Claims
- 1. A rail assembly for use with a pressurized fluid, the rail assembly comprising:
a fluid passageway; a first cavity disposed in the fluid passageway; a first orifice, disposed between the first cavity and the fluid passageway, wherein the first cavity, the fluid passageway, and the first orifice are in fluid communication, and wherein the first orifice is capable of attenuating waves in the pressurized fluid in the fluid passageway by causing frictional drag in fluid adjacent to the first orifice.
- 2. The rail assembly of claim 1, wherein the first cavity is disposed between a first portion of the fluid passageway and a second portion of the fluid passageway, wherein the first orifice is disposed between the first portion of the fluid passageway and the first cavity, wherein the first orifice is capable of attenuating waves in the pressurized fluid in the first portion of the fluid passageway, wherein a second orifice is disposed between the second portion of the fluid passageway and the first cavity, wherein the first cavity, the fluid passageway, and the second orifice are in fluid communication, and wherein the second orifice is capable of attenuating waves in the pressurized fluid in the second portion of the fluid passageway by causing frictional drag in fluid adjacent to the second orifice.
- 3. The rail assembly of claim 1, wherein the first cavity is disposed at a first end of the fluid passageway, wherein the rail assembly further comprises:
a second cavity disposed at a second end of the fluid passageway, a second orifice, disposed between the second cavity and the fluid passageway, wherein the second cavity, the fluid passageway, and the second orifice are in fluid communication, and wherein the second orifice is capable of attenuating waves in the pressurized fluid in the fluid passageway by causing frictional drag in fluid adjacent to the second orifice.
- 4. The rail assembly of claim 1, wherein the first cavity is disposed in an end cap engaged with the rail assembly.
- 5. The rail assembly of claim 1, further comprising at least one fluid outlet port disposed in the fluid passageway.
- 6. The rail assembly of claim 1, wherein the pressurized fluid is at least one of fuel and oil.
- 7. The rail assembly of claim 1, wherein the orifice is arranged and constructed to attenuate the waves in a predetermined frequency range.
- 8. The rail assembly of claim 1, wherein the fluid passageway is an elongate fluid passageway.
- 9. A method comprising the steps of:
receiving a pressurized fluid in a fluid passageway; providing fluid communication between the fluid passageway and a cavity through an orifice; attenuating waves in the fluid passageway by absorbing energy in the waves adjacent to the orifice.
- 10. The method of claim 9, wherein the step of attenuating comprises the steps of:
vibrating fluid in the orifice; exciting fluid in the cavity; and amplifying motion of the fluid in the orifice, thereby absorbing energy in the waves.
- 11. The method of claim 9, wherein the step of attenuating comprises the step of causing frictional drag in fluid adjacent to the orifice.
- 12. The method of claim 9, wherein the step of attenuating comprises attenuating the waves in a frequency range determined by the size of the orifice.
- 13. The method of claim 9, wherein the step of attenuating comprises attenuating the waves in a frequency range of 700 Hz to 2000 Hz.
- 14. A rail assembly for use with a pressurized fluid, the rail assembly comprising:
a fluid passageway; a first acoustic wave attenuator disposed in the fluid passageway, wherein the first acoustic wave attenuator is in fluid communication with the fluid passageway, and wherein the first acoustic wave attenuator is capable of attenuating waves in the pressurized fluid in the fluid passageway by absorbing energy in the waves.
- 15. The rail assembly of claim 14, wherein the first acoustic wave attenuator is disposed between a first portion of the fluid passageway and a second portion of the fluid passageway, and wherein the first acoustic wave attenuator is capable of attenuating waves in the pressurized fluid in the first section and the second section of the fluid passageway by absorbing energy in the waves.
- 16. The rail assembly of claim 14, wherein the first acoustic wave attenuator is disposed at a first end of the fluid passageway, wherein the rail assembly further comprises a second acoustic wave attenuator disposed at a second end of the fluid passageway, wherein the second acoustic wave attenuator is in fluid communication with the fluid passageway, and wherein the second acoustic wave attenuator is capable of attenuating waves in the pressurized fluid in the fluid passageway by absorbing energy in the waves.
- 17. The rail assembly of claim 14, wherein the first acoustic wave attenuator comprises a cavity and an orifice, wherein the orifice has a first end adjacent to the cavity, a second end opposed to the first end, and a beveled surface, wherein the second end of the orifice is larger than the first end of the orifice.
