BR112019020942B1 - SET OF RISE PIPE COMPONENTS HAVING A PRIMARY LUMEN, METHOD, AND METHOD FOR ASSEMBLY A RISE TUBE COMPONENT WITH A PRIMARY LUMEN - Google Patents

Abstract

These are sets of riser components and methods of mounting them that are suitable for managed pressure drilling (MPD) systems. For example, this disclosure includes integrated components of the flux coil and isolation tool that can be permanently coupled and that can be configured to traverse a rotary table or other platform equipment.

Description

DESCRIPTION CROSS REFERENCE TO RELATED ORDERS

[001] This patent application claims priority to the Provisional Application in U.S. 62/482,580 filed on April 6, 2017, the entire content of the application is specifically incorporated herein by reference without disclaimer.

FIELD OF INVENTION

[002] The present invention relates, in general, to riser assemblies suitable for offshore drilling and, more particularly, but without limitation, to integrated components of a riser assembly.

FUNDAMENTALS

[003] Offshore drilling operations have been carried out for many years. Traditionally, the pressure within a drill string and riser pipe is regulated by the density of the drilling mud alone. More recently, attempts have been made to control the pressure within a drill string and riser pipe using methods and characteristics in addition to the density of the drilling mud. Such attempts may be referred to in the art as managed pressure drilling (MPD). See, for example, Frink, Managed pressure drilling-what's in a name?, Drilling Contractor, March/April 2006, pp. 36 to 39.

SUMMARY

[004] MPD techniques generally require additional or different riser components compared to the risers used in conventional drilling techniques. These new or different components may be larger than those used in conventional techniques. For example, riser segments used for MPD techniques may utilize large components that force auxiliary lines to be routed around these components, which may increase the overall diameter or cross-sectional dimensions of the riser segments relative to to riser pipe segments used in conventional drilling techniques. However, numerous drilling rigs already exist, and it is generally not economical to adapt these existing drilling rigs to fit larger diameter riser segments.

[005] Currently, MPD riser segment assemblies and/or components with an overall diameter or other transverse dimension too large to fit into a rotary or rotary table of a drilling rig must be loaded onto the rig below deck ( e.g. on the mezzanine) and moved laterally to the position to be coupled to the riser pile below the roundabout. This movement of oversized components is generally more difficult than vertically lowering the equipment through the roundabout from above (e.g. with a crane). Solutions to these problems for insulation tool components and flux spool components can be found in U.S. Patent Applications No. 14/888,894 and PCT/US2014/036309, respectively. Although insulation tools and flow spools are often used together in MPD riser segment assemblies, they are conventionally manufactured as separate, coupled components when forming the riser assembly. In addition to the extra time and effort required to couple the isolation tool and flux coil together, the assembly generally also needs extra material in the form of connecting parts, such as flanges, to couple these components together. . At least some embodiments of the present invention can solve these problems by permanently coupling the insulation tool and the flux coil directly to each other (e.g., through soldering). In some embodiments, the isolation tool and flux coil are permanently coupled before being transported to the well or drilling site. In some embodiments, the flux coil component may be similar to a flux coil component such as that disclosed in PCT/US2014/036309, which is incorporated herein in its entirety. In some embodiments, the isolation tool may be an isolation tool such as that disclosed in U.S. Patent Application No. 14/888,894, each of which is incorporated herein in its entirety. In some embodiments, the combined isolation tool and flux coil component (also referred to herein as an integral isolation tool and flux coil component) may fit together through a rotary table.

[006] In some embodiments of the present riser component assemblies having a primary lumen, the assembly comprises: a first flange (the first flange comprising: a first mating face configured to mate with a flange of a first adjacent riser segment and a first central flange lumen in fluid communication with the primary lumen); a housing permanently coupled to the first flange, the housing having a first opening, a second opening and a central chamber in fluid communication with the primary lumen and configured to receive an annular seal about a primary geometric axis extending through the first and second openings, such that the annular seal can selectively seal an annular space in the housing around a drill string extending through the first and second openings; a second flange (the second flange comprising: a second mating face configured to mate with a flange of an adjacent second riser segment and a second central flange lumen in fluid communication with the primary lumen); and a flow diverter permanently coupled to the second flange between the housing and the second flange, the flow diverter having a collar defining a side opening in fluid communication with the primary lumen, the collar having a collar lumen in in fluid communication with the primary lumen, a main tube with a main tube lumen in fluid communication with the primary lumen and a valve in fluid communication with the lateral opening, the valve having a geometric axis of longitudinal flow that is more parallel than perpendicular to a longitudinal geometric axis extending through the first and second central flange lumens of the respective first and second flanges. Some embodiments additionally comprise: the annular seal. In some embodiments, the main tube is unitary with the collar. In some embodiments, the flow diverter and housing are permanently coupled. In some embodiments, the valve comprises a double ball valve.

[007] In some embodiments of the present riser component assemblies, the flow diverter further comprises a fitting coupled to the valve and collar over the side opening, the fitting defining a fitting lumen in fluid communication with the opening. side. Some embodiments further comprise: A first connector secured to the fitting and a first end of the valve and a second connector secured to a second end of the valve.

