The present invention relates to a valve assembly that may be used to control a flow of a fluid, and that resists damage from erosion or cavitation, and to a use of it.
The use of a purely mechanical valve in which a valve member seals against a valve seat is very widely known, and can be used either to adjust the flow of a fluid or to close off the flow altogether. Such a valve is not entirely suitable for use in controlling flows of potentially abrasive fluids, for example the liquids emerging from an oil well that may contain sand particles, as the particulate material will cause abrasion of the valve surfaces especially when the valve is almost closed. Fluid flows can also be controlled, as described in GB 2 209 411, by a fluidic vortex valve or vortex amplifier, in which the main flow enters a vortex chamber radially and leaves the chamber axially, and a flow of liquid is supplied to a tangential inlet by a suitable pump; the magnitude of the tangential flow has a very large effect on the main flow, as it generates a vortex in the chamber. Such a fluidic vortex amplifier can be used as a choke valve, and has the benefit that it suffers much less from abrasion. However a fluidic vortex amplifier must always have fluid emerging from it, since if the main flow is to be effectively shut off then the flow of the control fluid must be at its maximum.
According to the present invention there is provided a valve assembly comprising a valve stem defining a bore and at least one radial port, and having an outlet end, and a sleeve closed at one end slidable over the valve stem to obstruct the or each radial port in the valve stem, wherein the valve stem at the end opposite the outlet end defines a fluidic vortex chamber having at least one generally tangential inlet and at least one non-tangential peripheral inlet and having an axial outlet communicating with the bore, and the sleeve defines at least one port near the closed end of the sleeve.
The valve assembly operates in a conventional fashion except when approaching closure. Once the last of the radial ports in the valve stem has been closed, the only flow path is through the radial port in the sleeve, and hence through the fluidic vortex chamber. Initially the flow is primarily through the non-tangential peripheral inlet or inlets, but on further closure of the valve the radial port in the sleeve aligns with the tangential inlet to the fluidic vortex chamber, so a fluidic vortex is generated and the resistance to fluid flow is increased. In the final approach to closure, substantially all the fluid flow must pass through the tangential inlet or inlets, the resulting vortex maximizing the pressure drop but minimizing the erosion of the surfaces. Finally the flow is stopped altogether as the valve stem obstructs the radial port in the sleeve.
The erosive and cavitational wear on the mechanical valve mechanism is significantly reduced as compared to conventional choke valves, particularly at the low flow/high pressure drop conditions in which erosion is most severe. A wide range of flow modulation can be achieved with limited movement of the mechanical valve member, as closure is approached.
Preferably there are a plurality of non-tangential peripheral inlets that communicate with the end face of the valve stem. Preferably there are also a plurality of tangential inlets, and these are preferably linked by a peripheral groove on the outer surface of the valve stem. There may also be a plurality of radial inlets through the sleeve, lying in a common radial plane.
Thus the vortex chamber provides the flow path for the bulk of the fluid only when the valve assembly is almost closed, that is to say only at very low flow rates through the valve assembly. In contrast, when the valve assembly is fully open, substantially all the fluid passing through the valve assembly bypasses the vortex chamber. However, when the valve assembly is almost closed, the vortex chamber provides the flow path and also the bulk of the pressure drop across the valve assembly.
The invention will now be further and more particularly described, by way of example only, and with reference to the accompanying drawings in which:
a shows a fragmentary view of part of the assembly of
Referring to
Towards its top end (as shown) the bore 15 tapers; the valve stem 14 is almost closed at the top end, but defines a fluidic vortex chamber 22 with an axial outlet 24 communicating with the bore 15. Referring also to
The sleeve 18 defines four radial apertures 32 a short distance below the closed end. The radial apertures 32 are located such that as the sleeve 18 is lowered, the apertures 32 start to communicate with the circumferential groove 30 just as the last radial apertures 17 is closed. As shown in
Hence in use the valve assembly 10 operates in a conventional fashion except when approaching closure. As the sleeve 18 is lowered, it gradually obstructs the apertures 17 (which in this example are of progressively smaller diameters), so gradually restricting the fluid flow. When the valve sleeve 18 reaches the position shown in
Thus as the valve assembly 10 approaches closure, a progressively greater proportion of the overall pressure drop is due to the fluidic vortex rather than to the mechanical valve components.
Number | Date | Country | Kind |
---|---|---|---|
0214597.7 | Jun 2002 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/GB03/02239 | 5/22/2003 | WO | 00 | 12/23/2004 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO04/001260 | 12/31/2003 | WO | A |
Number | Name | Date | Kind |
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3025880 | Anderson | Mar 1962 | A |
3674044 | Mayer | Jul 1972 | A |
3990475 | Myers | Nov 1976 | A |
4041982 | Lindner | Aug 1977 | A |
4397331 | Medlar | Aug 1983 | A |
4471810 | Muchow et al. | Sep 1984 | A |
5133383 | King | Jul 1992 | A |
Number | Date | Country |
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0530967 | Mar 1993 | EP |
778928 | Mar 1935 | FR |
2209411 | May 1989 | GB |
Number | Date | Country | |
---|---|---|---|
20060076065 A1 | Apr 2006 | US |