A wearable device includes a frame, two feet, and two pivoting modules. Each of the pivoting modules includes a first bracket fixedly connected to the frame, and a second bracket fixedly connected to one of the feet and pivotally coupled to the first bracket. The second bracket includes a positioning member and an inserting member. The positioning member is located in the first bracket, and the positioning member includes a plurality of slots. The inserting member is switchably inserted into one of the slots for adjusting a maximum outreaching volume from the frame to the feet.

A pan-tilt and an aerial camera containing a pan-tilt. This pan-tilt includes a motor which has a first part and a second part of relative movement, a slip ring which is installed in the motor and has a fixing part and a rotating part, and a control part which is installed under the motor and at which the second part is installed. The center of the motor has a first hole which longitudinally penetrates through, in which the slip ring is installed. The fixing part is static relative to the first part. The control part is electrically connected to the rotating part via a wire which is set to pass through the first hole. The control part is electrically connected with the motor. The pan-tilt can be rotated by 360 degrees.

Provided is a working machine including first and second members, an angle detection device and a connection pin connected to the first and second members to rotate integrally with the second member relative to the first member. The angle detection device has a marker, an angle sensor and a guard member, which has a main guard portion covering the angle sensor and including an inner opposite surface opposed to an end surface of the projecting end portion and a guard-member-side engagement portion. One of the angle sensor and the marker is disposed on the inner opposite surface, the other disposed on the end surface. The first member has a first-member-side engagement portion engaging with the guard-member-side engagement portion to restrain the main guard portion from relative rotation. The guard member can contact with the connection pin to restrain the guard member from relative displacement to the projecting end portion.

A bearing joint assembly may include a bearing sleeve, a first collar, a first mount, a pair of second mounts and a fastener, which projects through the bearing sleeve and secures the bearing sleeve to the second mounts. The bearing sleeve extends axially along a centerline and includes a spherical bearing. The first collar is configured with the bearing sleeve. A first annular channel is formed by and extends axially between the spherical bearing and the first collar. The first mount is mounted on and slidably engages the spherical bearing. The spherical bearing and the first collar are axially between the second mounts.

A pivot structure assembly including a fixed cover and a hinge module is provided. The hinge module includes a torque element, a first shaft, a second shaft, a first bracket and a second bracket. The torque element is fixed on the fixed cover and has a first and a second axle sleeves, parallely disposed at two opposite sides of the torque element. The first shaft is disposed through the first axle sleeve, and the second shaft is disposed through the second axle sleeve. The first bracket is pivotally disposed on the torque element through the first shaft, and the second bracket pivotally disposed on the torque element through the second shaft. When the first and second brackets rotate relatively to the torque element, the first and second axle sleeves respectively provide different friction forces to the first and second shafts. In addition, an electronic device is also mentioned.

Systems for thrust reverser link arm connections are described herein. A linkage system for a nacelle may comprise a thrust reverser link arm and a fitting. The fitting may comprise a base plate configured to be fastened to a proximal surface of an inner fixed structure (IFS), a first wall extending orthogonally from the base plate, a second wall extending orthogonally from the base plate, and a pin extending orthogonally from the first wall and extending orthogonally from the second wall. A first end of the thrust reverser link arm may comprise a removable member, the removable member having an inner surface comprising a semi-circle, the inner surface configured to seat against the pin. The removable member may be removed from the linkage system from a radially outward side of the IFS.

According to some embodiments, a removably coupled stand for a screen comprises a holder portion to removably couple a screened device and a foot portion to move from a closed position to an open position. The foot portion is hinged to the holder portion and the holder portion comprises a top side, a rear side, and a bottom side.

Embodiments generally relate to hinge mechanisms. The central cylinder has a rotate channel transverse to the hinge axis. A collar may couple with the central cylinder and may include a pin that protrudes inwardly into the rotate channel. In some embodiments, the central cylinder may include a second rotate channel and the pin may extend through the first and second rotate channels of the central cylinder. In some embodiments, the central cylinder may include a tapered locking channel that extends and tapers in an axial direction from the rotate channel. Optionally, the collar may include an aperture for receiving the pin therethrough. The pin may be repositionable to a plurality of positions relative to the collar about an insertion axis. The pin repositioning may vary an axial position of the collar relative to the central cylinder, a rotational range of motion of the collar about the central cylinder, or both.

A pivot pin assembly for a tree shaker pivotally attaches the clamping arm to the stationary arm. Each end of the cylindrical pivot pin extends outside of a cylindrical bore of the clamping arm. A longitudinal load member extends through an aperture in the stationary arm and into an aperture in the cylindrical pivot pin. An axial load may be applied to the longitudinal load member which compresses a plate of the stationary arm against the cylindrical pivot pin, but without compressing the stationary arm against the clamping arm. This configuration allows substantial torque to be applied to the longitudinal load member, which reduces play between the stationary arm and the clamping arm without inhibiting the free rotation of the clamping arm. Application of this torque eliminates radial and vibratory movement in the shaker head, which otherwise cause damage to the components of the shaker head.

A power cell unit may include a piston assembly having a piston crown and a piston skirt. The piston crown may include a ring belt portion extending circumferentially about a combustion bowl and at least one boss portion extending downward from the combustion bowl. The power cell unit may also include a connecting rod having an elongated portion and a funnel portion, and at least one piston pin configured to connect the connecting rod with the piston assembly. A bottom surface of the at least one boss portion may engage with a corresponding surface of the funnel portion such that a gas load is substantially transferred directly from the piston crown to the connecting rod during downward motion of the piston assembly, and such that only inertial loading from the piston crown and/or piston skirt is transferred to the piston pin during upward motion of the piston assembly.