[008] Some embodiments of the present riser component assemblies further comprise: a first flow line with a first flow line lumen in fluid communication with the side opening, the first flow line having a first end. In some embodiments, the first lumen of the flow line has an inlet through which fluid can enter in a first direction substantially parallel to the longitudinal flow axis of the valve and an outlet through which fluid can exit in a second direction. the second direction being substantially different from the first direction. In some embodiments, the first flow line further comprises curvilinear portions configured to change the direction of fluid flow through the first flow line lumen without increasing the maximum transverse diameter of the first flow line. In some embodiments, the first flow line may include a curved portion (e.g., a gooseneck portion) that may increase the maximum transverse diameter of the first flow line. This curved portion may be removable so that it can be attached to the first flow line after the remainder of the riser component assembly passes through a roundabout. Such curved portion may include handles that provide protection against inadvertent contact with the curved portion. In some embodiments, the second connector further comprises a recess configured to receive the first end of the first flow line without threads or solder to permit fluid communication between the first lumen of the flow line and the valve. In some embodiments, the first flowline has a second end, the second end having a flowline flange configured to be coupled to a second flowline. In some embodiments, no transverse portion of either flow diverter and the first flow line extends beyond the maximum transverse dimension of the housing. In some embodiments, the housing further comprises a peripheral portion defining a first passage that is distinct from the first opening, the second opening and the central chamber and is configured to receive a first portion of the first flow line. Some embodiments further comprise: a spacer collar permanently coupled to the second flange and housing.

[009] In some embodiments of the present riser component assemblies, the first flow line is configured to be coupled to the main tube by a retainer. In some embodiments, the retainer includes a body having a passage configured to receive a first portion of the first flow line to restrict lateral movement of the first flow line relative to the main tube. In some embodiments, no transverse portion of any flow diverter, the first flow line, and the retainer extend beyond the maximum transverse dimension of the housing. In some embodiments, the maximum transverse dimension of the housing is less than 152.4 cm (60.5 inches). In some embodiments, the housing further comprises a peripheral portion defining a first passage that is distinct from the first opening, second opening, and central chamber and configured to receive a second portion of the first flow line, wherein the second portion is distinct from the first portion. .

[010] In some embodiments of the present riser component assemblies, the second flange further comprises a peripheral portion defining a first peripheral flange lumen, the first peripheral flange lumen being configured to receive a portion of a pin end. , a second flowline, the second flowline having a second flowline lumen. Some embodiments further comprise a third flange configured to mate with the second flange, the third flange having: a third mating face configured to mate with the second mating face of the second flange; a peripheral portion defining a second peripheral flange lumen, the second peripheral flange lumen configured to receive a portion of the pin end of the second flow line, wherein the pin end extends through the first and the second flange lumen peripheral; and a third central lumen of the flange configured to be in fluid communication with the primary lumen when the third flange is coupled to the second flange. In some embodiments, the pin end of the second flowline is configured to be coupled to a second end of the first flowline such that the second lumen of the flowline and the first lumen of the flowline are in fluid communication. . In some embodiments, the pin end of the second flow line is configured to be received within a recess of a housing connector on the second end of the first flow line. Some embodiments further comprise: A diverter collar permanently coupled to the third flange on a side opposite the third mating face, wherein the diverter collar defines a diverter collar lumen that has an inlet through which fluid can enter a first direction and an outlet through which fluid can exit in a second direction other than the first direction, the inlet configured to be coupled to a second end of the second flow line, wherein the second end is not the pin end.

[011] In some embodiments of the present riser component assemblies, the valve is further configured to be coupled to a choke line or a kill line, the choke line or kill line being configured to prevent the flow of fluid passing through the valve when operated.

[012] Some embodiments of the present methods comprise: lowering an embodiment of the present riser component assemblies through a rotary of a drilling rig.

[013] In some embodiments of the present methods of assembling a riser component having a primary lumen, the method comprises: permanently coupling a first flange to a housing, the first flange having a first central flange lumen in fluid communication with the primary lumen and a first mating face configured to mate with a flange of an adjacent first riser segment, and the housing has a first opening, a second opening and central chamber in fluid communication with the primary lumen ; permanently coupling a second flange to a flow diverter, the second flange having a second central flange lumen in fluid communication with the primary lumen and a second mating face configured to couple to a flange of a second pipe segment. adjacent rise and the flow diverter has a collar that defines a lateral opening in fluid communication with the primary lumen and has a collar lumen in fluid communication with the primary lumen, a main tube with a main tube lumen in fluid communication with the primary lumen and a valve in fluid communication with the lateral opening; and permanently couple the housing to the flow diverter.

[014] Some embodiments of the present methods further comprise: receiving within the central chamber an annular seal around a primary geometric axis extending through the first and second openings, so that the annular seal can selectively seal an annular space in the housing around a drill string extending through the first and second openings. In some embodiments, the valve comprises a longitudinal flow axis that is more parallel than perpendicular to a longitudinal axis that extends through the first and second central flange lumens of the respective first and second flanges. Some embodiments further comprise: coupling a fitting to the valve and collar over the side opening, the fitting defining a fitting lumen in fluid communication with the side opening. Some embodiments further comprise: attaching a first connector to the fitting and a first end of the valve and attaching a second connector to a second end of the valve that is different from the first end of the valve. Some embodiments further comprise: coupling a first end of a first flow line to the valve, the first flow line having a first flow line lumen in fluid communication with the side opening. Some embodiments further comprise: receiving the first end of the first flow line within a recess of the second connector without threads or soldering, so that there is fluid communication between the first flow line lumen and the valve. In some embodiments, no transverse portion of either flow diverter and the first flow line extends beyond the maximum transverse dimension of the housing.

[015] Some embodiments of the present methods further comprise: receiving a first portion of the first flow line within a passage of a peripheral portion of the housing, wherein the passage is distinct from the first opening, the second opening and the central chamber. Some embodiments further comprise: coupling the first flow line to the main pipe by a retainer. Some embodiments further comprise: receiving a first portion of the first flow line within a passage of a retainer body such that lateral movement of the first flow line relative to the main tube is restricted. In some embodiments, no transverse portion of any flow diverter, the first flow line, and the retainer extend beyond the maximum transverse dimension of the housing. In some embodiments, the maximum transverse dimension of the housing is less than 153.67 cm (60.5 inches). Some embodiments further comprise: receiving a second portion of the first flow line within a passage of a peripheral portion of the housing, wherein the passage is distinct from the first opening, second opening and central chamber and the second portion of the first flow line is distinct from the first portion of the first flow line. Some embodiments further comprise: permanently coupling a spacer collar to the second flange and housing.

