CRYOGENIC PUMP FLANGE

Abstract

A flange for a pump comprises first and second faces and a passageway for cryogenic fluid flow extending from the first face to the second face and at least one of (1) the passageway is for a pipe and comprises a first portion of a first diameter and a second portion of a second diameter greater than the first diameter, wherein when the pipe has an outer diameter that is smaller than the second diameter a gap is formed between the pipe and the passageway where the pipe passes through the second portion; and (2) a first annular groove in one of the first face and the second face and extending around the passageway, wherein the first annular groove in cooperation with the passageway forms a bellows. The gap and bellows increase the thermal resistance between the passageway and the flange, and the bellows allows for flexure during thermal contractions of the flange reducing thermal stress on welded fluid seals.

Claims

1. A flange, comprising: a first face; a second face; a passageway for cryogenic fluid flow extending from said first face to said second face, and one of: (a) a first annular groove in one of said first face or said second face and around said passageway, a first annular portion between said first annular groove and said passageway; or (b) a first annular groove in one of said first face or said second face and around said passageway, a first annular portion between said first annular groove and said passageway, a second annular groove extending from the other of the first or second face as said first annular groove and around said first annular groove, a second annular portion between said second annular groove and said first annular groove.

2. The flange of claim 1, wherein a pipe is in contact with an inner wall of said passageway.

3. The flange of claim 1, wherein a pump for pumping a cryogenic fluid from a storage vessel is coupled to said flange.

4. The flange of claim 1, said passageway comprising a first portion with a first diameter and a second portion with a second diameter, said second diameter being greater than said first diameter; wherein a gap is formed between a pipe and said passageway where said pipe passes through said second portion of said passageway.

5. The flange of claim 4, wherein the gap is (i) filled with a low thermal conductivity material, (ii) sealed at the second face to reduce accumulation of moisture in the gap or (iii) both (i) and (ii).

6. The flange of claim 1, wherein a first pipe is in fluid sealing contact with said first face around said passageway and a second pipe is in fluid sealing contact with said second face around said passageway.

7. The flange of claim 2, wherein when said first annular portion contracts due to a thermal gradient between said pipe and said flange along said first annular portion said pipe moves with said first annular portion.

8. A flange assembly, comprising: a process fluid pipe; a flange comprising: a first face; a second face; a passageway for cryogenic fluid flow extending from said first face to said second face, and one of: (a) said process fluid pipe passes through said passageway, a first annular groove in one of said first face and said second face and surrounding said passageway, a first annular portion between said first annular groove and said passageway; or (b) a first annular groove in one of said first face and said second face and extending around said passageway, a first annular portion between said first annular groove and said passageway, a second annular groove extending from the other of the first or second face as said first annular groove and around said first annular groove, a second annular portion between said second annular groove and said first annular groove.

9. The flange assembly of claim 8, wherein said flange comprises a bore extending from said first face to said second face, said flange assembly further comprises an insert and said passageway formed by inserting said insert into said bore.

10. The flange assembly of claim 8, wherein said process fluid pipe is welded to said flange.

11. The flange assembly of claim 8, said passageway comprising a first portion of a first diameter and a second portion of a second diameter greater than said first diameter; wherein a gap is formed between said process fluid pipe and said passageway where said process fluid pipe passes through said second portion of said passageway.

12. The flange of claim 11, wherein said gap is (i) filled with a low thermal conductivity material, (ii) sealed at the second face to reduce accumulation of moisture in the gap or (iii) both (i) and (ii).

13. The flange assembly of claim 8, wherein the process fluid pipe is a first process fluid pipe and further comprising a second process fluid pipe, wherein the first process fluid pipe is in fluid sealing contact with said first face around said passageway within said first annular groove and said second process fluid pipe is in fluid sealing contact with said second face around said passageway within said second annular groove.

14. The flange assembly of claim 8, wherein when said first annular portion contracts due to a thermal gradient between said pipe and said flange along said first annular portion said pipe moves with said first annular portion.

