1. Field of the Invention
The present invention relates generally to railway monitoring apparatus and, more particularly to a coupling mechanism for coupling railway apparatus to a railway. The present invention also relates to detection and railway switching systems employing such coupling mechanism.
2. Description of the Prior Art
Numerous different types of railroad switching equipment are known and understood in the railroad arts. It is generally understood that a railroad switch apparatus is employed to switch a train from a first set of railroad tracks onto a second set of railroad tracks. Such a railroad switch apparatus typically includes a pair of movable rails, a switch machine for moving the rails, a detection device for detecting the position of the rails, and assorted connective hardware that extends between the movable rails, the switch machine, and the detection device for various purposes. The switch machine provides the forces necessary to move the movable rails between a first position and a second position and to lock the movable rails in the first and second positions. The detection device monitors the position of the movable rails.
It is also known that railroad equipment including railroad switch apparatuses are typically subjected to extreme punishment and distortions due to the substantial forces and vibrations transmitted from passing railroad trains, as well as severe environmental conditions including heat, snow, and ice which can greatly distort and wear components. Railroad equipment thus is preferably designed and configured generally to resist the effects of such harsh conditions, and to perform reliably under such conditions.
It is further known that railroad tracks and other related equipment extend across many remote regions, commonly referred to as “dark territory”, and that trains commonly travel on such remote tracks at all hours of the day and night. As such, railroad personnel must be available to inspect and, if necessary, repair railroad equipment at numerous remote locations at any hour. As the skill level of railroad maintenance personnel varies greatly, railroad equipment is preferably of a relatively simple configuration that can be repaired with a minimal number of tools in order to limit the number of potential points of failure of such railroad equipment and to facilitate repair by virtually any railroad personnel no matter the skill level or the quantity of tools available to such personnel.
In order to ensure the proper functioning of railroad switch apparatuses in all types of weather conditions and to resist breakage and maladjustment of such switch apparatuses, the connective hardware that extends between a switch machine and a pair of movable rails has typically included connecting rods that have been substantially rigidly connected with function rods that are part of the switch machine and that are movable with respect to other parts of the switch machine. While such rigid connections generally enhance the reliability of railroad switch apparatuses, such rigid connections nevertheless increase the difficulty and expense of installing and maintaining railroad equipment due to the degree of alignment that must be attained between the switch machine and the movable tracks.
During installation and replacement of conventional railroad switch apparatuses, special care is required to align the switch machine with the movable tracks in order to ensure that the connective hardware that is rigidly connected between the switch machine and the movable tracks is properly connected, and that such connective hardware operates properly without the components thereof or the movable tracks binding during operation. Commonly, such conventional switch machines are mounted a distance from the rails of the railroad, typically on the wooden ties to which the rails were mounted or on cement pads near the wooden ties, with the base of the switch machine needing to be aligned either flush with the lower surfaces of the tracks or at a given vertical distance from such lower surfaces. Such alignment typically is burdensome and costly to achieve during initial construction, and is particularly difficult and time consuming after repair or replacement of a switch machine due to the gradual deterioration of railroad ties and the difficulty of reliably employing such ties to align a switch machine with railroad tracks.
Accordingly, there is room for improvement in structures that facilitate installation of a switch machine and connection thereof with the movable tracks of a railroad switch apparatus while providing the necessary reliability and resistance to the effects of environmental conditions in which the switch apparatus is employed.
Embodiments of the present invention improve upon known designs by providing a mechanism for coupling a switch point to a point detector box, a detection system for detecting the position of a movable switch point of a railway, and a railway switching system.
In one example embodiment, a mechanism for coupling a switch point to a point detector box having a point detector bar is provided. The coupling mechanism comprises a first portion structured to be slidably coupled to the point detector bar and a second portion structured to be slidably coupled to the switch point.
The first portion may be structured to slide along a first axis and the second portion may be structured to slide along a second axis, the second axis being oriented generally perpendicular to the first axis.
The point detector bar may move relative to the point detector box generally along a third axis, the third axis being oriented generally perpendicular to the first axis.
The first and second portions may be portions of a generally cylindrical body disposed about a central longitudinal axis and the longitudinal axis may coincide with the first axis.
The first portion may comprise a generally smooth cylindrical shaft portion structured to slidably engage a generally spherical ball member disposed within a socket coupled to the point detector bar.
The second portion may comprise an engagement portion of a first diameter bounded by an adjacent portion having a greater diameter and wherein the second portion is structured to slidably engage an elongated aperture disposed on, in or coupled to the switch point.
