The present invention relates generally to railroad track systems for trains and, in particular, to transverse rail-spacing gauge-plate members of such railroad track systems.
In order to maintain a uniform spacing between parallel rails of railroad track systems, transverse rail-spacing gauge-plate members are fixedly mounted between the parallel rails. The rails have traditionally been made of a metal such as steel selected for strength, durability, and electrical conductivity, while the rail-spacing members have traditionally been made of a metal such as steel selected for strength and durability but not for electrical conductivity. In addition, railroad tracks are typically divided into sections (or blocks) and each section is electrified to provide for detecting the presence of a train on any given section of the track. The train-detection systems monitor the sections of the track to determine whether the metallic rails are isolated from each other (indicating that no train is present on those track sections) or whether they are short-circuited (by a train providing an electrical path between the rails to indicate that a train is present on that track section).
To electrically insulate the parallel rails from each other, inline pairs of the rail-spacing members are provided with their outer-positioned ends mounted to the rails, their inner-positioned ends spaced apart, and a gauge-plate insulator mounted to their spaced-apart inner ends to form an electrical-insulation gap while still mechanically interconnecting them. These gauge-plate insulators are electrically insulating, so they include non-metallic (non-conducting) materials. Known gauge-plate insulators include a metallic core and a polyurethane insulating encasement. Other gauge-plate insulators have been made of a laminated SCOTCHPLY material, a high-strength fiber-reinforced phenolic material (Minnesota Mining & Manufacturing Company, Saint Paul, Minn.), and require the use of a separate insulating plug between the ends of the gauge-plate insulator to prevent material build-up that can cause an electrical short-circuit. While these known designs of gauge-plate insulators have proven operationally sufficient, they tend to be costly due to the high-performance materials required and/or their multi-piece constructions.
Accordingly, it can be seen that there exists a need for a more cost-effective yet still durable and reliable way to mechanically interconnect but electrically insulate parallel rails of railroad tracks from each other. It is to the provision of solutions to this and other problems that the present invention is primarily directed.
Generally described, the present invention relates to gauge-plate insulators for use in insulating parallel rails from each other in railroad track systems. The gauge-plate insulators are each designed for positioning between and mounting to two rail-spacing members that in turn extend transversely between and mount to two parallel rails to mechanically interconnect but electrical insulate the rail-spacing members and thus the parallel rails. The insulator includes a plate, front and rear mounting holes extending vertically through the plate, and a tongue extending downward from the plate along its lateral midsection from front to back. In typical embodiments, the insulator includes elongated platforms surrounding the mounting holes and arranged perpendicular to the tongue, and the insulator is of a one-piece monolithic construction made of a material selected for mechanical strength and electric insulation. And in some embodiments the insulator includes a tented top surface, ribs extending perpendicular to the tongue, and/or multi-level platforms. In other embodiments, the gauge-plate insulator includes only some of these features, includes mounting elements other than mounting holes, includes additional features, and/or is otherwise adapted for the function and use described herein while still embodying the inventive aspects described herein.
The specific structures and techniques employed to improve over the drawbacks of the prior art and accomplish the advantages described herein will become apparent from the following detailed description of example embodiments and the appended drawings and claims.
The present invention relates to gauge-plate insulators for use in insulating parallel rails from each other in railroad track systems. The gauge-plate insulators are fixedly mounted between two rail-spacing gauge-plate members to separate (insulate) them electrically but not mechanically (structurally). And the rail-spacing members extend generally transversely to and are fixedly mounted between two parallel rails to maintain their uniform spacing during use. In typical commercial embodiments, the two rail-spacing members are elongated members made of metal, arranged inline with each other and transverse to the parallel rails, and having outer ends and inner ends, with each of the outer ends fixedly mounted to a respective one of the two parallel rails, with the inner ends spaced apart to form an electrical-insulating gap, and with a gauge-plate insulator mounted to the spaced-apart inner ends to maintain the electrical-insulation gap while mechanically interconnecting the gauge-plate members.
In other embodiments, the gauge-plate insulator is adapted for use with gauge-plate members with other forms, materials, and arrangements, including non-elongated and/or non-inline rail-spacing members. Thus, in one alternative embodiment, the two rail-spacing members are parallel but not aligned, with their inner ends overlapping, and with the gauge-plate insulator extending generally parallel to the rails and mounted between the rail-spacing members. In another alternative embodiment, one rail-spacing member extends transverse to the rails, is mechanically and electrically connected to a first one of the rails, and has an end that is spaced apart from a second one of the rails, with the gauge-plate member and the second rail spaced apart to form the electrical-insulating gap, and with the gauge-plate insulator mounted between the gauge-plate member end and the second rail. And in yet another alternative embodiment, more than two rail-spacing members extend between the rails and more than one gauge-plate insulator electrically separates but mechanically interconnects them. Accordingly, it will be understood that the present invention is not limited to the specific example embodiments disclosed herein.
