A process of making a drag-reducing aerodynamic vehicle system includes injection molding a body configured for attachment to a roof of a vehicle with a sliding core, wherein the body comprises an air inlet extending through a surface of the body, wherein the air inlet includes an air guide boss extending from an interior surface of the body, wherein the air guide boss adjusts an air stagnation point away from the windshield to reduce air pressure and drag on the vehicle; and ejecting the drag-reducing aerodynamic vehicle system from the injection mold using the sliding core.

This invention provides aerodynamic structures for the rear of a cargo body that move between a deployed position and a retracted position. The aerodynamic structures are typically three-sided, with a top panel and opposing side panels that form a partial cavity at the rear of the body. The panels employ tensioned flexible (e.g. fabric) panels or rigid/semi-rigid panels that are stowed, rolled, or folded in a retracted position against the rear of the door frame (for flexible panels) of the cargo body, or along the sides of the cargo body (for rigid/semi-rigid panels). The rigid/semi-rigid panels can be stored within nacelles that protect the panels and improve aerodynamic performance. Various linkages, including rotating rigid members attached to the rear of the body can coordinate movement between a top panel and side panels between deployed and retracted positions and a variety of powered and non-powered actuators can facilitate panel movement.

Systems, methods, and devices for a vehicle windshield are disclosed herein. A vehicle includes a vehicle body comprising a front, a first side, and a second side, wherein the first side and the second side are opposite one another on the vehicle body. The vehicle comprises a cabin located within the body of the vehicle, wherein the cabin comprises an interior that is configured to accommodate at least one person. The vehicle comprises at least one door that provides ingress and egress to the interior of the cabin of the vehicle. The vehicle comprises a windshield that provides a visual line of sight out of the cabin for a user located within the interior of the cabin, and wherein the windshield extends across the front and at least partially on to at least one of the first side or the second side.

An air fairing device is connected below the bottom a frameless trailer to improve aerodynamic efficiency and improve fuel economy. One embodiment of the air fairing device provides an air deflector positioned forward of a trolley which supports the frameless trailer at a rear end. A second embodiment of the air fairing device provides two deflectors mounted below the frameless trailer. The first deflector is attached and extends downward from an articulating arm, said arm connecting the trailer to a semi-tractor or truck. The second deflector connected to below the bottom of the frameless trailer and positioned rear of the first deflector and forward of the trolley. A third embodiment is similar to the second but further includes a third deflector positioned between two axles of the trolley.

A truck or tractor semi-trailer combination interconnected via a fifth wheel, comprising a cabin and an air collection chamber, the air collection chamber provided between a rear end of the cabin and the semi-trailer and having a front wall substantially adjacent or identical to a cabin rear wall, and a rear wall distanced and substantially coplanar to the front wall, which air collection chamber is provided with an air accession structure and a heat exchanger, the air accession structure providing air access to the air collection chamber and towards the heat exchanger, said heat exchanger provided in the rear wall of the air collection chamber extending at least partly over a width of the truck and wherein said air accession structure comprises air accession side ports provided on the side walls of the air collection chamber designed to provide at least a passive air flow from the air accession side ports towards the heat exchanger.

Apparatus and associated methods relate to an airfoil configured to be disposed at a distal end of a tank. In an illustrative example, the airfoil may be configured such that, when the tank travels at a predetermined minimum speed in a proximal direction substantially parallel to a longitudinal axis of the tank, the airfoil coalesces off-coming air from the tank and distally repositions a low-pressure region downstream of the tank below a plane horizontal to the longitudinal axis. The region may be distally displaced, for example, by at least one of a length scale of the tank. A cross-section of the tank may, for example, define a substantially conic section. A span of the wing may, for example, be orthogonal to the longitudinal axis. The wing may, for example, be below an upper surface of the tank. Various embodiments may advantageously reduce turbulence in the wake of the tank.

A fairing includes a first part including a wall having and a top flange extending from the wall. A second part of the fairing includes a body and a bottom flange extending from the body. The bottom flange is configured to engage the top flange to couple the second part to the first part.

A vehicle comprising means for attaching a cargo transporting member thereto, wherein the vehicle further comprises a wind deflector for deflecting wind from the cargo transporting member when being attached to the vehicle, wherein the wind deflector comprises two or more wind deflector portions which are configured to deflect wind when the vehicle is travelling in a travelling direction, wherein the wind deflector is configured to be expanded into at least a first wind deflecting state and collapsed into a collapsed state, wherein the two or more wind deflector portions are configured to be pivoted relative each other with respect to a common rotational axis so that the wind deflector is expanded and collapsed between the first wind deflecting state and the collapsed state.

Vertical bars extend downwardly from the structural siderails of a trailer frame to a guard bar extending parallel to the longitudinal axis of the trailer, thus forming a side underride guard. Two side underride guards are fixed to the structural siderails of the trailer. The guard bars are located vertically below the bed of the trailer to have an effective ground clearance of twenty-seven inches. Lateral bracing of each guard bar extends from the guard bar to the structural siderail across the trailer. Bracing at the trailing end of the side underride guards employs a K-brace to provide an air brake hose non-chafing zone. The K-brace is displaced from the trailer bed.

A rear impact guard includes at least one vertical member, and a horizontal member connected to a distal end of the at least one vertical member, the horizontal member having a plurality of through passages allowing for air flow through the horizontal member.