[016] Some embodiments of the present methods further comprise: receiving a portion of a pin end of a second flow line within a first peripheral flange lumen of a peripheral portion of the second flange, the second flow line having a second flow line lumen. Some embodiments further comprise: coupling a third mating face of a third flange to the second mating face of the second flange, such that a central lumen of the third flange of the third flange is in fluid communication with the primary lumen and such that a portion of the pin end of the second flow line is received within a second peripheral flange lumen of a peripheral portion of the third flange. Some embodiments further comprise: coupling the pin end of the second flow line to a second end of the first flow line such that the second lumen of the flow line is in fluid communication with the first lumen of the flow line. Some embodiments further comprise: further comprising receiving the pin end of the second flow line within a recess of a box connector on the second end of the first flow line. Some embodiments further comprise: permanently coupling a diverter collar to the third flange on a side opposite the third mating face, the diverter collar defining a diverter collar lumen having an inlet through which fluid can enter a first direction and an outlet through which the fluid can exit in a second direction other than the first direction; and coupling the inlet of the diverter collar to a second end of the second flow line, wherein the second end is not the pin end. Some embodiments further comprise: coupling a throttling line or a scavenging line to the valve, wherein the throttling line or scavenging line is configured to impede the flow of fluid passing through the valve when actuated.

[017] The term "coupled" is defined as connected, although not necessarily directly, and not necessarily mechanically; two "coupled" items can be unitary with each other. The terms "a" and "an" are defined as one or more unless this disclosure explicitly requires otherwise. The term "substantially" is defined largely, but not necessarily entirely, as specified (and includes what is specified; e.g., substantially 90 degrees includes 90 degrees and substantially parallel includes parallel), as understood by one skilled in the art. in technique. In any disclosed embodiment, the term "substantially" may be replaced by "within [a percentage] of" specified, where the percentage includes 0.1, 1, 5 and 10 percent.

[018] Furthermore, a device or system that is "configured," in a certain way is configured at least in that way, but it can also be configured in other ways than those specifically described.

[019] The terms "understand" (and any form of understanding, such as "understands" and "understanding"), "have" (and any form of having, such as "has" and "having") and "include" (and any form of inclusion, such as "includes" and "including") are open linking verbs. As a result, an apparatus that "comprises", "possesses" or "includes" one or more elements has those or more elements, but is not limited to having only those elements. Likewise, a method that "comprises", "has" or "includes" one or more steps has those or more steps, but is not limited to having only those or more steps.

[020] Any embodiment of any of the apparatus, systems and methods may consist or essentially consist of - instead of comprising/including/possessing - any of the described steps, elements and/or features. Thus, in any of the claims, the term "consist of" or "consist essentially of" may be replaced by any of the open linking verbs cited above in order to change the scope of a given claim from what it would otherwise be. be using the open linking verb.

[021] The characteristic or characteristics of an embodiment may be applied to other embodiments, even if not described or illustrated, unless expressly prohibited by this disclosure or the nature of the embodiments.

[022] Some details associated with the modalities are described above and others are described below.

BRIEF DESCRIPTION OF THE DRAWINGS

[023] The following drawings illustrate by way of example and not limitation. For the sake of brevity and clarity, each feature of a given structure is not always labeled in every Figure in which that structure appears. Identical numerical references do not necessarily indicate an identical structure. Instead, the same numeric reference can be used to indicate a similar feature or a feature with similar functionality, as well as non-identical numeric references. The Figures are drawn to scale for at least the embodiments shown.

[024] Figure 1 depicts a perspective view of a prior art riser pipe pile, including an isolation tool and a flux coil.

[025] Figure 2A depicts a perspective view of an embodiment of the present riser component assemblies that includes an integral isolation tool and a flux coil component.

[026] Figure 2B depicts a partially exploded side view of the riser component assembly of Figure 2A.

[027] Figure 2C depicts a top view of the riser component assembly of Figure 2A.

[028] Figure 2D depicts a side view of the riser component assembly of Figure 2A being lowered through a roundabout in accordance with some embodiments of the present disclosure.

[029] Figure 2E depicts a cross-sectional view of the riser component assembly of Figure 2A.

[030] Figure 2F depicts an enlarged cross-sectional view of a portion of the riser component assembly of Figure 2A, as indicated by region 2F in Figure 2E.

[031] Figure 3A depicts a perspective view of another embodiment of the present riser component assemblies that includes an integral isolation tool and a flux coil component.

[032] Figure 3B depicts a partially exploded side view of the riser component assembly of Figure 3A.

[033] Figure 3C depicts a top view of the assembly of riser components of Figure 3A.

[034] Figure 3D depicts a side view of the riser component assembly of Figure 3A being lowered through a roundabout in accordance with some embodiments of the present disclosure.

[035] Figure 3E depicts a cross-sectional view of the assembly of riser components of Figure 3A.

[036] Figures 3F and 3G depict enlarged cross-sectional views of portions of the riser component assembly of Figure 3A, as indicated by regions 3F and 3G in Figure 3E.

[037] Figures 4A and 4B depict a side and top view, respectively, of another embodiment of the present riser component assemblies that includes an integral isolation tool and a flux coil component.

DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

[038] Now, with reference to the drawings and, more particularly, to Figures 1, shown there and designated by reference numeral 10, is a prior art riser assembly or stake that includes various riser components. As shown, the assembly 10 includes a rotary control device (RCD) body component 14, an isolation unit component 18, a flux coil component 22, and two crossover components 26 (one at each end of the assembly 10). ). The isolation unit component 18 and the flux coil component 22 are coupled together by the flange union 42. Figures 2A to 3G described below illustrate embodiments of an integral isolation tool and flux coil riser component. which do not require 42 flanges when used on a riser component assembly or stake.

