The present application claims priority to JP 2019-111744, filed Jun. 17, 2019, the entire contents of which are incorporated herein by reference.
The present disclosure relates to an upper vehicle-body structure of a vehicle including a pair of left and right roof side rails and pillar parts extending downward from intermediate portions in a vehicle front-rear direction of the pair of roof side rails.
A known conventional upper vehicle-body structure of a vehicle includes: a pair of left and right roof side rails disposed at respective ends of a roof panel in a vehicle width direction and extending in a vehicle front-rear direction; and a pair of left and right center pillars extending downward in an up-down direction from respective intermediate portions in the vehicle front-rear direction of the pair of roof side rails.
The center pillar of such a vehicle partitions an opening and supports a rear door, which means that the center pillar is apt to experience vibrations during traveling of the vehicle. Such vibrations during traveling of the vehicle may cause abnormal noise such as chattering sound and give an unpleasant feeling to occupants, which is unfavorable.
Effective ways to reduce vibrations include increasing connection rigidity of upper and lower ends of the center pillar and disposing a damping member. For example, Patent Document 1 discloses disposing damping members at two front and rear points in a roof side rail at a connecting portion between the roof side rail and an upper end of a center pillar in such a manner that the damping members constitute joints partitioning the space within the roof side rail, whereby vibrations are damped.
[Patent Document 1] JP-A-2017-039331
In an upper vehicle-body structure including: a roof side rail disposed at an upper and vehicle-width-direction outer side portion of the vehicle, the roof side rail including a closed cross-section extending in a vehicle front-rear direction; a pillar extending downward from an intermediate portion in the vehicle front-rear direction of the roof side rail; and a roof rail reinforcement disposed inside the roof side rail at the intermediate portion in the vehicle front-rear direction of the roof side rail and extending in the vehicle front-rear direction, the roof rail reinforcement including front and rear ends bent toward a vehicle-width-direction outer side, the roof rail reinforcement being configured to partition a space inside the intermediate portion of the roof side rail in the vehicle front-rear direction and a vehicle width direction, the upper vehicle-body structure being characterized in that the roof side rail includes a roof rail outer and a roof rail inner, the roof rail outer constituting a vehicle-width-direction outer side wall, the roof rail inner defining, jointly with the roof rail outer, a closed cross-section, the pillar includes a pillar outer and a pillar inner, the pillar outer constituting a vehicle-width-direction outer side wall, the pillar inner defining, jointly with the pillar outer, a closed cross-section extending in an up-down direction, the front and rear ends of the roof rail reinforcement, bent toward the vehicle-width-direction outer side, are fixed to the roof rail outer, and the roof rail reinforcement includes one or more first bonding members and one or more second bonding members for coupling of a portion of the roof rail reinforcement between the front and rear ends thereof to the roof rail inner coupled to an upper end portion of the pillar inner, the one or more first bonding members being disposed respectively near the front and rear ends of the roof rail reinforcement and having a vibration damping function, the one or more second bonding members being disposed at an intermediate portion between the front and rear ends of the roof rail reinforcement and having a higher damping property than the one or more first bonding members.
Embodiments of the present disclosure will be described below with reference to the drawings. The preferred embodiment given below are merely exemplary in nature and is not intended to limit the present disclosure, its application, or uses.
An object of the present disclosure is to provide an upper vehicle-body structure and the like of a vehicle that can reduce vibrations during traveling of the vehicle.
First, a description will be given of an overall configuration, according to some embodiments.
As shown in
The side sill 1 may be composed of an outer member and an inner member formed by pressing a steel plate. These outer and inner members jointly define a substantially linear closed cross-section extending in the front-rear direction. A lower end of a hinge pillar, which corresponds to a lower half of the A pillar 4, may be connected to a front end portion of the side sill 1, and a lower end of the B pillar 5 may be connected to an intermediate portion of the side sill 1. The A pillar 4, a front portion of the roof side rail 10, the B pillar 5, and a front portion of the side sill 1 may define a door opening edge of a front door (not shown).
A front end portion of a rear wheel well 8 may be connected to a rear end portion of the side sill 1. The B pillar 5, a rear portion of the roof side rail 10, the C pillar 6, a front portion of the rear wheel well 8, and a rear portion of the side sill 1 may define a door opening edge of a rear door (not shown). The B pillar 5 may be structured such that the bending rigidity of its upper portion corresponding to about two thirds of the length of the B pillar 5 from the upper end of the B pillar 5, may be larger than the bending rigidity of its lower portion corresponding to about one third of the length of the B pillar 5 from the lower end of the B pillar 5.
