Method of applying a thin spray-on liner and robotic applicator therefor

The invention claimed is: 1. A method of applying a liner material to a contoured surface, using a liner application device having a multi-axis robotic arm with a head assembly, comprising a sensor and a spray applicator, wherein each of the sensor and spray applicator has an operational axis extending from a distal end thereof, the multi-axis robotic arm being controllable for movement with multiple degrees of freedom capable of disposing the distal end in a three dimensional position and capable of disposing the operational axis at an orientation angle, the spray applicator comprising a spray nozzle fluidly coupled to a reservoir of the liner material for emitting a spray of the liner material toward the contoured surface, the method comprising: sensing locations of an initial plurality of surface points on the contoured surface, the initial plurality of surface points being spatially distributed so as to provide a representative initial topographical profile of the contoured surface, the locations of the initial plurality of surface points being sensed while scanning the contoured surface with the sensor along an initial scan path that generally follows the topographical profile of the contoured surface; identifying an anomalous point from the initial plurality of surface points, wherein the anomalous point has an anomalous coordinate that deviates from an extrapolated coordinate that is extrapolated from coordinates of the initial plurality of surface points upstream or downstream from the anomalous point along the initial scan path; scanning the contoured surface with the sensor along a secondary scan path that generally follows the topographical profile of the contoured surface to sense at least one intermediate point on the contoured surface between the anomalous point and the initial plurality of surface points upstream or downstream from the anomalous point along the initial scan path, extrapolating from the at least one intermediate point to determine whether the anomalous coordinate constitutes an initial scanning error or whether the anomalous coordinate has identified a discontinuity in the contoured surface at the anomalous point; when the anomalous coordinate is determined to be an initial scanning error, discarding the anomalous point from the initial plurality of surface points; when the anomalous coordinate has identified the discontinuity in the contoured surface at the anomalous point, adding the at least one intermediate point to the initial plurality of surface points to produce a secondary plurality of surface points thereby providing a representative secondary topographical profile of the contoured surface; based on the representative secondary topographical profile of the contoured surface, determining a spray path being a sequence of control vectors defining the movement of the multi-axis robotic arm and head assembly, the spray path comprising a trajectory of three dimensional positions of the distal end and orientation angle of the operational axis that follows the representative secondary topographical profile of the contoured surface offset therefrom within a spray range of the liner application device; and spraying the contoured surface with the liner material while automatically controlling the liner application device to undertake at least one portion of the spray path. 2. The method of claim 1 , further comprising while controlling the liner application device to follow the initial scan path and the secondary scan path, computing the sequence of control vectors for the spray path. 3. The method of claim 1 , further comprising: sensing locations of a plurality of reference landmark points on the contoured surface; and determining the initial scan path based on the plurality of reference landmark points. 4. The method of claim 3 , wherein the initial scan path is determined so as to maintain a predetermined range of distance between the sensor and the contoured surface during scanning between 8 and 35 inches. 5. The method of claim 3 , wherein the locations of the plurality of reference landmark points are sensed during a survey scan of the contoured surface performed by the sensor prior to the scanning. 6. The method of claim 3 , wherein the plurality of reference landmark points comprise local maxima in the topographical profile of the contoured surface. 7. The method of claim 1 , wherein the liner material is sprayed onto the contoured surface as a substantially constant-thickness surface layer. 8. The method of claim 1 , wherein the liner material is sprayed onto the contoured surface in a plurality of passes of the liner application device along the spray path, during each of the plurality of passes liner material is sprayed onto the contoured surface with the operational axis of the spray applicator being at a different orientation angle relative to the spray path. 9. The method according to claim 8 wherein the plurality of passes comprises: an upward vertical pass; a downward vertical pass; a forward horizontal pass; and a reverse horizontal pass. 10. The method according to claim 9 wherein the operational axis of the spray applicator is directed to spray liner material at an orientation angle of 30 degrees relative to the direction of travel. 11. The method of claim 1 , wherein the contoured surface comprises an exposed rock face, and wherein the liner material comprises liquid polymer. 12. The method of claim 11 wherein the liner material has a thickness in the range of 3 to 6 millimeters (about ⅛ to ¼ inches). 13. The method of claim 1 wherein the step of determining a spray path based on the plurality of surface points includes: eliminating a singularity by selecting between at least two different sequences of control vectors for defining the movement of the multi-axis robotic arm and head assembly that result in an identical trajectory of three dimensional positions of the distal end and orientation angle of the operational axis relative to the spray path. 14. The method of claim 1 wherein the anomalous point is disposed on a transitional contoured surface selected from the group consisting of: a T-shaped tunnel junction; a Y-shaped tunnel junction; a transition area between a horizontal tunnel and a vertical shaft; a recessed safety bay; a recessed formation; and a protruding formation. 15. The method according to claim 14 , wherein the spraying of the contoured surface with the liner material comprises spraying a hydrophilic base coat foam under layer in a primer pass to substantially fill said recessed formation; allowing the base coat to cure and then spraying a liquid polymer over the base coat in a finish pass. 16. The method according to claim 1 wherein the plurality of passes comprise a first pass having a first coverage area and a second pass having a second coverage area that is sprayed to overlap the first coverage area by about 50%. 17. A non-transitory computer-readable storage medium on which are stored instructions that, when executed by one or more data processors, program the one or more data processors to perform a method of applying liner material to a contoured surface using a liner application device having a multi-axis robotic arm with a head assembly, comprising a sensor; and a spray applicator, wherein each of the sensor and spray applicator has an operational axis extending from a distal end thereof, the multi-axis robotic arm being controllable for movement with multiple degrees of freedom capable of disposing the distal end in a three dimensional position and capable of disposing the operational axis at an