[039] Figures 2A shows the integral riser component assembly 38a, which comprises a first flange 108, a housing 116, a flow coil 120 and a second flange 112. The flanges 108, 112 may include mating faces 108b, 112b, respectively, which can be configured to mate with adjacent riser segments. The flange 108 may be permanently coupled (e.g., by welding) to the housing 116, the housing 116 may be permanently coupled to the flux coil 120, and the flux coil 120 may be permanently coupled to the flange 112. As used herein, the The term "permanently coupled" means not readily removable and includes coupling by welding, but does not include coupling by removable fasteners only (e.g., bolts, nuts) or coupling by removable threading only (e.g., threading into and/or or exterior of adjacent tubulars). The assembly of integral riser components 38a may include the primary axis 104 and the primary lumen 104a, which may be in fluid communication with a lumen of adjacent riser components. The flow coil 120 may include collar 128, main tube 132, valve assemblies 134, first flow lines 152, and retainer 168, as more fully described with reference to Figures 2B, 2E, and 2F below.

[040] Figures 2B shows components of the integral riser component assembly 38a, as they may appear before the assembly at a well site. In the orientation and configuration shown, the flange 108 was welded to the upper part of the housing 116, the lower part of the housing 116 was welded to the upper part of the collar 128, the upper part of the main tube 132 was welded to the lower part of the collar 128, and the upper part of the flange 112 has been welded to the bottom of the main tube 132. An annular seal 124 can be received within a central chamber 116c of the housing 116, as shown in Figure 2E, before mating the upper and lower portions 116e, 116f, respectively, of the housing 116 together (e.g., via screws 116g). The valve assemblies 134 may include valves 136 with ports 160, fittings 140, first connectors 144, and second connectors 148. The components of the valve assemblies 134 may be permanently or removably coupled together in the configuration shown in Figure 2B as described. in more detail with reference to Figure 2E below. Fittings 140 of valve assemblies 134 may be coupled to collar 128 over side openings 120a (see Figure 2E) via, for example, screws. Retainer 168 may be coupled to main tube 132 permanently (e.g., by welding) or removable (e.g., by screwing through cuts 168c). In this configuration, the retainer 168 must be coupled to the main tube 132 so that it is completely below the lowest portion of the valve assemblies 134. The first flow lines 152 can be coupled to the valve assemblies 134 by inserting the pin ends 152d through passages 168a (see Figure 2F) of retainer 168 and in recesses 148b (see Figure 2F) of second connectors 148. Valves 136 may be connected to other types of flow lines, such as a choke line or scavenging line through ports 160. Valves 136 can control fluid flow from primary lumen 104a through first flow lines 152.

[041] As shown in Figures 2C and 2D, the integral riser component assembly 38a may have a maximum transverse diameter 116d (e.g., defined in housing 116 for the embodiment shown) that is smaller than the transverse diameter of a opening, such as opening 300 of roundabout 304, so that the assembly of integral riser components 38a can fit through a roundabout, such as roundabout 304. In particular, the maximum transverse diameter 116d can be less than 153 .67 cm (60.5 inches), which is a common diameter for a rotary on many drilling rigs (often called a 152.4 cm (60 inch) rotary). Other embodiments of the integral riser component assembly 38a may have a different maximum transverse diameter (e.g., greater than 153.67 cm (60.5 inches)).

[042] As shown in the cross-sectional view of Figure 2E, the flanges 108, 112 may include central flange lumens 108a, 112a, respectively, which may be in fluid communication with the primary lumen 104a. Housing 116 may include first opening 116a, second opening 116b, and central chamber 116c, which may be in fluid communication with primary lumen 104a. The central chamber 116c may receive annular seal 124 about the primary axis 104. The annular seal 124 may be configured to seal around the pipeline, such as a drill string, which is axially passed through the central chamber 116c about the axis. primary geometric 104.

[043] The flow coil 120 may include side openings 120a in the collar 128 that may be in fluid communication with the primary lumen 104a. The fittings 140 may each include a fitting lumen 140a and be disposed at one end over side openings 120a such that the fitting lumens 140a are in fluid communication with the side openings 120a and the primary lumen 104a. The fittings 140 may define a boss such that a portion of the fitting lumens 140a has a longitudinal flow axis that runs substantially parallel to the primary geometric axis 104. The valves 136, which may be a known type of valve, such as a double ball valve, may be coupled to the fittings 140 directly or through a connector, such as the first connector 144, such that the fitting lumens 140a are in fluid communication with the valves 136. For example, the first connectors 144 may include first connector lumens 144a that are in fluid communication with plug lumens 140a and valves 136. First connectors 144 may be permanently attached (e.g., by means of welding) or removable (e.g., by means of screws). or threading) to fittings 140 at one end and permanently (e.g., by welding) or removably coupled (e.g., by bolting or threading) to valves 136 at the other end. The valves 136 may each include a longitudinal flow axis 136a that may be substantially parallel to the primary axis 104. This configuration may advantageously reduce the transverse diameter of the flow coil 120 so that the flow coil 120 can engage through a rotary or other mechanism as shown in Figure 2D (e.g., such that the maximum transverse diameter of the flux coil 120 is less than or equal to the maximum transverse diameter 116d).

