Fluids exiting a vessel tend to swirl and form a vortex, and it is often desirable to minimize the vortex or swirling flow in the exiting fluid. This is particularly true for liquefied natural gas (LNG) and other similar fluids. One way to reduce vortex and swirling flow is to use a breaker at the outlet of the vessel. For example, a vessel 10 illustrated in
Another vortex breaker 40 illustrated in
The basic vaned vortex breaker 30 of
In addition, the screen basket breaker 40 with internal vanes 50 of
What is needed is a vortex breaker that is more effective for LNG and other types of fluids and that can have a smaller size than conventionally possible.
A vortex breaker fits over a vessel's outlet. The breaker has a wire basket with a sidewall screen and a top screen. The sidewall screen is disposed on a base, and the base has an opening communicating with the vessel's outlet. The basket's sidewall screen has a cylindrical shape with profiled wires horizontally arranged around bars that extend vertically from the base. The basket's top screen is attached to the sidewall screen and has a flat, disc shape. As with the sidewall screen, the top screen has wires arranged perpendicularly across a plurality of bars. In an alternative, the basket's sidewall screen can have a cylindrical shape with profiled wires vertically arranged around bars that extend horizontally.
In use, fluid passing through the top and sidewall screens is directed by the profiled wires and the bars into the basket. Below the top screen, a baffle plate diverts the fluid passing through the top screen to the periphery of the top plate adjacent the sidewall screen. Inside the basket, a flow modifier has vanes attached to the base and disposed radially around the opening in the base. At least some of these vanes have cross-tees extending from the vane's sides to break the radially directed flow in the basket. Preferably, first planar vanes and second cross-teed vanes are arranged symmetrically and alternating around the central opening in the base.
Turning to the drawings, a vortex breaker 100 illustrated in
Both the top and sidewall screens 120 can be constructed from several modular screen components coupled together. For example, the top screen 120 can be formed from two or more panels coupled together. In a similar fashion, the sidewall screen 140 can be formed from several screen panels or quadrants that couple together to form the screen's cylindrical shape. Because the vessel in which the basket 110 may position may have a curved inner sidewall, the screen 140's lower edges can be contoured to conform to the shape of the vessel. In addition, the basket's base 150 can be shaped to fit against the vessel's inner wall.
As best shown in
As also best shown in
A baffle plate 162 positions below the top screen 120, and its peripheral edge almost extends to the surrounding sidewall screen 140. The baffle plate 162 may be set directly underneath and optionally attached to the top screen's bars 124. Alternatively, a gap or space can be provided between the baffle plate 162 and bars 124. In any event, being under the screen's wires 122 and rods 125, the baffle plate 162 diverts flow passing through the top screen 120 to the plate's peripheral edge. From this peripheral edge, the diverted flow can then be directed inside the basket 110 to the outlet insert 155.
In addition to the screen basket 110, the breaker 100 has a flow modifier 160 positioned within the basket 110, as shown in detail in
The first vanes 170 include planar, solid plates oriented radially from the base's central opening 152. The second vanes 180 also include planar, solid plates but have cross-tees 182 positioned perpendicularly thereto. These cross-tees 182 are intended to break radially directed flow. The locations and sizes of these cross-tees 182 depend on the fluid type, flow velocity, flow characteristics, number of vanes, size of the breaker, and other variables evident to those skilled in the art.
In use, the basket's wire screens 120/140 act as an initial barrier to fluid flow into the breaker 100 and operate to break the tendency of the flow to form vortices and swirls as the fluid passes through the screens 120/140 to the outlet insert 155 disposed in the vessel's outlet. The lengthwise bars 124/144 running perpendicular to the wires 122/142 on the inside of the basket 110 also act to control the flow into the basket 110. Internally, the vanes 170/180 of the flow modifier 160 help radially direct flow in the basket 110 toward the outlet insert 155, and the cross-tees 182 break the radially directed flow in a way that enables the entire breaker 100 to be reduced in overall size. As noted previously, prior art breakers may need a diameter that is about 4 to 5 times the outlet's diameter. The breaker 100 can be about 1.5 to 3 times the outlet's diameter, although the value depends on the outlet size, flow rate and height of fluid in the vessel during service.
The breaker 100 preferably prevents vortices with a minimum effect on flow-through resistance or pressure drop. Together, the combination of flow modifier 160 and screen basket 110 create a pressure and streamline pattern that prevent the formation of vortices. Moreover, the screen basket 110 and flow modifier 160 combination can effectively reduce vortices while requiring a smaller sized basket than conventionally used.
