초록 ▼

The present invention features a fluid flow regulator that functions to significantly influence fluid flow across the surface of an object, as well as to significantly effect the performance of the object subjected to the fluid. The fluid flow regulator comprises a pressure recovery drop that induce

The present invention features a fluid flow regulator that functions to significantly influence fluid flow across the surface of an object, as well as to significantly effect the performance of the object subjected to the fluid. The fluid flow regulator comprises a pressure recovery drop that induces a sudden drop in pressure at an optimal pressure recovery point on said surface, such that a sub-atmospheric barrier is created that serves as a cushion between the molecules in the fluid and the molecules at the object's surface.

대표청구항 ▼

What is claimed and desired to be secured by Letters Patent is: 1. A nozzle comprising: an intake for initially receiving a fluid therein; a surface relating with said intake that receives fluid flow thereon; a discharge providing an exit for said fluid from said nozzle; and at least one dynamic f

What is claimed and desired to be secured by Letters Patent is: 1. A nozzle comprising: an intake for initially receiving a fluid therein; a surface relating with said intake that receives fluid flow thereon; a discharge providing an exit for said fluid from said nozzle; and at least one dynamic fluid flow regulator featured and operable with said surface, said fluid flow regulator comprising: a leading edge, a trailing edge, and an orthogonal pressure recovery drop extending between said leading and trailing edges to form a down step, said pressure recovery drop comprising at least one drop face, and means for increasing the height of said drop face. 2. The nozzle of claim 1, wherein said fluid flow regulator is positioned to decrease the separation potential of said fluid. 3. The nozzle of claim 1, said fluid encounters and flows over said pressure recovery drop, producing a low pressure area of fluid molecules having decreased kinetic energy at said surface to facilitate laminar flow and assist in the reduction of the separation potential of said fluid. 4. An exhaust system comprising: an intake coupled to and initially receiving a fluid from a fluid generator; a surface relating with said intake that receives fluid flow thereon; a discharge providing an exit for said fluid from said exhaust system; and at least one fluid flow regulator featured and operable with said surface, said fluid flow regulator comprising a leading edge, a trailing edge, and an orthogonal pressure recovery drop extending between said leading and trailing edges to form a down step, said pressure recovery drop comprising at least one drop face of a calculated distance formed therein, said fluid flow regulator functioning to optimize air flow, reduce separation of said fluid over said surface relating with said intake of said exhaust system, and reduce induced noise. 5. The nozzle of claim 1, wherein said pressure recovery drop comprises a formation selected from the group consisting of linear, curved, spline, and any combination of these. 6. The nozzle of claim 1, wherein said fluid flow regulator comprises a pressure gradient regulator. 7. The nozzle of claim 1, wherein said pressure recovery drop extends entirely across said surface. 8. The nozzle of claim 1, wherein said pressure recovery drop extends across only a portion of said surface. 9. The nozzle of claim 1, wherein said surface comprises a plurality of fluid flow regulators that function together to regulate, influence, and control fluid flow and its properties and characteristics across said surface. 10. The nozzle of claim 1, wherein said fluid flow regulator is a dynamic fluid flow regulator capable of adjusting, on demand, with varying design constraints, flow characteristics, environmental conditions, and operational situations pertaining to said fluid, said device, and any combination of these during. 11. The nozzle of claim 10, wherein said dynamic fluid flow regulator comprises at least one selectively adjustable element, wherein said adjustable elements are selected from a movable leading edge, a movable pressure recovery drop, and a movable trailing edge, each capable of adjusting the height of said drop face and said pressure drop. 12. The nozzle of claim 1, wherein said fluid flow regulator comprises means for effectuating vector positioning about said surface. 13. The nozzle of claim 1, wherein said fluid flow regulator comprises at least one component that oscillates with varying situations and conditions to vary the height of said pressure recovery drop. 14. The nozzle of claim 1, wherein said leading edge is integrally formed with said surface. 15. The nozzle of claim 1, wherein said pressure recovery drop is integrally formed with said surface. 