초록 ▼

For achieving a fluidic device, being able to be made small in sizes, comprising a fluid inflow opening 1, a connector duct 2, and a fluid jet nozzle, wherein the connector duct 2 is constructed with curves, and is further constructed with two (2) pieces of flow passages, being symmetric on both sid

For achieving a fluidic device, being able to be made small in sizes, comprising a fluid inflow opening 1, a connector duct 2, and a fluid jet nozzle, wherein the connector duct 2 is constructed with curves, and is further constructed with two (2) pieces of flow passages, being symmetric on both sides. Constructing the connector duct with the curves reduces resistance of fluid within the duct, and further dividing the connector duct into two (2) parts in both side enhances the flows at confluent point in the duct (increase of the flow velocity).

대표청구항 ▼

What is claimed is: 1. A fluidic device, comprising: a fluid inflow opening; a connector duct; and a fluid jet nozzle portion, wherein fluid flow within said connector duct is driven by a pressure difference at said fluid jet nozzle portion, said pressure difference being reversed as a result of fl

What is claimed is: 1. A fluidic device, comprising: a fluid inflow opening; a connector duct; and a fluid jet nozzle portion, wherein fluid flow within said connector duct is driven by a pressure difference at said fluid jet nozzle portion, said pressure difference being reversed as a result of fluid flow, and again being driven, thereby oscillating, and further said connector duct is constructed with curved surfaces delimiting two pieces of flow passages that are symmetric with respect to each other; wherein said two pieces of flow passages are joined at a joining portion of said connector duct, so as to increase the velocity of the fluid flowing out of said fluid jet nozzle portion. 2. A fluidic device, comprising: a fluid flow opening; a connector duct; and a fluid jet nozzle portion, wherein fluid flow within said connector duct is driven by a pressure difference at said fluid jet nozzle portion, said pressure difference being reversed as a result of fluid flow, and again being driven, thereby oscillating, and further said connector duct is constructed with a plural number of flow passages; wherein said connector duct is made of curved surfaces delimiting two pieces of flow passages, being symmetric with each other, and said fluid inflow opening and said fluid jet nozzle portion are disposed in a center between said two pieces of flow passages; and wherein said two pieces of flow passages are joined at a joining portion of said connector duct, so as to increase the velocity of the fluid flowing out of said fluid jet nozzle portion. 3. The fluidic device, as described in the claim 1, wherein said connector duct is constructed with a wind guiding plate. 4. The fluidic device, as described in the claim 2, wherein said connector duct is constructed with a wind guiding plate. 5. The fluidic device, as described in claim 1, wherein a guide vane is provided within said connector duct. 6. The fluidic device, as described in the claim 1, wherein said connector duct is constructed with a space defined between a connector duct reverse plate and a connector duct front plate, and said fluid inflow opening is formed on said connector duct reverse plate while said fluid jet nozzle portion is provided on said connector duct front plate. 7. The fluidic device, as described in the claim 4, wherein said connector duct is constructed with a space defined between a connector duct reverse plate and a connector duct front plate, and said fluid inflow opening is formed on said connector duct reverse plate while said fluid jet nozzle portion is provided on said connector duct front plate. 8. The fluidic device, as described in the claim 1, further comprising a partition wall in a cylindrical shape, being connected to said fluid jet nozzle portion. 9. The fluidic device, as described in the claim 4, further comprising a partition wall in a cylindrical shape, being connected to said fluid jet nozzle portion. 10. The fluidic device, as described in the claim 8, wherein said partition wall has an air hole therein. 11. The fluidic device, as described in the claim 9, wherein said partition wall has an air hole therein. 12. The fluidic device, as described in the claim 1, wherein said fluid jet nozzle portion is smaller at an upstream part in the direction of the fluid flow than at a downstream part in cross-section area thereof. 13. The fluidic device, as described in the claim 4, wherein said fluid jet nozzle portion is smaller at an upstream part in the direction of the fluid flow than at a downstream part in cross-section area thereof. 14. The fluidic device, as described in claim 1, wherein said fluid inflow opening, said connector duct, and said fluid jet nozzle portion are installed within a housing in a cylindrical shape or in a spherical shape. 15. The fluidic device, as described in claim 3, wherein the wind guiding plate has a curved surface. 16. The fluidic device, as described in claim 4, wherein the wind guiding plate has a curved surface. 17. The fluidic device according to claim 1, wherein said connector duct is configured with a first portion and a second portion including a reverse plate of said connector duct and a front plate of said connector duct, wherein said first portion and said second portion are fixed to each other. 18. The fluidic device according to claim 2, wherein said connector duct is configured with a first portion and a second portion including a reverse plate of said connector duct and a front plate of said connector duct, wherein said first portion and said second portion are fixed to each other. 19. The fluidic device according to claim 1, wherein said fluid jet nozzle portion comprises part of an air shower apparatus. 20. The fluidic device according to claim 2, wherein said fluid jet nozzle portion comprises part of an air shower apparatus.