Laser cladding system and method

The invention claimed is: 1. A laser cladding head configured to receive weld material from a powder source and collimated light from a laser source, the laser cladding head comprising: a protective housing extending principally along a primary axis from a proximal end to a distal end; a focal array situated at the proximal end within the protective housing and oriented to receive and focus the collimated light in a laser beam along the primary axis, the focal array having a focal length and a focal point, the focal array comprising a plurality of mirrors, the plurality of alignment mirrors comprising: a first alignment mirror disposed to redirect the collimated light from the laser source into a first path substantially parallel to the primary axis, and separated from the primary axis by a first distance; a second alignment mirror disposed to redirect the collimated light from the first alignment mirror from the first path into a second path directed at least partially radially inward relative to the primary axis; and a third alignment mirror disposed to redirect the collimated light from the second alignment mirror from the second path into a third path coincident with the primary axis; a turning mirror situated at the distal end within the protective housing and disposed to redirect the laser beam in an emission direction transverse to the primary axis, towards a target point separated from the turning mirror by a working distance, the turning mirror comprising a nonfocal reflective surface indexable to alter an impingement location of the laser beam on the turning mirror; a powder nozzle situated at the distal end within the protective housing and configured to receive and direct the weld material towards the target point for melting by the laser beam; and a borescope having a probe extending along a direction parallel to but not coincident with the primary axis from a borescope body to an imaging head located at a distal end of the borescope probe and directed at the target point, in an imaging direction not parallel to the emission direction, wherein the borescope probe is separated from the primary axis by a borescope distance, and from the first path by a distance greater than the borescope distance, and wherein the third path is situated axially with respect to the primary axis between the borescope body and the imaging head, wherein the focal length is at least ten times the working distance and wherein the working distance is within a tolerance of the focal point, and wherein multiple of the plurality of alignment mirrors are separately adjustable to determine separate dimensional components of alignment of the laser beam, such that the plurality of alignment mirrors collectively determines the impingement location. 2. The laser cladding head of claim 1 , wherein the turning mirror is rotatably anchored within the laser cladding head about a central mirror axis, and wherein the impingement location is offset from the central mirror axis such that the mirror is indexed by rotating the turning mirror to expose a new impingement location. 3. The laser cladding head of claim 2 , wherein the turning mirror is indexable at least five times by rotating the turning mirror to expose new regions of the turning mirror as the impingement location. 4. The laser cladding head of claim 1 , wherein the protective housing has a beam outlet aligned with the impingement location so as to permit the redirected laser beam to leave the protective housing without exposing portions of the turning mirror other than the impingement location to debris and weld backspatter from the target point. 5. The laser cladding head of claim 1 , wherein the turning mirror is a flat mirror formed of copper and plated with gold. 6. The laser cladding head of claim 1 , further comprising: a temperature sensor disposed to sense changes in temperature of the turning mirror. 7. The laser cladding head of claim 6 , wherein the temperature sensor is a thermocouple situated within or adjacent the turning mirror. 8. The laser cladding head of claim 1 , wherein the focal length of the focal array is at least twenty times the working distance. 9. The laser cladding head of claim 1 , wherein the laser beam is capable of impinging on the target point at a width less than 0.25 mm. 10. The laser cladding head of claim 1 , wherein the imaging direction is angled between 15° and 25° with respect to the emission direction. 11. The laser cladding head of claim 1 , further comprising a gas subsystem, the gas system comprising: a high-speed gas nozzle disposed near the turning mirror, and configured to produce a gas sheath coaxial with the laser beam in a region between the turning mirror and the target point, thereby shielding the turning mirror from debris and molten backspatter; and a gas knife disposed between the turning mirror and the target point, such that the gas knife redirects the gas sheath away from the target point. 12. The laser cladding head of claim 11 , wherein the gas knife is a gas jet disposed substantially transverse to the gas sheath. 13. The laser cladding head of claim 11 , wherein the gas subsystem further comprises a coaxial inert gas nozzle surrounding the powder nozzle, and directed towards the target point such that oxygen density in the vicinity of the target point is reduced. 14. A method of operating a laser cladding system having a borescope extending along a primary axis, the method comprising: focusing a laser beam along the primary axis using a focal array, the focal array having a focal length of at least 400 mm and comprising a plurality of mirrors, the plurality of alignment mirrors comprising: a first alignment mirror disposed to redirect the collimated light from the laser source into a first path substantially parallel to the primary axis; a second alignment mirror disposed to redirect the collimated light from the first alignment mirror from the first path into a second path at least partially radially inward relative to the primary axis; and a third alignment mirror disposed to redirect the collimated light from the second alignment mirror from the second path into a third path substantially coincident with the primary axis; supplying weld material via a powder nozzle to a target location offset from the primary axis by a working distance; imaging the target location with a borescope having a borescope probe extending along a direction parallel to but not coincident with the primary axis, from a borescope body to an imaging head located at a distal end of the borescope probe, redirecting the laser beam in an emission direction transverse to the primary axis via a nonfocal turning mirror, towards the target point; determining separate dimensional components of alignment of the laser beam via separate adjustment of multiple of the plurality of alignment mirrors, such that the plurality of alignment mirrors collectively determines the impingement location; sensing failure conditions at the turning mirror indicating fouling or damage to the turning mirror; and indexing the turning mirror to change which portion of the turning mirror the laser beam impinges upon, without changing the emission direction, wherein the borescope probe is separated from the primary axis by a borescope distance, and from the first path by a distance greater than the borescope distance, and wherein the third path is situated axially with respect to the primary axis between the borescope body and the imaging head. 15. The method of claim 14 , further comprising: deflecting debris and molten backspatter away from the turning m