Fluid jet cutting systems

The invention claimed is: 1. A fluid jet cutting system, comprising: a fluid jet cutting head having an orifice to generate a high pressure fluid jet and a fluid jet outlet from which to discharge the high pressure fluid jet; a jet receiving receptacle to receive the high pressure fluid jet after the high pressure fluid jet passes through a workpiece during a workpiece processing operation; and a support structure to support the jet receiving receptacle, the support structure including a drive system to selectively adjust an angular orientation of the jet receiving receptacle relative to a fluid jet axis defined by the fluid jet outlet of the fluid jet cutting head such that the jet receiving receptacle can be tilted relative to the fluid jet axis at least during a portion of the workpiece processing operation. 2. The fluid jet cutting system of claim 1 , further comprising: a motion system coupled to the fluid jet cutting head to controllably manipulate the fluid jet cutting head in space. 3. The fluid jet cutting system of claim 1 wherein the support structure includes a vertical adjustment mechanism for selectively adjusting a position of the jet receiving receptacle in an axial direction parallel to the fluid jet axis defined by the fluid jet outlet of the fluid jet cutting head. 4. The fluid jet cutting system of claim 1 wherein the fluid jet receptacle is adjustably supported by the support structure, and wherein, during at least a portion of the workpiece processing operation, an angular orientation of the fluid jet receptacle is based at least in part on process model calculations. 5. The fluid jet cutting system of claim 1 wherein the fluid jet receptacle comprises an elongated tubular structure having a jet receiving inlet at a distal end thereof. 6. The fluid jet cutting system of claim 5 wherein the elongated tubular structure has an external surface that tapers toward the distal end to provide workpiece clearance in a region immediately adjacent to and downstream of the jet receiving inlet. 7. The fluid jet cutting system of claim 5 wherein the elongated tubular structure includes a distal portion that is generally cylindrical. 8. A fluid jet cutting system, comprising: a fluid jet cutting head having an orifice to generate a high pressure fluid jet and a fluid jet outlet from which to discharge the high pressure fluid jet; a jet receiving receptacle to receive the high pressure fluid jet after the high pressure fluid jet passes through a workpiece during a workpiece processing operation; and a support structure to support the jet receiving receptacle, the support structure including a drive system to selectively adjust at least one of a lateral position of the jet receiving receptacle and an angular orientation of the jet receiving receptacle relative to a fluid jet axis defined by the fluid jet outlet of the fluid jet cutting head such that the jet receiving receptacle can be tilted relative to the fluid jet axis at least during a portion of the workpiece processing operation, and wherein the support structure couples the jet receiving receptacle to the fluid jet cutting head to move therewith and positions the jet receiving receptacle opposite the fluid jet outlet of the cutting head to receive the high pressure fluid jet during the workpiece processing operation. 9. The fluid jet cutting system of claim 8 wherein the drive system is controllable to align a central axis of the fluid jet receptacle to be generally parallel to the high pressure fluid jet in a deflected state during the workpiece processing operation. 10. The fluid jet cutting system of claim 8 wherein the drive system is controllable to adjust the fluid jet receptacle laterally to align a central axis of the fluid jet receptacle to intersect with the high pressure fluid jet in a deflected state within an inlet portion of the fluid jet receptacle during the workpiece processing operation. 11. A fluid jet cutting system, comprising: a fluid jet cutting head having an orifice to generate a high pressure fluid jet and a fluid jet outlet from which to discharge the high pressure fluid jet; a jet receiving receptacle to receive the high pressure fluid jet after the high pressure fluid jet passes through a workpiece during a workpiece processing operation; and a support structure to support the jet receiving receptacle, the support structure including a drive system to selectively adjust at least one of a lateral position of the jet receiving receptacle and an angular orientation of the jet receiving receptacle relative to a fluid jet axis defined by the fluid jet outlet of the fluid jet cutting head, wherein the fluid jet cutting head is moved in a cutting direction during the workpiece processing operation, and wherein the fluid jet receptacle is adjustably supported by the support structure to enable selective adjustment of the lateral position of the jet receiving receptacle in a direction aligned with the cutting direction of the fluid jet cutting head and selective adjustment of the angular orientation of the jet receiving receptacle relative to the fluid jet axis defined by the fluid jet outlet of the fluid jet cutting head such that the fluid jet receptacle can be tilted relative to the fluid jet axis at least during a portion of the workpiece processing operation.