CA1112128A - Fluid pipeline extended vane elbow - Google Patents

Abstract

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ABSTRACT OF THE DISCLOSURE

Figure 1 shows a system for suppressing cavitation in fluid pipeline passages such as a fluid loading arm 10, particularly of the marine type, comprising extended turning vanes 28 in the elbows 24 of the loading arm, preferably in the upstream direction from the elbow tangent point, and having a negative attack angle. The combined effect of the extended vane and the negative attack angle improves cavitation performance to a greater extent than each of these expedients when used separately. This system obtains increased flow rates without significantly increasing the system back pressure.

Description

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2 The present invention relates generally to fluid

3 pipeline passages and more part~cularly to an improved fluid

4 loading arm which suppresses harmful cavitation without sig-nificant increase in system back pressure.
6 At the present time it is well known that flow 7 velocities in loading anms, and particularly in marine fluid 8 loating arms, are restricted by the phenomenon of "cavita-9 tion". This occurs in the loading arm short radius elbows.
Thus, as a fluit flows through an elbow there are pressure 11 gradients which occur across the elbow cross-section and the 12 pre6sure is lowest at the inner or shortest radius. As the 13 velocity of the flow increases, the ~ressure at the inner 14 radius will tecrease until the vapor pressure of the fluit has substantially been reached. At this particular point 16 in time a plurality of relatively small bubbles or cavities 17 of the protuct vapor will be formed and begin to flow down-18 stream ant when the bubbles reach a region of relatively 19 higher pressure, the bubbles will implode, in other words collapse, with a violent release of energy. ThQse implo-21 sions can cause erosion of the pipewall and vibration in 22 the arm, which can then result in arm failure because of 23 structural weakening, fatigue failure from the dynamic 24 stresses produced, or as a minimum, costly replacement of erodet arm components.
26 Generally, it i9 economically desirable and there 27 exists significant incentive to increase the flow velocity 28 through the arm. The advantages of increased flow are a .:

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1 shorter tur~around time at an existing or new berth, and 2 avoiding the need to replace existing arms with larger dia-3 meter arms, as well as in the case of new terminals smaller 4 and/or fewer arms can be used. This results in a reduction of capital investment. However, when these flow velocities 6 are increased this can cause a corresponding increase in 7 tamage to the arm because of the low pressure zones created 8 at the inner radius of the elbows. Thus, while increased 9 flow velocity is desirable, the corresponding problem of cavitation created thereby is a primary concern.
11 The primary parameters which determine when cavi-12 tation will occur include the flow variables of absolute 13 pressure, PO~ and velocity, VO~ the boundary geometry and 14 the vapor pressure, Pv~ and density, ~, of the liquid. The relationship between these parameters is generally known as 16 the cavitation number, sigma, which equals 17 Po Pv 18 l/Z e vO~
19 Thus, i~ one coult increase the flow velocity, the foregoing and other advantages will be obtainet but not without the 21 attendant tisatvantages, unl2ss means sre introtucet to 22 suppress cavitation.
23 The systems ant arrangements currently used in the 24 elbows for suppression of cavitation and improving flow rate comprise turning vanes in the arm elbows. These vanes 26 split the single flow stream into a mulciplicity of streams, 27 each of which ha~ smaller pressure gradients than the over-28 all pressure gradient of the single flowing stream. This .

