Ladders are conventionally employed to provide a user thereof with improved access to 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 (referred to herein as combination ladders). Combination ladders incorporate, in a single ladder, many of the benefits of other ladder designs as they can be used as an adjustable stepladder or as an extension ladder.
Ladders are common tools for professional tradesman and homeowners alike. Sometimes the use of a ladder can be an awkward experience, even for those who use ladders on a regular basis, when certain tasks are to be performed while standing on the rungs of a ladder. For example, it can be easy to lose one's balance on a ladder while w working on an overhead project (e.g., painting a ceiling, changing a light bulb, etc.).
Sometimes, a ladder may be, or at least feel, unstable when leaning against, and supported by, an edge of a roof (e.g., the rain gutter positioned against the edge of the roof), particularly if a user reaches out beyond the side rails of the ladder while working, changing the load dynamics experienced by the ladder. Thus, when leaning a ladder against a support surface (a wall, the edge of a roof, etc.), sometimes it is desirable to provide additional stability.
Another difficulty when using ladders includes exiting an upper portion of the ladder onto another surface. For example, when a combination ladder, a straight ladder or an extension ladder is used to access a roof, the transition from the ladder to the roof (and vice versa) introduces potential for slipping, tripping and substantial injury. Thus, it is sometimes desirable to provide so-called walkthrough devices to offer a structure that a user can grab or otherwise interact with in providing stability during such transitions.
While various accessories or “add-on” features may help to provide an improved stability and safety, if a ladder becomes laden with too many accessories, it becomes overly heavy, awkward to maneuver, and difficult to store and transport. Thus, in some instances, users would prefer to do without accessories or features that might otherwise provide increased stability or safety during use of a ladder.
It is a continual desire within the industry to improve various aspects of ladders including their safety, functionality, ergonomics and efficiency of use.
The present disclosure provides embodiments of ladders and accessories for ladders. The ladders and accessories may be deployed in any of several selected configurations including, for example, a walkthrough configuration, a standoff configuration, or a stored configuration.
In one embodiment, a ladder is provided that comprises a first rail assembly comprising including a first pair of rails and a first plurality of rungs coupled to the first pair of rails, a second rail assembly including a second pair of rails and a second plurality of rungs coupled to the second pair of rails, a pair of hinges rotatably coupling the first rail assembly with the second rail assembly, at least one bracket positioned on a laterally outer side surface of a first rail of the first pair of rails, at least another bracket positioned on a laterally outer side surface of a second rail of the first pair of rails a first component releasably coupled with the at least one bracket in at least two different positions including a storage position and a walkthrough position and a second component releasably coupled with the at least another bracket in at least two different positions including a storage position and a walkthrough position.
In one embodiment, the ladder further comprises at least one transverse bracket coupled to at least one of the first rail and the second rail.
In one embodiment, the first component is configured for releasable coupling with the at least one transverse bracket and the second component is configured for releasable coupling with the at least one transverse bracket.
In one embodiment, the ladder further comprises a coupling component extending between the first component and the second component when the first component is coupled with the at least one transverse bracket and when the second component is coupled with the at least one transverse bracket.
In one embodiment, the coupling component is a v-shaped component.
In one embodiment, the first component is coupled with the at least one transverse bracket, the first component extends substantially transverse to a plane in which the first rail and the second rail extend.
In one embodiment, the first component and the second component each include an end cap having an engagement surface.
In one embodiment, the first component and the second component each include a first arm d a second arm telescopingly coupled with the first arm.
In one embodiment, the first component and the second component each include an engagement member pivotally coupled with the second arm, the engagement member being selectively locked in two different positions relative to the second arm.
In one embodiment, the first component and the second component each have a length extending in a common plane with the first rail and the second rail regardless of whether the first component and the second component are in their respective first positions or second positions.
In one embodiment, the ladder further comprises a lock pin coupled with the first component and configured to engage a first opening formed in a least one of the first rail or the at least one bracket when rail is in the first position.
In one embodiment, the ladder further comprises a biasing member configured to bias the lock pin into engagement with the first opening.
In one embodiment, the ladder further comprises a pair of actuator members pivotally coupled with the lock pin.
