A height adjustable device including a counterbalance mechanism configured to be affixed adjacent to a rear portion of a vertical support member, a worksurface configured to be affixed adjacent to a front portion of the vertical support member, and a mounting member configured to slidably couple the worksurface to the counterbalance mechanism; wherein a portion of the mounting member extends through an opening defined in the vertical support member.

A monitor support assembly includes a base designed to rest on an ambient floor surface. An upright frame structure is spaced forward to the rear of and extends vertically upward from the base. The frame structure includes first and second vertical members and a top frame member that extends horizontally between the first and second vertical members. A shroud assembly is mounted to the upright frame structure and includes a first central wall member and first and second additional wall members extending from the first and second lateral edges in the same direction. The first central wall member and the additional wall members form a receiving space. A mounting plate mountable to the rear surface of a displays screen is releasably supported by the upright frame structure within the receiving space. A depth dimension of the receiving space is sufficient to accommodate a display screen mounted via the mounting plate.

A passive motion isolation system for motion-sensitive equipment is disclosed. The passive motion isolation system has a three-axis free motion platform mounted on a base subject to ambient motions. A vibration isolation subsystem is coupled between the motion-sensitive equipment and the three-axis free motion platform.

A passive motion isolation system for motion-sensitive equipment is disclosed. The passive motion isolation system has a three-axis free motion platform mounted on a base subject to ambient motions. A vibration isolation subsystem is coupled between the motion-sensitive equipment and the three-axis free motion platform.

A mount for adjusting a mounting plane is disclosed. The mount comprises a first adjustable device, a second adjustable device and a third adjustable device. A first intersection between the first adjustable device and the second adjustable device forming a first principal axis and a second intersection between the second adjustable device and the third adjustable device forming a second principal axis substantially perpendicular to the first principal axis. The first adjustable device, second adjustable device and third adjustable device rigidly coupled together. The first adjustable device is configurable to be adjusted in a first translational degree of freedom, and substantially constrain the first adjustable device in remaining translational degrees of freedom, wherein adjustment of the first adjustable device in the first translational degree of freedom causes a rotation of the mounting plane about the second principal axis. The second adjustable device is configurable to be adjusted in a second translational degree of freedom, and substantially constrain the second adjustable device in remaining translational degrees of freedom, wherein adjustment of the second adjustable device in the second translational degree of freedom causes a rotation of the mounting plane about a third principal axis, perpendicular to the first and second principal axis. The third adjustable device is configurable to be adjusted substantially in the first translational degree of freedom, and substantially constrain the third adjustable device in remaining translational degrees of freedom, wherein adjustment of the third adjustable device in the first translational degree of freedom causes a rotation of the mounting plane about the first principal axis. A first end of each adjustable device is configured to be fixed in location and a second end forms the mounting plane. Each adjustable device comprises a rotation device located between the first end and the second end of each adjustable device, the rotation device configured to allow the second end to rotate about three degrees of freedom.

An elevatable supporting device for bearing a display is provided. The elevatable supporting device comprises an upright, an energy storage element, and a bearing module. The upright includes a first surface and a second surface which is non-parallel to the first surface. The energy storage element abuts against the first surface and the second surface and includes a first arm providing a first resistance and a second arm providing a second resistance. A first included angle is defined between the first arm and the second arm. When the energy storage element moves from the highest position to the lowest position, the first included angle decreases so that one of the first resistance and the second resistance may increase in order to maintain a total effective resistance along the first axis. Accordingly, the display may be able to stop at any position between the highest position and the lowest position.

An apparatus for positioning an electronic display is described. The apparatus can be combined with an existing work surface to provide a multi-position workstation. In some cases, the apparatus includes a mounting portion configured to support an electronic display and a keyboard. The mounting portion may be movable with respect to the work surface between multiple positions, including for example, a sitting position and a standing position. Methods for positioning an electronic display and a keyboard are also included.

A mounting system capable of mounting objects to support structures is disclosed. The mounting system includes a wall mount including a display bracket configured to hold the object, a fixed support bracket couplable 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. The linkage assembly moves to another configuration to move the object. The object can be held in a lowered position. A biasing mechanism can facilitate convenient movement of the object.

A method of controlling operation of a linear actuator, including maintaining the linear actuator in equilibrium when supporting a first load, determining application of a second load on the linear actuator, and selectively actuating the linear actuator in response to application of the second load on the linear actuator.

A supporting mechanism with a rotating function is applied to a camera apparatus and includes a casing, a holder, an inner structural component and a damping component. The casing has a first opening. The inner structural component can be rotated relative to the casing. The holder is movably disposed inside the inner structural component and passes through the first opening. The damping component is disposed between the casing and the inner structural component.