Pressure-energized probe seal for female hydraulic coupling member

Abstract

A probe seal for a female hydraulic coupling member has both internal and external pressure-energized seals. The outer wall or opposing ends of the seal have one or more pressure-energized seals for sealing between the body of the probe seal and the body of a coupling member in which the probe seal is installed. Annular, L-shaped, T-shaped or angled grooves in the inner wall of the seal form cavities and sealing projections that can be urged in an inward, radial direction by fluid pressure within an associated cavity to increase the sealing effectiveness between the body of the seal and the probe of a male hydraulic coupling member inserted in the receiving chamber of the female coupling member.

Claims

1. A female member of a hydraulic coupling for coupling with a probe of a male member of the hydraulic coupling to seal fluid pressure therebetween, the probe having an external cylindrical surface, the female member comprising: a housing having a central axial bore, the central axial bore having an internal cylindrical surface, the central axial bore having first and second shoulders disposed at opposing angles to a longitudinal axis of the housing; and a seal disposed within the central axial bore between the first and second shoulders, the seal comprising: a ring-shaped body having a first end, an opposing second end, an outer surface, and an inner surface, the outer surface being configured to seal against the internal cylindrical surface, the inner surface forming a central passage, the central passage configured to receive the probe inserted therein and configured to seal against the external cylindrical surface of the probe inserted therein, the first end disposed adjacent the first shoulder, the second end disposed adjacent the second shoulder; a first annular chamber defined within the ring-shaped body toward the first end between the inner and outer surfaces, the first annular chamber disposed in communication with the central passage through a first passageway defined in the inner surface, the first annular chamber having a first inner wall and having a first outer wall, wherein the first inner wall, the first passageway, and a first portion of the inner surface define a first lip, the first lip being flexible inward against the external cylindrical surface of the probe inserted in the central passage by first of the fluid pressure within the first annular chamber; and a second annular chamber defined within the ring-shaped body toward the second end between the inner surface and the outer surface, the second annular chamber in communication with the central passage through a second passageway defined in the inner surface, the second annular chamber having a second inner wall and having a second outer wall, wherein the second inner wall, the second passageway, and a second portion of the inner surface define a second lip, the second lip being flexible inward against the external cylindrical surface of the probe inserted in the central passage by second of the fluid pressure within the second annular chamber.

2. The female member of claim 1, wherein the seal comprises a sealing projection disposed on the inner surface of the ring-shaped body between the first and second lips, the sealing projection configured to seal against the external cylindrical surface of the probe inserted in the central passage.

3. The female member of claim 2, wherein the sealing projection comprises an apex disposed about the inner surface at a midline of the seal.

4. The female member of claim 2, wherein the sealing projection comprises: a third lip disposed adjacent the first lip and separated therefrom by a third annular chamber; and a fourth lip disposed adjacent the second lip and separated therefrom by a fourth annular chamber, whereby the first, second, third, and fourth annular chambers define a plurality of grooves in the inner surface of the ring-shaped body, and whereby the first, second, third, and fourth lips define a plurality of sealing lips on the inner surface of the ring-shaped body.

5. The seal female member of claim 1, wherein the inner surface of the ring-shaped body defines a curved portion between the first and second lips.

6. The female member of claim 1, wherein the inner surface of the ring-shaped body defines straight portions respectively between the first passageway and the first end and between the second passageway and the second end.

7. The female member of claim 1, wherein the ring-shaped body of the seal comprises an elastomer.

8. The female member of claim 1, wherein the ring-shaped body of the seal is fabricated from a material selected from the group consisting of: polyetheretherketone (PEEK); acetal resins; polytetrafluoroethylene (PTFE); glass-filled PTFE; and, PEEK-filled PTFE.

9. The female member of claim 1, wherein the ring-shaped body of the seal consists of an engineering plastic.

10. The female member of claim 9, wherein the ring-shaped body is machined from the engineering plastic.

11. The female member of claim 1, wherein the first and second lips are configured such that inner fluid under pressure that enters the respective annular chamber via the respective passageway exerts an inward, radial force on the inner wall of the respective annular chamber and increases sealing effectiveness of the inner surface to the probe of the male member coupled to the female coupling member.

12. The female member of claim 11, wherein the seal further comprises: a first annular groove defined in the first end of the seal body proximate the outer surface; and a second annular groove defined in the second end of the seal body proximate the outer surface, wherein the first and second annular grooves are configured such that outer fluid under pressure that enters the respective annular groove exerts an outward radial force that increases a sealing effectiveness of the outer surface of the seal to the central axial bore of the housing.

