Patent Grant
6935245
Like passenger cars, semi-trucks, i.e., highway tractors for pulling semi-trailers, typically require shipping from their places of manufacture to their destinations, e.g. distribution centers or dealers. Passenger automobiles are typically shipped long distances utilizing specially-designed railcars or auto racks, as discussed below. Passenger cars also are shipped on highway trailers. Because of their large size, semi-trucks are difficult to transport. Many semi-trucks can be too large and heavy to transport cost-effectively on highway trailers. The problem of transporting semi-trucks has become particularly acute as production of some trucks for U.S. customers has shifted to Mexico, increasing the distances between the place of manufacture and the place of delivery.
Semi-trucks are typically transported on highways or other roadways in a piggy back manner, wherein one mule truck pulls two or three piggy back trucks. In a typical piggy back arrangement, the front end of a first piggy back truck rests on the rear end of the mule truck. The front ends of the second and third piggy back trucks rest on the rear ends of the first and second piggy back trucks, respectively. Dollies may be used to connect the first piggy back truck to the mule truck and to interconnect the piggy back trucks.
In order to transport semi-trucks in this manner, the semi-trucks must be arranged within dimensional constraints required by federal, state, and/or local regulatory agencies. For example, the total maximum allowable length from bumper to bumper for a mule pulling piggy back trucks is usually 75 feet on designated truck routes and 55 feet on other routes. The length constraints usually limit the maximum number of semi-trucks that can be transported in a piggy back arrangement to three or four, including the mule truck. Transporting semi-trucks in this way can be labor intensive, in that a driver is required for each mule truck.
The maximum allowable height of the mule with piggy back trucks is usually 13.5 feet on designated truck routes. In order to avoid exceeding the maximum allowable clearance height, the piggy back trucks may require partial disassembly for transportation. For example, the exhaust stacks and front wheels are often removed. Drive shafts may also be removed. Axles of piggy back trucks may need to be chained to prevent unwanted rotation during transportation. These steps can be time consuming and costly. For trucks having tall cabs, disassembly may be very difficult if not impossible.
Transporting the trucks in a piggy back manner is also disadvantageous because the trucks are exposed to the elements and may arrive at the place of delivery coated in dust or dirt, or even with cracked windshields and scratched or otherwise marred finishes. Damaged trucks may then require restoration to their original condition once delivered, which can involve time-consuming and costly cleaning and/or repairing. In addition, trucks transported in a piggy back manner may be exposed to vandalism and theft.
In an alternative that has been used in the past, some semi-trucks have been shipped on flat cars, such as 90 foot long flat cars. Shipping trucks on flat cars can be undesirable because the flat cars do not have structures enclosing the semi-trucks, thus leaving the trucks exposed to the elements, potential damage, and/or vandalism.
Auto rack cars have proven to be useful in transporting automobiles from the place of manufacture to distribution centers or dealers. Transporting passenger automobiles in enclosed auto rack railway cars can help reduce transportation costs because large quantities of vehicles can be shipped. Auto rack cars, such as disclosed in U.S. Pat. Nos. 5,765,486, 5,782,187, and 5,657,698, typically have a first deck on the floor of the railway car and one or more elevated decks. Auto rack cars also are typically enclosed to prevent vandalism and theft and to deliver the automobiles in good condition. However, semi-trucks will not fit on typical auto rack cars because the vertical clearances between the decks are not sufficient, and the horizontal clearances of the interior may also be insufficient. Auto racks are typically designed with low internal clearances for passenger automobiles that will not accommodate semi-trucks.
The elevated decks may not simply be removed from the interior of an auto rack car in order to adapt them for carrying semi-trucks. The elevated decks in an auto rack car typically are structural members. Without an elevated deck to provide support, sidewalls of an auto rack car may tend to rack or skew sideways. In addition, the end doors of typical auto rack railway cars are usually placed in close proximity to the end of the railway car in order to maximize the number of automobiles that may be transported. When radial end doors are moved into their open positions, they typically are partially recessed against the sidewalls of the auto rack car while remaining within required external clearances. This can require reduced horizontal clearances at ends of the auto rack car, i.e. a narrower opening to the railcar interior. The reduced horizontal clearances are undesirable for transporting semi-trucks, which are generally wider than passenger automobiles.
It has also been known to transport mobile homes, camper trailers, and other recreational vehicles and equipment on modified flat cars. One such flat car was produced in the past by Whitehead & Kales. The Whitehead & Kales car includes a roof and side panels. However, the side panels do not form a complete enclosure for the sides. In addition, the Whitehead & Kales car does not include end doors.
