Devices, systems, and methods are directed to mounting an auxiliary component to a tower based at least in part on a force distribution in which a normal force is greater than a shear force exerted by the auxiliary component on a shell of the tower such that the auxiliary component may be held in place relative to the tower without penetrating the shell of the tower. Thus, as compared to mounting techniques requiring penetration of the shell of the tower, this force distribution along the shell of the tower may facilitate mounting the auxiliary component to the tower with little to no impact on cost and/or structural requirements of the tower. Further, or instead, as compared to other mounting techniques, mounting the auxiliary component based at least in part on this force distribution may reduce or eliminate the need for specialized tools, thus facilitating in-field installation of the auxiliary component.

Devices, systems, and methods are directed to mounting an auxiliary component to a tower based at least in part on a force distribution in which a normal force is greater than a shear force exerted by the auxiliary component on a shell of the tower such that the auxiliary component may be held in place relative to the tower without penetrating the shell of the tower. Thus, as compared to mounting techniques requiring penetration of the shell of the tower, this force distribution along the shell of the tower may facilitate mounting the auxiliary component to the tower with little to no impact on cost and/or structural requirements of the tower. Further, or instead, as compared to other mounting techniques, mounting the auxiliary component based at least in part on this force distribution may reduce or eliminate the need for specialized tools, thus facilitating in-field installation of the auxiliary component.

A ladder standoff includes at least one bent plate that is configured to be detachably engaged with at least one ladder rung of a ladder by at least one connection plate that is configured to be detachably connected to the bent plate and to the ladder rung. The ladder standoff may be attached to a ladder and used to secure a ladder to a vertically-extending building wall structure at a selected distance. The length of the ladder standoff can be extended in a substantially horizontal direction in relation to the vertically extending ladder and vertically extending building wall to provide a ladder standoff with variable lengths to accommodate different distances between the ladder and the surface of the vertically extending building wall.

A ladder support attachment for spacing a ladder from a structure having a support member configured to mount to the structure and stabilizing the ladder; a spacing member integrally coupled to and extending outwardly from an upper edge of the support member; and a trough member integrally coupled to a distal edge of the spacing member and configured to receive a rung of the ladder. The trough member having a first planar member coupled to a distal edge of the spacing member at an acute angle relative to the support member, a second planar member coupled to a portion of a distal edge of the first planar member and extending transverse to the first planar member, and a third planar member being coupled to a distal edge of the second planar member and extending transverse to the first planar member.

Ribs for an elevating platform, the ribs designed and configured to insert through a slot in the sidewall of the elevating platform. The ribs are composed of T-shaped and/or L-shaped portions. Configurations include a T-shaped rib that inserts through the slot; a combination T-shaped and L-shaped rib wherein the T-shaped component inserts through the slot and the L-shaped component is attached on the exterior of the platform, and a double-L-shaped rib, wherein one of the L-shaped components inserts through the slot and the other L-shaped component is attached to it on the exterior of the platform.

Ribs for an elevating platform, the ribs designed and configured to insert through a slot in the sidewall of the elevating platform. The ribs are composed of T-shaped and/or L-shaped portions. Configurations include a T-shaped rib that inserts through the slot; a combination T-shaped and L-shaped rib wherein the T-shaped component inserts through the slot and the L-shaped component is attached on the exterior of the platform, and a double-L-shaped rib, wherein one of the L-shaped components inserts through the slot and the other L-shaped component is attached to it on the exterior of the platform.

A modular ladder system has a rung section having two elongate lateral stile extrusions and elongate rung extrusions spanning therebetween. Each stile extrusion may define an attachment side having an attachment face which has two attachment channels which are adjacent, parallel and longitudinally arranged along the attachment face. Each attachment channel may have inward facing rails which define an elongate insertion space therebetween and a relatively wider connector head accommodation void thereunderneath. Furthermore, each rail may define a connector head engaging under edge. Each stile extrusion may further define a connection side adjacent to the attachment side which may define a splice joint extrusion accommodating void therein. In this way, the present modular ladder system may be quickly and easily constructed and various accessories quickly and easily attached thereto.

A modular ladder system has a rung section having two elongate lateral stile extrusions and elongate rung extrusions spanning therebetween. Each stile extrusion may define an attachment side having an attachment face which has two attachment channels which are adjacent, parallel and longitudinally arranged along the attachment face. Each attachment channel may have inward facing rails which define an elongate insertion space therebetween and a relatively wider connector head accommodation void thereunderneath. Furthermore, each rail may define a connector head engaging under edge. Each stile extrusion may further define a connection side adjacent to the attachment side which may define a splice joint extrusion accommodating void therein. In this way, the present modular ladder system may be quickly and easily constructed and various accessories quickly and easily attached thereto.

A shelf electrical signal connector is provided that includes a ladder connector and a shelf connector. The ladder connector mounts to a ladder of a shelving system and includes a spring-loaded contact pin formed of an electrically conductive material and electrically connected to a first wire configured to carry an electrical signal. The shelf connector mounts to a shelf bracket and includes a contact pad formed of an electrically conductive material that is connected to a second wire. The contact pad abuts and rests on the spring-loaded contact pin to electrically connect the first wire to the second wire when the shelf bracket is mounted to the ladder of the shelving system.

A shelf electrical signal connector is provided that includes a ladder connector and a shelf connector. The ladder connector mounts to a ladder of a shelving system and includes a spring-loaded contact pin formed of an electrically conductive material and electrically connected to a first wire configured to carry an electrical signal. The shelf connector mounts to a shelf bracket and includes a contact pad formed of an electrically conductive material that is connected to a second wire. The contact pad abuts and rests on the spring-loaded contact pin to electrically connect the first wire to the second wire when the shelf bracket is mounted to the ladder of the shelving system.