13. The female member of claim 1, wherein the housing comprising at least one retainer disposed in a receptacle defined in the housing, the at least one retainer forming a portion of the central axial bore and having at least one of the first and second shoulders.

14. The female member of claim 1, wherein a first surface of the first end and a second surface of the second end are disposed at complimentary acute angles relative to a longitudinal axis of the ring-shaped body such that an axial dimension of the seal is greater at the outer surface than at the inner surface.

15. The female member of claim 1, wherein the first inner wall and the first outer wall of the first annular chamber are disposed at a first angle relative to a longitudinal axis of the ring-shaped body; and wherein the second inner wall and the second outer wall of the second annular chamber are disposed at a second angle, opposite the first angle, relative to the longitudinal axis of the ring-shaped body.

16. The female member of claim 15, further comprising: a third lip disposed adjacent the first lip and separated therefrom by a third annular chamber; and a fourth lip disposed adjacent the second lip and separated therefrom by a fourth annular chamber, whereby the first, second, third, and fourth annular chambers define a plurality of grooves in the inner surface of the ring-shaped body, and whereby the first, second, third, and fourth lips define a plurality of sealing lips on the inner surface of the ring-shaped body.

17. The female member of claim 15, further comprising a first annular groove defined in the first end of the ring-shaped body proximate the outer surface; and a second annular groove defined in the second end of the ring-shaped body proximate the outer surface.

18. The female member of claim 17, wherein an outside diameter of the seal is greater at the first and second ends of the body having the first and second annular grooves than at a middle of the ring-shaped body.

19. The female member of claim 15, wherein a first surface of the first end and a second surface of the second end are disposed at complimentary acute angles relative to a longitudinal axis of the ring-shaped body such that an axial dimension of the seal is greater at the outer surface than at the inner surface.

20. The female member of claim 1, wherein the first inner wall is acute to the inner surface and the first outer wall is acute to the outer surface; and wherein the second inner wall is acute to the inner surface and the second outer wall is acute to the outer surface.

21. The female member of claim 20, wherein each of the first and second annular chambers together with the associated first and second passageway is generally L-shaped in cross section; and wherein each of the first and second lips defines an axial projection extending along a longitudinal axis of the ring-shaped body toward the respective first and second end.

22. The female member of claim 20, wherein the first passageway of the first annular chamber is disposed in communication with the second passageway of the second annular chamber; and wherein each of the first and second lips defines an axial projection extending along a longitudinal axis of the ring-shaped body toward the opposite first and second end.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING(S)

(1) FIG. 1 is a cross-sectional view of a female hydraulic coupling member having a probe seal according to a first embodiment.

(2) FIG. 2 is an enlarged, cross-sectional view of the probe seal shown in FIG. 1.

(3) FIG. 2A is a detail of FIG. 2.

(4) FIG. 3A is a cross-sectional view of the probe seal of FIG. 2 shown installed in a female coupling member having a seal retainer.

(5) FIG. 3B is a cross-sectional view of the probe seal of FIG. 2 shown installed in a female coupling member having a seal cartridge.

(6) FIG. 4 is a cross-sectional view of a probe seal according to a second embodiment.

(7) FIG. 4A is a cross-sectional view of an alternative outside corner configuration for the probe seal shown in FIG. 4.

(8) FIG. 5 is a cross-sectional view of a probe seal according to a third embodiment of the invention.

(9) FIG. 5A is a detail of FIG. 5.

(10) FIG. 6 is a cross-sectional view of a probe seal according to a fourth embodiment of the invention.

(11) FIG. 7 is a cross-sectional view of a probe seal according to a fifth embodiment of the invention.

(12) FIG. 7A is a detail of FIG. 7.

(13) FIG. 8 is a cross-sectional view of a female hydraulic coupling member that incorporates the probe seal shown in FIG. 7.

DETAILED DESCRIPTION OF THE INVENTION

(14) The invention may best be understood by reference to certain illustrative embodiments shown in the drawing figures wherein like reference numbers are used to refer to like elements.

(15) Referring to FIG. 1, female hydraulic coupling member 10 comprises a generally cylindrical body with central axial bore 12. Optionally, one end of the coupling may be provided with means for connection to a hydraulic line or the like. In the illustrated embodiment, the connection means comprises threaded portion 14 of bore 12. The opposing end of coupling 10 has an enlarged portion of central bore 12 which forms receiving chamber 16 into which the probe of a corresponding male hydraulic coupling may be inserted. The female coupling 10 illustrated in FIG. 1 is configured to receive a cylindrical male probe having an outside diameter slightly smaller than the inside diameter of the innermost portion of receiving chamber 16.