The first portion may be disposed at or about a first end of a generally cylindrical body and the second portion may be disposed at or about a second end of the generally cylindrical body.
In another example embodiment, a detection system for detecting the position of a movable switch point of a railway is provided. The detection system comprises a point detector box having a point detector bar and a mechanism structured to couple the point detector bar to the movable switch point. The mechanism comprises a first portion slidably coupled to the point detector bar and a second portion structured to be slidably coupled to the movable switch point.
The first portion of the mechanism may be structured to slide along a first axis and the second portion of the mechanism may be structured to slide along a second axis, the second axis being oriented generally perpendicular to the first axis.
The point detector bar may move relative to the point detector box generally along a third axis and the third axis may be oriented generally perpendicular to the first axis.
The first and second portions of the mechanism may be portions of a generally cylindrical body disposed about a central longitudinal axis and the central longitudinal axis may coincide with the first axis.
The point detector bar may comprise a socket having a generally spherical ball member disposed therein and the first portion of the mechanism may comprise a generally smooth cylindrical shaft portion slidably coupled to the ball member.
The second portion of the mechanism may comprise an engagement portion of a first diameter bounded by an adjacent portion having a second diameter greater than the first diameter. The second portion of the mechanism may be structured to slidably engage an elongated aperture disposed on, in, or coupled to the switch point.
The first portion of the mechanism may be disposed at or about a first end of a generally cylindrical body and the second portion of the mechanism may be disposed at or about a second end of the generally cylindrical body.
In a further example embodiment, a railway switching system is provided. The railway switching system comprises a movable switch point and a detection system. The detection system comprises a point detector box having a point detector bar and a mechanism coupling the point detector bar of the point detector box to the movable switch point. The mechanism comprises a first portion slidably coupled to the point detector bar and a second portion slidably coupled to the movable switch point.
The first portion of the mechanism may be structured to slide along a first axis and the second portion of the mechanism may be structured to slide along a second axis, the second axis being oriented generally perpendicular to the first axis.
The point detector bar may move relative to the point detector box generally along a third axis and the third axis may be oriented generally perpendicular to the first axis.
The first and second portions of the mechanism may be portions of a generally cylindrical body disposed about a central longitudinal axis and the central longitudinal axis may coincide with the first axis.
The point detector bar may comprise a socket having a generally spherical ball member disposed therein and the first portion of the mechanism may comprise a generally smooth cylindrical shaft portion slidably coupled to ball member.
The second portion of the mechanism may comprise an engagement portion having a first diameter bounded by an adjacent portion having a second diameter greater than the first diameter and the second portion of the mechanism may slidably engage an elongated aperture disposed on, in, or coupled to the switch point.
A full understanding of the disclosed concept can be gained from the following description of the preferred embodiments when read in conjunction with the accompanying drawings in which:
As employed herein, the statement that two or more parts are “connected” or “coupled” together shall mean that the parts are joined together either directly or joined through one or more intermediate parts. Further, as employed herein, the statement that two or more parts are “attached” shall mean that the parts are joined together directly. Identical parts are provided with the same reference number in all figures.
As employed herein, the term “number” shall mean one or an integer greater than one (i.e., a plurality).
A railroad switch detection system 4 in accordance with the present invention is indicated generally in the plan view of
As shown in
The railroad switch detection system 4 includes a pair of movable rails 22 and 24 which are movable between a first position (
Point detector box 30 may comprise one or more sensor devices suitable for detecting the movement and or relative positioning of point detector bar 28, which is movably coupled to point detector box 30. As shown in
Having thus described the overall arrangement of railroad switch detection system 4 a detailed description of coupling mechanism 8 will now be provided in conjunction with
Second portion 40 of coupling mechanism 8 is structured to be slidably coupled to movable rail 22 such that second portion 40, and thus the entirety of coupling mechanism 8, is generally free to slide relative to movable rail 22 along axis 44, which is oriented generally perpendicular to axis 42, and thus conversely, movable rail 22 may freely move vertically with respect to coupling mechanism 8 (such as may commonly occur, for example, during passage of a train). In the example embodiment shown in
While specific embodiments of the disclosed concept have been described in detail, it will be appreciated by those skilled in the art that various modifications and alternatives to those details could be developed in light of the overall teachings of the disclosure. Accordingly, the particular arrangements disclosed are meant to be illustrative only and not limiting as to the scope of the disclosed concept which is to be given the full breadth of the claims appended and any and all equivalents thereof.
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Number | Date | Country | |
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20130264432 A1 | Oct 2013 | US |