Methods of separating strengthened glass sheets by mechanical scribing

The invention claimed is: 1. A method of scoring a strengthened glass sheet comprising: positioning a serrated scribing wheel at a position spaced apart from a first edge of the glass sheet and offset below a top surface of the glass sheet, wherein the glass sheet comprises a surface compression layer of depth DOL and a central region; translating the serrated scribing wheel into the first edge of the glass sheet; continuing to translate the serrated scribing wheel an engagement distance from the first edge in a first direction at an initiation speed such that the serrated scribing wheel forms a crack initiation site comprising surface indentations extending into the first strengthened surface layer; subsequent to translating the serrated scribing wheel into the first edge of the glass sheet and the engagement distance, translating the serrated scribing wheel upward in a vertical direction such that contact surfaces of the serrated scribing wheel contact the top surface of the strengthened glass sheet and accelerating the serrated scribing wheel in the first direction from the initiation speed to a scoring speed to scribe a score line extending into the glass sheet to a median crack depth greater than DOL; and stopping the serrated scribing wheel a termination offset distance that is at least greater than a diameter of the serrated scribing wheel before the score line reaches a second edge of the glass sheet that is opposite the first edge, wherein the score line is completed in a score time measured from when the serrated scribing wheel contacts the glass sheet to when the serrated scribing wheel is stopped, and the score line grows through the central region after the score time. 2. The method of claim 1 , wherein the score line grows through the glass sheet and forms a through-body crack. 3. The method of claim 1 , wherein a stress field within the central region surrounding the fixed position relaxes after the serrated scribing wheel has been translated away from a fixed position, inducing the score line to grow through the central region such that, at the fixed position on the glass sheet, the score line grows through the central region at a time after the serrated scribing wheel has been translated away from the fixed position. 4. The method of claim 1 wherein, the engagement distance is 2 to 4 times the diameter of the serrated scribing wheel. 5. A method of separating a strengthened glass sheet comprising: positioning a serrated scribing wheel at a position spaced apart from a first edge of the glass sheet and offset below a top surface of the glass sheet, wherein the glass sheet is an ion-exchanged glass sheet having a first strengthened surface layer and a second strengthened surface layer under a compressive stress and extending from a surface of the ion-exchanged glass sheet to a depth of layer DOL, and a central region between the first strengthened surface layer and the second strengthened surface layer that is under tensile stress; translating the serrated scribing wheel into the first edge of the glass sheet; continuing to translate the serrated scribing wheel an engagement distance from the first edge in a first direction at an initiation speed such that the serrated scribing wheel forms a crack initiation site comprising surface indentations extending into the first strengthened surface layer; subsequent to translating the serrated scribing wheel into the first edge of the glass sheet and the engagement distance, translating the serrated scribing wheel upward in a vertical direction such that contact surfaces of the serrated scribing wheel contact the top surface of the strengthened glass sheet and accelerating the serrated scribing wheel in the first direction from the initiation speed to a scoring speed to scribe a score line extending into the glass sheet to a median crack depth greater than DOL; stopping the serrated scribing wheel a termination offset distance that is at least greater than a diameter of the serrated scribing wheel before the score line reaches a second edge of the glass sheet that is opposite the first edge; positioning the serrated scribing wheel at a position spaced apart from a third edge of the glass sheet and offset below the top surface of the glass sheet; translating the serrated scribing wheel in a second direction transverse to the first direction at a cross-cut initiation speed such that the serrated scribing wheel forms a cross-cut crack initiation site comprising surface indentations extending into the first strengthened surface layer; and accelerating the serrated scribing wheel in the second direction from the cross-cut initiation speed to a cross-cut scoring speed to scribe a cross-cut score line extending into the glass sheet a cross-cut median crack depth. 6. The method of claim 5 , wherein at a fixed position on the glass sheet, the score line grows through the central region at a time after the serrated scribing wheel has been translated away from the fixed position. 7. The method of claim 6 , wherein a stress field within the central region surrounding the fixed position relaxes after the serrated scribing wheel has been translated away from the fixed position, inducing the score line to grow through the central region. 8. The method of claim 5 , further comprising scoring a plurality of spaced score lines in the first direction from a plurality of crack initiation sites from the first edge. 9. The method of claim 8 , wherein the glass sheet is separated into glass portions along the cross-cut score line and the plurality of score lines. 10. The method of claim 5 , further comprising scoring a plurality of cross-cut score lines in the second direction from a plurality of cross-cut crack initiation sites from the third edge. 11. The method of claim 5 , wherein after the serrated scribing wheel is accelerated to the scoring speed, applying a normal force to the serrated scribing wheel in a direction towards the top surface of the glass sheet. 12. The method of claim 5 , wherein the glass sheet has a thickness of less than 1.5 mm. 13. The method of claim 5 , wherein the serrated scribing wheel applies a force to the glass sheet that is less than 6 Newtons. 14. A method of separating a strengthened glass sheet comprising: positioning a serrated scribing wheel at a position spaced apart from a first edge of the glass sheet and offset below a top surface of the glass sheet, wherein the glass sheet is an ion-exchanged glass sheet having a first strengthened surface layer and a second strengthened surface layer under a compressive stress and extending from a surface of the ion-exchanged glass sheet to a depth of layer DOL, and a central region between the first strengthened surface layer and the second strengthened surface layer that is under tensile stress; translating the serrated scribing wheel into the first edge of the glass sheet; continuing to translate the serrated scribing wheel an engagement distance from the first edge in a first direction at an initiation speed such that the serrated scribing wheel forms a crack initiation site comprising surface indentations extending into the first strengthened surface layer; subsequent to translating the serrated scribing wheel into the first edge of the glass sheet and the engagement distance, translating the serrated scribing wheel upward in a vertical direction such that contact surfaces of the serrated scribing wheel contact the top surface of the strengthened glass sheet and accelerating the serrated scribing wheel in the first direction from the initiation speed to a scoring speed to scribe a score line extending into the glass