Another vortex breaker 200 illustrated in
The breaker's top screen 220 is surrounded by the banding 230 that attaches the stop screen 220 to the sidewall screen 240. The top screen 220 has wires 222 welded to perpendicularly oriented bars 224 that run across the top screen 220. Below the top screen 220, a baffle plate 262 positions underneath the top bars 224, which can be welded thereto, and covers most of the top screen 220 except for the outer periphery near the banding 230.
The sidewall screen 240 of the basket 210 has horizontally oriented wires 242 wrapped around and welded to vertically oriented bars 244. These bars 244 extend from the base 250 and can be welded or affixed thereto in ways known in the art. The outlet insert 255 is a cylindrical tube extending from a central opening in this base 250 for passage of fluid out of the basket 210. As an alternative to the present arrangement of wires 242 and bars 244, the basket's sidewall screen 240 can have profiled wires 242 horizontally arranged around bars 244 that extend vertically from the base.
As at least partially visible in
This breaker 200 also has a modular construction. For example, the screen basket 210 has first and second halves 212A-B that attach together at the outlet of a vessel (not shown). For example, both the top screen 220 and the banding 230 having semi-circular portions that connect together to form the disc shape screen 220 and banding 230. As shown in
As shown in
As shown in
As shown in
The vortex breaker 200 uses the flow modifier 260 and directs flow in a similar manner to that discussed above with reference to
The first vanes 270 include planar, solid walls oriented radially from the central opening 252. These vanes 270 extend from the central opening 252 radially outward to a point almost to the vertically oriented bars 244 of the sidewall 240. The second vanes 280 also include planar, solid walls that are similarly oriented radially from the central opening 252. These vanes 280 also extend from the central opening 252 radially outward to a point almost to the vertically oriented bars 244 of the sidewall 240.
The second vanes 280 also have cross-tees 282 positioned perpendicularly thereto. As shown, these cross-tees 282 may be positioned relatively closer to the surrounding sidewall 240 as opposed to the central opening 252. Likewise, these cross-tees 282 can encompass half or less than half of the distance d between the second vane 280 and the adjacent first vanes 270. For support, semicircular stabilizer bands 264 can attach to outer top corners of the vanes 270/280 near the basket 210's periphery, and curved stabilizer bands 266 can attach to inner corners of the vanes 270 and 280 near the basket 210's center.
The size, placement, and shape of the vanes 270/280 and cross-tees 282 can be determined based on rules of thumb, equations, guidelines, and other considerations available to one skilled in the art. To determine the expected shape of the free flow vortex, for example, formulas can first be used for estimation, and then computation fluid dynamic (CFD) models can be used. The breaker 200 is then sized to be large enough to disrupt the shape of the vortex. Sizing ratios for the breaker 200 relative to the size of the vortex that have proven to be successful in previous installations can then be used to finalize the size for the vortex breaker 200. These ratios can vary based on the nozzle size and vessel orientation (horizontal or vertical vessels).
For further refinement, CFD models are used to determine the streamline pattern for the vessel geometry and nozzle configuration during expected operation. The vortex breaker 200 is then added to the CFD model to determine its effects on the streamlines. If the breaker 200 removes the turbulent or swirling streamlines in the CFD model, then the current design of the breaker 200 may be deemed acceptable. If the breaker 200 does not remove the turbulent or swirling streamlines, then the size, number, location and other general configuration variables of the vanes, screen, and other components are altered until the desired flow control effect is observed.
For illustrative dimensions, the basket 210 may have an overall diameter D1 of about 737-mm, and the central opening 252 for the outlet may have a diameter D2 of about 251-mm. The planar portions of the vanes 270/280 may have a length L1 of about 197-mm. The cross-tees 282 may have an expanse L2 of about 102-mm and may be positioned at a distance L3 about 133.5-mm from the inner edge of the vanes 280. For additional illustration, the slot width between the sidewall's wires (242;
The foregoing description of preferred and other embodiments is not intended to limit or restrict the scope or applicability of the inventive concepts conceived of by the Applicants. In exchange for disclosing the inventive concepts contained herein, the Applicants desire all patent rights afforded by the appended claims. Therefore, it is intended that the appended claims include all modifications and alterations to the full extent that they come within the scope of the following claims or the equivalents thereof.
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Entry |
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“Monarch's 2 & 3 Phase Separators, Excellence in Production and Process Operations,” by Monarch Separators, Inc., obtained from www.monarchseparators.com, 8 pages. |
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Number | Date | Country | |
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20120298232 A1 | Nov 2012 | US |