The present invention relates generally to ladders, including stepladders, and methods of making and using such ladders.
Ladders are conventionally utilized to provide a user thereof with improved access to elevated locations that might otherwise be inaccessible. Ladders come in many shapes and sizes, such as straight ladders, straight extension ladders, stepladders, and combination step and extension ladders. So-called combination ladders may incorporate, in a single ladder, many of the benefits of multiple ladder designs.
Ladders such as stepladders and step stools are highly utilized by various tradesman as well as homeowners. Such ladders are “self-supporting” in that they do not require the upper end of the ladder to be positioned against a supporting structure, such as against a wall or the edge of a roof. Rather, stepladders (including step stools) include multiple feet (typically either three or four) that are spaced from one another to provide a stable base or foundational structure to support the ladder and a user when placed on, for example, a floor or the ground. This enables a user of the ladder to gain access to elevated areas even though the accessed area may be, for example, in the middle of a room, away from walls or other potential supporting structures that are conventionally required when using a straight ladder or an extension ladder.
For these reasons and others, ladders configured as stepladders or step stools are popular configurations that comprise a large segment of the ladder market. However, there are always areas of potential improvement. For example, the rungs on conventional configurations of stepladders typically exhibit relatively short depth, meaning that there is a relatively small amount of surface area for a user to place their foot on while standing on the rungs of a step ladder. Some ladders have attempted to increase the depth of the rungs in an effort to provide a more comfortable or stable support surface for a user of the ladder. However, often the increase in depth of a rung translates to more bulk in the stored ladder. For example, where the rungs are static and rigidly fixed to the side rails, the rail assembly becomes larger in its overall depth. It follows that that the stored ladder (i.e., when folded or collapsed for storage) exhibits a greater depth as well.
Some ladders, primarily step stools, have utilized rungs that fold or pivot when the ladder is collapsed for storage. However, these ladders typically include struts or braces coupled to the rungs and to another structure on the ladder such as a platform, a rail, or another rung. The struts or braces typically provide a couple of functions with respect to the rungs. First, the struts or braces are coupled to a cantilevered end of the rung to provide structural support to the rung so that it can bear an anticipated load. Second, the struts or braces act as linkages to help “lift” the rung into a folded position when the ladder is being collapsed for storage. Examples of such configurations are shown in U.S. Pat. No. 3,303,906 to Bouwmeester et al. and U.S. Pat. No. 5,722,507 to Kain.
It is a continued desire of the ladder industry to improve the performance of ladders, including stepladders and step stools. For example, it is a continued desire within the ladder industry to provide products that provide a safer working experience for the user, provide added comfort to the user, and enhance the user's experience in a variety of ways.
The present invention relates to various configurations of ladders and to methods relating to the use and manufacture of stepladders.
In accordance with one embodiment, a ladder is provided that comprises a first assembly having a pair of spaced apart rails and at least one rung extending therebetween and a second assembly having a pair of spaced apart rails, second assembly being hingedly coupled with the first assembly. The at least one rung includes a first component extending between and fixedly coupled to the pair of rails of the first assembly and a second component extending between and rotatably coupled to the pair of rails of the first assembly, wherein when in a first position, a surface of the second component abuts a surface of the first component such that rotation in a first direction is prohibited.
In one embodiment the second assembly of the ladder includes at least one bracing member extending between and coupled to the pair of rails of the second assembly, wherein when the second assembly is rotated adjacent the first assembly, the at least one bracing member contacts an undersurface of the second component of the at least one rung. The at least one bracing member may be configured to push against the undersurface of the second component and rotate the second component in a second direction opposite the first direction. In one embodiment, a flexible material component positioned between the first component of the rung and the second component of the rung.
The ladder may further comprise a platform rotatably coupled with the first assembly and configured to selectively engage the second assembly. In one embodiment a locking mechanism may be configured to selectively lock the platform with a component of the second assembly.
The rails of the first assembly may extend beyond a hinge point between the first and second assemblies. A handle may extend between and coupling upper ends of the pair of rails of the first assembly and the handle may further be configured for selective coupling with at least one accessory.
In accordance with another embodiment of the present invention, a method of transitioning a ladder from a deployed state to a stowed state is provided. The method includes rotating a first assembly relative to a second assembly in a first direction until an undersurface of a first rung associated with the first assembly is engaged by a component of the second assembly; and continuing to rotate the first assembly relative to the second assembly in the first direction such that the component of the second assembly effects rotation of at least a portion of the first rung relative to a pair of rails of the first assembly.
The method may further include rotating the at least a portion of the first rung to lie within an envelope defined by the pair of rails of the first assembly and, further, may include maintaining the first rung in a rotated position with the component of the second assembly while the ladder is in the stowed state.
In one embodiment, the method includes engaging an undersurface of a second rung of the first assembly with a second component of the second assembly and continuing to rotate the first assembly relative to the second assembly in the first direction such that the second component of the second assembly effects rotation of at least a portion of the second rung relative to a pair of rails of the first assembly. The at least a portion of the first rung and the at least a portion of the second rung may be rotated in a sequential order upon rotation of the first assembly relative to the second assembly.
In accordance with another aspect of the invention, a ladder is provided comprising a first assembly having a pair of spaced apart rails and at least one rung having a first component extending between and pivotally coupled to the pair of rails, the first component including an abutment surface, a platform surface, and a ramped surface. The ladder also includes a second assembly having a pair of spaced apart rails, second assembly being hingedly coupled with the first assembly. The second assembly includes at least one component located and configured to engage the ramped surface of the first component when the second assembly is displaced relative to the first assembly from a deployed state to a collapsed state.
In one embodiment, the at least one rung component is configured to rotate the at least one rung relative the rails of the first assembly when the second assembly is displaced relative to the first assembly from a deployed state to a collapsed state.
