Conventional freight railroad cars in North America and other parts of the world typically include a car body and two spaced apart trucks. The car body or car body under frame typically includes two spaced apart center plates that respectively rest on and are rotatably received by bolster bowls of the two trucks. The trucks rollingly support the car body along railroad tracks or rails. Each truck typically has a three piece truck configuration that includes two spaced apart parallel side frames and a bolster. The side frames generally extend in the same direction as the tracks or rails, and the bolster generally extends transversely or laterally to the tracks or rails. The bolster extends laterally through and between and is supported by the two spaced apart side frames. Each side frame typically defines a center opening and pedestal jaw openings on each side of the center opening. Each end of each bolster is typically supported by a spring group positioned in the center opening of the side frame and supported by the lower portion of the side frame that defines the center opening.
Each truck also typically includes two axles that support the side frames, four wheels, and four roller bearing assemblies respectively mounted on the ends of the axles. The truck further typically includes four bearing adapters respectively positioned on each roller bearing assembly in the respective pedestal jaw opening below the downwardly facing wall of the side frame that defines the top of the pedestal jaw opening. The wheel sets of the truck are thus received in bearing adapters placed in leading and trailing pedestal jaws in the side frames, so that axles of the wheel sets are generally parallel. The bearing adapters permit relatively slight angular displacement of the axles. The spring sets or groups permit the bolster to move somewhat with respect to the side frame, about longitudinal or horizontal, vertical, and transverse axes (and combinations thereof).
Directions and orientations herein refer to the normal orientation of a railroad car in use. Thus, unless the context clearly requires otherwise, the “longitudinal” axis or direction is substantially parallel to straight tracks or rails and in the direction of movement of the railroad car on the track or rails in either direction. The “transverse” or “lateral” axis or direction is in a horizontal direction substantially perpendicular to the longitudinal axis and the straight tracks or rails. “Vertical” is the up-and-down direction, and “horizontal” is a plane parallel to the tracks or rails including the transverse and longitudinal axes. The “leading” side of the truck means the first side of a truck of a railroad car to encounter a turn; and the “trailing” side is opposite the leading side.
There is a continuing demand in the railroad industry to improve bolsters and side frames, and to reduce potential stress fractures or cracks in bolsters and side frames.
Various embodiments of the present disclosure provide a new railroad car truck, and more particularly a new railroad car truck including a new bolster that includes one or more of a plurality of different improvements that individually and in various combinations reduce, inhibit, and/or minimize the likelihood of stress fractures or cracks in the bolster.
Various embodiments of the present disclosure also provide a new railroad car, and more particularly a new railroad car having a new railroad car truck including a new bolster that includes one or more of a plurality of different improvements that individually and in various combinations reduce the overall weight of the bolster and thus the railroad car truck and the railroad car. Such reduced weight increases fuel efficiency.
In various embodiments, the present disclosure provides an improved casted bolster for a freight railroad car truck configured to be employed in a freight railroad car truck and that includes one or more of a plurality of improvements that in combination reduce, inhibit, and/or minimize the likelihood of stress fractures or cracks in the bolster, and thus reduce maintenance expense and time out of service. These improvements also provide for an overall lighter bolster and truck making the freight railroad car more efficient. In various embodiments, the improved bolster generally includes: (a) a first end; (b) a first diagonal member connected to the first end via a transitional concave first turn of spring seat; (c) a center rib assembly connected to the first end, to the straight first diagonal member, and to the first turn of spring seat and comprising: (i) a first center rib; (ii) a second center rib connected to the first center rib via a first U transition; and (iii) a third center rib connected to the first and second center ribs via the first U transition; (d) a first diagonal rib connected to the first turn of spring seat adjacent the third center rib; (e) a second diagonal rib connected to the first turn of spring seat adjacent the third center rib, the third center rib being between the first and second diagonal ribs; and (f) a bottom member connected to the first diagonal member and having thickened walls (or beadings) that respectively form the brake rod holes. The improved bolster generally also includes: (a) a second end; (b) a second diagonal member connected to the second end via a transitional concave second turn of spring seat; (c) a second center rib assembly connected to the second end, to the straight second diagonal member, and to the second turn of spring seat and comprising a fourth center rib connected to the first and second center ribs via a second U transition; (d) a third diagonal rib connected to the second turn of spring seat adjacent the fourth center rib; and (e) a fourth diagonal rib connected to the second turn of spring seat adjacent the fourth center rib, the fourth center rib being between the third and fourth diagonal ribs.