[044] The valves 136 may also be coupled (e.g., at the opposite end to the first connectors 144 and/or fittings 140) to the first flow lines 152 directly or through a connector such as the second connector 148, so that the first flowline lumens 152a are in fluid communication with valves 136. For example, the second connectors 148 may include second connector lumens 148a that are in fluid communication with both the valves 136 and the first flowline lumens 152a. The second connectors 148 may be permanently connected (e.g., by welding) or removable (e.g., by screws or threads) to the valves 136 at one end. Although the other end of the second connectors 148 may be permanently connected (e.g., by welding) or removably coupled via screws and/or threads to the first flow lines 152, the second connectors 148 may also be coupled to the first lines 152 receiving a portion of the pin ends 152d of the first flow lines 152 in the recesses 148b of the second connectors 148, as shown more clearly in Figure 2F. In this configuration, the second connectors 148 may additionally include grooves 148c sized to receive sealing and/or lubricating components (e.g., O-rings, rigid washers, grease) to facilitate insertion of a portion of the pin ends 152d into the recesses 148b. of the second connectors 148.

[045] When connected, fluid may enter the first flow line lumens 152a of valves 136 in a first direction, such as direction 152b, and exit the first flow line lumens 152a in a second direction that is different from the first. direction, such as 152c directions. The first flow lines 152 may include flange portions 152e near or at their outlet. Flange portions 152e can facilitate coupling of first flow lines 152 to second flow lines (not shown), such as auxiliary lines. The second flow lines may be attached to the first flow lines 152 after the assembly of integral riser components 38a traverses a roundabout (e.g., as shown in Figure 2D). The second flow lines may have a lumen with an inlet that can receive fluid from the first flow line lumens 152a in direction 152c. This configuration (i.e., having the first flowline lumens exit fluid 152a and enter the second flowline lumens in direction 152c) allows the second flowlines to be coupled to the first flowlines 152 without interfering with other riser segments, such as a riser segment coupled to the mating face 112b of the flange 112. This advantageous configuration can be accomplished without increasing the transverse diameter of the flow coil 120 (e.g., so that the flow coil flow 120 may have a maximum transverse diameter smaller than the maximum transverse diameter 116d) including curvilinear portions, such as curvilinear portions 152f, 152g, in first flow lines 152. For example, the curvilinear portion 152f may curve toward the main pipe 132 and the curvilinear portion 152g may curve away from the main tube 132 so that the fluid is directed in directions 152c without increasing the transverse diameter of the flow coil 120.

[046] As shown more clearly in Figure 2F, the first flow lines 152 can be attached to the main tube 132 by means of retainer 168. Retainer 168 can include passages 168a that can receive a portion of the pin ends 152d of the first flow lines 152. The pin ends 152d of the first flow lines 152 may include protrusions 152h that may engage with the recesses 168b of the retainer 168 to ensure that the first flow lines 152 are properly aligned within the passages 168a. The retainer 168 may prevent the valve assemblies 134 from moving laterally (e.g., bending) during riser operations or otherwise.

[047] Figures 3A to 3G depict another embodiment of the riser component assemblies that allows auxiliary or other lines to be connected to the flux coil portion of the assembly above the isolation tool portion of the assembly, which may be advantageous in some operations. Figures 3A shows the integral riser component assembly 38b, which comprises a first flange 208, a housing 216, a flow coil 220, a second flange 212, a spacer collar 296, a diverter collar assembly 292, and a third flange 280. Flanges 208, 212 and 280 may include mating faces 208b, 212b, 280b, respectively, which may be configured to mate with adjacent riser segments or with each other. A fourth flange (not shown) may be coupled to the diverter collar assembly 292 on the opposite side of the flange 280 and may include a mating face configured to mate with an adjacent riser segment. The bypass collar assembly 292 may be permanently coupled (e.g., by welding) to the flange 280; the mating face 280b of the flange 280 may be removably coupled (e.g., via screws) to the mating face 208b of the flange 208; the flange 208 may be permanently coupled to the spacer collar 296, the spacer collar 296 may be permanently coupled to the housing 216; housing 216 may be permanently coupled to flux coil 220; and flux coil 220 may be permanently coupled to flange 212. As used herein, the term "permanently coupled" means not readily removable and includes coupling by welding, but does not include coupling by removable fasteners alone (e.g. , screws, nuts) or coupling only by removable threading (for example, threading on the inside and/or outside of adjacent tubulars). The assembly of integral riser components 38b may include the primary axis 204 and the primary lumen 204a, which may be in fluid communication with a lumen of adjacent riser components. The flow coil 220 may include collar 228, main tube 232, valve assemblies 234, first flow lines 252, and retainer 268. The diverter collar assembly 292 may include diverter collar 292b and second flow lines 276. The components of the flow coil 220 and the bypass collar assembly 292 are described in more detail with reference to Figures 3B to 3G below.

[048] Figures 3B shows components of the integral riser component assembly 38b, as they may appear prior to assembly at a well site. In the orientation and configuration shown, the bottom of the offset collar 292b has been welded to the top top (i.e., not the mating face 280b) of the flange 280, the bottom of the flange 208 (i.e., not the mating face 208b) was welded to the top of the spacer collar 296, the bottom of the spacer collar 296 was welded to the top of the housing 216, the bottom of the housing 216 was welded to the top of the collar 228, the bottom of the collar 228 was welded to the top of the tube main 232, and the bottom of the main tube 232 has been welded to the top (i.e., not the mating face 212b) of the flange 212. An annular seal 224 can be received within the central chamber 216c of the housing 216, as shown in Figure 3E , before coupling the upper and lower portions 216e, 216f, respectively, of the housing 216 together (e.g., by means of screws). A portion of the first flow lines 252 may be displaced laterally from the primary axis 204 and may be received within the passages 216g of the housing 216 (which may be different from the screw holes), so that the maximum transverse diameter of the assembly of components of riser 38b is the maximum transverse diameter 216d, as described in more detail with reference to Figures 2C and 2D below. The spacer collar 296 may have an axial length sufficient to permit alignment of first flow lines 252 and second flow lines 276 above the housing 216.

