Patent Abstract:
An internally supported cable system control for a bicycle that does not interfere with the steering mechanism and does not require the structural integrity of the bicycle frame to be compromised. In the disclosed internal cable system, the control cables are routed through a passageway in the gooseneck and the bicycle frame to the mechanism or device that they are designed to control. The gooseneck design is unique in that it allows for an unobstructed passageway for the cables to travel into the steering tube and frame, while allowing for both sliding forward and rearward as well as raising and lowering, as desired by the bicycle rider. For aesthetic reasons, a casing may be added to cover the cabling between the control levers and the gooseneck.

Full Description:
[0001]    This patent claims the benefit under 35 USC 119(e) of provisional application No. 60/457,555 filed on Mar. 26, 2003 which is incorporated herein in full by this reference to it. 
     
    
     
       FIELD OF THE INVENTION  
         [0002]    The subject invention relates to internally supporting bicycle control cables, and more specifically to routing control cables through various components of all types of bicycles including, but not limited to, standard, racing and mountain bikes and to headsets for bicycles.  
         BACKGROUND OF THE INVENTION  
         [0003]    Bicycles have been utilized as a means of transportation for over a hundred years and continue to grow in popularity. The mountain bike is one type of bike that has become more and more popular in recent years. These types of bikes are often used in rough terrain.  
           [0004]    Operational or control cables typically extend from control levers, often secured to the bicycle handlebars, used to control both front and back wheel braking capacities and front and back shifting mechanisms such as the front and rear derailleurs. The operational or control cables are normally mounted along the outside of the tubular frame members, with various attachment members, such as clips. The cables can interfere with either the rider or other components of the bicycle, such as tool compartments, which are also attached to the frame exterior. In the case of mountain bikes, externally located cables are susceptible to damage from the surrounding environment, such as tree branches. Further, the cables also detract from the aesthetic appearance of the frame, as they may cover art or graphic logos on the bike frame.  
           [0005]    To eliminate the appearance of cables on the exterior of bicycle frames, prior art attempts have been made to extend the cables through the interiors of tubular frame components. An early example is described in French Patent No. 982,877, which shows a bicycle frame in which the top tube consists of a hollow, tubular member having a forward cable outlet at a location near the head tube socket which is attached to the top tube, and a rearward cable outlet adjacent to the seat mast of the bicycle frame. A later example is described in German Patent Application No. 19712326, where at least one section of the base frame has an extruded profile tube section with at least one channel to accept a cable.  
           [0006]    While the internal cable system of this type of frame eliminates the appearance of the cable on the exterior of the frame components, the forming of several openings along the top tube of a bicycle frame tends to weaken the wall of that tube, which would require either that the tube be made of a strong but heavy material such as steel, or that the tube walls be thickened if made of a relatively light material which would also add to the overall weight of the frame.  
           [0007]    A more recent example of an internal cable routing system can be found in U.S. Pat. No. 5,478,100, where the cables are located inside of the top tube or down tube. However, the cables are still exposed from the brake or shift levers until they are routed into the frame some distance away.  
           [0008]    In U.S. Pat. No. 4,768,798, the cables are routed directly into the frame at a point in front of the steering axis. In this case, the cables are also exposed until they reach the frame. In addition, the complexity of the steering tube is increased so that the cables can be routed through the tube and not interfere with the steering mechanism.  
           [0009]    In recent years, it has also become recognized that the old-fashioned stationary handlebar and stem bicycle configuration can cause health problems such as lower back pain and wrist pain, due to the crouched body position necessary during bike riding. Many issued patents claim bicycle handlebars or stems that can be adjusted in one manner or another. U.S. Pat. Nos. 5,133,224, 5,273,302, 5,456,135, 5,727,427 and 5,737,967 describe various systems for adjusting bicycle handlebars or bicycle stems. However, these prior art adjustable handlebar stems would interfere with any internal cable routing system.  
           [0010]    Accordingly, there is a need for an internal cable system for a bicycle frame that does not interfere with the steering mechanism and does not compromise the structural integrity of the tubes housing the cable, while permitting adjustable handlebars or stems.  
         SUMMARY OF THE INVENTION  
         [0011]    In one aspect, the present invention is an internal control cabling system that does not interfere with the steering mechanism and does not compromise the structural integrity of the bicycle frame. In the disclosed internal control cable system, the control cables are routed through the interiors of the handlebar stem or gooseneck and, optionally, one or more parts of the bicycle frame, such as a head or steering tube, to the mechanism or device that they are designed to control. The headset design is unique in that it allows for one or more of, an unobstructed passageway for the cables to travel into the steering tube of the frame; sliding of the handlebar forward or rearward; raising and lowering of the handlebar, as desired by the bicycle rider. For aesthetic reasons, a casing can be added to cover the cabling between the control levers and the gooseneck. In other aspects, the invention provides one or more parts for a headset such as a fork with a fork yoke, a handlebar stem adapted to be inserted into the fork yoke and a handlebar adapted to be attached to the handlebar stem. Connections between these components permit internal passageways in the handlebar stem and fork yoke to remain open or permit the arrangement of at least one of these components to be adjusted relative to another. The description above is intended only to introduce the reader to the invention and other aspects of the invention may lie in a combination or sub-combination of elements described above or in other parts of this patent, or as described in the claims. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0012]    Other advantages of the present invention will be readily appreciated as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings of an exemplary embodiment wherein:  
         [0013]    [0013]FIG. 1 is a side view of a bicycle, which illustrates the preferred embodiment of the invention;  
         [0014]    [0014]FIG. 2 is an isometric view of the handle bar and stem gooseneck assembly without the casing;  
         [0015]    [0015]FIG. 3 is a side view of the handle bar and stem gooseneck assembly without the casing;  
         [0016]    [0016]FIG. 4 is a cross-sectional view of the handle bar and stem gooseneck assembly similar to that of FIG. 3, illustrating the internal cabling; and  
         [0017]    [0017]FIG. 5 is an isometric view of the handlebars and stem gooseneck, fully assembled with the casing. 
     