In various embodiments, the present disclosure provides a railroad car truck including a first side frame, a second side frame, and this improved bolster supported by the first frame and the second frame. In various embodiments, the present disclosure provides a railroad car including one or more such railroad car trucks.
Other objects, features, and advantages of the present disclosure will be apparent from the following detailed disclosure, taken in conjunction with the accompanying sheets of drawings, wherein like reference numerals refer to like parts.
Various embodiments of the present disclosure provide a new bolster for a railroad car truck and a new railroad car truck having the new holster, and a new railroad car having at least one new truck with the new bolster. It should be appreciated that the bolster of the present disclosure can be used in connection with any suitable transportation device (such as freight railroad cars).
Referring now to the drawings,
More specifically, in this illustrated example embodiment, the first truck 14 (as shown in
In this illustrated example embodiment, the bolster 100 is configured to be partly positioned in the first side frame 104 and in the second side frame 112, and is resiliently supported by the first side frame 104 and by the second side frame 112 via the springs 118 and 119 in a conventional manner.
In this illustrated example embodiment, when the first truck 14 is assembled, the bolster bowl wear liner 122 is positioned in the bowl of the bolster 100. The first truck 14 and the second truck 16 are rotatably engaged with the car body 12 (as generally shown in
In operation of this illustrated example embodiment, the first side frame 104 and the second side frame 112 extend generally longitudinally in the same direction as the tracks 20 of
As shown in more detail in
The illustrated example embodiment of the bolster 100 of the present disclosure includes the following combination of four specific sets of improvements including: (a) the first end 300 transitioning to the first diagonal member 500 via a concave first turn of spring seat 520 and the second end 350 transitioning to the second diagonal member 550 via a concave second turn of spring seat 570; (b) the center rib assembly 600 having a first center rib 602 and a second center rib 624 that transition into a third center rib 644 via a first U transition 658; (c) the bottom member 400 having thickened walls (or beadings) 412A and 412B that respectively form the brake rod holes 410A and 410B; and (d) the first diagonal rib 686 and the second diagonal rib 688 connecting the top member 200 to the first end 300, to the first turn of spring seat 520, and to the first diagonal member 500. The combination of these improvements substantially reduce, inhibit, and/or minimize potential stress fractures in the bolster 100 by adding supporting specific structures to the bolster 100 and/or by removing stress-concentrating areas to enable the loads to be distributed more evenly across the entire bolster.
More specifically, the top member 200 is integrally connected to the first end 300, the second end 350, the bottom member 400, the first diagonal member 500, the second diagonal member 550, the center rib assembly 600, the first diagonal rib 686, the second diagonal rib 688, the third diagonal rib, and the fourth diagonal rib.
The top member 200 includes a center plate bearing surface 202, a center plate rim 204, and side bearing pads 208 (as shown in
The first end 300 of the bolster 100 includes a first spring seat 310, a first column set 330, and a first bolster pocket 340 (as shown in
The first spring seat 310 and the second spring seat 360 include spring seat lugs 312. The spring seat lugs 312 are generally circular. The first spring seat 310 and the second spring seat 360 are configured to engage the springs 118 of
The first column set 330 and the second column set 380 of the bolster 100 include outer column guides 332 and inner column guides 334. The first column set 330 and the second column set 380 are configured to engage column wear plates (not shown).
