A switch arrangement for a track-borne vehicle has at least two articulatedly interconnected switch segments mounted so as to be movable with respect to a base surface. At least one switch segment has a drive. At least two switch segments are interconnected by means of an articulation, which has at least two degrees of rotational freedom. The articulation also or alternatively can have at least one degree of translational freedom, which is optionally formed with at least one additional degree of rotational freedom.

The present invention provides a movable point frog. In this application, quasi-continuity of rails is achieved at the frog, so that a gap in the frog is eliminated, vibration and noise are reduced, and transverse impact of wheels is eliminated. Guard rails do not need to be disposed. The frog itself does not limit the speed of a train running on a main line and a branch line. Therefore, the train running on the main line can pass through the frog without reducing the speed. A relatively small curve radius and a relatively large frog angle may be adopted for the branch line. Compared with integrally cast frog equipment in the prior art, all the components in this application are detachably connected, and therefore can be simply mounted, easily maintained, and produced in batch.

An automated material handling system (AMHS) and a method of operating the AMHS are disclosed. In one aspect, the AMHS includes a network of rails and a vehicle configured to hold a sample carrier that stores one or more samples, wherein the vehicle is configured to move within the FAB via the network of rails. The AMHS also includes a turn table connected to the network of rails and configured to rotate about an axis substantially perpendicular to a surface of the turn table. The AMHS further includes a hash rail connected to and overlapping the turn table. The hash rail is configured to rotate about the axis with the turn table.

An automated material handling system (AMHS) and a method of operating the AMHS are disclosed. In one aspect, the AMHS includes a network of rails and a vehicle configured to hold a sample carrier that stores one or more samples, wherein the vehicle is configured to move within the FAB via the network of rails. The AMHS also includes a turn table connected to the network of rails and configured to rotate about an axis substantially perpendicular to a surface of the turn table. The AMHS further includes a hash rail connected to and overlapping the turn table. The hash rail is configured to rotate about the axis with the turn table.

A switch arrangement for a track-borne vehicle has at least two articulatedly interconnected switch segments mounted so as to be movable with respect to a base surface. At least one switch segment has a drive. At least two switch segments are interconnected by means of an articulation, which has at least two degrees of rotational freedom. The articulation also or alternatively can have at least one degree of translational freedom, which is optionally formed with at least one additional degree of rotational freedom.