Thus, there remains a need for an improved railway car capable of carrying semi-trucks.
In accordance with the invention, an enclosed railway car is provided for transporting semi-trucks that provides for increased carrying capacity, reduces the amount of disassembly of the trucks required for transportation, and provides increased protection for the trucks from the elements, as well as from theft and vandalism.
To accommodate the increased widths of the semi-trucks as compared to passenger automobiles, the horizontal clearance of the openings at each end of the railway car is increased. Preferably, only the mirrors on the sides of the semi-trucks need to be adjusted to fit the trucks into the interior of the railway car. Sufficient vertical clearance may be provided so that semi-trucks of certain types may also be arranged in a piggy back manner in the interior of the railway car to increase the number of trucks that may be transported.
The railway car includes a floor having sufficient strength and durability for carrying semi-trucks in commercial rail service. Side posts extend vertically upward along each side of the floor to support upstanding sidewalls. The first side posts are preferably spaced between 4 and 5.5 feet from each end of the railway car. Intermediate side posts are spaced between the first side posts along each side of the railway car. The first side posts and the intermediate side posts on each side of the railway car may be aligned in a substantially coplanar arrangement.
End doors are preferably provided near each end of the railway car, substantially supported by the first side posts. The end doors are selectively operable between an open position for allowing access to the interior of the railway car and a closed position for restricting access to the interior of the railway car. The end doors are pivotally attached to the railway car with hinges proximate the sidewalls of the railway car such that the end doors are substantially aligned with the sidewalls when in their open positions. When the end doors are in their open position, their outer edges, opposite the hinges, preferably do not extend beyond the end of the railway car. Loading and unloading of coupled railway cars is possible without requiring the railway cars to first be uncoupled.
Hinging the end doors proximate the sidewalls allows for an increased horizontal clearance between the first side posts compared to auto rack cars with radial end doors. It is typical in auto rack car radial end doors to have the pivot axes of the end doors spaced laterally inward from the sidewalls and ends of the railway car. The first side posts are also typically spaced laterally inward from the intermediate side posts to provide exterior recesses for the doors when in open positions. The positions of the first side posts reduce the horizontal clearance of the interior of the typical auto rack car. In the preferred embodiment of the invention, the end doors in their open positions are in or near the plane of the sidewalls and set back a sufficient distance, such as 4 to 5.5 feet, from the end of the railway car to prevent the edges of the end doors from extending past the end of the railway car.
According to an embodiment of the invention, the hinges of the railway car may include non-metallic bushings in order to reduce or eliminate the need for greasing or other maintenance of the hinges. The non-metallic bushing may be disposed between a hinge pin and one or more hinge sockets. The doors may be provided with extra reinforcements as compared to end doors on typical auto rack railway cars. The doors may also be provided with exterior lower recessed portions to reduce or avoid interference between the doors in their open position and railcar equipment that may extend above the upper surface of the floor, such as ladders or brake mechanisms.
The hinged end doors may be provided with mechanisms to help support the doors in both their open and closed positions. Due to the weight of the doors, it can be desirable to provide support for the doors in their open and closed positions in order to reduce loads on the sidewalls or side posts to which the doors are attached. The mechanisms may each comprise a roller wheel disposed on the bottom of the door proximate the end of the door opposite the hinge. Elevated supports may be attached to the floor of the railway car so that the roller wheel contacts a first support when in the closed position and a second support when in the open position. While the door is between its open and close positions, the roller wheel may remain out of contact with the floor and the supports. A wedge or riser member may be attached to the top of each support for ensuring that the roller rolls up onto the support.
Locking pins may be disposed proximate bottoms of the doors on surfaces thereof to lock the doors in their fully open or closed positions. The locking pins may be translatable from a retracted or unlocked position to an extended or locked position. The locking pins may be spring biased downwardly toward their extended positions.
A handle or other manual device may be provided on an outer surface of the door for moving the locking pins from a closed position to an open position. Upstanding tubular members can be provided on the floor of the railway car for receiving the locking pins when the doors are in either their open or closed positions. For example, one of the tubular members may be placed on the floor at the location where the locking pin will be when the door is in its closed position. Another tubular member can be placed on the floor at the location where the locking pin will be when the door is in its open position. An inclined ramp member may be placed before each tubular member in order to raise the locking pin to its retracted position so that it clears the top of the raised tubular member. Once the locking pin is in position over the raised tubular member, it can be driven downward by gravity and/or the spring force.
