Large diameter travelling pipe cutter

The invention claimed is: 1. A pipe machining apparatus adapted to perform at least one of cutting and beveling a hollow vessel while traveling around the hollow vessel, the pipe machining apparatus comprising: a frame including a top end and a bottom end, wherein the bottom end is opposed to the top end and is adjacent an outer surface of the hollow vessel; a cable wrapped around the hollow vessel; a pair of rollers coupled to the frame with each roller defining a groove therein for receiving the cable, wherein each roller rotates about an axis that extends generally parallel to a central longitudinal axis of the hollow vessel, wherein the cable is positioned in each groove of the pair of rollers and each axis is positioned between the cable and the outer surface of the hollow vessel, and wherein the cable is tensioned to provide a force on the frame in a direction toward the outer surface of the hollow vessel; and a pair of guides coupled to the frame, wherein the cable is inserted through the pair of guides. 2. The pipe machining apparatus of claim 1 , wherein the hollow vessel is a generally cylindrical hollow vessel. 3. The pipe machining apparatus of claim 1 , further comprising a magnet coupled to the frame and moveable from a first position, in which the magnet is adjacent the bottom end of the frame and engages the outer surface of the hollow vessel, to a second position, in which the magnet is away from the bottom end of the frame and is disengaged from the outer surface of the hollow vessel. 4. A pipe machining apparatus adapted to perform at least one of cutting and beveling a hollow vessel while traveling around the hollow vessel, the pipe machining apparatus comprising: a frame including a top end and a bottom end, wherein the bottom end is opposed to the top end and is adjacent an outer surface of the hollow vessel; a cable wrapped around the hollow vessel; and a pair of rollers coupled to the frame with each roller defining a groove therein for receiving the cable, wherein each roller rotates about an axis that extends generally parallel to a central longitudinal axis of the hollow vessel, wherein the cable is positioned in each groove of the pair of rollers and each axis is positioned between the cable and the outer surface of the hollow vessel, and wherein the cable is tensioned to provide a force on the frame in a direction toward the outer surface of the hollow vessel; wherein the cable is positioned over the frame such that the frame is between the cable and the outer surface of the hollow vessel. 5. A pipe machining apparatus adapted to perform at least one of cutting and beveling a hollow vessel while traveling around the hollow vessel, the pipe machining apparatus comprising: a frame including a top end and a bottom end, wherein the bottom end is opposed to the top end and is adjacent an outer surface of the hollow vessel; a cable wrapped around the hollow vessel; a pair of rollers coupled to the frame with each roller defining a groove therein for receiving the cable, wherein each roller rotates about an axis that extends generally parallel to a central longitudinal axis of the hollow vessel, wherein the cable is positioned in each groove of the pair of rollers and each axis is positioned between the cable and the outer surface of the hollow vessel, and wherein the cable is tensioned to provide a force on the frame in a direction toward the outer surface of the hollow vessel; and a tension interface cable assembly connected with each end of the cable, wherein the tension interface cable assembly includes a chain connected with the cable at one end and sprockets adjustably connected with a series of shafts formed on a lever tension interface at an opposing end, and wherein an overall length of the lever tension interface is adjustable using a tensioning lever. 6. A pipe machining apparatus adapted to perform at least one of cutting and beveling a hollow vessel while traveling around the hollow vessel, the pipe machining apparatus comprising: a frame including a top end and a bottom end, wherein the bottom end is opposed to the top end and is adjacent an outer surface of the hollow vessel; a cable wrapped around the hollow vessel; a pair of rollers coupled to the frame with each roller defining a groove therein for receiving the cable, wherein each roller rotates about an axis that extends generally parallel to a central longitudinal axis of the hollow vessel, wherein the cable is positioned in each groove of the pair of rollers and each axis is positioned between the cable and the outer surface of the hollow vessel, and wherein the cable is tensioned to provide a force on the frame in a direction toward the outer surface of the hollow vessel; a drive mechanism including a drive shaft; a cutting tool coupled to the drive shaft for rotating the cutting tool; and a center mount plunge feed system including a self-locking worm drive adapted to move the cutting tool and the drive shaft in a first direction away from the outer surface of the hollow vessel and a second direction towards the outer surface of the hollow vessel; wherein the center mount plunge feed system is located under a top plate of the frame, and wherein the center mount plunge feed system includes an adjustment mechanism coupled to the self-locking worm drive and projecting from a side of the frame. 7. A pipe machining apparatus adapted to perform at least one of cutting and beveling a hollow vessel while traveling around the hollow vessel, the pipe machining apparatus comprising: a frame including a top end and a bottom end, wherein the bottom end is opposed to the top end and is adjacent an outer surface of the hollow vessel; a cable wrapped around the hollow vessel; a drive mechanism coupled to the frame and including a drive shaft; and a driven member coupled to the frame and defining a groove therein, wherein the cable is positioned in the groove, wrapped around the driven member, and tensioned, wherein the driven member is coupled to the drive mechanism via the drive shaft which is adapted to rotate the driven member in either a clockwise direction or a counterclockwise direction, and wherein the driven member is adapted to move the frame along the outer surface of the hollow vessel in a first direction corresponding to rotation of the driven member in the clockwise direction and in a second direction, opposite the first direction, corresponding to rotation of the driven member in the counterclockwise direction. 8. The pipe machining apparatus of claim 7 , wherein the driven member rotates about an axis generally perpendicular to a central longitudinal axis of the hollow vessel. 9. The pipe machining apparatus of claim 7 , wherein the hollow vessel is a generally cylindrical hollow vessel. 10. The pipe machining apparatus of claim 7 , wherein the cable is positioned over the frame such that the frame is between the cable and the outer surface of the hollow vessel. 11. The pipe machining apparatus of claim 7 , wherein the drive mechanism is a first drive mechanism and the drive shaft is a first drive shaft, the pipe machining apparatus further comprising: a second drive mechanism including a second drive shaft; a cutting tool coupled to the second drive shaft for rotating the cutting tool; and a center mount plunge feed system including a self-locking worm drive adapted to move the cutting tool and the second drive shaft in a first direction away from the outer surface of the hollow vessel and a second direction towards the outer surface of the hollow vessel. 12. A pipe machining apparatus adapted to perform at least one of cutting and beveling a hollow vessel whil