A portable video display system includes a base container and a display monitor mounted to a display support structure. The display support structure is hingedly coupled to the base container and can be moved between; (i) a closed position wherein at least a portion of the display support structure is stored within the case interior space; and (ii) an open position wherein at least a portion of the display support structure is in a deployed position outside of the case interior space. In the open position, the base container acts as a stand and supports the display support structure in the deployed position. The display support structure is configured to protect a display monitor when the display support structure is in the open position and includes a translucent shield that is positioned over the display monitor.

A portable video display system includes a base container and a display monitor mounted to a display support structure. The display support structure is hingedly coupled to the base container and can be moved between; (i) a closed position wherein at least a portion of the display support structure is stored within the case interior space; and (ii) an open position wherein at least a portion of the display support structure is in a deployed position outside of the case interior space. In the open position, the base container acts as a stand and supports the display support structure in the deployed position. The display support structure is configured to protect a display monitor when the display support structure is in the open position and includes a translucent shield that is positioned over the display monitor.

The present invention relates to the technical field of vehicle maintenance and device calibration, and discloses a vehicle-mounted radar calibration device and method. The vehicle-mounted radar calibration device includes a bracket apparatus and a radar calibration component. The radar calibration component is configured to be installed on the bracket apparatus and includes a base board. After calibration on the vertical plane of the base board is completed, the radar calibration component is configured to reflect a radar wave, emitted by a vehicle-mounted radar of a to-be-calibrated vehicle, to the vehicle-mounted radar, to calibrate the vehicle-mounted radar. In the present invention, after the vertical plane of the base board is calibrated, the radar calibration component is used to reflect the radar wave emitted by the vehicle-mounted radar to the vehicle-mounted radar.

A stand for supporting a board includes a wire frame having a first portion configured to support an edge of the board, and a second portion extending from the first portion. The stand also includes a latch mounted on the second portion. The latch is operable to restrain movement of the board relative to the wire frame.

A stand for supporting a board includes a wire frame having a first portion configured to support an edge of the board, and a second portion extending from the first portion. The stand also includes a latch mounted on the second portion. The latch is operable to restrain movement of the board relative to the wire frame.

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 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 wall mount bracket assembly includes a first bracket having a vertical flange and a horizontal flange and a second bracket having a vertical flange and a horizontal flange. The horizontal flanges of the first and second bracket are adjustably coupled such that a gap defined between the vertical flanges of the first and second brackets may be varied, wherein the first and second brackets define a downwardly opening channel.

A wall mount bracket assembly includes a first bracket having a vertical flange and a horizontal flange and a second bracket having a vertical flange and a horizontal flange. The horizontal flanges of the first and second bracket are adjustably coupled such that a gap defined between the vertical flanges of the first and second brackets may be varied, wherein the first and second brackets define a downwardly opening channel.

A method of reassembling a gas turbine engine including steps to support a core engine on a core stand and support a fan case on a fan stand that includes a base frame coupled a fan case frame by a hinge. The fan case frame is arranged to (i) rotate about an axis of the hinge between abutting the base frame and being perpendicular to the base frame, and (ii) tilt about a yaw axis perpendicular to the hinge, which is located in a plane of the fan case frame. The method includes rotating and tilting the fan case frame to align the fan case and core engine, translating at least one of the core engine and the fan case into axial abutment, coupling the fan case and the core engine to reassemble the gas turbine engine, and decoupling the fan case from the fan stand.