I invented a ladder leveler that provides adjustable extensions to ladder legs, U.S. Pat. No. 5,678,656. That leveler is shown in
A release lever 75 on the pawl 73 releases the pawl when activated by hand. A safety bar (shown in
The support foot 27 is secured to the leg extension 71 with the securing bolt 33 which acts as a hinge pin by passing through an oblong securing bolt aperture in the leg extension, and is held in place with a securing nut 35. The support foot 27 includes a rubber friction pad tread 31.
The leveler also includes a retraction spring 53 coupled at one end to the outer housing at a spring fastener 55 and at the other end to the leg extension 71. The retraction spring continually applies an upward biasing force on the leg extension. To facilitate the extension and retraction of the extension leg 71 into and out of the outer housing 41, a foot pedal 101 is secured to the front portion of the extension leg 71 with a foot pedal pivot pin 103. Pressing on the pedal opposes the force of the retraction spring 53.
The invention provides improvements to the leg extension of my prior ladder leveler and, more generally, improvements to ladder legs.
In one aspect, the invention is a ladder leg with a nailable, pivoting shoe, comprising a ladder leg having a bottom end with a pivotable structure at the bottom end; pivotably coupled to the pivotable structure, a ladder shoe having a planar bottom surface, the bottom surface being a surface of a support structure of the ladder shoe adapted to apply weight of the ladder to a planar surface on which the ladder rests when erected; at least one hole in the support structure, the hole passing through the support structure perpendicular to the planar bottom surface of the ladder shoe; and the hole having a minimum diameter of at least 1/16 inch and no part large enough to allow passage of a ⅜ inch sphere.
The hole may be round or a slot. The support structure may include a metal portion and a rubber portion and the rubber portion forming the planar bottom surface of the ladder shoe, in which case the at least one hole in the support structure passes through the metal portion and aligns with a hole in the rubber portion. The hole in the rubber portion may be smaller than the hole in the metal portion with which it is aligned so that the hole in the rubber portion is enlarged by entry of a penetrating object that is smaller than the hole in the metal portion but larger than the hole in the rubber portion and the penetrating object is thereby gripped by the rubber portion. The planar bottom surface of the ladder shoe may comprises multiple, discontinuous bottom surfaces in a single plane, the lowest parts of the rubber tread as shown in the figures. The support structure may include, on a top surface surrounding the hole, a raised edge that supports a head of a nail inserted into the hole such that the head can be easily engaged by a forked claw for removing the nail. The leg may be an extendable and adjustable leg.
In another aspect, the invention is a retractable ladder leveler with improved foot operable control, comprising an outer housing mountable on a bottom end of a ladder and, slidably coupled to the outer housing, an adjustable ladder leg extension having a direction of extension and an opposite direction of retraction. The outer housing and the leg extension together present a shoe-contactable boundary around the leveler defined as the limit of locations on or near the outer housing and the leg extension that can be contacted by a sphere of 7½ inches diameter (the typical curvature of the inside or outside ball of the foot of a typical shoe).
A spring is coupled to the leg extension and to the outer housing. It urges the leg extension to slide in the direction of retraction. A retaining pawl releaseably connects the outer housing and the leg extension. When the pawl is engaged, it holds the leg extension from sliding in the direction of retraction. The retaining pawl has a release lever.
A foot pedal is coupled at its proximal end via a pivot to the leg extension. The pivot and the foot pedal are configured so that, when pivoted into an action position, the foot pedal presents a foot engagable surface that is perpendicular to the direction of extension and transmits to the leg extension a force applied by a foot in opposition to the spring, causing the extension to extend.
The improvement is that the pivot and the foot pedal are further configured so that, when the foot pedal is pivoted into a non-action position, the distal end of the foot pedal protrudes to form a foot engageable ledge perpendicular to and extending at least ⅛ inch beyond the shoe-contactable boundary so that a human's shoe moving in the direction of extension along the outer housing and the leg extension will catch the foot pedal and cause it to pivot into an action position. For better functionality, the distal end of the foot pedal may protrude at least 5/16 inch beyond the outer shoe-contactable boundary, preferably 9/16 inch beyond the shoe-contactable boundary.
The release lever may also have a distal end protruding at least ¼ inch beyond the outer shoe-contactable boundary of the outer housing and the leg extension so that a human's shoe moving in the direction of extension along the outer housing and the leg extension will catch the release lever to release the pawl. The distal end of the release lever may have a lip extending in the direction of retraction so that a shoe can more easily catch and engage the release lever. For better functionality, the distal end of the release lever may protrude at least ⅜ inch beyond the outer shoe-contactable boundary, preferably 9/16 inch beyond the shoe-contactable boundary.
In another aspect, the invention is an extendable and adjustable ladder leg with an improved shoe with a claw, comprising an extendable and adjustable ladder leg extension having a longitudinal direction of extension and an opposite longitudinal direction of retraction and having a shoe hingedly coupled to a distal end of the leg extension in a way that gives the shoe a range of hinging motion with respect to the hinge and a range of longitudinal motion with respect to the leg extension. The shoe has a hinge pin that forms a hinge axis, as well as a first end that is most distant from the hinge axis, and a second end that is most distant from the first end.
