Mica rolls for use in glass manufacturing processes and methods for making the same

1 . A push roll spool for use in processing a glass tube, the spool comprising: a. a base having first and second axially spaced ends, b. multiple sheets of heat resistant material disposed on the base between the axially spaced ends, forming an axially extending stack, c. the stack having a circumferential, generally U-section groove having a profile defined by the peripheral edges of multiple said sheets having different diameters, the groove sized to engage and drive a glass tube. 2 . The push roll spool of claim 1 , wherein the groove has two contact areas at which to engage and drive a glass tube. 3 . The push roll spool of claim 1 , wherein the heat resistant material comprises mica. 4 . The push roll spool of claim 1 , wherein the heat resistant material comprises mica paper. 5 . The push roll spool of claim 1 , wherein the heat resistant material comprises ceramic fiber millboard. 6 . A method for producing a push roll spool for use in glass manufacturing comprising: a. providing a plurality of sheets of a heat resistant material; b. stacking the plurality of sheets; c. compressing the plurality of sheets axially; d. grinding the plurality of sheets to form a concave groove around the spool. 7 . The method for producing a push roll spool of claim 6 , wherein the heat resistant material comprises mica. 8 . The method for producing a push roll spool of claim 6 , wherein the heat resistant material comprises mica paper. 9 . The method for producing a push roll spool of claim 6 , wherein the heat resistant material comprises ceramic fiber millboard. 10 . A method for producing a glass sleeve with a flattened portion comprising the steps of: a. providing one or more rotatable push roll spools, each rotatable push roll spool comprising a concave contact surface made of a first heat resistant material; b. providing a substantially cylindrical tube made of glass, the substantially cylindrical tube having a longitudinal axis, an outer curved surface, and an inner curved surface at least partially enclosing a space; c. introducing the concave contact surface into contact with the outer curved surface to push the substantially cylindrical tube; d. heating at least a portion of the substantially cylindrical tube to a temperature within the softening range of the glass; e. introducing one or more shaping mandrels into the partially-enclosed space; f. moving the substantially cylindrical tube over the one or more shaping mandrels to deform the tube, forming the flattened portion. 11 . The method of claim 10 , wherein the concave contact surface contacts the substantially cylindrical tube at two contact areas. 12 . The method of claim 10 , further comprising moving the substantially cylindrical tube over the one or more shaping mandrels to deform the tube, forming two opposing flattened portions. 13 . The method of claim 10 , further comprising moving the substantially cylindrical tube over the one or more shaping mandrels to deform the tube, forming two opposing curved portions. 14 . The method of claim 13 , wherein the two opposing curved portions are substantially semi-circular. 15 . The method of claim 10 wherein the first heat resistant material comprises mica. 16 . The method of claim 10 wherein the first heat resistant material comprises mica paper. 17 . The method of claim 10 wherein the first heat resistant material comprises ceramic fiber millboard. 18 . The method of claim 10 , comprising introducing one or more rotatable pull roll spools having a flat contact surface made of a second heat resistant material such that the flat contact surface contacts the outer surface to pull the substantially cylindrical tube over the one or more shaping mandrels. 19 . The method of claim 18 wherein the second heat resistant material comprises mica. 20 . The method of claim 18 wherein the second heat resistant material comprises mica paper. 21 . The method of claim 18 wherein the second heat resistant material comprises ceramic fiber millboard.