Turbine abradable layer with compound angle, asymmetric surface area ridge and groove pattern

What is claimed is: 1. A turbine engine ring segment abradable component, adapted for coupling to an interior circumference of a turbine casing in opposed orientation with a rotating turbine blade tip circumferential swept path, the blade tip having a rotational direction, a leading edge, a mid-chord cutoff point on its pressure side concave surface where a surface tangent is generally parallel to a corresponding turbine blade rotational axis and a trailing edge, the component comprising: a support surface adapted for coupling to a turbine casing inner circumference that circumscribes a turbine blade rotational axis, the support surface having upstream and downstream ends and a support surface axis adapted for parallel orientation with a corresponding turbine blade rotational axis; an abradable substrate coupled to the support surface, having a substrate surface with a compound angle planform pattern of grooves and vertically projecting ridges defined by a pair of a forward and an aft linear segment portions that are conjoined by a transition portion; the forward linear segment portion originating near the support surface upstream end, oriented at an angle within a range of angles plus or minus 10 degrees relative to the support surface axis, and terminating between the support surface ends upstream of a radial and axial projected location of swept path of an intended turbine blade mid-chord cutoff point; the aft linear segment portion originating downstream of said intended turbine blade mid-chord cutoff point, angularly oriented opposite corresponding turbine blade rotational direction, and terminating near the support surface downstream end; and the forward ridges in the forward linear segment portion having greater surface area density than the aft ridges in the aft linear segment portion. 2. The component of claim 1 , further comprising the forward ridges being wider than the aft ridges for creating the forward ridge greater surface density. 3. The component of claim 2 , further comprising ridge width in the transition section narrowing from forward to aft for matching respective widths of the corresponding conjoined forward and aft ridge widths. 4. The component of claim 2 , further comprising ridges and grooves in the transition section defining a curved planform. 5. The component of claim 2 , at least portions of the ridges having distal projecting tips that are inclined relative to the support surface. 6. The component of claim 2 , the ridges and grooves comprising a continuous zig-zag groove pattern. 7. The component of claim 2 , the ridges and grooves having constant spacing pitch. 8. The component of claim 1 , the ridges and grooves having constant spacing pitch. 9. The component of claim 1 , the ridges and grooves comprising a continuous zig-zag groove pattern. 10. The component of claim 1 , further comprising the forward linear segment portion oriented parallel to the support surface axis. 11. A turbine engine, comprising: a turbine housing; a rotor having blades rotatively mounted in the turbine housing, distal tips of which forming a blade tip circumferential swept path in the blade rotation direction and axially with respect to the turbine housing, the blade tips having a leading edge, a mid-chord cutoff point on its pressure side concave surface where a surface tangent is generally parallel to a corresponding turbine blade rotational axis and a trailing edge; and an abradable component having: a support surface adapted for coupling to a turbine housing inner circumference that circumscribes a turbine blade rotational axis, the support surface having upstream and downstream ends and a support surface axis adapted for parallel orientation with the turbine blade rotational axis; an abradable substrate coupled to the support surface, having a substrate surface with a compound angle planform pattern of grooves and vertically projecting ridges defined by a pair of a forward and an aft linear segment portions that are conjoined by a transition portion; the forward linear segment portion originating near the support surface upstream end, oriented within a range or angles plus or minus 10 degrees relative to the support surface axis, and terminating between the support surface ends upstream of a radial and axial projected location of swept path of an intended turbine blade mid-chord cutoff point; the aft linear segment portion originating downstream of said intended turbine blade mid-chord cutoff point, angularly oriented at an angle opposite corresponding turbine blade rotational direction, and terminating near the support surface downstream end; and the forward ridges in the forward linear segment portion having greater surface area density than the aft ridges in the aft linear segment portion. 12. The engine of claim 11 , the component further comprising the forward ridges being wider than the aft ridges for creating the forward ridge greater surface density. 13. The engine of claim 12 , the component further comprising ridge width in the transition section narrowing from forward to aft for matching respective widths of the corresponding conjoined forward and aft ridge widths. 14. The engine of claim 13 , the component further comprising ridges and grooves in the transition section defining a curved planform. 15. The engine of claim 12 , the component further comprising at least portions of the ridges having distal projecting tips that are inclined relative to the support surface. 16. The engine of claim 12 , the component further comprising the ridges and grooves forming a continuous zig-zag groove pattern. 17. The engine of claim 12 , the component further comprising the ridges and grooves having constant spacing pitch. 18. The engine of claim 11 , the component further comprising the forward linear segment portion oriented parallel to the support surface axis.