Patent Grant
8893626
1. Field of the Invention
The invention relates to a railway car truck incorporating a novel interconnection between the wheel set and side frame.
2. Description of the Related Art
The conventional railway car truck in use in North America for several decades has been the three-piece truck, comprising a pair of parallel side frames connected by a transversely mounted bolster. The bolster is supported on the side frames by spring sets. The wheelsets of the truck are received in bearing adapters placed in leading and trailing pedestal jaws in the side frame, so that axles of the wheelsets are parallel. The bearing adapters permit slight angular adjustment of the axles. The railway car is mounted on the center plate of the bolster, which allows the truck to pivot with respect to the car. The spring sets permit the side frames to move somewhat with respect to the bolster, about the longitudinal, vertical, and transverse axes.
On straight track, a three piece truck with parallel side frames and parallel axles perpendicular to the side frames (i.e., a perfectly “square” truck) rolls without inducing lateral forces between the wheel flange and the rail. However, at high speeds, minor perturbations in the track or in the equipment can lead to a condition known as “hunting,” which describes an oscillating lateral movement of the wheelsets that causes the railcar to move side-to-side on the track. Hunting may be dangerous when the oscillations attain a resonant frequency. A number of causes are implicated in hunting, and a number of solutions have been proposed in the prior art to raise the “hunting threshold,” but the condition is generally thought to be improved by increasing the rigidity of the truck.
Curved track poses a different set of challenges for the standard three-piece truck. When a railway car truck encounters a turn, the distance traversed by the wheels on the outside of the curve is greater than the distance traversed by wheels on the inside of the curve, resulting in lateral and longitudinal forces between the wheel and the rail. These wheel forces cause the wheel set to turn in a direction opposing the turn. On trucks with insufficient rigidity this results in a condition variously known as “warping,” “parallelogramming” or “lozenging,” wherein the side frames remain parallel, but one side frame moves forward with respect to the other. The “lozenging” condition can cause increased wear on the track and equipment, increase rolling resistance, and if severe enough result in a derailment.
In order to provide the standard three-piece truck with the ability to negotiate turns, the truck is generally designed to allow a nonparallel condition of the axles during the turn, which is then recovered on straight track. This may be achieved by permitting relative movement of the bearing adapters within the pedestal jaws of the side frames.
For the purposes herein, a “bearing adapter” is a piece which fits in a pedestal jaw of a side frame. One side of the bearing adapter is curved for engagement with the roller bearing of the axle and the other side fits in the pedestal jaw. Typically, a thrust lug protrudes from the vertical side wall of the pedestal jaw, and mates with a slot on the bearing adapter to maintain the bearing adapter in place and provide limits on the range of relative movement between the bearing adapter and pedestal jaw.
In order to improve curving performance, it is known to interpose an elastomeric bearing member between the side frame and the tops of the bearing adapters. The elastomeric member permits the side frames to maintain a ninety degree relationship with the wheelsets on straight track, while on curved track allowing the wheelsets some freedom of movement to depart from a square relationship to respond to turning forces and accommodate the nonparallel condition of the axles. The elasticity of the member biases the truck to return to its square position. Various systems to securely attach elastomeric pads to the side frame pedestal jaw are described in the prior art, including U.S. Pat. No. 4,674,412, which also contains a description of the prior art related to elastomeric pads generally.
The prior art is also replete with systems for maintaining the bearing adapter securely in place in the pedestal jaw. U.S. Pat. No. 5,503,084, for example, describes a truck having a system for holding the bearing adapter in position within the pedestal jaw using tie rods running through a bore in the bearing adapter to prevent the bearing adapters from rotationally moving.
A further mechanism to permit a truck to negotiate a turn is known as a “steerable” truck, which is generally a truck that allows rotation of each wheelset about its vertical axis so that the wheelsets may take an out-of-square position with respect to a longitudinal axis of the truck. In a steerable truck, the wheelsets are joined by an arm which controls and maintains the relationship between the wheelsets. The arm is further connected to a body of the railroad car so that movement between the car body and the wheelsets is maintained in a fixed relationship. An exemplary steerable truck is disclosed in U.S. Pat. No. 3,789,770. The invention described herein may be used with steerable and non-steerable trucks.
None of the above-described prior art recognized the advantage of an interconnection providing increased stiffness in a longitudinal direction relative to a reduced spring rate laterally between the side frame and the bearing adapter to improve passive steering and reduce lozenging.
These and other objects of the invention may be achieved by various means, as described in connection with the following description of the preferred embodiments.
In one aspect, the invention is directed to a three-piece truck having an interconnection between the side frame and the bearing adapter that provides increased stiffness in a longitudinal direction relative to a reduced spring rate laterally while also providing a restoring force responsive to displacement in the longitudinal and lateral directions with minimal friction or equivalent damping.
The interconnection between the side frame and the bearing adapter provides a lateral spring constant no more than about 5,000 lb/in, preferably less than about 3,000 lb/in, and a longitudinal spring constant in a range of about 20,000 lb/in to about 40,000 lb/in, as well as a restoring force in response to an applied load, characterized by a static coefficient of friction between two sliding surfaces or equivalent damping of no more than 0.10, preferably less than 0.08.
