In the following detailed description, reference is made to the accompanying drawings which form a part hereof wherein like numerals designate like parts throughout, and in which is shown by way of illustration specific embodiments in which they may be practiced. It is to be understood that other embodiments may be utilized and structural or logical changes may be made without departing from the scope of the present invention. Therefore, the following detailed description is not to be taken in a limiting sense, and the scope of the present invention is defined by the appended claims and their equivalents.
In the following detailed description, various terms are used to define various elements of a hinge. Other terms are used in the art to reference the same hinge element. Therefore, it is understood that the present invention is not to be limited by the use of a particular term used in reference to a particular hinge element. The following terminology is used throughout the description: a conventional hinge comprises two leaves, namely a stationary leaf and a hinge leaf, which pivot on a single axis of rotation; a leaf consists generally of a mounting portion, such as, but not limited to, a mounting plate, and one or more knuckles; a knuckle comprises an element, generally circular, having a bore adapted to accept a hinge pin, the knuckle extending from a mounting portion of a leaf; a notch is a space between two adjacent knuckles on one leaf into which a knuckle from a second leaf is positioned and interleaved; a stationary leaf is the leaf which is attached to a non-moving structure, such as a door frame; a hinge leaf is a leaf which is attached to a door; and a hinge pin is generally a rod adapted to pass through the bore of the interleaved knuckles of two leaves to join the leaves together.
Embodiments of multi-axis vehicle door hinges are provided that are adapted to facilitate pivotal motion of a vehicle door about a substantially vertical axis of rotation for swing-out rotation, as well as to facilitate pivotal motion of a vehicle door about a substantially horizontal axis of rotation for vertical-lift rotation. Other embodiments of multi-axis vehicle door hinges are provided with means for adjusting the opening angle of the hinge in both the horizontal and vertical axis of rotation.
The first leaf 210 is adapted to be coupled to a hinge mount body surface 52 of a doorjamb 152 as shown in
The multi-axis vehicle door hinge 201, as will be discussed below, provides a combination of swing-out and vertical-lift motion for, among other things, the retrofitting of a conventional single-axis swing-out vehicle door for swing-out and vertical-lift operation. In an embodiment, the door 53 is adapted to open from a closed position in the conventional swing-out rotation about the swing-out hinge 202 within a substantially horizontal plane. At a predetermined angle .alpha. of the door 53 to the vehicle body 51, the door 53 is adapted to rotate upward about the vertical-lift hinge 203 within a substantially vertical plane to a predetermined lift angle .beta. The door 53 is adapted to close by lowering the door 53 to the substantially horizontal orientation and swung-in in the conventional manner.
Referring again to
The first leaf 210 further comprises a recessed portion 218, extending a predetermined distance into the first leaf second side 214. The recessed portion 218 is adapted to receive a portion of the second leaf 220, as will be described below. In another embodiment, the recessed portion 218 is a through hole extending from the first leaf second side 214 to the first leaf first side 213. In yet another embodiment, the first leaf 210 has no recessed portion as defined above.
Referring again to
A lift hub 274 defining a cylindrical shape extends substantially perpendicular from the second leaf first side 225 adjacent the second leaf first end 221 and defining a horizontal axis X substantially transverse to the second swing knuckle bore 295, which is located along the vertical axis Y. The lift hub 274 defines a first half of a lift bearing 269. The lift hub 274 further comprises a threaded bore 277 to receive a fastener 291 therein, as explained further below.
The second leaf second end 222 comprises a bevel portion 241 defined therein. The bevel portion 241 faces the first leaf 210 and prevents rotation of the second leaf 220 greater than a predefined bevel angle .gamma., such as, but not limited to, 20.degree. (degrees), by the impact of the bevel portion 241 with a bevel impact surface 246 on the first leaf second side 214 adjacent the first leaf fourth edge 216. The second leaf second end 222 defines one or more threaded swing-limiting bores 248 extending through to the bevel portion 241. End portions of suitable fasteners 249, such as but not limited to bolts and set screws, adjustably extend beyond the bevel portion 241 to contact the bevel impact surface 246 when the second leaf 220 is at a predetermined swing angle .alpha. to provide adjustability of the extent of the swing angle .alpha. up to the maximum bevel angle .gamma.
In the embodiment of
The arm bore 288 is adapted to receive the lift hub 274 therein in substantially coaxial alignment therewith. The arm bore 288 defines a second half of the lift bearing 269, shown in
The particular shape of the lift arm 237 is chosen suitable for a particular purpose. The goose-neck shape, as shown in
Referring also to
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Referring again to
Referring again to
The length of the lift rotation limiter 440 further defines the range of motion and maximum extent of rotation, of the lift arm 237 about the lift hub 274.
