An actuator according to an embodiment includes a first rotating body that is rotatable around an input axis and includes a first groove part extending in a first direction, a second rotating body that is rotatable around an output axis and includes a second protruding part extending in a second direction substantially perpendicular to the first direction, a strain body that includes a first protruding part capable of being engaged with a first groove part through a gap whose direction is vertical to that of the input axis and a second groove part capable of being engaged with a second protruding part through a gap whose direction is vertical to that of the output axis and transmits a rotational torque of the input axis to the output axis, and a detection element that is attached to the strain body.

A force sensor comprising a force sensitive resistor having a common electrode and an electrode array separated by a force sensitive resistor material. The sensor includes a preload structure, where the preload structure imparts a force on the force sensitive resistor material. The sensor may also include a signal conditioning board to read a signal from the electrode array and convert it to a digital output.

A pressure reading assembly including a housing defining a conduit configured to transmit bodily fluid therethrough and a receiving tube having a first opening and an inner cylindrical surface. The pressure reading assembly further includes a sensing apparatus which includes a sensor disposed on a substrate and an engagement member including a generally columnar sealing member configured to engage an inner cylindrical surface of a receiving tube within the housing connected to the substrate about the sensor. The sealing member defines an axial bore extending from a proximal end to a distal end and includes an outer sealing surface defining one or more engaging elements configured to non-adhesively engage the inner cylindrical surface of the receiving tube to resist removal of the sensor assembly so that a pre-sterilized sensor assembly can be removed from a clean sealed packaging and joined directly with the housing.

A force sensor includes a first structure, four strain generation parts, and a second structure. The first structure is formed in such a way that a third axis penetrates therethrough. The four strain generation parts are provided along first and second axes on a reference plane formed by the first and second axes. The second structure is connected to the first structure with the strain generation parts interposed therebetween. The strain generation parts each includes a first beam part extending along the first axis or the second axis, and a second beam part extending in a direction orthogonal to the first beam part and connected to the first beam part at an intermediate part. The strain generation parts are formed in such a way that they are line-symmetric with respect to both the first axis and the second axis when projected in a direction of the third axis.

A force sensor includes a first structure, four strain generation parts, and a second structure connected to the first structure with the strain generation parts interposed therebetween. The strain generation part includes a first connection part connected to the first structure, a first branch part, which is a beam-like part branching into two from the first connection part toward the second structure and extending in directions separating from each other, a second branch part, which is a beam-like part connected to the first branch part with bent parts interposed therebetween and extending in directions approaching each other, and a second connection part where branched parts of the second branch part join and connects to the second structure. The strain generation parts are formed so that the strain generation parts become line-symmetric with respect to the first and second axes when projected in a direction perpendicular to the reference plane.

An example sensor device is provided. The sensor device includes (a) a substrate having a first end and a second end, wherein the substrate includes a contact portion, a first sensor portion positioned between the first end of the substrate and the contact portion, and a second sensor portion positioned between the second end of the substrate and the contact portion, (b) a first strain gauge sensor positioned at the first sensor portion, and (c) a second strain gauge sensor positioned at the second sensor portion, wherein the first end of the substrate and the second end of the substrate are configured to be coupled to a rigid curved surface, and wherein the sensor device is configured such that a force applied to the contact portion of the substrate will be sensed by each of the first strain gauge sensor and the second strain gauge sensor.

An example sensor device is provided. The sensor device includes (a) a substrate having a first end and a second end, wherein the substrate includes a contact portion, a first sensor portion positioned between the first end of the substrate and the contact portion, and a second sensor portion positioned between the second end of the substrate and the contact portion, (b) a first strain gauge sensor positioned at the first sensor portion, and (c) a second strain gauge sensor positioned at the second sensor portion, wherein the first end of the substrate and the second end of the substrate are configured to be coupled to a rigid curved surface, and wherein the sensor device is configured such that a force applied to the contact portion of the substrate will be sensed by each of the first strain gauge sensor and the second strain gauge sensor.

A six-axis Force Torque Transducer (FTT) including a hub and at least one flexural beam disposed on the hub and extending outwardly from the hub. Each of the at least one flexural beams including a U-beam having a substantially U-shaped cross section and at least one beam plate attached to the U-beam at a portion of the U-beam that is remote from the hub. A first strain gauge carrier, including at least one strain gauge, is mounted on an exterior surface of the at least one U-beam. A second strain gauge carrier, including at least one strain gauge, is mounted on an exterior surface of the at least one beam plate. A connection element electrically connects the strain gauges of the first strain gauge carrier and the strain gauges of the second strain gauge carrier in a bridge configuration.

A pressure sensing assembly, a pressure sensing method, and a device having the pressure sensing assembly are disclosed. The detection circuit and the signal generating circuit are connected to a signal processing circuit, the detection circuit includes a first bridge circuit constituted by connecting at least four force sensors R1, R2, R3 and R4. During use, the rigid structure is attached on an object to be detected which is deformed under action of an acting force, the detection circuit and the signal generating circuit are cooperated so as to generate different output signals that pass through the signal processing circuit, so that a direction and a magnitude of the acting force is recognized. The pressure sensing assembly has an integrated structure, is prone to be assembled, has a simple circuit configuration, and is low in cost.

A force measurement assembly is disclosed herein. The force measurement assembly includes a top component, the top component having a top surface for receiving at least one portion of the body of the subject; a single force transducer supporting the top component, the single force transducer configured to sense one or more measured quantities and output one or more signals that are representative of forces and/or moments being applied to the top surface of the top component by the subject; and a base component disposed underneath the single force transducer, the base component configured to be disposed on a support surface.