1. Field of the Invention
The present invention relates to model vehicles, such as model trains, and more particularly, to a coupling mechanism for a model train or other model vehicle.
2. Description of Related Art
Various model trains and vehicles are known in the art, which model an actual or imaginary train or vehicle at a reduced scale. Many model trains include a model locomotive driven by an engine. The locomotive is constructed to run on a model railway track. Various types of model tracks may be provided for different kinds of trains. For many trains, a hobbyist may obtain short segments or sections of pre-assembled model track. Track sections may include, for example, straight sections, curve sections having various radii, switches, and junctions. The track sections may be assembled and combined in various ways to construct a model track layout. Various model cars without engines are also available, which may be connected in various ways with one or more model locomotives to form trains.
Model train cars may be coupled together to form a model train using various coupling mechanisms. For instance, drawbar connectors, c-shaped connectors (knuckle couplers), and ball and hitch connectors may be used to connect adjacent train cars together. Some such couplings are generally reliable and easy to couple and decouple. Some obtain higher levels of realism than others. Notwithstanding their advantages, however, couplings for model train cars may be subject to certain disadvantages. In conventional coupling arrangements, the movement of the coupling member in both directions may be limited by the outer structure of the train car. For example, when a train encounters a curve in a model track, the coupling member associated with that train car moves in the direction of the curve. If the radius of the curve is too small, the coupling member may come into contact with the structure of its connected train car. In other words, the range of travel of the coupling member is physically limited by the rigid structure of the train car. A greater range of rotation may be achieved by increasing the length of the coupling drawbar, but this may cause the train cars to be coupled too far away from one another, lending to unrealistic appearance to the train as a whole.
The turning radius of the train may therefore be limited by the coupling member. Model train hobbyists may therefore be limited in their selection of track, and may not be able to construct layouts having curves that have a desired tightness in radius. Large-radius curves, in turn, may disadvantageously require a larger number of track sections to construct, and may cause a track layout to occupy more space than desired. In addition, the constraints imposed by prior-art coupling mechanisms may increase the chance of derailment of the train car, particularly when the train is moving at a relatively high speed.
Accordingly, a need exists for a model train with an improved coupling mechanism that overcomes these and other limitations of the prior art.
The invention provides a reduced-scale model train car with an improved coupling mechanism. A train assembled using cars according to the invention should be able to negotiate tracks having tighter-radius curves than was possible using prior-art coupling mechanisms, without sacrificing a close-coupled appearance.
A model train car in accordance with the present invention comprises a housing shaped to resemble an actual or fanciful train car. The model train further includes a coupling mechanism attached to the model train car. The coupling mechanism comprises a drawbar or other elongated structure connected to a lower frame of the model rail car, having a coupling disposed at a distal end thereof. The coupling is configured to mate with a complementary coupling of an adjacent model car.
The drawbar may be moveably connected to the model rail car. In an embodiment of the invention, the drawbar is connected to the train car using a special sliding and rotating connection structure that permits the drawbar to both rotate and move linearly relative to the rail car. When the model train is traversing a straight section of track, the special connector is configured to retract the drawbar in towards the center of the model car, drawing adjacent cars closer together. When the train is traversing a curve, the connector is configured to both rotate and extend away from the model car. The extending action advantageously provides additional clearance between the coupling at the frame or body of the model car. This additional clearance may permit a greater degree of rotation of the drawbar, and hence, permit the train to negotiate a tighter curve. As the train exits the curve, the drawbar rotates back towards the center of the car and retracts.
In embodiments of the invention, the extending action of the drawbar may not provide the desired degree of rotation between cars. The extending action of the rotating and sliding connector may tend to be limited by design constraints such as available space and range of reliable motion for a cost-effective design. The coupling end of the drawbar may therefore still tend to interfere with the body of the train car near the corners of the car. To lessen such interference and permit greater rotation of the drawbar, segments of the body at the four corners of the car may be configured to be movable via an elastic connection with the body or frame. For example, segments at the corners of the body may be attached to the body via an elastic hinged or sliding connection. When the train negotiates a tight curve, rotational forces on the drawbar push the nearest corner segment outward, permitting greater rotation of the coupling mechanism and hence, adjacent train cars, than would otherwise be possible. As the train straightens out, the drawbar stops pushing on the moveable corner segment, which therefore returns to its rest position under the impetus of a return spring or other elastic member.
It should be apparent that the moveable corner segment of the invention may be implemented entirely separately from the remainder of the coupling mechanism. For example, a standard vehicle frame and coupling mechanism may be fitted to a train car body having moveable corner segments, thereby providing a train car having a coupling mechanism permitting greater rotation than with a prior-art car body. In the alternative, the moveable-corner feature may be implemented partly or wholly in association with the vehicle frame.
