Dual head pECM

The invention claimed is: 1. A pulsed electrochemical machining system, comprising: a first tool body defining a first tool axis, the first tool body comprising a first electrode defining a first working surface configured to face a workpiece; a second tool body defining a second tool axis, the second tool body comprising a second electrode defining a second working surface configured to face the workpiece; a mechanical system configured to: position the first working surface of the first tool body relative to the workpiece and configured to position the second working surface of the second tool body relative to the workpiece; oscillate the first tool body relative to the workpiece between a closest approach and a most distant point from the workpiece while the second tool body is stationary, and oscillate the second tool body relative to the workpiece between a closest approach and a most distant point from the workpiece while the first tool body is stationary; wherein the first tool body and the second tool body are configured to oscillate at different frequencies; an electrolyte system configured to supply electrolyte to: a first interelectrode gap between the first working surface of the first tool body and a first target surface of the workpiece; a second interelectrode gap between the second working surface of the second tool body and a second target surface of the workpiece; and a power supply configured to generate a pulsed direct current between the first tool body and the workpiece and the second tool body and the workpiece. 2. The pulsed electrochemical machining system of claim 1 , wherein the first tool axis of the first tool body is substantially parallel to the second tool axis of the second tool body. 3. The pulsed electrochemical machining system of claim 1 , wherein the first tool axis of the first tool body is substantially collinear with the second tool axis of the second tool body. 4. The pulsed electrochemical machining system of claim 1 , wherein the first tool axis of the first tool body is disposed at an angle between about 30 degrees and about 60 degrees from the second tool axis of the second tool body. 5. The pulsed electrochemical machining system of claim 1 , wherein a pulse of DC current is delivered to the at least one of the first tool body or the second tool body when the at least one of the first tool body or the second tool body reaches its closest approach, and the at least one of the first tool body or the second tool body does not receive a pulse of DC current when the at least one of the first tool body or the second tool body reaches its most distant point from the workpiece. 6. The pulsed electrochemical machining system of claim 1 , further comprising the workpiece, wherein the workpiece is a coversheet or spar formed of a nickel superalloy. 7. The pulsed electrochemical machining system of claim 1 , wherein the mechanical system comprises at least one mechanical support for the workpiece. 8. The pulsed electrochemical machining system of claim 7 , wherein the mechanical support engages the workpiece at two or fewer points of contact. 9. A method for pulsed electrochemical machining a workpiece, comprising: delivering electrolyte through an electrolyte system into a first interelectrode gap between a first working surface and a first target surface of the workpiece, and into a second interelectrode gap between a second working surface and a second target surface of the workpiece, wherein the first working surface is defined by a first electrode of a first tool body, wherein the second working surface is defined by a second electrode of a second tool body; generating pulsed direct current between the first electrode and the workpiece, and between the second electrode and the workpiece, oscillating the first tool body relative to the workpiece between a closest approach and a most distant point from the workpiece while the second tool body is stationary, and oscillating the second tool body relative to the workpiece between a closest approach and a most distant point from the workpiece while the first tool body is stationary; wherein oscillating the first tool body comprises oscillating the first tool body at a first frequency, and wherein oscillating the second tool body comprises oscillating the second tool body at a second frequency, wherein the first frequency is different than the second frequency. 10. The method for pulsed electrochemical machining a workpiece of claim 9 , further comprising positioning a first tool axis of the first tool body such that it is substantially parallel to a second tool axis of the second tool body. 11. The method for pulsed electrochemical machining a workpiece of claim 9 , further comprising positioning a first tool axis of the first tool body such that it is substantially collinear with a second tool axis of the second tool body. 12. The method for pulsed electrochemical machining a workpiece of claim 9 , wherein a first tool axis of the first tool body is disposed at an angle between about 30 degrees and about 60 degrees from a second tool axis of the second tool body. 13. The method for pulsed electrochemical machining a workpiece of claim 9 , wherein the workpiece is a coversheet or spar formed of a nickel superalloy. 14. The pulsed electrochemical machining system of claim 1 , wherein the second tool body is configured to oscillate at a harmonic frequency of the first tool body. 15. The method for pulsed electrochemical machining a workpiece of claim 9 , wherein the second frequency is a harmonic frequency of the first frequency.