A capacitive sensor includes an upper block; a lower block; a plurality of elastic supports for elastically supporting the upper block and the lower block; upper vertical electrodes formed to have faces perpendicular to the bottom surface of the upper block; lower vertical electrodes formed to have faces perpendicular to the top surface of the lower block and disposed to face the upper vertical electrodes such that at least parts of the lower vertical electrodes overlap with the upper vertical electrodes; and an electronic circuit including the upper vertical electrodes and the lower vertical electrodes as parts of the circuit and outputting a signal corresponding to changes in capacitances between the upper vertical electrodes and the lower vertical electrodes caused by a force or a torque applied to at least one of the upper block and the lower block.

A flexible sensor that includes a printed circuit board (PCB), a capacitive structure on the PCB, and mechanical coupling sites. The PCB includes a slot extending from an outer edge of the PCB to an inner portion of the PCB, and the slot defines a first edge and a second edge facing the first edge. The first and second edges are separated by a gap when the PCB is in an unflexed state. The slot is configured to permit the PCB to flex so as to vary a relative position of the first edge with respect to the second edge. The capacitive structure on the PCB includes a first edge electrode on a portion of the first edge of the PCB, and a second edge electrode on a portion of a second edge of PCB. The second edge electrode is aligned with the first edge electrode across the slot.

A tool driver for use in robotic surgery includes a base configured to couple to a distal end of a robotic arm, and a tool carriage slidingly engaged with the base and configured to receive a surgical tool. In one variation, the tool carriage may include a plurality of linear axis drives configured to actuate one or more articulated movements of the surgical tool. In another variation, the tool carriage may include a plurality of rotary axis drives configured to actuate one or more articulated movements of the surgical tool. Various sensors, such as a capacitive load cell for measuring axial load, a position sensor for measuring linear position of the guide based on the rotational positions of gears in a gear transmission, and/or a capacitive torque sensor based on differential capacitance, may be included in the tool driver.

A tool driver for use in robotic surgery includes a base configured to couple to a distal end of a robotic arm, and a tool carriage slidingly engaged with the base and configured to receive a surgical tool. In one variation, the tool carriage may include a plurality of linear axis drives configured to actuate one or more articulated movements of the surgical tool. In another variation, the tool carriage may include a plurality of rotary axis drives configured to actuate one or more articulated movements of the surgical tool. Various sensors, such as a capacitive load cell for measuring axial load, a position sensor for measuring linear position of the guide based on the rotational positions of gears in a gear transmission, and/or a capacitive torque sensor based on differential capacitance, may be included in the tool driver.

The invention relates to a component transducer (20) for sensing a torque component (Mx, My, Mz); wherein an element (21) made of piezoelectric crystal material comprises element surfaces; wherein a force component (Fx, Fy, Fz) produces electric polarization charges on the element surfaces; and wherein the torque component (Mx, My, Mz) to be sensed consists of at least one pair having force components (+Fx, Fx; +Fy, Fy; +Fz, Fz) wherein said force components (+Fx, Fx; +Fy, Fy; +Fz, Fz) of a pair have the same axis of action and opposite directions of action. The component transducer (20) receives the force components (+Fx, Fx; +Fy, Fy; +Fz, Fz) of a pair separately.

The invention relates to a method for measuring the torque of a drive unit (10), particularly a vehicle drive unit (10), said drive unit (10) comprising at least one bearing (20) for connecting to a fixed support point (21), and at least one sensor (22) being provided which measures a change in force and/or position, particularly a relative rotation of the drive unit (10), as a sensor value, wherein a torque at the drive unit (10) is determined as a measurement value on the basis of said sensor value.

A force measurement device is arranged in one of axle holes respectively formed in two ends of a crank. The force measurement device includes a sensor seat positioned in one of the axle holes and a plurality of stress detection units arranged on the sensor seat in an annular configuration and spaced from each other by an angle. A calculation and transmission device is electrically connected with the plurality of stress detection units. When a force is applied in a force application direction to the crank, the force is transmitted through the crank to the sensor seat, and the plurality of stress detection units detect the force and generate and transmit a plurality of stress variation signals corresponding to a magnitude of the force to the calculation and transmission device.

A torque sensor includes: an annular deformation body; first and second displacement electrodes which cause displacement by elastic deformation of the annular deformation body; first and second fixed electrodes arranged at positions opposite the first and second displacement electrodes; and a detection circuit that outputs an electric signal indicating a torque based on a variation amount of capacitance values of first and second capacitive elements each of which is configured of the displacement electrode and the fixed electrode. The annular deformation body includes a high elastic portion and a low elastic portion having a spring constant smaller than a spring constant of the high elastic portion. The detection circuit determines whether the torque sensor functions normally based on a ratio between first and second electric signals.

A flexible sensor that includes a printed circuit board (PCB), a capacitive structure on the PCB, and mechanical coupling sites. The PCB includes a slot extending from an outer edge of the PCB to an inner portion of the PCB, and the slot defines a first edge and a second edge facing the first edge. The first and second edges are separated by a gap when the PCB is in an unflexed state. The slot is configured to permit the PCB to flex so as to vary a relative position of the first edge with respect to the second edge. The capacitive structure on the PCB includes a first edge electrode on a portion of the first edge of the PCB, and a second edge electrode on a portion of a second edge of PCB. The second edge electrode is aligned with the first edge electrode across the slot.

A capacitive sensor according to an embodiment of the present invention comprises: an upper block; at least one first electrode fixed to the upper block; a lower block located below the upper block; a first support column for supporting at least one second electrode fixed to the lower block and the upper block such that at least a part thereof overlaps the first electrode; a second support column for supporting the lower block; and a plurality of elastic supports, which include an elastic deformation part connected to the first support column and the second support column and elastically deformed by an external force acting on the upper block and/or the lower block.