In another aspect, the invention is a three-piece truck comprising an interconnection between the side frame and the bearing adapter providing relatively increased stiffness in a longitudinal direction and reduced spring rate laterally, and providing a restoring force between the bearing adapter and the side frame with minimal friction or equivalent damping, and further including a transom, as described in co-pending application Ser. No. 13/600,560, filed on even date herewith, and incorporated by reference in its entirety, which provides the desired rigidity to the truck longitudinally and laterally, and a softer spring rate vertically (compared to the prior art).
In another aspect, a railway car truck according to the invention comprises: first and second side frames each having a leading and trailing pedestal jaw, the side frames being in opposed relationship and parallel, and respective leading and trailing pedestal jaws on each side frame being aligned to receive transversely mounted leading and trailing wheelsets. Each wheelset is received in the pedestal jaws and comprises an axle, wheels, and roller bearings. Each pedestal jaw comprises leading and trailing side walls and a pedestal roof. A bearing adapter is received in each pedestal jaw between the roller bearing and the pedestal roof, having a curved bottom surface facing the roller bearing and a flat upper surface facing the pedestal roof. An interconnection between the bearing adapter and the side frame comprises one or more pre-biased members positioned longitudinally with respect to the side frame against the bearing adapter, providing a force between the side frame and the bearing adapter in a longitudinal direction.
In embodiments, the bearing adapter has slots on its leading and trailing sides mating with thrust lugs on the side walls of the pedestal jaw, and two pre-biased elastomeric members are provided on the pedestal side walls between the thrust lugs and the side frame. The elastomeric members provide opposing forces in the longitudinal direction, so that zero net force is exerted between the side frame and the bearing adapter on a stationary car.
The pre-biased member(s) serve to increase the spring rate between the side frame and the bearing adapter in the longitudinal direction. This is combined with a relatively reduced spring rate in the lateral direction. In embodiments, the low lateral spring rate may be achieved, for example, by providing (a) a non-elastic surface on the pedestal roof contacting the bearing adapter providing a static coefficient of friction or equivalent damping less than 0.1, preferably less than 0.08; (b) a non-elastic surface on the top of the bearing adapter contacting the pedestal roof providing a static coefficient of friction less than 0.1, preferably less than 0.08; or both (a) and (b).
Directions and orientations herein refer to the normal orientation of a railway car in use. Thus, unless the context clearly requires otherwise, 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. A truck is “square” when its wheels are aligned on parallel tracks and the axles are parallel to each other and perpendicular to the side frames. The “leading” side of the truck means the first side of a truck on a railway car to encounter a turn; and the “trailing” side is opposite the leading side.
“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, natural rubber, neoprene, isoprene, butadiene, styrene-butadiene rubber (SBR), and derivatives.
“Coefficient of friction” refers to a static coefficient of friction between two surfaces. Unless the context clearly requires otherwise, a “reduced coefficient of friction” means that the coefficient of friction is reduced as compared to steel-on-steel, which is the conventional interface between the pedestal roof and the bearing adapter. “Minimal friction” is defined as a static coefficient of friction between two sliding surfaces no greater than 0.10, preferably less than 0.08. By way of comparison, the static coefficient of friction between two sliding steel surfaces is 0.40 or greater.
“Equivalent damping” refers to the calculated energy dissipation per cycle of movement, for comparing different interconnections between the bearing adapter and side frame, whether the interconnection is by way of sliding surfaces, shearing or compression of elastomeric material, or other means.
“Interconnection” between the side frame and the bearing adapter refers to any member contacting and transmitting force between the side frame and the bearing adapter.
Where a railway car truck according to the invention includes a plurality of substantially identical elements, such as two side frames, two wheelsets, four wheels, etc., it is understood that a description of one element herein serves to describe all of them.
The Association of American Railroads (“AAR”) sets forth standards for railroad trucks in Standard M-976. Reference to M-976 and other AAR standards refers to the standards in effect on the filing date of this application.
The invention contemplates a variety of ways in which an interconnection may be provided between the wheelset and side frame to provide optimal and proportional spring forces to the wheelset bearing adapters. The interconnection controls relative longitudinal and lateral motion of the bearing adapters (and thereby also the wheelsets) with respect to the truck side frames to optimize steering and stability. Additionally, the interconnection provides a restoring force whereby a small movement results in a proportionally small restoring spring force with minimal friction or equivalent damping.
The elastomeric member(s) 24 may be made of neoprene rubber, such that inserting the elastomeric member into the slot between the bearing adapter and the thrust lug when the bearing adapter is installed compresses the member about ⅛ inch, resulting in a spring force in a range of about 500 lbs to about 1000 lbs, preferably about 750 lbs. In the embodiment shown, identical elastomeric members are similarly positioned in slots 41 on opposite longitudinal sides of the bearing adapter, so that the net force on the bearing adapter when the truck is not moving is zero. In preferred embodiments, the elastomeric members do not contact the lateral sides of the bearing adapter. In some instances, it may be desirable to provide elastomeric contact with the lateral side(s) of the bearing adapter, but still provide the interconnection with a lower lateral spring rate compared to the longitudinal spring rate.