- 18. The rail assembly of claim 14, wherein the first acoustic wave attenuator is capable of attenuating waves in the pressurized fluid in the fluid passageway by vibrating the fluid in at least a part of the acoustic wave attenuator.
- 19. The rail assembly of claim 14, wherein the first acoustic wave attenuator is capable of attenuating waves in the pressurized fluid in the fluid passageway by causing frictional drag in fluid adjacent to the first acoustic wave attenuator.
- 20. The rail assembly of claim 14, wherein the first acoustic wave attenuator is disposed in an end cap engaged with the rail assembly.
- 21. The rail assembly of claim 14, further comprising at least one fluid outlet port disposed in the fluid passageway.
- 22. The rail assembly of claim 14, wherein the pressurized fluid is at least one of fuel and oil.
- 23. The rail assembly of claim 14, wherein the first acoustic wave attenuator is arranged and constructed to attenuate the waves in a predetermined frequency range.
- 24. An end cap utilizable with a rail assembly capable of enclosing a pressurized fluid within a fluid passageway, the end cap comprising:
a cavity disposed within a housing; an orifice disposed at a first end of the cavity and in fluid communication with the cavity, wherein the orifice capable of being in fluid communication with the fluid passageway, and wherein the orifice is capable of attenuating waves in the pressurized fluid in the fluid passageway; an engagement mechanism disposed on an outer surface of the housing and capable of engaging the rail assembly.
- 25. The end cap of claim 24, further comprising a plug disposed at the first end of the cavity and comprising the orifice.
- 26. The end cap of claim 24, wherein the orifice has a first end adjacent to the cavity, a second end opposed to the first end, and a beveled surface, wherein the second end of the orifice is larger than the first end of the orifice.
- 27. The end cap of claim 24, wherein the orifice is capable of attenuating waves in the pressurized fluid in the fluid passageway by causing frictional drag in fluid adjacent to the first orifice.
- 28. The end cap of claim 24, wherein the orifice is capable of attenuating waves in the pressurized fluid in the fluid passageway by vibrating fluid in the orifice, thereby exciting fluid in the cavity and absorbing energy in the waves.
- 29. The end cap of claim 24, wherein the engagement mechanism comprises threads.
- 30. The end cap of claim 24, wherein the pressurized fluid is at least one of fuel and oil.
- 31. The end cap of claim 24, wherein the orifice is arranged and constructed to attenuate the waves in a predetermined frequency range.
- 32. A rail assembly for use with a pressurized fluid, the rail assembly comprising:
a first cavity in fluid communication with and disposed in a first end cap at a first end of a first portion of an elongate fluid passageway; a second cavity in fluid communication with and disposed in a second end cap at a first end of a second portion of the elongate fluid passageway; a third cavity in fluid communication with and disposed at the second end of the first portion of the elongate fluid passageway and at the second end of the second portion of the elongate fluid passageway; at least one fluid outlet port disposed in the elongate fluid passageway; a first orifice, disposed between the first cavity and the first portion of the elongate fluid passageway; a second orifice, disposed between the second cavity and the second portion of the elongate fluid passageway; a third orifice, disposed between the third cavity and the first portion of the elongate fluid passageway; a fourth orifice, disposed between the third cavity and the second portion of the elongate fluid passageway; wherein the first orifice, the second orifice, the third orifice, and the fourth orifice are each capable of attenuating waves in the pressurized fluid in the elongate fluid passageway by vibrating fluid in the respective orifice.
- 33. The rail assembly of claim 32, wherein the pressurized fluid is at least one of fuel and oil.
- 34. The rail assembly of claim 32, wherein each orifice is arranged and constructed to attenuate the waves in a predetermined frequency range.
CROSS REFERENCE TO RELATED APPLICATIONS
[0001] This application is related to U.S. patent application Ser. No. 10/177,195, filed Jun. 21, 2002, on behalf of the same inventors as the present application, and assigned to the assignee hereof and is related to U.S. patent application Ser. No. 10/177,202, filed Jun. 21, 2002, on behalf of the same inventors as the present application, and assigned to the assignee hereof.
Continuation in Parts (1)
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Number |
Date |
Country |
Parent |
10177195 |
Jun 2002 |
US |
Child |
10463179 |
Jun 2003 |
US |