The invention relates to a system for monitoring the state of a cable (70), which is guided in an energy chain (1) between a base and a movable driver element. The movable energy chain forms a movable run (1B) at a driver element (2), a resting run (1A) at a base (4) and, between the two runs, a deflecting bend (1C). A monitoring device having at least one indicating element (64) at the energy chain (1) evaluates an indicating-element signal and monitors whether an error state occurs. The indicating element has two electrical indicating conductors (62A, 62B) guided by the energy chain, which indicating conductors extend along the movable run (1B), and the monitoring device comprises a measuring circuit for resistance measurement or conductance measurement (65 . . . 69). One end point of each indicating conductor (62A, 62B) is connected to the measuring circuit and the other end points of the indicating conductors (62A, 62B) are short circuited such that the indicating conductors (62A, 62B) form a measurement loop (62).

A method for capturing a tensile force exerted during the pulling of a pipe or line during installation, includes capturing a strain on the pipe or line via one or more sensors arranged on the pipe or line. Multiple strain sensors may be arranged such that they are offset at various angles across the circumference of the element being installed. One or more sensors may be mounted to a towing head for pulling the pipe or the line during installation.

A tensioning device includes a housing, a drive member, an inner sleeve and a driven member. The housing includes a first attachment feature. The driven member includes a second attachment feature. The inner sleeve is disposed at least partially in the housing and is rotatably coupled with the housing. The drive member is rotatably coupled with the housing and is operably coupled with the inner sleeve such that rotation of the drive member facilitates rotation of the inner sleeve. The driven member is movable with respect to the guide member between a retracted position and an extended position along a centerline.

A cable barrier system is managed by a cable barrier management system including a management system controller having a management processor, a wireless data communications interface, and a plurality of turnbuckle subsystems configured to be joined to respective barrier cables to provide pretension. Each of the turnbuckle subsystems has a strain gauge mounting zone and is configured to enable communication of strain from a strain gauge circuit to the management processor. The management system controller includes a sensing circuit to receive the strain gauge output voltage from the strain gauge circuit and provide sensing circuit output to the management processor. The management system controller includes a cable barrier analysis module configured to determine excess strain events. The management processor generates strain event data, which is sent via the wireless data communications interface to a remote recipient computing device.

A cable barrier system is managed by a cable barrier management system including a management system controller having a management processor, a wireless data communications interface, and a plurality of turnbuckle subsystems configured to be joined to respective barrier cables to provide pretension. Each of the turnbuckle subsystems has a strain gauge mounting zone and is configured to enable communication of strain from a strain gauge circuit to the management processor. The management system controller includes a sensing circuit to receive the strain gauge output voltage from the strain gauge circuit and provide sensing circuit output to the management processor. The management system controller includes a cable barrier analysis module configured to determine excess strain events. The management processor generates strain event data, which is sent via the wireless data communications interface to a remote recipient computing device.

A system for monitoring the performance of a multi-stranded tensile member where a portion of the strands are concealed within a termination. The invention provides a monitoring system that allows the user to determine when one or more of the strands has degraded to a point of concern. In some embodiments the monitoring system depends on visual inspection and in other embodiments the monitoring system is automated.

Apparatus for monitoring performance of tie down straps are disclosed. A tie down strap is attached to a strap monitor. The strap monitor continuously monitors the physical parameters of the tie down strap. Further, an electronic device communicatively coupled to the strap monitor receives physical parameters of the tie down strap from the strap monitor to determine performance of the tie down strap. Furthermore, upon determining any issues with the performance of the tie down strap, a user is alerted of the issue by the electronic device.

The invention relates to floating platform mooring and involves an improved platform mounted tendon tension monitoring system with porch mounted variable reluctance measurement technology sensors configured. The variable reluctance measurement technology sensors of this system are optimized for porch mounting. The porch mounted tendon tension monitoring system can also be configured such that the porch-mounted optimized variable reluctance measurement technology sensors are replaceable. Sensors may be replaced to extend the desired useful lifetime of a tendon tension monitoring system or in the event that a sensor happens to malfunction. A plurality of variable reluctance measurement technology sensors can be configured in sensor packs at the corners or at other locations where tendon tension monitoring can be useful for a floating platform.

In the case of a method for detecting a tensile stress of a circumferential belt (5), this is deflected around a tension roller (4). In this way, the running length of the circumferential belt (5) is changed by adjusting the tension roller (4). A force measuring device (10) is provided, wherein the force measurement changes along with the adjustment path (6) of the tension roller (4). In order to make a reliable tensile stress detection possible, the sensitivities of the force measuring device (10) are determined with respect to the tensile stress for different points of the adjustment path. These sensitivities or calculated values are stored in a memory (32), which a controller (15) accesses. This calculates the tensile stress from the current adjustment path (6), the current bearing force and the stored sensitivities or values by means of interpolation.

A cargo restraint system includes a body, a first connecting end and a second connecting end on opposing sides of the body, wherein the first and second connecting ends are coupled to a securing member which is used to restrain the cargo. One or more load sensors are coupled to the first connecting end and/or the second connecting end. A controller is coupled to the one or more load sensors. The controller is configured to receive tension information from the one or more load sensors. The controller includes a transmitter capable of transmitting the tension information to a remote device. The controller may include a database to store the information.