US2023131218A1PendingUtilityA1
Rupture disc assembly
Est. expiryMar 30, 2040(~13.7 yrs left)· nominal 20-yr term from priority
F16K 17/16E21B 34/06E21B 34/063
65
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Claims
Abstract
Disclosed is a rupture disc assembly for use in making a temporary seal in a vessel such as a casing string. The rupture disc assembly may generally include (A) a rupture disc having a side surface having a shallow taper inward towards a bottom surface of the rupture disc (B) an actuating mechanism including (i) an outer sled having an inner supporting surface forming a taper complimentary to the shallow taper of the side surface, (ii) an inner sled disposed within the outer sled and having a support shoulder to support the bottom surface of the rupture disc and (iii) a securing mechanism and (C) a housing to house the rupture disc and actuating mechanism.
Claims
exact text as granted — not AI-modified1 . A rupture disc assembly for use in a vessel, the rupture disc assembly comprising:
a rupture disc comprising a pressure facing surface, a bottom surface, and a side surface having a shallow taper inward towards the bottom surface of the rupture disc; an actuating mechanism configured to support the rupture disc and operable to be activated when the pressure facing surface of the rupture disc is subjected to a disc failure trigger pressure, the actuating mechanism comprising: i) an outer sled operable to move in a downhole direction from a first position to a second position after activation of the actuating mechanism, the outer sled comprising an inner supporting surface having an uphole portion and a downhole portion having an inward taper complementary to and abutting the shallow taper of the side surface of the rupture disc and a bottom surface; ii) an inner sled disposed within the outer sled and operable to move in a downhole direction from a first position to a second position after activation of the actuating mechanism, the inner sled comprising a cylindrical inner surface, a support shoulder configured to abut with at least a segment of the bottom surface of the rupture disc and a bottom surface downhole from the bottom surface of the outer sled; iii) a securing mechanism operable to secure the outer sled and inner sled in their first positions and release the outer sled and inner sled after activation of the actuating mechanism; wherein the rupture disc is operable to form a temporary seal within the rupture disc assembly when the outer sled and inner sled are in their first positions and, after activation of the actuating mechanism, to break after the inner sled reaches its second position.
2 . The rupture disc assembly of claim 1 , further comprising a housing configured to house the rupture disc and actuating mechanism, the housing comprising a) an upper tubular member having an upper end, a lower end and an interior surface defining a fluid passageway therethrough and b) a lower tubular member having an upper end coupled to the lower end of the upper tubular member, a lower end and an interior surface defining a fluid passageway therethrough with a stop shoulder positioned on the interior surface operable to stop downhole movement of the inner sled at its second position when the bottom surface of the inner sled contacts the stop shoulder.
3 . The rupture disc assembly of claim 2 wherein the actuating mechanism further comprises a ring abutting an uphole portion of the inner supporting surface of the outer sled and having an impact surface and wherein the ring is operable to move in downhole direction after activation of the actuating mechanism.
4 . The rupture disc assembly of claim 3 , wherein the impact surface comprises a plurality of spaced apart ridges on a bottom surface of the hollow ring.
5 . The rupture disc assembly of claim 4 , wherein in operation, in response to the pressure facing surface of the rupture being subjected to pressure at least equal to the disc trigger pressure, the actuating mechanism is activated and the securing mechanism releases the outer sled and inner sled allowing the outer sled and inner sled to begin to move in a downhole direction wherein movement of the inner sled stops at its second position while movement of the outer sled and ring continues and wherein the rupture disc breaks in response to the pressure facing surface being subjected to: a disc rupture pressure; the impact surface of the ring; or a combination thereof.
6 . The rupture disc assembly of claim 1 , wherein the securing mechanism comprises a shear ring.
7 . The rupture disc assembly of claim 1 , wherein the actuating mechanism further comprises a lock ring operable to lock the outer sled in its second position.
8 . An apparatus for forming a buoyant chamber in a well, the apparatus comprising:
a) a first length of tubing operable to be positioned in the well and having an uphole end and a downhole end operable for connection to a second length of tubing having a float device operable for forming a lower boundary of a buoyant chamber and b) the rupture disc assembly of claim 2 coupled to the uphole end of the first length of tubing and operable for forming an upper boundary of the buoyant chamber during deployment of the buoyant chamber into the well.
9 . A casing string float assembly comprising a tubular having a lower seal in a lower position of the tubular, the rupture disc assembly of claim 1 at an upper position of the tubular to form an upper boundary and a buoyant chamber positioned between the lower boundary and the upper boundary.
10 . A method for installing a casing string in a wellbore, the method comprising: after a casing string float assembly of claim 7 has been run into a wellbore with a buoyant fluid maintained in the buoyant chamber, applying hydraulic pressure through the casing string float assembly to apply a pressure to the pressure facing surface of the rupture disc that is at least as great as the disc trigger pressure to cause the actuating mechanism to activate thereby releasing the securing mechanism to cause the inner sled to move from the first position to the second position and break the rupture disc thereby releasing the buoyant fluid from the buoyant chamber.
