Shaft mechanical lock for pipeline isolation tools

What is claimed is: 1. A mechanical lock unit of a pipeline isolation tool comprising: a teeth-form ring for surrounding a shaft, said teeth-form ring having a first end, a second end, a longitudinal axis, and an outer surface, said outer surface defining a plurality of teeth thereon; a teeth-form split gripper assembly surrounding said teeth-form ring, said teeth-form split gripper assembly having at least a first teeth-form split gripper, a second teeth-form split gripper, and a spring between said first teeth-form split gripper and said second teeth-form split gripper for biasing said first teeth-form split gripper away from said second teeth-form split gripper, said first teeth-form split gripper and said second teeth form split gripper defining an inner surface, said inner surface defining a plurality of teeth for cooperative engagement with said plurality of teeth of said teeth-form ring. 2. The mechanical lock unit according to claim 1 wherein: said teeth-form ring has a first part and a second part for facilitating installation on a shaft. 3. The mechanical lock unit according to claim 2 further comprising: a connector for joining said first part and said second part of said teeth-form ring. 4. The mechanical lock unit according to claim 1 wherein: said teeth-form ring defines a slot for receiving a bolt for slidably retaining said teeth-form ring on a shaft. 5. The mechanical lock unit according to claim 4 wherein said bolt is threadably received in a threaded hole in said shaft. 6. The mechanical lock unit according to claim 1 wherein said plurality of teeth on said teeth form ring and said plurality of teeth on said teeth form split gripper assembly are parallel for allowing full rotation of said teeth-form split gripper assembly with respect to said teeth-form ring without losing engagement. 7. The mechanical lock unit according to claim 1 wherein: said teeth-form split gripper assembly has an outer surface that defines at least one ramp; and further comprising a lock piston located for sliding parallel to said longitudinal axis, said lock piston having a ramped portion defining an inside surface for selective engagement with said at least one ramp on said outer surface of said teeth-form split gripper assembly for selectively pressing said teeth-form split gripper assembly into contact with said teeth-form ring. 8. The mechanical lock unit according to claim 7 , wherein, the outer surface of the teeth-form gripper assembly includes a flat run adjacent to the at least one ramp; and the inside surface of the lock piston includes a corresponding flat run portion adjacent to the ramped portion. 9. A pipeline isolation tool comprising: a shaft having a plug cylinder affixed thereto; a packer activated by hydraulic pressure used to move said plug cylinder and said shaft; a mechanical lock unit for securing a position of said shaft, said mechanical lock unit comprising a teeth-form ring for surrounding said shaft, said teeth-form ring having a first end, a second end, a longitudinal axis, and an outer surface, said outer surface defining a plurality of teeth thereon; a teeth-form split gripper assembly surrounding said teeth-form ring, said teeth-form split gripper assembly having at least a first teeth-form split gripper, a second teeth-form split gripper, and a spring between said first teeth-form split gripper and said second teeth-form split gripper for biasing said first teeth-form split gripper away from said second teeth-form split gripper; said first teeth-form split gripper and said second teeth form split gripper defining an inner surface, said inner surface defining a plurality of teeth for cooperative engagement with said plurality of teeth of said teeth-form ring. 10. The mechanical lock unit according to claim 9 wherein: said teeth-form ring has a first part and a second part for facilitating installation on said shaft. 11. The mechanical lock unit according to claim 10 further comprising: a connector for joining said first part and said second part of said teeth-form ring. 12. The mechanical lock unit according to claim 9 wherein: said teeth-form ring defines a slot for receiving a guide pin for slidably retaining said teeth-form ring on a shaft for limiting axial travel of said teeth-form ring on the shaft. 13. The mechanical lock unit according to claim 9 wherein said plurality of teeth on said teeth form ring and said plurality of teeth on said teeth form split gripper assembly are parallel for allowing full rotation of said teeth-form split gripper assembly with respect to said teeth-form ring without losing engagement. 14. The mechanical lock unit according to claim 9 wherein: said teeth-form split gripper assembly has an outer surface that defines at least one ramp; and further comprising a lock piston located for sliding parallel to said longitudinal axis, said lock piston having a ramped portion defining an inside surface for selective engagement with said at least one ramp on said outer surface of said teeth-form split gripper assembly for selectively pressing said teeth-form split gripper assembly into contact with said a teeth-form ring. 15. The mechanical lock unit according to claim 14 , wherein, the outer surface of the teeth-form gripper assembly includes a flat run adjacent to the at least one ramp; and the inside surface of the lock piston includes a corresponding flat run portion adjacent to the ramped portion. 16. A method of securing a pipeline isolation tool in a pipeline comprising: moving a piston for actuating the isolation tool, said piston affixed to a shaft; extending a slip assembly to engage a wall of the pipeline; extending a packer to engage the wall of the pipeline for creating a high pressure on a high pressure side of the isolation tool and a low pressure on a low pressure side of the isolation tool; engaging said shaft with a mechanical lock; compressing a compression spring with said high pressure by moving said cylinder towards said low pressure side; wherein said moving of said cylinder increases a set volume, which lowers a set pressure for effecting a self-lock mode. 17. The method according to claim 16 wherein: said mechanical lock comprises a teeth-form ring for surrounding said shaft, said teeth-form ring having a first end, a second end, a longitudinal axis, and an outer surface, said outer surface defining a plurality of teeth thereon; a teeth-form split gripper assembly surrounding said teeth-form ring, said teeth-form split gripper assembly having at least a first teeth-form split gripper and a second teeth-form split gripper, said first teeth-form split gripper and said second teeth form split gripper defining an inner surface, said inner surface defining a plurality of teeth for cooperative engagement with said plurality of teeth of said teeth-form ring. 18. Th method according to claim 17 , wherein the mechanical lock further comprises: a spring between said first teeth-form split gripper and said second teeth-form split gripper for biasing said first teeth-form split gripper away from said second teeth-form split gripper. 19. The method according to claim 17 , wherein: said teeth-form split gripper assembly has an outer surface that defines at least one ramp; and wherein the mechanical lock further comprises: a lock piston located for sliding parallel to said longitudinal axis, said lock piston having a ramped portion defining an inside surface for selective engagement with said at least one ramp on said