(16) Coupling member 10 is also shown equipped with optional poppet valve 26 which is biased to the closed position by poppet spring 28 bearing against spring stop 29 within bore 12. Poppet valve 26 may prevent the loss of hydraulic fluid from within the coupling and the entry of seawater into the coupling when a male coupling member is not coupled to coupling 10.

(17) Central axial bore 12 has a stepped inside diameter with shoulders (some angled; some straight) between the various sections of differing diameters. Of particular note is angled shoulder 24 in bore 12. Probe seal 30 has a corresponding angled shoulder which bears against shoulder 24. Threaded retainer nut 18 has angled surface 22 on at least a portion of its inner face. Angled surface 22 may be a mirror image of angled shoulder 24. Retainer nut 18 may be provided with one or more pairs of spanner engagement holes 20 to permit the use of a spanner in seating and removing retainer nut 18.

(18) Pressure-energized probe seal 30 is shown with enhanced detail in FIG. 2. Probe seal 30 is comprised of a generally ring-shaped body having a central axial opening. The body has inner wall 31, outer wall 32 and opposing ends which comprise angled surfaces 33 and 33′. Seal 30 may be symmetric about its midline.

(19) Pressure-energized seals are provided on both the inner and outer surfaces of seal 30. A pair of opposed, pressure-energized seals on the outer surface of seal 30 are formed by a generally T-shaped groove 34 in outer wall 32. Sealing projections (or “lips”) 35 and 35′ may be angled slightly outwardly from outer wall 32 to preload the seals when seal 30 is installed in a female coupling member. Fluid chambers 36 and 36′ are provided immediately inboard of sealing projections 35 and 35′, respectively.

(20) On the inner surface of seal 30, generally T-shaped groove 38 in inner wall 31 forms sealing projections (or “lips”) 39 and 39′. Fluid chambers 40 and 40′ are provided immediately inboard of sealing projections 39 and 39′, respectively.

(21) As will be appreciated by those skilled in the art, fluid pressure within chamber 36 acts to urge sealing projection 35 in an outward, radial direction thereby increasing the sealing effectiveness at sealing surface 37. Likewise, fluid pressure within chamber 40 acts to urge sealing lip 39 in an inward, radial direction, thereby increasing the sealing effectiveness at sealing surface 41.

(22) When installed in female coupling member 10, angled surfaces 33 and 33′ engage angled shoulder 24 and angled surface 22 in a dovetail interfit when retainer nut 18 is fully seated on shoulder 25. Implosion of seal 30 into receiving chamber 16 is thereby inhibited during negative pressure events—i.e., when the pressure within receiving chamber 16 is less than the ambient pressure (such as may occur upon withdrawal of a male probe from receiving chamber 16).

(23) Probe seal 30 may be fabricated of any suitable material and may be formed by any suitable method including, but not limited to, molding and machining. One particularly preferred material for probe seal 50 is polyetheretherketone (PEEK). Additional examples of suitable materials include DELRIN™ acetal resin engineering plastic, TEFLON™ polytetrafluoroethylene (PTFE), glass-filled PTFE, PEEK-filled PTFE, and similar, relatively soft, machinable polymers.

(24) Operation of pressure-energized seal 30 will now be described. Because seal 30 is symmetric about its midline (and may therefore be inserted in coupling 10 in either direction), in the following description, the elements designated with the prime symbol (e.g., 35′ and 39′) are those proximate retainer nut 18 and those corresponding elements without the prime symbol (e.g., 36 and 40) are those proximate shoulder 24 in coupling 10.

(25) In operation under positive pressure conditions—i.e., when the pressure of the hydraulic fluid within the coupling exceeds the ambient pressure (most commonly that produced by the hydrostatic head of the surrounding seawater)—hydraulic fluid enters chamber 36′ and urges the outer sealing projection 35′ in an outward, radial direction, thereby increasing the contact pressure (and hence, sealing effectiveness) between sealing surface 37′ and the opposing inner wall of central axial bore 12.

(26) Likewise, hydraulic fluid under pressure will enter chamber 40′ and urge inner sealing projection 39′ in an inward, radial direction, thereby increasing the contact pressure (and hence, sealing effectiveness) between sealing surface 41′ and the opposing outer surface of a male probe member seated in receiving chamber 16.

