Thermal torch lead gas delivery methods and related systems and devices

What is claimed: 1. A method of initiating a plasma arc in a plasma cutting system, the method comprising: providing a plasma gas supply lead line extending between a power supply and a plasma arc cutting torch, the lead line comprising a first segment proximate to the power supply and a second segment proximate to the torch, and an in-line valve within the lead line between the first segment and the second segment; closing the in-line valve, by a controller, to capture a static volume of gas in the first segment; establishing a volume of gas in the second segment having a decaying pressure; and initiating the plasma arc when the decaying pressure of the volume of gas in the second segment reaches a pressure value within a predetermined range while the in-line valve remains closed. 2. The method of claim 1 wherein the first segment and the second segment are a part of a hose that carries a pilot gas flow and cutting gas flow. 3. The method of claim 1 further comprising changing the pressure of the gas through the plasma gas supply lead line to the plasma arc cutting torch in a controlled manner to establish a gas flow rate for plasma cutting after initiation of the arc. 4. The method of claim 1 further comprising connecting a plurality of gas sources to the plasma arc cutting torch through a plurality of plasma gas supply lines, each plasma gas supply line having an in-line solenoid valve. 5. The method of claim 1 further comprising controlling the in-line valve with a digital signal processor that provides an output to the in-line valve, such that the in-line valve is controlled based on the output from the digital signal processor. 6. The method of claim 1 , wherein the initiating step is followed by the steps of: changing one of the in-line valve or a supply valve to a first position thereby adjusting a flow of the gas to the plasma arc cutting torch; establishing a cutting pressure in the second segment after a transient pressure in the second segment increases to a cutting pressure level; and increasing a plasma arc current to a pre-determined level. 7. The method of claim 1 , wherein a first position of the in-line valve is open and a second position of the in-line valve is closed, further comprising: measuring a first time for the pressure in the second segment to reach a proportion of a set value for a first known length and inner diameter of the gas in the plasma gas supply lead line; measuring a second time for the pressure in the second segment to reach a proportion of a set value for a second known length and inner diameter of the plasma gas supply lead line; and calculating a length of the plasma gas supply lead line based on the difference between the second time and the first time, wherein the difference between the second time and the first time is proportional to the difference between the amount of gas in the second known length and the first known length of the plasma gas supply lead line. 8. The method of claim 1 , further comprising the steps of: changing the in-line valve to a first position thereby increasing a flow of the gas to the plasma arc cutting torch such that a transient pressure in the second segment increases prior to pressure dissipation through a plasma chamber of the plasma arc cutting torch; and igniting the plasma arc cutting torch when the transient pressure in the second segment reaches a value within the predetermined range. 9. A plasma cutting system comprising: a power supply; a torch; a plasma gas supply lead line extending from a gas supply to the torch and comprising a first segment proximate to the power supply and a second segment proximate to the torch; an in-line valve positioned in the lead line between the first segment and the second segment; and a controller configured to control a position of the in-line valve, the controller being programmed to execute a sequence comprising: i) closing the in-line valve to capture a static volume of gas in the first segment; ii) establishing a volume of gas in the second segment having a decaying pressure; and iii) initiating a plasma arc when the decaying pressure of the volume of gas in the second segment reaches a pressure value within a predetermined range while the in-line valve remains closed. 10. The plasma cutting system of claim 9 further comprising a pressure sensor in the second segment of the plasma gas supply lead line. 11. The plasma gas cutting system of claim 9 wherein the first segment and the second segment are a part of a hose that provides a pilot gas flow and cutting gas flow to the plasma cutting system. 12. The plasma cutting system of claim 9 wherein the controller is programmed to change the pressure of the gas through the plasma gas supply line to the plasma arc torch in a controlled manner to establish a flow rate for cutting after initiation of the arc. 13. The plasma cutting system of claim 12 wherein the controller is programmed to terminate a plasma arc when a transient second pressure reaches a predetermined pressure level. 14. The plasma cutting system of claim 9 further comprising means for connecting a plurality of gas sources to the plasma arc torch through a plurality of plasma gas supply lines and a plurality of in-line solenoid valves. 15. A method for operating a plasma torch system, the plasma torch system including a plasma power supply coupled to a torch by a lead line, an in-line valve located in the lead line and a section of the lead line between the in-line valve and the torch defining an off-valve hose segment, the method comprising: supplying a gas to the torch through the lead line; closing the in-line valve to establish a volume of gas having a decaying pressure in the off-valve hose segment; and initiating a plasma arc in the torch when a pressure of the gas at the torch reaches a pressure value within a predetermined range by: enabling a pressure of a volume of gas captured between the in-line valve and the torch to dissipate to the pressure value; or opening the in-line valve to release a volume of gas trapped between an upstream regulator valve and the in-line valve, and enabling a pressure of the gas in the off-valve segment to increase to the pressure value. 16. The method of claim 15 further comprising the step of: closing the in-line valve to allow a pressure of a volume of gas captured in the off-valve hose segment to decay at a selected rate while ramping down a plasma arc current in conjunction with the decaying pressure. 17. The method of claim 15 further comprising changing the pressure of the gas through the plasma gas supply line to the torch in a controlled manner to establish a flow rate of gas for cutting after initiation of the arc. 18. The method of claim 15 , wherein the initiating step further comprises: changing one of the in-line valve or a supply valve to a first position thereby adjusting the flow of the gas to the torch; establishing a cutting pressure when a transient second pressure increases to a cutting pressure level; and increasing an arc current to a pre-determined level. 19. The method of claim 18 , wherein a lower pressure value of the predetermined range is about 9 psi and an upper pressure value of the predetermined range is about 50 psi. 20. The method of claim 15 further comprising connecting a plurality of gas sources to the plasma arc torch through a plurality of plasma gas supply lines each having a dedicated in-line solenoid valve. 21. The method of claim 15 further com