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i28 1 permits a higher press~re rating to be achieved with a vaned 2 elbow before the vapor pressure of the fluid is reached and 3 without producing cavitation. This arrangement is generally 4 known in the art as typified by the disclosures of United States Patents 1,837,901; 1,996,596; 2,662,553; 2,723,680;
6 2,733,044; 3,597,166. A patent of particular interest i9 U.S.
7 3,724,499 wherein there is disclosed a loading arm having 8 sbapet turnlng vanes in the elbows in combination wi~h a 9 Venturi section at the outlet of the loading arm for raising the fluit pressure in the arm. The concept of increasing arm 11 fluid pressure is well-known in the industry. As previousl~
12 t$scussQt, it will pe~mit higher flow velocity to be achievet 13 before ca~itation occurs. Thus, in the prior art patentet 14 loati~g arm design it is necessary to have increased back 15 pressure to cause the improved flow rate. The same effect 16 can be obtainet as well by employing a valve at the outlet 17 pipe for restrictiag flow. However, a disadvantage of that 18 type of 9y9tem would be the additional pump capacity which is 19 requiret in order to overcome the adtitional back pres3ure tue either to the Venturi or the valve. Other prior art 21 patents of general interest are U.S. 2,564,683 which tiscloses 22 ad~ustable plates in a flow passage ant U.S. 3,398,765 dis-23 closes an elbow-locatet guite plate for minimizing the effect 24 of the bent on flow. Thus, it is apparent that there is a neet ~or a system which will permit higher flow rate through 26 the fluit loading arm without cavitation ant without a sig-27 nificant increase in the bac~ pressure.
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1 SUMMARY 0~ THE I~VE~TION
2 The present invent$on comprises a system which over-3 comes the disad~antages of the prior art systems and basically 4 comprises a coaction between an extended vane upstream of the elb~w tangent point and a negative attack angle for the vane.
6 It ~s generally applicable to fluid pipeline passage~ having 7 elbows and particularly useful in loading arms of the marine 8 type. The etge of the vane facing the flow also is shaped to 9 provide a relatively clean aerodynamic shape. The extended vane i~ supported on its sites in order to prevent any flut-11 tering of the leading etge in those cases where the elbow is ,' 12 at~acent a straight pipe or if in a nipple portion of the 13 swivel then the site etges can be welded to the pipe sw,ivel.
14 In those cases where the elbow is atjacent a swivel body and close to the swivel nipple, a rotatable ring support can be 16 provided. This ring can be recesset in a groove tisposed in 17 the swivel nipple p~rtion. The sides of the extended vane 18 are welded to the ring in orter to eliminate any fluttering 19 p roblems as well as to maintain the vane ~n a relatively con-stant attack angle relative to the fluid flow. By pro~iting 21 for ad~ustabllity of the attack angle of the extendet vane, 22 this permits optimization of the combinet extentet vane ant 23 attack angle to produce the most tesirable flow rate without 24 incurring cavitation. A suitable vane adjustment means which, can be employed is a manually operatet screw which activates 26 a rot bearing against the vane to cause the vane to atjust its 27 attack angle, or alternatively, a solenoid or hydraulically-28 operated piston motor for remote control of the adjustability 2~

feature particularly in inaccessible locations may also be employed. The advantages which would result from vaned elbows according to the present invention are basically higher arm flow rates without the attendant cavitation and~or higher system pressure levels of the prior art systems, which means less investment required in the loading arms for a new grass roots project, since smaller or fewer larger arms can be supplied to obtain desired low capacity; at existing facilities increased throughput can be realized without the addition of more arms or without replacing existing arms with the same number of larger arms; and lower tanker demurrage costs can be realized because shorter pumping times will result in less time in the berth.
In accordance with a particular embodiment of the invention a fluid passage comprises at least a curved pipe elbow section and an adjacent upstream straight pipe section adapted for receiving fluid flow in a direction from said straight section to said elbow section, at least a single curved vane mounted in the flow pas~age of said curved pipe elbow section, said vane extending lengthwise in a curved con-figuration corresponding to that of said curved pipe elbow section beyond the end of said curved pipe elbow section into said straight pipe section for a predetermined distance, ~aid extended portion of said vane being disposed at a negative angle relative to the direction of flow of said fluid through said pipe section, whereby the combination of said extended vane and said negative attack angle of said vane substantially suppresses cavitation of the fluid flowing through said fluid passage without increasing the back pressure.
BRIEF DESCRIPTION OF THE DRAWINGS
Fig. 1 is a perspective view, partially broken away, of a fluid loading arm employing the present invention.
Fig. 2 is a cross-sectional view substantially along the pipe axis at an elbow incorporating a vane constructed and arranged according to the present invention.

- 5a -Fig. 3 is a cross-sectional view substantially along the line 3-3 of Fig. 2.
Fig. 4 is a cross-sectional view illustrating a vane constructed and arranged according to the present invention, which is mounted in a loading arm elbow adjacent to a swivel.
Fig. 5 illustrates a typical means for adjusting the attack angle of the vane according to the present invention.