The pair of roof side rails 10 may be disposed at the vehicle-width-direction outer side portions so as to respectively correspond to left and right ends of the roof panel. The pair of roof side rails 10 include a pair of front and rear headers 21, 22, and two roof reinforcements 23, 30. The front header 21 may connect front ends of the pair of roof side rails 10, and the rear header 22 may connect rear ends of the pair of roof side rails 10. The rear header 22 may be mounted with a pair of left and right hinges (not shown) for opening and closing a lift gate (not shown). The roof reinforcement 23 may be positioned so as to connect upper end portions of the pair of C pillars 6 in the left-right direction. The roof reinforcement 30 may be positioned so as to connect upper end portions of the pair of B pillars 5 in the left-right direction.
As shown in
Next, a description will be given of the roof reinforcement 30, according to some embodiments.
As shown in
In some embodiments, a right end of the roof reinforcement 30, and more specifically, the right ends of the connecting portion 33 and the pair of front and rear flanges 34 may be disposed so as to face the left edge of the roof rail outer 11 with a slight gap in between. The connecting portion 33 and the pair of front and rear flanges 34 may be formed with protrusions 35 extended rightward from their respective ends. Each protrusion 35 is present between two adjacent bulges 11a and joined by welding to the upper surface (reference surface) of the roof rail outer 11. A gusset 40 (shown in
Next, a description will be given of the roof side rail 10, according to some embodiments.
As shown in
In some embodiments, an upper end of an outer member 5a (pillar outer) of the B pillar 5 may be joined to a right side of the roof rail outer 11 on which the reinforcement member 14 is disposed. An upper end portion of an inner member 5b (pillar inner) of the B pillar 5 may be joined and fixed to a lower end portion of the roof rail outer 11 with a lower end of the roof rail reinforcement 13 interposed in between. The outer member 5a may be formed with an opening 5c at a position corresponding to this joining portion. The roof rail outer 11, the roof rail reinforcement 13, and the inner member 5b may be joined through the opening 5c. Forming the opening 5c may also reduce weight.
Referring now to
As shown in
The third and the fourth joining portions P3 and P4 are at positions corresponding to intermediate portions of the gusset 40 in the front-rear direction. The roof rail inner 12 may be partially extended leftward. Thus, at the third joining portion P3, the roof rail outer 11 is interposed between the protrusion 35 (the connecting portion 33) and the roof rail inner 12, and they may be triple-joined to each other by welding. At the fourth joining portion P4, which is on the vehicle-width-direction outer side relative to the third joining portion P3, the roof rail inner 12 is interposed between the side flange 44 and the inner member 5b, and they may be triple-joined to each other by welding.
In the present embodiment, the same joining method may be used to join the members at the first, second and fourth joining portions P1, P2, and P4. Further, the joining method to join the roof rail outer 11, the roof rail inner 12, and the roof reinforcement 30 at the third joining portion P3 may be the same as the joining method to join the members at the first, second and fourth joining portions P1, P2, and P4. This allows the welding to be done using the same welding station, helping to improve production efficiency.
Next, a description will be given of the roof rail reinforcement 13, according to some embodiments.
As shown in
In some embodiments, a lower portion of the body 13a reduces its width in the front-rear direction toward the lower end. This may reduces weight and also may allow the body 13a to fit within the B pillar 5. An opening 13j formed in an upper portion of the body 13a may enable spot welding of the outer member 5a of the B pillar 5 and the roof rail outer 11 through the opening 13j and also contributes to reduced weight. To fix the roof rail reinforcement 13 to the roof rail inner 12, the first bonding members 15a may be attached respectively to middle front and middle rear portions of the body 13a (portions near the front and rear ends of the body 13a). The second bonding member 15b may be attached at an intermediate portion between the first bonding members 15a.
In some embodiments, the roof rail reinforcement 13 may partition the trapezoidal closed cross-section of the roof side rail 10 into inner and outer sides in the vehicle width direction, and the closed cross-section on the vehicle-width-direction outer side may also be partitioned on front and rear sides by the joints 13b, 13c of the roof rail reinforcement 13. These joints 13b, 13c may function to prevent collapse of the closed cross-section of the roof side rail 10 on the vehicle-width-direction outer side and increase its rigidity, restraining deformation of the roof side rail 10 in the event of a side collision to thereby reduce entry of the B pillar 5 into the vehicle interior. Additionally, the roof rail reinforcement 13 may be fixed to the roof rail inner 12, which may allow the roof rail reinforcement 13 to also prevent collapse of the closed cross-section of the roof side rail 10 on the vehicle-width-direction inner side. This allows to further restrain deformation of the roof side rail 10 in the event of a side collision. In this way, the roof rail reinforcement 13 may increase rigidity at the connecting portion between the B pillar 5 and the roof side rail 10.