The upstanding sidewalls may be attached to the side posts along each side of the railway car. In an embodiment of the invention, ventilation in the sidewalls of the railway car may be provided by small diameter perforations at select locations, with remaining portions of the sidewalls being imperforate, thereby providing sufficient passive light and ventilation for the interior of the railway car, while substantially reducing admission of airborne particulates. The sidewalls may be load-bearing with structural components positioned to avoid protruding unnecessarily into the car interior. To this end, load bearing shear plates may be used as sidewalls of the railway car. Protection for the doors of semi-trucks carried in the railway car may be provided, e.g., by a plurality of door edge protection strips of a resilient material attached in parallel to one another and vertically spaced from one another along the inside of the sidewalls. The door edge protection strips may be positioned at a range of elevations to enable them to absorb impacts from doors of semi-trucks of various designs and heights.
A roof may be attached to the top of the sidewalls and side posts. The roof may be of a corrugated material having alternating grooves and ridges to provide additional strength to the roof. In an embodiment of the invention, the roof comprises corrugated, galvanized steel.
In order to provide rigidity and structural support to the upstanding sidewalls of the railway car, supports or brackets may extend between opposing sidewalls. Typical auto rack railway cars have one or more intermediate decks for transporting passenger automobiles. These intermediate decks often provide structural support for the upstanding sidewalls and prevent racking of the sidewalls. Semi-trucks require large vertical clearances and weigh much more than typical passenger automobiles, rendering intermediate decks on railway cars impractical. The addition of supports between the posts and roof of the railway car of the invention can help prevent racking of the sidewalls of the railway car and help maintain the sidewalls of the railway car in their upright positions.
Support for the sidewalls of the railway car may be provided by cross members that connect some or all of corresponding pairs of the side posts at their upper ends. The cross members may be rigidly attached to be constrained against angular displacement relative to their associated side posts, so as to provide added support to the side posts to prevent racking of the attached sidewalls. The cross members may be of a contour generally similar to the profile of the roof, with each cross member having side portions extending upward and inward, and a horizontal central portion. The side portions of the cross members may have channel portions for fitting around the upper ends of the side posts. Bolts may be used to attach the cross members at their channel portions to the side posts. The contour of the cross members can be optimized to minimize their intrusion into the interior of the railway car, retaining sufficient vertical clearance between the floor and the cross members. The cross members may be aligned so that they are at least partially recessed in the grooves of the corrugated roof to retain sufficient vertical clearance between the floor and the cross members.
The railway car may comprise an articulated railway car with two car units pivotally connected to each other and sharing a single truck assembly at their connection. An articulated railway car may be configured to transport two semi-trucks loaded end-to-end in each unit of the railway car. Three semi-trucks may be transported in each unit if arranged in a piggy back manner. Railroad industry and government regulations restrict the total length of railway cars in proportion to their widths in order to ensure they can safely navigate typical curves on railway track lines. Accordingly, a longer railway car is usually required to be of a narrower width than a shorter railway car. Providing a railway car in an articulated form having shorter car units allows for each unit to have an increased width, advantageous for transporting wide semi-trucks.
A flexible enclosure may be provided to enclose the space between car units in the articulated railway car. The enclosure may be made of a flexible, resilient elastomeric material or the like, and may have internal reinforcement provided by wires or by other reinforcing material to provide resistance to cutting for improved security. Supports may be provided along the height of the flexible enclosures to help keep them in a preferred alignment.
The railway car may have a plurality of bridge plates spanning the pair of car units at their connection. The bridge plates can allow rolling transport of vehicles between the pivotally interconnected car units for rolling loading and unloading of vehicles. In an embodiment of the invention, the bridge plates may be formed of Metton or other suitable polymers and reinforced with steel wires or strips to provide additional strength in order to reduce deflection of the bridge plates as heavy semi-trucks are driven thereover.
The railway car may also include a pair of bridge plates pivotably mounted on the floor proximate each end thereof, extendable between coupled railway cars. When extended, these bridge plates allow semi-trucks to be driven thereover from one railway car to the next. The extended bridge plates can allow for a train of coupled railway cars to be loaded and unloaded from just one end, greatly simplifying loading and unloading by eliminating the need to uncouple each car separately for loading and unloading.
Semi-trucks often have a pair of front wheels spaced a first distance apart and a pair of rear wheels spaced a second distance apart. To provide for chocking of the wheels of a truck, the floor of the railway car may be provided a first pair of parallel chock tracks substantially aligned with the front wheels of the truck. The floor of the railway car may also include a second pair of parallel chock tracks substantially aligned with the rear wheels of the truck. In a preferred embodiment, the chock tracks are attached to the upper surface of the floor and extend upwards therefrom. However, the chock tracks may also be provided recessed in the floor such that the tracks are flush with the upper surface of the floor.