The adjustable ladder leg has a safety bar slidably mounted on the leg extension and coupled to the shoe such that the safety bar moves in the direction of retraction with respect to the leg extension when the shoe moves in the direction of retraction with respect to the leg extension, the safety bar thereby preventing release of a release mechanism that, when activated, releases the leg extension to move in the direction of retraction.
The improvement comprises the shoe having a toothed claw on at least one of the first end or the second end; the shoe including cut-outs that allow the shoe to hinge 180 degrees about the hinge axis when the extension leg is fully retracted; and the shoe including retaining surfaces that contact parts of the leg extension and retain the claw in a fully hinged position when force is applied along the leg extension in the direction of retraction, urging the claw against an object which the claw grips. In addition, the shoe and leg extension parts are configured such that, when the shoe is in a fully hinged position and force is applied along the leg extension in the direction of retraction, the shoe can move toward the leg extension to actuate the safety bar and thereby prevent activation of the release mechanism.
The retaining surfaces that contact parts of the leg extension and retain the shoe in a fully hinged position may comprise part of a circumference of each of two triangular holes, one in each of two sidewalls of the shoe, which retaining surfaces contact a hinge pin coupled to the leg extension.
The triangular holes may each include at least one slope in its circumference which slope is a retaining surface that applies a lateral force to the shoe via contact with the hinge pin when weight is applied to the leg extension while the ladder leg is in an erected position and the shoe is in a fully hinged position.
The retaining surfaces that contact a part of the leg extension and retain the shoe in a fully hinged position may comprise an upper side of a support base of the shoe which upper side contacts a lower corner of the leg extension to retain the shoe in a fully hinged position. In this case, the retaining surfaces also comprise part of a circumference of each of two holes, one in each of two sidewalls of the shoe, which holes, when the shoe is in a fully hinged position, are longer in the longitudinal direction than a diameter of the hinge pin, such that the shoe can move in the direction of retraction with respect to the leg extension after the shoe is in a fully hinged position and thereby place the retaining surfaces in position to retain the shoe in a fully hinged position and simultaneously actuate the safety bar.
In another aspect, the invention is a ladder leg with an improved shoe with a claw, comprising a ladder leg having a longitudinal direction along the leg, having a bottom end, and having a shoe hingedly coupled to the bottom end of the leg in a way that gives the shoe a range of hinging motion with respect to the hinge and a range of longitudinal motion with respect to the leg, the shoe having a hinge pin that forms a hinge axis, a first end that is most distant from the hinge axis, and a second end that is most distant from the first end. The shoe has a toothed claw on at least one of the first end or the second end. The shoe and bottom end of the leg are configured to allow the shoe to hinge about the hinge axis to a point where the shoe base is parallel to the leg.
The improvement comprises: the shoe and leg each have retaining surfaces that contact each other and retain the shoe in a fully hinged position, which retaining surfaces comprise: an upper side of a support base of the shoe which upper side contacts a lower corner of the leg to retain the shoe in a fully hinged position; and a part of a circumference of each of two holes, one in each of two sidewalls of the shoe, which holes, when the shoe is in a fully hinged position, are longer in the longitudinal direction than a diameter of the hinge pin, and the part of the circumference of each of two holes contacting the hinge pin retain the shoe in a fully hinged position. In this event, the shoe can move in the direction of retraction with respect to the leg after the shoe is in a fully hinged position and thereby place the retaining surfaces in position to retain the shoe in a fully hinged position. The two holes may each be triangular in shape.
Ladder Shoe with Fastener Holes
As shown in
The hole or slot in the metal portion of the shoe can be the same size or slightly larger than the penetrating object, (i.e. 16d framing nail) to minimize any friction between the two objects, but the rubber tread underneath the metal portion can be slightly smaller than the penetrating object so that the rubber tread grips the penetrating object tightly, thereby minimizing the chance of it sliding back up and out too easily.
The penetrating object may be slid into the hole or slot when a ladder or leveler is set up on a slippery surface, as an added safety measure. An example would be setting up a ladder on a mossy deck. A nail can be slid through the leveler shoe hole and in between the grooves in between deck boards. A 16d framing nail, or sinker, is the most common nail found on a construction site, used for general framing, temporary scaffolding, saw horses, etc. A 16d framing nail placed in a slightly larger hole in the metal, a slightly smaller hole in the tread make the best combination of holes and penetrating devices.
Additionally, as shown in
The rubber tread 31 located under the bottom, metal surface of the leveler shoe, and riveted on, also has holes of a slightly smaller diameter, in line with the holes in the metal portion of the shoe, so that the nail can penetrate all the way though the shoe assembly, including the holes in rubber tread, and in between deck boards, or the nail can be pounded into a wood surface, such as a subfloor on a new building or on a sheathed roof (sloped or not) of a new structure. The nails can also be used to penetrate into a lawn or any other soft surface that may be wet, moldy, mossy and/or slippery. These holes can also be shaped as slots that would enable a shim or other sharp device to be slid through to act as a securing, or non-skid device.