(27) In operation under negative pressure conditions—i.e., when the pressure of the hydraulic fluid within the coupling is less than the hydrostatic head—seawater enters chamber 36 and urges the outer sealing projection 35 in an outward, radial direction, thereby increasing the contact pressure (and hence, sealing effectiveness) between sealing surface 37 and the opposing inner wall of central axial bore 12.

(28) Likewise, seawater will enter chamber 40 and urge inner sealing projection 39 in an inward, radial direction, thereby increasing the contact pressure (and hence, sealing effectiveness) between sealing surface 41 and the opposing outer surface of a male probe member seated in receiving chamber 16.

(29) The use of probe seal 30 in female coupling members of alternative design is illustrated in FIGS. 3A and 3B. Female coupling member 50 (shown in FIG. 3A) additionally comprises a seal retainer 70 and a pressure-energized metal C-seal 76. Female coupling member 80 (shown in FIG. 3B) additionally comprises a seal cartridge comprised of seal retainer 100 and shell 88 as well as a pressure-energized metal C-seal 106.

(30) Referring to FIG. 3A, female hydraulic coupling member 50 comprises a generally cylindrical body with central axial bore 52. Optionally, one end of the coupling may be provided with means for connection to a hydraulic line or the like (not shown). The opposing end of coupling 50 has an enlarged portion of central bore 52 which forms receiving chamber 56 into which the probe of a corresponding male hydraulic coupling may be inserted. The female coupling 50 illustrated in FIG. 3A is configured to receive a cylindrical male probe having an outside diameter slightly smaller than the inside diameter of the innermost portion of receiving chamber 56.

(31) Coupling member 50 is also shown equipped with optional poppet valve 66 which is biased to the closed position by poppet spring 68 bearing against spring stop 69 within bore 52. Poppet valve 66 may prevent the loss of hydraulic fluid from within the coupling and the entry of seawater into the coupling when a male coupling member is not coupled to coupling 50.

(32) Central axial bore 52 has a stepped inside diameter with shoulders between the various sections of differing diameters. Of particular note is shoulder 74 in bore 52. Pressure-energized probe seal 76 is installed on shoulder 74. In the illustrated example, probe seal 76 is a metal C-seal. Probe seal 76 is held on shoulder 74 by inner end 79 of seal retainer 70. Seal retainer 70 is held against shoulder 78 by retainer nut 58. Inner end 79 of seal retainer 70 may have an annular groove into which an O-ring seal 72 (or similar such seal) may be inserted for sealing between the body of coupling 50 and seal retainer 70.

(33) Seal retainer 70 may include angled shoulder 64 sized and configured to engage angled surface 33′ of probe seal 30. The inner end of retainer nut 58 may include angled surface 62 which is similarly sized and configured to engage angled surface 33 of probe seal 30. Angled surface 62 may be a mirror image of angled shoulder 64. A non-angled portion of the inner face of threaded retainer nut 58 may bear against outer end 77 of seal retainer 70, holding it on shoulder 78. Retainer nut 58 may be provided with one or more pairs of spanner engagement holes 60 to permit the use of a tool in seating and removing retainer nut 58.

(34) Referring to FIG. 3B, female hydraulic coupling member 80 comprises a generally cylindrical body with central axial bore 82. Optionally, one end of the coupling may be provided with means for connection to a hydraulic line or the like (not shown). The opposing end of coupling 80 has an enlarged portion of central bore 82 which forms receiving chamber 86 into which the probe of a corresponding male hydraulic coupling may be inserted. The female coupling 80 illustrated in FIG. 3A is configured to receive a cylindrical male probe having an outside diameter slightly smaller than the inside diameter of the innermost portion of receiving chamber 86.

(35) Coupling member 80 is also shown equipped with optional poppet valve 96 which is biased to the closed position by poppet spring 98 bearing against spring stop 99 within bore 82. Poppet valve 96 may prevent the loss of hydraulic fluid from within the coupling and the entry of seawater into the coupling when a male coupling member is not coupled to coupling 80.

(36) Central axial bore 82 has a stepped inside diameter with shoulders between the various sections of differing diameters. The outermost portion of bore 82 may be internally threaded to engage a corresponding portion of shell 88.

(37) Female coupling member 80 includes a seal cartridge comprised of seal retainer 100 and cartridge shell 88. Extension 89 may be an interference fit with reduced o.d. diameter portion 109 of retainer 100 such that removal of shell 88 (e.g., by unscrewing) also effects withdrawal of retainer 100. Retainer 100 and shell 88 may each have angled shoulders sized and configured to engage angled surfaces 33 and 33′ on probe seal 30.

