rail. The safety curtain raises when the safety rail is raised and curls back in its box when the safety rail is collapsed and can be attached on either side.

[0047] The safety rail system can be adapted for industrial use, commercial use, and residential use (both indoors and outdoors). Indoor residential applications can be made from lightweight materials and made in a smaller configuration to function as a pet or child gate.