Belt Ratcheting Device III

Abstract

The Belt Ratcheting Device (BRD) facilitates unidirectional belt fastening and fast release. The BRD includes a turning gate rotatably installed diagonally in a channel. The turning gate has a blade holder with sharp blade front. Attached at the rear is a resilient plate which acts as a spring. The BRD has two states: active and inactive. In the active state the device works as a belt ratchet i.e. allowing the belt to be pulled forwards but restricting any belt motion backwards. In the inactive state the ratcheting is disabled and the belt is released. Usually, the BRD is kept in active state by a preloaded resilient plate. After fastening, the belt remains fastened until the BRD is switched manually into inactive state by pulling a latch. The blade's smooth side and channel's smooth surfaces minimize belt wear. BRDs facilitate belt fastening for garments and footwear.

Claims

1. A ratcheting device configured for fastening a belt and releasing a fastened belt; wherein the ratcheting device comprising: a channel, a turning gate, a blade and said belt; wherein the channel is being configured to carry through a portion of the belt; said channel further comprises a gripping wall being adapted with a surface configured to engage said belt; the ratcheting device has an active state and an inactive state; the ratcheting device while in the active state is configured to restrict translation of the belt in the channel in a backwards direction and to facilitate translation of the belt in the channel in a forwards direction; the ratcheting device while in the inactive state is configured to facilitate translation of the belt both in said forwards direction and in said backwards direction; the turning gate being rotationally engaged with the channel at a fulcrum, wherein the turning gate comprises a blade holder attached to an elastic part; wherein the blade includes a blade front; wherein the blade is installed into the blade holder such that the blade front protrudes in a front of the blade holder; the turning gate is installed in the channel such that a straight line emanating from the blade front and passing through the fulcrum is at an obtuse angle with respect to the forwards direction; wherein the blade front is disposed within the channel opposite the gripping wall; wherein the blade front is disposed opposite the gripping wall such that there is a gap between the blade front and the gripping wall; wherein the belt is configured to pass through the gap between the blade front and the gripping wall; wherein, the turning gate is configured to reduce the gap and to increase a pressure force exerted by the blade front on the belt when the turning gate is turned increasingly backwards; wherein the turning gate is configured to increase the gap and to reduce the pressure force exerted by the blade front on the belt when the turning gate is turned increasingly forwards; at the active state, the blade front is configured to exert the pressure force on the belt and the blade front is configured to frictionally engage the belt and to turn forwards the turning gate when the belt is translated in said forwards direction; also, at the active state the blade front is configured to frictionally engage the belt and to turn backwards the turning gate when the belt is translated in said backwards direction; wherein the turning gate is configured to facilitate forwards translation of the belt by turning increasingly forwards and consequently diminishing the pressure force of the blade front on the belt; wherein the turning gate is configured to restrict backwards translation of the belt by turning increasingly backwards and consequently increasing the pressure force of the blade front on the belt; at the inactive state of the ratcheting device, the blade front is configured not to exert said pressure force on the belt and translation of the belt is facilitated both in the forwards direction and in the backwards direction.

2. The ratcheting device of claim 1, wherein said fulcrum comprises an axle which is fitted into a bearing.

3. The ratcheting device of claim 1, wherein said elastic part is structured as a resilient plate which acts as a flat spring which is attached to the blade holder; while in the active state, the resilient plate is configured to be at a bent state and is configured to apply said backwards turning force on the turning gate; wherein the backwards turning force is configured to turn the turning gate backwards, which is configured to reduce the gap and to apply the pressure force on the belt; wherein at the active state the turning gate is configured to apply a pressure force on the belt; while in the active state, the resilient plate is held in the bent state by a latch which is resiliently attached to a middle floor wall of the ratcheting device; wherein when manually pulled, the latch is configured to release the resilient plate from the bent state; wherein the turning gate is configured to diminish the backwards turning force when the resilient plate is released and to switch the ratcheting device from the active state into the inactive state.

