An adhesive strain sensing pod includes at least one strain sensor, electronics for electrically sensing at least one strain signal from the at least one strain sensor, and a sensor adhesive for adhering the strain sensor to a surface of a structural element. The pod may have a protective case for protecting the strain sensor and the electronics and for transferring at least part of a force, pressing the pod against the surface, to press the strain sensor against the surface. The sensor adhesive may be a liquid adhesive contained in a fragile pouch that ruptures when the pod is forced against the surface, or may be a thermally activated adhesive film that is activated to bond the strain sensor to the surface. A protective film may protect the sensor adhesive prior to installation of the pod and is removed prior to installation of the pod on the surface.

The invention relates to a system for protecting a sensor for a force measurement comprising: a force measurement sensor (1), designed to measure at least one tractive force or one compressive force exerted along a longitudinal axis (X) of the sensor, said sensor being designed to be made integral with a moveable part of a fluid reservoir, and a pre-strained elastic element (2) arranged to bias the force sensor (1) in a direction opposite to said exerted force, said elastic element being deformable in the direction of the exerted force so as to protect the sensor from at least one compressive or tractive force greater than a threshold.

The invention relates to a system for protecting a sensor for a force measurement comprising: a force measurement sensor (1), designed to measure at least one tractive force or one compressive force exerted along a longitudinal axis (X) of the sensor, said sensor being designed to be made integral with a moveable part of a fluid reservoir, and a pre-strained elastic element (2) arranged to bias the force sensor (1) in a direction opposite to said exerted force, said elastic element being deformable in the direction of the exerted force so as to protect the sensor from at least one compressive or tractive force greater than a threshold.

An assembly for sensing an amount of strain in an object, including a first cup having a first end, a second end, a cylindrical side wall extending therebetween, and an end wall disposed at the first end of the first cup, and a strain wafer disposed on one of an outer surface and an inner surface of the end wall.

A pressure sensor includes: a base substrate including an embossed pattern; a first conductive layer disposed on the base substrate; a pressure sensitive material layer disposed on the first conductive layer such that its electrical characteristic is varied corresponding to a strain applied thereto, the pressure sensitive material layer including a dielectric and nanoparticles dispersed in the dielectric; and a second conductive layer disposed on the pressure sensitive material layer, wherein the dielectric and the nanoparticle include materials having pyroelectricities of polarities opposite to each other.

A hand tool edge tester for evaluating the sharpness and smoothness of the cutting edge of a blade for the hand tool like a knife is provided according to the invention. The knife blade is held stationary along a horizontal, longitudinal axis. A long piece of solid tape of the cuttable substrate material like Teflon moved within a reel-to-reel tape mechanism attached to a tape carriage travels simultaneously horizontally as the tape carriage moves along a longitudinal axis, and along an upwardly inclined, diagonal pathway defined by the reel-to-reel mechanism. The blade of the hand tool slices the upwardly, diagonally moving tape ribbon with the load cell measuring the cutting force exerted by the tape ribbon against the blade as it is moved along the distance of the cutting edge substantially between the hand tool handle and the blade tip. The diagonal axis for the path of the traveling cuttable substrate media tape allows the knife blade to cut the tape more easily without tearing, along with an approximate 90° angle between the blade tip and the cutting media pathway, thereby providing a more accurate measurement by the load cell of the tip portion of the blade as it slices the tape. The cutting force data produced by the load cell yields a cutting profile for the cutting edge along the hand tool blade to indicate the relative sharpness and smoothness of the cutting edge.

A sensing fretboard for stringed instruments is described herein with respect to a guitar. The present invention includes custom frets and a modular sensing array that can be incorporated into a fretboard and coupled to the guitar. By measuring the dynamic forces applied by the players on the frets and strings of the guitar, musicians can be warned in real time during practice, when their grip is too strong, and to help musicians learn and recover from injuries.

A load cell includes a force transmitting element, a force sensing element converting a force acting on the force transmitting element into a measurement signal, a cover having an opening spaced apart from the force sensing element, and a gel element disposed in the opening. The force transmitting element extends into the opening and from the opening toward the force sensing element. The force transmitting element rests against the gel element in the opening.

A semiconductor device is detachably mountable on a measurement target that includes sensors provided on a predetermined surface thereof. The semiconductor device includes a wiring board having a first surface, and a second surface opposite to the first surface, a semiconductor integrated circuit mounted on the first surface of the wiring board, measuring spring terminals mounted on the second surface of the wiring board, and projections provided on the second surface of the wiring board. Each of the measuring spring terminals makes contact with a terminal connecting to a corresponding one of the sensors to electrically connect the terminal and the corresponding one of the sensors, and each of the projections makes contact with the measurement target, in a state where the semiconductor device is mounted on the measurement target so that the predetermined surface of the measurement target opposes the second surface of the wiring board.

A semiconductor device is detachably mountable on a measurement target that includes sensors provided on a predetermined surface thereof. The semiconductor device includes a wiring board having a first surface, and a second surface opposite to the first surface, a semiconductor integrated circuit mounted on the first surface of the wiring board, measuring spring terminals mounted on the second surface of the wiring board, and projections provided on the second surface of the wiring board. Each of the measuring spring terminals makes contact with a terminal connecting to a corresponding one of the sensors to electrically connect the terminal and the corresponding one of the sensors, and each of the projections makes contact with the measurement target, in a state where the semiconductor device is mounted on the measurement target so that the predetermined surface of the measurement target opposes the second surface of the wiring board.