[049] Valve assemblies 234 may include valves 236 with orifices 260, fittings 240, first connectors 244, and second connectors 248. Components of valve assemblies 234 may be permanently coupled (e.g., by welding) or removably (e.g., via screws) together in the configuration shown in Figure 3B and are described in more detail with reference to Figure 3E below. The fittings 240 of the valve assemblies 234 may be coupled to the collar 228 over the side openings 220a (see Figure 3E) by means of, for example, screws. Retainer 268 may be coupled to main tube 232 permanently (e.g., by welding) or removable (e.g., by screwing through cuts 268c). In this configuration, the retainer 268 must be coupled to the main tube 232 such that the retainer 268 is entirely above the uppermost portion of the valve assemblies 234. The first flow lines 252 may be coupled to the valve assemblies 234 by inserting the ends pin 252d from first flow lines 252 through passages 268a of retainer 268 and into recesses 248b (see Figure 2F) of second connectors 248. Valves 236 may be connected to other types of flow lines, such as a choke line or elimination line through ports 260. Valves 236 can control fluid flow from primary lumen 204a through first flow lines 252.

[050] The second flow lines 276 of the diverter collar assembly 292 may have ends permanently coupled (e.g., by welding) or removably coupled (e.g., by screws and/or threads) to the diverter collar. deviation 292b. The second flow lines may also include pin ends 276b, a portion of which may be received in the peripheral lumen of the flange 280c of the flange 280, as shown in Figure 3B. Although the second flow lines 276 may be coupled to the first flow lines 252 permanently (e.g., by welding) or removable via screws and/or threads, the second flow lines 276 may also be coupled to the first flow lines. flow 252 removably by inserting a portion of the pin ends 276b of the second flow lines 276 through the peripheral flange lumens 208c of the flange 208 (e.g., after first being inserted through the peripheral flange lumens 280c of the flange 280). and in the recesses 252b (see Figure 3G) of the ends of the box 252c of the first flow lines 252, as described in more detail by reference to Figures 3E and 3G below.

[051] As shown in Figures 3C and 3D, the integral riser component assembly 38b may have a maximum transverse diameter 216d (e.g., defined in housing 216 for the embodiment shown) that is smaller than the transverse diameter of a opening, such as opening 300 of roundabout 304, so that the assembly of integral riser components 38b can fit through a roundabout, such as roundabout 304. In particular, the maximum transverse diameter 216d can be less than 153 .67 cm (60.5 inches), which is a common diameter for a rotary on many drilling rigs (often called a 152.4 cm (60 inch) rotary). Other embodiments of the integral riser component assembly 38b may have a different maximum transverse diameter (e.g., greater than 153.67 cm (60.5 inches)).

[052] As shown in the cross-sectional view of Figure 3E, the flanges 208, 212, 280 may include central flange lumens 208a, 212a, 280a, respectively, which may be in fluid communication with the primary lumen 204a. The housing 216 may include the first opening 216a, the second opening 216b, and the central chamber 216c, which may be in fluid communication with the primary lumen 204a. The central chamber 216c may receive annular seal 224 about the primary axis 204. The annular seal 224 may be configured to seal around the pipeline, such as a drill string, which is axially run through the central chamber 216c about the axis. primary geometric 204.

[053] The flow coil 220 may include side openings 220a in the collar 228 that may be in fluid communication with the primary lumen 204a. The fittings 240 may each include a fitting lumen 240a and be disposed at one end over side openings 220a such that the fitting lumens 240a are in fluid communication with the side openings 220a and the primary lumen 204a. The fittings 240 may define a boss such that a portion of the fitting lumens 240a has a longitudinal flow axis that runs substantially parallel to the primary geometric axis 204. The valves 236, which may be a known type of valve, such as a double ball valve, may be coupled to the fittings 240 directly or through a connector, such as the first connector 244, such that the fitting lumens 240a are in fluid communication with the valves 236. For example, the first connectors 244 may include first connector lumens 244a that are in fluid communication with plug lumens 240a and valves 236. First connectors 244 may be permanently attached (e.g., by means of welding) or removable (e.g., by means of screws). or threading) to fittings 240 at one end and permanently (e.g., by welding) or removably coupled (e.g., by bolting or threading) to valves 236 at the other end. The valves 236 may each include a longitudinal flow axis 236a that may be substantially parallel to the primary axis 204. This configuration may advantageously reduce the transverse diameter of the flow coil 220 so that the flow coil 220 can engage through a rotary mechanism or other mechanism as shown in Figure 3D (e.g., such that the maximum transverse diameter of the flux coil 220 is less than or equal to the maximum transverse diameter 216d).

[054] Valves 236 may also be coupled (e.g., at the opposite end to the first connectors 244 and/or fittings 240) to the first flow lines 252 directly or through a connector such as the second connector 248, so that the first flowline lumens 252a are in fluid communication with valves 236. For example, the second connectors 248 may include second connector lumens 248a that are in fluid communication with both the valves 236 and the first flowline lumens 252a. The second connectors 248 may be permanently connected (e.g., by welding) or removable (e.g., by screws or threads) to the valves 236 at one end. Although the other end of the second connectors 248 may be permanently connected (e.g., by welding) or removably coupled via screws and/or threads to the first flow lines 252, the second connectors 248 may also be coupled to the first lines of flow 252 receiving a portion of the pin ends 252d of the first flow lines 252 in the recesses 248b of the second connectors 248, as shown more clearly in Figure 3F. In this configuration, the second connectors 248 may additionally include grooves 248c sized to receive sealing and/or lubricating components (e.g., O-rings, rigid washers, grease) to facilitate insertion of a portion of the pin ends 252d into the recesses 248b. of the second 248 connectors.