16. The nozzle of claim 1, wherein said trailing edge is integrally formed with said surface. 17. The nozzle of claim 1, wherein said leading edge, said pressure recovery drop, and said trailing edge of said fluid flow regulator are each embodied in a fluid flow regulator device that is removably attachable to an existing surface to allow said existing surface to comprise one or more fluid flow regulators. 18. The nozzle of claim 1, wherein said pressure recovery drop comprises a plurality of drop faces to magnify the influence of fluid flow regulator on said fluid. 19. The exhaust system of claim 18, wherein said plurality of drop faces each comprise a sub-atmospheric barrier. 20. The exhaust system of claim 1, wherein said pressure recovery drop is positioned at or proximate an optimal pressure recovery point defined as the location(s) about said surface at which there is an imbalanced or unequal pressure gradient forward and aft of said fluid, thus creating an adverse pressure within said device, which adverse pressure gradient induces friction and pressure drag that ultimately increases the separation potential of said fluid. 21. The exhaust system of claim 1, wherein said fluid is selected from the group consisting of gaseous fluids, liquid fluids, and any combination of these. 22. An exhaust system comprising: an intake coupled to and initially receiving a fluid from a fluid generator; a surface relating with said intake that receives fluid flow thereon; a discharge providing an exit for said fluid from said exhaust system; and at least one dynamic fluid flow regulator featured and operable with said surface, said fluid flow regulator comprising a leading edge, a trailing edge, and a an orthogonal pressure recovery drop extending between said leading and trailing edges to form a down step, said pressure recovery drop comprising at least one drop face of a calculated distance formed therein, and means for vertically positioning the height of said drop, said fluid flow regulator functioning to optimize air flow, reduce separation of said fluid over said surface relating with said intake of said exhaust system, and reduce induced noise. 23. The exhaust system of claim 22, wherein said pressure recovery drop is oriented in a position selected from the group consisting of perpendicular to the direction of flow of said fluid, substantially perpendicular to the direction of flow of said fluid, on an angle with respect to said direction of flow of said fluid, parallel or substantially parallel to the direction of flow of said fluid, and any combination of these. 24. The exhaust system of claim 22, wherein said pressure recovery drop comprises a formation selected from the group consisting of linear, curved, spline, and any combination of these. 25. The exhaust system of claim 22, wherein said fluid flow regulator comprises a pressure gradient regulator. 26. The exhaust system of claim 22, wherein said pressure recovery drop extends entirely across said surface. 27. The exhaust system of claim 22, wherein said pressure recovery drop extends across only a portion of said surface. 28. The exhaust system of claim 22, wherein said surface comprises a plurality of fluid flow regulators that function together to regulate, influence, and control fluid flow and its properties and characteristics across said surface. 29. The exhaust system of claim 22, wherein said fluid flow regulator is a dynamic fluid flow regulator capable of adjusting, on demand, with varying design constraints, flow characteristics, environmental conditions, and operational situations pertaining to said fluid, said device, and any combination of these during. 30. The exhaust system of claim 29, wherein said dynamic fluid flow regulator comprises at least one selectively adjustable element, wherein said adjustable elements are selected from a movable leading edge, a movable pressure recovery drop, and a movable trailing edge, each capable of adjusting the height of said drop face and said pressure drop. 31. The exhaust system of claim 22, wherein said fluid flow regulator comprises means for effectuating vector positioning about said surface. 32. The exhaust system of claim 22, wherein said fluid flow regulator comprises at least one component that oscillates with varying situations and conditions to vary the height of said pressure recovery drop. 33. The exhaust system of claim 22, wherein said leading edge is integrally formed with said surface. 34. The exhaust system of claim 22, wherein said pressure recovery drop is integrally formed with said surface. 35. The exhaust system of claim 22, wherein said trailing edge is integrally formed with said surface. 