(38) Inner end 108 of seal retainer 100 may have a shoulder 104 for holding pressure-energized probe seal 106. In the illustrated example, probe seal 106 is a metal C-seal. Inner end 108 of seal retainer 100 may also have an annular groove into which an O-ring seal 102 (or similar such seal) may be inserted for sealing between the body of coupling 80 and seal retainer 100.

(39) Seal retainer 100 may include angled shoulder 94 sized and configured to engage angled surface 33′ of probe seal 30. Shell 88 may include angled shoulder 92 which is similarly sized and configured to engage angled surface 33 of probe seal 30. Angled surface 92 may be a mirror image of angled shoulder 94. A non-angled portion of the shoulder of shell 88 adjacent extension 89 may bear against outer end of seal retainer 100, holding it on the shoulder in bore 82. Retainer 88 may be provided with one or more pairs of spanner engagement holes 90 to permit the use of a tool in seating and removing the seal cartridge comprised of seal retainer 100 and shell 88.

(40) A second embodiment of the invention is shown in FIG. 4. The pressure-energized seal on the interior surface of probe seal 200 is the same as that employed by probe seal 30 illustrated in FIGS. 1-4. Specifically, generally T-shaped groove 208 in inner wall 201 forms sealing projections (or “lips”) 209 and 209′. Fluid chambers 210 and 210′ are provided immediately inboard of sealing projections 209 and 209′, respectively.

(41) As will be appreciated by those skilled in the art, fluid pressure within chamber 210 acts to urge sealing lip 209 in an inward, radial direction, thereby increasing the sealing effectiveness at sealing surface 211.

(42) When installed in female coupling member such as 10, 50 or 80, angled surfaces 203 and 203′ engage corresponding angled shoulders and/or angled surfaces in the coupling body in a dovetail interfit. Implosion of seal 200 into the receiving chamber of the coupling is thereby inhibited during negative pressure events—i.e., when the pressure within the receiving chamber is less than the ambient pressure (such as may occur upon withdrawal of a male probe from the receiving chamber).

(43) The ends of ring-shaped seal 200 each have an annular groove 206 open to an end surface of seal 200. Hydraulic fluid, under pressure, can enter one or both of grooves 206,206′ through the open end of the groove. Inasmuch as the distal portion of seal 200 is substantially at ambient pressure (typically, a lower pressure than that of the hydraulic fluid), a pressure differential is established which exerts an outward, radial force on sealing surface 207. This force acts to increase the sealing effectiveness of seal 200 to the body of the coupling member in which it is installed by increasing the pressure on sealing surface 207. Sealing projections 205 may act as a “living hinge” or flexure bearing. In female coupling members having a seal cartridge, the outward, radial force acts to increase the sealing effectiveness of seal 200 to the seal cartridge. In female coupling members not having a seal retainer or seal cartridge (such as that illustrated in FIG. 1), the outward, radial force acts to increase the sealing effectiveness of seal 200 directly to the body of the female coupling member.

(44) In negative pressure situations—i.e., wherein the pressure within the receiving chamber of the female coupling member is lower than the ambient pressure such as often occurs during probe withdrawal, the pressure differential between cavity 204 and cavity 206 creates an outward, radial force against the distal pressure-energized sealing surface 207 increasing the sealing effectiveness. As shown in the drawing figures, sealing projections 205 may project slightly from outer surface 202 of seal 200 such that the seals are preloaded when installed in the body or seal cartridge of a female coupling member. Stated another way, the outside diameter of seal 200 may be somewhat greater at sealing surfaces 207 than at surface 202.

(45) The symmetry of seal 200 about its midline permits its installation in a female coupling member such as the ones illustrated in FIGS. 1, 3A and 3B without regard to its orientation. This feature decreases the possibility of incorrect assembly of the coupling. A portion of the body of the female coupling member is shown in phantom in FIG. 4.

(46) An alternative configuration of seal 200 is shown in FIG. 4A. The end of the seal body has an outer, flat portion 300 adjacent an inner, angled portion 303 so as to fit a correspondingly configured female coupling member body or seal cartridge (shown in phantom). This gives a slightly different shape to sealing projection 305 and annular groove 310.

