Turbine abradable layer with asymmetric ridges or grooves

What is claimed is: 1. A turbine abradable component, comprising: a support surface for coupling to a turbine casing; a thermally sprayed ceramic/metallic abradable substrate coupled to the support surface, having a substrate surface adapted for opposed, spaced orientation proximal a rotating turbine blade tip circumferential swept path, with the turbine blade having a lower pressure side and a higher pressure side; and at least one asymmetric cross sectional profile ridge projecting from the substrate surface, having an opposed pair of first and second non parallel lateral walls terminating in a common plateau which extends between the non parallel lateral walls, the plateau adapted for orientation in opposed spaced relationship with the turbine blade tip, so as to form a blade tip gap there between. 2. The component of claim 1 , the first lateral wall adapted for orientation upstream a turbine blade rotation direction to resist blade tip airflow leakage from a turbine blade higher pressure side to a lower pressure side through a blade tip gap and the second lateral wall adapted for redirecting the airflow leakage downstream the plateau to resist further blade tip airflow leakage. 3. The component of claim 2 comprising a plurality of identical ridges. 4. The component of claim 2 , the ridge having a trapezoidal cross sectional profile. 5. The component of claim 4 , the first lateral wall angled and projecting toward an upstream a turbine blade rotation direction. 6. The component of claim 2 , the ridge having a saw tooth like cross sectional profile, the first lateral wall oriented generally perpendicularly to the substrate surface and the second lateral wall ramping downwardly and away from the plateau. 7. The component of claim 1 further comprising at least one angularly oriented first groove formed in the ridge plateau adapted for angular orientation upstream a turbine blade rotation direction to resist blade tip airflow leakage from a turbine blade higher pressure side to a lower pressure side through a blade tip gap. 8. The component of claim 7 , further comprising a plurality of first grooves oriented transverse the ridge at a skewed angle relative to a centroidal axis of the ridge. 9. The component of claim 7 , further comprising a plurality of identical ridges separated by second grooves that are skewed relative to the respective ridge plateaus and the substrate that are adapted for orientation upstream a turbine blade rotation direction to resist blade tip airflow leakage. 10. A turbine abradable component, comprising: a support surface for coupling to a turbine casing; an abradable substrate coupled to the support surface, having a substrate surface adapted for opposed, spaced orientation proximal a rotating turbine blade tip circumferential swept path, with the turbine blade having a lower pressure side and a higher pressure side; and a plurality of identical trapezoidal cross sectional profile first ridges projecting from the substrate surface, each respective first ridge having: an opposed pair of first and second lateral walls terminating in a common plateau, the plateau adapted for orientation in opposed spaced relationship with the turbine blade tip, so as to form a blade tip gap there between; at least one angularly oriented first groove formed in the ridge plateau adapted for angular orientation upstream a turbine blade rotation direction to resist blade tip airflow leakage from a turbine blade higher pressure side to a lower pressure side through the blade tip gap; and the first ridges separated by second grooves that are skewed relative to the respective ridge plateaus and the substrate that are also adapted for orientation upstream the turbine blade rotation direction to resist blade tip airflow leakage. 11. The component of claim 10 further comprising a plurality of first grooves oriented transverse the ridge at a skewed angle relative to a centroidal axis of the ridge. 12. The component of claim 10 , the first groove having an elongated centroidal axis that is aligned with a centroidal axis of the ridge. 13. The component of claim 10 , the second grooves having parallel centroidal axes and first groove having an elongated centroidal axis that is aligned with the centroidal axes of the respective second grooves. 14. The component of claim 10 , the second grooves having parallel centroidal axes and a plurality of first grooves respectively having an elongated centroidal axis that is aligned transverse with the second grooves centroidal axes. 15. The component of claim 10 , further comprising a plurality of vertical ridges coupled to and oriented transverse to at least one pair of adjacent first ridges. 16. The component of claim 15 , the vertical ridges skipping at least one row of first ridges and staggered laterally across the abradable surface. 17. The component of claim 10 , the at least one first groove having a depth of approximately ⅓ to ⅔ of the first ridge height. 18. A method for reducing turbine engine blade tip leakage, comprising: providing a turbine having a turbine housing, a rotor having blades rotatively mounted in the turbine housing, each respective turbine blade having a lower pressure side and a higher pressure side, a distal tip of which forming a blade tip circumferential swept path in the blade rotation direction and axially with respect to the turbine housing; inserting a generally arcuate shaped abradable component in the housing in opposed, spaced relationship with the blade tips, the abradable component having: a support surface for coupling to the turbine casing; an abradable substrate coupled to the support surface, having a substrate surface in opposed, spaced orientation proximal the rotating turbine blade tip circumferential swept path and defining a blade tip gap there between; and a plurality of asymmetric cross sectional profile ridges projecting from the substrate surface, each respective ridge having an opposed pair of first and second non parallel lateral walls terminating in a common ridge plateau, the first lateral wall oriented upstream the turbine blade rotation; the ridges separated by grooves that are skewed relative to the respective ridge plateaus and the substrate that are adapted for orientation upstream the turbine blade rotation direction to resist blade tip airflow leakage; and operating the turbine engine, so the first lateral wall of each respective ridge resists blade tip leakage from the turbine blade higher pressure side to the lower pressure side through the blade tip gap and the second lateral wall redirects airflow leakage downstream the plateau to resist further blade tip airflow leakage. 19. The method of claim 18 , further comprising providing in the abradable component at least a first groove formed in the abradable component respective ridge plateaus that is angularly oriented upstream the turbine blade rotation direction to resist blade tip airflow leakage. 20. The method of claim 18 , further comprising providing a plurality of first grooves in each respective ridge plateau.