Referring also to
Referring again to
The multi-axis vehicle door hinge 301 further comprises a cap 370 suitable for coupling the arm second end 286 to the lift hub 274, substantially as shown in
It is appreciated that there are a plurality of component modifications and changes suitable for a particular purpose. The previous and following specific embodiments highlight various elements that provide various control over the swing and lift of the multi-axis vehicle door hinge. Though these embodiments show elements in specific combinations, it is appreciated that these and other elements can be used singularly and in combination suitable for a particular purpose.
Referring again to
Referring again to
Referring again to
The lift hinge retention element 320 is an integral or coupled element that extends a predetermined distance, defining angle .delta., from the first leaf second side 214 adjacent the first leaf second edge 212 and the first leaf third edge 215. The lift hinge retention element 320 comprises a first engagement surface 322 adjacent the lift arm 237 when the lift arm 237 is in the down position and the second leaf 220 is in the closed position. The first engagement surface 322 is adapted for cooperative engagement with a first lift arm engagement surface 323 to restrict the function of the vertical-lift feature of the multi-axis vehicle door hinge 301 until the swing angle of the second hinge leaf 420 exceeds angle .delta., and the lift arm 237 clears the lift hinge retention element 320.
The lift hinge retention element 320 terminates at a second engagement surface 325. Once the second hinge leaf 420 exceeds angle .delta., the lift arm 237 is not subject to engagement with the first engagement surface 322 and is free to rotate vertically about the lift hub. When the lift arm 237 is in the rotated position, the lift arm 237 is prevented from moving to a swing angle less than angle .delta. by the cooperative engagement of the lift arm 237 and the second engagement surface 325.
In operation, the door is opened initially from a closed position in the conventional swing-out rotation. At a predetermined swing-out angle .delta., or greater, of the door 53 to the vehicle body 51, as shown in
In another embodiment, the lift hinge retention element 320 comprises a third engagement surface 327 opposite the first engagement surface 322. The lift arm 237 is adapted to rotate upward to an angle .beta. such that the lift arm 237 rotates beyond and clear of the first engagement surface 322 and the second engagement surface 325. The third engagement surface 327 is adapted for cooperative engagement with a lift arm surface, such as, but not limited to, lift arm surface 328, when the third hinge leaf 230 is moved to a position less than angle .delta. while the lift arm 237 is in the up position. While in the up position and at an angle of less than angle .delta., the lift arm 237 engages the third engagement surface 327 restricting downward rotation of the third leaf 230. Thus, the lift hinge retention element 320 is adapted to retain the third leaf 230 in an up position.
The length of the lift hinge retention element 320 extending from the first leaf second side 214, shown in
The multi-axis vehicle door hinge 301 requires an initial swing-out prior to enabling vertical-lift of the door 53, shown in
The initial swing-out of the door 53 provides that all door structures will clear the vehicle body 51 as the door 53 is vertically-lifted, shown in
In other embodiments, the multi-axis vehicle door hinge further comprises torsion control for the vertical lift hinge. Torsion control provides assistance in the operation of the lift arm by providing one or a combination of: return bias for returning the lift arm to the down position; retaining, counterbalancing or equilibrating the lift arm in any position between down and up when released by the user; and biasing the lift arm in the maximum up position. Embodiments of the multi-axis vehicle door hinge further comprise torsion control in the forms of springs, gas struts, and linear actuators, wherein the linear actuators can provide for powered operation.
It is appreciated that the multi-axis vehicle door hinge 201, 301, shown in
It is appreciated that the shape of the knuckles and notches may be varied while retaining the functionality provided by the multi-axis vehicle door hinge 201, 301. For example, but not limited thereto, the knuckle is in the form of one or more extending flanges each having an aperture substantially coaxial with the other, each flange aperture being coaxial with and placed in sliding pivoting engagement with a corresponding flange aperture of a corresponding leaf.
Referring again to
It is contemplated that a wide variety of locations may be used as the hinge mount body surface 52 and the hinge mount door surface 54 as being suitable for a particular purpose. For example, but not limited thereto, the hinge mount door surface 54 is a forward door inner surface. In another embodiment, providing pivoting motion from the rear of the door 53, the hinge mount body surface 52 is a rear portion of the doorjamb 152 and the hinge mount door surface 54 is a rear door edge, providing door opening from the front of the door 53 rather than from the rear.
In an application of the multi-axis vehicle door hinge 201, 301, in accordance embodiments, the first leaf 210 is the stationary leaf coupled to a hinge mount body surface 52 of a doorjamb 152 of a vehicle 50 as shown in
In an embodiment, the first leaf 210 is adapted to facilitate the provision of a plurality of bolt holes 37 extending from the first leaf first side 213 to the first leaf second side 214, such as, but not limited to, those made by the consumer or assembler using a drill. The plurality of bolt holes 37 are located in predetermined locations that correspond to a bolt pattern provided in the hinge mount body surface 52 of the doorjamb 152 of a specific vehicle 50 after the removal of the conventional stock hinge. In another embodiment, the plurality of bolt holes 37 correspond to a new bolt hole pattern provided in the hinge mount body surface 52 of the doorjamb 152 made by the consumer or assembler. One or more bolts (not shown) couple the first leaf 210 to the vehicle 50.