(47) A third embodiment of a pressure-energized probe seal according to the invention is shown in FIG. 5. Probe seal 500 features the same type of pressure-energized sealing elements on its outer surface 502 as that of probe seal 200 shown in FIG. 4. Namely, the ends of ring-shaped seal 500 each have an annular groove 506 open to an end surface of seal 500. Hydraulic fluid, under pressure, can enter one or both of grooves 506,506′ through the open end of the groove. Inasmuch as the distal portion of seal 500 is substantially at ambient pressure (typically, a lower pressure than that of the hydraulic fluid), a pressure differential is established which exerts an outward, radial force on sealing surface 507. This force acts to increase the sealing effectiveness of seal 500 to the body of the coupling member in which it is installed by increasing the pressure on sealing surface 507. Sealing projections 505 may act as a “living hinge” or flexure bearing. In female coupling members having a seal cartridge, the outward, radial force acts to increase the sealing effectiveness of seal 500 to the seal cartridge. In female coupling members not having a seal retainer or seal cartridge (such as that illustrated in FIG. 1), the outward, radial force acts to increase the sealing effectiveness of seal 500 directly to the body of the female coupling member.

(48) In negative pressure situations—i.e., wherein the pressure within the receiving chamber of the female coupling member is lower than the ambient pressure such as often occurs during probe withdrawal, the pressure differential between cavity 506 and that at surface 502 creates an outward, radial force against the distal pressure-energized sealing surface 507 increasing the sealing effectiveness. As shown in the drawing figures, sealing projections 505 may project slightly from outer surface 502 of seal 500 such that the seals are preloaded when installed in the body or seal cartridge of a female coupling member. Stated another way, the outside diameter of seal 500 may be somewhat greater at sealing surfaces 507 than at surface 502.

(49) The pressure-energized seals on the interior surface of probe seal 500 are formed by generally L-shaped grooves 508 and 508′ in inner wall 501. Grooves 508 define sealing projections (or “lips”) 509 and 509′ together with fluid cavities 510 and 510′. Inner wall 501 may have a curved portion 512 between straight portions 513 and 513′. Sealing projections 509 may project slightly from inner wall 501 so as to provide a preload to the seals when the probe element of a male coupling member is inserted. Stated another way, the inside diameter of probe seal 500 may be slightly smaller at sealing surface 511 than at flat portion 513. As will be appreciated by those skilled in the art, if fluid pressure in chamber 510 (or 510′) exceeds that at surface 512, sealing projection 509 (or 509′) will be urged in an inward, radial direction, thereby enhancing the sealing effectiveness of sealing surface 511 (or 511′) to the probe of a male coupling member inserted in the female coupling member holding probe seal 500.

(50) FIG. 6 shows a fourth embodiment of the invention which is a variation of the third embodiment (illustrated in FIG. 5). Probe seal 600 has the same pressure-energized seals as the probe seal shown in FIG. 5. However, probe seal 600 has an additional radial sealing projection 620 at its midline. Sealing projection 620 may be generally triangular in cross section with apex 625 projecting into the central cavity. Sealing projection 620 may help align the probe member of a corresponding male coupling member during insertion.

(51) A fifth embodiment of the invention is shown in FIGS. 7 and 7A. Probe seal 700 has the same type of pressure-energized sealing elements on its outer surface as that described above in reference to probe seals 200, 500 and 600. Specifically, the ends of ring-shaped seal 700 each have an annular groove 706 open to an end surface of seal 700. Hydraulic fluid, under pressure, can enter one or both of grooves 706, 706′ through the open end of the groove. Inasmuch as the distal portion of seal 700 is substantially at ambient pressure (typically, a lower pressure than that of the hydraulic fluid), a pressure differential is established which exerts an outward, radial force on sealing surface 707. This force acts to increase the sealing effectiveness of seal 700 to the body of the coupling member in which it is installed by increasing the pressure on sealing surface 707. Sealing projections 705 may act as a “living hinge” or flexure bearing. In female coupling members having a seal cartridge, the outward, radial force acts to increase the sealing effectiveness of seal 700 to the seal cartridge. In female coupling members not having a seal retainer or seal cartridge (such as that illustrated in FIG. 1), the outward, radial force acts to increase the sealing effectiveness of seal 700 directly to the body of the female coupling member.

(52) In negative pressure situations—i.e., wherein the pressure within the receiving chamber of the female coupling member is lower than the ambient pressure such as often occurs during probe withdrawal, the pressure differential between cavity 706 and that at surface 702 creates an outward, radial force against pressure-energized sealing surface 707′ increasing the sealing effectiveness. As shown in the drawing figures, sealing projections 705 may project slightly from outer surface 702 of seal 700 such that the seals are preloaded when installed in the body or seal cartridge of a female coupling member. Stated another way, the outside diameter of seal 700 may be somewhat greater at sealing surfaces 707 than at surface 702.