~ i 2 1 Fig. 6 iIlustrates in large partial cross-sectional 2 view of the adjustment means employed in Fig. 5.
3 Fig. 7 illustrates a cross-sectional view of a vane ; 4 according to the present invention mounted in an elbow ad-jacent to a swivel (like Fig. 4) and having means for regula-6 ting the vane attack angle.
7 Fig. 8 illu~trates an enlargement of a portion of 8 Fig. 7 illustrating the vane mounted in a ring.
9 Fig. 9 illustrates typical test results obtained from vaned elbows according to the present invention.
11 DESCRIPTION OF THE PREF~RRED EMBODIMENT
12 A typical embodiment of the present invention is in 13 a fluid loading arm environment, particularly for use, ~or 14 example, in the transfer of petroleum or other liquid products between a tanker and shore based storage facility as illus-16 trated in Fig. 1. Other uses of the invention sre in pipe-17 line passages which contain an elbow. There i9 shown a 18 marine loading arm 10 comprising a plurality of straight sec-19 tions of pipe ~oined by ~luit swivels and pipe elbows. The srm comprises an inboasd pipe section 12, ~nd an out~oard 21 pipe 9ection 14, pivotally connected through swivel ~oint 16 22 to the inboard section, an upstanding riser section 18 to 23 which the inner section is pivotally connected by a further 24 swivel ~oint 20, and a triple swivel assembly connected to the end of the outboard pipe, 14. For purposes of illu~tration 26 only, the riser i9 shown mounted on a dock 22. Suitable 27 piping (not shown) is pro~ided between the riser and a liquid 28 storage reservoir (also not shown). At the upper end of the . ~ , . .
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1 riser 18, there is provided an elbow 24, which is mounted 2 on the lower straight section by means of a swivel joint 26 3 which facilitates movement of the arm relative to the riser 4 vertical axis. The triple swivel assembly comprises three swivels in mutually perpendicular planes ant a series of 6 at~acent elbows, to permit free movement of the arm. The 7 overall configuration of the arm is essentially conventional 8 and is illustrated in greater detail in the aforesaid U.S.
9 Patent 3,724,499. Other types of marine ant fluid loading arms are contemplatet for the present invention. In the load-11 in8 arm~ prevlously tiscusset, as the fluid passes through 12 the various elbows, the centrifugal force created will cause 13 a pressure tifferential with the outer radius being at a 14 higher pressure relative to the inner ratius of the elbow.
When the flow velocity is great enough, then the pressure 16 level at the inner ratius will fall below the known vapor pres-17 sure of the liquid and vapor bubbles will form. As the 18 velocity increases, the degree of cavltation will also increasc 19 correspondingly. When the cavitation has teveloped suffi-ciently, lt will e~tend into the straight sections of the 21 down~tream pipe~, and it will end st a point downstream where 22 there are no longer any centrifugal force effects in the 23 pressure fielt ant/or the fluid angular momentum will have 24 t~ssipated. The formet vapor bubbles are then subJected to higher pressures ant implosions or collapse of the bubbles 26 occur, causing the problems previously tiscussed.
27 To overcome these, there is providet in the pipe 28 elbows turning vanes 28 according to the present invention '"

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1 which will suppress the occurrence of cavitation while im-2 prov~ng the flow rate. These vanes are curved, rigid snd 3 made of metal or other light material ant function to split 4 the ~ingle flow stream into multiple streams which have smaller pressure gradients than the single flow stream pres-6 sure gradient. This permits higher flow rates to be achievet 7 prior to reaching the fluid's vapor pressure, at which cavi-8 tation will result. According to the present invention, 9 vanes are extended for a distance past the elbow tangent point which has been shown to improve the non-cavitating flow 11 velocitles. By lengthening the vane from about 0.4 to one 12 tim~s the elbow's inner dismeter this accomplishes the te-13 siret obJectives. Also, the extendet vane was disposed at a 14 slightly negative attack angle. By this it is meant that the extended portion of the vane is di~posed at a negative angle 16 re}ative to a plane parallel with the axis of the 3traight 17 pipe section. Test results show that proviting an approxi-18 sate attack angle of -1.5 de8rees and a vane extension of 19 .4 to 1 times the elbow radlus wili prevent cavitation.
However, it is anticipated ant can b~ deter~inet experimentally 21 that the optimal negative att~ck angle ~ can vary, depenting 22 upon the product and elbow geometry employed. Fi~. 2 illu8-23 trate9 the vane 28 extendet at 30 for a distance L lnto the 24 adJacent up~tream section 32 of the pipe. The vane i9 situ-atet on a llne of constant bent radiuA which may be equal to 26 approximately 0.85 time~ the elbow's internal diameter D.
27 While the present embodiment is shown as employing a single 28 vane, it i9 also contemplated that more than one vane may be ~, . , .
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~1~12~Z8 1 employed, depending upon the amount of increase in flow veloc-2 ity desired. The forward up~tream or leading vane edge 34 3 is disposed transverse to the direction of flow through the 4 ar m and shaped with a ~loping surface 36 away from the direc-tion of flow in order to attain a relatively clean aerodyna~ic 6 shape.
7 While a particular vane extension has been dis-8 closed and described herein, the particular amount of e~ten-9 sion of the vane upstream into the straight section can be optimized through standard testing in the laboratory and field.
11 While shorter vane estensions may be pos3ible in time the 12 leating edges of the ~ane9 may erode from the various local 13 edge cavitation which can hasten more harmful elbow cavita-14 tion to occur. If it i~ desired to minimize the effects of the vane edge corrosion, then a longer extendet vane can be 16 utilizet. In order to prevent the leading edge of the e~ten-17 ded vane from fluttering, it is preferable to support the side 18 edges of the vane as shown at 38 by mean~ of welding (see Fig.
19 3) the vane on the upper and bottom sides to the i~ner wall of the loating arm pipo sectlon.
21 As shown in Fi~. 4, when the elbow conta~n~ng the 22 vane 28 according to the present invention i9 locatet ad~acent 23 to a swivel, there is provided an annular support ring 40 24 which i~ rotatably mounted relative to a surrounding swivel portion. As shown, the support rin8 40 rides in a recessed 26 groove 42 formed in the rotatable nipple portion 44 of the 27 swivel and between the outer surface of the ring and the 28 groove surface i5 disposed a ~tsrial 46 which has low friceion . . .