In one embodiment, the pair of actuator members includes a first member positioned on a first side of an arm of the first component and a second member on an opposing side of the arm of the first component, wherein when the first actuating member and the second actuating member are displaced towards each other, a free end of the lock pin retracts relative to the at least one bracket.
In one embodiment, the first assembly includes a first pair of inner rails slidably coupled with the first pair of rails and wherein the second assembly includes a second pair of inner rails slidably coupled with the second pair of rails.
In one embodiment, the ladder further comprises a third plurality of rungs coupled between the first pair of inner rails and a fourth plurality of rungs coupled between the second pair of inner rails.
In accordance with another embodiment of the present disclosure, an accessory for a ladder is provided. The accessory comprises at least one arm, at least one bracket coupled with the at least one arm and a locking mechanism associated with the at least one bracket. The locking mechanism includes a first actuating member positioned on a first side of the at least one arm, a second actuating member positioned on a second opposing side of the at least one arm, a lock pin pivotally coupled with the first and second actuating members, the lock pin extending through a first portion and a second portion of the at least one arm, a biasing member positioned about a portion of the lock pin and biasing the lock pin in a first direction, wherein, when the first and second actuating members are displaced towards each other, the lock pin is displaced in a second direction, opposite the first direction.
In one embodiment, the at least one arm includes a first arm and a second arm telescopingly coupled with the first arm.
In one embodiment, the ladder further comprises an engagement member pivotally coupled with the at least one arm.
In one embodiment, the ladder further comprises a second locking mechanism configured to selectively lock the engagement member in a first position and at least a second position relative to the at least one arm.
In one embodiment, when in the first position, the engagement member extends longitudinally outward from the at least one arm and, when in the at least a second position, the engagement member extends at an angle of substantially 90 degrees relative to a length of the at least one arm.
Features, components and aspects of one embodiment may be combined with features, components and aspects of any other embodiment 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:
Referring to
The combination ladder 100 also includes a second rail assembly 114 that includes an inner assembly 114A slidably coupled with an outer assembly 114B. The inner assembly 114A includes a pair of rails 116 coupled with a plurality of rungs 118 and is configured similar to the inner assembly 102A of the first rail assembly 102A described hereinabove. Likewise, the outer assembly 114B includes a pair of rails 120 coupled with a plurality of rungs 122 and is configured similar to the outer assembly 102B of the first rail assembly 102 described hereinabove. Locking mechanisms 124 may be associated with inner and outer assemblies 114A and 114E to enable selective positioning of the inner assembly 114A relative to the outer assembly 114B as described with respect to the first rail assembly 102 hereinabove.
Some examples of locking mechanisms that may be used with the first and second rail assemblies 102 and 114 are described in U.S. Pat. No. 8,186,481 (the '481 patent) issued May 29, 2012, and U.S. Patent Application Publication No. 20170254145, published Sep. 7, 2017, the disclosures of which are incorporated by reference herein in their entireties. While the locking mechanism described in '481 patent is generally described in conjunction with an embodiment of an adjustable step ladder, such a locking mechanism may by readily used with an embodiment such as the presently described combination ladder as well. It is additionally noted that, in one embodiment, the rail assemblies 102 and 114 may be configured similar to those which are described in U.S. Pat. No. 4,210,224 to Kummerlin, the disclosure of which is incorporated by reference in its entirety, the disclosure of which is incorporated by reference herein in its entirety.
The first rail assembly 102 and the second rail assembly 114 are coupled to each other may way of a pair hinge mechanisms 126. Each hinge mechanism 126 may include a first hinge component coupled with a rail of the first rail assembly's inner assembly 102A and a second hinge component coupled with a rail of the second rail assembly's inner assembly 114A. The hinge components of a hinge pair 126 rotate about a pivot member such that the first rail assembly 102 and the second rail assembly 114 may pivot relative to each other. Additionally, the hinge mechanisms 126 may be configured to lock their respective hinge components (and, thus, the associated rails to which they are coupled) at desired angles relative to each other. One example of a suitable hinge mechanism is described in U.S. Pat. No. 4,407,045 to Boothe, the disclosure of which is incorporated by reference herein in its entirety. Additional examples of hinges and hinge mechanisms are described in U.S. Pat. No. 7,364,017, issued Apr. 29, 2008, U.S. Patent Application Publication No. 20170356244, published Dec. 14, 2017, the disclosures of which are incorporated by reference herein in their entireties. Of course other configurations of hinge mechanisms are also contemplated as will be appreciated by those of ordinary skill in the art.
