Freight accommodation on freight carrier – Particular article accommodation – Wheeled vehicle
Reexamination Certificate
2000-09-11
2003-04-22
Gordon, Stephen T. (Department: 3612)
Freight accommodation on freight carrier
Particular article accommodation
Wheeled vehicle
C410S004000, C410S024000, C105S004100, C105S355000, C105S378000, C105S458000
Reexamination Certificate
active
06551039
ABSTRACT:
FIELD OF THE INVENTION
This invention relates to the field of auto rack rail road cars for carrying motor vehicles.
BACKGROUND OF THE INVENTION
Auto rack rail road cars are used to transport automobiles. Most often, although not always, they are used to transport finished automobiles from a factory to a distribution center. A long standing concern has been the frequency of damage claims arising from high accelerations imposed on the lading during train operation. Many of these damage claims are related to slack action in the train. In this context, slack action includes (a) the free slack in the couplers; and (b) the travel of the draft gear of successive rail road cars under the varying buff and draft loads. Slack run-out occurs, for example, as a train climbs a long upgrade, and all of the slack is taken out of the couplings as the train stretches. Once the train clears the crest, and begins a relatively steep descent, the rail road cars at the end of the train may tend to accelerate downhill into the cars in front, closing up the slack. This slack run-in and run-out can result in significant longitudinal accelerations. These accelerations are transmitted to the automobiles carried in the auto-rack cars.
Historically, the need for slack was related, at least in part, to the difficulty of using a steam locomotive to “lift” (that is, move from a standing start) a long string of cars with journal bearings, particularly in cold weather. Steam engines were reciprocating piston engines whose output torque at the drive wheels varied as a function of crank angle. By contrast, presently operating diesel-electric locomotives are capable of producing high tractive effort from a standing start, without concern about crank angle or wheel angle. For practical purposes, presently available diesel-electric locomotives are capable of lifting a unit train of one type of cars having little or no slack.
Switching is another process having a long history. Two common types of switching are “flat switching” and “humping”. Humping involves running freight cars successively over a raised portion of track, and then allowing the car to run down-hill under gravity along various leads and sidings to couple with other cars as a train consist is assembled. For this type of operation the coupling speeds can be excessive, resulting in similarly excessive car body accelerations. For many types of rail road car, humping is now forbidden due to the probability of damaging the lading. An alternate form of switching is “flat switching” in which a locomotive is used to give a push to a rail road car, and then to send it rolling under its own inertia down a chosen siding to couple with another car. Particularly when done at night, the desirability of making sure that a good coupling is made tends to encourage rail yard personnel to make sure that the rail road cars are given an extra generous push. This often less than gentle habit tends to lead to rather high impact loads during coupling at impacts in the 5 m.p.h. (or higher) range. Forces can be particularly severe when there is an impact between a low density lading rail road car, such as an auto rack car, and a high density lading car (or string of cars) such as coal or grain cars.
Given this history, rail road car draft gear are designed to cope with slack run-out and slack run-in during train operation, and also to cope with the impact as cars are coupled together. Historically, common types of draft gear, such as that complying with, for example, AAR specification M-901-G, have been rated to withstand an impact at 5 m.p.h. (8 km/h) at a coupler force of 500,000 lbs. (roughly 2.2×10
6
N). Typically, these draft gear have a travel of 2¾ to 3¼ inches in buff before reaching the 500,000 lbs. load, and before “going solid”. The term “going solid” refers to the point at which the draft gear exhibits a steep increase in resistance to further displacement. If the impact is large enough to make the draft gear “go solid” then the force transmitted, and the corresponding acceleration imposed on the lading, increases sharply. While this may be acceptable for coal or grain, it is undesirably severe for more sensitive lading, such as automobiles or auto parts, paper, and other consumer goods such as household appliances.
Consequently, from the relatively early days of the automobile industry, there has been a history of development of longer travel draft gear to provide lading protection for relatively high value, low density lading, in particular automobiles and auto parts, but also farm machinery, or tractors, or highway trailers. Draft gear development has tended to be directed toward providing longer travel on impact to reduce the peak acceleration. In the development of sliding sills, and latterly, hydraulic end of car cushioning (EOCC) units, the same impact is accommodated over 10, 15, or 18 inches of travel. As a result, for example, by the end of the 1960's nearly all auto rack cars, and other types of special freight cars had EOCC units. Further, of the approximately 45,000 auto-rack cars in service in 1997, virtually all were equipped with end of car cushioning units. A discussion of the developments of couplers, draft gear and EOCC equipment is given the 1997 Car and Locomotive Cyclopedia (Simmons-Boardman Books, Inc., Omaha, 1997 ISBN 0-911382-20-8) at pp. 640-702. In summary, there has been a long development of long travel draft gear equipment to protect relatively fragile lading from end impact loads.
In light of the foregoing, it is counter-intuitive to employ short-travel, or ultra short travel, draft gear for carrying wheeled vehicles. However, by eliminating, or reducing, the accumulation of slack, the use of short travel buff gear may tend to reduce the relative longitudinal motion between adjacent rail road cars, and may tend to reduce the associated velocity differentials and accelerations between cars. The use of short travel, or ultra-short travel, buff gear also has the advantage of eliminating the need for relatively expensive, and relatively complicated EOCC units, and the fittings required to accommodate them. This may tend to permit savings both at the time of manufacture, and savings in maintenance during service.
Further, as noted above, given the availability of locomotives that develop continuous high torque from a standing start, it is possible to re-examine the issue of slack action from basic principles. The use of vehicle carrying rail road cars in unit trains that will not be subject to operation with other types of freight cars, that will not be subject to flat switching, and that may not be subject to switching at all when loaded, provides an opportunity to adopt a short travel, reduced slack coupling system throughout the train. The conventional approach has been to adopt end of car equipment with sufficient travel to cope with existing slack accumulation between cars. In doing so, the long travel end of car equipment has tended to add to the range of slack action in the train that is to be accommodated by the draft gear along the train. The opposite approach, as adopted herein, is to avoid a large accumulation of slack in the first place. If a large amount of slack is not allowed to build up along the train, then the need for long-travel draft gear and other end of car equipment is also reduced, or, preferably, eliminated.
One way to reduce slack action is to use fewer couplings. To that end, since articulated connectors are slackless, use of articulated rail road cars significantly reduces the slack action in the train. Some releasable couplings are still necessary, to permit the composition of a train to change, if desired. Further, it is necessary to be able to change out a car for repair or maintenance when required.
To reduce overall slack, it would be advantageous to adopt a reduced slack, or slackless, coupler, (as compared to AAR Type E). Although reduced slack AAR Type F couplers have been known since the 1950's, and slackless “tightlock” AAR Type H couplers became an adopted standard typ
Gordon Stephen T.
Grant Stephen L.
Hahn Loeser + Parks LLP
National Steel Car Limited
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