4. The ratcheting device of claim 1, wherein said blade is tapered towards the blade front; wherein the blade front ends with a sharp blade front; wherein the sharp blade front is adapted with a smooth side; wherein, the sharp blade front is configured to concentrate said pressure force on the belt when the turning gate is turned backwards while the sharp blade front engages the belt; wherein, the smooth side is configured to engage the belt when the turning gate is turned forwards; wherein, the smooth side is configured to reduce said belt wear while the turning gate is turned forwards and the belt is translated in the forwards direction.

5. The ratcheting device of claim 1, wherein the surface of the gripping wall is adapted with a smooth surface; wherein, the smooth surface is configured to reduce the belt wear when the belt is fastened at the active state and also when the belt is translated in the inactive state.

6. The ratcheting device of claim 1, wherein the ratcheting device further comprising one or more bulges disposed on the surface of the gripping wall; wherein said bulge is configured to cause an additional bending of the belt due to said pressure force; wherein, said additional bending is configured to increase a mutual friction force between the belt and the surface of the gripping wall while said ratcheting device is in said active state and the belt is pulled in said backwards direction.

7. The ratcheting device of claim 1, wherein said belt further comprises a first belt end and a second belt end; wherein said ratcheting device is configured for said belt fastening by tying said second belt end to said ratcheting device and fastening said first belt end with said ratcheting device; wherein, when the belt is fastened, said first belt end is configured to pull said ratcheting device in said backwards direction, while second belt end is configured to pull in said forwards direction the belt ratcheting device.

8. The ratcheting device of claim 4, wherein said sharp blade front is split into at least two split sharp blade fronts each with a split smooth side; wherein, each of the split sharp blade fronts is configured to concentrate said pressure force on the belt when the turning gate is turned backwards; wherein, each of the split smooth sides is configured to engage the belt when the turning gate is turned forwards; whereby, each of the split smooth sides is configured to reduce said belt wear when the belt is translated in the forwards direction.

9. The ratcheting device of claim 1, wherein at least one ratcheting device which is anchored to a footwear item, is configured to fasten said belt which is attached to the footwear item.

10. The ratcheting device of claim 3, wherein the resilient plate is attached to a leaf spring at a leaf spring first end; wherein a leaf spring second end is unattached and is situated below the resilient plate; wherein when the resilient plate is rotated downwards towards the active state, the first end of the leaf spring is configured to move downwards as well and the second end of the leaf spring is configured to be pressed against the middle floor wall of the ratcheting device while bending the leaf spring; when the ratcheting device is at the active state and the latch is pulled, the resilient plate is configured to turn forwards the turning gate and the bent leaf spring is configured to be released and to facilitate turning forwards the resilient plate and the turning gate towards the inactive state.

11. The ratcheting device of claim 1, wherein the gripping wall further comprises a recess opposite the blade front end; wherein said recess is configured to cause an additional bending of the belt due to said pressure force; wherein, said additional bending is configured to increase a mutual friction force between the belt and the surface of the gripping wall while said ratcheting device is in said active state and the belt is pulled in said backwards direction.

12. The ratcheting device of claim 1, wherein the elastic part is being configured also to serve as a lever for manually switching the ratcheting device from the active state into the inactive state by manually turning down the resilient plate which also turns forwards the turning gate and consequently diminishing the pressure force exerted by the blade front on the belt; wherein the elastic part is being configured also to serve as a lever for manually switching the ratcheting device from the active state into the inactive state by manually turning up the resilient plate which also turns backwards the turning gate and consequently increasing the pressure force exerted by the blade front on the belt.

