A door of a vehicle may include a first door module forming a door skeleton; and a second door module coupled with the first door module and forming a door window; wherein the second door module includes a relatively lightweight material as compared to the first door module; a reinforcement member is inserted along an edge portion forming the door window of the second door module; and a stepped portion is formed at the reinforcement member, reducing weight and cost of the door of the vehicle.

A hemming structure may include a door, in which the door has an internal panel and an external panel made of different materials, the hemming structure being configured such that each of the internal panel and the external panel is provided with a contact area with end portions of the internal panel and the external panel contacting with each other at the contact area, wherein the contact area includes a first contact area with a sealer applied onto a contact surface between the internal panel and the external panel, and a second contact area extending from the first contact area and being bent to be brought into contact with the internal panel at the first contact area, and the second contact area is provided with a bonding portion at which the internal panel and the external panel are mechanically bonded to each other.

Disclosed is a structure for a hybrid-type door, which is capable of preventing deformation caused by difference in thermal expansion coefficient between an outer panel of aluminum alloy and an inner panel of iron steel. The structure for a hybrid-type door may include an inner panel and an outer panel made of different material from the inner panel. In particular, an end portion of the inner panel and an end portion of the outer panel may be provided at a contact area, and the end portion of the inner panel may be hemmed by the end portion of the outer panel. A sealer may be applied to the contact areas at which the inner panel and the outer panel may be brought into contact with each other, and the contact area of the inner panel may include a non-contact space being free from contacting the sealer.

A motor vehicle includes a tailgate which has an inner panel, a reinforcing component and an outer panel. The inner component or the outer component is flanged on an end portion, forming a cavity or intermediate space. An adhesive is placed in the intermediate space. An end portion of the non-flanged component is arranged in the intermediate space. An intermediate space is formed between an inner surface of the inner component and an inner surface of the outer component and is filled with adhesive. The end portion of the middle component present in each case is arranged in the intermediate space.

A vehicular door includes a resin outer panel and a resin inner panel mounted on a vehicular interior side of the resin outer panel, and the resin inner panel includes a resin body member that configures an interior design surface of the vehicular door and a resin reinforcing member that is arranged on a vehicular exterior side and on a peripheral portion of the resin body member.

A vehicular door includes an inner panel and an outer panel that is mounted on a vehicular exterior side of the inner panel such that they are mounted to and separated from each other by sliding. The outer panel is mounted to the inner panel while the first outer side stopper and the first inner side stopper being fit to each other and the second outer side stopper and the second inner side stopper being fit to each other. In the relative sliding of the inner panel and the outer panel in the lateral direction, the first outer side stopper, the second inner side stopper, the second outer side stopper, and the first inner side stopper are arranged such that the first outer side stopper is not contacted with the second inner side stopper or the second outer side stopper is not contacted with the first inner side stopper.

A vehicular door includes an outer panel, an inner panel mounted on a vehicular interior side of the outer panel and configuring a vehicular interior design surface of the vehicular door, a functional component, a driving component driving the functional component and mounted on a vehicular exterior surface side of the inner panel, and a switch configured to activate the driving component to exert a function of the functional component and mounted on a vehicular interior surface side of the inner panel.

A vehicle door includes an inner panel having an upper edge and a lower edge, a door trim panel having an upper edge portion and a lower edge portion, and an upper panel connected to the upper edge portion of the door trim panel. The upper panel includes an upper edge section and a lower edge section, and a crack initiator extending between the upper edge section and the lower edge section. A belt bracket connects the upper panel and the inner panel. The belt bracket includes a first dual pin member and a second dual pin member spaced from the first dual pin member. The first dual pin member and the second dual pin member connect the upper panel with the inner panel.

A structural adhesive film is provided whereby both adhesion and edge coverage can be achieved. The structural adhesive film (1) includes a first curable resin layer (1a) containing a first thermosetting resin and a first foaming agent; and a second curable resin layer (1b) containing a second thermosetting resin. A curing temperature of the first curable resin layer (1a) is lower than a curing temperature of the second curable resin layer (1b); and a foaming starting temperature of the first foaming agent is lower than the curing temperature of the first curable resin layer (1a).

The end portion of a first member includes a plate part and a groove. The end portion of a second member includes an edge and two side surfaces. The groove extends around the edge of the second member and the two side surfaces. The groove includes a side surface including an engaging portion. One of the side surfaces of the end portion of the second member includes an engaged portion. A method for manufacturing a swaged structure includes preparing the first member including the plate part and the groove having a wide opening. The method further includes inserting the end portion of the second member into the groove after preparing the first member. The method further includes pressing the plate part in a direction narrowing the opening of the groove to bring the engaging portion into contact with the engaged portion after inserting the second member.