The invention relates to a tamping assembly for tamping sleepers (2) of a track (3), comprising a tamping unit (1) having a lowerable tool carrier (4) and oppositely positioned tamping tools (5), wherein each tamping tool (5) is connected via a pivot arm (6) to a squeezing drive (7) for generating a squeezing motion, and wherein a vibration drive (8) is provided for actuation of the tamping tools (5) with a vibratory motion. In this, it is provided that the vibration drive (8) comprises an electromagnetic actuator (11).

An oscillatory actuator includes a first damper 51 and a second damper 251 attached to a case 1 and including spiral arms, and first elastic member 150 and second elastic member 350 bridging adjacent arms of the first damper 51 and the second damper 251.

An oscillatory actuator includes a first damper 51 and a second damper 251 attached to a case 1 and including spiral arms, and first elastic member 150 and second elastic member 350 bridging adjacent arms of the first damper 51 and the second damper 251.

An LRA with a magnet assembly sandwiched between a pair of moving masses or support blocks which are further sandwiched between a pair of springs. A stationary elongated shaft extends through both the magnet assembly and the pair of moving masses and the pair of springs with two opposite ends secured to the corresponding end walls of the case in which all the magnet assembly, the pair of moving masses and the springs are disclosed. The moving mass forms a pair of recesses in opposite top and bottom surfaces. The case forms a pair of protrusions on opposite top and bottom walls to respectively received within the corresponding recesses so as to provide the reliable support upon the moving mass in a vertical direction. Each moving mass forms a protrusion to hold the corresponding spring in position.

An LRA with a magnet assembly sandwiched between a pair of moving masses or support blocks which are further sandwiched between a pair of springs. A stationary elongated shaft extends through both the magnet assembly and the pair of moving masses and the pair of springs with two opposite ends secured to the corresponding end walls of the case in which all the magnet assembly, the pair of moving masses and the springs are disclosed. The moving mass forms a pair of recesses in opposite top and bottom surfaces. The case forms a pair of protrusions on opposite top and bottom walls to respectively received within the corresponding recesses so as to provide the reliable support upon the moving mass in a vertical direction. Each moving mass forms a protrusion to hold the corresponding spring in position.

A torque motor assembly includes a shell which has a first wall and a second wall which defines a cavity. A torque motor is positioned at least partially within the cavity. At least one compliant pad is positioned between the first wall and the torque motor and is configured to trap at least one wire within the shell. A housing for a torque motor and a method of assembling a torque motor assembly are also disclosed.

A torque motor assembly includes a shell which has a first wall and a second wall which defines a cavity. A torque motor is positioned at least partially within the cavity. At least one compliant pad is positioned between the first wall and the torque motor and is configured to trap at least one wire within the shell. A housing for a torque motor and a method of assembling a torque motor assembly are also disclosed.

A vibration motor and a tactile device are provided. The vibration motor has: a stationary portion; a movable portion having a magnet and capable of vibrating with respect to the stationary portion along a central axis extending in an up-down direction; and an elastic member. The stationary portion has: a housing, disposed radially outside from the movable portion and having a cylindrical shape extending along the central axis; a top surface portion, disposed above the movable portion, fixed to the housing, and extended in a direction intersecting with the central axis; and a coil, capable of applying a driving force to the movable portion. The elastic member is disposed below the top surface portion and above the movable portion. The elastic member is fixed to both the top surface portion and the movable portion, and supports the movable portion so that the movable portion can vibrate along the central axis.

A vibration motor and a tactile device are provided. The vibration motor has: a stationary portion; a movable portion having a magnet and capable of vibrating with respect to the stationary portion along a central axis extending in an up-down direction; and an elastic member. The stationary portion has: a housing, disposed radially outside from the movable portion and having a cylindrical shape extending along the central axis; a top surface portion, disposed above the movable portion, fixed to the housing, and extended in a direction intersecting with the central axis; and a coil, capable of applying a driving force to the movable portion. The elastic member is disposed below the top surface portion and above the movable portion. The elastic member is fixed to both the top surface portion and the movable portion, and supports the movable portion so that the movable portion can vibrate along the central axis.

An actuator includes a movable body, a support body provided with a case that houses the movable body and a coil assembly, a first connecting body and a second connecting body to be connected to the movable body and the support body, and a magnetic drive circuit that vibrates the movable body with respect to the support body in an X direction. The coil assembly includes a first plate that overlaps the coil from a Z1 direction, and a second plate that overlaps the coil from a Z2 direction. The first plate includes a notch portion that comes into contact with a short side portion of the coil from an outer peripheral side, and positions the coil by the notch portion.