A roof equipment support includes a platform, a pair of sidewalls extending from the platform, and a top wall extending between the pair of sidewalls and offset from the platform. The platform, the pair of sidewalls, and the top wall define an interior cavity that extends a length of the support from a first end to a second end. A pair of strut extensions extend above the top wall, and each of the pair of strut extension include a hook at a distal end. The pair of strut extensions and the top wall define a substantially U-shaped channel that extends at least a portion of the length of the support, and the platform, the pair of sidewalls, the top wall, and the pair of strut extensions are unitarily formed.

A cable management system including a plurality of separably interconnectable clips. Each clip has a plurality of longitudinally extending cells, the cells forming cable channels having open longitudinal ends and an open bottom side, the cable channels arranged side-by-side in a one-dimensional array. Each cell is adapted and configured to receive and retain a corresponding cable of a slightly smaller diameter than that of its cable channel. The clips interconnect in a vertically stacked series to form a clip stack, the one-dimensional cable channel arrays of the clips in the clip stack thus being arrayed vertically to form a two-dimensional cable channel array. Cells without a clip connected below retain corresponding cables with a clearance to permit longitudinal sliding. Cables retained in a clip with a clip connected below are clamped between the cells that retain them and impinging contact regions of a top side of the below clip.

A cable holder prevents fraying or tangling of cables configured to physically and electrically connect to one or more devices, such as patient monitoring devices. The cable holder can be configured to: (i) detachably secure the one or more cables, and (ii) be detachably secured to a support structure. The cable holder may include a first surface in which an aperture configured to receive a cable is defined, and a second surface on which a connector configured to removably interconnect with a connector of another cable holder is defined.

A retainer clip assembly includes a first retainer clip and a second retainer clip that, when attached to the first retainer clip, defines a first aperture and a second aperture with an opening therebetween. The opening between the first and second apertures provides thermal communication between first and second elongate elements, for example an electrical bus bar and a coolant conduit providing a heat sink for the bus bar, when they are secured within the first and second apertures.

A cable hanger for securing cables to a supporting structure includes: a base panel having opposed ends; a pair of arms attached to a respective end of the base panel and having a free end; a pair of locking projections, each of the locking projections attached to a respective free end of the arms; a pair of gripping members, each gripping member attached with a respective arm or to the base panel, wherein the arms and locking projections are spread apart to enable insertion of a first cable between the arms, wherein the gripping members engage and grip the first cable, and wherein the locking projections are inserted into the aperture of the supporting structure; and at least one finger attached to and extending from one of the arms or the base panel, the finger configured to deflect and grasp a second cable against the arm or base panel.

A cable hanger for securing cables to a supporting structure includes: a base panel having opposed ends; a pair of arms attached to a respective end of the base panel and having a free end; a pair of locking projections, each of the locking projections attached to a respective free end of the arms; a pair of gripping members, each gripping member attached with a respective arm or to the base panel, wherein the arms and locking projections are spread apart to enable insertion of a first cable between the arms, wherein the gripping members engage and grip the first cable, and wherein the locking projections are inserted into the aperture of the supporting structure; and at least one finger attached to and extending from one of the arms or the base panel, the finger configured to deflect and grasp a second cable against the arm or base panel.

A cable clip for use with a medical instrument system comprises a base member; a first prong projecting from the base member; and a second prong projecting from the base member. The first prong and the second prong project in a spaced, parallel manner relative to each other and the first prong is offset from the second prong in at least two dimensions.

A cable cleat (10) is disclosed. The cleat has a first portion (12) partially defining first apertures (14) for receiving a respective first cables and a second portion (18) partially defining said first apertures, and partially defining a second aperture (22) for receiving a second cable. The second portion is adapted to be mounted to the first portion to retain the first cables in the respective first apertures. The cleat also has a third portion (26) partially defining the second aperture and adapted to be mounted to the first and/or second portion to retain the second cable in the second aperture.

A cable cleat (10) is disclosed. The cleat has a first portion (12) partially defining first apertures (14) for receiving a respective first cables and a second portion (18) partially defining said first apertures, and partially defining a second aperture (22) for receiving a second cable. The second portion is adapted to be mounted to the first portion to retain the first cables in the respective first apertures. The cleat also has a third portion (26) partially defining the second aperture and adapted to be mounted to the first and/or second portion to retain the second cable in the second aperture.

An encapsulated tubular cable with a colorized identification strap includes armored protection ducts and an encapsulation protection layer. A hollow passage is formed in the center of the duct body after each armored protection duct is formed. A wire cable, an optical fiber, or an oil duct is placed in the hollow passage. The encapsulation protection layer wraps the armored protection ducts. A plurality of armored protection ducts are arranged in one encapsulated protection layer. A peripheral edge of each armored protection duct is correspondingly provided with at least one colorized identification strap group. The encapsulation protection layer improves the corrosion resistance of the encapsulated duct cable; the colorized identification straps are provided at the thinnest positions of the encapsulation protection layer to facilitate tearing and encapsulation; and each colorized identification strap has a respective color identifier, which is convenient for distinguishing objects in each hollow passage during use.