The combination ladder 100 is constructed so as to assume a variety of states or configurations. For example, using the locking mechanisms (112 or 124) to adjust a rail assembly (102 or 114) enables the ladder 100 to adjust in height. More specifically, considering the first rail assembly 102, as the rail assembly 102 is adjusted, with the outer assembly 102B being displaced relative to the inner assembly 102A, the associated locking mechanisms 112 engages the inner and outer assemblies (102A and 102B) when they are at desired relative positions with the rungs (106 and 110) of the inner and outer assemblies (102A and 102B) at a desired vertical spacing relative to each other. At some of the adjustment heights of the rail assembly 102, at least some of their respective rungs (106 and 110) align with each other (such as shown in
Considering the embodiment shown in
Additionally, the hinge mechanisms 126 provide for additional adjustability of the ladder 100. For example, the hinge pairs 126 enable the first and second rail assemblies 102 and 114 to be adjusted to a variety of angles relative to each other. As shown in
The ladder 100 may additionally include feet 130 coupled with the lower extents of the outer rails 108 and 120 of the first and second assemblies 102 and 104. Feet or other structures may also be coupled wo the inner rails 104 and 116 of the first and second assemblies 102 and 104. In some embodiments, wheels 132 may be coupled with one of the assemblies (e.g., the outer rails 108 of the first assembly) for purposes of transporting the ladder by tipping the ladder 100 such that the wheels 132 engage the ground and rolling the ladder between locations) When the ladder 100 is in a usable configuration, such as a step ladder as shown in
As seen in
In one embodiment, the components 140A and 140B may be removably coupled to the rails 108 by way of brackets 142 coupled to the rails 108 and mating brackets 144 coupled with the components 140A and 140B. Each component 140A and 140B may further include a locking pin 146 that engages an opening in the associated rail 108 to maintain the component 140A or 140B in a locked position relative to its associated rail 108. For example, with the lock pins 146 engaged as shown in
As shown in
As seen in
Referring now to
When assembling the components 140A and 140B in a stand-off configuration, a third, v-shaped component 180 may be used to couple their respective proximal ends 182. For example, the proximal ends 182 may include a spring biased button 184 or other detent mechanism configured to extend through corresponding openings 186 formed in the third component 180 as perhaps best seen in
The components 140A and 140B may include additional features for use as a stand-off device. For example, caps 190 or other devices may be coupled with the components 140A and 140B at or near their distal ends 172. These caps 190 may include non-marring, non-marking materials so that as they engage with an upper support structure (e.g., the siding or stucco of a wall), they are less likely to leave marks or damage the support structure any way. Additionally, the caps 190 or other features may include slip resistant portions to help provide traction between the components 140A and 140B and the support structure, helping to keep the ladder more stable during use. In one embodiment, the caps 190 may include engagement surfaces 192 that are oriented at an angle relative to the length or longitudinal axis of the components 140A and 140B, such that they are substantially parallel with an anticipated surface of engagement. Statement another way, the engagement surfaces, or a substantial portion thereof, may extend in a plane that is substantially parallel to the plane in which the rails 108 extend.
It is noted that in other embodiments, the brackets 170 to which the components 140A and 140B are coupled may be located on the back surface of the rails 108 such that the components 140A and 140B may be positioned on the back side of the ladder 100. However, coupling the stand-off device with the front side of the ladder may provide some benefits such as ease of assembly for the user while also serving as a natural barrier to prevent a user from climbing beyond a desired height on the ladder. Further, it is noted that the brackets 170 are positioned in close proximity to the top-most rung 110 (in the orientation shown in
Referring now to
In one embodiment, the components 200A and 200B may be removably coupled to the rails 108 by way of brackets 202 coupled to the rails 108 and mating brackets 204 coupled with the components 200A and 200B. Each component 200A and 200B may further include a locking mechanism 206 configured to lock the component 200A or 200B to its associated rail 108 or to other components as discussed below. In some embodiments, the brackets 204 coupled with the components 200A and 200B may be integrated into, at least partially, the locking mechanism 206 such as further discussed below. When the components 200A and 200B are coupled with the rails 108 and the locking mechanism 206 is unactuated, the components 200A and 200B are locked in a stored configuration, such as shown in
Referring to
In one embodiment, the components 200A and 200B may extend substantially parallel to their associated rails 108, or at least relative to the portions of the rails 108 to which they are attached (e.g., the flared or angled portions of the rails 108). In another embodiment, the components 200A and 200B may include a bent portion to position them closer to one another and providing a walk through space that is reduced in width. In some embodiments, when in the walkthrough configuration, the components 200A and 200B may extend in a common plane as the rails 108. In some embodiments, additional features or structures may be associated with the components 200A and 200B, including, for example, handles, slip resistant portions for grasping by a user, and the like.
