A controlling device may include an actuator for mechanically actuating a component. The actuator may be driven by an electric motor. The controlling device provides a return spring. In the case of a failure of the electric motor, the return spring brings about a shifting of the actuator into a starting position. The return spring may be mounted in the controlling device so that it prestresses the actuator into the starting position with a predetermined minimum restoring force.

The invention relates to an actuator mechanism for adjusting at least one angular position of a mirror element in an exterior mirror device for a motor vehicle. The actuator mechanism comprises a base element and a mirror element movably coupled with the base element, which comprises a mirror support for supporting a mirror surface. The mirror element is rotatable relative to the base element about at least a first pivoting axis with the aid of a first electric motor provided in the actuator mechanism, which extends in a longitudinal direction that is substantially transverse to a supporting surface of the mirror support. What can be elegantly facilitated by this, for instance also in the case of a relatively small mirror surface that is only a few centimeters wide and/or is only a few centimeters long, is that, as seen from a direction in which during use the mirror surface is being viewed by a driver, such electric motor does not protrude, or hardly protrudes, next to, above and/or below the mirror surface.

A pipe gripping device includes a gripper arm arrangement having first and second gripper arms and having an open state which enables the pipe to be introduced into an opening between the arms, and an engaged state in which the gripper arms are adapted to engage with the pipe. First and second drive arms movably connect the respective first gripper arm and the second gripper arm to a support structure. Pivots rotationally connect the drive arms to the support structure. The device further comprises a transmission drive shaft and a transmission arrangement having first, second and third transmission members, each rotatable in respect to each other and coupled with each other. The first member is coupled with the drive shaft, the second member is coupled to the first member and the first drive arm, and the third member is coupled with the second member and the second drive arm.

The present disclosure provides a driving mechanism configured to drive a target object to perform a linear motion. The driving mechanism may include an output component including an output member. The driving mechanism may also include a transmission component configured to operably connect the output component and the target object. The transmission component may include an output end and an input end. The input end may be operably connected with the output member. The output end may be operably connected with the target object. A linear velocity of the output end may be larger than a linear velocity of the input end.

An output axle includes: an axle hole, through which a manual shaft is inserted; an axle pipe portion, at which the axle hole is formed, and an output axle tubular portion, which is located on a side of the axle pipe portion that is opposite to a shift range change device. A magnet holder includes: a holder main body, at which a holder hole to be fitted with the manual shaft is formed; and a seal portion, which is formed integrally with the holder main body in one-piece, while the seal portion is configured to contact an inner peripheral wall of the output axle tubular portion and seal between the magnet holder and the output axle tubular portion.

A gear arrangement comprising: a housing having a gear axis and a housing stop, the housing stop having a first abutment and an second abutment spaced apart from one another about the gear axis; a rotatable member mounted on the gear axis, the rotatable member having a first member side having a first member stop and a second member side having a second member stop, the first member side opposite the second member side, such that the first member stop is positioned between the first abutment and the second abutment; and a gear mounted on the gear axis, the gear having a first gear side, and a second gear side having a gear stop, the first gear side opposite the second gear side, such that the gear stop is engageable and disengageable with the second member stop during rotation of the gear about the gear axis, the rotatable member positioned between the housing and the gear; wherein said rotation of the gear is hindered while the gear stop and the second member stop are engaged when the first member stop enters into engagement with either the first abutment or the second abutment.

A mechanical arm assembly which has two arm members connected by an elbow. The movable connectors at the end of each arm are connected by belts or the like to a locking mechanism at the elbow such that engaging the locking mechanism simultaneously locks both movable connectors as well as the elbow.

An apparatus for raising and lowering a cutting tool within a decoking drum, a decoking system and a method of raising and lowering a decoking system cutting tool. Instead of using metallic ropes, chains, or a self-propelled gear-based approach, non-metallic belts are secured at respective ends to a crosshead and one or more counterweights to enable vertical movement of the crosshead that in turn permits vertical movement of the cutting tool throughout the height of the drum. A motorized pulley system controls the movement of the belt, and preferably avoids having the motor be carried by the crosshead. The belts on each pulley are preferably arranged as cooperative sets so that within each set, both primary load belts and secondary load belts are present. Enhanced engagement between at least the primary load belts and the pulleys promotes greater load-bearing capability, while the secondary load belts are sufficiently strong to ensure positional stability of the crosshead and decoking tool upon damage to or failure of one or more of the primary load belts.

A transmission module for transmitting torques having a base, a first drive shaft, a second drive shaft parallel thereto, a first output shaft and a second output shaft, both rotatable about a common axis, the axes of the drive shafts are arranged parallel to the axis of the output shafts, a gear unit, where the two drive shafts, the gear unit and the first output shaft are rotatably supported in the base, and the second output shaft is rotatably supported in the first output shaft and the gear unit is designed in such a way that a synchronous rotary movement of the two output shafts can be effected by a rotary movement of the first drive shaft and a relative rotary movement of the two output shafts can be effected by a rotary movement of the second drive shaft.

In a parking lock for an automatic transmission, an electrical parking lock actuator has an electric motor, a spur gear stage driveable by the electric motor, and a worm gear stage driveable by the spur gear stage. A worm shaft of the worm gear stage is connected rotationally conjointly to an output gear of the spur gear stage, and a worm gear of the worm gear stage is connected rotationally conjointly to a transmission-side parking lock shaft. The worm shaft is fixed in an axially displaceable manner in the output gear. A stop limits the pivoting movement of the worm gear when a parking lock position of the parking lock shaft is reached. A spring braces the worm shaft in an axial direction of the worm shaft against a holding mechanism which is situated in a stop position, in which the holding mechanism is fixed by an electrically energized electromagnet.