Referring now to the drawings,
The plate 14 has a bottom surface 22 and a top surface 24. Typically, the bottom surface generally conforms to upper surfaces of the rail-spacing members 8 so that the opposing surfaces are generally flush with each other. In the depicted embodiment, for example, the plate bottom surface 22 is generally flat as are the upper surfaces of the rail-spacing members 8. Typically, the plate top surface 24 is tented when viewed from the front (see
In the depicted embodiment, the plate top surface 24 is tented with a gentle slope to form a triangular or double-wedge-shaped profile with a peak 27 when viewed from the front (see
In a typical commercial embodiment having a rectangular plate 14 with plan-view peripheral dimensions of about 7.5 inches by 8.0 inches (see
The pairs of mounting holes 16 and 18 extend generally vertically all the way through the plate 14. The front mounting-hole pair 16 is positioned on the front end section 21 of the plate 14 and the rear mounting-hole pair 18 is positioned on the end section 23 rear of the plate. Thus, the left-side holes of the front and rear mounting-hole pairs 16 and 18 are located in the left-side section 15 of the plate 14, while the right-side holes of the front and rear mounting-hole pairs are located in the right-side section 17 of the plate. In the depicted embodiment, the mounting holes 16 and 18 are generally circular and peripherally defined by the plate 14, though in other embodiments the mounting holes are formed by notches in the front and/or rear edges of the plate. In the depicted embodiment, the plate includes two front mounting holes 16 and two rear mounting holes 18, though in other embodiments there are more or fewer mounting holes, as long as there is at least one front mounting hole and at least one rear mounting hole. Thus, in some embodiments more than four mounting holes are provided.
Platforms 26 and 28 surround each of the mounting-holes pairs 16 and 18, respectively. Thus, the front platform 26 is elongated and surrounds both holes 16 of the front mounting-hole pair and the rear platform 28 is elongated and surrounds both holes 18 of the rear mounting-hole pair. This platform feature provides for increased twisting-torque and flex strength of the gauge-plate insulator 10 while minimizing weight and material usage.
The platforms 26 and 28 extend generally vertically upward from the top surface 24 of the plate 14. In the depicted embodiment, the platforms 26 and 28 have top surfaces 30 and 32, respectively, that are generally flat and thus are at a generally uniform distance from the generally flat bottom surface 22 of the plate 14. In other embodiments, the platform top surfaces 30 and 32 have ramped, curved, ribbed, or other shapes. The platforms 26 and 28 can have a generally elliptical plan shape (see
In embodiments with more or fewer than two front and/or rear mounting holes 16 and 18, the front and rear platforms 26 and 28 surround a corresponding number of mounting holes. For example, in an embodiment with one front and one rear mounting holes, the front and rear platforms each surround only one mounting hole. And in an embodiment with four front and four rear mounting holes, the front and rear platforms each surround four mounting holes. In addition, in some embodiments with multiple front and/or multiple rear mounting holes, each platform surrounds only one mounting hole, so there can be multiple front and/or rear platforms.
The mounting-hole pairs 16 and 18 align with corresponding mounting holes in the rail-spacing members 8 so that the aligned holes can receive fasteners to secure the gauge-plate insulator 10 to the rail-spacing members 8 (see
The tongue 20 extends generally vertically downward from the plate 14 along its lateral midsection 19, typically horizontally front-to-rear substantially all the way along the plate from the front section 21 to the rear section 23 (see
The tongue 20 has a horizontal thickness (at its thickest point), when viewed from the front (see
In typical embodiments such as those illustrated in the drawings (see
In this embodiment, however, the gauge-plate insulator 110 additionally includes one or more ribs 142 extending generally vertically upward from the top surface 124 of the plate 114. This ribbed-plate feature advantageously provides for increased twisting-torque and flex strength of the gauge-plate insulator 110 while minimizing weight and material usage. In the depicted embodiment, for example, the gauge-plate insulator 110 includes a front rib 142a, a rear rib 142b, and a center rib 142c (collectively, the ribs 142″). In other embodiments, fewer or more ribs 142 can be provided on the plate 114, for example, only the center rib can be provided. Unlike the first embodiment, the top surface 124 of the plate 114 is not tented and instead is for example generally flat, while in other embodiments including the ribs the plate top surface is tented (peaked).