15. A cryogenic pump system, comprising: a storage vessel; a pipe to transport cryogenic fluid; and a flange coupled to said storage vessel and said pipe, said flange comprising: a first face; a second face; a passageway for cryogenic fluid flow extending from said first face to said second face, and one of: (a) said pipe passing through said passageway, a first annular groove in one of said first face and said second face and extending around said passageway, a first annular portion between said first annular groove and said passageway, wherein said flange is configured with said pipe connected with said first annular portion such that when said first annular portion contracts due to a thermal gradient between said first pipe and said flange along said first annular portion said first pipe moves with said first annular portion; or (b) a first annular groove in one of said first face and said second face and extending around said passageway, a first annular portion between said first annular groove and said passageway, a second annular groove extending from the other of the first or second face as said first annular groove and around said first annular groove, a second annular portion between said second annular groove and said first annular groove, wherein said flange is configured with said pipe connected with said first annular portion such that when said first annular portion contracts due to a thermal gradient between said pipe and said flange along said first annular portion said pipe moves with said first annular portion.

16. The cryogenic pump system of claim 15, wherein said flange further comprises at least one hydraulic fluid passageway in fluid communication with said hydraulic drive unit.

17. The cryogenic pump system of claim 15, wherein element (a) of the flange further comprises a second annular groove that extends from the other of the first or second face as said first annular groove and around said first annular groove, said first and second annular grooves in cooperation with said passageway forms a bellows.

18. The cryogenic pump system of claim 15, said passageway comprising a first portion of a first diameter and a second portion of a second diameter greater than said first diameter; wherein a gap is formed between said process fluid pipe and said passageway where said process fluid pipe passes through said second portion of said passageway.

19. The flange of claim 18, wherein the gap (i) filled with a low thermal conductivity material, (ii) sealed at the second face to reduce accumulation of moisture in the gap or (iii) both (i) and (ii).

20. The flange assembly of claim 15, wherein the pipe is a first pipe and further comprising a second pipe, wherein the first pipe is in fluid sealing contact with said first face around said passageway and said second pipe is in fluid sealing contact with said second face around said passageway.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0016] FIG. 1 is a schematic view of a cryogenic pump.

[0017] FIG. 2 is a cross-sectional partial view of a double-walled cryogenic vessel with the pump of FIG. 1 inserted into a sleeve.

[0018] FIG. 3 is a simplified cross-sectional view of a warm end assembly of the pump of FIG. 1 comprising a flange assembly and a flange according to a first embodiment.

[0019] FIG. 4 is a cross-sectional view of the flange of FIG. 3.

[0020] FIG. 5 is a cross-sectional view of a flange of the pump of FIG. 1 according to a second embodiment.

[0021] FIG. 6 is an exploded view of the flange of FIG. 4.

[0022] FIGS. 7 and 8 are schematic views of an annulus of the flange of FIG. 4.

[0023] FIG. 9 is a cross-sectional view of the annulus of FIG. 8 taken along line 8-8.

[0024] FIG. 10 is a cross-sectional view of a flange assembly of the pump of FIG. 1 comprising a flange according to a third embodiment.

[0025] FIG. 11 is a cross-sectional view of the flange of FIG. 10.

[0026] FIG. 12 is a cross-sectional view of a flange of the pump of FIG. 1 according to a fourth embodiment.

[0027] FIG. 13 is a cross-sectional view of a flange assembly of the pump of FIG. 1 comprising a flange according to a fifth embodiment.

[0028] FIG. 14 is a cross-sectional view of the flange of FIG. 13.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENT(S)

[0029] Referring to FIG. 1, there is shown cryogenic pump 10 comprising warm end assembly 20 and cold end assembly 30. Process fluid pipe 40, also known as a delivery pipe, delivers cryogenic fluid pumped from cold end assembly 30 through flange 50 in warm end assembly 20. Pipe 40 connects with external piping (not shown) that delivers the cryogenic fluid to another cryogenic vessel (when the system is transferring cryogenic fluid, for example when filling a vehicle fuel tank) or to an external vaporizer (when the cryogenic fluid is to be used by an end user in gaseous form, for example when the cryogenic fluid is natural gas that is used to fuel an internal combustion engine for powering a vehicle). With reference to both FIGS. 1 and 3, a compact arrangement is shown for a hydraulic drive unit that is mounted adjacent to flange 50 with hydraulic fluid passageways 60 and 70 for delivering hydraulic fluid into and out of cylinder 75 in a manner that is well known for causing piston 80 to produce reciprocating motion. Fittings 90 and 100 connect passageways 60 and 70 to external hydraulic conduits (not shown).