    
     DETAILED DESCRIPTION OF THE INVENTION  
       [0018]    Referring to the Figures, wherein like numerals indicate like or corresponding parts throughout the several views, the preferred embodiment of the invention consists of a bicycle  100  having a frame  26  that includes a head tube or steering head  6  that is adapted to receive a handlebar stem  2  in its upper end  70  and a fork stem or yoke  12  of a fork  14  through its lower end  72 . In the preferred embodiment, the handlebar stem  2  is adjustable and may be referred to as a “gooseneck”. The particular gooseneck  2  described herein is an open-ended tube bent so that, with a first end  16  of the gooseneck  2  oriented substantially vertically, a second end  18  of the gooseneck  2  is at an angle from the vertical of greater than  45  degrees. In a preferred embodiment, the angle between the two ends  16 ,  18  of the handlebar stem is substantially 90 degrees, or perpendicular.  
         [0019]    As best seen in FIG. 4, but with reference to the other Figures, the bicycle  100  has a headset  50  that includes the fork  14 , handlebar stem  2 , handlebar  1 , connectors between those components and connectors between the headset  50  and the head tube  6 . The head tube  6  has a counter bore  52  on each of its upper and lower ends, each counter bore  52  holding a bearing assembly  54 . A fork ring  11  is fitted over a bottom end  58  of the fork yoke  12  and rests on a fork bridge  15 . The fork  14  slides into the lower end  70  of the head tube  6  so that the fork bridge  15  bears on the fork ring  11  which in turn bears on the lower bearing assembly  54 . The fork bridge  15  is attached to the outside of the fork yoke  12  so as to not close an opening in the bottom end  58  of the fork yoke  12  to an internal passageway  56  through the fork yoke  12 . The top end  60  of the fork yoke  12  protrudes above the upper end  70  of the head tube  6  and is externally threaded and split with two longitudinal slits (not labeled). The top end  60  of the fork yoke  12  is open and receives the first end  16  of the handlebar stem  2 . A head locking collar  30  is internally threaded and screwed onto the upper end  70  of the fork yoke  12 . An abutment  74  on the bottom of the head locking collar  30  bears on the bearing assembly  54  in the upper end  70  of the head tube  6  to compress the bearing assemblies  54  and hold the fork  14  in the head tube  6 . Head locking collar  30  is split with a vertical slit that may be closed with a head collar bolt  31 . When the head collar bolt  31  is tightened, the slits in both head locking collar  30  and the top end  60  of the fork yoke  12  are closed. This compresses the top end  60  of the fork yoke  12  about the first end  16  of the handlebar stem  2 . In this way, the fork  14  and handlebar stem  2  are frictionally connected together without closing an internal passageway  62  through the handlebar stem  2  or the internal passageway  56  through the fork yoke  12 . The head locking collar  30  is also secured in position on the fork yoke  12  to preserve the desired compression on the bearing assemblies  54 .  
         [0020]    As best seen in FIGS. 2, 3 and  4 , the handlebar stem or gooseneck  2  and handle bar  1  are attached by a handle bar locking collar  5 , which is tightened by means of a handle bar collar bolt  10 . The proposed arrangement has the advantage of allowing the handle bar  1  to have up/down and fore/aft adjustment to suit a variety of rider sizes and preferences. Referring to FIG. 3, if head collar bolt  31  is loosened in order to free head locking collar  30 , then the handle bar  1  and gooseneck  2  assembly can be moved in the direction of the axis of steering head  6 , that is substantially in the vertical or up/down direction. If the handle bar collar bolt  10  is loosened, then the handle bar locking collar  5  will loosen such that the handle bar  1  can be moved along the gooseneck  2 , providing for substantially fore/aft adjustment of the handle bar  1 . The handle bar locking collar  5  connects to the outside of the handlebar stem  2  and so does not close the open second end  18 , or the internal passageway  62  of the handlebar stem  2  which may extend forward beyond handle bar locking collar  5 .  