Additional features and advantages of the invention are disclosed in the detailed description of the preferred embodiments and in the accompanying drawings.
A railway car 1 comprising two substantially identical railway car units 10 connected at an articulation 8 is shown in the embodiments illustrated in
A bracket assembly 110 is provided at the ends of each railway car unit 10 to constrain the sidewalls 18 so that racking of the sidewalls 18 remains within acceptable limits. The bracket assemblies 110 are connected to the interior of the roofs 12 proximate the ends of each railway car unit 10 and extend laterally across the railway car 1. As illustrated in
In the embodiments illustrated in
The end doors 30 of each unit 10 of the railway car 1 are attached proximate the first side posts 22 and are operable between open and closed positions, as illustrated in FIG. 3. When the end doors 30 are in their open positions, access is provided to the interior of the railway car 1. The horizontal clearance between the end doors in their open position is between 9.5 and 10 feet. By having the first side posts 22 spaced inwardly from the ends of the railway car 1, when the end doors 30 are in their open positions they do not extend beyond the end of the railway car 1. In the illustrated embodiment, the doors 30 in open position do not extend beyond the striker. However, in other embodiments the doors 30 may be configured to extend beyond the striker when open. In either case, the doors 30, when open, preferably do not interfere with open doors on an adjacent car, and preferably are pivoted about axes spaced a sufficient distance inward of the striker to achieve sufficient clearance for the cars to be moved with the doors 30 open, while complying with applicable safety standards.
In the illustrated embodiment, the doors 30 are of a generally rigid configuration, i.e., they do not fold or bend significantly, and are preferably of a flat configuration, as distinguished from radial doors. As shown in
The end doors 30 are pivotally attached to the railway car 1 with hinges 40 comprising intermeshing male and female hinge members 46 and 48, as illustrated in
Locking mechanisms 70 are used to secure the end doors 30 in their closed positions and restrict access to the interior of the railway car 1. According to the embodiment of the railway car illustrated in
Attached to the floor 14 of the railway car 1 are pin tubes 64 for receiving the locking pins 76. The tubes 64 are disposed on the floor 14 at locations where the pins 76 extend downward when the doors 30 are in either their open and closed positions. When the extended pins 76 are received in the tubes 64, the doors 30 are prevented from moving between their open and closed positions. Pin tubes 64 are also disposed to receive the locking pins 76 located at the tops of the doors 30 when the doors 30 are in their closed positions. In the embodiment illustrated in
A handle assembly 80 located on each door 30 is operable to move the locking pins 76 of the door 30 from their locked to their unlocked positions. The handle assembly 80 comprises a handle 84 rotatably mounted to the door. Rotation of the handle 84 from a locked position to an unlocked position translates the pins 76 to their retracted positions via cables 82 extending between the pins 76 and the handle 84. The cables 82 are slidable attached to the interior of the door 80 with cable guides 88 mounted to the door 30.
Due to the weight of the doors 30, door supports 50 are provided to maintain the doors 30 at a generally predetermined elevation relative to the floor 12 of the railway car 1 when the doors 30 are in either their open or closed positions. The supports 50 each comprise a roller bracket 58 mounted to the bottom of the door 30 opposite the hinges 40. Rotatably received within the bracket 58 is a roller 56 that at least partially protrudes beyond the bottom edge of the door 30. The roller 56 engages raised blocks 52 attached to and extending upwardly from the floor 12. The raised blocks 52 are positioned to be aligned with the roller 56 when the doors 30 are in either their open or closed positions. A wedge plate 54 is placed on top of each raised block 52 to ensure that the blocks 52 adequately support the rollers 56 and thus the doors 30.
To secure the semi-trucks 5 relative to the railway car 1, a plurality of parallel chocking tracks 120 extend longitudinally on the floor 12 of the railway car. The chocking tracks 120 are adapted for receiving chocking blocks for securing the wheels of the semi-trucks 5. Semi-trucks 5 often may have front wheels aligned with an inner set of back wheels. The trucks 5 may also include an outer set of back wheels that are not aligned with the front wheels. To accommodate chocking of both the front wheels and the outer back wheels of the trucks, an inner and outer set of chock tracks 124 and 122 are provided on each side of the railway car 1.
