Sheet metal forming die laser surface hardening process

What is claimed is: 1. A laser heat treatment process of surface hardening a binder surface around a die cavity of a sheet metal forming die without needing to perform a post-hardening machining operation on the sheet metal forming die, the process comprising: scanning a laser beam along spaced apart side-by-side laser tracks to form corresponding spaced apart side-by-side hardened metal tracks across the binder surface of the forming die, with each hardened metal track extending longitudinally in a direction that maintains an orientation that is normal to a local metal flow direction across each hardened metal track of the binder surface during a sheet metal forming operation with the forming die; wherein the scanning forms the corresponding hardened metal tracks across the binder surface without needing to perform a post-hardening machining operation on the sheet metal forming die. 2. The laser heat treatment process of claim 1 , wherein the scanning comprises using a single laser head to simultaneously scan two or more of the spaced apart side-by-side laser tracks to simultaneously form a corresponding two or more of the spaced apart side-by-side hardened metal tracks. 3. The laser heat treatment process of claim 1 , wherein the scanning comprises forming the corresponding spaced apart side-by-side hardened metal tracks between an edge of a forming cavity of the forming tool and a draw bead of the binder surface. 4. The laser heat treatment process of claim 1 , wherein the scanning comprises using a single laser head to simultaneously scan four or more of the spaced apart side-by-side laser tracks to simultaneously form a corresponding four or more of the spaced apart side-by-side hardened metal tracks. 5. The laser heat treatment process of claim 1 , wherein the scanning comprises forming the corresponding spaced apart side-by-side hardened metal tracks across portions of the binder surface in which adjacent local metal flow directions during a sheet metal forming operation are angled toward each other. 6. The laser heat treatment process of claim 1 , wherein the scanning comprises: forming a first group of the corresponding spaced apart side-by-side hardened metal tracks adjacent a first side of an inside corner oriented to extend longitudinally in a first direction; and forming a second group of the corresponding spaced apart side-by-side hardened metal tracks adjacent a second side of the inside corner oriented to extend longitudinally in a second direction. 7. The laser heat treatment process of claim 1 , wherein the scanning comprises forming a group of the corresponding spaced apart side-by-side hardened metal tracks with terminal ends that are spaced along a length of a cavity edge forming an inside corner of the cavity. 8. The laser heat treatment process of claim 1 , wherein the scanning comprises forming the corresponding spaced apart side-by-side hardened metal tracks across an entirety of the binder surface. 9. The laser heat treatment process of claim 1 , wherein the scanning comprises forming multiple groups of the corresponding spaced apart side-by-side hardened metal tracks longitudinally extending in different directions. 10. The laser heat treatment process of claim 1 , wherein the scanning comprises forming multiple groups of the corresponding spaced apart side-by-side hardened metal tracks with at least one of the groups having terminal ends that are spaced along a longitudinal length of a side of a hardened metal track of another group. 11. The laser heat treatment process of claim 1 , wherein the scanning comprises forming the corresponding spaced apart side-by-side hardened metal tracks with a hardened metal track width laterally spaced apart by a hardened metal track gap width, and with the hardened metal track width being between 1 and 5 times the hardened metal gap width. 12. The laser heat treatment process of claim 1 , wherein the scanning comprises forming the corresponding spaced apart side-by-side hardened metal tracks with a hardened metal track width laterally spaced apart by a hardened metal track gap width, and with the gap width being between 1 and 3 times a thickness of a metal sheet to be formed using the sheet metal forming die.