Please substitute the new Abstract submitted herewith for the original Abstract:

A front-end structure for a vehicle has a wheelhouse, a rocker panel, a support carrier which is connected to the wheelhouse and the rocker panel and which extends at an angle, an A-pillar, a door flange and a connecting portion connecting the A-pillar to the door flange. The connecting portion extends, at least in portions, substantially parallel to the support carri er.

Please substitute the new Abstract submitted herewith for the original Abstract:

A front-end structure for a vehicle has a wheelhouse, a rocker panel, a support carrier which is connected to the wheelhouse and the rocker panel and which extends at an angle, an A-pillar, a door flange and a connecting portion connecting the A-pillar to the door flange. The connecting portion extends, at least in portions, substantially parallel to the support carri er.

In a vehicle to which the present joining structure of vehicle steel plates is applied, a third welded portion is set between a first welded portion and a second welded portion, wherein at the first welded portion, a pillar outer rear flange, an SM outer rear flange, a pillar inner rear flange are joined to one another; and at the second welded portion, the pillar outer rear flange and the pillar inner rear flange are joined to each other. At the third welded portion, the pillar outer rear flange and the SM outer rear flange are joined to each other. Accordingly, a tensile load F acting on the pillar outer rear flange is distributed toward the SM outer rear flange side.

In a vehicle to which the present joining structure of vehicle steel plates is applied, a third welded portion is set between a first welded portion and a second welded portion, wherein at the first welded portion, a pillar outer rear flange, an SM outer rear flange, a pillar inner rear flange are joined to one another; and at the second welded portion, the pillar outer rear flange and the pillar inner rear flange are joined to each other. At the third welded portion, the pillar outer rear flange and the SM outer rear flange are joined to each other. Accordingly, a tensile load F acting on the pillar outer rear flange is distributed toward the SM outer rear flange side.

A vehicular side structure includes: a side panel that is located above a door opening provided to a vehicle and forms an outer surface, wherein a ridge line is formed, along an upper edge of the door opening, in the side panel.

A vehicular side structure includes: a side panel that is located above a door opening provided to a vehicle and forms an outer surface, wherein a ridge line is formed, along an upper edge of the door opening, in the side panel.

The invention relates to an air outlet structure, a column, and a vehicle. The air outlet structure comprises: an air duct; a first air outlet and a second air outlet, the first air outlet and the second air outlet being configured to be spaced apart from each other and parallel to each other; and a first air-inducing channel and a second air-inducing channel, the first air-inducing channel extending to the first air outlet from the air duct, the second air-inducing channel extending to the second air outlet from the air duct, and the first air-inducing channel and the second air-inducing channel being configured in such a manner that a first airflow flowing out of the first air outlet and a second airflow flowing out of the second air outlet intersect and scatter each other. Through the foregoing air outlet structure, the vehicle according to the invention can expand an air supply range, significantly improve uniformity of air supply, and prevent directly blowing air to a passenger.

An embodiment vehicle body for an electric vehicle includes a fender apron upper part and an A pillar part positioned at a rear portion of the fender apron upper part, wherein a first load path is formed in a length direction of the vehicle body on an upper part of the fender apron upper part, wherein a second load path is formed in a vertical direction of the vehicle body along a connection portion of the fender apron upper part and the A pillar part, wherein a third load path connecting the first load path and the second load path is obliquely formed in a lower part of the fender apron upper part, and wherein a charging hole is formed between the first, second, and third load paths.

An embodiment vehicle body for an electric vehicle includes a fender apron upper part and an A pillar part positioned at a rear portion of the fender apron upper part, wherein a first load path is formed in a length direction of the vehicle body on an upper part of the fender apron upper part, wherein a second load path is formed in a vertical direction of the vehicle body along a connection portion of the fender apron upper part and the A pillar part, wherein a third load path connecting the first load path and the second load path is obliquely formed in a lower part of the fender apron upper part, and wherein a charging hole is formed between the first, second, and third load paths.

A front pillar upper structure of a vehicle includes an outer member and an inner member. The inner member forms an inner wall of the front pillar upper structure in a vehicle-width direction, and is joined to the outer member forming an outer wall in the vehicle-width direction to form a closed cross-section structure. The inner member includes a flange part, a first wall part, and a second wall part. The second wall part is disposed between the flange part located on the lower side of the inner member and joined to the outer member and the first wall part located above the flange part. The second wall part has an angle of inclination in a range from 41° to 68° to a principal axis of inertia extending in the vehicle-width direction in a cross section substantially vertical to a longitudinal direction of the front pillar upper structure.