The disclosed water barrier systems may include a first mobile water barrier, and adjacent second mobile water barrier, and a translation mechanism for translating the first mobile water barrier and the second mobile water barrier toward each other. Lowering mechanisms may be configured to lower sidewalls of the mobile water barriers. The mobile water barriers may include sealing elements to form water seals between the adjacent mobile water barriers and between the sidewalls and a surface. Related methods of forming a water barrier assembly are also disclosed.

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 cargo restraint panel may include a foam component. That foam component may have at least one polymer foam sheet. A front facing material may be bonded to and substantially cover a front face of the foam component. A rear facing material may be bonded to and substantially cover a rear face of the foam component. The cargo restraint panel may include one or more edge guards. Cargo may be secured in a railcar or other conveyance by, e.g., placing cargo restraint panels between cargo units.

A cargo restraint panel may include a foam component. That foam component may have at least one polymer foam sheet. A front facing material may be bonded to and substantially cover a front face of the foam component. A rear facing material may be bonded to and substantially cover a rear face of the foam component. The cargo restraint panel may include one or more edge guards. Cargo may be secured in a railcar or other conveyance by, e.g., placing cargo restraint panels between cargo units.

According to some embodiments, a railcar extension for extending the width of a railcar comprises: a top portion for attaching to a railcar support; a first side portion coupled to the top portion, the first side portion comprising two parallel transverse walls connected by a longitudinal wall all extending perpendicular from the top portion and the two transverse walls are for attaching to the railcar support; a second side portion coupled to the first side portion, the second side portion comprising two parallel transverse walls connected by a longitudinal wall all extending downward from the first side portion and the two transverse walls are for attaching to the railcar support, and wherein the second side portion pivots with respect to the first side portion to conform to the railcar support; and a bottom portion coupled to the second side portion, the bottom portion for attaching to the railcar support.

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.

An object processing system is disclosed that includes a plurality of track sections, and a plurality of remotely actuatable carriers for controlled movement along at least portions of the plurality of track sections, each of the actuatable carriers being instructed at any time to move a limited number of track section only.

An automated carrier system is disclosed for moving objects to be processed. The automated carrier system includes a base structure of a carrier on which an object may be supported, and at least two wheels mounted to at least two motors to provide at least two wheel assemblies, the at least two wheel assemblies being pivotally supported on the base structure for pivoting movement from a first position to a second position to effect a change in direction of movement of the carrier.

A logistic monorail transportation system. The logistic monorail transportation system comprises a logistic track beam system, a logistic vehicle system, a logistic turnout system, a logistic handling system, and a logistic signal system. The logistic track beam system is set up on the road, in the field, or in the streets in the form of single-column pier studs or frame-type pier shads. The technical solution of the present application solves the problems of short distance, high costs, and low speed of existing transportation systems, and the purpose of long-distance, low-cost, and high-speed logistic monorail transportation is achieved.