Wheel alignment for line striper

The invention claimed is: 1. A line striper comprises: a wheeled frame; a fluid reservoir mounted on the wheeled frame; a sprayer mounted to the wheeled frame, and fluidly connected to the fluid reservoir to receive spray fluid; a guided wheel assembly rotatably mounted to the frame, such that rotational orientation of the guided wheel assembly relative to the frame determines a turning angle of the wheeled frame, the guided wheel assembly comprising: a spindle axle secured to but rotatable with respect to the wheeled frame; a guide wheel secured to the spindle axle, and rotatable therewith; an adjustment disk fixedly anchored to the spindle axle, and having first and second screw notches in its outer diameter, the first and second screw notches having first and second adjustment surfaces, respectively; an alignment plate surrounding and rotatably abutting the adjustment disk, the alignment plate having a locking feature; and first and second alignment screws threadable through the alignment plate into the screw notches of the adjustment disk to abut the adjustment surfaces and thereby determine a rotational alignment of the alignment plate relative to the adjustment disk. 2. The line striper of claim 1 , wherein the sprayer is not moved relative to the wheeled frame during operation, such that the position and orientation of the sprayer is fully determined by the position and orientation of the wheeled frame. 3. The line striper of claim 1 , wherein guide wheel is secured to the spindle axle via a fork having arms bracketing the guide wheel. 4. The line striper of claim 1 , wherein a substantially cylindrical inner diameter of the alignment plate abuts the outer diameter of the adjustment disk except at the first and second screw notches. 5. The line striper of claim 1 , further comprising: an antirotation lock fixed to the wheeled frame and actuatable to engage and disengage the locking feature of the alignment plate, thereby fixing the orientation of the guide wheel relative to the wheeled frame. 6. The line striper of claim 5 , further comprising a manual release, and wherein the antirotation lock is biased to engage the locking feature except when actuated by the manual release. 7. The line striper of claim 5 , wherein the locking feature comprises a locking notch in the alignment plate, and further wherein the antirotation lock comprises a locking lug fitted to the locking notch and pivotable away from the locking notch via a rotatable locking arm. 8. The line striper of claim 7 , wherein the locking notch is disposed in an outer diameter of the alignment plate. 9. The line striper of claim 1 , wherein the alignment plate includes parallel first and second threaded screw passages disposed to position the first and second adjustment screws adjacent the first and second screw notches. 10. The line striper of claim 9 , wherein the parallel first and second threaded screw passages are separated by a distance at least 50% the diameter of the adjustment disk. 11. The line striper of claim 9 , wherein the first and second threaded screw passages permit the first and second adjustment screws to be recessed into the alignment plate when fully engaged with the adjustment disk. 12. The line striper of claim 1 , wherein the first and second adjustment surfaces are coplanar. 13. The line striper of claim 12 , wherein the first and second screw notches are each defined by the coplanar first and second adjustment surfaces and by parallel first and second notch surfaces. 14. The line striper of claim 1 , wherein the first and second screw notches are separated by at least sixty degrees with respect to an axis of the spindle axle. 15. The line striper of claim 14 , wherein the first and second screw notches are separated by less than ninety degrees with respect to the axis of the spindle axle. 16. An alignment method for a line striper comprising a sprayer affixed to frame, and a guide wheel rotatably secured to the frame via a spindle axle, the method comprising: engaging a locking feature of an alignment plate via an antirotation lock affixed to the frame; threading first and second alignment screws through the alignment plate to engage adjustment surfaces of screw notches in an outer diameter of an adjustment disk disposed coaxially within the alignment plate and affixed to the spindle axis; and turning the first and second alignment screws to adjust a rotational orientation of the alignment plate relative to the adjustment disk, such that the guide wheel is oriented in a forward direction while the locking feature is engaged by the antirotation lock. 17. The alignment method of claim 16 , wherein turning the first and second alignment screws comprises loosening the first screw and subsequently tightening the second screw, such that the first and second screws both abut the adjustment surfaces of the screw notches. 18. The alignment method of claim 16 , wherein the alignment screws are parallel and the adjustment surfaces are coplanar, such that once tightened, the first and second alignment screws both abut the adjustment surfaces at identical angles that define an alignment adjustment to the spindle axle. 19. The alignment method of claim 16 , wherein the antirotation lock is biased to engage the locking feature via a biasing force, such that selectively engaging the locking feature comprises rotating the spindle axis such that the locking feature is aligned with the antirotation lock, and permitting the antirotation lock to engage the locking feature under the biasing force. 20. The alignment method of claim 16 , wherein selectively engaging the locking feature comprises inserting an antirotation lug into a locking notch along an outer diameter of the alignment plate.