The invention is directed to a cushioning apparatus for a railway car, and more particularly to a selective travel apparatus that absorbs draft and buff loads applied to a coupler of a railway car.
As is generally known, railway cars are connected to an adjacent car by a coupler. The coupler is joined to a yoke, for example an “E-type” or “F-type” yoke, by a draft key or pin, and the assembly is mounted in a railway car center sill.
To prevent damage to the railway cars and the laded goods during operation, and especially during assembly of the railway car train in the yard, various devices have been installed to absorb loads on the coupler so that impact forces are not transmitted to the railway car.
In a conventional frictional draft gear, one or more elastic elements, such as a coil spring or a set of elastomeric pads, is enclosed in a housing mounted in the yoke behind the coupler. A piston-like element frictionally received in the housing absorbs buff loads transmitted via a coupler follower which moves inside the yoke in response to buff impact force applied on the coupler, and the draft gear is compressed in the yoke in response to draft loads. The basic draft gear apparatus has been used for decades. However, in many cases unacceptably large forces are transmitted to the railway car.
A hydraulic cushioning unit comprises a piston received in a cylinder filled with fluid. Such devices may dissipate more force than a conventional draft gear, but they are known to be prone to leakage.
U.S. Pat. No. 2,766,894 describes a selective travel draft gear with separate cushioning elements for buff and draft loads on the coupler. In this design, both of the cushioning elements are located forward of the back wall of the yoke.
U.S. Pat. No. 2,825,472 describes a selective travel draft gear which comprises separate cushioning elements for buff and draft loads on the coupler, but both stacks of cushioning elements are attached to the yoke.
U.S. Pat. No. 6,446,820 discloses a selective travel draft gear of more recent vintage where the separate draft and buff cushioning elements are coupled and adapted to fit into the draft gear pocket. These apparatuses have not been very well received, and may be prone to buckling, wherein a stack of elastomeric elements is pushed out of alignment and fails to operate according to specifications.
All of the above-referenced U.S. Patents are incorporated by reference.
In view of the prior art, one object of the invention is to provide an alternative cushioning device that provides cushioning over a range of impact speeds.
Another object of the invention is to provide a cushioning apparatus for a railway car that provides cushioning for both draft and buff loads applied to the coupler, limiting force transmitted to the railway car over a range of impact speeds, such as may be encountered during train build, where impact speeds may be in the neighborhood of 4-14 mph or higher, and during start-up and stopping. Embodiments according to the invention may exhibit low displacement per unit of force applied over a range of relevant force levels.
Yet another object of the invention is to provide improved alignment and positioning of elastomeric pads in a cushioning device, to prevent over-compression, permanent deformation, and buckling during use.
Yet another object of the invention is to provide a cushioning apparatus that absorbs both draft and buff loads in a compact format, more easily installed in a standard pocket such as for an AAR standard EOC-9 or EOC-10 configuration.
These and other objects of the invention are met in one aspect with an end-of-car cushioning device for a railway car, comprising: a yoke having aligned apertures at a front end adapted to receive a pin or key for attaching the yoke to a railway car coupler, and having a vertical wall at a second end of the yoke opposite the front end; a coupler-receiving member adapted to receive buff force from the coupler and adapted to move inside the yoke; a first stack of elastomeric units positioned between the coupler-receiving member and the vertical wall of the yoke, said first stack being compressed by draft and buff loads on the coupler; a front buff plate positioned adjacent to and rearward of the yoke and connected to a rear buff plate by a center rod; a second stack of elastomeric units positioned between the front buff plate and the rear buff plate, said second stack being compressed in response to buff loads on the coupler; wherein, the yoke, the front buff plate and the rear buff plate are positioned within a center sill of the railway car; and wherein, the yoke is not mechanically attached to the front buff plate or the rear buff plate.
In another aspect, the invention resides in the arrangement of the plurality of elastomeric units, each comprising a plate and an elastomeric pad positioned in the middle of the plate. A first set of the plates is arranged in a rear or “buff” stack and the plates are each sized to fill the sill area to ensure alignment of the elastomeric pads. A second set of plates is arranged in a front or “draft” stack, sized to fit inside a yoke. The edges of the plates extending around the elastomeric pads are configured so that the plates can nest with each other, and at full compression the edges of the plates contact one another to prevent overcompression of the individual elastomeric pads.
The subject matter regarded as the invention is particularly pointed out and distinctly claimed in the concluding portion of the specification. The invention, however, both as to organization and method of operation, together with objects, features, and advantages thereof, may best be understood by reference to the following detailed description when read with the accompanying drawings in which:
The drawings are not to scale, and features not necessary for an understanding of the invention are not shown.
