A method and device are provided for positioning a mounted camera. The device includes a holding element that secures the mounted camera to the device, a wireless linkage at which remote attitude commands representing attitude changes of a remote driver are received, a local controller that interprets the remote attitude commands and generates local attitude commands that move the camera to mimic an orientation of the remote driver, and an attitude sensing element that senses a local attitude of the device. The attitude sensing element includes a gyro, an accelerometer, or a magnetometer, and jitter present in the remote attitude commands is removed and not passed on to the local attitude commands.

An expandable plant caddy assembly is provided with a frame with a plurality of legs. A plurality of plates is each mounted for translation to one of the plurality of legs, to collectively support a planter, and to allow expansion to accommodate planters of varying sizes. A plurality of guides is each mounted to one of the plurality of plates to connect each plate for translation along the corresponding leg of the plurality of legs. A plurality of casters is each mounted to one of the plurality of guides with the corresponding leg therebetween to apply compression upon the corresponding leg between the caster and the guide to resist inadvertent adjustment of each of the plurality of plates, and to permit travel of the expandable plant caddy.

An expandable plant caddy assembly is provided with a frame with a plurality of legs. A plurality of plates is each mounted for translation to one of the plurality of legs, to collectively support a planter, and to allow expansion to accommodate planters of varying sizes. A plurality of guides is each mounted to one of the plurality of plates to connect each plate for translation along the corresponding leg of the plurality of legs. A plurality of casters is each mounted to one of the plurality of guides with the corresponding leg therebetween to apply compression upon the corresponding leg between the caster and the guide to resist inadvertent adjustment of each of the plurality of plates, and to permit travel of the expandable plant caddy.

A swivel device includes a base, a first gear fixed to the base, a tray configured to relatively rotate with respect to the base, a second gear fixed to the tray and engaged with the first gear so as to rotate together with the tray wherein the second gear has a smaller diameter than the first gear, a stopper wheel coaxially fixed to the second gear, and a stopper configured to stop rotation of the stopper wheel to fix a position of the tray.

A swivel device includes a base, a first gear fixed to the base, a tray configured to relatively rotate with respect to the base, a second gear fixed to the tray and engaged with the first gear so as to rotate together with the tray wherein the second gear has a smaller diameter than the first gear, a stopper wheel coaxially fixed to the second gear, and a stopper configured to stop rotation of the stopper wheel to fix a position of the tray.

The invention relates to a device 10 for holding workpieces 30 in a process chamber. The invention additionally relates to a coating system 20 and to a method for coating a workpiece 30. In order to allow for precise adjustment of the height of the position of workpieces 30 while supporting same in a secure and stable manner, the holding device 10 comprises a tray 72 for the workpieces 30, a height-adjustable first support element 22 and a height-adjustable second support element 48 for the tray 72, wherein each of the support elements 22, 48 comprises at least one first and one second limb element 26, 56, wherein the respective first and the respective second limb element 26, 56 are coupled so as to be pivotable relative to one another about a pivot axis X, Y, and wherein the pivot axis X of the first support element 22 is arranged at an angle to the pivot axis Y of the second support element 48.

A calibration bracket (100), comprising: a base (10); a stand component (20) connected to the base (10); a cross beam component (30, 30′) mounted to the stand component (20) and used for mounting a calibration element, which is used for calibrating an advanced driver assistant system of a vehicle; and a rotating component (40) mounted between the stand component (20) and the base (10), and used for driving the stand component (20) to pivot about a central axis of the stand component (20) relative to the base (10) so as to adjust an angle of rotation of the cross beam component (30, 30) relative to the central axis of the stand component (20). According to the structure, an angle of rotation of the cross beam component (30, 30′) relative to the central axis of the stand component (20) can be adjusted, so that the rotation of the cross beam component (30, 30′) is free from the mounting position. The calibration bracket is simple in structure, and convenient to carry.

A calibration bracket (100), comprising: a base (10); a stand component (20) connected to the base (10); a cross beam component (30, 30′) mounted to the stand component (20) and used for mounting a calibration element, which is used for calibrating an advanced driver assistant system of a vehicle; and a rotating component (40) mounted between the stand component (20) and the base (10), and used for driving the stand component (20) to pivot about a central axis of the stand component (20) relative to the base (10) so as to adjust an angle of rotation of the cross beam component (30, 30) relative to the central axis of the stand component (20). According to the structure, an angle of rotation of the cross beam component (30, 30′) relative to the central axis of the stand component (20) can be adjusted, so that the rotation of the cross beam component (30, 30′) is free from the mounting position. The calibration bracket is simple in structure, and convenient to carry.

A calibration support includes a support body (100) configured to mount a calibration element, the calibration element being configured to calibrate a driving assistance system of a vehicle (500); an image acquisition device (200) connected to the support body (100) and configured to acquire an image of the vehicle (500); a processing device (300) provided on the support body (100), electrically connected to the image acquisition device (200), and configured to calculate, according to the image acquired by the image acquisition device (200), the movement position of the support body (100) relative to the vehicle (500) and output a control signal comprising the movement position; and a control device (400) provided on the support body (100), electrically connected to the processing device (300), and configured to receive the control signal and control the support body (100) to move.

A calibration support includes a support body (100) configured to mount a calibration element, the calibration element being configured to calibrate a driving assistance system of a vehicle (500); an image acquisition device (200) connected to the support body (100) and configured to acquire an image of the vehicle (500); a processing device (300) provided on the support body (100), electrically connected to the image acquisition device (200), and configured to calculate, according to the image acquired by the image acquisition device (200), the movement position of the support body (100) relative to the vehicle (500) and output a control signal comprising the movement position; and a control device (400) provided on the support body (100), electrically connected to the processing device (300), and configured to receive the control signal and control the support body (100) to move.