The first bolster pocket 340 and the second bolster pocket 390 of the bolster 100 include bolster pocket sloped surfaces 342, bolster pocket side walls 344, bolster pocket wear plates 346, and lands 348. The bolster pocket wear plates 346 are connected to the bolster pocket sloped surfaces 342 (as shown in
The first diagonal member 500 is connected to the first end 300 via the first turn of spring seat 520. The first diagonal member 500 is connected to the bottom member 400 via the first transition curve 510. The first diagonal member 500 is substantially straight. In other words, the first diagonal member 500 in this illustrated example embodiment has no curves, inflection, or turns between the first turn of spring seat 520 and the first transition curve 510 (as shown in
Similarly, the second diagonal member 550 is connected to the second end 350 via the second turn of spring seat 570. The second diagonal member 550 is connected to the bottom member 400 via the second transition curve 560. The second diagonal member 550 is substantially straight. The second turn of spring seat 570 is a singular concave curve with no convex and/or re-curve features in this illustrated example embodiment. Thus, a single angle is formed between the second diagonal member 550 and the second end 350 in this example embodiment. This configuration reduces, inhibits, and/or minimizes stress by more evenly distributing stress in the second turn of spring seat 570 because the first turn of spring seat 570 is a single larger concave arc connecting the straight second diagonal member 550 with the second end 350.
The first diagonal member 500 and the second diagonal member 550 each define side wall lightener holes 502 (as shown in
The center rib assembly 600 is disposed inside the bolster 100. As shown in
The center rib assembly 600 includes the first center rib 602, the second center rib 624, the third center rib 644, and the first U transition 658 (as best shown in
The first center rib 602 includes: a first center rib lightening hole set 604, a first mating side 608, a first taper region 612, a first thick region 614, a first thin region 616, a first outer face 618, and a first inner face 622 (as best shown in
The third center rib 644 includes a first neck region 646, a second neck region 648, and a third taper region 656 (as best shown in
The first U transition 658 includes a first curved shoulder 662, a second curved shoulder 672, and an inner curve 682 (as shown in
The first center rib 602 transitions into the third center rib 644 via the first curved shoulder 662. Similarly, the second center rib 624 transitions into the third center rib 644 via the second curved shoulder 672. Further, the first center rib 602 and the second center rib 624 transition into one another via the first curved shoulder 662 and the second curved shoulder 672. The first center rib 602 and the second center rib 624 are substantially parallel (as shown in
The first inner face 622 transitions into the second inner face 642 via the inner curve 682 (as shown in
The bottom member 400 includes two thickened walls (or beadings) 412A and 412B that respectively form the brake rod holes 410A and 410B (as shown in
The first diagonal rib 686 and the second diagonal rib 688 are disposed inside the bolster 100. The first diagonal rib 686 and the second diagonal rib 688 are connected to the first end 300, the first turn of spring seat 520, the first diagonal member 500, and the top member 200 (as shown in
It should be appreciated that the example embodiment of the bolster 100 illustrated in the Figures employs one example configuration of components and one example size and shape of each of the components. It should be appreciated that other embodiments of the bolster may employ different configurations of the components and/or components of different sizes or shapes.
Referring now to
Like the illustrated example bolster 100, this example bolster 1100 generally includes: (a) a top member 1200; (b) a first end 1300; (c) a second end 1350; (d) a bottom member 1400; (e) a first diagonal member 1500; (f) a second diagonal member 1550; (g) a first transition curve 1510; (h) a second transition curve 1560; (i) a first turn of spring seat 1520; (j) a second turn of spring seat 1570; (k) a center rib assembly (not shown or labeled); (l) a first diagonal rib (not shown or labeled); and (m) a second diagonal rib (not shown or labeled). The example bolster 1100 further includes a third diagonal rib (not shown) and a fourth diagonal rib (not shown). Thus, this illustrated example embodiment includes all of the advantageous features of the example bolster 100 described above.