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1 ant aids in forming relative sliding relationship between the 2 surface of the swiveI nipple and the support ring. This ma-3 terial may comprise Teflon or other materials which are com-4 patible with the fluids' properties. In order to eliminate any flutter problems with the extended portion of the vane, 6 the sides of the vane may be welded to the inner surface of 7 ~he ring, which also aids in maintaining the vane at a con-8 stant negative attack angle relative to the direction of 9 fluid flow. The extended side portions of the vane between 10 the ring and the elbow tangent point is free, that is not il welded. The swivel body i9 provided with su~table packing 12 material 48, 50 for preventing leakage between ~he rotatable 13 nipple and the main body relative movement of which is facili-14 tatod by means of the bearings 52.
In order to obtain the preferred and optimum angle 16 of attack, the extended portion of the vane may be made to 17 coact with means for ad~ustably regulating the attack angle.
18 This is shown in Fig. 5 by means of the screw-type adjustment 19 member 54 which i9 unted in the 9traight section of the pipe and e~tends through a seal unit ln ~he pipe wall, perpen-21 dicular to flow direction and pipe longitudinal axis and in 22 contact with the surface of the vane. By rotating the screw 23 mem~er which i9 threadet into support 56 secured to the pipe 24 wall, as shown in Fig. 6 the stem rotates up or down depending on direction of rotation which causes the vane to move up or 26 down, thus controlling the attack angle. The stem portion 60 27 itself, which extends through the pipe wall into contact with 28 the vane can be aerodynamically shapet with an airfoil like . . . :, , . . .
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1 configuration in order tO avoid interference with the flow.
2 The vane adjustment stem is packed with valve packing material 3 58 such as molded elastomeric or plastic rings, surrounding 4 it in order to prevent leakage of the fluid flow from the pipe

5 and mounted on top of the packing firmly to hold it in place

6 is threatet support plug 56. The extended portion of the

7 vane i9 not welded when employed with an adjustment mechanism

8 for regulating and controlling the attack angle for obvious

9 reasons. Also, the illustrated screw adjustment feature can be.replaced by other means of a more sophisticated variety, 11 such as a soLenoid, hydraulically-operated pistons or motors 12 for remote control at relatively inaccessible elbows in the 13 arm, e.g., the elbows between the inboard pipe 12 and the 14 outboart pipe 14 of Fig. 1.
In the case of a vane which e~tends into a swivel, 16 the ssme general.type of adjustment feature as tiscussed above 17 in connection with Fig. 5 can be used in combination with the 18 support ring 40 as shown in Fig. 4. As illustrated, the 19 ~upport ring 40, as shown in Fig. 7, at and ad~acent to the vane leading edge 34 captur~s the vane on e~th-r side thereo 21 by means of bear~ng block ant packlng 60 directly ad~acent to 22 each surface (upper and lower). On opposed upper ant lower 23 sides of the vane at its transverse end, there is alsa provided 24 atJu~tment springs 62 which are disposed between the support ring 40 and the bearing block and packing 60. This i9 all 26 mounted in the recess 64 formed in the support ring, and 27 each bearing block 60 is coated ~ith a material 46 such as 28 Teflon to provide a sliding surface relati~e to th- ri~g ..

