IV membrane attachment systems and methods

We claim: 1. An intravenous delivery system comprising: a drip unit comprising: an exterior wall shaped to at least partially define a drip chamber that receives a liquid from a liquid source, wherein the exterior wall comprises a generally tubular shape, wherein the generally tubular shape comprises a reduced diameter portion and an annular surface, wherein the annular surface forms a seat; a secondary exterior wall comprising a generally conical shape, wherein the secondary exterior wall receives the reduced diameter portion to engage the exterior wall with the secondary exterior wall; and an anti-run-dry membrane comprising a plurality of pores that are permeable to the liquid, wherein the anti-run-dry membrane is formed of a hydrophilic material configured to resist passage of air through the pores, wherein the anti-run-dry membrane is secured to and contacts the secondary exterior wall, wherein the anti-run-dry membrane is proximate the seat. 2. The intravenous delivery system of claim 1 , further comprising: tubing comprising a first end connectable to the drip unit and a second end; and an intravenous access unit connectable to the second end of the tubing to deliver the liquid intravenously to a patient. 3. The intravenous delivery system of claim 2 , wherein the secondary exterior wall comprises an outlet portion, wherein the outlet portion is coupled to the first end of the tubing. 4. The intravenous delivery system of claim 1 , wherein the exterior wall and the secondary exterior wall are secured together only by the secondary exterior wall receiving the reduced diameter portion. 5. A method of manufacturing a drip unit, the method comprising: providing an exterior wall shaped to at least partially define a drip chamber configured to receive a liquid from a liquid source, wherein the exterior wall comprises a generally tubular shape, wherein the generally tubular shape comprises a reduced diameter portion and an annular surface, wherein the annular surface forms a seat; engaging the exterior wall with a secondary exterior wall, wherein the second exterior wall comprises a generally conical shape, wherein the secondary exterior wall receives the reduced diameter portion to engage the exterior wall with the secondary exterior wall, wherein the secondary exterior wall comprises an outlet portion through which fluid is configured to flow; and positioning an anti-run-dry membrane in contact with the secondary exterior wall, wherein the anti-run-dry membrane is configured to be proximate the seat when the exterior wall is engaged with the secondary exterior wall, wherein the anti-run-dry membrane comprises a plurality of pores that are permeable to a liquid to be delivered to a patient, wherein the anti-run-dry membrane is formed of a hydrophilic material configured to resist passage of air through the pores. 6. The method of claim 5 , wherein the anti-run-dry membrane and the secondary exterior wall are formed before the exterior wall. 7. The method of claim 6 , wherein the anti-run-dry membrane is positioned in contact with the secondary exterior wall before engaging the exterior wall with the secondary exterior wall. 8. The method of claim 7 , further comprising positioning the secondary exterior wall and the anti-run-dry membrane in a mold, wherein engaging the exterior wall with the secondary exterior wall comprises molding the exterior wall through use of the mold after positioning the secondary exterior wall and the anti-run-dry membrane in the mold. 9. The method of claim 5 , further comprising: coupling a tubing to the outlet portion, wherein the tubing comprises a first end connectable to the drip unit and a second end; and connecting an intravenous access unit to the second end of the tubing to deliver the liquid intravenously to a patient.