         [0021]    In the preferred embodiment, first control cable  8 , which controls the front derailleur  25 , is controlled by first lever  7 . Second control cable  9 , which controls the rear brake  24 , is controlled by second lever  28 . The cables pass through the bent stem gooseneck  2 . The cables  8 ,  9  pass out of the bottom of the gooseneck  2 , such that the gooseneck  2  acts as a cable conduit, and also out of the bottom of the steering head  6 . The cables  8 ,  9  are then routed into the frame  26  of the bicycle  100  through opening  21 . It is obvious to someone skilled in the art that multiple openings could be used on the gooseneck  2  or the frame  26 . The cables  8 ,  9  are then routed through the frame  26  to the mechanism or device that they are meant to control.  
         [0022]    In the disclosed embodiment, first control cable  8  is routed into the interior of stem gooseneck  2 , steering head  6  and then through the interior of frame  26  via an entrance hole  21 , and exits through opening  22 , where the cable  8  is then attached to its associated control mechanism, the front derailleur  25 . Similarly, the second control cable  9  is routed into the interiors of stem gooseneck  2 , steering head  6  and then through the interior of frame  26  via an entrance hole  21 , and exits through opening  23 , where it is attached to its associated control mechanism, the rear brake  24 . The control cables  8 ,  9  are able to pass through the gooseneck  2  unhindered and without interfering with the steering mechanism, as the gooseneck  2  is essentially an open cable conduit. In passing from the down tube to the seat tube of the frame  26 , the cables  8 ,  9  may exit the frame  26  through an additional opening in the down tube and re-enter the frame  26  through an additional opening in the seat tube. Alternately, the cables  8 ,  9  may pass through the interior of the bottom bracket of the frame  26  or a portion of the down tube or seat tube extending outside of the bottom bracket.  
         [0023]    For aesthetic reasons, the handle bar  1 , gooseneck  2  and cables  8 ,  9  in the region of the handle bar  1 , may be covered with a casing  27  as illustrated in FIG. 5. In this embodiment, the casing  27  is constructed in a clamshell manner having both an upper half  41  and lower half  42 . The two halves  41 ,  42  can be secured to the handlebar  1  by bolting the two halves  41 ,  42  together around the handlebar  1 , for example. Any other suitable means may be used, including bonding, welding, or riveting the halves together. Alternately, the casing  27  can be attached to the handlebar  1  and handlebar stem  2  directly or by means of intermediate brackets or components.  
         [0024]    In a further embodiment, additional accessories can be added to the casing  27 , such as a speedometer  29 , as shown in FIG. 5. Optionally, any cables associated with the speedometer  29  can be routed through the gooseneck  2  and either into the frame  26  or down the front forks  14  to the speedometer sensor, not shown.  
         [0025]    While the form of apparatus described herein constitutes a preferred embodiment of this invention, it is to be understood that the invention is not limited to this precise form of apparatus. For example, additional control cables, levers and derailleurs, brakes, electric wires, or other systems can be included. The frame  26  may also be a different sort of frame, such as a monocoque frame. The components of the headset  50  may be modified in various ways. Further, the casing  27  may not be a clamshell design. These and other modifications may still be within the scope of the invention protected by this patent which is defined by the following claims.

Technology Classification (CPC): 1