The front and rear ribs 142a and 142b are positioned at the front and rear outer edges of the front and rear sections 121 and 123, respectively, of the plate 114 such that the plate top surface 124 is not exposed between the platforms 126 and 128 and the front and rear edges of the plate, respectively. That is, the front rib 142a and the front platform 126 form one continuous elevated front element, and the rear rib 142b and the rear platform 128 form one continuous elevated rear element (see
In this embodiment, however, the gauge-plate insulator 210 includes a different arrangement of ribs 242. In particular, the gauge-plate insulator 210 includes front and rear ribs 242a and 242b, but it does not include a center rib between the front and rear ribs 242a and 242b. Thus, the entire inter-end midsection 225 of the plate top surface 224 between the front and rear platforms 226 and 228 is exposed (see
In this embodiment, the gauge-plate insulator 310 includes the tented plate top surface 324 of the first embodiment (see
In the depicted embodiment, for example, the front upper platform levels 326a each individually surround a corresponding one of the two front mounting holes 316, but they do not extend laterally across the plate 314 between the two front mounting holes. Instead, the front lower platform level 326b extends laterally across the plate 314 between the two front upper platform levels 326a and thus between the two front mounting holes 316. Similarly, the rear upper platform levels 328a each individually surround a corresponding one of the two rear mounting holes 318, but they do not extend laterally across the plate 314 between the two rear mounting holes. Instead, the rear lower platform level 328b extends laterally across the plate 314 between the two rear upper platform levels 328a and thus between the two rear mounting holes 318. Thus, the top surfaces 330a and 332a of the upper platform levels 326a and 328a are positioned above the top surfaces 330b and 332b of the lower platform levels 326b and 328b. And the top surfaces 330b and 332b of the lower platform levels 326b and 328b are positioned above the top surface 324 of the plate 314 at least at the left-side section 315 and the right-side section 317 of the plate.
In embodiments with more than two front mounting holes, the same design concept can be applied such that each mounting hole has a dedicated upper platform level surrounding it and adjacent upper platform levels are connected by a lower platform level extending between them. The same design concept can be readily applied to embodiments having more than one rear mounting hole, as would be understood by a person of ordinary skill in the art.
Typically, the top surface 324 of the plate 314 is tented with its peak 327 extending generally parallel to the tongue 320 along the lateral midsection 319 (see
Having described several example embodiments of the invention, additional alternatives will now be addressed. In typical embodiments such as those illustrated in the drawings, only one of the gauge-plate insulators is installed inline between two rail-spacing members. In other embodiments the gauge-plate insulators have one-half-height tongues and two of them are stacked (in a tongue-to-tongue arrangement, within the bottom insulator inverted) and installed inline between and sandwiching two rail-spacing members. And in yet other embodiments two such gauge-plate insulators are integrally formed as a single piece having the shape of an “H” on its side.
Moreover, in typical embodiments such as those illustrated in the drawings, the insulators are installed between two rail-spacing members, though in other embodiments they can be adapted for use as switch-rod insulators and installed between two switch-rod members. In other embodiments, the insulators can be adapted for use as another type of railroad-track system insulator.
The dimensions shown in the drawing figures are in inches, are typical of example commercial embodiments, and provided for illustration purposes only. In other embodiments, the gauge-plate insulator is provided with different dimensions selected based on the particular size and shape of the body, the particular material used, the particular application (e.g., based on the speed and weight of the train, or the electric current and voltage of the detection system), and other such relevant design considerations. As such, the dimensions in the drawings are representative and not limiting of the invention.
The design of the gauge-plate insulator, as well as its manufacture and use, are innovative in the rail industry. Standard engineering practices for rail and track accessories are to fabricate parts from off-the-shelf materials, without using CAD or CAM technologies. Typically, stock materials are selected with dimensions nearest to what is desired. And even when new materials have been used to make gauge-plate insulators, conventional practice has still been to fabricate stock sheet/strip materials into end products. This leads to wasted materials and overly cumbersome parts that have to be manhandled into position, thereby requiring excessive quantities and qualities of physical labor.
