A force sensor including a first surface and a second surface facing each other in a first direction; a first protrusion protruded from the first surface toward the second surface; a first electrode on the first protrusion; a first force sensing layer on the first electrode; a second protrusion protruded from the second surface toward the first surface; and a second electrode on the second protrusion; wherein the first protrusion and the second protrusion are not overlapped with each other or are partially overlapped with each other.

A force sensor including a first surface and a second surface facing each other in a first direction; a first protrusion protruded from the first surface toward the second surface; a first electrode on the first protrusion; a first force sensing layer on the first electrode; a second protrusion protruded from the second surface toward the first surface; and a second electrode on the second protrusion; wherein the first protrusion and the second protrusion are not overlapped with each other or are partially overlapped with each other.

A pressure sensing device comprises a first diaphragm which is deformable and a second diaphragm which is non-deformable. One of the diaphragms comprises a pressure sensitive material arranged on its surface. The other diaphragm comprises a detection electrode arranged its surface. The first diaphragm forms part of a force transmission device comprising a cavity having a force transmission fluid therein. The force transmission device is configured to receive an external force and transmit the external force to the first diaphragm, such that the first and second diaphragms are mutually deformed in response to the external force.

A pressure sensing mat including a first conductive layer, a second conductive layer, and an insulative layer disposed therebetween. The first conductive layer includes a first plurality of spaced apart conductive paths and a first plurality of non-conductive paths therebetween. The first plurality of spaced apart conductive paths and the first plurality of non-conductive paths extend in a first direction. The second conductive layer includes a second plurality of spaced apart conductive paths and a second plurality of non-conductive paths therebetween. The second plurality of spaced apart conductive paths and the second plurality of non-conductive paths extends in a second direction different than the first direction.

The present invention is a system and method using a hand-mounted force sensor to verify installation of a CPA-enabled electrical connector. The system has at least one CPA-enabled electrical connector with a locking button; at least one hand-mounted force sensor; an interface board; a transmission channel; a system processor; a non-transitory computer readable memory element; a display; and an input. The hand-mounted force sensors have an electrical output that is proportional to the force. The method is accomplished with the steps of mounting at least one force sensor so that it will record the force exerted when depressing a locking button of a CPA-enabled electrical connector; depressing the locking button; measuring the force; recording the force; comparing the force to a pre-determined threshold; passing the CPA-enabled electrical connector if the force was less than the pre-determined threshold and otherwise failing it.

Provided is a tension-insensitive tactile sensor having high sensitivity and a wide sensing range by using a stretchable sensor array. According to the stretchable sensor array and the method for manufacturing the same of the present invention, pressure may be measured without interference of tension while maintaining flexibility of the sensor. In addition, the stretchable sensor array may have high initial resistance, induce a large change in contact resistance when pressure is applied, thereby being capable of measuring pressure with high sensitivity, have a wide pressure sensing range, and have decreased interference by an when sensing a pressure distribution.

A device for detecting wear of a wear member composed of electrically resistive material. The wear member comprises at least two electrodes separated from each other, where each electrode overlies, or is embedded in, an outer surface of the electrically resistive material. One of the electrodes is connected to a resistor at a measurement node to form a resistive voltage divider. A voltage measurement device measures a change in voltage at the measurement node, where the change is voltage is indicative of the degree of removal of resistive material from a face of the wear member and where the change in voltage is continuously variable and not limited to discrete wear levels.

A device for detecting wear of a wear member composed of electrically resistive material. The wear member comprises at least two electrodes separated from each other, where each electrode overlies, or is embedded in, an outer surface of the electrically resistive material. One of the electrodes is connected to a resistor at a measurement node to form a resistive voltage divider. A voltage measurement device measures a change in voltage at the measurement node, where the change is voltage is indicative of the degree of removal of resistive material from a face of the wear member and where the change in voltage is continuously variable and not limited to discrete wear levels.

A supramolecular conductive polymer composition comprising; a polymer comprising repeating subunits comprising at least one functional group, for forming a part in a hydrogen bond, selected from alcohol, amine, ether, amide, carboxylic acid, ester, ketone, nitrile, aldehyde and carbamide; a polyphenol comprising a minimum of 12 aromatic hydroxyl groups; a solvent with a dielectric constant of at least 20; and an electrically conductive filler.

A piezoresistive force sensor which is designed in particular as a pressure sensor and can generate a sensor signal which is dependent on an amount of a force which acts on the force sensor in a force measuring direction. The force sensor has a first electrode, a second electrode and an elastically deformable resistance layer which electrically connects the two electrodes. A resistance value of a total resistance of an electrically conductive path between the first electrode to the second electrode via the resistance layer changes according to the amount of the acting force. By measuring a voltage between the electrodes or a current which flows along the electrically conductive path, for example, a sensor signal can be detected which describes the amount of the acting force. The resistance layer contains electrically conductive first staple fibers and electrically non-conductive second staple fibers. A proportion of the first staple fibers relative to the total quantity of staple fibers can be varied in order to adapt the force-resistance characteristic of the force sensor to the particular task.