[055] When connected, fluid can enter the first flow lines 252 through the pin ends 252d of the valves 236 and exit the first flow lines 252 through the ends of the casing 252c. As shown more clearly in Figure 3G, the recesses 252b of the ends of the casing 252c may receive a portion of the pin ends 276b of the second flow lines 276, such that the first lumen flow line 252a and the second flow line of 276a lumens are in fluid communication. In this configuration, the housing ends 252c may additionally include grooves 252f sized to receive sealing and/or lubricating components (e.g., O-rings, rigid washers, grease) to facilitate insertion of a portion of the pin ends 276b of the second rows. of flow 276 into recesses 252b of the first flow lines 252. Another end of the second flow lines 276 (e.g., the spaced end of the pin end 276b may be permanently coupled (e.g., by welding) or coupled in a manner removable (e.g., via screws or thread) to the bypass collar 292b of the bypass collar assembly 292 so that the second flowline lumens 276a are in fluid communication with the bypass collar lumens 292a.

[056] When connected, fluid may enter the lumens of the bypass collar 292a from a second lumen flow line 276a in a first direction, such as direction 292c, and exit into the lumens of the bypass collar 292a in a second direction. different from the first direction, such as directions 292d. The diverter collar 292b may be coupled to third flow lines (not shown), such as an auxiliary line, by means of, for example, screws in the mating surfaces 292e (see Figure 3A). The third flow lines may be attached to the diversion collar 292b after the integral riser component assembly 38b passes through a roundabout (e.g., as shown in Figure 3D). The third flow lines may have a lumen with an inlet that may receive fluid from the diversion collar lumens 292a in direction 292d. This configuration (i.e., having the fluid exit the first fluid outlet bypass collar 292a lumens and enter the third lumen flow line in direction 292d) allows the third flow lines to be coupled to the bypass collar 292b without interfering with other riser segments, such as a riser segment coupled above the bypass collar assembly 292 in the orientation shown in Figure 3E.

[057] As shown in Figures 3E and 3F, the first flow lines 252 can be attached to the main tube 232 by means of retainer 268. The retainer 268 can include passages 268a that can receive a portion of the pin ends 252d of the first lines of flow lines 252. The pin ends 252d of the first flow lines 252 may include protrusions 252e that may engage with the recesses 268b of the retainer 268 to ensure that the first flow lines 252 are properly aligned within the passages 268a. The retainer 268 may prevent the valve assemblies 234 from moving laterally (e.g., bending) during riser operations or otherwise.

[058] Figures 4A and 4B depict another embodiment of an integral riser component assembly 38c that allows lines, such as auxiliary lines, to be connected to the assembly around the flow coil without increasing the maximum diameter of the assembly. As shown, assembly 38c includes many of the same components as previous embodiments, including a first flange 408, a housing 416, a flow coil 420, a retainer 468, and a second flange 412. These components generally operate and have the same characteristics and assembly of the previously described modalities. Housing 416 includes a plurality of passages 416g similar to passages 216g that can receive a portion (including all) of the transverse diameter of the lines, such as auxiliary lines 480, such that the lines fit within the maximum transverse diameter 416d of the housing 416 The maximum transverse diameter 416d is greater than or equal to the maximum transverse diameter of the flux coil 420, so that the assembly 38c can engage through a rotary mechanism or other mechanism, similar to that shown in Figures 2D and 3D, when the lines 452 gooseneck flow tubes are not connected. Flow lines 452 are similar to curvilinear flow lines 152 in that they can receive fluid from valves 436 in one direction, but direct flow in another direction 452c that is different from the first direction. As shown in Figure 4A, direction 452c is substantially opposite to the input direction (although other output directions are also possible). As shown in Figures 4A and 4B, flux lines 452 extend beyond the maximum transverse diameter 416d of housing 416. Accordingly, flux lines 452 may be removably coupled to flux coils 420, e.g., via connection threaded and/or screwed 484, so that they can be connected to the rest of the assembly 38c after crossing a roundabout. Handles 476 may be coupled to flow lines 452 (e.g., by welding or integrally) to facilitate this connection. Furthermore, because flow lines 452 extend beyond the maximum transverse diameter 416d of housing 416, they are at greater risk of inadvertent contact and damage to other riser components. Consequently, the handles 476 provide some protection against such contact.

[059] The specification and examples above provide a complete description of the structure and use of illustrative embodiments. Although certain embodiments have been described above with a certain degree of particularity, or with reference to one or more individual embodiments, those skilled in the art can make numerous changes to the disclosed embodiments without departing from the scope of this invention. Therefore, the various illustrative embodiments of the methods and systems are not intended to be limited to the particular forms disclosed. Rather, they include all modifications and alternatives that fall within the scope of the claims, and embodiments other than the one shown may include some or all of the features of the depicted embodiment. For example, elements may be omitted or combined as a unitary structure and/or connections may be replaced. Furthermore, where appropriate, aspects of any of the examples described above may be combined with aspects of any of the other examples described to form additional examples with comparable or different properties and/or functions, and address the same issues or problems. many different. Likewise, it will be understood that the benefits and advantages described above may be related to one modality or may be related to multiple modalities.

[060] Although the above specification refers to embodiments of the integral sets of riser components 38a and 38b, the invention should not be so limited. Permanent connection of other riser components, such as rotary control device (RCD) body components (e.g., RCD body component 14) is also contemplated.

[061] The claims are not intended to include, and should not be construed as including, limitations of means plus or steps plus functions, unless such limitation is explicitly cited in a given claim using the phrase (or phrases) "means to" or "step to", respectively.