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1 recess. As illustrated, the portion of the side edges of the 2 vane between the support ring and the tangent point for the 3 elbow are not welded and the adjustment mechanism is unted 4 directly pro~imate the elbow tangent point, although it can be mounted at other 10cations such as further upstream of the 6 swive1. Adjustment of the threaded screw will cause a force 7 up or down to be imposed on the extended vane thereby per-8 mitting the vane to move accordingly and thus adjust the 9 attac~ angle. The springs 62 are stiff enough to prevent flut-ter during flow and thus, there is no need for welding as in 11 the case of the other embodiment. The bearing members 60 12 act as not only bearin8 surfaces but also as a seal to pre-13 vent the springs fsom getting clogged with the fluid passing 14 through the ar~s.
The aforedescribed invention combining the extendet 16 vane and the negative vane attack angle has been shown to 17 pro~ite an effect which improves cavitation performance to a 18 greater extent than when employed separately. The anticipatet 19 improvement in ~low characteristics by providing vaned elbows did not materialize until the vane was in accordance with the 21 present lnvention axtended upstr~am o~ the elbow beyond the 22 tange~t point and at a negatlve attac~ angle. It was found 23 that merely extending the vane alone would not produce the 24 improved performance des~red and in those instances would be no better thsn equivalent unvaned single elbow. Accordingly, 26 it is felt that the combination of both the vane extension and 27 the negative angle are essential features of the present in-28 vention. It is believed that with these features consistently . ' , . ' ''' ; : '.

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: ~ ::, ,: ' ' - , ., ~ 13 1 superior flow performance will result in actual operation 2 without increase in bac~ pressure. Fig. 9 illustrates test 3 results obtained from an extendet vane of length equal to one 4 pipe diameter and at a negative attack angle of 1.3.
In those instances where more than a single elbow 6 is present in the loading arm, the criteria employed in the 7 tests was to vary the included angle between adjacent el~ows.
8 While only limitet testing was tone on vaned multi-elbow 9 geometries, the beneficial effects on safe flow velocity of vaning single elbows are expected. The features such as 11 extending the vane ant vasylng the attac~ angle would also 12 apply for the elbows of the multl-elbow geometries.
13 Having thus set forth the present invention in its 14 preferred embodiments, it will be apparent that various modification ant variatlons may be mate thereto without de-16 parting from the true spirit and scope of the sub~ect in~en-17 tion.

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Claims (10)

THE EMBODIMENTS OF THE INVENTION IN WHICH AN EXCLUSIVE
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:

1. A fluid passage comprising at least a curved pipe elbow section and an adjacent upstream straight pipe section adapted for receiving fluid flow in a direction from said straight section to said elbow section, at least a single curved vane mounted in the flow passage of said curved pipe elbow section, said vane extending lengthwise in a curved configuration corresponding to that of said curved pipe elbow section beyond the end of said curved pipe elbow section in-to said straight pipe section for a predetermined distance, said extended portion of said vane being disposed at a nega-tive single relative to the direction of flow of said fluid through said pipe section, whereby the combination of said extended vane and said negative attack angle of said vane substantially suppresses cavitation of the fluid flowing through said fluid passage without increasing the back pres-sure.

2. The fluid passage according to claim 1 wherein said vane extents from the tangent point of said pipe elbow section and including means for adjusting said attack angle.

3. The fluid passage according to claim 1 wherein said vane extents upstream from about 0.4 times the inside diameter of said pipe elbow section to about one times the inside diameter of said pipe elbow section.

4. The fluid passage of claim 1 wherein said leading edge of said vane has a sloping surface away from the direction of flow.

5. The fluid passage according to claim 1 wherein the side edges of said vane are supported against any substan-tial fluttering of the leading edge thereof.

6. The fluid passage according to claim 1 wherein the side edges of said extended vane are welded at least par-tially adjacent the leading edge thereof to said straight pipe section.

7. The fluid passage according to claim 1 wherein said pipe elbow section comprises a swivel body and including a ring mounted for relative rotation relative to said swivel body and supporting the leading extended portion of said vane.

8. The fluid passage according to claim 7 including means for resiliently supporting the forward portion of said extended vane while preventing fluttering thereof during flow of fluid through said arms in combination with means for ad-justably controlling the attack angle of said vane.

9. The fluid passage according to claim 2 wherein said adjustment means comprises a threaded screw-type member for controlling said attack angle of said vane.

10. The fluid passage of claim 1 wherein said pas-sage comprises a loading arm.