The present disclosure relates to vehicle door displacement limiting systems and more specifically to a device and method of assembly for automobile door striker systems.
The statements in this section merely provide background information related to the present disclosure and may not constitute prior art.
Vehicles including automobile sport utility vehicles, station wagons, mini-vans, cross-over vehicles, cargo vans and trucks often provide an access door, commonly known as a lift-gate door. Other similar door designs include hatchback doors, sliding doors and horizontally swinging doors. Although these door designs can be mounted differently, for simplicity, these door designs will hereinafter be summarized in reference to lift-gate doors. Lift-gate doors are frequently hinged along an upper horizontal surface, and latch adjacent to a flooring system of the automobile, commonly adjacent to the rear fender of the automobile. One or more latches can be used. The side edges of lift-gate doors are generally not hinged or physically connected to the vehicle structure or support posts at the rear of the vehicle. Motion of the vehicle therefore can result in “match-boxing”, or non-parallel deflection of the support posts relative to the squared sides of the lift-gate door. Match-boxing is undesirable for several reasons. First, side-to-side or non-parallel motion of support posts can impart additional vehicle noise, known as “chucking” at the lift-gate latch as the vehicle travels along rough or uneven surfaces. Second, unless a mechanism is positioned between the lift-gate door edge and the support posts of the vehicle, full structural allowance for the stiffness of the lift-gate cannot be used in the design of the support structure area.
In order to include the stiffness of the lift-gate door in the analysis and design of structural support posts, wedge type fittings have been used which slide to span the gap between the lift-gate door and the support post. These fittings reduce match-box deflection of the support posts by transferring some deflection load to the lift-gate door using a sliding wedge mechanism generally positioned between each support post and the lift-gate door. The sliding wedge mechanism can be fastened to either or both edges of the lift-gate door or to an edge of one or both of the support posts. In a further known design, a free sliding displaceable wedge is positioned against each lift-gate door side edge and a striker plate is separately mounted to each support post such that the sliding wedge engages the striker plate and displaces relative to the lift gate door to limit match-boxing between the support posts.
Existing designs of polymeric striker assemblies have several drawbacks. When molded, part cooling often results in shrinkage which distorts the striker and prevents proper engagement between the striker and the vehicle component. In some applications, existing fittings are present, which require removal of material of the striker to avoid. This increases mold cost and can decrease part strength. Existing striker designs may also not accommodate sufficient clearance to allow the opposed wedge assembly to freely clear the striker during travel of the lift gate door when wedge engagement is not desirable.
According to several embodiments of an automobile vehicle striker assembly of the present disclosure, a vehicle striker for use between a vehicle opening/closing component and a vehicle body member provides a homogenous polymeric striker body. A first body portion has opposed first and second sides and an inclined surface positioned between the first and second sides. A second body portion is created at an angle with respect to the first body portion. The second body portion has at least one rectangular-shaped cavity created on a vehicle body engaging side adapted to non-rotatably receive a geometrically configured fastener. A resilient bumper is engaged with the second body portion and extends partially over the inclined surface.
According to several further embodiments, a vehicle striker for use between a vehicle opening/closing component and a vehicle body member includes a homogenous polymeric striker body. A first body portion includes opposed first and second sides, and a raised mid-body positioned between the first and second sides. A second body portion oriented at an angle with respect to the first body portion includes first and second mounting wings and a bumper receiving portion positioned between the first and second mounting wings. A resilient bumper is engaged with the second body portion and extends freely and partially over the inclined surface. The raised mid-body defines a substantially planar, inclined surface continuously increasing in elevation with respect to the first and second sides between a free end of the first body portion and an intersection of the first and second body portions.
According to still further embodiments, a method for creating a vehicle striker for use between a vehicle opening/closing component including a homogenous polymeric striker body having a first body portion having opposed first and second sides, and a vehicle body member includes co-molding a raised mid-body between the first and second sides defining a substantially planar inclined surface. In an additional step, the method includes orienting a second body portion at an angle with respect to the first body portion. The method also includes creating first and second mounting wings and a bumper receiving portion between the first and second mounting wings of the second body portion. The method still further includes engaging a resilient bumper with the second body portion, the resilient bumper extending freely and partially over the inclined surface. The method yet further includes continuously increasing an elevation of the inclined surface of the raised mid body with respect to the first and second sides between a free end of the first body portion and an intersection of the first and second body portions.