Claims (18)

1. ASSEMBLY OF RISE PIPE COMPONENTS HAVING A PRIMARY LUMEN, the assembly characterized in that it comprises: a first flange comprising: a first mating face configured to engage a flange of an adjacent first riser pipe segment , and a first lumen of the central flange in fluid communication with the primary lumen; a housing permanently coupled to the first flange, the housing having a first opening, a second opening and a central chamber in fluid communication with the primary lumen and configured to receive an annular seal about a primary axis extending through the first and the second opening, so that the annular seal can selectively seal an annular space in the housing around a drill string extending through the first and second openings; a second flange comprising: a second mating face configured to engage a flange of a second adjacent riser segment, and a second central flange lumen in fluid communication with the primary lumen; and a flow diverter permanently coupled to the second flange between the housing and the second flange, the flow diverter having a collar defining a side opening in fluid communication with the primary lumen, the collar having a collar lumen in fluid communication with the primary lumen, a main tube having a main tube lumen in fluid communication with the primary lumen and a valve in fluid communication with the lateral opening, the valve having a longitudinal flow axis that is more parallel than perpendicular to a longitudinal axis extending through the first and second central flange lumens of the respective first and second flanges; wherein the flow diverter is permanently coupled to the housing, and the maximum transverse dimension of the flow diverter is less than or equal to the maximum transverse dimension of the housing. 2. ASSEMBLY, according to claim 1, characterized by the fact that it additionally comprises the annular seal. 3. ASSEMBLY, according to claim 1, characterized by the fact that the main tube is unitary with the collar. 4. ASSEMBLY, according to claim 1, characterized by the fact that the flow diverter additionally comprises a fitting coupled to the valve and the collar over the side opening, the fitting defining a fitting lumen in fluid communication with the side opening . 5. ASSEMBLY according to claim 1, characterized by the fact that the flow diverter further comprises a first flow line with a first flow line lumen in fluid communication with the side opening. 6. ASSEMBLY according to claim 5, characterized by the fact that the first lumen of the flow line has an inlet through which fluid can enter in a first direction substantially parallel to the longitudinal flow axis of the valve and an outlet through from which the fluid may exit in a second direction, the second direction being substantially different from the first direction. 7. ASSEMBLY according to claim 5, characterized by the fact that the housing further comprises a peripheral portion defining a first passage that is distinct from the first opening, the second opening and the central chamber and is configured to receive a first portion of the first flow line. 8. ASSEMBLY, according to claim 5, characterized by the fact that the first flow line is configured to be coupled to the main tube by a retainer. 9. ASSEMBLY, according to claim 8, characterized by the fact that the maximum transverse dimension of the housing is less than 153.67 cm (60.5 inches). 10. ASSEMBLY according to claim 5, characterized by the fact that the first flange further comprises a peripheral portion defining a first peripheral flange lumen, the first peripheral flange lumen being configured to receive a portion of a pin end, a second flowline, the second flowline having a second flowline lumen. 11. ASSEMBLY, according to claim 10, characterized by the fact that it additionally comprises a third flange configured to be coupled to the second flange, the third flange has: a third fitting face configured to engage the first fitting face of the first flange; a peripheral portion defining a second peripheral flange lumen, the second peripheral flange lumen being configured to receive a portion of the pin end of the second flow line, wherein the pin end extends through the first and second lumen of the peripheral flange; and a third central lumen of the flange configured to be in fluid communication with the primary lumen when the third flange is coupled to the second flange. 12. ASSEMBLY, according to claim 11, characterized by the fact that it additionally comprises a deviation collar permanently coupled to the third flange on a side opposite the third fitting face, wherein the deviation collar defines a deviation collar lumen that has an inlet through which fluid can enter in a first direction and an outlet through which fluid can exit in a second direction other than the first direction, the inlet configured to be coupled to a second end of the second flow line, in that the second end is not the pin end. 13. METHOD, characterized by the fact that it comprises: lowering a set of riser pipe components, as defined in claim 1, through a rotary of a drilling rig. 14. METHOD FOR MOUNTING A RISE PIPE COMPONENT WITH A PRIMARY LUMEN, the method characterized by the fact that it comprises: permanently coupling a first flange to a housing, the first flange having a first central flange lumen in fluid communication with the primary lumen and a first fitting face configured to engage a flange of an adjacent first riser segment and the housing has a first opening, a second opening and central chamber in fluid communication with the primary lumen; permanently coupling a second flange to a flow diverter, the second flange having a second central flange lumen in fluid communication with the primary lumen and a second mating face configured to engage a flange of a second riser segment adjacent and the flow diverter has a collar that defines a lateral opening in fluid communication with the primary lumen and has a collar lumen in fluid communication with the primary lumen, a main tube with a main tube lumen in fluid communication with the lumen primary and a valve in fluid communication with the lateral opening; wherein a maximum transverse dimension of the flow diverter is less than or equal to the maximum transverse dimension of the housing; and permanently couple the housing to the flow diverter. 15. METHOD according to claim 14, characterized by the fact that it further comprises receiving within the central chamber an annular seal around a primary axis extending through the first and second openings, so that the annular seal can selectively seal an annular space in the housing surrounding a drill string extending through the first and second openings. 16. METHOD according to claim 14, characterized by the fact that it further comprises coupling a first end of a first flow line of the flow diverter to the valve, the first flow line having a first flow line lumen in fluid communication with the lateral opening. 17. METHOD, according to claim 16, characterized by the fact that it further comprises coupling the first flow line to the main tube by a flow diverter retainer; and receiving a first portion of the first flow line within a passage of a retainer body such that lateral movement of the first flow line relative to the main tube is restricted. 18. METHOD, according to claim 14, characterized by the fact that it further comprises coupling a third fitting face of a third flange to the second fitting face of the second flange, so that a central lumen of the third flange of the third flange is in fluid communication with the primary lumen and such that a pin end portion of the second flow line is received within a second peripheral flange lumen of a peripheral portion of the third flange.