Plasma torch and system with electromagnetic shield assist mechanism

What is claimed is: 1. A plasma arc system, the system comprising: a plasma torch, the plasma torch having a torch nozzle with an opening at a distal end for a plasma jet to exit the plasma torch; an electromagnetic shield cap disposed near the distal end of the torch nozzle, the electromagnetic shield cap having an opening that is coaxial with the opening of the torch nozzle; a plasma cutting power source to supply current to the torch to create the plasma jet; a magnetic field power source to provide a current to the electromagnetic shield cap to generate a magnetic field near the plasma jet to focus the plasma jet as the plasma jet exits the torch nozzle; and a controller to synchronize operation of the plasma cutting power source and operation of the magnetic field power source during a transition from a piercing operation that burns through a workpiece to a cutting operation that cuts the workpiece, wherein the magnetic field ramps from a background level value to a peak level value prior to the transition from the piercing operation to the cutting operation and the magnetic field reaches the peak level value at a same time as the transition from the piercing operation to the cutting operation. 2. The plasma arc system of claim 1 , wherein the magnetic field is generated at the opening in the electromagnetic shield cap as the plasma jet passes through the opening in the electromagnetic shield cap. 3. The plasma arc system of claim 2 , wherein the magnetic field generates a pinch or squeezing force on the plasma jet that aids in keeping the plasma jet focused. 4. The plasma arc system of claim 1 , wherein the magnetic field ramp from the background level value to the peak level value is linear. 5. The plasma arc system of claim 1 , wherein a flow of the shield gas to the torch is maintained at a constant flow rate during the transition from the piercing operation to the cutting operation in the plasma arc system. 6. The plasma arc system of claim 1 , wherein a flow of the shield gas to the torch is reduced during the transition from the piercing operation to the cutting operation in the plasma arc system. 7. The plasma arc system of claim 1 , wherein the opening in the electromagnetic shield cap has a length in a range of 0.03 in to 0.5 in. 8. The plasma arc system of claim 1 , wherein the opening in the electromagnetic shield cap has a diameter in a range of 0.0625 in to 0.75 in. 9. The plasma arc system of claim 1 , further comprising: a torch shield disposed between the distal end of the torch nozzle and the electromagnetic shield cap, the torch shield having an opening that is coaxial with the openings of the torch nozzle and the electromagnetic shield cap. 10. The plasma arc system of claim 9 , wherein the opening in the electromagnetic shield cap has a diameter that is larger than a diameter of the opening of the torch shield. 11. The plasma arc system of claim 10 , wherein the opening in the electromagnetic shield cap has a diameter that is in a range of 5 percent to 70 percent larger than a diameter of the opening in the torch shield. 12. The plasma arc system of claim 10 , wherein the opening in the electromagnetic shield cap has a diameter that is in a range of 10 percent to 40 percent larger than a diameter of the opening in the torch shield. 13. The plasma arc system of claim 10 , wherein the torch shield has one of vents and slots and the electromagnetic shield cap has corresponding one of vents and slots that align with the one of vents and slots of the torch shield. 14. The plasma arc system of claim 10 , wherein a gap exists between a majority area of an outer surface of the torch shield and a majority area of an inner surface of the electromagnetic shield cap. 15. The plasma arc system of claim 10 , wherein a majority area of an outer surface of the torch shield and a majority area of an inner surface of the electromagnetic shield cap are in direct contact. 16. The plasma arc system of claim 1 , wherein the magnetic field ramps down from the peak level value to the background level value after the transition ends. 17. A plasma torch assembly, the assembly comprising: an electrode assembly to receive current from a plasma cutting power source to create a plasma jet; a torch nozzle with an opening at a distal end for the plasma jet to exit the torch nozzle; an electromagnetic shield cap disposed near the distal end of the torch nozzle, the electromagnetic shield cap having an opening that is coaxial with the opening of the torch nozzle, the electromagnetic shield cap to receive a current from a magnetic field power source such that a magnetic field is generated near the plasma jet to focus the plasma jet as the plasma jet exits the torch nozzle; and a torch shield disposed between the distal end of the torch nozzle and the electromagnetic shield cap, the torch shield having an opening that is coaxial with the openings of the torch nozzle and the electromagnetic shield cap. 18. The plasma torch assembly of claim 17 , wherein the magnetic field is generated at the opening in the electromagnetic shield cap as the plasma jet passes through the opening in the electromagnetic shield cap. 19. The plasma torch assembly of claim 18 , wherein the magnetic field generates a pinch or squeezing force on the plasma jet that aids in keeping the plasma jet focused. 20. The plasma torch assembly of claim 17 , wherein the opening in the electromagnetic shield cap has a length in a range of 0.03 in to 0.5 in. 21. The plasma torch assembly of claim 17 , wherein the opening in the electromagnetic shield cap has a diameter in a range of 0.0625 in to 0.75 in. 22. The plasma torch assembly of claim 17 , wherein the opening in the electromagnetic shield cap has a diameter that is larger than a diameter of the opening of the torch shield. 23. The plasma torch assembly of 17 , wherein the opening in the electromagnetic shield cap has a diameter that is in a range of 5 percent to 70 percent larger than a diameter of the opening in the torch shield. 24. The plasma torch assembly of claim 17 , wherein the opening in the electromagnetic shield cap has a diameter that is in a range of 10 percent to 40 percent larger than a diameter of the opening in the torch shield. 25. The plasma torch assembly of claim 17 , wherein the torch shield has one of vents and slots and the electromagnetic shield cap has corresponding one of vents and slots that align with the one of vents and slots of the torch shield. 26. The plasma torch assembly of claim 17 , wherein a gap exists between a majority area of an outer surface of the torch shield and a majority area of an inner surface of the electromagnetic shield cap. 27. The plasma torch assembly of claim 17 , wherein a majority area of an outer surface of the torch shield and a majority area of an inner surface of the electromagnetic shield cap are in direct contact. 28. A method of controlling a plasma arc system, the method comprising: providing a plasma gas to a plasma torch; creating a plasma jet in the plasma torch such that the plasma jet exits the plasma torch through an opening in a torch nozzle of the plasma torch; generating a magnetic field in an electromagnetic shield cap disposed near the distal end of the torch nozzle, the electromagnetic shield cap having an opening that is coaxial with the opening of the torch nozzle;