36. The exhaust system of claim 22, wherein said leading edge, said pressure recovery drop, and said trailing edge of said fluid flow regulator are each embodied in a fluid flow regulator device that is removably attachable to an existing surface to allow said existing surface to comprise one or more fluid flow regulators. 37. The exhaust system of claim 22, wherein said pressure recovery drop comprises a plurality of drop faces to magnify the influence of fluid flow regulator on said fluid. 38. The exhaust system of claim 37, wherein said plurality of drop faces each comprise a sub-atmospheric barrier. 39. The exhaust system of claim 22, wherein said pressure recovery drop is positioned at or proximate an optimal pressure recovery point defined as the location(s) about said surface at which there is an imbalanced or unequal pressure gradient forward and aft of said fluid, thus creating an adverse pressure within said device, which adverse pressure gradient induces friction and pressure drag that ultimately increases the separation potential of said fluid. 40. The exhaust system of claim 22, wherein said fluid is selected from the group consisting of gaseous fluids, liquid fluids, and any combination of these. 41. A conduit comprising: an conduit intake capable of receiving a fluid therein; a surface relating with said conduit intake that receives fluid flow thereon; a conduit discharge providing an exit for said fluid from said conduit; and at least one dynamic fluid flow regulator featured and operable with said surface, said fluid flow regulator comprising a leading edge, a trailing edge, a pressure recovery drop extending between said leading and trailing edges to form a down step, and means for adjusting the height of said drop said pressure recovery drop comprising at least one drop face of a calculated distance formed therein, said fluid flow regulator functioning to optimize air flow, reduce separation of said fluid over said first surface of said conduit, and reduce induced noise. 42. A method for influencing internal fluid flow and regulating pressure gradients within an internal flow device or system and for influencing the rate and magnitude of pressure recovery about a surface within said device, said method comprising the steps of: featuring at least one fluid flow regulator with one or more surfaces of an internal fluid flow device having at least one surface thereon, said fluid flow regulator comprising: a pressure recovery drop having at least one drop face formed therein, said drop face comprising a calculated height; subjecting said device to a fluid, such that said fluid is caused to move within said device; causing said fluid to encounter said fluid flow regulator, such that said pressure recovery drop induces a sudden drop in pressure as said fluid flows over said fluid flow regulator, wherein a sub-atmospheric barrier is created at the base of said drop face, said fluid flow regulator functioning to optimize fluid flow within said device, thus increasing the performance of said device; and dynamically adjusting the height of said recovery drop in response to variable fluid conditions. 43. The method of claim 42, wherein said step of featuring comprises the step of positioning said fluid flow regulator at an optimal pressure recovery point. 44. The method of claim 43, wherein said step of positioning said fluid flow regulator comprises positioning it in an orientation selected from the group consisting of perpendicular to the direction of flow of said fluid, substantially perpendicular to the direction of flow of said fluid, on an angle with respect to said direction of flow of said fluid, parallel or substantially parallel to the direction of flow of said fluid, and any combination of these. 45. The method of claim 43, further comprising the step of repositioning said fluid flow regulator as said optimal pressure recovery points change in response to varying conditions surrounding said fluid flow. 46. The method of claim 42, further comprising the step of varying said pressure recovery drop, and particularly said height of said drop face in response to changing conditions. 47. The method of claim 42, wherein said step of causing said fluid to encounter said fluid flow regulator has the effect of optimizing fluid flow and the performance of said object within said fluid, said fluid flow regulator: regulating the pressure gradients that exist along said surface by reducing the pressure drag at various locations along said surface, as well as the pressure drag induced within forward and aft of said fluid in said device, via a pressure recovery drop; increasing pressure recovery and pressure recovery potential as a result of regulating said pressure gradients and reducing said pressure drag; reducing friction drag along said surface as a result of increasing said pressure recovery; and decreasing fluid separation and fluid separation potential as a result of said reducing friction drag.