A photovoltaic support includes a first vertical upright column (110) and a second vertical upright column (120) on a foundation, and a beam (10) respectively hinged with a first end of the first vertical upright column (110) and a first end of the second vertical upright column (120). The photovoltaic support further includes a first movable connecting piece (140) provided on the foundation and connected with a second end of the first vertical upright column (110). The first movable connecting piece (140) is automatically adjusted according to the wind intensity, such that the first vertical upright column (110) moves in a vertical direction to adjust an inclination angle of the beam (130). The photovoltaic support can adjust the angle adaptively in the case of a strong wind, and restore automatically after the strong wind has passed.

The present disclosure provides a handheld gimbal control method and a handheld gimbal. The method includes: acquiring an input signal (S301); and performing a first control operation triggered by a first trigger signal in response to the input signal being a predetermined first trigger signal, where the first control operation is used to control the yaw axis motor disposed on the handheld gimbal to start and continue to work so as to enable the imaging device carried by the handheld gimbal to start and continue a rolling rotation (S302). The control method relieves a user from pressing the control button on the handle at all times, thereby improving the flexibility of user operation and user experience.

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 gimbal control method includes obtaining a working parameter of a gimbal, where the gimbal includes an axial arm and a motor configured to drive the axial arm to rotate to drive a photographing device mounted on the gimbal to move in one or more directions; detecting that the working parameter matches a preset condition that a human force is applied to gimbal; and according to a direction of the human force applied to the gimbal, controlling the motor to drive the axial arm to rotate to a target attitude at which the human force stops to be applied to the gimbal.

A handheld gimbal includes a handheld structure and a gimbal body operably coupled with the handheld structure. The handheld structure includes a handheld body having at least one functional button, and a gripping structure extending from a bottom portion of the handheld body away from the handheld body. The gimbal body is operably coupled with a side of the handheld body.

A mounting system capable of mounting objects to support structures. The mounting system includes a wall mount including a display bracket configured to hold the object, a fixed support bracket coupleable to a vertical support structure, and a linkage assembly. The linkage assembly has a low-profile stowed configuration in which the object is held in a raised position close to the support structure. Tilt adjustment mechanisms are used to adjust the tilt of the display bracket.

A variable height workstation system comprises a base, a variable height platform, a lift mechanism, a lower adjustable pivot assembly, and an upper adjustable pivot assembly. The base is configured to be mounted to a support surface. The lift mechanism is configured to move the variable height platform between a fully lowered and raised position. The lower adjustable pivot assembly is configured to be connected be to the base and the lift mechanism. The lower adjustable pivot assembly comprises a lower adjustable force regulator configured to adjust a force required to rotate a lower pivot member about its first vertical rotational axis. The upper adjustable pivot assembly is configured to be connected to the lift mechanism and the variable height platform. The upper adjustable pivot assembly comprises an upper adjustable force regulator configured to adjust a force required to rotate an upper pivot member about its second vertical rotational axis.

A gimbal includes a pitch axis assembly including a pitch axis motor and configured to be connected to a payload, a roll axis assembly connected to the pitch axis and including a roll axis motor positioned below the pitch axis motor, and a yaw axis assembly connected to the roll axis assembly and including a yaw axis motor positioned below the roll axis motor. The roll axis motor and the yaw axis assembly are configured to be positioned below the payload.

The present disclosure provides a control device for controlling an imaging device. The control device includes an operation unit configured to be operated by an external force; a detection unit configured to detect an operation state of the operation unit; a processor configured to execute a program to: perform a predetermined operation based on the operation state of the operation unit; and invalidate an execution of the predetermined operation performed by the processor based on the operation state of the operation unit when the imaging device is connected to an object satisfying a condition.

A support arm arrangement for a local gas extractor arrangement and a local gas extractor arrangement including such a support arm arrangement. The support arm arrangement includes a first support arm and at least one second support arm being pivotally coupled to each other by of friction joint arrangements. The support arm arrangement receives a tube device coupled to an extractor hood an exterior pump device and the support arms. The extractor hood is arranged at an outermost second support arm by of a linkage arm arrangement including a first link arm, pivotally coupled to the outermost second support arm by a first friction joint pivotable about a first pivoting axis, and a second link arm fixedly attached to the extractor hood and pivotally coupled to the first link arm by a second friction joint pivotable about a second pivoting axis extending in a direction perpendicular to the first pivoting axis.