A wire fastening device, wherein two parallel wire guides, arranged oppositely are provided on the flat wire fastening device on a first and second guide sides, wherein two wire ends can be fixed permanently in the wire fastening device, which wire ends are guided movably in the wire guides against the wire fastening device, wherein for this purpose two flat sections of the wire fastening device can be fixed removably to one another by means of a fastening device provided to that effect, that the wire guides respectively of a wire end are deflected and run substantially parallel and opposite to one another, so that the guiding direction of the wire ends can be substantially reversed in the wire guiding device.

A wire fastening device, wherein two parallel wire guides, arranged oppositely are provided on the flat wire fastening device on a first and second guide sides, wherein two wire ends can be fixed permanently in the wire fastening device, which wire ends are guided movably in the wire guides against the wire fastening device, wherein for this purpose two flat sections of the wire fastening device can be fixed removably to one another by means of a fastening device provided to that effect, that the wire guides respectively of a wire end are deflected and run substantially parallel and opposite to one another, so that the guiding direction of the wire ends can be substantially reversed in the wire guiding device.

A device configured to join two ropes includes a device body that extends from a first end to a second end along a central axis, the device body including an inner surface defining a through hole that extends through both the first end and the second end, the device body defining an inner dimension. The device defines an unassembled configuration in which the first and second ropes are positioned outside the through hole and the inner dimension is smaller than both the first outer diameter and the second outer diameter. The device defines an assembled configured in which a portion of each of the first and second ropes are positioned in the through hole, and the inner dimension is greater than both the first outer diameter and the second outer diameter.

A device configured to join two ropes includes a device body that extends from a first end to a second end along a central axis, the device body including an inner surface defining a through hole that extends through both the first end and the second end, the device body defining an inner dimension. The device defines an unassembled configuration in which the first and second ropes are positioned outside the through hole and the inner dimension is smaller than both the first outer diameter and the second outer diameter. The device defines an assembled configured in which a portion of each of the first and second ropes are positioned in the through hole, and the inner dimension is greater than both the first outer diameter and the second outer diameter.

An attachment system is formed by a primary device and a secondary device connected to the primary device in a pivoting manner. The primary device has a main body, two lateral sides and a bar for attaching the primary device to another object. Each of the lateral sides has a protrusion extending laterally outward from the lateral sides. The secondary device has two lateral sides, each equipped with an aperture that corresponds to one of the protrusions on the primary device, so that fitting the protrusions into the apertures pivotally connects the primary device to the secondary device, with the lateral sides of the secondary device being disposed outside of the lateral sides of the primary device. The secondary device can be pivoted between a folded position where the secondary device lies against the primary device, and an open position where the secondary device is raised up.

An attachment system is formed by a primary device and a secondary device connected to the primary device in a pivoting manner. The primary device has a main body, two lateral sides and a bar for attaching the primary device to another object. Each of the lateral sides has a protrusion extending laterally outward from the lateral sides. The secondary device has two lateral sides, each equipped with an aperture that corresponds to one of the protrusions on the primary device, so that fitting the protrusions into the apertures pivotally connects the primary device to the secondary device, with the lateral sides of the secondary device being disposed outside of the lateral sides of the primary device. The secondary device can be pivoted between a folded position where the secondary device lies against the primary device, and an open position where the secondary device is raised up.

An attachment system is formed by a primary device and a secondary device connected to the primary device in a pivoting manner. The primary device has a main body, two lateral sides and a bar for attaching the primary device to another object. Each of the lateral sides has a protrusion extending laterally outward from the lateral sides. The secondary device has two lateral sides, each equipped with an aperture that corresponds to one of the protrusions on the primary device, so that fitting the protrusions into the apertures pivotally connects the primary device to the secondary device, with the lateral sides of the secondary device being disposed outside of the lateral sides of the primary device. The secondary device can be pivoted between a folded position where the secondary device lies against the primary device, and an open position where the secondary device is raised up.

An attachment system is formed by a primary device and a secondary device connected to the primary device in a pivoting manner. The primary device has a main body, two lateral sides and a bar for attaching the primary device to another object. Each of the lateral sides has a protrusion extending laterally outward from the lateral sides. The secondary device has two lateral sides, each equipped with an aperture that corresponds to one of the protrusions on the primary device, so that fitting the protrusions into the apertures pivotally connects the primary device to the secondary device, with the lateral sides of the secondary device being disposed outside of the lateral sides of the primary device. The secondary device can be pivoted between a folded position where the secondary device lies against the primary device, and an open position where the secondary device is raised up.

Flexible sensor systems and sensor mounting devices and methods are disclosed. A sensor-mounting device includes an elongate tubular body made of foam so as to be flexibly manipulatable. The body has a bore extending between front and rear ends in a longitudinal direction. A sensor is located within the bore of the tubular body. Situated within the bore of the body is an inner tube having a central bore. The sensor is protected by and located within the central bore of the inner tube. The inner tube is more rigid than the body and allows the sensor system to be poseable and fixable into many non-permanent positions.

Flexible sensor systems and sensor mounting devices and methods are disclosed. A sensor-mounting device includes an elongate tubular body made of foam so as to be flexibly manipulatable. The body has a bore extending between front and rear ends in a longitudinal direction. A sensor is located within the bore of the tubular body. Situated within the bore of the body is an inner tube having a central bore. The sensor is protected by and located within the central bore of the inner tube. The inner tube is more rigid than the body and allows the sensor system to be poseable and fixable into many non-permanent positions.