11 . A method of installing a casing string in a wellbore containing a well fluid having a specific gravity, the wellbore having an upper, substantially vertical portion, a lower, substantially horizontal portion, and a bend portion connecting the upper and lower portions, the method comprising: (a) running a casing string comprising the casing string float assembly of claim 7 into the wellbore, wherein the buoyant chamber comprises a fluid having a specific gravity less than the specific gravity of the well fluid, and (b) floating at least a portion of the casing string float assembly of 7 in the well fluid into the lower, substantially horizontal portion of the wellbore.
12 . A rupture disc assembly for use in a vessel, the rupture disc assembly comprising:
a rupture disc comprising a pressure facing surface, a bottom surface, and a side surface having a shallow taper inward towards the bottom surface of the rupture disc; an actuating mechanism configured to support the rupture disc and operable to be activated when the pressure facing surface of the rupture disc is subjected to a disc failure trigger pressure, the actuating mechanism comprising: an outer sled operable to move in a downhole direction from a first position to a second position after activation of the actuating mechanism, the outer sled comprising an inner supporting surface having an uphole portion and a downhole portion having an inward taper complementary to and abutting the shallow taper of the side surface of the rupture disc and a bottom surface; an inner sled disposed within the outer sled and operable to remain stationary in a first position after activation of the actuating mechanism, the inner sled comprising a cylindrical inner surface, a support shoulder configured to abut with at least a segment of the bottom surface of the rupture disc and a bottom surface downhole from the bottom surface of the outer sled; a securing mechanism operable to secure the outer sled and inner sled in their first positions and release the outer sled and inner sled after activation of the actuating mechanism; wherein the rupture disc is operable to form a temporary seal within the rupture disc assembly when the outer sled and inner sled are in their first positions and, after activation of the actuating mechanism, to break after the outer sled reaches its second position.
13 . The rupture disc assembly of claim 12 , further comprising a housing configured to house the rupture disc and actuating mechanism, the housing comprising a) an upper tubular member having an upper end, a lower end and an interior surface defining a fluid passageway therethrough and b) a lower tubular member having an upper end coupled to the lower end of the upper tubular member, a lower end and an interior surface defining a fluid passageway therethrough and a stop shoulder positioned on the interior surface operable to stop downhole movement of the outer sled at its second position when the bottom surface of the inner sled contacts the stop shoulder.
14 . The rupture disc assembly of claim 13 wherein the actuating mechanism further comprises a ring abutting an uphole portion of the inner supporting surface of the outer sled and having an impact surface and wherein the ring is operable to move in downhole direction after activation of the actuating mechanism.
15 . The rupture disc assembly of claim 14 , wherein the impact surface comprises a plurality of spaced apart ridges on a bottom surface of the ring.
16 . The rupture disc assembly of claim 15 , wherein in operation, in response to the pressure facing surface of the rupture being subjected to hydraulic pressure at least equal to the disc trigger pressure, the actuating mechanism is activated and the securing mechanism releases the outer sled and inner sled wherein the inner sled remains stationary and the outer sled moves in a downhole direction until it reaches its second position and the rupture disc breaks in response to the pressure facing surface being subjected to: a pressure of at least a disc rupture pressure; the impact surface of the ring; or a combination thereof.
17 . The rupture disc assembly of claim 12 , wherein the securing mechanism comprises a shear ring.
18 . The rupture disc assembly of claim 12 , wherein the actuating mechanism further comprises a lock ring operable to lock the outer sled in its second position.
19 . An apparatus for forming a buoyant chamber in a well, the apparatus comprising:
a) a first length of tubing operable to be positioned in the well and having an uphole end and a downhole end operable for connection to a second length of tubing having a float device operable for forming a lower boundary of a buoyant chamber and b) the rupture disc assembly of claim 13 coupled to the uphole end of the first length of tubing and operable for forming an upper boundary of the buoyant chamber during deployment of the buoyant chamber into the well.
20 . A casing string float assembly comprising a tubular having a lower seal in a lower position of the tubular, the rupture disc assembly of claim 12 at an upper position of the tubular to form an upper boundary and a buoyant chamber positioned between the lower boundary and the upper boundary.
21 . A method for installing a casing string in a wellbore, the method comprising: after a casing string float assembly of claim 20 has been run into a wellbore with a buoyant fluid maintained in the buoyant chamber, applying hydraulic pressure through the casing string float assembly to apply a pressure to the pressure facing surface of the rupture disc that is at least as great as the disc trigger pressure to cause the actuating mechanism to activate thereby releasing the securing mechanism to cause the outer sled to move from the first position to the second position and break the rupture disc thereby releasing the buoyant fluid from the buoyant chamber.
22 . A method of installing a casing string in a wellbore containing a well fluid having a specific gravity, the wellbore having an upper, substantially vertical portion, a lower, substantially horizontal portion, and a bend portion connecting the upper and lower portions, the method comprising: (a) running a casing string comprising the casing string float assembly of claim 20 into the wellbore, wherein the buoyant chamber comprises a fluid having a specific gravity less than the specific gravity of the well fluid, and (b) floating at least a portion of the casing string float assembly of 20 in the well fluid into the lower, substantially horizontal portion of the wellbore.Cited by (0)
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