Further areas of applicability will become apparent from the description provided herein. It should be understood that the description and specific examples are intended for purposes of illustration only and are not intended to limit the scope of the present disclosure.
The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way.
The following description is merely exemplary in nature and is not intended to limit the present disclosure, application, or uses. It should be understood that throughout the drawings, corresponding reference numerals indicate like or corresponding parts and features.
According to several embodiments of the present disclosure and referring generally to
Second body portion 14 includes a first mounting wing 26 and a second mounting wing 28 having a bumper receiving portion 30 positioned between each of the first and second mounting wings 26, 28. A first fastener aperture 32 is created in first mounting wing 26 and a second fastener aperture 34 is similarly created in second mounting wing 28. First and second fastener apertures 32, 34 are each adapted to receive a fastener used to fastenably engage striker 10 to a vehicle body. A resilient bumper 36 created of a resilient material which in several embodiments is rubber is retained on bumper receiving portion 30. Resilient bumper 36 can include a hollow cavity 38 in several embodiments which allows resilient bumper 36 to more easily deflect. With the exception of resilient bumper 36, the material of striker 10 in several embodiments is a polymeric material such as a glass filled polyamide 6-6 material which can be created using a molding operation such as injection molding.
As best seen in reference to
Inclined surface 22 of raised mid-body 20 defines an included surface angle β with respect to a reference axis 46. In several embodiments, included surface angle β is approximately 5 degrees. Inclined surface 22 continuously increases in height from a first free end (height Z) of first body portion 12 to the intersection of first and second body portions 12 and 14 (height Z′). Reference axis 46, similar to axis 42, is substantially perpendicular to second mounting surface 44. Second body portion 14 has a second body portion thickness “B” which in several embodiments is approximately 14.0 mm. Resilient bumper 36 positioned on second body portion 14 defines a total bumper stand-off height “C” which in several embodiments is approximately 32.9 mm.
Referring now to
Referring now in general to
Referring now to
An aperture spacing “J” defines the location of each of the first and second fastener apertures 32, 34. According to several embodiments of the present disclosure aperture spacing “J” is approximately 49.0 mm. A cavity width “K” is therefore controlled when each of first, second, third and fourth inner walls 58, 60, 62, 64 are created in the mold or die used to create striker 10 to coincide with the dimension across the flats of the associated nut or fastener. A cross-brace wall 66 can be used to span the otherwise significantly hollow rear portion of bumper receiving portion 30. In addition to cross-brace wall 66, a first intermediate wall 68, a second intermediate wall 70, a curved wall 72, and a third intermediate wall 74 can also be used to stiffen the proximate area of bumper receiving portion 30 where a bumper retention element 75 of resilient bumper 36 is engaged within an aperture 77 created in bumper receiving portion 30. The relative sizes and locations of each of first and second stiffener ribs 54, 56 are also visible in
Referring now generally to
In the exemplary installation shown in
Referring now generally to
A striker 10 of the present disclosure offers several advantages. By incorporating rectangular-shaped cavities in a vehicle engaging side of second body portion 14, nuts or similar fasteners can be non-rotatably engaged which allows a blind installation of striker 10 with respect to the nuts. A blind installation (the installer places the striker over the nuts and the nuts are freely received in the striker without visual reference to the nuts) is made possible because the orientation of the nuts is pre-determined by a correspondingly rectangular-shaped aperture in the vehicle panel. The use of body offset angle α allows striker 10 to engage a substantially 90 degree body or lift gate door panel junction allowing for manufacturing tolerances including part shrinkage of striker 10 and configuration/stamping tolerances of the body or lift gate door panel junction area.
This application is a continuation-in-part of U.S. Design Application No. 29/229,039, filed on May 2, 2005, which is incorporated herein by reference.
Number | Date | Country | |
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Parent | 29229039 | May 2005 | US |
Child | 11415458 | May 2006 | US |