Pressurized fluid line deresonator

I claim: 1. A deresonated fluid system, comprising: a pressurizable fluid line having distal, opposite line ends, the fluid line extending between the line ends; a source configured to apply variations in pressure of fluid in the fluid line having a frequency appropriate for producing a standing wave in the fluid line between the line ends; a fluid coupler having opposite first and second coupler ends attached to the fluid line in a medial portion of the fluid line between the line ends; a flow acceleration ramp formed about an inside of the first coupler end; and an artificial acoustic shoulder formed about an inside of the second coupler end, the artificial acoustic shoulder defining a substantially central orifice in fluid communication with the flow acceleration ramp; wherein the standing wave has a wavelength, and the artificial acoustic shoulder is disposed at least one-tenth of the wavelength from a nearest position in the fluid line that is an integral number of half wavelengths from one of the line ends when the fluid line is open ended and that is an odd integral number of quarter wavelengths from one of the line ends when the fluid line is closed ended. 2. The deresonated fluid system of claim 1 , wherein the central orifice has a first cross-sectional area normal to a direction of fluid flow through the central orifice that is less than one half of a second cross-sectional area inside the fluid line proximate the second coupler end. 3. The deresonated fluid system of claim 2 , wherein the first cross-sectional area is less than one-fourth of the second cross-sectional area. 4. The deresonated fluid system of claim 1 , wherein the artificial acoustic shoulder is spaced from a terminal edge of the second coupler end and the second coupler end defines a fluid passageway having a uniform cross-sectional configuration normal to a direction of fluid flow through the second coupler end between the terminal edge and the artificial acoustic shoulder. 5. The deresonated fluid system of claim 1 , wherein the flow acceleration ramp tapers between a terminal edge of the first coupler end and the central orifice. 6. The deresonated fluid system of claim 5 , wherein the flow acceleration ramp is frustoconical in shape. 7. The deresonated fluid system of claim 1 , wherein the artificial acoustic shoulder extends from the central orifice normal to a direction of fluid flow through the central orifice. 8. A method comprising: applying variations in pressure of fluid in a fluid line having distal, opposite line ends, the pressure variations having a frequency appropriate for producing a standing wave in the fluid line between the line ends; inserting a fluid-line deresonator into the fluid line in a medial portion of the fluid line between and spaced from the line ends, the fluid-line deresonator having a flow acceleration ramp and an artificial acoustic shoulder defining a substantially central orifice in fluid communication with the flow acceleration ramp; and determining a wavelength of the standing wave; wherein inserting the fluid-line deresonator into the fluid line includes inserting the fluid-line deresonator at least one-tenth of a wavelength from a nearest position in the fluid line that is an integral number of half wavelengths from one of the line ends if the fluid line is open ended and that is an odd integral number of quarter wavelengths from one of the line ends if the fluid line is closed ended. 9. The method of claim 8 , wherein inserting into the fluid line a fluid-line deresonator includes inserting into the fluid line a fluid-line deresonator having an artificial acoustic shoulder that is sufficiently transverse to a direction of fluid flow through the central orifice to partially reflect a pulse of pressurized fluid impinging the artificial acoustic shoulder from the fluid line. 10. The method of claim 9 , wherein inserting into the fluid line a fluid-line deresonator includes inserting into the fluid line a fluid-line deresonator having a flow acceleration ramp that tapers from proximate the fluid line to the central orifice. 11. A method comprising: applying variations in pressure of fluid in a fluid line having distal, opposite line ends, the pressure variations having a frequency appropriate for producing a standing wave in the fluid line between the line ends; determining a wavelength of the standing wave; inserting a fluid-line deresonator into the fluid line with an artificial acoustic shoulder of the fluid-line deresonator at least one-tenth of a wavelength from a nearest position in the fluid line that is an integral number of half wavelengths from one of the line ends if the fluid line is open ended and that is an odd integral number of quarter wavelengths from one of the line ends if the fluid line is closed ended, the fluid-line deresonator further having a flow acceleration ramp and the artificial acoustic shoulder defines a substantially central orifice in fluid communication with the flow acceleration ramp; and causing fluid to flow in a general direction from the flow acceleration ramp toward the acoustic shoulder. 12. The method of claim 11 , wherein inserting into the fluid line a fluid-line deresonator includes inserting into the fluid line a fluid-line deresonator having an artificial acoustic shoulder that is sufficiently transverse to a direction of fluid flow through the central orifice to partially reflect a pulse of pressurized fluid impinging the artificial acoustic shoulder from the fluid line. 13. The method of claim 11 , wherein inserting into the fluid line a fluid-line deresonator includes inserting into the fluid line a fluid-line deresonator having a flow acceleration ramp that tapers from proximate the fluid line to the central orifice. 14. The method of claim 11 , wherein the central orifice has a first cross-sectional area normal to a direction of fluid flow through the central orifice that is less than one half of a second cross-sectional area inside the fluid line. 15. The method of claim 14 , wherein the first cross-sectional area is less than one-fourth of the second cross-sectional area. 16. The method of claim 11 , wherein the artificial acoustic shoulder defines a fluid passageway having a uniform cross-sectional configuration normal to a direction of fluid flow. 17. The method of claim 11 , wherein the flow acceleration ramp tapers between a terminal edge and the central orifice. 18. The method of claim 17 , wherein the flow acceleration ramp is frustoconical in shape. 19. The method of claim 11 , wherein the artificial acoustic shoulder extends from the central orifice normal to a direction of fluid flow through the central orifice.