This application claims the foreign priority benefit under Title 35, United States Code, § 19(a)-(d) of Japanese Patent Application Numbers 2006-017032, filed on Jan. 26, 2006, and 2006-064021, filed on Mar. 9, 2006, the contents of which are hereby incorporated by reference.
1. Field of the Invention
The present invention relates to a hatchback door structure for vehicles, which is light and rigid.
2. Description of the Background Art
A hatchback door structure has been known, which includes an inner panel in which a lateral beam is integrally formed with a frame which has a shape outlining an outer shape of the hatchback door so that the lateral beam divides the frame into an upper portion and a lower portion (for example, refer to paragraphs 0010 to 0015 and FIG. 1 of Japanese Patent Laid-Open Publication Kokai No. H08-258568). Here,
In the hatchback door structure 201, a rigidity of the inner panel 206 is increased by disposing the pair of joint reinforcements 200a in the opening 212b.
Generally, a hatchback door fitted up on a tailgate in a rear part of a vehicle is jointed to the vehicle with a hinge structure. An opening-closing motion of the hatchback door is performed by rotating the door about the hinge located at the upper end of the door. These types of hatchback doors are required to increase the rigidity for improving collision strength and for avoiding muffled sounds when a vehicle runs a punishing road. On the other hand, the hatchback door must be light for reducing fuel consumption of a vehicle and improving easiness of the opening-closing motion of the door. Because of the above reasons, most of conventional hatchback doors for vehicles have a structure combining a thin outer panel and a thin inner panel which has openings, and the structure is reinforced by utilizing shapes of the both panels.
However, in the hatchback door structure 201 in
In addition, in
The first problem is as follows. When the lateral beam 306c is integrally formed as in the inner panel 302c shown in
The second is as follows. Corners 312c, where the lateral beam 306c and the frame 304c of the inner panel 302c are jointed, are required to have a radius R larger than a predetermined value. As a result, a size of the opening 308c for the rear glass window should be made smaller, which narrows a rearward visibility of a vehicle.
The third is as follows. Improvement of the rigidity of the inner panel 302c against bending in a tangential direction relative to a circular path formed by the rotation circle of the hatchback door is difficult. When a hatchback door is closed, the hatchback door receives a force in the tangential direction. Therefore, if the louvered-walls 311c of the lateral beam 306c are formed in parallel with the tangential direction, the vibrations of the hatchback door are effectively suppressed. However, since an inclination of the louvered-walls 311c of the lateral beam 306c is determined by a direction of the press-forming of the inner panel 302c, the louvered-walls 311c may not be inclined in the effective direction for suppressing the vibrations of the hatchback door when the door is closed.
The fourth is as follows. Since the lateral beam 306c is integrally formed with the inner panel 302c, a panel thickness of the lateral beam 306c can not easily be made different from that of the inner panel 302c. For example, changes in design to thin the panel thickness of the lateral beam 306c for the weight saving thinner than that of the frame 304c can not be performed.
It is, therefore, desired to provide a hatchback door structure for vehicles, which is light and capable of increasing a rigidity of the hatchback door structure, as well as capable of reducing a manufacturing process and cost.
It is also desired to provide a hatchback door structure for vehicles, which can improve a rearward visibility of a vehicle.
According to a first aspect of the present invention, there is provided a hatchback door structure for vehicles which comprises: an inner panel which is arranged on an inner side of a vehicle; and an outer panel which is arranged on an outer side of the vehicle, wherein the inner panel comprises a frame which has a shape outlining an outer shape of the hatchback door, and a pair of stiffening ribs which is integrally formed with the frame and extends approximately in a V-shape to both side portions of the frame from a bottom side of the frame.
In the hatchback door structure, the inner panel is formed so that the pair of stiffening ribs extends approximately in a V-shape from the bottom side to the both side portions of the frame which has the shape outlining the outer shape of the hatchback door. That is, in the hatchback door structure, by securing an opening as large as possible on the inner panel due to utilization of the frame and stiffening ribs, the weight saving can be achieved, as well as increase in the rigidity.
In addition, in the hatchback back door structure, since the frame and stiffening ribs are integrally formed, a plurality of reinforcements become unnecessary in contrast with the conventional hatchback door (for example, refer to Japanese Patent Laid-Open Publication No. H08-258568), resulting in the weight saving and a reduction of the manufacturing cost.
Further, in the hatchback back door structure, since the plurality of reinforcements become unnecessary in contrast with the conventional hatchback door (for example, refer to Japanese Patent Laid-Open Publication No. 08-258568), the welding of the reinforcements becomes unnecessary, resulting in reduction of the working process of the manufacturing.
