The present disclosure generally relates to railroad track equipment and more particularly, relates to a derailer of such railroad equipment.
In the normal operation of railroad, it is often necessary to move a car, locomotive, or entire train from one track to another. If the train is to continue on, this is typically performed using a turnout that enables the train to be moved from one line to the other. however, sometimes in emergency situations it is necessary to derail the train or car off the track to prevent fouling of the mainline or other protected track, in order to prevent significant damage. Examples of such situations include when a train or unattended car is approaching a raised drawbridge, intersections with other rail lines or roadways, or when train crews are working, dead ends, and the like.
With such locations, a double point derail switch is purposely provided to for its ability to derail a train or unattended car. As the name implies, the switch derails the train to prevent entry to foul a main or protected track . A standard double point derail switch uses a normally closed switch for train traffic to continue unaltered on a mainline track. When derailing is required, the switch is opened the same as it would be if it was required to divert a train to another track and the train or car is routed onto a short truncated section and thus derailed so as to protect fouling a mainline or other protected track . However, because one switch point, when closed, sits above the main track, a train passing the double point derail switch experiences a bump and some crosslevel condition when traversing the switch. Further, because the switch is in the path of mainline train traffic during normal use, the switch requires routine maintenance even though it may never be activated for use as a derailer.
U.S. Pat. No. 463,727 (the '727 patent) issued Nov. 24, 1891 describes a switch which lifts a train car wheel over the active track. However, the way the switch rail in the '727 patent is constructed is impractical to produce and too costly to deploy.
In accordance with one aspect of the disclosure, a derailer for use with railroad tracks includes an outside switch rail, an outside switch point mechanically fastened to the outside switch rail. The outside switch point selectively overlays a running surface of a first mainline rail and rises above the running surface of the first mainline rail. The derailer also includes an inside switch rail including a second switch point that selectively lies adjacent a head of a second mainline track and terminates between the first and second mainline rails.
In another aspect of the disclosure, a derailer includes an outside switch rail moveably mounted adjacent to a field side of a first mainline rail, the outside switch rail having a point end and a distal end and an outside switch point fixedly attached to the point end of the outside switch rail. The outside switch point includes a shelf having a flat bottom surface configured to rest on a running surface of the first mainline rail, a tapered upper surface that rises above the running surface of the first mainline rail, and a mounting bracket extending down from a side of the shelf. The mounting bracket is affixed to the outside switch rail. The derailer further includes an inside switch rail moveably mounted adjacent to a gage side of a second main rail. The derailer is configured, when activated, to lift via the shelf, a flange of a railcar wheel above and over the running surface of the first mainline rail.
In yet another aspect of the disclosure, a method of operating a derailer includes fastening an outside switch point to an outside switch rail, the outside switch rail mounted adjacent to a field side of a first mainline rail, the outside switch rail having a point end and a distal end. The outside switch point is fastened at the point end. The outside switch rail has a height above the running surface greater than a flange height of a railroad wheel. The method also includes moving the outside switch point over a running surface of the first mainline rail and coincident with moving the outside switch point over the running surface of the first mainline rail, setting a point of an inside switch rail against a gage side of a second mainline rail. The inside switch rail maintains an operating gage with the outside switch rail. The inside switch rail terminates between the first and second mainline rails approximately coequal with the distal end of the outside switch rail.
These and other aspects and features will be more readily understood when reading the following detailed description and taken in conjunction with the accompanying drawings.
Referring now to the drawings, and with specific reference to
The derailer 100 may be used to move a railroad car (not depicted) off a railroad track 101. However, in a significant departure from the prior art the derailer 100 of the present disclosure is deployed in a normally open position, thereby avoiding the raised configuration and bumps associated with normally closed prior art derailers. More specifically, an outside switch rail 104 includes an outside switch point 102. A point end 106 of the outside switch rail 104 includes a web portion without a head (shown in more detail in
An inside switch rail 112 is mounted adjacent to a second mainline rail 115. The inside switch rail 112 includes a point end 113 and a distal end 114 opposite the point end 113. The distal end 114 may also include a downward curving arc similar to that of the outside switch rail distal end 107. In other embodiments, the distal end may simply end or may have a cut or ground slope. For the purpose of the following discussion, a gage side 116 of either mainline rail 108 or 115 is the side facing the other mainline rail. A field side 118 of the first mainline rail 108 is the side of the first mainline rail 108 facing away from the second mainline rail 115. The outside switch rail 104 is so designated because it is outside the gage limits of the track structure. Either or both of the switch rails 104, 112 may be a continuous rail or may have a joint at a heel block (not depicted). When derailing is desired, a head rod 120 and a back rod 122 are used pull the derailer 100 from the open position shown in
Turning to
As illustrated in
A view of the derailer 100 corresponding to the “C” reference line of
A perspective view of the first mainline rail 108 and the outside switch rail 104 is shown in
In general, the present disclosure may find applicability in rail industries and may be used in mainline track or other track requiring protection from the undesired further movement of the train or unattended rail car.
A flowchart 200 for deploying a derailer 100 and derailing a train in accordance with the current disclosure are illustrated in
Continuing at block 204, the outside switch rail 104, including the outside switch point 102 may be disposed on a field side 118 of the first mainline rail 108. The outside switch rail 104 may be attached in a conventional manner to one or more rods 120, 122 that are used to move the outside switch rail 104 from an idle, or inactive position, to an operating, or active, position and back. The outside switch rail 104 has a height 160 above the first mainline rail 108 that is greater than a flange height 158 of a railroad wheel 152.
When derailing a train is desired as determined at decision block 205, the outside switch rail 104 is moved so that the outside switch point is positioned above the running surface 131 of the first mainline rail 108 as shown at block 206. As mentioned above, such purposed derailing may be desired when a train is approaching protected track, another line, construction, or the like, where further movement of the train along the line will cause damage of other assets. However, if derailing is not desired, nothing needs to be done as the derailer 100 is deployed in a normally open configuration as represented by a block 207.
The movement of an inside switch rail 112 and its associated point end 113 is represented at block 208. The inside switch rail 112, when activated by the head and back rods 120, 122, is moved into position on a gage side 116 of a second mainline rail 115. The point end 113 causes the wheel 150 to divert against the inside switch rail 112 in a conventional manner.
Both the inside switch rail 112 and the outside switch rail 104 are limited in length. When a car reaches the distal ends 107, 114 of the switch rails 104 and 112, the car will fall off the rails. In an embodiment, the inside switch rail 112 may be longer than the outside switch rail 104 so that the inside wheel 152 will spill onto the ground first and cause the car to tip toward the outside switch rail 104, away from the first mainline rail 108.
Among other things, the ability to provide a derailer that does not require a switch to be placed in the main line track provides several benefits. Among them, the elimination of a full-time activated derailer switch also eliminates the track bump associated with a closed switch and the related mechanical shock to cars as they pass over the old-style derailer. In addition, the old style derailer, because it is subjected to constant main line traffic, requires frequent maintenance to keep it in working order and maintain the required one fourth inch rise above the main line track. A derailer 100 in accordance with the current disclosure on the other hand has no contact with the main line rails during normal operation, eliminating the bump associated with the prior art derailer. Also because the derailer 100 of the current disclosure is not constantly subjected to train loads, the routine maintenance required to keep the derailer 100 in working order is also reduced. The use of an outside switch point 102 to attach to the point end 106 of the outside switch rail 104 reduces the complexity of the castings required and makes the implementation of the derailer 100 practical and cost effective compared to the prior art switch.