Provided is a micro-power generator suitable for a wearable, portable or moving electronic device, including a rotor wheel including a multipole magnetic array of a circular design, such as a multipole magnetic ring or disc, which multipole magnetic array has an inner radius r3 and an outer radius r4, at least one stator which is a multipole metal stator including at least one stator coil having a plurality of windings for producing an electric voltage, and a base plate onto which the rotor wheel and the stator are mounted. The at least one stator is fixedly connected to the base plate. The rotor wheel is pivotally connected to the base plate by a pivoting mechanism which allows for a rotation of the rotor wheel about a pivot axis perpendicular to a first plane in which the rotor wheel extends, which pivot axis preferably has a concentric orientation to the rotor wheel. The rotor wheel is provided on one side of the base plate, and the rotor wheel has a centre of mass that has an eccentric position with respect to the pivot axis.

A vibration attenuator for a rotor of an aircraft has a housing adapted for rotation with the rotor about an axis. A first ring is rotatably carried within the housing on a first bearing, a first weight being coupled to the first ring for rotation therewith relative to the housing about the axis. A second ring is rotatably carried by the first ring on a second bearing, a second weight being coupled to the second ring for rotation therewith relative to the housing and to the first ring. A first motor is configured for rotating the first ring relative to the housing, and a second motor is configured for rotating the second ring relative to the housing and to the first ring. The first and second motors are operated to rotate the weights within the housing and position the weights relative to each other for attenuating vibrations.

A game controller including a housing with a first handgrip and a second handgrip is provided. The game controller includes a first vibration actuator integrated within the housing proximate to the first handgrip. Further included is a second vibration actuator integrated within the housing proximate to the second handgrip. A controller device is included and is configured to communicate one or more vibrational signals to one or both of the first vibration actuator and the second vibration actuator. The vibrational signals are configured to cause the housing of the game controller to vibrate in a vibrational pattern during use of the controller. The vibrational pattern is one of a plurality of vibrational patterns, and one or more of the plurality of vibration patterns are activated in correlation to one or more game actions occurring during gameplay of a video game using the game controller.

An actuator for generating vibration, including a shaft; a middle supporter having a fitting portion fitted into an upper portion of the shaft and a support portion below the fitting portion to form a first space where a lower portion of the shaft is exposed; a circuit board having a driving coil and a hollow formed through the middle supporter; a housing having an inner space that accommodates the middle supporter and the circuit board so the circuit board is fixed thereto; a first yoke plate having a first magnet installed to face an upper surface of the driving coil and coupled to an upper portion of the middle supporter; a second yoke plate having a second magnet installed to face a lower surface of the driving coil and coupled to a lower portion of the middle supporter; and a weight installed to at least one of the yoke plates.

A device is provided for monitoring the compaction of concrete introduced into a slipform of a slipform paver by means of at least one concrete compacting device that has an asynchronous motor for driving an unbalanced mass which generates vibrations. The monitoring device comprises an apparatus for monitoring the stator current of the asynchronous motor, the apparatus being configured such that a change in the compaction of the concrete is determined based on an analysis of the stator current. The apparatus for monitoring the stator current of the asynchronous motor is preferably configured such that the amplitude spectrum of the stator current is determined in order to analyse the stator current. It is advantageous that the compaction of the concrete is not monitored using sensors which are exposed to harsh ambient conditions during operation of the slipform paver.

Provided is a user-friendly power tool. The power tool 1 comprises: a battery pack mount 2c to which a battery pack 4 can be attached and detached; and a cover 17 that can cover the battery pack 4, mounted on the battery pack mount 2c, and the battery pack mount 2c so as to allow opening and closing. The wall 23 of the battery pack mount 2c is provided with a correcting part 23a that is capable of correcting inward warping of both the left and right side surfaces of the cover 17, which are the longitudinal direction surfaces. The lower edge of the correcting part 23a has a rounded shape.

A rotary device with an unbalance drive, a carrier unit, which rotates around a first axis of rotation R1, which is rotatably mounted, at least two unbalances (U.sub.1; U.sub.2; . . . U.sub.x) of first type, each around a corresponding unbalance axis (UA.sub.1; UA.sub.2; . . . UA.sub.x) running parallel to the first axis of rotation R1 and at a distance (d.sub.UA1; d.sub.UA2; . . . d.sub.UAx) and are arranged from the first axis of rotation R1 and an unbalance drive device, which is arranged stationary with respect to the carrier unit and at least for driving the unbalances (U.sub.1; U.sub.2; . . . U.sub.x) and rotationally coupled with the unbalances (U.sub.1; U.sub.2; . . . U.sub.x).

Circular force generator devices (100), systems, and methods for damping vibrations which include two complementary rotor assemblies (110, 120) that are rotatable together about a common shaft (102) but that have an adjustable rotational position (P1, P2) with respect to one another such that a significant reduction in rotor inertia and bearing drag relative to conventional CFG configurations is provided. The present architecture creates virtually zero rotating moment.

A vibratory handle for use with a surface finishing float, the vibratory handle including a first end having a bore for receiving a first float attachment screw therein for attaching the first end to the finishing float. The vibratory handle further including a second end having an oblong slot for receiving a second float attachment screw therein for attaching the second end to the finishing float such that the first float attachment screw and second float attachment screw are in operative alignment and spaced apart a distance along a surface the float. The vibratory handle also includes a gripping portion extending between the first end and second end.

The present disclosure discloses an encapsulated cylindrical shell structure with a motor. The encapsulated cylindrical shell structure includes a second shell and a second shell. The first shell internally has a mounting space; the second shell is inserted into the mounting space; the second shell includes a hard main body and a soft main body; the soft main body is detachably mounted on the hard main body; the hard main body is provided with a first cavity; the soft main body is provided with a second cavity; a first driving mechanism is mounted in the first cavity; and a second driving mechanism is mounted in the second cavity. The first shell made of the elastic material, and the transverse parts can provide an elastic handfeel, so that the flexural resistance generated by the first driving mechanism and the second driving mechanism is effectively reduced, which affects gripping.