A fuel tank apparatus is disposed above an engine. The fuel tank apparatus includes a fuel tank in which fuel is stored and a fuel pump coupled to the bottom of the fuel tank. A heat-shield cover that covers a portion of the fuel pump, which portion is exposed from the fuel tank, to shield the portion from heat of the engine is mounted on a coupling portion between the fuel pump and the fuel tank.

A protective structure for a fuel pump includes a protector including a connecting wall, a first protective wall, and a second protective wall. The first protective wall and the second protective wall are disposed outside the fuel pump assembled to an internal combustion engine. A standing surface of the second protective wall on a side opposite to a second base end surface in a standing direction of the second protective wall includes a curved surface that is concave on the second base end surface side and that becomes closer to the second base end surface side as the curved surface becomes farther from the first protective wall.

An assembly includes a subframe, a rocker, a battery cage supported by the rocker, and a battery supported by the battery cage. The assembly includes a reinforcement bolted to the rocker and positioned to be along a load path through the subframe resulting from a vehicle frontal impact.

There is provided a robotic vehicle (100) for operating in a confined space, such as under a floor of a building, for example a house. The robotic vehicle (100) comprises a chassis (102) having a front (F) and a rear (R) defining a longitudinal direction extending between the front (F) and the rear (R), the robotic vehicle (100) for movement in the longitudinal direction. The robotic vehicle (100) further comprises a plurality of first parts (116a, 116b, 16c, 116d) for a respective plurality of release mechanisms (166), the first parts (116a, 16b, 116c, 116d) each connected to the chassis (102) and each release mechanism (166) for securing a respective wheel (160a, 160b, 160c, 160d) to the chassis (102). Each first part (116a, 116b, 116c, 116d) provides a mounting point for the respective wheel 10 (160a, 160b, 160c, 160d) away from the front (F) or the rear (R) of the chassis (102). Each release mechanism (160) is operable by an operator to release the respective wheel (160a, 160b, 160c, 160d) from the chassis (102) for separate removal of the wheels (160a, 60b, 160c, 160d) and the robotic vehicle (100) from the confined space.

A vehicle attachable shielding device for protecting a vehicle control assembly from moisture damage includes a shell that defines an interior space. A first penetration is positioned in a bottom of the shell and defines a rim. The first penetration is configured to insert a control assembly of the vehicle into the interior space. A coupler is coupled to the rim and is configured to couple to an interior surface of a vehicle. A second penetration is positioned in a top of the shell. A panel, which is coupled to the shell, is positioned to selectively couple to the shell to close the second penetration. The shell and the panel are configured to protect the control assembly from moisture damage. The panel is positioned to selectively decouple from the shell so that the second penetration is configured to insert a hand of a user to manipulate the control assembly.

A heat insulating structure of an internal combustion engine (engine 1) includes a cylinder-head-side heat insulating cover (30) and a cylinder-block-side heat insulating cover (40). Each of the first side walls (32) of the cylinder-head-side heat insulating cover (30) is disposed outwardly of, and is spaced apart from, a corresponding one of the second side walls (43) of the cylinder-block-side heat insulating cover (40) in the width direction of the vehicle. The lower edge of each of the first side walls (32) is positioned below the upper edge of the corresponding one of the second side walls (43) to overlap with the corresponding one of the second side walls (43) when viewed from the side of the vehicle.

A transverse engine adjacent to a drive shaft includes an engine body having a crankshaft, a first pipe connected to the engine body and running such that an engine coolant flows therethrough, and an accessory drive system. The accessory drive system includes an endless outer belt wound between a crankshaft pulley and an alternator drive pulley. A portion of the first pipe forms a water protector located between the drive shaft and the outer belt and overlapping with the outer belt as viewed from the front or rear of the vehicle.

A two-track vehicle having a chassis on the lower face of which a component is arranged that is sensitive to scraping the road surface, the outer contour jutting out downward from the lower face of the chassis in the direction of the road surface by an offset variable and the component being covered by a base portion of a cover element to protect the component from scraping the road surface. At least one edge portion of the base portion of the cover element is laterally extended in a vehicle transverse direction, the edge portion forming a scraper stop that juts out downward from the cover element base portion in a direction onto the road surface by a vertical offset so that, when the lower face of the vehicle scrapes the road surface, the cover element base portion remains substantially out of contact with an interference contour on the road surface.

A mechanically attached thermal protection system (MATPS) includes an insulating tile having a top surface, a bottom surface, and a plurality of access holes that extend through the insulating tile from the top surface to the bottom surface. A plurality of brackets include a first end attached to the insulating tile and a second end including a mounting hole therethrough, the second end being positioned proximate the bottom surface of the insulating tile. A plurality of fasteners are positioned proximate the bottom surface of the insulating tile and at least partially positioned within one of the access holes so as to be accessible from the top surface of the insulating tile through one of the plurality of access holes. A MATPS including a plurality of air channels within the insulating tile and a method for sealing these air channels to those within an adjacent structure is also described herein.

An inorganic platelet composition for use as thermal and/or electrical insulation and fire protection for electrochemical cells such as lithium ion cells. The inorganic platelet composition may be located on individual battery cells, within the interstitial spaces of adjacent battery cells and/or between modules of battery cells in a larger battery pack. The inorganic platelet composition prevents thermal runaway that may occur in one cell or modules of cells from propagating to adjacent or nearby cells or modules within the battery pack.