In one embodiment, the first component includes a substantially triangular cross-sectional profile.
In accordance with one embodiment, the at least one rung includes a second component extending between and fixedly coupled with the rails of the first assembly. The second component may include a platform surface and an abutment surface.
The first component may be configured to rotate from a first position to a second position relative to the second component. In one embodiment, when the first component is in the first position, the platform surface of the first component and the platform surface of the second component lie in a substantially common plane. When the first component is in the second position, the platform surface of the first component is positioned at an angle relative to the platform surface of the second component. Additionally, in one embodiment, when the first component is in the first position, the abutment surface of the first component is in abutting contact with the abutting surface of the second component.
In one embodiment, the at least one component includes a brace extending between and fixedly coupled to the rails of the second assembly.
Various features and components of any of the embodiments described herein may be combined with features or components of other embodiments without limitation.
The foregoing and other advantages of the invention will become apparent upon reading the following detailed description and upon reference to the drawings in which:
It is noted that numerous photographs are also included in the detailed description and reference should be made to these photographs in association with
Referring generally to
The ladder 100 also includes a second assembly 108 having a pair of spaced apart rails 110. The second assembly 108 includes bracing members 111 or other structural components that extend between the rails 110 to provide a desired level of structural support and strength to the spaced apart rails 110. In some embodiments, the bracing members 111 of the second assembly 108 may be configured as rungs to support a user. The second assembly 108, thus, may be used to help support the ladder 100 when in an intended operational state, such as depicted generally in
In the embodiment shown in
It is noted that in the embodiment shown in
In the embodiment shown in
The first and second assemblies 102 and 108 may be formed of a variety of materials and using a variety of manufacturing techniques. For example, in one embodiment, the rails 104 and 110 may be formed of a composite material, such as fiberglass, while the rungs and other structural components may be formed of aluminum or an aluminum alloy. In another embodiment, substantially all of the components of the assemblies may be formed of aluminum or an aluminum alloy. In other embodiments, the assemblies 102 and 108 (and their various components) may be formed of other materials including other composites, plastics, polymers, various metals and metal alloys.
The rungs 106 of the first assembly 102 are formed of multiple components. In the embodiment shown, the rungs 106 each include a first component 106A that extends between, and is rigidly coupled to, the side rails 104. The first component 106A is located near the outward facing portion of the assembly 102 (i.e., the side which faces a user as they ascend and descend the rungs 106). In one particular embodiment, the first component 106A includes a front surface 120 that is substantially flush with the front surface 122 of the rails 104 such that they define a common plane. The rungs 106 further include a second component 106B that extend between the rails 104 but which are positionable relative to the rails 104. For example, in one embodiment, the second component 106B may be hingedly coupled to the rails 104. In another embodiment, the second component 106B may be hingedly coupled with the first component. In either case, the second component 106B may be rotated relative to both the first component 106A and the rails 104. For example,
Thus, when the ladder 100 is in folded or collapsed into a stored state, the second components 106B of the rungs may be folded up within an envelope that may be defined, in one embodiment, by the rails 104 of the first assembly 102. For example, the envelope may be bound on one side by a plane defined by the front surface 122 of the rails 104, and bound on another side by a substantially parallel plane defined by the back surface 124 of the rails 104. The rotated or folded-up position of the second component 106B may be seen, for example, in
It is noted that there are no connecting struts, bracing members or other structural components coupled to the second components 106B of the rungs 106. For example, no structural components are coupled between the cantilevered ends of the second components (i.e., the ends closest to the second assembly 108 as shown in
For example, as may be seen best in the cross-sectional views of
The underside 144 of the second component 106B provides a ramped surface for engagement with a component of the second assembly 108 during the folding or collapsing of the ladder 100. In one embodiment, the underside of the second component may include a curved surface (e.g., generally convex in cross-sectional profile as seen in
Still referring to
When opening the ladder 100, or transitioning from the stowed/stored state to a deployed state, the second components 106B simply “fall” or rotate back into their cantilevered position by reason of gravity. Again, no linkages, struts or other such components are used to effect rotation of the second components 106B of the rungs 106, or to provide structural support to them when in a cantilevered position. Thus, deployment of the ladder 100, including deployment of the second component 106B, occurs in the reverse order as that shown in
Referring briefly to
In certain embodiments, the rungs 106 of the ladder may include additional components. For example, in one embodiment, a flexible material (e.g., rubber or some other polymer material) may extend between the first component 106A and the second component 106B along the upper surface. Such a layer may help to conceal a potential pinch point (e.g., when the second component 106B is rotating relative to the first component 106A) and may help to keep dirt and debris from entering the space between the two components 106A and 106B. The flexible component may also act as a gripping surface to prevent slipping of a user when their foot is placed on the rung 106. In some embodiments, the flexible material may extend to cover part or substantially all of the upper surface of the first component 106A, the second component 106B or both.
The ladder 100 may further include other features and components. For example, as shown in
Other features and components may include, for example, feet 130 on the ends of the rails 104 and 110 which may be configured as clip on components such as described in the above referenced U.S. patent application Ser. No. 13/402,013.
While the invention may be susceptible to various modifications and alternative forms, specific embodiments have been shown by way of example in the drawings and have been described in detail herein. Of course, one or features of one described embodiment may be utilized in conjunction with one or more features of another described embodiment. It should be understood that the invention is not intended to be limited to the particular forms disclosed. Rather, the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the following appended claims.
This application claims the benefit of U.S. Provisional Patent Application No. 61/764,439 entitled LADDERS AND RELATED METHODS, filed on Feb. 13, 2013, the disclosure of which is incorporated by reference herein in its entirety.
Number | Date | Country | |
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61764439 | Feb 2013 | US |