13. The ratcheting device of claim 1, wherein the turning gate is made of plastic materials.

14. The ratcheting device of claim 1, wherein the blade is made of metal.

15. The ratcheting device of claim 1, wherein the entire ratcheting device except the blade is made of plastics materials.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0039] FIGS. 1 and 2 illustrate two views of 3D isometric drawings of an embodiment of a Belt Ratcheting Device (BRD). FIG. 3 illustrates in 3D isometric drawing a disassembled BRD. FIG. 4 shows in 3D isometric drawing a BRD in inactive state while inserted with a portion of the belt. FIG. 5 illustrates in 3D isometric drawing a BRD in active state while inserted with a portion of the belt. FIG. 6 illustrates in 3D isometric drawing a cross section of the BRD in active state while inserted with a portion of the belt. FIG. 7 depicts a footwear item with two BRDs which are fastening its belts.

DETAILED DESCRIPTION OF THE DRAWINGS

[0040] FIGS. 1 and 2 illustrate two views of 3D isometric drawings of an embodiment of a Belt Ratcheting Device (BRD). The BRD's channel 1 includes the gripping wall 3 at the bottom which also has a recess 6 configured to increase the friction and the restricting force of blocked belts. Parallel and above the gripping wall there is the middle floor wall 5, which is resiliently connected to the latch 4. The turning gate 2 which is turned upwards (backwards) and is in inactive state in FIGS. 1 and 2. The blade holder 7 holds the blade 8 in one of 3 slots engraved in the blade holder 7. The turning gate turns on axes 9 which are inserted in bearings in the upper and lower side walls of the channel 1. The resilient plate 10 is the elastic part of the turning gate 2, which is attached to the blade holder 7. The resilient plate 10 is in unbent state in FIGS. 1 and 2 since the BRD is in inactive state. One end of the leaf spring 11 is attached to the lower face of the resilient plate 10. The other end of the leaf spring 11 is configured to be pressed against the middle floor wall 5 when the resilient plate 10 is turned backwards (down) when the BRD is in active state.

[0041] FIG. 3 illustrates in 3D isometric drawing a disassembled BRD. FIG. 3 is very similar to FIG. 1 except that the BRD is disassembled in FIG. 3. The turning gate axles 9 are separated from their bearings 12 in FIG. 3.

[0042] FIG. 4 illustrates in 3D isometric drawing the BRD in inactive state while inserted with a portion of the belt 13. The belt 13 is shown both in the channel's entrance (on the right side) and at the channel's exit (on the left side). Parallel and above the gripping wall 3 (which is not shown in FIG. 4) there is the middle floor wall 5, which is resiliently connected to the latch 4. The turning gate 2 which is turned upwards (backwards) and is in inactive state in FIG. 4. The blade holder 7 holds the blade 8 in one of 3 slots engraved in the blade holder 7. The turning gate turns on axes 9 which are inserted in bearings in the upper and lower side walls of the channel 1. The resilient plate 10 is the elastic part of the turning gate 2, which is attached to the blade holder 7. The resilient plate 10 is in unbent state in FIGS. 1 and 2 since the BRD is in inactive state. One end of the leaf spring 11 is attached to the lower face of the resilient plate 10. The other end of the leaf spring 11 is configured to be pressed against the middle floor wall 5 when the resilient plate 10 is turned backwards (down) when the BRD is in active state.

[0043] FIG. 5 illustrates in 3D isometric drawing a BRD 1 in active state while inserted with a portion of the belt 13. The resilient plate 10 is turned fully backwards (down) and is held in a bent state by the latch 4.

[0044] FIG. 6 illustrates in 3D isometric drawing a cross section of the BRD in active state while inserted with a portion of the belt 13. The belt 13 is pressed against the gripping wall recess 6 by the sharp blade front 8, which is inserted in the blade holder 7. The resilient plate 10 is turned fully backwards (down) and is held in a bent state by the latch 4. The holes 14 are used for attaching to the BRD 1 the second end of a fastened belt.

[0045] FIG. 7 depicts a footwear item 37 on a leg 39 with two BRDs 40 which are fastening its belts 38.