A facility for automated modelling of the cutting process for a particular material to be cut by a beam cutting tool, such as a waterjet cutting system, from empirical data to predict aspects of the waterjet's effect on the workpiece across a range of material thicknesses, across a range of cutting geometries, and across a range of cutting quality levels, all of which may be broader than, and independent of the actual requirements for a target workpiece, is described.

A facility for automated modelling of the cutting process for a particular material to be cut by a beam cutting tool, such as a waterjet cutting system, from empirical data to predict aspects of the waterjet's effect on the workpiece across a range of material thicknesses, across a range of cutting geometries, and across a range of cutting quality levels, all of which may be broader than, and independent of the actual requirements for a target workpiece, is described.

A gear fine-tuning pan-tilt includes a rotating base, a roll worm support seat, a roll adjusting assembly, a pitch adjusting assembly, and a bearing seat arranged in sequence from bottom to top; the pitch adjusting assembly of the complete gear structure is located on the above, and the roll adjusting assembly located below adopts an arc-shaped rack structure, which reduces the interference to the pitching movement of the upper assembly and makes the height of the pan-tilt smaller. The arc opening of the arc-shaped rack faces upwards, so that the rotation axis is closer to the center axis of the lens. The upper and lower combination of the two structures strengthens the swing ability of the top of the pan-tilt in the limited size. The structure is able to be aimed at the subject through the rotating base, and leveled the left and right, and determined the pitch angle.

A gear fine-tuning pan-tilt includes a rotating base, a roll worm support seat, a roll adjusting assembly, a pitch adjusting assembly, and a bearing seat arranged in sequence from bottom to top; the pitch adjusting assembly of the complete gear structure is located on the above, and the roll adjusting assembly located below adopts an arc-shaped rack structure, which reduces the interference to the pitching movement of the upper assembly and makes the height of the pan-tilt smaller. The arc opening of the arc-shaped rack faces upwards, so that the rotation axis is closer to the center axis of the lens. The upper and lower combination of the two structures strengthens the swing ability of the top of the pan-tilt in the limited size. The structure is able to be aimed at the subject through the rotating base, and leveled the left and right, and determined the pitch angle.

A product dispenser holder comprises a dispenser holder body configured to receive a product dispenser that stores a supply of a product to be dispensed, an actuation sensor that senses actuations of the product dispenser, and an actuation button, such that when an actuation force is applied to a pump of the product dispenser, a substantially downward force is applied to the actuation button causing the actuation button to rotate substantially downwardly and actuate the actuation sensor to generate a dispenser actuation signal.

A track mounted workstation assembly is disclosed having a housing including a track and one or more communication or electrical or communication ports, and one or more roller mount assemblies further including a sliding carriage configured to slide along the track. In addition, the mounts may further include wiring and cables configured to communicate with the communication or electrical ports of the track housing at either ends. In addition, the mounts may further include one or more receiving members for receiving one or more articulating arms for monitors, peripherals, and other equipment.

The invention relates to a device (10) for displaceably positioning a kitchen appliance (11) on a working surface (12), comprising a displacement means (13) for displacing the kitchen appliance (11) on the working surface (12), wherein the displacement means (13) is designed for installation in a ground area (14) of a base unit (16) of the kitchen appliance (11), and a displacement means (15) for displacing the displacement means (13) between a deactivated state (Z1) of the displacement means (13) for positioning the displacement means (13) spaced from the working surface (12) and an activated state (Z2) of the displacement means (13) for positioning at least a part of the displacement means (13) on the working surface (12) for displacing the kitchen appliance (11). The invention further relates to a base unit (16) with a device (10) according to the invention, as well as a method for operating a base unit (16) according to the invention.

The invention relates to a device (10) for displaceably positioning a kitchen appliance (11) on a working surface (12), comprising a displacement means (13) for displacing the kitchen appliance (11) on the working surface (12), wherein the displacement means (13) is designed for installation in a ground area (14) of a base unit (16) of the kitchen appliance (11), and a displacement means (15) for displacing the displacement means (13) between a deactivated state (Z1) of the displacement means (13) for positioning the displacement means (13) spaced from the working surface (12) and an activated state (Z2) of the displacement means (13) for positioning at least a part of the displacement means (13) on the working surface (12) for displacing the kitchen appliance (11). The invention further relates to a base unit (16) with a device (10) according to the invention, as well as a method for operating a base unit (16) according to the invention.

A display device 20 includes: a hinge 91; a first monitor device 21 including a first front surface 22; and a second monitor device 31 including a second front surface 32. Parallel planes from a virtual second front surface on a rear side by predetermined distances at a first angle a to a third angle c between the first front surface 22 and the virtual second front surface are defined as first to third virtual planes E to G. A rotation axis X1 of the hinge 91 is disposed on anyone of these three virtual planes or inside a space formed by the three virtual planes in a view in a direction parallel to the rotation axis X1, and the second front surface 32 is disposed at a position away from the rotation axis X1 on a front side of the second monitor device 31 by a predetermined distance.

A display device 20 includes: a hinge 91; a first monitor device 21 including a first front surface 22; and a second monitor device 31 including a second front surface 32. Parallel planes from a virtual second front surface on a rear side by predetermined distances at a first angle a to a third angle c between the first front surface 22 and the virtual second front surface are defined as first to third virtual planes E to G. A rotation axis X1 of the hinge 91 is disposed on anyone of these three virtual planes or inside a space formed by the three virtual planes in a view in a direction parallel to the rotation axis X1, and the second front surface 32 is disposed at a position away from the rotation axis X1 on a front side of the second monitor device 31 by a predetermined distance.