[0030] Referring now to FIGS. 3 and 4, passageway 110 is provided in flange 50, extending from opening 125 in face 65 to opening 135 in face 85. Passageway 110 comprises first portion 120 and second portion 130 which in this embodiment are cylindrical bores. The diameter of first portion 120 is less than the diameter of second portion 130. When process fluid pipe 40 is assembled into passageway 110 it is in contact with inner wall 145 of first portion 120, but gap 140 exists between the pipe and inner wall 150 of second portion 130. In other embodiments there can be a finite space between pipe 40 and first portion 120 of passageway 110 at least around a portion of the external surface of the pipe. Gap 140 is an annular gap in the present example. Process fluid pipe 40 is secured to flange 50 by weld 160. Depending upon application requirements, it is possible in other embodiments that a mechanical arrangement or an adhesive can secure pipe 40 to flange 50, or other known techniques can be employed.

[0031] The thermal resistance between process fluid pipe 40 and flange 50 is increased by gap 140 since the contact area between the pipe and the flange is reduced. Normally both pipe 40 and flange 50 are made from metal, which is a better conductor of heat than air occupying gap 140. The gap decreases cooling effect on flange 50 caused by the flow of cryogenic fluid through pipe 40, thereby reducing the likelihood of the hydraulic fluid freezing and reducing condensation of humidity and frost/ice build-up around warm end assembly 20.

[0032] Passageway 110 is at an oblique angle to both faces 65 and 85, such that opening 125 is further from longitudinal axis 15 than opening 135. Referring now to FIG. 2, when cryogenic pump 10 is installed in storage vessel 25 the majority of its length is preferably housed in sleeve 35 as shown in FIG. 2, so that opening 135 is located within the sleeve, where it is not exposed directly to the cryogen space. Storage vessel 25 is a double-walled vessel comprising outer wall 26 and inner wall 27. In preferred embodiments vacuum space 45 provides additional thermal insulation between sleeve 35 and cryogen space 55. The oblique angle of passageway 110 has the advantage of locating the contact area between pipe 40 and inner wall 145 of passageway 110 further from hydraulic fluid in passageways 60 and 70 and in cylinder 75. This has the effect of increasing the thermal resistance of the heat path between hydraulic fluid and cryogenic fluid in pipe 40. In other embodiments opening 125 can be located the same distance from axis 15 or closer compared to opening 135. In a preferred embodiment, process fluid pipe 40 is secured to flange 50 by weld 160 such that gaseous fuel vapor between sleeve 35 and pump 10 does not escape to the external environment. It is preferred that pipe 40 is welded to flange 50 at opening 125, compared to opening 135 which would tend to increase heat transfer between pipe 40 and cylinder 75 and passageway 70.

[0033] Referring now to FIGS. 5-9, there is shown a second embodiment wherein like parts to the previous embodiment and all other embodiments have like reference numerals and may not be discussed in detail, if at all. Flange 52 comprises a bore 200 that extends from face 65 to face 85. An annulus 210 generally in the form of a hollow cylindrical tube is inserted into bore 200 thereby forming passageway 110 and first and second portions 120 and 130. Annulus 210 can be secured to flange 52 in a variety of ways. As non-limiting examples, annulus 210 can be press or interference fit into bore 200, slip fit into the bore and secured by an adhesive or by welding, by a combination of these techniques, or by other known techniques to mechanically secure parts together.