(53) Probe seal 700 features a plurality of pressure-energized seals on its interior surface. These pressure-energized seals are formed by outer angled grooves 730 and 730′ and inner angled grooves 740 and 740′ in inner wall 701 of seal 700. Probe seal 700 may be symmetric about its midline thereby obviating “reverse” installation in a female coupling member. Grooves 730 and 740 form sealing lips 732 and 742.

(54) As will be appreciated by those skilled in the art, when fluid pressure within grooves 730 and/or 740 exceeds the fluid pressure at surface 701′, sealing lips 732 and 742, respectively, will be urged in an inner, radial direction thereby enhancing their sealing effectiveness. Conversely, when fluid pressure within grooves 730′ and/or 740′ exceeds the fluid pressure at surface 701, sealing lips 732′ and 742′, respectively, will be urged in an inner, radial direction thereby enhancing their sealing effectiveness. In this way, a pressure-energized seal is provided under both “positive” and “negative” pressure conditions—i.e., both during coupled operation of the coupling (when hydraulic fluid pressure exceeds the ambient pressure) and during probe withdrawal or loss of hydraulic pressure (when the ambient pressure of the surrounding seawater exceeds the pressure at the inner end of the receiving chamber).

(55) Because of the plurality of pressure-energized seals on the inner surface of seal 700, it may be desirable to provide the body of seal 700 with a somewhat larger axial dimension than that of seals 30, 200, 500 and 600, described above. However, a greater axial dimension would necessitate a female coupling member of different dimensions. Such a coupling member is shown in FIG. 8 as coupling member 710. Coupling 710 is of the same general design as that shown in FIG. 1. However, in coupling 710, the distance between angled shoulder 24 and angled surface 22 is increased in order to accommodate the longer length of pressure-energized probe seal 700.

(56) Summary of the embodiments in the present disclosure are discussed in the following paragraphs.

(57) In embodiments shown in FIGS. 2, 2A, 4, 5, 5A, 7, and 7A, a probe seal (30, 200, 500, 600, 700) for a female hydraulic coupling member (10, 80) comprises: a generally ring-shaped body (400, 800, 900, 1000) having a first end (402, 802, 902, 1002), an opposing second end (404, 804, 904, 1004), a generally cylindrical outer surface (406, 806, 906, 1006) and a generally cylindrical inner surface (408, 808, 908, 1008); a first annular chamber (40, 210, 510, 730) within the ring-shaped body (400, 800, 900, 1000) between the inner surface (406, 806, 906, 1006) and the outer surface (408, 808, 908, 1008), the chamber (40, 210, 510, 730) having (i) an inner wall (418, 818, 918, 1018), the inner wall (418, 818, 918) in FIGS. 2, 2A, 4, 5 and 5A being generally parallel to the inner surface (408, 808, 908) and the inner wall (1018) in FIGS. 7 and 7A being acute to the inner surface (1008), and (ii) an outer wall (416, 816, 916, 1016), the outer wall (416, 816, 916) in FIGS. 2, 2A, 4, 5 and 5A being generally parallel to the outer surface (406, 806, 906) and the outer wall (1016) in FIGS. 7 and 7A being acute to the inner surface (1008); and a first fluid passageway (410, 810, 910, 1010) connecting the annular chamber (40, 210, 510, 730) with the inner surface (408, 808, 908, 1008).

(58) In embodiments shown in FIGS. 4, 5, 5A, 6, 7, and 7A, the probe seal (200, 500, 600, 700) has an annular groove (206, 506, 706) in at least one end (802, 804/902, 904/1002, 1004) of the ring-shaped body (800, 900, 1000) proximate the outer surface (806, 906, 1006).

(59) In embodiments shown in FIGS. 2, 2A, 4, 5, 5A, 7, and 7A, the probe seal (30, 200, 500, 600, 700) has a second annular chamber (40′, 210′, 510′, 730′, 740, 740′) within the ring-shaped body (400, 800, 900, 1000) between the inner surface (408, 808, 908, 1008) and the outer surface (406, 806, 906, 1006), the chamber (40′, 210′, 510′, 730′, 740, 740′) having (i) an inner wall (418, 818, 918, 1015), the inner wall (418, 818, 918) in FIGS. 2, 2A, 4, 5 and 5A being generally parallel to the inner surface (408, 808, 908) and the inner wall (1018) in FIGS. 7 and 7A being acute to the inner surface (1008), and (ii) an outer wall (416, 816, 916, 1016), the outer wall (416, 816, 916) in FIGS. 2, 2A, 4, 5 and 5A being generally parallel to the outer surface (406, 806, 906) and the outer wall (1016) in FIGS. 7 and 7A being actuate to the inner surface (1008).

