Methods and devices for reducing stress and for increasing the load-bearing capacity of cable racks supporting electrical power and communication conduits and cables having increased versatility for conduit and cable sizes and quantities. Underground devices including rack arms for these applications are desirably made from plastic or composite materials. Rack arms desirably include openings for tying down the conduits and cables atop the arms. While non-metallic materials are designed to withstand environmental stresses, they typically have strength and rigidity properties less than the metallic structures previously used in such applications. Non-metallic rack arms with such openings may be reinforced locally with a stress attenuator or with ribs to increase their load-bearing and buckling capacity and to reduce their stress, strain and deflection under load. A stress attenuator may be made by increasing the in-molded thickness of the web in areas adjacent to or surrounding the tie-down openings.

A cable management device for managing cables of a trolling motor is provided. The cable management device can slide axially along a shaft of a trolling motor while being affixed to a portion of a cable of the trolling motor. A trolling motor including such a cable management device is provided.

A cable management device for managing cables of a trolling motor is provided. The cable management device can slide axially along a shaft of a trolling motor while being affixed to a portion of a cable of the trolling motor. A trolling motor including such a cable management device is provided.

A cable manager includes a backbone assembly and at least one side wall extending from the backbone assembly. The at least one side wall optionally includes one or more cable finger units. The backbone assembly includes a spine member having an extruded construction. The spine member includes one or more channels extending substantially an entire length thereof to facilitate easy attachment, removal and/or repositioning of a structure relative to the spine member. The cable manager optionally includes an accessory rod, a half-spool assembly, a cable finger accessory, a strap/buckle accessory, and/or a door assembly having an interference-free hinge set.

A cable manager includes a backbone assembly and at least one side wall extending from the backbone assembly. The at least one side wall optionally includes one or more cable finger units. The backbone assembly includes a spine member having an extruded construction. The spine member includes one or more channels extending substantially an entire length thereof to facilitate easy attachment, removal and/or repositioning of a structure relative to the spine member. The cable manager optionally includes an accessory rod, a half-spool assembly, a cable finger accessory, a strap/buckle accessory, and/or a door assembly having an interference-free hinge set.

A cable management device for managing cables of a trolling motor is provided. The cable management device can slide axially along a shaft of a trolling motor while being affixed to a portion of a cable of the trolling motor. A trolling motor including such a cable management device is provided.

A cable management device for managing cables of a trolling motor is provided. The cable management device can slide axially along a shaft of a trolling motor while being affixed to a portion of a cable of the trolling motor. A trolling motor including such a cable management device is provided.

A grommet assembly configured to be disposed within an aperture in a panel having a first surface and a second surface opposite the first surface is presented herein. The grommet assembly includes a grommet frame configured to contact the first surface of the panel and an elastomeric region extending from the grommet frame and configured to be inserted within the aperture. The elastomeric region defines a plurality of ribs angled such that the ribs are configured to provide an insertion force when the elastomeric region is inserted within the aperture and provide a removal force greater than the insertion force when the elastomeric region is withdrawn from the aperture. A method of manufacturing the grommet assembly is also presented.

A grommet assembly configured to be disposed within an aperture in a panel having a first surface and a second surface opposite the first surface is presented herein. The grommet assembly includes a grommet frame configured to contact the first surface of the panel and an elastomeric region extending from the grommet frame and configured to be inserted within the aperture. The elastomeric region defines a plurality of ribs angled such that the ribs are configured to provide an insertion force when the elastomeric region is inserted within the aperture and provide a removal force greater than the insertion force when the elastomeric region is withdrawn from the aperture. A method of manufacturing the grommet assembly is also presented.

A method of attaching a line to a support structure includes providing a holder having a fastening section, a side-part section, a closure section, and an engagement section, where the fastening section, the side-part section, and the engagement section define a ring having a gap. The method further includes fastening the fastening section to the support structure, bending the side-part section with respect to the fastening section after the fastening section has been fastened to the support structure, inserting the line through the gap into the ring, and bending the closure section with respect to at least one of the fastening section, the side-part section, and the engagement section such that the closure section engages the engagement section and closes the gap.