A smoothly continuous surface portion may preferably but not necessarily be formed at a connection part of a side portion of the frame and stiffening rib.
In the hatchback door structure, since there is not a bended portion where stresses tend to be concentrated, that is, since the smooth and continuous surface portion is formed at a connection part of the side portion of the frame and the stiffening rib, the rigidity can be further increased.
The pair of the stiffening ribs may preferably but not necessarily extend approximately in a V-shape from a locking device fixing portion which is formed on the bottom part of the frame to each of the couple of side portions of the frame, the locking device fixing portion being configured for fixing a locking device.
In the hatchback door structure, since the stiffening ribs extend approximately in a V-shape from the locking device fixing portion, the rigidity is further increased.
The inner panel may preferably but not necessarily have louvered-walls which are integrally formed with the inner panel, protrude outward to an outer panel side and are jointed to the outer panel.
In the hatchback door structure, since the louvered-walls formed in the inner panel are jointed to the outer panel, the rigidity is further increased. In addition, in the hatchback door structure, since the louvered-walls are formed by cutting and turning up the panel when they are integrally formed with the inner panel, the louvered-walls can be formed easily at desired positions and with optimal shapes.
On an upper side of the stiffening ribs, a first opening may preferably but not necessarily be defined by the stiffening ribs and the frame, on a lower side of one of the stiffening ribs, a second opening be defined by the one of the stiffening ribs and the frame, and on a lower side of the other stiffening rib, a third opening be defined by the other stiffening rib and the frame.
In the hatchback door structure, since the first opening, the second opening, and the third opening are formed on the inner panel, openings can be formed as large as possible to cover a broader area of the inner panel. As a result, the hatchback door structure can achieve the weight saving, as well as improvement of the rigidity.
The inner panel further may preferably but not necessarily comprise a lateral beam which extends between jointing portions of the side portions of the frame and stiffening ribs, and is integrally formed with the inner panel by press-forming.
In the hatchback door structure, since the lateral beam is formed to extend between the jointing portions of the side portions of the frame and the stiffening ribs, the rigidity is further increased. In addition, since the lateral beam is integrally formed with the frame and the stiffening ribs, a manufacturing process of the hatchback door structure (inner panel) can be simplified.
The inner panel may preferably but not necessarily be integrally formed by press-forming, and further comprise a discrete lateral beam which extends between jointing portions of the side portions of the frame and stiffening ribs.
In the hatchback door structure, by forming the discrete lateral beam which is different from the frame and the stiffening ribs, the press-forming of the inner panel can be performed easily and a flexibility in the press-forming can be increased. Accordingly, a larger opening can be secured in the inner panel.
The discrete lateral beam may preferably but not necessarily be formed in a circular arc so that the lateral beam protrudes in convex to an outer side of a vehicle, and a size of a cross section of the lateral beam gradually becomes smaller from a center to both ends of the lateral beam.
In the hatchback door structure, the discrete lateral beam is formed in a circular arc so that the lateral beam protrudes in convex to an outer side of a vehicle, and curves along an outer side of the hatchback door. If a heavy object such as a motor of a wiper is fixed at a center portion of the lateral beam, a large stress is generated at the center portion. In the hatchback door structure, even if the size of the cross section of the center portion is increased for supporting the heavy object with the center portion of the lateral beam, the weight saving of the lateral beam can be achieved, because the size of the cross section of the lateral beam gradually becomes smaller from the center to both ends of the lateral beam.
The discrete lateral beam may preferably but not necessarily be arranged so that a protruded direction of the lateral beam which is approximately perpendicular to an extending direction of the lateral beam is directed along an opening-closing direction of the hatchback door.
In the hatchback door structure, the lateral beam has a sufficient rigidity against a stress applied to the lateral beam, especially, when closing the hatchback door.
Each fixing portion of the discrete lateral beam on each jointing portion may preferably but not necessarily be formed so that the each fixing portion is arranged on a same plane defined in a vehicle width direction.
In the hatchback door structure, since a stress applied to the lateral beam, especially when closing the hatchback door, is uniformly transferred to each of the fixing portion, a load on the fixing portion of the lateral beam can be uniformly dispersed.
In addition, in the hatchback door structure, since the lateral beam is fixed on the same plane, a positioning of the lateral beam relative to the jointing portion becomes easy, thereby resulting in improvement of workability for fixing the lateral beam.