(60) In embodiments shown in FIGS. 2, 2A, and 4, the second annular chamber (40′, 210′) is in fluid communication with the first fluid passageway (410, 810) of the first annular chamber (40, 210).

(61) In embodiments shown in FIGS. 2, 2A, 4, 5 and 5A, the annular chamber (40, 40′, 210, 210′, 510, 510′, 730, 730′, 740, 740′) together with the fluid passageway (810, 910, 1010) is generally L-shaped in cross section. In embodiments shown in FIGS. 2, 2A, 4, 5, 5A, 7, and 7A, the annular chamber (40, 40′, 210, 210′, 510, 510′, 730, 730′, 740, 740′) defines an axial projection (41, 41′, 210, 210′, 509, 509′, 732, 732′, 742, 742′) which may be urged in an inward, radial direction by fluid pressure within the annular chamber (40, 40′, 210, 210′, 510, 510′, 730, 730′, 740, 740′).

(62) In embodiments shown in FIGS. 2, 2A, 4, 5, 5A, 7, and 7A, the probe seal (30, 200, 500, 600, 700) is symmetric about its midline.

(63) In embodiments shown in FIGS. 5, 5A, 6, 7, and 7A, the probe seal (500, 600, 700) further comprises at least one sealing projection (elements 509, 509′, 511, 511′; elements 620, 625; elements 742, 742′) on the inner surface (908, 1008) of the probe seal (500, 600, 700). As shown, the sealing projection is at the midline of the seal (500, 600, 700).

(64) In embodiments shown in FIGS. 7 and 7A, a probe seal (700) for a female hydraulic coupling member comprises: a generally ring-shaped body (1000) having a first end (1002), an opposing second end (1004), a generally cylindrical outer surface (1006) and a generally cylindrical inner surface (1008); a plurality of grooves (730, 730′, 740, 740′) in the inner surface (1008), the grooves (730, 730′, 740, 740′) being disposed at an acute angle (β, β′) to the longitudinal axis of the ring-shaped body (1000) and forming a plurality of sealing lips (732, 732′, 742, 742′) on the inner surface (1008) of the ring-shaped body (1000); and an annular groove (706, 706′) in at least one end (1002, 1004) of the ring-shaped body proximate (1000) the outer surface (1006).

(65) In embodiments shown in FIGS. 4, 5, 6, and 7, the probe seal (200, 500, 600, 700) comprises an annular groove (206, 206′; 506, 506′; 706, 706′) in each end (802, 804/902, 904/1002, 1004) of the ring-shaped body (800, 900, 1000) proximate the outer surface (806, 906, 1006), the probe seal (200, 500, 600, 700) being symmetric about its midline. As shown, the outside diameter of the probe seal (200, 500, 600, 700) is greater at the end (802, 804/902, 904/1002, 1004) of the ring-shaped body (800, 900, 1000) having the annular groove (206, 206′; 506, 506′; 706, 706′) than at the middle of the ring-shaped body (800, 900, 1000).

(66) In embodiments shown in FIGS. 2, 2A 4, 5, 5A, 6, 7, and 7A, at least a portion of the surface (e.g., 33, 203, 503, 703) of the first end (402, 802, 902, 1002) and at least a portion of the surface (e.g., 33′, 203′, 503′, 703′) of the second end (404, 804, 904, 1004) are disposed at complimentary acute angles (a, a′) to the longitudinal axis of the generally ring-shaped body (400, 800, 900, 1000) such that the axial dimension of the probe seal (30, 200, 500, 600, 700) is greater at its outer surface (406) than its axial dimension at its inner surface (408, 808, 908, 1008).

(67) In an embodiment, the ring-shaped body (400, 800, 900, 1000) comprises an elastomer.

(68) In an embodiment, the ring-shaped body (400, 800, 900, 1000) is fabricated from a material selected from the group consisting of:

(69) polyetheretherketone (PEEK); acetal resins; polytetrafluoroethylene (PTFE); glass-filled PTFE; and, PEEK-filled PTFE.

(70) In an embodiment, the ring-shaped body (400, 800, 900, 1000) consists of an engineering plastic.

(71) In an embodiment, the ring-shaped body (400, 800, 900, 1000) is machined from the engineering plastic.

(72) Although the invention has been described in detail with reference to certain preferred embodiments, variations and modifications exist within the scope and spirit of the invention as described and defined in the following claims.