Claw Foot Locks in 90 Degree Rotation
As shown in
The shoe has specially designed shapes and sizes, with carefully designed relationships between the shapes and sizes, including an elongated hole 205 through which a hinge pin couples the shoe to the ladder leg. When used together, these shapes and sizes and holes enable the bottom tread/claw surface and assembly of the shoe to pivot into the parallel position, in relation to the leg, and then, once pivoted into a parallel position, upward force applied to a claw end of the shoe will slide the shoe upward, the elongated hole allowing the hinge pin to move downward in the hole as shown in
In effect, the shoe becomes wrapped around the lower, outer leg, thus pointing the claw, on the desired end of the shoe, downward toward, and/or into the slippery surface on which the ladder is erected. These special shapes and dimensions allow the shoe to pivot and wrap around the bottom end of the lower leg, while working together with the automatic, back-up safety mechanism, and without any type of interference between the leveler leg, safety mechanism or shoe assembly. Both the shoe locking system and the release lever locking system will remain locked in their respective positions until weight is removed from the ladder leveler.
These new features provide a ladder leveler with a shoe and an automatic, back-up safety lock, having metal claws on either one or both ends of shoe, with the ability to pivot 180 degrees, slide up and down the leveler leg assembly and remain locked parallel to the leveler leg, thereby enabling the claw to dig into ice, snow or other slippery surfaces without concern for accidentally tripping the shoe to the flat position while on the ladder and without concern for retracting the leg extension.
There are various ways to achieve these results, including, but not limited to A.) specially designed, triangular shaped holes in two side flanges of leveler shoe as shown in
This invention provides much more versatility in the ladder leveler because it enables the ladder user to quickly and easily flip the leveler shoe all the way back or forward, allowing the inside, upper surface of the bottom portion of the shoe to slide up against the leg, thereby activating the automatic, back-up, safety mechanism up against the pawl (and its release lever), thereby keeping the pawl locked, without the need to extend the leg extension several inches beforehand. This option enables a ladder user, who prefers not to extend the leveler leg, to easily use the claw on either end of the shoe (double claw shoe—front and back) when setting up a ladder on flat, even surfaces, or uneven surfaces, with ladder levelers that have automatic, back-up safety mechanisms installed.
Lever Controls Actuatable with a Person's Foot
As shown in
The increased length of the release lever adds significantly to the ease of operation by creating quick and easy access to the lever, even when a person with large feet (large shoes) is attempting to depress the lever to release the locking system and retract the leg extension. The slight upward bend 209 in the release lever, located approximately ¼″ from the outermost tip of the lever, creates an angled edge for shoes that may be slippery from being wet, muddy or smooth from wear that is much easier to snag with a foot or toe. Additionally, the top surface of the lever, including the upwardly curved tip 209, has grooves in it for extra grip. The release lever is also shaped so that it will not protrude from the outside face of the ladder leveler to a point at which it would be considered overly obtrusive, thereby creating interference, when the leveler is not in use and/or the ladder and leveler combination is being carried or stored.
As shown in
The proximity and immediate relationship between the two parts (leveler's outer surface and the foot pedal) is critically important in how the foot pedal/locking system will respond when touched with a foot or shoe, particularly in relation to the automatic, back-up, safety mechanism, which is deactivated when weight (load) is removed from the leveler shoe, and activated when weight is placed on the leveler shoe. The special shape is designed so that it is easier to snap up and snap down with a foot, while activating or deactivating the back-up, automatic safety mechanism. This special shape, combined with the extra length (at least ⅛″ beyond the shoe-contactable boundary of the leveler, better 5/16″, preferably 9/16″, and no more than 1″ beyond the shoe-contactable boundary the leveler) is a more ergonomic shape, is easier to reach, and is combined with grooves running perpendicular to the length of the foot pedal for added non-slip features. The foot pedal is also shaped so that it will not protrude from the outside face of the ladder leveler to a point at which it would be considered overly obtrusive, thereby creating interference, when the leveler is not in use and/or the ladder and leveler combination is being carried or stored.
This application is a continuation of application Ser. No. 14/184,662 filed Feb. 19, 2014 and claims priority from my provisional application 61850566 filed Feb. 20, 2013 which is hereby incorporated by reference.
Number | Name | Date | Kind |
---|---|---|---|
544520 | Reiffenstein | Aug 1895 | A |
1379808 | Fies | May 1921 | A |
2691479 | Sharp | Oct 1954 | A |
3456757 | Sain | Jul 1969 | A |
4415062 | Shaw | Nov 1983 | A |
5370203 | Kiska | Dec 1994 | A |
5678656 | Lanzafame | Oct 1997 | A |
6145618 | Verenski | Nov 2000 | A |
20080134620 | Contasti | Jun 2008 | A1 |
Number | Date | Country | |
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20160305186 A1 | Oct 2016 | US |
Number | Date | Country | |
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61850566 | Feb 2013 | US |
Number | Date | Country | |
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Parent | 14184662 | Feb 2014 | US |
Child | 15197272 | US |