A plurality of articulation bridge plates 90 are provided over the articulation 8 between the units 10 of the railway car 1. The articulation bridge plates 90 are mounted to allow each unit 10 of the railway car 1 to respectively pivot about the central truck 15, while still providing a support surface over which semi-trucks 5 can be rolled between units 10 of the railway car 1. The articulation bridge plates 90 are mounted to the floor 14 of the car units 10 in alignment with the chocking tracks 120, as illustrated in FIG. 9. The articulation bridge plates 90 are of sufficient strength to allow semi-trucks 5 to be driven thereover, allowing the trucks 5 to be loaded at one end of one of the units 10 and driven through the unit 10, over the articulation bridge plates 90, and into the other unit 10. In the embodiment illustrated in
Also disposed on the floor 14 at ends of the units 10 opposite the articulation 8 are end bridge plates 140 for extending between coupled railway cars 1. The end bridge plates 140 are pivotable between bridging and storage positions, as illustrated in FIG. 9. When in their bridging positions, each end bridge plate 140 extends between coupled railway cars to allow semi-trucks to be driven thereover. The bridge plates end 140 allow semi-trucks to be loaded onto a plurality of coupled railway car 1 by driving through a first railway car 1 and over the end bridge plates 140 to a next railway car. This loading operation may be repeated to allow a train comprising multiple coupled railway cars 1 to be loaded with semi-trucks 5 without having to uncouple each railway car 1 for separate unloading.
To load semi-trucks 5 on the railway car 1 for transportation, the end doors 30 of at least one of the railway car units 10 are both unlocked and moved to their open positions. The semi-trucks 5 may then be rolled or driven over the floor 12 of the railway car and over the bridge plate 90 to cross the articulation 80. Two semi-trucks 5 are placed end-to-end in each unit 10 of the railway car 1, according to the embodiment of the invention as illustrated in FIG. 2. After loading of the semi-trucks 5, the doors 30 are returned to their closed positions, whereby the door lock mechanisms 70 secure the end doors 30 in their closed position. To unload the railway car 1, the end doors 30 of at least one of the railway car units 10 are opened and the semi-trucks 5 are rolled or driven from the interior of the railway car 1.
From the foregoing it should be appreciated that the invention provides a novel and improved railway car for carrying semi-trucks. While preferred embodiments of the invention are described above, the invention is not limited to the preferred embodiments. For example, the invention may be embodied in a non-articulated car consisting of a single railway car unit. The invention is further described and more particularly pointed out in the following claims:
This application claims the benefit of provisional application No. 60/234,592, filed Sep. 22, 2000. The invention relates generally to railway cars, and more particularly to a railway car for transporting semi-trucks.
| Number | Name | Date | Kind |
|---|---|---|---|
| 1254920 | Mathias | Jan 1918 | A |
| 2016430 | Hice | Oct 1935 | A |
| 2761581 | Cohee | Sep 1956 | A |
| 3611949 | Peisner | Oct 1971 | A |
| 3995563 | Blunden | Dec 1976 | A |
| 4077330 | Peisner et al. | Mar 1978 | A |
| 4120076 | Lebre | Oct 1978 | A |
| 4263751 | Bennett et al. | Apr 1981 | A |
| 4697526 | Vigliani | Oct 1987 | A |
| 4751883 | Bealer | Jun 1988 | A |
| 4834608 | Middaugh et al. | May 1989 | A |
| 4854790 | Andre | Aug 1989 | A |
| 4867071 | Weber | Sep 1989 | A |
| 4917021 | Murphy | Apr 1990 | A |
| 5032044 | Dorst | Jul 1991 | A |
| 5312213 | Winsor | May 1994 | A |
| 5320046 | Hesch | Jun 1994 | A |
| 5509175 | Baughan et al. | Apr 1996 | A |
| 5669745 | Anderson | Sep 1997 | A |
| 5743192 | Saxton et al. | Apr 1998 | A |
| 5765486 | Black, Jr. et al. | Jun 1998 | A |
| 5794537 | Zaerr et al. | Aug 1998 | A |
| 5845584 | Bullock et al. | Dec 1998 | A |
| 6142082 | Burke et al. | Nov 2000 | A |
| 6227512 | Andre et al. | May 2001 | B1 |
| 6283040 | Lewin | Sep 2001 | B1 |
| 6289822 | Black et al. | Sep 2001 | B1 |
| Number | Date | Country | |
|---|---|---|---|
| 20020035948 A1 | Mar 2002 | US |
| Number | Date | Country | |
|---|---|---|---|
| 60234592 | Sep 2000 | US |