The discrete lateral beam may preferably but not necessarily be formed by press-forming, and a window frame on which a window glass is fixed be formed in an upper portion of the frame.
In the hatchback door structure, the inner panel and the lateral beam to be jointed to the inner panel can be formed independently. Therefore, each of the members (inner panel and lateral beam) can be formed in an optimal shape for increasing the rigidity of the hatchback door structure.
The discrete lateral beam and the inner panel can be formed with different press directions to each other.
In the hatchback door structure, flexibility in the press-forming for the inner panel and lateral beam can be increased.
The discrete lateral beam may preferably but not necessarily be fixed at approximately right angle against the frame of the inner panel at both bottom corners of the window frame.
In the hatchback door structure, an area of the glass window at the bottom corners can be enlarged. As a result, a visibility in the bottom corners of the glass window can be improved.
Structures of the inner panel and the discrete lateral beam may preferably but not necessarily have different cross sectional widths to each other in an inside-outside direction of the hatchback door.
In the hatchback door structure, regardless of a press-formability of the lateral beam, the structures of the frame of the inner panel can be designed thicker in the inside-outside direction of the hatchback door. As a result, the rigidity of the hatchback door structure can be increased.
The inner panel and the discrete lateral beam may preferably but not necessarily have different panel thicknesses to each other.
In the hatchback door structure, the weight saving of the hatchback door structure can be achieved by thinning the panel thickness of the lateral beam.
A material of the inner panel and a material of the discrete lateral beam may preferably but not necessarily be different to each other.
In the hatchback door structure, the weight saving of the hatchback door structure can be achieved by forming the lateral beam with, for example, aluminum alloy.
A hatchback door structure for vehicles according to the present invention can achieve the weight saving, while maintaining a sufficient rigidity. Further, the working process and manufacturing cost of the hatchback door structure can be reduced.
In addition, the press-formability of the inner panel can be improved and the degree of freedom of the inner panel shape can be increased without using a highly-ductile panel material. As a result, the rigidity of the inner panel can be further increased. In addition, by enlarging the opening for the rear glass window compared with the conventional one, a rearward visibility of a vehicle can be widened. In addition, the direction of the press-forming of the discrete lateral beam can be optimized for increasing the rigidity of the hatchback door which is necessary for suppressing the vibrations of the hatchback door at closing the door. Further, a panel thickness of the discrete lateral beam can be changed for, for example, the weight saving.
For a more complete understanding of the present invention, the reader is referred to the following detailed description section, which should be read in conjunction with the accompanying drawings. Throughout the following detailed description and in the drawings, like numbers refer to like parts.
Next, a hatchback door structure for vehicles according to a first embodiment will be explained in detail by referring to figures, as needed.
As shown in
The hatchback door structure 1a includes an outer panel 5 which is arranged on an outer side of the hatchback door 2 and forms an outer side surface of the vehicle V, and an inner panel 6a arranged on an inner side of the outer panel 5. The hatchback door 1a further includes a window 7 to be completed by fitting a glass in an upper portion of the hatchback door 2, and a wiper 8 arranged in a lower portion of the window 7.
As shown in
As shown in
In addition, a locking device fixing portion 11 is disposed at a bottom center of the frame 9 for fixing the locking device (not shown).
As shown in
Accordingly, by partitioning an opening formed inside the frame 9 with the stiffening ribs 10a, 10b, a first opening 12 is defined by upper sides of the stiffening ribs 10a, 10b and the frame 9, a second opening 13 is defined by a lower side of one stiffening rib 10a and the frame 9, and a third opening 14 is defined by a lower side of another stiffening rib 10b and the frame 9. Meanwhile, the first opening 12 according to the embodiment has a pentagonal shape and the second opening 13 and third opening 14 are triangular, in plane view.
As shown in
In addition, as shown in
Meanwhile, the inner panel 6a of the hatchback door structure 1a according to the first embodiment is also used for a hatchback door structure 1b (refer to
Next, effects and advantages of the hatchback door structure 1a according to the embodiment will be explained.