This illustrated example bolster 1100 further includes: (a) a first vertical or substantially vertical rib 1900 positioned adjacent to (such as approximately ⅜ inches outside of) the first interior brake rod hole or opening 1410A; and (b) a second vertical or substantially vertical rib 1950 positioned within adjacent to (such as approximately ⅜ inches outside of) the second interior brake rod hole or opening 1410B. In this illustrated example, (a) the first vertical or substantially vertical rib 1900 is integrally connected to and extends downwardly from the top member 1200; and (b) the second vertical or substantially vertical rib 1950 is integrally connected to and extends downwardly from the top member 1200.
More specifically, during center bowl rock loading, substantial weight of the car can be concentrated on or at one of the edges of the center bowl. This causes stress at the points of the bolster below such edges. By positioning the vertical ribs 1900 and 1950 respectively adjacent to the respective interior windows, these concentrated loading areas are better supported. This provides additional stress relief to the surfaces or walls that define the interior brake rod holes or openings 1410A and 1410B that can be prone to stress cracking.
It should be understood that the top member 1200, the first end 1300, the second end 1350, the bottom member 1400, the first diagonal member 1500, the second diagonal member 1550, the center rib assembly, the first diagonal rib, the second diagonal rib, the third diagonal rib, the fourth diagonal rib, the first rib 1900, and the second rib 1900 are monolithically formed together and integrally connected to one another during a suitable casting process in this illustrated example embodiment. Thus, the bolster 1100 is a single, integral, unitary structure in this illustrated example embodiment.
It should further be appreciated that this illustrated example embodiment of the bolster 1100 of the present disclosure thus includes the following combination of five specific sets of improvements including: (a) the first end 1300 transitioning to the first diagonal member 1500 via a concave first turn of spring seat 1520 and the second end 1350 transitioning to the second diagonal member 1550 via a concave second turn of spring seat 1570; (b) the center rib assembly 1600 having a first center rib and a second center rib that transition into a third center rib via a first U transition; (c) the bottom member 1400 including thickened walls 1412A and 1412B that respectively define the outer brake rod holes (not labeled); (d) the first diagonal rib and the second diagonal rib 1688 connecting the top member 1200 to the first end 1300, to the first turn of spring seat 1520, and to the first diagonal member 1500; and (e) the first rib 1900 and the second rib 1900. The combination of these improvements substantially reduce, inhibit and/or minimize potential stress fractures in the bolster 1100 by adding supporting specific structures to the bolster 1100 and/or by removing stress-concentrating areas to enable the loads to be distributed more evenly across the entire bolster.
It should also be appreciated from the above description, that each of the stress reducing features on their own reduce the amount of stress placed in certain critical areas on the bolster. In combination, the benefits are further increased. These combinations provide a new bolster configuration that enables the bolster to pass the new testing requirements to be imposed by the Association of American Railroads. Combinations of these components also enable an overall lighter weight bolster, lighter weight castings to enhance production, and lighter castings to enable the railroad cars to become more efficient.
It should also be appreciated that the present disclosure contemplates that any two or more of the five sets of stress reducing features can be employed together in a bolster without incorporating one or more of the other stress reducing features in various alternative embodiments of the present disclosure.
It should further be appreciated that the present disclosure contemplates that any one of the five sets of stress reducing features can be individually employed in a bolster without incorporating one or more of the other stress reducing features in various alternative embodiments of the present disclosure.
It should further be appreciated that the present disclosure provides an overall reduction in the weight of the bolster and thus the railroad car truck and the railroad car. Such reduced weight increases fuel efficiency.
It will be understood that modifications and variations may be effected without departing from the scope of the novel concepts of the present invention, and it is understood that this application is to be limited only by the scope of the claims.
This application claims priority to and the benefit of U.S. Provisional Patent Application No. 62/607,051, filed Dec. 18, 2017, the entire contents of which are incorporated herein by reference.
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Number | Date | Country | |
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Number | Date | Country | |
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62607051 | Dec 2017 | US |