Technical methods described herein include a motor vehicle frame having an improved field of view. The motor vehicle frame includes a pillar body, such as an A-pillar, having an opening positioned between opposite sidewalls of the pillar body. A transparent material is disposed within the opening in the pillar body. The transparent material is selected from materials having a transmission coefficient of at least 50 percent for light in the infrared (IR), visible, and ultraviolet (UV) wavelengths and a refractive index between 1 and 2 for visible light, such as polymethylmethacralate (PMMA) or an optically transparent polycarbonate.

A vehicle door includes a window and further includes window glass, an outer panel made of resin, and a belt molding. The outer panel is placed outwardly in the vehicle width direction from the window glass and faces the window glass in at least part of the peripheral edge of the opening. The belt molding is fixed to the inner surface of the outer panel facing the window glass and seals a gap between the window glass and the outer panel. The belt molding includes a base member and a belt molding body. The base member is bonded to the inner surface of the outer panel and has an attachment surface facing the window glass. The belt molding body is supported on the attachment surface of the base member via a plurality of fixed points provided such that the fixed points are distanced from each other.

The subject invention includes a fixed window assembly for a vehicle comprising a fixed glass, a trim portion having a polymeric base and a decorative member bonded to the polymeric base. An encapsulation is coupled to the fixed glass and the polymeric base to mount the trim portion in a spaced and adjacent position relative to the fixed glass. A method of manufacturing is also provided using first and second molding apparatuses. Polymeric material is injected into a first mold cavity of the first molding apparatus to form the polymeric base bonded to the decorative member. Polymeric material is injected into a second mold cavity of the second molding apparatus to form the encapsulation coupled to the fixed glass and simultaneously coupled to the polymeric base to mount the trim portion in an adjacent position to the fixed glass.

A removable panel assembly for a vehicle window, the panel assembly includes a removable panel sized and shaped to overlie at least a portion of an outward-facing surface of a vehicle window. A first retainer is configured to secure the panel in abutting relation to the window, the first retainer including a first engagement element configured to engage a first edge of the window and a second engagement element configured to engage an inward-facing surface of the window. A second retainer is configured to secure the panel in abutting relation to the window, the second retainer including a third engagement element configured to engage a second edge of the window and a fourth engagement element configured to engage the inward-facing surface of the window.

To provide a slider-equipped window glass capable of increasing the productivity and quality, and a process for its production. A slider 24 is an integrally molded product comprising an inner layer portion 36 and an outer layer portion 38. The inner layer portion 36 is bonded to a vehicle inner surface 20F of a window glass 20, and the outer layer portion 38 is located on the vehicle inner surface side of the inner layer portion 36 and is made of a material harder than the inner layer portion 36. Further, in the outer layer portion 38, a concave engaging portion 26 to engage with an up-and-down movement guide member 22, is formed.

A zipper less removable window system having removable windows for use with a foldable, stowable roof for a vehicle. A plurality of attachment devices of the zipper less removable window system connect the windows to the foldable, stowable roof and to the vehicle without the use of zippers. The operator zipper effort caused by traditional windows is thereby eliminated and misalignment issues present with traditional zippered windows is eliminated or reduced. The stress placed on the portions of the windows connectable to the foldable roof during installation and removal, including around curved portions of the removable window, is eliminated or reduced.

A frame for a vehicle is provided such that a glass plate including a variable transparency region is installed. The frame includes a glass plate mount that is stepped to allow the glass plate to be inserted and mounted. A cable passage is defined in one side surface of the glass plate mount to allow a cable connected to a connection portion of the glass plate to pass through the cable passage.

A flush glass apparatus includes a fixed glass having an opening, an operation glass configured to open and close the opening of the fixed glass, a lower rail configured to slidably support a lower portion of the operation glass, a sealing member provided below the lower rail to seal a gap between an inner surface of the fixed glass and a vehicle body, one or more upper drain holes provided on the lower rail to discharge rainwater on the lower rail to a buffer area between the lower rail and the sealing member, and a drain induction member interposed between the inner surface of the fixed glass and the sealing member and providing a lower drain hole to discharge rainwater in the buffer area to the outside.

A zipper less removable window system having removable windows for use with a foldable, stowable roof for a vehicle. A plurality of attachment devices of the zipper less removable window system connect the windows to the foldable, stowable roof and to the vehicle without the use of zippers. The operator zipper effort caused by traditional windows is thereby eliminated and misalignment issues present with traditional zippered windows is eliminated or reduced. The stress placed on the portions of the windows connectable to the foldable roof during installation and removal, including around curved portions of the removable window, is eliminated or reduced.

Technical methods described herein include a motor vehicle frame having an improved field of view. The motor vehicle frame includes a pillar body, such as an A-pillar, having an opening positioned between opposite sidewalls of the pillar body. A transparent material is disposed within the opening in the pillar body. The transparent material is selected from materials having a transmission coefficient of at least 50 percent for light in the infrared (IR), visible, and ultraviolet (UV) wavelengths and a refractive index between 1 and 2 for visible light, such as polymethylmethacralate (PMMA) or an optically transparent polycarbonate.