Venturi inlet printhead

The invention claimed is: 1. A jetting assembly for ejecting a print material, comprising: a jetting assembly block, wherein the jetting assembly block defines: a pump chamber; a converging part having a first end with a first width and a second end with a second width, wherein the first width is wider than the second width; and a nozzle bore terminating in a nozzle from which a print material is ejected, wherein: the converging part is positioned between the pump chamber and the nozzle bore; the first end of the converging part is proximate the pump chamber; the second end of the converging part is proximate the nozzle bore; and the pump chamber, the converging part, and the nozzle bore are in fluid communication, each with the other; a diverging part having a third end with a third width and a fourth end having a fourth width, wherein: the third width is narrower than the fourth width; the diverging part is positioned between the converging part and the nozzle bore; the third end is proximate the converging part; the fourth end is proximate the nozzle bore; the diverging part is in fluid communication with the pump chamber, the converging part, and the nozzle bore; and the converging part and the diverging part define, at least in part, a venturi; and an actuator configured to apply a pressure to a print material within the pump chamber. 2. The jetting assembly of claim 1 , wherein the venturi further comprises a throat positioned between, and in fluid communication with, the converging part and the diverging part. 3. The jetting assembly of claim 2 , wherein radial centers of the pump chamber, the converging part, the throat, the diverging part, the nozzle bore, and the nozzle are aligned along an axis. 4. The jetting assembly of claim 2 , wherein the jetting assembly block further defines a supply channel that ends in a supply port, wherein the supply channel opens into the throat of the venturi at the supply port. 5. The jetting assembly of claim 1 , wherein the jetting assembly block further defines a supply channel that ends in a supply port, wherein the supply channel opens into the nozzle bore. 6. The jetting assembly of claim 1 , wherein radial centers of the pump chamber, the converging part, the nozzle bore, and the nozzle are aligned along an axis. 7. The jetting assembly of claim 1 , further comprising a print material within the pump chamber, the converging part, and the nozzle bore. 8. A printer, comprising: a jetting assembly for ejecting a print material, the jetting assembly comprising a jetting assembly block, wherein the jetting assembly block defines: a pump chamber; a converging part having a first end with a first width and a second end with a second width, wherein the first width is wider than the second width; and a nozzle bore terminating in a nozzle from which a print material is ejected, wherein: the converging part is positioned between the pump chamber and the nozzle bore; the first end of the converging part is proximate the pump chamber; the second end of the converging part is proximate the nozzle bore; and the pump chamber, the converging part, and the nozzle bore are in fluid communication, each with the other; a diverging part having a third end with a third width and a fourth end having a fourth width, wherein: the third width is narrower than the fourth width; the diverging part is positioned between the converging part and the nozzle bore; the third end is proximate the converging part; the fourth end is proximate the nozzle bore; the diverging part is in fluid communication with the pump chamber, the converging part, and the nozzle bore; and the converging part and the diverging part define, at least in part, a venturi; and an actuator configured to apply a pressure to a print material within the pump chamber; and a housing that encases the jetting assembly. 9. The printer of claim 8 , wherein the venturi further comprises a throat positioned between, and in fluid communication with, the converging part and the diverging part. 10. The printer of claim 9 , wherein radial centers of the pump chamber, the converging part, the throat, the diverging part, the nozzle bore, and the nozzle are aligned along an axis. 11. The printer of claim 9 , wherein the jetting assembly block further defines a supply channel that ends in a supply port, wherein the supply channel opens into the throat of the venturi at the supply port. 12. The printer of claim 8 , wherein the jetting assembly block further defines a supply channel that ends in a supply port, wherein the supply channel opens into the nozzle bore. 13. The printer of claim 8 , wherein radial centers of the pump chamber, the converging part, the nozzle bore, and the nozzle are aligned along an axis. 14. The printer of claim 8 , further comprising a print material within the pump chamber, the converging part, and the nozzle bore. 15. A method for printing, comprising: firing an actuator to apply a pressure to a print material within a pump chamber; increasing a velocity of the print material within the pump chamber responsive to the firing of the actuator; flowing the print material from the pump chamber into first end of a converging part, through the converging part, and to a second end of the converging part responsive to the firing of the actuator, wherein the first end has a first width, the second end has a second width, and the first width is wider than the second end; flowing the print material from the second end of the converging part to a throat; then flowing the print material from the throat to a third end of a diverging part, through the diverging part, and to a fourth end of the diverging part, wherein: the third end of the diverging part has a third width; the fourth end of the diverging part has a fourth width; the third width is narrower than the fourth width; and the converging part, the throat, and the diverging part define, at least in part, a venturi; flowing the print material from the fourth end of the diverging part into a nozzle bore, and flowing the print material from the nozzle bore to the nozzle, responsive to the firing of the actuator; and ejecting a drop of the print material from the nozzle responsive to the firing of the actuator. 16. The method of claim 15 , further comprising: increasing a velocity of the print material as the print material passes through the throat; decreasing a pressure of the print material within the throat responsive to the increasing of the velocity; and resupplying at least a portion of a volume of the printed drop from a supply channel, through a supply port, and into the throat responsive to the decreasing of the pressure of the print material within the throat; then performing the ejecting of the drop of the print material from the nozzle after performing the resupplying. 17. The method of claim 15 , further comprising: increasing a velocity of the print material as the print material passes through the nozzle bore; decreasing a pressure of the print material within the nozzle bore responsive to the increasing of the velocity; and resupplying at least a portion of a volume of the printed drop from a supply channel, through a supply port, and into the nozzle bore responsive to the decreasing of the pressure of the print material within the nozzle bore; then performing the ejecting of the drop of the print material from the nozzle after performing the resupplying. 18. The method of claim 15 , further comprising: decreasing a pressure