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.

Provided is a hydraulic piping clamp device for a construction machine, with which it is possible to easily assemble a plurality of clamp members used to fasten hydraulic piping. A fastener (5) includes a bracket (6) and a plurality of clamp members (7). Hydraulic hoses (4) are respectively held by the plurality of clamp members (7). Each clamp member (7) has a holding portion (71) for holding a hydraulic hose and an insertion hole into which a guide bar (65) can be inserted. The clamp members (7) are mounted on the bracket (6) by inserting the guide bar (65) into the insertion hole in the clamp members (7). When two adjacent clamp members move away from one another, a first engaging portion (73) of one clamp member engages with a second engaging portion (75) of the other clamp member.

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 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 system for spacing and fastening tubular structures, and a related method. The system includes a spacer element configured to engage a plurality of tubular structures, to spatially separate the plurality of tubular structures from one another, and to distribute stress in the plurality of tubular structures. The system further includes a fastening element configured to extend around at least a portion of an outer surface of the plurality of tubular structures, and to fasten the plurality of tubular structures to the spacer element in an adaptively spaced configuration.

A method of adapting an electronic equipment structure for cable management, the method comprising: providing a cable manager having one or more cable finger units extending from a frame, the frame including at least one spine member having an extruded construction and one or more ledges that extend along a length thereof; providing an accessory rod assembly having a base member and an accessory rod, wherein the base member includes a front-facing socket, a rear-facing hook, and a rotatable knob having a threaded end received within a threaded portion at a side of the base member, and wherein the accessory rod has an extruded construction and a generally uniform, at least partially cylindrical, cross-sectional shape; positioning the rear-facing hook of the base member against one side of the one or more ledges of the at least one spine member; rotating the rotatable knob such that the threaded end is wound within the threaded portion of the base member and bears on an opposite side of the one or more ledges of the at least one spine member, thereby clamping the at least one spine member between the rear-facing hook and the rotatable knob; and positioning a proximal end of the accessory rod within the front-facing socket of the base member such that the accessory rod extends therefrom into a cable management space.

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 line assembly for installation in an aircraft fuselage includes a first line section having a first diameter, a second line section having a second diameter, a set of first line brackets, and a set of second line brackets. The first line brackets include a first receiving space configured to hold the first line section and a first support portion for attaching the first line brackets to a fuselage structural part. The second line brackets include a second receiving space configured to hold the second line section and a second support portion for attaching the second line brackets to the first line section. The second line section includes a higher flexibility than the first line section. The second line section is attached to the first line section through a plurality of second line brackets arranged at a distance to and independent from the first line brackets.

A cable hanger includes: a generally flat base; and first and second opposed arms extending in a first direction from the base; wherein hooks are positioned on free ends of the arms; wherein each of the free ends of the arms has an arcuate cross-section; wherein the arms form a gap configured to receive and grasp a cable; and wherein the cable hanger is a unitary member formed of a polymeric material.

A cable hanger assembly comprises a unitary skeletal frame comprising (i) a base that comprises a first base surface and a second base surface that are separated by a channel that is open at a proximate channel end and closed at a distal channel end, (ii) a first sidewall extending from a distal end of the first base surface to the distal channel end, (iii) a second sidewall extending from a distal end of the second base surface to the distal channel end, and (iv) where at least one of the first and second base surfaces includes a slot open on its respective proximate slot end. A removable and replaceable strap or supplemental hanger assembly may be engaged with the slot and hangs from the slot.