[0034] Referring now to FIGS. 10 and 11, there is shown a third embodiment of flange 53. Pipe 41 is welded to face 85, and is employed to communicate a cryogenic fluid through flange 53, which depending on the type of pipe (fill pipe, delivery pipe or drain pipe) can flow in either direction. Passageway 111 is similar to passageway 110 in FIG. 4, except that portion 120 of passageway 111 extends from face 85 and portion 130 extends from face 65. Annular groove 155 extends around passageway 111, which in cooperation with the passageway forms a bellows to redirect thermal contractions of flange 53 in a direction that is not constrained, thereby reducing stress on weld 160. Annular portion 56 allows for axially contraction (in the direction of the axis of passageway 111) and flexion when flange 50 thermally contracts. Pipe 41 is normally not anchored within storage vessel 25, and is free to move, such that when a thermal gradient exists between the pipe and flange 53 along portion 56, the portion can contract along the axial direction of passageway 111. The thermal resistance between pipe 41 and flange 53 is also increased by annular groove 155, compared to when annular groove 155 is not employed, due to the narrowing of the metal conduction path from the pipe to the flange. Water vapour can condense and freeze (and/or desublimate) in annular space 165, formed by bore 150 and pipe 41, due to the cold temperatures of the cryogenic fluid in the pipe. Annular space 165 can be filled with a low thermal conductivity material that can contract at a predetermined rate comparable to the rate of temperature change, to displace moisture. Non-limiting examples of such materials comprise glass fiber reinforced plastic, a composite material, and a PTFE foam. Alternatively, the opening into annular space 165 can be sealed at surface 65 to prevent the accumulation of moisture in the space. In general, portion 120 of the passageway can extend from either face 65 or 85, as long as the relative spatial relationship between portion 120 and annular groove 155 is maintained, that is the annular groove extends from the opposite face as portion 120.

[0035] Referring now to FIG. 12 a fourth embodiment of flange 54 is shown where passageway 111 and annular groove 155 are formed by placing insert 58 in bore 175, which extends from face 85 to face 65 of the flange. Insert 58 is connected to bore 175 by annular groove weld 161, or alternatively the insert can be epoxied to, threaded into or press-fit into the bore. By using insert 58 the length of annular portion 56 can be increased, which allows for an increased range of axial contraction and flexion when flange 54 thermally contracts, thereby reducing the stress on weld joints between the pipe and the flange. The increased length of annular portion 56 also increases the thermal resistance between the pipe and the flange. In alternative embodiments, flange 55 can be formed as illustrated in FIG. 12 as an integrated component, for example machined from a unitary metal block.

[0036] Referring now to FIGS. 13 and 14, a fifth embodiment of flange 55 is shown. Pipes 42 and 44 are welded to face 65 and 85 by welds 162 and 164 respectively, and are employed to communicate a cryogenic fluid to and from flange 55, which depending on the type of pipe (fill pipe, delivery pipe or drain pipe) can flow in either direction through a passageway defined by bore 300. In other embodiments pipes 42 and 44 can be one pipe that extends through bore 300 in flange 55. Annular groove 155 around bore 300 extends into flange 55 from face 65, in the illustrated embodiment. Annular groove 310 extends from face 85 into the flange and around both annular groove 155 and bore 300. Annular grooves 155 and 300 in cooperation with bore 300 form a bellows to redirect thermal contractions of flange 50 in a direction that is not constrained, thereby reducing stress on welds 162 and 164. Annular portions 56 and 57 allow for axially contraction (in the direction of the axis of passageway 111) and flexion when flange 50 thermally contracts. In other embodiments, additional annular grooves can be employed, around bore 300, alternating between face 65 and 85, to increase the size of the bellows formed by these grooves, thereby increasing the flexion of the flange during thermal contractions. Annular groove 155, and any other annular grooves that are externally facing with respect to storage vessel 25 (seen in FIG. 2), can be filled with a low thermal conductivity material (such as epoxy), or sealed at the opening, to displace moisture therein thereby reducing the likelihood of frost and/or ice forming in the groove(s).

[0037] While particular elements, embodiments and applications of the present invention have been shown and described, it will be understood, that the invention is not limited thereto since modifications can be made by those skilled in the art without departing from the scope of the present disclosure, particularly in light of the foregoing teachings.