The invention provides a lightweight hand-held stabilizer comprising a gimbal and a 7-shaped handle. The 7-shaped handle comprises a first connection arm (1) and a second connection arm (2), one end of the first connection arm (1) is rigidly connected to one end of the second connection arm (2), and a movable connector(s) is arranged at the end face of the other end of the first connection arm (1) and/or the second connection arm (2). The present invention can provide multiple using modes of the stabilizer handle, and the user experience of a stabilizer product is enhanced.

A display mounting system including a support column, a moving bracket, an arm assembly, and a tilt assembly is described. The display mounting system includes one or more display attachment brackets to support one or more electronic displays. The display mounting system is used to hold one or more electronic displays over a work surface or in front of a wall, and it allows the user of the display mounting system to easily change the orientation of one or more electronic displays according to user's preferences.

The present disclosure is directed to table mount for mounting a touchscreen device to a surgical table. The table mount includes a clamp configured to releasably secure the table mount to the table, a first arm rotatably connected to the clamp and configured to extend vertically from the surgical table, a second arm rotatably connected to the first arm, and a touchscreen device docking assembly rotatably connected to the second arm and configured to hold a touchscreen device.

A stabilisation system (6) comprises a base for attachment to a first object (2), a telescopic element having a first portion rotatably engaged with the base, and a second portion linearly slidably engaged with the first portion. The second portion has an attachment portion adapted for reception of a second object (1). The system includes plurality of linear actuators, each linear actuator having a first portion rotatably engaged with the base, and a second portion linearly slidably engaged with the first portion of the actuator concerned, and rotatably engaged with the second portion of the telescopic element. Each linear actuator is operable to drive the second portion thereof linearly with respect to the first portion thereof.

The present disclosure relates to a plane-distributed load sharing pressure device and a use method thereof. The plane-distributed load sharing pressure device includes a first-stage balance rod to an Nth-stage balance rod, N≥2. The middle part of the first-stage balance rod is hinged to a force applying member. The two ends of the first-stage balance rod are respectively perpendicular to and hinged to the middle parts of second-stage balance rods. The two ends of the second-stage balance rod are respectively perpendicular to and hinged to the middle parts of third-stage balance rods. Similarly, the two ends of an (N−1)th-stage balance rod are respectively perpendicular to and hinged to the middle parts of Nth-stage balance rods. Force bearing members used for resolving a force applied by the force applying member to target members are arranged at the two ends of the Nth-stage balance rods.

A display mounting system including a support column, a moving bracket, an arm assembly, and a tilt assembly is described. The display mounting system includes one or more display attachment brackets to support one or more electronic displays. The display mounting system is used to hold one or more electronic displays over a worksurface or in front of a wall, and it allows the user of the display mounting system to easily change the orientation of one or more electronic displays according to user's preferences.

The present invention relates to the field of wave compensation equipment, and discloses a 6-Dof platform for wave compensation, comprising a soleplate, a 2R1T parallel unit, a 1R2T series unit and an upper platform. The soleplate is installed on a deck of a ship, the 2R1T parallel unit is installed on the soleplate, the 1R2T series unit is installed on the 2R1T parallel unit, and the upper platform is installed on the 1R2T series unit. The invention compensates 6-Dof motion of heave, roll, pitch, sway, surge and yaw of the ship under action of waves. The present invention has the advantages of simple structure, high carrying capacity, easy control and high precision in posture control.

A gimbal assembly includes a body and a gimbal frame movably connected with the body. The gimbal frame is configured to completely fit with the body or partially fit with the body through a sliding mechanism to reduce a volume of the gimbal assembly. The sliding mechanism includes a first sliding member disposed at the body and a second sliding member disposed at the gimbal frame to match with the first sliding member, such that the gimbal frame slides from an extended position to a receiving position with respect to the body.

A gimbal photographing device includes a machine body, a foldable mechanism connected with the machine body, and a gimbal camera connected with the foldable mechanism. The gimbal camera is configured to cling to the machine body through the foldable mechanism and to be positioned in an extended state or a folded state. The machine body includes a support wall configured to support the gimbal camera. The foldable mechanism includes a rotation member rotatably connected with the support wall around a rotation axis direction to cause the gimbal camera to rotate relative to the machine body. The rotation member is configured to cause the gimbal camera to rotate to the folded state in which the gimbal camera clings to the support wall.

A gimbal photographing device includes a body including a supporting wall and a side wall adjacent to the supporting wall, a folding mechanism connected to the body and configured to rotate around a rotation axis, and a gimbal camera connected to the folding mechanism and having an expanded state and a folded state. In response to the folding mechanism driving the gimbal camera to rotate to the expanded state, at least a portion of the folding mechanism abuts against the supporting wall. In response to the folding mechanism driving the gimbal camera to rotate to the folded state, the gimbal camera fits to the side wall of the body.