A switch device for moving switch rails. The switch device includes a motor operatively coupled to move the switch rails into and between first and second positions. The motor is configured for electricity to flow therethrough along a first path and a second path. A first path relay has two normally open contacts each within the first path, where activating the first path relay closes the two normally open contacts thereof. A second path relay has two normally open contacts each within the second path, where activating the second path relay closes the two normally open contacts thereof. The motor moves the switch rails towards the first position when the first path relay is activated and the second path relay is deactivated, and the motor moves the switch rails towards the second position when the second path relay is activated and the first path relay is deactivated.

A track switch that comprises track rails of basic (2), (3), straight, (4), (5) and lateral (6), (7) directions fastened on a slab track (1); sliding switch rails (8); (9) and point rails (10), (11) that are rigidly fastened to the slab track (1) by means of mounting means (12). The point rails and switch rails form points. The track switch comprises also a shift mechanism with a drive (14) and an axis (15), whereto sliding locks (16), (17) are connected. The point rails (10), (11) and the switch rails (8), (9) are connected with each other by means of units. Each of the units is a guide (18) that is rigidly fastened to the point rail, a wedge (19) that is rigidly fastened to the switch rail (8), (9), a cleat wedge (20) placed in the guides that is capable of moving longitudinally and fastened with its both ends to point rods (21) of the wedge (see FIGS. 1 and 4). The sliding wedges (20) are connected to each other by means of point rods (21), the last of the point rods being connected with the axis of the shift mechanism that is capable of rotating or moving longitudinally, and is set into motion by a shift drive mechanism. The sliding switch rails (8), (9) are connected to each other by means of spacing rods (22).

The present invention relates to a track switching apparatus for rail trolleys. It comprises at least one linear track, a curved track connected to the at least one linear track, at least one switching region formed at a connection region of the linear track and the curved track, and at least one switching unit disposed in the at least one switching region.

A rail-switching unit, functioning singly or combined with other same units as part of a track-switching unit of a track-switching system of a vehicle-guiding system is provided. The rail-switching unit includes a rotatable ensemble including a rotatable-hub with attached switch-rails and auxiliary components and stationary elements including a main fixed-rail, branch fixed-rails and a supporting structure, wherein the branch fixed-rails are attached to common rails and the rotatable-hub selectively rotates to allow an engagement of each switch-rail simultaneously with the main fixed-rail and with a corresponding branch fixed-rail with a purpose of creating alternative continuous rail paths for vehicles to move through the rail-switching unit. A mechanism is applicable to mono/multi-railed tracks, to supporting/suspended vehicles, to traditional/rail-wrapping wheels-assemblies, to diverge/merge/cross-points, and to a wide variety of track-switching configurations.

A railroad switch circuit controller assembly includes a switch frame configured to be mounted to a stock rail, and a switch controller held by the switch frame. The switch controller includes at least one switching mechanism. The switch controller includes a point detection rod operatively connected to the at least one switching mechanism. The point detection rod extends a length from a proximate end portion to a distal end portion. The proximate end portion of the point detection rod is located closer to the stock rail as compared to the distal end portion when the switch frame is mounted to the stock rail. The railroad switch circuit controller assembly also includes a switch foot configured to be mounted to a switch rail, and an external rod operatively connected between the switch foot and the point detection rod of the switch controller such that the external rod is configured to translate linear movement of the switch foot toward and away from the stock rail to the point detection rod. The external rod is connected to the proximate end portion of the point detection rod.

An improved switch point machine is provided which can seal out water, even if the machine itself becomes submerged. The operating rod and the point indicating rod that extend out of the switch box housing should be ground round and have a smooth surface for an improved seal. Those rods are preferably chrome plated. Dynamic hydraulic seals can be used to seal out moisture. Internal components, within the switch box housing, should also be sealed to be water resistant in the event water does enter the housing.

The present invention relates to a track switching apparatus for rail trolleys. It comprises at least one linear track, a curved track connected to the at least one linear track, at least one switching region formed at a connection region of the linear track and the curved track, and at least one switching unit disposed in the at least one switching region.

A railroad switch circuit controller assembly includes a switch frame configured to be mounted to a stock rail, and a switch controller held by the switch frame. The switch controller includes at least one switching mechanism. The switch controller includes a point detection rod operatively connected to the at least one switching mechanism. The point detection rod extends a length from a proximate end portion to a distal end portion. The proximate end portion of the point detection rod is located closer to the stock rail as compared to the distal end portion when the switch frame is mounted to the stock rail. The railroad switch circuit controller assembly also includes a switch foot configured to be mounted to a switch rail, and an external rod operatively connected between the switch foot and the point detection rod of the switch controller such that the external rod is configured to translate linear movement of the switch foot toward and away from the stock rail to the point detection rod. The external rod is connected to the proximate end portion of the point detection rod.

A switch device for moving switch rails. The switch device includes a motor operatively coupled to move the switch rails into and between first and second positions. The motor is configured for electricity to flow therethrough along a first path and a second path. A first path relay has two normally open contacts each within the first path, where activating the first path relay closes the two normally open contacts thereof. A second path relay has two normally open contacts each within the second path, where activating the second path relay closes the two normally open contacts thereof. The motor moves the switch rails towards the first position when the first path relay is activated and the second path relay is deactivated, and the motor moves the switch rails towards the second position when the second path relay is activated and the first path relay is deactivated.

A track switch that comprises track rails of basic (2), (3), straight, (4), (5) and lateral (6), (7) directions fastened on a slab track (1); sliding switch rails (8), (9) and point rails (10), (11) that are rigidly fastened to the slab track (1) by means of mounting means (12). The point rails and switch rails form points. The track switch comprises also a shift mechanism with a drive (14) and an axis (15), whereto sliding locks (16), (17) are connected. The point rails (10), (11) and the switch rails (8), (9) are connected with each other by means of units. Each of the units is a guide (18) that is rigidly fastened to the point rail, a wedge (19) that is rigidly fastened to the switch rail (8), (9), a cleat wedge (20) placed in the guides that is capable of moving longitudinally and fastened with its both ends to point rods (21) of the wedge (see FIGS. 1 and 4). The sliding wedges (20) are connected to each other by means of point rods (21), the last of the point rods being connected with the axis of the shift mechanism that is capable of rotating or moving longitudinally, and is set into motion by a shift drive mechanism. The sliding switch rails (8), (9) are connected to each other by means of spacing rods (22).