The joints 13b, 13c of the roof rail reinforcement 13 may produce differences in rigidity against sectional collapse between portions of the closed cross-section partitioned into inner and outer sides in the vehicle width direction; the closed cross-section includes a vibration-resistant portion and a vibration-prone portion. As a result, in response to vibrations transmitted from the B pillar 5, the roof rail inner 12 may vibrate relatively more than the roof rail reinforcement 13. These vibrations may be damped by the first and the second bonding members 15a, 15b absorbing and converting them into heat, whereby vibrations transmitted to the roof reinforcement 30 and other components are reduced. In other words, the first and the second bonding members 15a, 15b may be damping members functioning to damp vibrations transmitted to the roof side rail 10 via the B pillar 5.
In some embodiments, the second bonding member 15b of the body 13a may be more distant from the joints 13b, 13c than the first bonding members 15a are and thus may be disposed at a portion that is most prone to vibrations. The second bonding member 15b at this intermediate portion may be given a higher damping capability than that of the front and rear first bonding members 15a to enhance vibration damping effects. More specifically, the second bonding member 15b may be given a larger bonding area than that of the two first bonding members 15a. In other embodiments, the second bonding member 15b may be given a larger thickness in the vehicle width direction than that of the two first bonding members 15a. The second bonding member 15b may also be given both a larger bonding area and a larger thickness than those of the two first bonding members 15a. In still other embodiments, the second bonding member 15b may be made of a material having a higher damping capability than that for the first bonding members 15a and thus given different physical properties for increased damping effects. In these embodiments, the second bonding member 15b may also be given a different bonding area and/or a different thickness in the vehicle width direction, similarly to the above.
Next, functions and effects of the above described upper vehicle-body structure will be described, according to some embodiments.
The upper vehicle-body structure includes the roof rail reinforcement 13 disposed inside the roof side rail 10, which has a closed cross-section extending in the front-rear direction, at the intermediate portion of the roof side rail 10 in the vehicle front-rear direction where the B pillar 5 is connected to the roof side rail 10. The roof rail reinforcement 13 may partition the space inside the roof side rail 10 in a joint-like manner at two points in the front-rear direction and also may partition the space between the two points into inner and outer portions in the vehicle width direction. The roof rail reinforcement 13 may be fixed to the roof rail outer 11 and the roof rail inner 12 constituting the roof side rail 10 and to the inner member 5b constituting the B pillar 5.
The roof rail reinforcement 13 fixed to both of the roof side rail 10 and the B pillar 5 enhances the connection rigidity of the roof side rail 10 and the B pillar 5 and makes them vibration-resistant. The roof rail reinforcement 13 may be further fixed to the roof rail inner 12 at its first and second bonding members 15a, 15b having vibration damping function and damps vibrations. The second bonding member 15b, which may have a higher damping capability than that of the first bonding members 15a, may be disposed at the vibration-prone portion between the fixed front and rear ends of the roof rail reinforcement 13, and this may allow to effectively dampen vibrations. Hence, vibrations during traveling of the vehicle may be reduced.
The second bonding member 15b may be given a larger bonding area than that of the first bonding members 15a, or the second bonding member 15b may be given a larger thickness in the vehicle width direction than that of the first bonding members 15a. This may allow the second bonding member 15b with a larger bonding area or a larger thickness in the vehicle width direction to have a higher damping capability of vibrations than that of the first bonding members 15a, even when the same material is used for the first bonding members 15a and the second bonding member 15b. Hence, a vibration damping structure may be easily achieved.
Each of the joints 13b, 13c at the front and rear ends of the roof rail reinforcement 13 partitioning the space inside the roof side rail 10 in a joint-like manner may be fixed to multiple faces of the roof rail outer 11 to support the roof rail outer 11. This may increase rigidity so as to prevent collapse of the closed cross-section on the vehicle-width-direction outer side of the roof side rail 10 partitioned into the inner and outer sides in the vehicle width direction by the roof rail reinforcement 13. This also may produce rigidity difference from the closed cross-section on the vehicle-width-direction outer side and allows the first and the second bonding members 15a, 15b disposed between the vibration-resistant portion and the vibration-prone portion to effectively absorb vibrations.
The outer member 5a may include the opening 5c at the portion corresponding to the lower end of the roof rail reinforcement 13. This may allow for joining through the opening 5c, enabling an easy assembly and may reduce the weight of the vehicle body.
Besides the above, those skilled in the art will readily understand that various modifications to the above embodiment are possible while keeping with the essential teaching of the present disclosure. The present disclosure encompasses these modifications and alterations.
Number | Date | Country | Kind |
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2019-111744 | Jun 2019 | JP | national |