On the other hand, the gauge-plate insulator is designed from the ground up to perform its structural/mechanical and electrical-insulation functions and at the same time to be quick and easy to install. The gauge-plate insulator was designed using CAD technology to withstand severe tensile stresses applied to it during use due to rail expansion, as well as severe tensile stresses applied to it during installation. For example, in some embodiments the design of the gauge-plate insulator is based on the maximum bending stress and the maximum tensile stress for the material used. Whereas conventional gauge-plate insulator designs are limited to the traditional T-shaped and flat profiles, the unique profile of the gauge-plate insulator maximizes the strength with a minimum of material used. The unique profile of the insulator was created and then refined through multiple trial circles using CAD technology and finite-element analysis. By going beyond traditional good engineering practices for this industry and using design and production methods that are non-standard for this industry, the innovative design of the gauge-plate insulator is unique, an advance beyond past designs, and beyond what normal and standard design procedures for this industry could have produced.
In another aspect of the invention, there is provided a method of manufacturing the gauge-plate insulator. The gauge-plate insulator can be made using conventional manufacturing techniques and equipment, such as for example compression molding of plastics. The manufacturing method includes providing a mold, filling the mold with the selected material (described above with respect to the first embodiment), and drying or curing the material into a rigid piece. Preferably, this is done using CAM technology. In addition, the method can include the step of compressing the material in the mold, before and/or during drying/curing it, using conventional compression-molding equipment and techniques, to provide a denser finished material with high flex modulus potential.
In addition, the step of filling the mold can include producing a unique internal flow pattern within the material placed into the mold. Composite materials are unique in that their strength varies from application to application. The normal procedure is to place the material in a mold in the easiest and fastest way that provides a complete part. Other known efforts in this area have placed reinforcement elements in a preset pattern (aligned along the part front-to-back, aligned across the part side-to-side, or arranged randomly) based on the profile of the fabricated part and the placement of the materials. In the present manufacturing method, however, the material is placed in a mold in such a way that the reinforcements flow and align to provide strength beyond what a normal part would have.
In use, the gauge-plate insulator mechanically connects the two metal rail-spacing members 8 (and thus the two parallel rails 6). Because of the structural design of the gauge-plate insulator, it withstands the mechanical stresses it is subjected to in its normal use, and because of its high electrical-insulating capability the two rail-spacing members 8 (and thus the two parallel rails 6) are electrically insulated from each other. In addition, because of its unique design features described herein, the gauge-plate insulator is failsafe electrically in the event it does somehow fracture. This is because for a failure of the insulator body in tension there is no internal metal core or other conductive material that could be exposed and thus across which the electricity could travel to short-circuit the track section, and the material the body is made of is strongest in compression and withstands any compressive load it could realistically experience under industry-standard design mechanical loads.
To install the gauge-plate insulator for use, it is positioned adjacent two spaced-apart rail-spacing members 8, with the tongue extending into the space between the rail-spacing members and with the left-side and right-side sections and holes positioned over the rail-spacing members and aligned with corresponding holes in the rail-spacing members. The fasteners 34 are then installed through the aligned holes in the plate and the rail-spacing members 8 to secure the gauge-plate insulator in place for use. In this way, the gauge-plate insulator mechanically couples the adjacent rail-spacing members 8 together but keeps them electrically insulated from each other, thereby mechanically interconnecting and electrically isolating the two parallel rails 8.
It is to be understood that this invention is not limited to the specific devices, methods, conditions, or parameters described and/or shown herein, and that the terminology used herein is for the purpose of describing particular embodiments by way of example only. Thus, the terminology is intended to be broadly construed and is not intended to be unnecessarily limiting of the claimed invention. For example, as used in the specification including the appended claims, the singular forms “a,” “an,” and “one” include the plural, the term “or” means “and/or,” and reference to a particular numerical value includes at least that particular value, unless the context clearly dictates otherwise. In addition, any methods described herein are not intended to be limited to the sequence of steps described but can be carried out in other sequences, unless expressly stated otherwise herein.
While the invention has been shown and described in exemplary forms, it will be apparent to those skilled in the art that many modifications, additions, and deletions can be made therein without departing from the spirit and scope of the invention as defined by the following claims.
This application is a continuation of U.S. Non-provisional patent application Ser. No. 13/783,735 filed Mar. 4, 2013, which claims the priority benefit of U.S. Provisional Patent Application No. 61/609,577 filed on Mar. 12, 2012, which is hereby incorporated herein by reference.
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Number | Date | Country | |
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20160097166 A1 | Apr 2016 | US |
Number | Date | Country | |
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61609577 | Mar 2012 | US |
Number | Date | Country | |
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Parent | 13783735 | Mar 2013 | US |
Child | 14966150 | US |