The invention relates to a chain link for an energy guide chain for guiding cables and the like, comprising chain links which are connected in an articulated manner. The chain link has two link plates, which are laterally spaced from each other and which have narrow sides, and at least one pivotal transverse web, which connects the link plates together in an articulated manner and which can be converted into a closed position that connects the link plates together and into an open position that at least partly releases the link plate intermediate space. At least one pivotally designed end region of the transverse web can be secured to the link plate in a latching manner. The articulated connection between the transverse web and the link plate has a substantially cylindrical joint pin with a radius (R1) over at least one part of the circumference of the pin on one of the corresponding components consisting of the transverse web and the chain link and a substantially cylindrical pin receiving area on the other of the two corresponding components.

A refrigerator with a slide rail wiring mechanism, comprising a compartment configured to open forward, and a drawer-type door, wherein the compartment comprises a bottom wall, a rear wall and two side walls, and the drawer-type door is provided with an electrical component; the slide rail wiring mechanism comprises a cable for supplying power to the electrical component and a first wiring box fixed in the compartment; the first wiring box is formed with a first receiving portion and a second receiving portion; the cable comprises a fixed section fixed in the first receiving portion and a movable section that may be at least partially received in the second receiving portion; the second receiving portion is disposed apart from the bottom wall, the second receiving portion comprises a top plate and a bottom plate, and the bottom plate is provided with drainage holes.

A protective device for a cable in the form of a plurality of interconnected links forming a chain. At least one of the links comprises a retaining element, which may be a C-shaped or an L-shaped element which completes the formation of an enclosed void into which a cable can be inserted for protection. Each link preferably includes two opposed sidewalls connected by a bottom wall and the C-shaped or L-shaped element. When the retaining member is the L-shaped element, the L-shaped element is hingedly connected to one of the opposed sidewalls.

A variable area fan nozzle actuation (VAFN) system is disclosed. The VAFN system may include an electrohydrostatic actuator (EHA) arranged to translate a VAFN panel relative to a translating sleeve. An electrical coupling may extend between a translating sleeve associated with the VAFN system and the fixed structure. The electrical coupling may be movable so that as the translating sleeve and fixed structure move relative to each other, power may be provided to the EHA by a wiring harness extending across the space between the translating sleeve and the fixed structure and connecting the EHA to an EHA power source.

A wire harness routing device includes: a rail for a sliding seat, which is installed on a floor surface of a vehicle; a slider that is slidably attached to the rail; a wire harness extending from the sliding seat side; a guide member configured to connect the wire harness to the slider, and to guide the wire harness to the side of the rail and in a direction along the rail; and an accommodation portion that is provided to the side of the rail, and that accommodates the wire harness that is guided by the guide member so that the wire harness is movable along with the movement of the slider, wherein the guide member is connected to the slider to be able to approach and separate from the slider, and to be inclined to the slider.

A cable guide device and a wire harness that can allow the mounting position of the wire harness to be lowered. A bracket to be fixed to a fixed portion; a guide end disposed at an end portion of a cable guide that can be bent into a predetermined shape, and held by the bracket; a rotary portion provided on an upper surface side of the guide end in a state of being held by the bracket fixed to the fixed portion, and having an outer surface formed with a curved surface; and an upper flange protruding from the outer surface of the rotary portion substantially in a horizontal direction in the state of being held by the bracket, and configured to enter a groove formed in the bracket.

A dynamic line guiding system for high speeds and/or long displacement paths, with an energy chain arranged as lying on the side, which chain, in the configuration of a first strand, a second strand, as well as a deflection curve, is displaceable back and forth. The energy chain is guided in a guide trough with two laterally-opposite side walls and a trough floor therebetween, wherein each strand is respectively displaceable with a lateral surface on a respective bearing surface on the trough floor, and is held, relative to the outside, by means of one of the two side walls. It is provided that the trough floor comprises at least one bearing surface with a step or a ramp, which counteracts a deviation of the first strand out of its intended target location on the respective bearing surface.

An outlet relocation assembly includes a male electrical outlet that can be plugged into a female electrical outlet on a wall that is blocked by furniture. A ring is rotatably positioned around the male electrical outlet. An arm is coupled to and extends away from the ring such that the arm is oriented parallel to the wall in which the female electrical outlet in the wall is positioned. A female electrical outlet is pivotally coupled to the arm. The female electrical outlet on the arm can be spaced from the female electrical outlet in the wall thereby facilitating the female electrical outlet on the arm to be extended beyond the furniture. Moreover, the female electrical outlet on the arm is in electrical communication with the male electrical outlet to supply electrical power.

An outlet relocation assembly includes a male electrical outlet that can be plugged into a female electrical outlet on a wall that is blocked by furniture. A ring is rotatably positioned around the male electrical outlet. An arm is coupled to and extends away from the ring such that the arm is oriented parallel to the wall in which the female electrical outlet in the wall is positioned. A female electrical outlet is pivotally coupled to the arm. The female electrical outlet on the arm can be spaced from the female electrical outlet in the wall thereby facilitating the female electrical outlet on the arm to be extended beyond the furniture. Moreover, the female electrical outlet on the arm is in electrical communication with the male electrical outlet to supply electrical power.

Aspects of the technology relate to rotational electromechanical systems, in which data and or power are supplied to components while one part of the system is rotating relative to another part of the system. Repeated rotation may create strain on or otherwise cause the cables to intermittently or permanently fail. A helical cable management system is provided that enables full rotation to the extent permitted. One or more cables are wound in a helical shape around the axis of rotation, which distributes the deformation of the cable along the helical length. Rotation in one direction causes the helix diameter to increase, while rotation in the other direction causes the helix diameter to decrease. A structure is used to maintain the distance between helical turns, while permitting the increase and decrease of the helix diameter. This reduces the overall strain on the cables, which can significantly extend their useful lifetime.