In another embodiment, the first leaf 210 is provided with a plurality of bolt holes 37 in predetermined locations that correspond to a bolt pattern provided in a hinge mount body surface 52 of the doorjamb 152 of one or more specific model of vehicle 50 after the removal of the conventional stock hinge, negating the need for the consumer or assembler to provide the bolt hole pattern in the multi-axis vehicle door hinge 201, 301.
In yet another embodiment, the first leaf 210 is provided with a plurality of elongated bolt holes (not shown) in predetermined locations that correspond to one or more bolt patterns provided in the hinge mount body surface 52 of the doorjamb 152 of one or more specific models of vehicle 50 after the removal of the conventional stock hinge. The elongated bolt holes allow for, among other things, accommodation of mal-aligned bolt hole patterns and applicability across a plurality of models of vehicle.
The specific configuration of the first leaf 210 to permit coupling to a vehicle surface is dependent on a specific vehicle under consideration. Therefore, it is understood that other leaf configurations are anticipated that are adapted to couple to a vehicle's particular body and/or door surface while retaining the mechanical function of a component of a multi-axis vehicle door hinge, as provided herein.
As stated previously, the specific configuration of a first leaf 210 and/or a third leaf 230 to permit coupling to a hinge mount body surface 52 and/or hinge mount door surface 54, respectively, is dependent on the specific vehicle under consideration. Therefore, it is understood that other leaf configurations are anticipated that are adapted to couple to a vehicle's particular body and/or door surface while retaining the mechanical function of the multi-axis vehicle door hinge 201, 301 as provided herein.
Another important consideration, among others, in the retrofitting of conventional swing-out doors with swing-out vertical-lift operation is to provide the ability to adjust or fine tune the operation and alignment of the multi-axis vehicle door hinge. Adjustment and alignment considerations can take many forms, including, but not limited to: strategic placement of the multi-axis vehicle door hinge for proper alt-azimuth location of the vertical and horizontal pivot axis location; means for accommodating misaligned bolt holes; means for adjusting minimum swing-out opening angle α until disengagement of the lift arm 237 and the lift hinge retention element 320; adjustment means for adjusting maximum swing-out opening angle α, and adjustment means for adjusting door alignment with the doorjamb.
In an embodiment, means for accommodating misaligned bolt holes between the bolt holes of the first leaf 210 and the hinge mount body surface 52, and the bolt holes 37 of the third leaf 30 and the hinge mount door surface 54, is provided. As discussed previously, in one embodiment, the bolt holes 37 in the first leaf 210 and/or the third leaf 230 are elongated to facilitate alignment with misaligned bolt holes 37 in the hinge mount body surface 52 and/or hinge mount door surface 54. In another embodiment, the elongated bolt holes 37 further provide the ability to adjust and align the angular position of the multi-axis vehicle door hinge with respect to global horizontal and vertical axes.
Embodiments of a vertical-lift door system provides the assembler or consumer an integrated system of one or more hinges and lift assist devices to provide the operating characteristics of a swing-out vertical-lift door. The lift assist devices provide for, singularly or in combination, among other things, controlled and deliberate movement of the door, power-assisted door operation, and easier integration and assembly onto vehicles during assembly as well as stock vehicles for retrofit applications.
Embodiments of the multi-axis vehicle door hinge provide the ability to make available vertical-lift door operation not only to vehicle manufacturers, but also to the vehicle enthusiast who desires to convert a vehicle from swing-out door operation to vertical-lift operation with a minimum amount of modification to the vehicle.
Although specific embodiments have been illustrated and described herein for purposes of description of the preferred embodiment, it will be appreciated by those of ordinary skill in the art that a wide variety of alternate and/or equivalent implementations calculated to achieve the same purposes may be substituted for the specific embodiment shown and described without departing from the scope of the present invention. Those with skill in the art will readily appreciate that the present invention may be implemented in a very wide variety of embodiments. This application is intended to cover any adaptations or variations of the embodiments discussed herein. Therefore, it is manifestly intended that this invention be limited only by the claims and the equivalents thereof.
This application is a U.S. non-provisional patent application taking priority to U.S. provisional Patent Application 60/828,217, filed Oct. 4, 2006, incorporated herein in its entirety by reference, and is related to U.S. non-provisional patent application Ser. No. 11/691,491, filed Mar. 26, 2007, incorporated herein in its entirety by reference, and related to U.S. non-provisional patent application Ser. No. 11/056,136, now U.S. Pat. No. 7,210,200, filed Feb. 11, 2005, incorporated herein in its entirety by reference, and U.S. non-provisional patent application Ser. No. 10/396,284, now U.S. Pat. No. 7,007,346, filed Mar. 25, 2003, incorporated herein in its entirety by reference.
Number | Date | Country | |
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60828217 | Oct 2006 | US |