As described above, in the hatchback door structure 1a, since the inner panel 6a is formed so that the pair of the stiffening ribs 10a, 10b extend to the both sides in approximately a V-shape from the bottom side of the frame 9 which outlines the outer shape of the hatchback door 2, the first opening 12, the second opening 13, and the third opening 14 are formed in the inner panel 6a (refer to
In addition, in the hatchback door structure 1a, since the frame 9 and the stiffening ribs 10a, 10b are integrally formed by, for example, press-forming, a plurality of reinforcements become unnecessary in contrast with the conventional hatchback door 201 (refer to
In addition, in the hatchback door structure 1a, since a plurality of the reinforcements are unnecessary in contrast with the conventional hatchback door 201 (refer to
Further, in the hatchback door structure 1a, since there is not a bended portion where stresses tend to be converged and the curved surface portion 16 (refer to
Furthermore, in the hatchback door structure 1a, since the louvered-walls 15 formed on the peripheries of the first opening 12, the second opening 13, and the third opening 14 are jointed to the outer panel 5 (refer to
Next, a hatchback door structure for vehicles according to a second embodiment of the present invention will be explained in detail by referring to figures, as needed.
As shown in
In addition, as shown in
Next, effects and advantages of the hatchback door structure 1b according to the embodiment will be explained.
In the hatchback door structure 1b, the press-forming of the inner panel 6a can be easily performed by forming the lateral beam 18 as a discrete member which is different from the frame 9 and the stiffening ribs 10a, 10b. In addition, a larger opening (first opening 12) can be achieved due to the increase in the level of freedom of the press-forming.
In the hatchback door structure 1b, the lateral beam 18 is curved in a circular arch, and the size of the cross section gradually increases from each of the ends to the center portion (see
In addition, in the hatchback door structure 1b, since the lateral beam 18 is arranged so that the protruding direction H (refer to
Further, in the hatchback door structure 1b, each of the lateral beam fixing portions 19, 19 (refer to
Meanwhile, the present invention is not limited to the aforementioned embodiments, but can be embodied in various modifications. In the first and second embodiments, the louvered-walls 15 of the inner panel 6a are formed on the peripheries of all openings: the first opening 12, the second opening 13, and the third opening 14. However, the louvered-walls 15 may be formed on the peripheries of at least one of these openings.
In addition, in the second embodiment, the lateral beam 18 is fixed on the inner panel 6a as a discrete member. However, the present invention is not limited to this. Here,
As shown in
In the hatchback door structure 1c, since the lateral beam 18 is integrally formed with the frame 9 and the stiffening ribs 10 (10a, 10b), the manufacturing process of the hatchback door structure 1c (inner panel 6b) can be simplified, and at the same time, the rigidity can be increased.
In addition, in the aforementioned embodiments, the stiffening ribs 10a, 10b extend approximately straight. However, the stiffening ribs 10a, 10b may extend with a curvature within a range not to undermine the purposes of the present invention.
Next, a hatchback door structure for vehicles according to a third embodiment of the present invention will be explained in detail by referring to figures, as needed.
On an upper side of the lateral beam 106a, an opening 108a in which a glass window is fixed is disposed. In addition, on a lower side of the lateral beam 106a, an opening 109a is disposed. On peripheries of these openings 108a, 109a, cut-and-turned-up walls (hereinafter referred to as louvered-walls) 111a are formed. The louvered-walls 111a have the effect of increasing the rigidity of the inner panel 102a against bending.
A portion between the pair of welding portions 123, 123 is a beam portion 121. In the beam portion 121, a pair of louvered-walls 122 is formed. The louvered-walls 122 are provided to increase the rigidity of the inner panel 102a against a lateral bending.
The louvered-walls 122 become higher from each end of the beam portion 121 to a center portion. The louvered-walls 122 have the maximum height L3 at a center of the beam portion 121. Thus, the lateral beam 106a is formed in an arch in which a size of a cross section of the lateral beam 106a becomes maximum at the center and minimum at the both ends of the beam portion 121. By forming the lateral beam 106a as described above, a bending stress applied to the lateral beam 106a becomes uniform within the lateral beam 106a.
In addition, since the lateral beam 106a is formed as a discrete member different from the frame 104a, a level of freedom of the shape design becomes higher than that of the conventional lateral beam 306c (refer to
Further, the lateral beam 106a has a superior press formability since it is formed as a discrete member by press-forming. Therefore, a formation of holes for weight saving on a bottom 124 and an upper curved portion 125 of the beam portion 121 can be performed relatively easily. A hole for fixing, for example, a motor of a wiper may be formed on the upper curved portion 125 of the lateral beam 106a in some case, and any portion of the upper curved portion 125 can be used to form the hole because of the excellent press formability. For example, for a motor of a wiper or the like fixed on the lateral beam 106a, a fixing weld-nut or the like can be welded in advance on the upper curved portion 125 of the lateral beam 106a.