Directions and orientations herein refer to the normal orientation of a railway car in use. Thus, unless the context dearly requires otherwise, the “front” of a coupler is in a direction away from the body of the car and “rear” is in a direction toward the center of the car. Likewise, the “longitudinal” axis or direction is parallel to the rails and in the direction of movement of the railway car on the track in either direction. The “transverse” or “lateral” axis or direction is in a horizontal plane perpendicular to the longitudinal axis and the rail. The term “inboard” means toward the center of the car, and may mean inboard in a longitudinal direction, a lateral direction, or both. Similarly, “outboard” means away from the center of the car. “Vertical” is the up-and-down direction, and “horizontal” is a plane parallel to the rails including the transverse and longitudinal axes.
“Elastomer” and “elastomeric” refer to polymeric materials having elastic properties so that they exert a restoring force when compressed. Examples of such materials include, without limitation, thermoplastic elastomer (TPE), natural and synthetic rubbers such as: neoprene, isoprene, butadiene, styrene-butadiene rubber (SBR), polyurethanes, and derivatives.
As used herein, the term “about” associated with a numerical value is understood to encompass a margin of +/−10% of the value. An object is said to “substantially fill” a space (such as a railway car sill) when just enough space is provided to allow the object to move in the space without interference. This may mean a clearance of up to about ¼ inch laterally and up to about ¾ inch vertically.
In embodiments, a cushioning device according to the invention is adapted to fit into an Association of American Railroads (“AAR”) standard pocket. The dimensions of a standard pocket and permitted tolerances may be set by the AAR. from time to time, and reference herein to AAR standards refers to standards in the AAR Manual of Standards and Recommended Practices in effect at the filing date of this application, including performance standards, such as M-921-B, for hydraulic cushioning units. A person having ordinary skill in the art has a general knowledge of AAR standards and the published AAR standards cited herein are incorporated by reference as background.
In embodiments, cushioning device assembly 10 may be characterized by a pocket length of about 38¾ inches described in AAR standard S-183 for an “EOC-9” pocket, or a pocket length of about 48¾ inches described in AAR standard S-184 for an “EOC-10” pocket. In other embodiments, the cushioning device may be adapted to fit other pocket dimensions.
In
In
For ease of understanding the invention, a single elastomeric unit 25 is shown in
Referring again to
The elastomeric pads 27 may be provided with a through hole in the center, which aligns with a protrusion, which may be cast, stamped or fabricated on the plate, for example, and provided to keep the pads in alignment. The diameter of the through hole may be referred to as the “inner diameter”. The lateral edge of each elastomeric pad 27 may be curved in a toroidal manner, and the outside diameter of the pad is measured at the middle of the thickness dimension of the pad.
Pads 37 in the buff stack 16 may have the same general shape as pads 27 in the draft stack 17 but they are scaled larger. The maximum design force of the larger pads 37 is higher due to larger surface area, but the surface pressure on each pad is the same. For example, and not by way of limitation, the uncompressed thickness of a pad 37 may be about 1.70 inches and the outer diameter may be about 8.82. Compressed for installation with a force of about 32 klb, the installed thickness of the pads is about 1.24 inches. Under full compression, with metal-to-metal contact of plates 226 preventing further compression of pads 37, the pad thickness may be about 0.91 inches and the outside diameter may reach 10.63 inches. Thus, in embodiments, the pads and plates are designed to allow compression of 20-80 percent, and in embodiments 40-60 percent, where the amount that the pad is compressed at full compression is expressed as a percentage of the uncompressed thickness of the pad, prior to installation. Bolt head 33 is flush mounted in front plate 31 so that the rear unit 30 may be mounted directly against front unit 20. In embodiments, rear unit 30 is not attached to the front unit 20, which facilitates installation. As shown in
The same elastomeric material may be used for the elastomeric pads in the draft stack as in the buff stack, such as a thermoplastic elastomer.
The elastomeric units of the draft pack are adapted to slide between straps 26 of yoke 20. In an E-type arrangement, the yoke is attached to the coupler using a draft key, but the performance considerations for the pads and plates are similar.
In embodiments, draft stack 17 is provided in a pre-shortened installation configuration, which allows draft portion 20 and the buff portion 30 to slide into the pocket and allows the coupler to be installed without interference. A plurality of shear pins, for example four shear pins pass through the yoke into the coupler follower 22. The pins break on first impact, and in this fully-installed or post-installation position, the coupler is pre-stressed, applying buff force against the first and second stacks.
The description of the foregoing preferred embodiments is not to be considered as limiting the invention, which is defined according to the appended claims. The person of ordinary skill in the art, relying on the foregoing disclosure, may practice variants of the embodiments described without departing from the scope of the invention claimed. A feature or dependent claim limitation described in connection with one embodiment or independent claim may be adapted for use with another embodiment or independent claim, without departing from the scope of the invention.