Fluid application systems including pressure dampeners

What is claimed is: 1. A fluid application system comprising: a manifold defining an internal passageway; and a plurality of nozzle assemblies connected in fluid communication with the internal passageway, wherein each nozzle assembly of the plurality of nozzle assemblies comprises: a body defining a fluid passage; an inlet connected to the manifold for receiving fluid flow into the fluid passage; a spray outlet for discharging fluid from the fluid passage; an electrically actuated valve fluidly connected between the inlet and the spray outlet and configured to control fluid flow through the fluid passage; and a pressure dampener connected in fluid communication with the fluid passage between the inlet and the spray outlet and configured to dampen fluctuations in fluid pressure within the fluid passage. 2. The fluid application system of claim 1 further comprising a controller communicatively connected to the electrically actuated valve of each of the plurality of nozzle assemblies, wherein the controller is configured to control the electrically actuated valves independently of one another. 3. The fluid application system of claim 1 , wherein the pressure dampener of each nozzle assembly comprises a standpipe. 4. The fluid application system of claim 3 , wherein the standpipe is a cylinder. 5. The fluid application system of claim 1 , wherein the pressure dampener of each nozzle assembly is oriented vertically and perpendicular to a travel direction of the fluid application system. 6. The fluid application system of claim 1 , wherein the pressure dampener of each nozzle assembly comprises a sidewall defining a cavity having a volume containing gas therein. 7. The fluid application system of claim 6 , wherein each nozzle assembly further comprises a fluid line defining a fluid passage providing fluid communication between the fluid passage of the nozzle assembly and the cavity of the pressure dampener. 8. The fluid application system of claim 1 , wherein the pressure dampener of each nozzle assembly is connected in fluid communication with the fluid passage between the inlet and the electrically actuated valve. 9. The fluid application system of claim 1 , wherein the pressure dampener of each nozzle assembly is connected in fluid communication with the fluid passage upstream of the electrically actuated valve. 10. A fluid application system comprising: a manifold defining an internal passageway; a plurality of nozzles connected in fluid communication with the internal passageway, each nozzle defining a spray outlet for discharging fluid therefrom; a plurality of electrically actuated valves configured to control fluid flow through the plurality of nozzles, wherein each electrically actuated valve of the plurality of electrically actuated valves is connected in fluid communication with a corresponding nozzle of the plurality of nozzles between the manifold and the spray outlet of the corresponding nozzle for controlling fluid flow through the corresponding nozzle; and a plurality of pressure dampeners, wherein each pressure dampener of the plurality of pressure dampeners is connected in fluid communication with a corresponding electrically actuated valve of the plurality of electrically actuated valves between the manifold and the spray outlet of the corresponding nozzle connected in fluid communication with the electrically actuated valve. 11. The fluid application system of claim 10 further comprising a controller communicatively connected to each of the plurality of electrically actuated valves, wherein the controller is configured to control the electrically actuated valves independently of one another. 12. The fluid application system of claim 10 , wherein each pressure dampener of the plurality of pressure dampeners comprises a standpipe. 13. The fluid application system of claim 12 , wherein the standpipe is a cylinder. 14. The fluid application system of claim 10 , wherein each pressure dampener of the plurality of pressure dampeners is oriented vertically and perpendicular to a travel direction of the fluid application system. 15. The fluid application system of claim 10 , wherein each pressure dampener of the plurality of pressure dampeners comprises a sidewall defining a cavity having a volume containing gas therein. 16. The fluid application system of claim 10 , wherein each pressure dampener is connected in fluid communication upstream of the corresponding electrically actuated valve. 17. A nozzle assembly for use with a fluid application system, the nozzle assembly comprising: a body defining a fluid passage; an inlet for receiving fluid flow into the fluid passage; a spray outlet for discharging fluid from the fluid passage; an electrically actuated valve fluidly connected between the inlet and the spray outlet and configured to control fluid flow through the fluid passage; and a pressure dampener connected in fluid communication with the fluid passage between the inlet and the spray outlet and configured to dampen fluctuations in fluid pressure within the fluid passage. 18. The nozzle assembly of claim 17 , wherein the pressure dampener comprises a sidewall defining a cavity having a volume containing gas therein. 19. The nozzle assembly of claim 18 further comprising a fluid line defining a fluid passage providing fluid communication between the fluid passage defined by the nozzle assembly body and the cavity of the pressure dampener. 20. The nozzle assembly of claim 17 , wherein the pressure dampener is connected in fluid communication with the fluid passage upstream of the electrically actuated valve.