An apparatus includes a panel, a fastener, and a cushion. The panel is coupled to a side of a railcar. The fastener engages the panel. A vertical position of the fastener on the panel is adjustable. The cushion is coupled to the fastener. The cushion extends from the side of the railcar towards an interior of the railcar and prevents the side of the railcar from contacting an object stored in the railcar.

A vehicle restraint system for an auto-rack railroad car which includes an active chock and an anchor chock configured to co-act to secure a vehicle in the auto-rack railroad car. In various embodiments, each chock has a chock body including a substantially diamond shaped elongated tube which includes four integrally connected elongated walls. In various embodiments, for each chock, various components of that chock extend substantially along longitudinal axis that lie in the same or substantially the same vertical plane as the apex and trough of the substantially diamond shaped elongated tube of the chock body. The active and anchor chocks: (a) have a lower height than known commercially available vehicle restraints; (b) have a smaller width than known commercially available vehicle restraints; (c) position the strap and the torque tube closer to the tire of the wheel than any known commercially available vehicle restraints; (d) take up a smaller area of each safe zone adjacent to the wheel than known commercially available vehicle restraints; (e) provide a greater strength to size ratio than known commercially available vehicle restraints; and (f) are easy to operate, install, and remove.

A method comprises removing a first deck of a plurality of decks and a second deck of the plurality of decks from an autorack. The method further comprises removing one or more of a plurality of posts of the autorack and coupling a cross-brace assembly to one or more of the plurality of posts, wherein the cross-brace assembly is coupled to the one or more of the plurality of posts at a location above an existing brace bay of the autorack. The method also comprises coupling the second deck of the plurality of decks to the autorack at a location above or below the cross-brace assembly.

A method comprises removing a first deck of a plurality of decks and a second deck of the plurality of decks from an autorack. The method further comprises removing one or more of a plurality of posts of the autorack and coupling a cross-brace assembly to one or more of the plurality of posts, wherein the cross-brace assembly is coupled to the one or more of the plurality of posts at a location above an existing brace bay of the autorack. The method also comprises coupling the second deck of the plurality of decks to the autorack at a location above or below the cross-brace assembly.

A system includes a railcar, a first deck, and a second deck. The second deck is positioned within the railcar above the first deck. The second deck includes a first portion, a second portion coupled to a first end of the first portion, and a third portion coupled to a second end of the first portion opposite the first end. The second and third portions can move towards a center of the first portion such that the first portion is positioned above or beneath the second and third portions.

A method of shipping automobiles, railcars for shipping automobiles, and methods of manufacturing railcars for shipping automobiles to enable more efficient shipping of automobiles by facilitating conversion of autorack cars between unilevel, bi-level and tri-level configurations, and/or by providing increased load factors.

A locking assembly includes an elongated guide tube configured to be coupled to a first component. The guide tube is elongated in a first direction from a first end to an opposite second end. The locking assembly also includes a first pin partially disposed in the guide tube and protruding from the first end of the guide tube. The first pin can be received in a first receiver. The locking assembly also includes a second pin partially disposed in the guide tube and protruding from the second end of the guide tube. This second pin can be received in a second receiver. The locking assembly also includes a handle removably coupled with the second pin. The handle can be grasped and moved to slide the second pin relative to the guide tube and the first pin along the first direction.

Methods and means for reconfiguring an aircraft assembly plant that receives fuselages or fuselage sections via a public railroad system. In cases where the aircraft assembly plant comprises a first assembly line for installing (i.e., stuffing) equipment inside fuselages or fuselage sections and a second assembly line for installing equipment on exteriors of internally equipped fuselages or fuselage sections, both assembly lines being housed in the same building, the facility can be reconfigured by moving at least one fuselage stuffing operation of the first assembly line to an auxiliary building which overlies a railroad track connected to the public railroad system. The moved fuselage stuffing operations will be performed inside the auxiliary building while each fuselage or fuselage section is supported in an upright position on a respective railroad flat car.

A method of shipping automobiles, railcars for shipping automobiles, and methods of manufacturing railcars for shipping automobiles to enable more efficient shipping of automobiles by facilitating conversion of autorack cars between unilevel, bi-level and tri-level configurations, and/or by providing increased load factors.

Method and apparatus are disclosed for autonomous vehicle sequential car loading and alignment. A vehicle comprising a wireless communication module and a processor. The processor determines whether the vehicle will fit inside a string of railcars based on capacity and dimension data received from the railcars. When the vehicle fits, the processor autonomously navigates the vehicle to a farthest available space on the string of railcars, and positions the vehicle within the space to satisfy spacing requirements.