A cable retaining apparatus includes a body defining at least one aperture for receiving a respective cable, a first insulator device arranged in the, or each, aperture for preventing electrical conduction from a cable to a surface of the body facing the cable, and a second insulator device for preventing electrical conduction from a cable to a surface of the body facing away from the cable.

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 tube spacing and fastening system for a gas turbine engine includes a plurality of tubular structures, a wear sleeve, a spacer element, and a fastening element. The plurality of tubular structures provides a fluid flow to a component of the gas turbine engine. The wear sleeve is located around each of the plurality of tubular structures. The spacer element receives the plurality of tubular structures. The fastening element extends around the wear sleeves and is configured to secure the plurality of tubular structures to the spacer element. An interference between the fastening element and wear sleeves is configured to allow the fastening element to slide with respect to the wear sleeves and to provide a damping effect under gas turbine engine vibrations and operating conditions. A method of damping vibrations in the plurality of tubular structures includes allowing the fastening element to slide with respect to the wear sleeve.

A tube spacing and fastening system for a gas turbine engine includes a plurality of tubular structures, a wear sleeve, a spacer element, and a fastening element. The plurality of tubular structures provides a fluid flow to a component of the gas turbine engine. The wear sleeve is located around each of the plurality of tubular structures. The spacer element receives the plurality of tubular structures. The fastening element extends around the wear sleeves and is configured to secure the plurality of tubular structures to the spacer element. An interference between the fastening element and wear sleeves is configured to allow the fastening element to slide with respect to the wear sleeves and to provide a damping effect under gas turbine engine vibrations and operating conditions. A method of damping vibrations in the plurality of tubular structures includes allowing the fastening element to slide with respect to the wear sleeve.

An infusion line harness includes a rectangular material with first and second anchor tabs opposing ends of a first longitudinal edge of the rectangular material such as to extend the first longitudinal edge of the material to include a length of the first and second anchor tabs. The rectangular material includes one or more first fasteners positioned on the rectangular material along the first longitudinal edge and one or more complimentary fasteners positioned along the second longitudinal edge and which are configured to connect to the one or more first fasteners, the first fasteners and second fasteners being positioned such that when connected to each other the rectangular material forms a tubular structure. The first and second anchor tabs each are configured to wrap around a respective object and fasten to itself, or to a respective portion of the rectangular material, to anchor the harness to the respective object.

Example aspects of a pipe clamp assembly can comprise a pipe clamp comprising a first clamp segment and a second clamp segment, the first clamp segment defining an inner surface, a first end, and a second end, the second clamp segment defining an inner surface, a first end, and a second end; a projection extending from the inner surface of the first clamp segment, the projection defining a linear top edge configured to engage a pipe, the linear top edge oriented distal to the inner surface of the first clamp segment; and a support flange coupled to the pipe clamp proximate to the first end of the first clamp segment and the first end of the second clamp segment, the support flange configured to support the pipe clamp assembly on a support surface.

A cable management bracket including a cable management base, one or more cable clamps, and a cable distribution block is disclosed. The cable management base has a base panel, and a first sidewall and a second sidewall between a front end and a rear end of the base panel. The first sidewall and the second sidewall extend from and along opposite sides of the base panel. The one or more cable clamps are disposed on the base panel. Each cable clamp has two opposing arms separated by a slot. Each of the two opposing arms are flexibly movable to accommodate a cable in the slot. The cable distribution block is disposed at the rear end of the base panel. The cable distribution block has a plurality of through holes, each through hole configured to accommodate the cable through an opening that is flexibly movable in a horizontal direction.

A sprinkler reducer fixing bracket that is capable of allowing a reducer to be adjusted in height, especially in a state where the reducer is coupled thereto. The sprinkler reducer fixing bracket includes a body fitted to a horizontal bar, a hook member whose one side is rotatably coupled to the body by means of a shaft member, a locking shaft disposed on the hook member and having a cam portion adapted to push the body to allow the hook member to move to a position for fixing the reducer up and down, and U-shaped first and second locking pins adapted to allow the hook member to maintain the fixed position of the reducer in the up and down directions.

A sprinkler reducer fixing bracket that is capable of allowing a reducer to be adjusted in height, especially in a state where the reducer is coupled thereto. The sprinkler reducer fixing bracket includes a body fitted to a horizontal bar, a hook member whose one side is rotatably coupled to the body by means of a shaft member, a locking shaft disposed on the hook member and having a cam portion adapted to push the body to allow the hook member to move to a position for fixing the reducer up and down, and U-shaped first and second locking pins adapted to allow the hook member to maintain the fixed position of the reducer in the up and down directions.

Integrated joining system in tubular fluid distribution elements includes a tubular element having a first enlarged cup-shaped end and a second opposite end with a radial protuberance, the first end equipped with a flange having an external concentric edge and an inside cavity capable of receiving and retaining an elastomeric gasket, the first end having a concentric radial groove adjacent to the edge, and having an end edge protruding from the tubular element, the assembly of the tubular elements occurs by inserting the second end of a tubular element inside the cup-shaped end of a similar tubular element up to a shoulder of the cup-shaped end with the edge of the second end having passed the gasket, a junction block including two semicircles placed around the tubular element at this concentric edge and end edge which, by tightening by clamping elements, crimps the two tubular elements.