Microfluidic delivery system and method

1 . A microfluidic delivery system, comprising: a first chamber facing a fluid transport member, the first chamber being configured to receive fluid from an end of the fluid transport member; a printed circuit board having a through opening in fluid communication with the first chamber; a semiconductor die mounted on the printed circuit board covering the through opening, the semiconductor die including: a plurality of second chambers in fluid communication with the first chamber and configured to receive the fluid from the first chamber through the through opening in the printed circuit board; a plurality of nozzles in fluid communication with the plurality of second chambers; and a plurality of ejection elements associated with the plurality of second chambers, each of the plurality of ejection elements being configured to cause the fluid in the plurality of second chambers to be expelled through the plurality of nozzles. 2 . The microfluidic delivery system of claim 1 , wherein the semiconductor die is arranged below the printed circuit board and the first chamber. 3 . The microfluidic delivery system of claim 2 , wherein, after fluid exits the plurality of nozzles, the plurality of second chambers refill with fluid to due capillary action and gravity. 4 . The microfluidic delivery system of claim 2 , wherein the plurality of nozzles are sized so that the fluid does not expel through the plurality of nozzles until ejection elements cause the fluid to be expelled through the plurality of nozzles. 5 . The microfluidic delivery system of claim 1 , wherein the semiconductor die is arranged above the printed circuit board and the first chamber. 6 . The microfluidic delivery system of claim 5 , wherein when the fluid that is expelled through the plurality of nozzles, the fluid travels with a trajectory that includes a vertical component in opposition to gravity. 7 . The microfluidic delivery system of claim 6 , wherein after fluid exits the plurality of nozzles, the plurality of second chambers refill with fluid in a fluid path by capillary action. 8 . The microfluidic delivery system of claim 1 , wherein the semiconductor die is arranged horizontally relative to the printed circuit board and the first chamber. 9 . The microfluidic delivery system of claim 8 , wherein when the fluid is expelled through the plurality of nozzles, the fluid travels with a trajectory that includes a horizontal component. 10 . The microfluidic delivery system of claim 1 , wherein the plurality of ejection elements are heating elements configured to heat the fluid in the second chambers creating a vapor bubble that causes fluid to be ejected through the nozzles. 11 . A microfluidic delivery system, comprising: a lid configured to be secured to a reservoir; a first through hole in the lid, a first end of the through hole in fluid communication with the reservoir and configured to receive fluid from an end of a fluid transport member located in the reservoir; a second through hole in the lid, the second through hole being in fluid communication with air in the reservoir; and a microfluidic delivery member coupled to the lid, the microfluidic delivery member including: a plurality of second chambers in fluid communication with the first through hole in the lid; a plurality of nozzles in fluid communication with the plurality of second chambers; and a plurality of ejection elements associated with the plurality of second chambers, each of the ejection elements being configured to cause the fluid in the plurality of second chambers to be expelled through the plurality of nozzles. 12 . The microfluidic delivery system of claim 11 , wherein the lid includes a planar portion and a side portion that extend from the planar portion, wherein the first through hole is in the planar portion of the lid and the second through hole is in the side portion of the lid. 13 . The microfluidic delivery system of claim 12 , wherein the lid further includes a channel in the side portion of the lid, the channel being in fluid communication with the second through hole and with air in the reservoir. 14 . The microfluidic delivery system of claim 13 , wherein the channel has a serpentine shape. 15 . The microfluidic delivery system of claim 13 , further comprising a cover over a portion of the channel and the second through hole. 16 . The microfluidic delivery system of claim 11 , wherein the lid includes a planar portion and a side portion that extends from the planar portion, wherein the first and second through holes are in the planar portion of the lid. 17 . The microfluidic delivery system of claim 16 , wherein the lid further includes a channel in the planar portion of the lid, the channel being in fluid communication with the second through hole and with air in the reservoir. 18 . The microfluidic delivery system of claim 17 , wherein the channel has a serpentine shape. 19 . The microfluidic delivery system of claim 17 , wherein the channel is located on a surface of the planar portion that faces the reservoir. 20 . The microfluidic delivery system of claim 17 , further comprising a cover over a portion of the channel and the second through hole. 21 . The microfluidic delivery system of claim 17 , further comprising a tube having a channel in fluid communication with the second through hole to place the second through hole in fluid communication with the air in the reservoir. 22 . A lid for a microfluidic refill cartridge, the lid comprising: a planar portion having first and second surfaces; a first through hole in the planar portion, the first through hole configured to be in fluid communication with a fluid in a reservoir; a second through hole in the planar portion, the second through hole configured to be in communication with air in the reservoir when the lid is coupled to the reservoir; a circuit board located on the planar portion and having a third through hole that faces the first through hole in the planar portion; and a semiconductor die coupled to the circuit board covering the third through hole, the semiconductor die including a nozzle plate having a plurality of nozzles that are configured to eject fluid received from the reservoir through the third through hole of the circuit board. 23 . The lid of claim 22 , further comprising a channel on a surface of a side, the channel being in fluid communication with the second through hole. 24 . The lid of claim 23 , further comprising a cover over a portion of the channel and the second through hole. 25 . The lid of claim 23 , wherein channel is serpentine shaped. 26 . A lid for a microfluidic refill cartridge, the lid comprising: a planar portion and a side portion extending from the planar portion; a first through hole in the planar portion, the first through hole configured to be in fluid communication with a fluid in a reservoir; a second through hole in the side portion, the second through hole configured to be in communication with air in the reservoir when the lid is coupled to the reservoir; a circuit board located on the planar portion and having a third through hole that faces the first through hole in the planar portion; and a semiconductor die coupled to the circuit board covering the third through hole, the semiconductor die including a nozzle plate having a plurality of nozzles that are configured to eject fluid