A rotary connector device includes a fixed body, a rotation body, a connector, and an electrode. The connector is coupled to the fixed body and includes a second space and a cable cutting member in the second space which is in communication with the first space. The electrode is provided in the second space of the connector. An exposed conductor portion provided at one end of a cable is connected to the electrode. The cable extends from the second space to the first space. The other end of the cable is connected to the rotation body. The cable cutting member is configured to cut the cable before the exposed conductor portion connected to the electrode of the connector is disconnected when the cable is pulled due to rotation of the rotation body.

A link assembly has a pair of mechanical links pivotally connected to rotate relative to one another about a pivot axis. A cable protector is provided as part of the link assembly. The cable protector has a cup with an end wall which defines a first end of a winding chamber, and an annular side wall which extends from the end wall and defines a side of the winding chamber. A lid defines a second end of the winding chamber opposite to the first end. The lid is coupled to the cup by a bearing so that the cup and lid can rotate with respect to each other. An opening is formed in the side wall of the cup and a slot is formed in the lid. The assembly is fitted with a cable having a length, a width, and a thickness, wherein the width of the cable is greater than its thickness. The cable has a first portion which extends along a first one of the links and passes into the side of the winding chamber through the opening in the side wall of the cup, a second portion which extends along a second one of the links and passes into the second end of the winding chamber through the slot in the lid, and a rolled portion in the winding chamber in which the cable is wound into a roll, the roll including an outer turn which leads to the first portion and an inner turn which is inside the outer turn and leads to the second portion.

A link assembly has a pair of mechanical links pivotally connected to rotate relative to one another about a pivot axis. A cable protector is provided as part of the link assembly. The cable protector has a cup with an end wall which defines a first end of a winding chamber, and an annular side wall which extends from the end wall and defines a side of the winding chamber. A lid defines a second end of the winding chamber opposite to the first end. The lid is coupled to the cup by a bearing so that the cup and lid can rotate with respect to each other. An opening is formed in the side wall of the cup and a slot is formed in the lid. The assembly is fitted with a cable having a length, a width, and a thickness, wherein the width of the cable is greater than its thickness. The cable has a first portion which extends along a first one of the links and passes into the side of the winding chamber through the opening in the side wall of the cup, a second portion which extends along a second one of the links and passes into the second end of the winding chamber through the slot in the lid, and a rolled portion in the winding chamber in which the cable is wound into a roll, the roll including an outer turn which leads to the first portion and an inner turn which is inside the outer turn and leads to the second portion.

A system for electrically coupling a first structure with a second structure in a vehicle is disclosed, and includes a control module receiving at least one of electrical power and data, a cable, and a reel. The cable has a variable length and is electrically coupled to the control module. The cable transmits at least one of electrical power and data from the first structure to the second structure. The reel is located at the first structure and defines an axis of rotation. The cable is windable around the reel, and the reel is rotatable about the axis of rotation to adjust the variable length of the cable. The variable length of the cable is a portion of the cable that extends between the first structure to the second structure that is not wound around the reel.

The invention relates to a movement-tolerant wiring arrangement (10), more particularly for a stand device (1) configured for arrangement in an operating room, comprising a mounting apparatus (20) for movement-tolerant mounting of at least one line (70), more particularly a cable, about an axis of rotation (D) between two connection components (3; 4; 104) that are displaceable, more particularly twistable, relative to one another; and a fastening apparatus (30; 130) for arranging the at least one line relative to one of the connection components (3; 4; 104), more particularly at a socket of the stand device; wherein the mounting apparatus (20) is fixable to the fastening apparatus (30; 130) and configured for movement-tolerant, in particular, rotation-tolerant guidance of the at least one line about the axis of rotation and/or in the direction at least approximately parallel to the axis of rotation. Furthermore, the invention relates to a rotary joint, a socket or a stand device, respectively, with such a wiring arrangement, and the use of such a wiring arrangement (10) at a stand device (1), more particularly in the operating room.

The invention relates to a movement-tolerant wiring arrangement (10), more particularly for a stand device (1) configured for arrangement in an operating room, comprising a mounting apparatus (20) for movement-tolerant mounting of at least one line (70), more particularly a cable, about an axis of rotation (D) between two connection components (3; 4; 104) that are displaceable, more particularly twistable, relative to one another; and a fastening apparatus (30; 130) for arranging the at least one line relative to one of the connection components (3; 4; 104), more particularly at a socket of the stand device; wherein the mounting apparatus (20) is fixable to the fastening apparatus (30; 130) and configured for movement-tolerant, in particular, rotation-tolerant guidance of the at least one line about the axis of rotation and/or in the direction at least approximately parallel to the axis of rotation. Furthermore, the invention relates to a rotary joint, a socket or a stand device, respectively, with such a wiring arrangement, and the use of such a wiring arrangement (10) at a stand device (1), more particularly in the operating room.

The proposed line guiding system for at least one heavy and/or rigid line, for example a power cable for shore-side power supply for a ship (alternative maritime power), has a winding device which is rotatable about an axis of rotation for coiling and uncoiling the line and a rotary guide for the line from a first point to a relatively rotatable second point. The rotary guide has a helical guiding course having first helical layers, in which the line is wound about the axis of rotation, and second helical layers, in which the line is wound in the opposite direction. A return curve connects the two helical layers. According to the invention, the rotary guide has a tubular support sleeve which is coaxial with respect to the axis of rotation and serves to support the helical layers radially outwards or radially inwards. Furthermore, a rotary decoupling structure is provided, by which helical layers supported on the support sleeve are decoupled from the winding device.

The proposed line guiding system for at least one heavy and/or rigid line, for example a power cable for shore-side power supply for a ship (alternative maritime power), has a winding device which is rotatable about an axis of rotation for coiling and uncoiling the line and a rotary guide for the line from a first point to a relatively rotatable second point. The rotary guide has a helical guiding course having first helical layers, in which the line is wound about the axis of rotation, and second helical layers, in which the line is wound in the opposite direction. A return curve connects the two helical layers. According to the invention, the rotary guide has a tubular support sleeve which is coaxial with respect to the axis of rotation and serves to support the helical layers radially outwards or radially inwards. Furthermore, a rotary decoupling structure is provided, by which helical layers supported on the support sleeve are decoupled from the winding device.

Various embodiments are described that relate to dispensing from an apparatus. The apparatus can be a cable dispensing apparatus that is attached to a vehicle. As the vehicle travels, the apparatus can lay or retract cable. The rate of this laying or retracting can be based, at least in part, on a travel condition of the vehicle.

A cable handling assembly is adapted to store and pay-out a telecommunications cable. The assembly includes first and second sets of pulleys, a housing, and a cable route. The first and second sets of pulleys are spaced from each other by a take-up distance that decreases upon the cable being paid-out. The housing supports the pulleys and also guides the pulleys as the take-up distance changes. The cable route is routed between the first and second sets of pulleys. A stack of pulley sets may be formed and may include at least one intermediate pulley set positioned between the first and second pulley sets. The cable route is routed between adjacent pulley sets of the stack of pulley sets. A route length decreases as the take-up distance decreases. A rack unit for organizing a plurality of telecommunications cables in a telecommunications rack may include a plurality of the cable handling assemblies. At least one of the cable handling assemblies may include a retraction apparatus that further adapts the at least one cable handling assembly to retract the corresponding telecommunications cable.