Referring now to
Additionally, in this configuration, the engagement members 212 located at the laterally outer ends of the components 200A and 200B may be pivotally rotated relative to the main arms 214 (which, as discussed below, may include first and second arm members 220 and 222) of the components 200A and 200B such that an engagement surface 216 of each engagement member 212 is positioned behind or rearward of the ladder 100. Thus, when the ladder 100 is positioned against an upper supporting surface or structure (e.g., a wall, edge of a roof, etc.), the engagement members 212 contact the supporting structure while the remainder of the ladder 100 (e.g., the rails 108) remains spaced away from the supporting structure a desired distance. As with other embodiments, the engagement members 212 may include or incorporate non-marring, non-marking materials so that as they engage with an upper support structure (e.g., the siding or stucco of a wall), they are less likely to leave marks or damage the support structure in any way. Additionally, the caps 190 or other features may include slip resistant portions to help provide traction between the components 140A and 1408 and the support structure, helping to keep the ladder more stable during use.
With the components 200A and 200B in the stand-off configuration, the ladder 100 may be further stabilized with wider points of contact against the upper support structure. Such a configuration may also help to avoid potential damage to portions of the support structure. For example, use of a stand-off stabilizer helps to avoid placing undue force by the ladder rails on a structure such as a rain gutter, a window or other structure.
Comparing
Referring to
The component 200A includes a pair of shafts or arm members 220 and 222 telescopingly coupled to one another (e.g., with the second arm 222 having a smaller cross-sectional area than, and slidingly fitting within and interior portion of the first arm 220). A pair of bushings or spacers 224 and 226 may be coupled between the two arm members 220 and 222 to accommodate the telescoping arrangement of the two arms 220 and 222. An arm lock assembly 226 may be coupled to one or both of the arms 220 and 222 to lock the two arms in a desired position relative to one another.
For example, as shown in
When the lever 230 is pivoted such that the engagement pin is retracted from the opening in the second arm 222 (e.g., opening 236B) as shown in
Referring back to
As previously noted, the component 200A may also include a bracket 202 for coupling the component 200A with the ladder 100. In one embodiment, the bracket 204 may include multiple bracket members 204A-204C aligned along a length of the first arm 220. In one embodiment, one of the bracket members (e.g., 204B) may also function as a cover for the locking mechanism 206, being positioned over actuator members 250 (also referred to as squeeze handles) of the locking mechanism 206. The bracket 202 may be configured with grooves or slots that are sized and configured to receive correspondingly shaped and sized portions of mating brackets (e.g., brackets 202 or 210) such as previously discussed.
In one embodiment, the locking mechanism 206 may be configured as a squeeze mechanism having a pair of actuator members 250, hingedly coupled via a spring pin or hinge pin 252. The locking mechanism 206 may further include an engagement pin or a lock pin 254 coupled with the spring pin 252, and a biasing member such as a coiled spring 256, configured to bias the lock pin 254 radially outward through an opening 258 formed in the first arm 220 (and a corresponding opening formed in any bracket component—e.g., bracket component 204B—positioned adjacent the opening 258).
As seen in
As seen in
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. However, it should be understood that the invention is not intended to be limited to the particular forms disclosed. Additionally, features, components and aspects of one embodiment may be combined with features, components and aspects of any other embodiment without limitation. The disclosure is considered to include 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. 62/584,279 filed Nov. 10, 2017, entitled WALKTHROUGH AND STANDOFF MECHANISMS FOR LADDERS, LADDERS INCORPORATING SAME AND RELATED METHODS, the disclosure of which is incorporated by reference herein.
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