According to the invention, an interconnection between the bearing adapter and side frame provides a lateral spring constant of no more than about 5000 lb/in, preferably less than about 3000 lb/in, while providing a longitudinal spring constant in a range of about 20,000 lb/in to about 40,000 lb/in, preferably in a range of about 25,000 lb/in to about 35,000 lb/in. The interconnection also provides a restoring force in response to an applied load, with minimal friction or equivalent damping. Preferably, the coefficient of friction between the side frame and the wheel set in response to an applied load, or the equivalent damping, is less than 0.1, or more preferably less than 0.08.
According to embodiments of the invention, the bearing adapter is engaged in the pedestal jaw with pre-biased elastomeric members, and a restoring force is provided in the longitudinal and lateral directions by the pre-biased members, with the lateral restoring force being much less than the longitudinal restoring force. For example, the force between the side frame and the bearing adapter results in a longitudinal spring rate between each bearing adapter and each side frame of about 25,000 lb/in to about 35,000 lb/in, and a lateral spring rate between the side frame and the bearing adapter is no more than 10 percent of the longitudinal spring rate.
In other embodiments, shown in
In another aspect of the invention, the tolerances of the truck design may be modified so as to improve performance when combined with the pre-biased thrust lug described herein, which includes modification of the pedestal itself. A conventional pedestal has a total longitudinal gap between the bearing adapter and thrust lugs of about 0.10 inches. The inventors have found that a gap of about 0.20 to 0.25 inches permits better passive steering of the wheel sets.
Conventionally, an elastomeric pad has been provided between the pedestal roof and the top surface of the bearing adapter. A conventional elastomeric pad allows a softer spring rate in both the lateral and longitudinal directions. According to the invention, a softer spring rate is provided between the bearing adapter and the side frame in the lateral direction compared to the spring rate in the longitudinal direction. “Spring rate,” in this context, refers to the amount of force needed to displace the bearing adapter a given distance relative to the side frame.
In embodiments, the truck does not include an elastomeric pad between the pedestal roof and the bearing adapter. However, it is possible to use an elastomeric pad at the pedestal roof interface in combination with the pre-biased thrust lug members and in some instances it may be desirable.
Referring again to
In a further embodiment, a modified wheelset to side frame interconnection as described above may be combined in a truck having a transom as described in U.S. application Ser. No. 13/600,560, filed on even date herewith and incorporated by reference. The overall rigidity of the truck provided by the transom combined with the increased ratio of longitudinal to lateral spring rate provided by the bearing adapter and pedestal jaw modifications leads to a synergistic improvement in hunting threshold, angle of attack, and other critical performance parameters.
The improved performance of a truck according to the invention compared to the prior art was evaluated using a computer model. A first truck was modeled according to the invention, incorporating elastomeric members on the leading and trailing sides of the bearing adapter and Teflon® surfaces on the roof of the pedestal and on the top surface of the bearing adapter, all as described above. Additionally, the truck was modeled having a transom. The elastomeric members were modeled to apply a force of 750 lbs in opposed longitudinal directions between the side frame and the bearing adapter. The elastomeric members did not have surfaces contacting the lateral sides of the bearing adapter. The first truck was modeled to have a coefficient of friction between the pedestal roof and the bearing adapter of 0.08. To reflect the comparative performance, a current approved truck meeting the M-976 standard, having an elastomeric pad positioned between the side frame and the bearing adapter was similarly modeled.
The results of the foregoing modeling are depicted in the graphic of
The upper line, with data points represented by a dashed line, represents a model of a current M-976 truck without a modified side frame bearing adapter interconnection according to the invention. The lower line, with data points represented by a solid line, represents data modeled on a truck according to the invention. The truck according to the invention exhibits significantly greater resistance to hunting and a higher hunting threshold, exhibiting lateral acceleration below the M-976 limit value well above the velocity required in the current standard.
One of ordinary skill in the art will recognize that other modeling may be used to obtain information about other performance criteria, and that such performance criteria may be impacted by other components of the truck. Different trucks, each meeting the M-976 standard, may have different components. Further, the above examples reflect the combined advantages of using both the modified bearing adapter configuration described herein and the transom described in co-pending application Ser. No. 13/600,560, filed on even date herewith, and both of these modifications affect performance. Moreover, computer modeling is no substitute for testing on actual track in real world conditions, and AAR specifications require the results of such testing to be gathered over thousands of miles before a truck is approved. However, the modeling described above is commonly used and relied upon as a directional indicator of truck performance. In particular, one of ordinary skill in the art would recognize the AOA data as reflecting improvements in the pedestal jaw/bearing adapter configuration.
The description of the foregoing preferred embodiments is not to be considered as limiting the invention, which is defined according to the appended claims.
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| Entry |
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| Number | Date | Country | |
|---|---|---|---|
| 20140060380 A1 | Mar 2014 | US |
