In order to improve a device for pulling a trailer and/or retaining a load carrying unit that is mountable at the rear end of a motor vehicle body and which comprises a supporting arm that is connected by a first end region to the motor vehicle body and is provided at a second end region with an element for attaching the trailer and/or for fixing the load carrying unit and furthermore which comprises sensors for capturing reversible deformations of the supporting arm caused by loads on the supporting arm in such a manner as to provided a device with which an allocation of captured elongations to individual applications of force is possible in as simple a way as possible, it is proposed that strain sensors which are affected by reversible deformations thereof be assigned to a supporting arm section of the supporting arm, and that, for capturing at least one selected bending strain, at least one strain sensor be arranged on one side and at least one strain sensor on an opposite side of a surface region of a neutral reference surface assigned to the selected bending load and that each of the strain sensors be arranged at a distance from this surface region.

The invention deals with a measuring apparatus (1) comprising a body (11) with an interior (114) and an opening for accessing the interior (114) from outside the body (11), a rigid plunger (12) having an edge (1212) being identically shaped as an edge of a opening of a target vial, and a force sensor (13). The rigid plunger (12) extends though the opening of the body (11) into the interior (114) of the body (11). The edge (1212) of the rigid plunger (12) is arranged outside the body (11). The force sensor (13) is arranged in the interior (114) of the body (11). The rigid plunger (12) is movable relative to the body (11) and is coupled to the force sensor (13). The apparatus (1) can be used for measuring a force acting on the edge of the opening of the target vial for optimizing the adjustment of a vial closure facility.

An article of apparel and method include a structure configured to enclose a human body part, a pressure sensor array including multiple pressure sensors separately positioned at locations within the structure, wherein each pressure sensor is configured to output a signal indicative of an amount of pressure being exerted on the pressure sensor by an external mechanical force, an electronic display, and a controller. The controller is configured to receive signals from the pressure sensors and, based on a sequence and a timing of the signals as received, determine a command related to a function of a device. The electronic display is configured to display information related to the function.

Systems and methods for optimizing body and object interactions are provided. Based on obtained contact pressure maps and coefficient of friction (COF) maps at a contact interface where at least a portion of a body is in physical contact with a surface of an object, friction force maps can be determined, which can be used to optimize body and object interactions.

In an embodiment a tactile sensor includes a plurality of stress sensors and at least one contact body, wherein the stress sensors are configured to detect a load pattern applied on a detection surface of the contact body.

A tendon actuator unit comprises a housing; a pulley disposed within the housing, the pulley comprising a screw-like groove about a predetermined portion of an outer surface of the pulley configured to accept a predetermined length of a cable; a motor disposed in or proximate to the housing and operatively in communication with the pulley; one or more online cable sensors; one or more sensor rollers; and one or more conduit force sensors.

A method and apparatus for measuring the cutting force on a single fiber. The method includes the steps of: providing a blade having an edge; providing a fiber mount for holding the single fiber; providing at least one sensor connected to the fiber mount; providing a fiber sleeve to contain a fiber within the fiber mount to simulate the location of the hair within the hair follicle; moving the blade toward the fiber and cutting the fiber; and measuring the cutting force on the fiber with the at least one sensor.

A detection device and a detection method are provided for robot-induced loads that can act upon the human body in contact with the robot during a working process. The robot-induced loads, in particular forces, are measured by the measuring device (16) of an external sensing device (2). The measuring device (16) is suitably positioned and oriented in this process in the working area of an industrial robot (3) by means of a positioning device (15).

A collision sensor assembly is attachable to a stationary structure such as a pallet rack, a door frame, the corner of a wall, or the like. The collision sensor is configured to sense when a collision occurs with the stationary structure such as when a piece of movable machinery contacts the stationary structure. The collision sensor assembly includes a sensor operatively connected to a processor which determines when a collision occurs, and produces a signal to an output signal generator to provide an external indication of the collision.

A measurement device for measuring dynamometric features of elongated textile samples of the yarns, threads, tapes type and the like, such a device comprises a first clamp and a second clamp that is substantially aligned and relatively movable with respect to the first clamp along a first translation direction, each of the first clamp and the second clamp including a fixed jaw and a movable jaw in relation to the respective fixed jaw along a second translation direction substantially orthogonal to the first translation direction and the movable jaw is movable between a resting position and an operating position.