The invention relates to a torque sensor (10) with a main body (12) that extends in an axial and circumferential direction, and which extends in a radial direction of the main body from an annular inner flange (18) with first force introduction points (16) via a mechanically weakened sensor portion (20), which is provided with measuring sensors that generate output signals, to an annular outer flange (32) with second force introduction points (34), wherein the second force introduction points (34) are connected to the sensor portion (20) via a radially elastic material portion (28). The radially elastic material portion (28) is formed by multiple radially elastic bending strips 31), which are arranged in a distributed manner around a circumference of the main body (12), and is connected to the mechanically weakened sensor portion (20) via an annular, radially stiff decoupling region (27).

A torsion sensor, including a casing assembly, a sleeve set, a driven slider, a driving slider, an elastic member, a magnetic sensor, and a magnetic member is provided. The sleeve set includes a first sleeve, a second sleeve, and a third sleeve. The first sleeve is disposed in the casing assembly. The second sleeve has a neck portion sleeved on the second side of the first sleeve. The third sleeve is disposed between the first and the second sleeves. The driven slider is connected to a head portion of the second sleeve. The driving slider surrounds an outer side of the driven slider. The elastic member surrounds an outer side of the second sleeve. One of the magnetic sensor and the magnetic member is disposed in the casing assembly, and the other one is disposed in the sleeve set. The magnetic sensor and the magnetic member are disposed opposite to each other.

A torque sensor apparatus capable of suppressing the behavior of a vehicle when the vehicle breaks down even when an adhesive between a magnet and a sleeve is peeled off is provided. The torque sensor apparatus includes a rotor and a stator that are rotatable relative to each other and are respectively fixed to an input shaft and an output shaft. The torque sensor apparatus includes a sleeve, fixed to the input shaft and fixed to the magnet of the rotor; a position regulating portion, disposed on the magnet and restricting a rotational position of the magnet and the sleeve; and a protruding portion, disposed on the sleeve and installed corresponding to the position regulating portion. A front end of the protruding portion is enlarged along a circumferential direction of the sleeve.

The disclosure relates to a linear actuator including a base, a linear motor, a load cell and a rotary motor. The linear motor is disposed on the base and includes a fixed coil module and a movable magnetic backplane. The fixed coil module is fixed on the base, and the movable magnetic backplane is configured to slide relative to the fixed coil module along a first direction. The rotary motor is rotated around a central axis in parallel with the first direction. The load cell has two opposite sides parallel to the first direction, respectively. The movable magnetic backplane of the linear motor and the rotary motor are connected to the two opposite sides of the load cell, respectively. The load cell is subjected to a force applied thereto by the rotary motor and parallel to the first direction, and configured to convert the force into an electrical signal.

The present disclosure relates to a boots damage detection apparatus and a method. More specifically, the boots damage detection apparatus according to the present disclosure includes: a transmitter that transmits a command current for a movement to a first rack position or a second rack position; a receiver that receives a rack position to which a movement is performed in accordance with the command current and a rack force corresponding to the rack position from a plurality of sensors; and a determiner that determines damage/non-damage of boots based on a first rack force corresponding to the first rack position and a second rack force corresponding to the second rack position.

Systems for force measurement upon orthodontic appliances are described. Generally, a system for measuring a force or moment imparted by an orthodontic appliance may comprise a dentition mold having one or more target teeth each formed upon a fixture and which is movable independently of the dentition mold, a measurement sensor coupled to the fixture, and a processor in communication with the measurement sensor. An orthodontic appliance may be configured for placement upon the dentition mold where the orthodontic appliance imparts a force or moment upon the one or more target teeth such that the force or moment is transmitted to the measurement sensor via the fixture for measurement of the force or moment.

A torque detection device includes a base, a load sensing member, a push member, a transmission module, and a drive module. The push member has a first extension wall and a second extension wall. The transmission module includes two adjustable transmission sets each including a torque transmission part. The torque transmission part respectively rests on the first extension wall and the second extension wall of the push member. The torque transmission part of the transmission module applies a force to push and press the push member reciprocatingly. The push member transmits the force of the torque transmission part to the load sensing member which cooperates with an electronic device to measure the maximum static friction torque of a detected workpiece.

A motor and a torque transducer box, an end cover front panel is installed at a front portion of the motor, the torque transducer box is installed at a front portion of the end cover front panel, a transmission pole is installed in the an extrusion rotating wheel, thermal dissipation and explosion proof boxes are installed on a surface of the motor, a sealing and thermal insulation module is installed at a front portion of the transmission pole, two sets of cable wrapping posts are symmetrically provided at the surface of the motor, and two sets of correction boxes are symmetrically provided at a surface of a rotor assembly.

A transducer for measuring the characteristics of a clamping instrument includes a stator which has an annular support adapted to form a substantially cylindrical longitudinal cavity adapted to receive a rotor which is also substantially shaped cylindrical adapted to rotate inside this cavity of the stator around its longitudinal axis, this rotor being provided at one end with a seat for insertion into it of the head of an instrument of tightening which determines such rotation around the axis, and a sensor arranged on its body capable of detecting specific parameters of the tightening of the instrument, and generating corresponding electrical signals. The transducer includes a magnetic coupling device adapted to transfer electrical energy from the stator to the rotor and an optical coupling device adapted to transfer the electrical signals generated by said sensor means from the rotor to the stator.

A method includes transmitting an instruction to a motive power supply of an elastically deformable device to drive the elastically deformable device in accordance with a drive setting; measuring a force exerted on the elastically deformable device with a sensor; outputting an observed value representative of the force; comparing the observed value with a reference value corresponding with a predetermined force to be exerted on the elastically deformable device; and adjusting the drive setting based on a determination that the observed value is outside of a predetermined range of the reference value. The method prevents slack in the elastically deformable device over time. Related apparatuses, systems, techniques and articles are also described.