1. Field of the Invention
The present invention relates to a motor vehicle closure hinge having a pivot axis with spring biasing provided by a laterally coiled spring to prop the closure.
2. Background Art
Many previously known vehicle closure hinges such as those used for engine compartment hoods and trunk lids often include spring biasing to assist displacement of the heavy panel which is displaced about a pivot axis at one end of the panel. However, a spring biasing assist force sufficient to maintain the closure in a fully open position is often provided by additional structure such as a prop rod, gas struts or the like that resists closure of the closure panel by the weight of the panel acting in a moment of arm about the pivot axis or force transfer through a linkage.
One method to provide the spring biasing has been to use the torsion rods that can be routed across the car. However, while such spring biasing can be strong enough to resist closure, since the entire length of the torsion rod provides spring biasing force, the elongated torsion rods can obstruct and form a substantial impediment to the access through the opening or within the compartment covered by the closure panel. Other improvements to spring design, such as gas powered struts or powerful springs often require multiple installation steps since the spring biasing force unit must be separately installed to assist a conventional hinge structure. Such improvements substantially increase the difficulty of production, rendering the use of such components prohibitively expensive because they add production steps as well as additional pieces and mass to the vehicle. In the case of a gas strut power source, in a closed position the line up force in the strut is directed to the hinge pivot, thus forcing the pivot to endure high loading that shortens useful life of the original installation. Also, the life of a gas strut is both time-dependent and cycle-dependent, making it much less durable than a steel spring.
Moreover, once the design and the spring force has been determined for a particular application, the hinge designs may not be readily incorporated into other vehicles having differently sized, weighted or balanced mass or center of gravity than the installation for which it was designed. Rather, the alternative closures need specially designed linkage and/or biasing structures for each particular closure panel type, thereby substantially multiplying the number of assemblies and production pieces that must be made and inventoried by automobile manufacturers and dealers trying in order to accommodate production and repair of the entire product lines of vehicles.
A previously known attempt to address the problems discussed above involves the use of a single pivot arm as part of a four bar link assembly and integral radially wound clock spring. However, while the clock spring may integrate spring biasing force to a hinge mechanism, such springs and require an extremely large envelope both vertically as well as fore-and-aft accommodate the four bar linkage. As a result, these known mechanisms are suitable only for large vehicles, such as trucks. Moreover, alternative designs have been complex, requiring numerous parts and assembly operations, the addition of parts rendering the hinge relatively heavy, and thus have not found favor in many production applications due to the large expense compared to more conventional systems.
The present invention overcomes the above mentioned disadvantages by providing a single pivot closure hinge design that is preassembled as an integral unit for shipping and installation in one piece. Linkage geometry can be designed to accommodate packaging restraints such as available room in the hinge region, and differences in the mass or center of gravity of closure panels can be accommodated without substantially changing the physical link structure of the integral package components. More particularly, the package includes a laterally coiled spring whose coil diameter, wire diameter and number of laterally aligned coils can be changed to modify closure panel performance. In addition, the coil can be mounted about the pivot axis of the hinge, or eccentrically from the pivot axis when space limitations at the pivot envelope demand or when adjacent areas permit a four bar linkage to fit in the vehicle. In addition, the integral packaging of the laterally coiled spring may be applied to various linkage arrangements.
In a preferred embodiment, the laterally coiled spring is housed in a bracket for pivotally mounting a goose-neck bar about a pivot axis. The coil spring can be wrapped around the pivot axis or as shown in a modified version, mounted eccentrically to the pivot axis of the goose-neck bar through a lever assembly. In addition, the eccentrically mounted coil spring can include radially extended end portions that form a four bar linkage with a mount including a pivot axis flange and a pivot link pivotally coupled to the mount. Furthermore, the strand ends may be coupled to the links at one end of the coil, so that the coil ends are arranged substantially in a plane of displacement of the linkage.
Accordingly, the present invention provides substantial cost savings since the integral hinge unit requires substantially fewer labor steps and part installation steps than previously known gas strut or clock spring assemblies. Moreover, the reliability of springs, such as those made of steel, is improved since they can endure a wide range of temperatures and ambient conditions that may have previously affected gas struts and previously known hinge constructions. Moreover, the present invention reduces obstruction at the openings or within the compartments covered by the vehicle closure panels. Moreover, a predetermined hinge structure may be more readily modified for different closure panels having different mass or center of gravity requirements, in large part by adjusting the connection points of the hinge and the size of the coils, the size of the spring strand diameter and the number of coils in the spring. Moreover, the present invention may reduce hinge pivot loading.
The present invention will be more clearly understood by reference to the following detailed description of a preferred embodiment when read in conjunction with the accompanying drawing, in which like reference characters refer to like parts throughout the views, and in which
Referring first to
The hinge assembly 28 comprises a mount bracket 30 to be secured to the body structure 24 for example, by bolts 25 and correspondingly threaded nuts. The bracket 30 includes pivot axis flanges 32 and 34 spaced apart along a pivot axis defined by openings in the flanges 32 and 34, preferably at opposite ends of the central opening 36. A pivot pin 38 extends across the opening 36 through the pin receiving openings 39 and 40 in each of the flanges 32 and 34. A pivot link 42, preferably in the form of a goose-neck bar 44, includes openings receiving the pivot pin 38 at one end of the bar 44. Preferably, the bar is fabricated in the form of a rectangular tube.
The pivot pin 38 is also received through the coils 48 of a laterally coiled spring 50 carried within the opening 36 of the bracket 30. A core 52 made of bushing material that does not cause noise when in contact with metal, for example nylon, supports the coiled spring 50 coaxially over the pivot pin 38 and adjacent to the bar 44. One strand end 54 is retained in a notch 56 adjacent the opening 36 in the bracket 28. The other end 58 of the strand 60 includes an elongated portion captured in an opening 59 (
As best shown in
Referring now to
The bracket 68 also includes spring support flanges 76 and 78 having openings adapted to receive a mounting pin 80. The mounting pin 80 is received in the central opening of a spring bushing. The coil spring 50 includes a bracket engaging end 54 received in a retention groove 86 (
As best shown in
Referring now to
The hinge assembly 108 also includes a laterally coiled spring 50. However, one end 120 of the coiled strand includes an elongated terminal portion that proceeds generally radially outwardly from the center of the coil. A terminal end 121 is bent for engagement in pivot flanges 118 carried by the mount 110. The other end 124 of the coiled strand includes a return portion 122 that extends along a longitudinal direction of the coil, preferably through the interior of the coil, to a position at or near the coil end 120. The longitudinally extended portion 122 is then extended in a direction generally radially away from the center of the coil along a portion 125 toward a retaining end 126. The end 126 is pivotally engaged in pivot axis flanges 128 carried at the end of the pivot link 116. The terminal portions 125 and 120 of the spring 50 join with the pivot link 116 and the mount 110 to form a four bar hinge.
Accordingly, a lid 16 may be mounted to pivot link 116, for example at mounting flange 130, and spring biased upwardly to an open position as shown in
Having thus described preferred embodiments of the present invention, many modifications will become apparent to those skilled in the art to which it pertains without departing from the scope and spirit of the present invention as defined in the appended claims.
This application is a division of U.S. application Ser. No. 10/774,807 filed Feb. 9, 2004.
Number | Date | Country | |
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Parent | 10774807 | Feb 2004 | US |
Child | 11446857 | Jun 2006 | US |