A more complete understanding of the model vehicle with coupling mechanism will be afforded to those skilled in the art, as well as a realization of additional advantages and objects thereof, by a consideration of the following detailed description of the preferred embodiment. Reference will be made to the appended sheets of drawings which will first be described briefly.
FIGS. 4A-B are schematic plan views of a coupling arrangement of a model train in accordance with the present invention.
The present invention provides a model vehicle with an improved coupling mechanism, that overcomes the limitations of the prior art. In the detailed description that follows, like element numerals are used to indicate like elements appearing in one or more of the figures.
With reference to
With reference to
In an exemplary embodiment, coupling member 24 comprises a drawbar connector pivotally coupled to car 16. Coupling member 24 may comprise an elongated slot 36 in its distal portion, within which a fixed pin 38 protruding from an underside of frame 23 may be disposed. Pin 38 may be configured to retain member 24, while still permitting it to extend and retract relative to frame 23 and car 16. At the same time coupling member 24 is free to pivot about fixed pin 38.
Coupling mechanism 25 may further comprise a second guide member 40 protruding from member 24 and passing through a V-shaped slot 42 in frame 23. Guide member 40 may comprise a pin, roller, or other suitable guide. Guide member 40 may be disposed within slot 42 so as to be guided as coupling member 24 moves from side-to-side of frame 23, i.e., in a first radial direction 44 relative to longitudinal axis 30, and a second radial direction 46 opposite first radial direction 44. Slot 42 may comprise a V-shaped slot, or other suitable shape such as C-shaped or U-shaped. Slot 42 should be configured such that when car 16 and an adjacent connected car are being pulled and traversing a straight section of track, coupling member 24 is substantially aligned with a central longitudinal axis 30 of car 16, and guide member 40 is located substantially at the vertex or minima 48 of slot 52 furthest from the end 32 of frame 23. At the same time, fixed pin 38 is disposed at or near a first end 50 of elongated slot 36. Accordingly, coupling member 24 is retracted in an axial direction under frame 23 and towards the center of car 16, resulting in a close coupling relative to the adjacent train car.
In comparison, when car 16 and adjacent cars are pulled along a curved portion of track, for example a track curved towards the right, coupling member 24 is urged in a radial direction 46 (i.e., to the right). As train 16 turns, coupling member 24 pivots about and slides along fixed pin 38, such that pin 38 is disposed at or near a right distal end 52 of elongated slot 36. Coupling member 24 therefore extends out from frame 23 in an axial direction. Likewise, when traversing a leftward curve, coupling member 24 moves in a left radial direction 44 and guide member 40 rides outwardly within V-shaped slot 42 towards a left distal end 54 of V-shaped slot 42 near the perimeter of housing 22. Thus, coupling member 24 extends outward from frame 23 and rotates when car 16 and an adjacent car are traversing a curved section of track. As should be apparent from
Optionally, any number of additional or alternative guide mechanisms may be provided, for example, second guide slot 43 in frame 23, cooperating with a guide stud 41 in member 24. The second guide mechanism may assist in smoother operation of the primary guide provided by slot 42 and guide member 40.
Notwithstanding the advantages of the coupling mechanism as described thus far, in some cases the degree of possible rotation may still not be as great as desired. Lower corners of a train car body 22 often extend below the level of lower frame 23, and thus may prevent coupling 24 from rotating to its mechanical limit. The invention therefore provides a method and apparatus for overcoming this limitation, as described below.
With reference to
The invention is not limited to a particular mechanism by which the corner pieces are made moveable. For example, a hinge 58 as shown adjacent to piece 26 in
A first exemplary corner piece 28 is shown in
A second exemplary corner piece 26 is shown in
The present invention thereby provides a close coupling for model trains, without sacrificing the ability of the model train to negotiate curve sections having a relatively tight radius.
Having thus described a preferred embodiment of a model vehicle with an improved coupling mechanism, it should be apparent to those skilled in the art that certain advantages of the within system have been achieved. It should also be appreciated that various modifications, adaptations, and alternative embodiments thereof may be made within the scope and spirit of the present invention. For example, a particular coupling mechanism has been illustrated, but it should be apparent that the inventive concepts described above would be equally applicable to other coupling mechanisms arranged according to the spirit and scope of the invention. The invention is defined by the following claims.
This application claims priority pursuant to 35 U.S.C. § 119(e) to U.S. Provisional Application No. 60/575,594, filed May 28, 2004, which application is specifically incorporated herein, in its entirety, by reference.
Number | Date | Country | |
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60575594 | May 2004 | US |