Class / Patent application number | Description | Number of patent applications / Date published |
318631000 | Antistatic friction features (e.g., "dither" voltage) | 7 |
20090251094 | HYSTERESIS MITIGATION AND CONTROL METHOD - A system and control method mitigates hysteresis of an adjustable component in the system. A control module can allow small control changes to be effected to the component within limits of the component's and/or the system's normal hysteresis band. The control method can allow finer, more accurate and more aggressive control to be obtained from the component. The system and method can utilize two separate control regimes to control adjustments to the component. The first control regime can control changes larger than a hysteresis band and/or changes in a same direction as the last adjustment that was performed with the first control regime. The first control regime can be a feedback-based adjustment to the component. The second control regime can be utilized to control changes within the hysteresis band. The second control regime can use open-loop based adjustments to the component. | 10-08-2009 |
20110050146 | CONTROLLER OF ELECTRIC MOTOR HAVING FUNCTION OF ESTIMATING INERTIA AND FRICTION SIMULTANEOUSLY - A controller estimates Coulomb friction itself together with inertia and viscous friction, and reduces the influence of the Coulomb friction on the accuracy of the estimated inertia. In addition, the controller estimates inertia, viscous friction and Coulomb friction simultaneously with sequential adaptation in which a Fourier transformer is not used but an inverse transfer function model is used in order to minimize the estimated error. Data sampled for a predetermined time need not be accumulated, as a result, a large amount of data memory is unnecessary. | 03-03-2011 |
20110210689 | Reluctance And Lorentz-Force-Operated Linear Drive - A linear motor for optical systems, for example, endoscopes, is described. The motor has a stator with a magnetic guiding member and a coil. The armature of the motor includes two permanent magnets which are of opposite polarity. A pole piece made of soft-magnetic material is provided between the permanent magnets. By applying current to the coil, the armature can be displaced from a rest position in the longitudinal direction. | 09-01-2011 |
20110210690 | LINEAR MOTOR WITH PERMANENT-MAGNETIC SELF-HOLDING - A linear motor for optical systems, for example, endoscopes, is described. The motor has a stator with a magnetic guiding member and two adjacently disposed coils which are energized in opposite directions. Furthermore permanent magnets polarized in opposite directions and in the axial direction are provided on both sides of the pair of coils. The armature of the motor comprises a permanent magnet which is polarized in the opposite direction to the permanent magnet of the stator and is connected to a pole piece at each end. The pole pieces are arranged so that in the rest position each pole piece lies at the centre of one of the coils. By applying current to the coil, the armature can be displaced from a rest position in the longitudinal direction. | 09-01-2011 |
20110221379 | ELECTROMAGNETIC LINEAR STEPPER MOTOR - A linear stepper motor is used for the displacement of an armature parallel to a stator having N steps. The stator includes (N+2) stator pole pieces which are enclosed by a magnetic guiding element and are each approximately the same distance from neighboring stator pole pieces. Furthermore, at least one coil is located between two stator pole pieces. The armature is enclosed by the stator in the radial direction and has a permanent magnet magnetized parallel to the stator which is disposed between two armature pole pieces. As a result of the reluctance forces, the armature occupies stable idle positions inside the stator in which the stator pole pieces lie opposite the armature pole pieces. By energizing the coils with a short current pulse, the armature can be displaced inside the stator between the different stable idle positions. | 09-15-2011 |
20120268055 | DRIVE DEVICE - According to one embodiment, a drive device comprises a first generating unit which moves in straightly movable manner or rotatable manner and generates precharge pressure, a sliding guide unit which has a sliding guide surface that comes into contact with a sliding surface of the first generating unit and to which the precharge pressure is given, a vibration unit which gives vibration to the first generating unit, and a second generating unit. When the vibration is given to the first generating unit, the second generating unit generates driving force for driving the first generating unit in a predetermined direction so that the driving force is more than frictional force between the sliding surface and the sliding guide surface. When the vibration is not given to the first generating unit, the second generating unit generates the driving force so that the driving force is less than the frictional force. | 10-25-2012 |
20150295522 | POSITION CONTROL DEVICE - A compensation function constituting device calculates a correlation coefficient based on a moving distance required for reversing a moving direction of a movable unit and a sliding resistance acting on the movable unit, and a compensation amount output device calculates a moving distance on a position command value required until the movable unit starts to move according to the correlation coefficient and a feedback torque when the moving direction is reversed and increases a torque compensation amount in accordance with the moving distance after reversing the moving direction until the moving distance after the moving direction is reversed reaches the moving distance required until the movement is started. | 10-15-2015 |