Bell assemblies for glass tubing manufacturing and glass tubing manufacturing apparatuses comprising the same

What is claimed is: 1. A glass tubing manufacturing apparatus comprising: a glass delivery tank for containing molten glass, the glass delivery tank comprising a delivery orifice extending through a bottom of the glass delivery tank; a bell head configured for forming molten glass into glass tubing, the bell head positioned at least partially beneath the delivery orifice of the glass delivery tank; a support connected to the bell head, the support comprising: a bell shaft with an inner bore and an outer surface, the bell shaft extending from the bell head through the delivery orifice of the glass delivery tank to a bell shaft support; a thermal shield positioned around at least a portion of the outer surface of the bell shaft, the thermal shield extending through the glass delivery tank, the thermal shield comprising: an outer cladding; and an insulation layer positioned between the outer cladding and the outer surface of the bell shaft; and a gap positioned between the outer surface of the bell shaft and the thermal shield, the gap extending the length of the thermal shield, wherein the gap is disposed directly between the insulation layer and the outer surface of the bell shaft, wherein the thermal shield ends at a position on the bell shaft that is spaced apart from the bell head. 2. The glass tubing manufacturing apparatus of claim 1 , wherein the bell head comprises a body with an inner channel, a bell head outer surface and a wall made from a solid metallic material extending between the inner channel and the bell head outer surface. 3. The glass tubing manufacturing apparatus of claim 2 , wherein the wall of the bell head and the bell shaft are made from platinum or a platinum alloy. 4. The glass tubing manufacturing apparatus of claim 1 , wherein the bell shaft extends from the bell head up through the glass delivery tank. 5. The glass tubing manufacturing apparatus of claim 1 , further comprising a liner positioned in the inner bore of the bell shaft. 6. The glass tubing manufacturing apparatus of claim 5 , wherein the liner is made from a refractory material. 7. The glass tubing manufacturing apparatus of claim 6 , wherein the refractory material is substantially free from organic compounds. 8. The glass tubing manufacturing apparatus of claim 7 , wherein the liner is made from alumina. 9. The glass tubing manufacturing apparatus of claim 5 , wherein a pressurized fluid is directed through the inner bore of the bell shaft, wherein the pressurized fluid contacts the liner. 10. The glass tubing manufacturing apparatus of claim 1 , wherein the outer cladding is made from platinum or a platinum alloy. 11. The glass tubing manufacturing apparatus of claim 1 , wherein the insulation layer is made from a refractory material. 12. The glass tubing manufacturing apparatus of claim 11 , wherein the refractory material is substantially free from organic compounds. 13. The glass tubing manufacturing apparatus of claim 1 , further comprising a heater section located above the glass delivery tank, the heater section configured to heat the molten glass in the glass delivery tank. 14. The glass tubing manufacturing apparatus of claim 13 , wherein the thermal shield extends through the heater section. 15. A method for manufacturing glass tubing comprising: directing molten glass into a glass delivery tank, the glass delivery tank comprising a delivery orifice extending through a bottom of the glass delivery tank; drawing the molten glass around a bell head located at least partially below the delivery orifice of the glass delivery tank thereby forming glass tubing, the bell head connected to a support comprising: a bell shaft with an inner bore and an outer surface, the bell shaft extending from the bell head through the delivery orifice of the glass delivery tank to a bell shaft support; and a thermal shield positioned around at least a portion of the outer surface of the bell shaft, the thermal shield extending through the glass delivery tank, the thermal shield comprising: an outer cladding; an insulation layer positioned between the outer cladding and the outer surface of the bell shaft; and a gap positioned between the outer surface of the bell shaft and the thermal shield, the gap extending the length of the thermal shield, wherein the gap is disposed directly between the insulation layer and the outer surface of the bell shaft, wherein the thermal shield ends at a position on the bell shaft that is spaced apart from the bell head. 16. The method of claim 15 wherein the thermal shield terminates within the glass delivery tank above the delivery orifice. 17. The method of claim 15 , further comprising heating the molten glass with a heater section located at least partially above the glass delivery tank, wherein the thermal shield extending through the heater section. 18. The method of claim 17 , further comprising the thermal shield maintaining an average temperature variation across a width of the bell shaft within the heater section to less than 20% of an average temperature variation across a width of the outer cladding of the thermal shield. 19. The method of claim 15 , further comprising a liner positioned within the inner bore of the bell shaft, the liner extending from the bell head up through the glass delivery tank. 20. The method of claim 19 , wherein the liner is made from a refractory material. 21. The method of claim 20 , wherein the refractory material is substantially free from organic compounds. 22. The method of claim 21 , wherein the liner is made from alumina. 23. The method of claim 19 , further comprising the liner mitigating degradation of the inner bore of the bell shaft. 24. The method of claim 19 , wherein the liner is a barrier to particulate matter resulting from mitigation of the inner bore of the bell shaft from coming into contact and being incorporated in the glass tubing drawn over the bell head. 25. A bell assembly for a glass tubing manufacturing apparatus comprising: a bell head configured for forming molten glass into glass tubing; a support connected to the bell head, the support comprising: a bell shaft comprising an inner bore and an outer surface; a liner positioned in the inner bore of the bell shaft; a thermal shield extending along the outer surface of the bell shaft, the thermal shield comprising: a cladding layer; and an insulation layer positioned between the cladding layer and the outer surface of the bell shaft; and a gap positioned between the outer surface of the bell shaft and the thermal shield, the gap extending the length of the thermal shield, wherein the gap is disposed directly between the insulation layer and the outer surface of the bell shaft, wherein the thermal shield ends at a position on the bell shaft that is spaced apart from the bell head. 26. The bell assembly of claim 25 , wherein the bell head comprises a body with an inner channel, a bell head outer surface and a wall made from a solid metallic material extending between the inner channel and the bell head outer surface. 27. The bell assembly of claim 26 , wherein the wall of the bell head is made from platinum or a platinum alloy. 28. The bell assembly of claim 25 , wherein the liner is made from a refractory material. 29. The bell assembly of claim 25 , wherein the bell shaft is made f