A vehicle strengthening member includes a top wall and a pair of lateral walls so that the vehicle strengthening member has a hat-shaped cross section. The vehicle strengthening member further includes a plurality of bend portions each of which is bent along a fold line extending in a transverse direction so that the vehicle strengthening member is curved as a whole. The top wall includes a recess extending in a longitudinal direction along a center of the top wall. The top wall also includes a pair of ridges extending in the longitudinal direction on lateral sides of the recess. The top wall further includes at least one raised bead formed in the recess at a position corresponding to each of the bend portions, each raised bead extending in the transverse direction. Each raised bead comprises ends, each of which is joined to a side of the ridge.

A vehicle strengthening member includes a top wall and a pair of lateral walls so that the vehicle strengthening member has a hat-shaped cross section. The vehicle strengthening member further includes a plurality of bend portions each of which is bent along a fold line extending in a transverse direction so that the vehicle strengthening member is curved as a whole. The top wall includes a recess extending in a longitudinal direction along a center of the top wall. The top wall also includes a pair of ridges extending in the longitudinal direction on lateral sides of the recess. The top wall further includes at least one raised bead formed in the recess at a position corresponding to each of the bend portions, each raised bead extending in the transverse direction. Each raised bead comprises ends, each of which is joined to a side of the ridge.

Sensor module for mounting on a motor vehicle panel component having a sensor housing, at least one environment sensor, at least part of which is disposed in the sensor housing, and which is configured to send and/or receive electromagnetic signals to thus detect a vehicle environment, and a kinematic system having a drive configured to move the sensor housing from a retracted position into at least one deployed position. The kinematic system is configured to move the sensor housing into a first deployed position, which activates the at least one environment sensor to detect the vehicle environment in a portion of its field of view, and to move the sensor housing into a second deployed position, which activates the at least one environment sensor to detect the vehicle environment in its entire field of view.

Sensor module for mounting on a motor vehicle panel component having a sensor housing, at least one environment sensor, at least part of which is disposed in the sensor housing, and which is configured to send and/or receive electromagnetic signals to thus detect a vehicle environment, and a kinematic system having a drive configured to move the sensor housing from a retracted position into at least one deployed position. The kinematic system is configured to move the sensor housing into a first deployed position, which activates the at least one environment sensor to detect the vehicle environment in a portion of its field of view, and to move the sensor housing into a second deployed position, which activates the at least one environment sensor to detect the vehicle environment in its entire field of view.

In a vehicle, a roof siderail outer includes an upper flange, a first portion that is disposed across a gap from a roof siderail inner, and a second portion disposed between the first portion and the upper flange. A boundary line between the upper flange and the second portion is configured of a first bent portion that is bent to form a valley crease line on an outer face of the roof siderail outer. A boundary line between the second portion and the first portion is configured of a second bent portion that is bent to form a ridge crease line on the outer face. The second bent portion extends toward the first bent portion in a rearward direction, and is connected to the first bent portion. The upper flange is welded to a rear pillar.

In a vehicle, a roof siderail outer includes an upper flange, a first portion that is disposed across a gap from a roof siderail inner, and a second portion disposed between the first portion and the upper flange. A boundary line between the upper flange and the second portion is configured of a first bent portion that is bent to form a valley crease line on an outer face of the roof siderail outer. A boundary line between the second portion and the first portion is configured of a second bent portion that is bent to form a ridge crease line on the outer face. The second bent portion extends toward the first bent portion in a rearward direction, and is connected to the first bent portion. The upper flange is welded to a rear pillar.

A vehicle body includes a rear opening and a rear header. The rear header includes a first and a second rear header panel. A closed cross-section space is defined by the first and the second rear header panels. The vehicle body includes a reinforcing member that is disposed in the closed cross-section space. The first and the second rear header panels each include a first portion extending downward in the vehicle up-down direction and a second portion bending from a lower end of the first portion and extending rearward in the vehicle front-rear direction. The reinforcing member is disposed in a region in which the first portion of the first rear header panel and the first portion of the second rear header panel face each other. A space is provided between a lower face of the reinforcing member and the second portion of the first rear header panel.

A vehicle body includes a rear opening and a rear header. The rear header includes a first and a second rear header panel. A closed cross-section space is defined by the first and the second rear header panels. The vehicle body includes a reinforcing member that is disposed in the closed cross-section space. The first and the second rear header panels each include a first portion extending downward in the vehicle up-down direction and a second portion bending from a lower end of the first portion and extending rearward in the vehicle front-rear direction. The reinforcing member is disposed in a region in which the first portion of the first rear header panel and the first portion of the second rear header panel face each other. A space is provided between a lower face of the reinforcing member and the second portion of the first rear header panel.

A beam assembly includes a first beam that has a first tubular portion and a first projecting portion that extends from the first tubular portion. A second beam has a second tubular portion and a second projecting portion that extends from the second tubular portion. The elongated interior of the first tubular portion defines a first hollow area and the elongated interior of the second tubular portion defines a second hollow area. The first beam is attached to the second beam with the first projecting portion attached to the second tubular portion and the second projecting portion attached to the first tubular portion to define a third hollow area between the first and second projecting portions.

A hot-stamping formed article is formed of a single steel sheet, and includes: a top sheet portion; a pair of standing wall portions; and a protrusion portion which connects the top sheet portion to the standing wall portion and protrudes outward from the top sheet portion, in which the protrusion portion includes an inner wall portion which stands upright from the top sheet portion, and an outer wall portion which is folded outward from an end edge of the inner wall portion, and an angle between the top sheet portion and the protrusion portion is 80° to 90°.