The present invention relates to a sensor system (1) for detecting mechanical changes, in particular material fatigue and wear and tear, at an early stage, comprising a sensor housing (2) having a receiving region (21) and a sensor head (4), wherein the sensor head (4) is maintained on the receiving region on the sensor housing (2) and is at a distance, at least in regions from the sensor housing (2). The sensor head (4) comprises a breaking body (40) having at least one measuring conductor (50). The at least one measuring conductor (50) is electrically connected by means of at least one electronic measurement unit (25) in the sensor housing (2), and the electrical resistance of the at least one measuring conductor (50) can be detected by the electronic measurement unit (25).

A method for determining a fluid pressure parameter related to a fluid located within a fluid conduit, the method may include measuring one or more resistances of one or more nanoparticle based sensing elements to provide sensed information; wherein the one or more nanoparticle based sensing elements comprise nanometric particles having an electrical resistance that is responsive to at least one out of pressure and temperature; wherein the one or more nanoparticle based sensing elements are printed between conductive electrodes, wherein the conductive electrodes are either printed on an exterior of the fluid conduit or are formed on a substrate that is attached to the exterior of the fluid conduit; and determining, based on the sensed information, the fluid pressure parameter.

A portable electronic device may include an electrical resistance sensor and a battery assembly being adjacent to the electrical resistance sensor. The electrical resistance sensor is positioned to be compressed when the battery assembly swells, and the electrical resistance sensor further includes a pressure sensitive material that exhibits a characteristic of changing an electrical conductance when compressed.

A method for producing a sensor device (2) for the measurement of an instantaneous load on a component (1, 15), in which the component (1, 15) is made of plastic, in which a sensor layer (3) is arranged in the component (1, 15). The sensor layer (3) is formed of a carrier material with electrically conductive particles embedded therein. To be able to measure or determine loads and/or forces in the component (1, 15) in a better an/or more reliable way, the method includes forming at least one blind hole-like recess (4) in the component (1, 15) to receive the sensor layer (3).

A method for fatigue-monitoring of a submarine cable during off-shore jointing or reparation includes: a) determining a plurality of curvature values concerning a curvature of the submarine cable at different points in time during the off-shore jointing or reparation, b) determining a plurality of strain ranges of the submarine cable based on the plurality of curvature values, and c) determining a fatigue damage of the submarine cable based on the plurality of strain ranges.

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.

A belt includes a laminate including a back surface layer disposed on a back surface side and a tension member layer including a tension member. The belt includes a sensor provided in the laminate and configured to detect a state of the belt, and a passive RFID also provided in the laminate, including an IC chip and an antenna, and configured to transmit state information on the belt detected by the sensor to an outside.

An additively manufactured strain gauge resides on the surface of a component to monitor component fatigue. The strain gauge is additively manufactured, and applied to the curvature of the component surface through either a flexible substrate or through direct printing.

A low power consumption multi-contact micro electro-mechanical strain/displacement sensor and miniature autonomous self-contained systems for recording of stress and usage history with direct output suitable for fatigue and load spectrum analysis are provided. In aerospace applications the system can assist in prediction of fatigue of a component subject to mechanical stresses as well as in harmonizing maintenance and overhauls intervals. In alternative applications, i.e. civil structures, general machinery, marine and submarine vessels, etc., the system can autonomously record strain history, strain spectrum or maximum values of the strain over a prolonged period of time using an internal power supply or a power supply combined with an energy harvesting device. The sensor is based on MEMS technology and incorporates a micro array of flexible micro or nano-size cantilevers. The system can have extremely low power consumption while maintaining precision and temperature/humidify independence.

A method for determining a fluid pressure parameter related to a fluid located within a fluid conduit, the method may include measuring one or more resistances of one or more nanoparticle based sensing elements to provide sensed information; wherein the one or more nanoparticle based sensing elements comprise nanometric particles having an electrical resistance that is responsive to at least one out of pressure and temperature; wherein the one or more nanoparticle based sensing elements are printed between conductive electrodes, wherein the conductive electrodes are either printed on an exterior of the fluid conduit or are formed on a substrate that is attached to the exterior of the fluid conduit; and determining, based on the sensed information, the fluid pressure parameter.