Work piece condition detection using flame electrical characteristics in oxy-fuel thermal processing equipment

The invention claimed is: 1. An oxy-fuel thermal processing system, comprising: a torch; a power source; a driver coupled between a first surface of the torch and a second surface of a workpiece, the driver configured to drive the power source to provide a driven power source between the first surface and the second surface, the first surface and the second surface exposed to a flame of the torch during a thermal cutting process; a sensor coupled between the first surface and the second surface, the sensor configured to sense an electric response to the driven power source and provide a sensed electric response; a microprocessor in communication with the driver and the sensor, the microprocessor configured to: receive information about the driven power source and the sensed electric response, calculate a slope of a current-voltage (I-V) relationship associated with a thermal process of the oxy-fuel thermal processing system based on the information about the driven power source and the sensed electric response, determine if the slope is a maximum value in the I-V relationship, and in response to determining that the slope is not the maximum value in the I-V relationship, instruct adjustment of a gas mixture associated with the thermal cutting process; and a switch, controlled by the microprocessor, connecting the torch to ground when the oxy-fuel thermal cutting process is not in operation. 2. The oxy-fuel thermal processing system of claim 1 , wherein the microprocessor is further configured to calculate a first parameter based on the information about the driven power source and the sensed electric response. 3. The oxy-fuel thermal processing system of claim 2 , wherein the first parameter is representative of whether the flame is lit. 4. The oxy-fuel thermal processing system of claim 3 , wherein the first surface is a probe located a predetermined distance from the torch. 5. The oxy-fuel thermal processing system of claim 4 , wherein the probe comprises an ignition system. 6. The oxy-fuel thermal processing system of claim 2 , wherein the power source is a current, the sensor is a voltage sensor, and the microprocessor is configured to calculate the first parameter while thermal processing of the workpiece is being performed. 7. The oxy-fuel thermal processing system of claim 2 , wherein the power source is a voltage, the sensor is a current sensor, and the microprocessor is configured to calculate the first parameter while thermal processing of the workpiece is being performed. 8. The oxy-fuel thermal processing system of claim 1 , further comprising a computer numerical control (CNC) machine connected to the torch, wherein the first surface is movable with respect to the second surface, and wherein the microprocessor is further configured to calculate a distance between the first surface and the second surface based on information about the driven power source and the sensed electric response, to determine if the distance is within a predetermined range, and in response to determining that the distance is outside the predetermined range, to instruct the CNC machine to adjust a height of the torch. 9. The oxy-fuel thermal processing system of claim 8 , wherein the microprocessor is further configured to start the flame of the torch by: instructing the CNC machine to move the torch away from the workpiece such that the first surface is not in contact with the second surface; directing the power source to charge an energy storage device associated with the torch; instructing the CNC machine to move the torch toward the workpiece; and directing the energy storage device to discharge while directing the torch to supply an ignition gas to a gap between the first surface and the second surface. 10. The oxy-fuel thermal process system of claim 1 , wherein the microprocessor is further configured to detect whether a flame is started by determining whether there is an electric response to a test current driven by the driver. 11. The oxy-fuel thermal process system of claim 1 , wherein the first surface and the second surface have the same geometry and comprise the same material, and wherein the first surface and the second surface are positioned in the flame in a symmetric relationship with respect to the torch. 12. The oxy-fuel thermal process system of claim 1 , wherein the microprocessor is further configured to calculate a temperature of the workpiece based on the information about the driven power source and the sensed electric response, to determine if the temperature reaches a predetermined level, and in response to determining that the temperature reaches the predetermined level, to initiate a cutting process for the workpiece. 13. The oxy-fuel thermal processing system of claim 12 , wherein, after the cutting process is initiated, the microprocessor is further configured to calculate a second temperature of the workpiece based on information about a second driven power source and a second sensed electric response, to determine if the second temperature falls below the predetermined level, and in response to determining that the second temperature falls below the predetermined level, to stop the cutting process for the workpiece. 14. The oxy-fuel thermal processing system of claim 13 , wherein, after the cutting process for the workpiece is stopped, the microprocessor is further configured to wait until a predetermined time is elapsed and then calculate a third temperature of the workpiece based on information about a third driven power source and a third sensed electric response, to determine if the third temperature reaches the predetermined level, and in response to determining that the temperature reaches the predetermined level, to resume the cutting process for the workpiece. 15. The oxy-fuel thermal processing system of claim 2 , wherein the first parameter is representative of imminent cut loss. 16. The oxy-fuel thermal processing system of claim 2 , wherein the first parameter is representative of a cut quality. 17. The oxy-fuel thermal processing system of claim 1 , wherein the microprocessor is further configured to calculate an extrapolation based on information about a plurality of driven power sources and sensed electric responses to determine a zero distance between the first surface and the second surface.