In the lateral beam 106a of the inner panel 102a which is used for the hatchback door structure 101a (refer to
When the hatchback door is closed, the hatchback door structure 101a (refer to
In a conventional inner panel 302c shown in
Since the lateral beam 106a is a discrete member different from the frame 104a of the inner panel 102a, a panel thickness of the lateral beam 106a may be different from that of the frame 104a for the weight saving as described above. In addition, a material of the lateral beam 106a may be different from that of the frame 104a.
An explanation of corner portions 112a, 112a (refer to
In the inner panel 102a which is used for the hatchback door structure 101a according to the embodiment, since the lateral beam 106a is formed as a discrete member, a height L1 (refer to
In the inner panel 102a, since the lateral beam 106a is formed as a discrete member different from the frame 104a, the press formability is superior to that of the conventional inner panel 302c. Therefore, the height L1 of the louvered-walls 111a can easily be made higher than the limited height Lc of the louvered-walls 311c. Therefore, by increasing the height L1 of the louvered-walls 111a as needed, that is, by increasing a cross sectional width in an inside-outside direction of the hatch back door structure 101a, the rigidity of the frame 104a which configures the inner panel 102a can be increased.
Next, effects and advantages of the hatchback door structure 101a according to the embodiment will be explained based on the configuration of the hatchback door structure 101a.
In the hatchback door structure 101a according to the embodiment, a press direction of the lateral beam 106a of the inner panel 102a can be determined independently from that of the inner panel 102a. As a result, as described above, by selecting the press direction of the lateral beam 106a, the vibrations of the hatchback door at closing the door can be suppressed effectively, compared with the conventional hatchback door.
In the inner panel 102a to be used for the hatchback door structure 101a according to the embodiment, since the lateral beam 106a is fixed as a discrete member, the press formability of the inner panel 102a is improved, compared with the conventional example. As a result, the height of the louvered-walls 111a of the frame 104a of the inner panel 102a can be made higher than that of the louvered-walls 311c of the conventional inner panel 302c. Accordingly, the rigidity of the inner panel 102a can be increased.
In the inner panel 102a to be used for the hatchback door structure 101a according to the embodiment, as shown in
In the inner panel 102a to be used for the hatchback door structure 101a according to the embodiment, since the lateral beam 106a is formed as a discrete member different from the frame 104a (refer to
In addition, since the lateral beam 106a is formed as a discrete member different from the frame 104a, an amount of a panel material punched out by the press-forming from a window portion of the frame 104a becomes fairly large. Therefore, the panel material punched out by the press forming can be utilized for manufacturing other components.
In the hatchback door structure 101a according to the third embodiment, a small component such as a nut can be assembled in advance on the discrete lateral beam 106a. For example, a weld-nut for fixing a motor of a wiper can be welded in advance on the lateral beam 106a. Through the above, a number of component to be welded on the panel can be reduced, thereby resulting in simplification of the welding process.
The present invention is not limited to the aforementioned embodiment. Modifications of each figuration requirement of the embodiment are possible without departing from the spirits of the present invention. For example, it is unnecessary that a press direction of the lateral beam 106a in
In a hatchback door structure which uses the inner panel 102b shown in
Although the present invention has been described herein with respect to a number of specific illustrative embodiments, the foregoing description is intended to illustrate, rather than to limit the invention. Those skilled in the art will realize that many modifications of the preferred embodiment could be made which would be operable. All such modifications, which are within the scope of the claims, are intended to be within the scope and spirit of the present invention.
Number | Date | Country | Kind |
---|---|---|---|
2006-017032 | Jan 2006 | JP | national |
2006-064021 | Mar 2006 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
5314228 | Figge, Sr. | May 1994 | A |
6003931 | Dancasius et al. | Dec 1999 | A |
6053562 | Bednarski | Apr 2000 | A |
6776449 | Komatsu et al. | Aug 2004 | B2 |
6929308 | Komatsu et al. | Aug 2005 | B2 |
7306279 | Saitoh | Dec 2007 | B2 |
20070145768 | Saitoh et al. | Jun 2007 | A1 |
20070145773 | Saitoh | Jun 2007 | A1 |
20070210613 | Tanaka et al. | Sep 2007 | A1 |
20080030047 | Munenaga et al. | Feb 2008 | A1 |
Number | Date | Country |
---|---|---|
7550 | May 2005 | AT |
196 35 873 | Mar 1998 | DE |
62-113615 | May 1987 | JP |
08-258568 | Oct 1996 | JP |
10-100684 | Apr 1998 | JP |
11-514613 | Dec 1999 | JP |
2000-118445 | Apr 2000 | JP |
Number | Date | Country | |
---|---|---|---|
20070170751 A1 | Jul 2007 | US |