EP3715582B1

EP3715582B1 - Diamond high temperature shear valve designed to be used in extreme thermal environments

Info

Publication number: EP3715582B1
Application number: EP20152711.6A
Authority: EP
Inventors: Thomas Kruspe; Ryan Damont GREEN
Original assignee: Baker Hughes Holdings LLC
Current assignee: Baker Hughes Holdings LLC
Priority date: 2019-03-27
Filing date: 2020-01-20
Publication date: 2023-12-13
Anticipated expiration: 2040-01-20
Also published as: EP3947908A1; WO2020198420A1; EP3947908A4; EP3715582A1

Description

BACKGROUND

Downhole operations often include a downhole string that extends from an uphole system into a formation. The uphole system may include a platform, pumps, and other systems that support resource exploration, development, and extraction. In some instances, fluids may be passed from the uphole system into the formation through the downhole string. In other instances, fluid may pass from the formation through the downhole string to the uphole system. The downhole string may include various sensors that detect downhole parameters including formation parameters and parameters associated with the downhole string.
It is desirable to communicate information from downhole sensors to the uphole system. Communication may take place through wired, optical, or acoustical systems. Acoustical systems rely upon passage of pressure pulses generated downhole to an uphole receiver. The pressure pulses are created by a mud pulser by moving a piston into a choke valve in order to create an additional temporary pressure increase at the pump system on the surface. The generated pressure pulse travels with sound speed to the surface. The uphole receiver converts the pressure pulses to data indicative of sensed parameters. The pressure pulses provide useful information to uphole operators. Therefore, advances in downhole communication systems would be well received by resource exploration and recovery companies.
During drilling, a typical mud pulser substantially continuously generates pressure pulses over long time periods, often several days. In addition, a number of wellbores are currently drilled in formations having temperatures that are above 300 °F (149 °C). A majority of currently utilized mud pulsers include oil fillings, elastomers and/or electrical high pressure connectors, all of which tend to deteriorate over time and thus are not suitable for use in high temperature environments. The disclosure herein provides pulsers that are suitable for high temperature environments while also being made without oil fillings, elastomers or electrical high pressure connectors.
US 2001/048091 A1 discloses a control valve assembly having the features of the preamble of claim 1. WO 2017/156107 A1 discloses a control valve assembly for a downhole wellbore which activates a solenoid to shift a magnetic plunger.

SUMMARY

An aspect of the present invention provides a control valve assembly for a downhole wellbore in accordance with claim 1.
Another aspect of the present invention provides a resource exploration system in accordance with claim 13.

BRIEF DESCRIPTION OF THE DRAWINGS

Referring now to the drawings wherein like elements are numbered alike in the several Figures:

FIG. 1 depicts a resource exploration system having an uphole system operatively connected to a downhole string including a pulser alternator generator (PAG) having a plunger-type control valve assembly, in accordance with an exemplary embodiment;
FIG. 2 depicts a partial cross-sectional view of the PAG of FIG. 1;
FIG. 3 depicts a partial cross-sectional view of the plunger-type control valve assembly in a first or open position; and
FIG. 4 depicts a partial cross-sectional view of the plunger-type control valve assembly in a second or closed position.

DETAILED DESCRIPTION

A resource exploration system, in accordance with an exemplary embodiment, is indicated generally at 2, in FIG. 1. Resource exploration system 2 should be understood to include well drilling operations, resource extraction and recovery, CO₂ sequestration, and the like. Resource exploration and recovery system 2 may include an uphole system 4 operatively connected to a downhole system 6. Uphole system 4 may include pumps 8 that aid in completion and/or extraction processes as well as fluid storage 10. Fluid storage 10 may contain a gravel pack fluid or slurry (not shown) that is introduced into downhole system 6.
Downhole system 6 may include a downhole string 20 that is extended into a wellbore 21 formed in formation 22. Downhole string 20 may include a number of connected downhole tools or tubulars 24. One of tubulars 24 may include a pulser alternator generator (PAG) assembly 28. PAG assembly 28 may receive signals from one or more sensors (not shown) indicating one or more of formation parameters, downhole fluid parameters, tool condition parameters and the like. PAG assembly 28 creates one or more pressure pulses that are received at uphole system 4. The one or more pressure pulses define a code that may contain information regarding data received by the sensors. In accordance with an exemplary embodiment, PAG assembly 28 creates pressure pulses by selectively stopping a flow of pressurized downhole fluid or mud as will be detailed more fully below.
In accordance with an exemplary embodiment illustrated in FIG. 2, PAG assembly 28 includes a body portion 30 having an outer surface portion 32 and an inner portion 34. An inner housing 36 is arranged within inner portion 34. Inner housing 36 includes an outer surface 38 and an inner surface 40 that defines an interior portion 42. Interior portion 42 houses an alternator assembly 46, a control valve assembly (CVA) 48, and a main valve assembly (50) having a mud flow inlet portion (not separately labeled) and a mud flow outlet portion (also not separately labeled). As will be detailed more fully below, alternator assembly 46 provides signals to CVA 48 that allow drilling mud to flow through MVA 50 and creates pressure pulses in the mud flow according to the signals. CVA 48 creates pressure pulses in the mud flow that provide downhole data from sensors (not shown) operatively coupled to alternator assembly 46 to uphole operators.
As shown in FIGS. 3 and 4, CVA 48 includes a body 60 having a first body portion 62 and a second body portion 64 joined by a sleeve member 66. Second body portion 64 may be formed from a corrosion resistant magnetic material such as a soft magnetic material e.g., Vacoflux^® 9CR from Vacuumschmelze GmbH and Co. Magnetic and soft-magnetic materials are defined as having a magnetic permeability µ greater than about 1.26 * 10^-4 N/A² (ferromagnetic or ferrimagnetic material). First body portion 62 includes a mud flow or fluid passage 70 having a first passage portion 72 and a second passage portion 74. At this point, it should be understood that the term magnetic material comprises any suitable material that may form part of a magnetic circuit including soft magnetic material.
First passage portion 72 defines a mud flow inlet 76 that receives a flow of mud from MVA 50 and second passage portion 74 defines a mud flow outlet 78. The number and location of second passage portions may vary. Correspondingly, the number and location of mud flow outlets may vary. First body portion 62 also includes a central passage 82 having an increased diameter portion 84 that defines a mud flow outlet chamber 86. A mud flow or fluid sleeve 90 is arranged in central passage 82. Mud flow sleeve 90 includes an outer surface (not separately labeled)and an inner surface 93 that defines a channel 95. Mud flow sleeve 90 includes, a plunger fluid inlet (not separately labeled) and a third passage portion 100 and a fourth passage portion 101, third and fourth passage portions 100 and 101 may take the form of a first plunger fluid outlet and second plunger fluid outlet respectively. Third and fourth passage portion 100 and 101 fluidically connect first passage portion 72 with second passage portion 74. The number and location of passage portions extending through mud flow sleeve 90 may vary.
Second body portion 64 may also be formed from soft magnetic material and includes a solenoid support 108 having an axial end 110. A solenoid carrier 114 is supported on solenoid support 108. Solenoid carrier 114 may be formed from high-strength, non-magnetic material such as Inconel and provides support for a solenoid 120. Solenoid 120 is operatively connected to alternator assembly 46 through a conductor (not shown) extending through a conductor passage 124 formed in second body portion 64. A housing 128, which may take the form of a pressure sleeve, is mounted in second body portion 64 about solenoid 120. Housing 128 is formed from soft magnetic material and provides protection to solenoid 120 from downhole fluids passing through CVA 48 as well as from the high downhole pressure.
Housing 128 may be made from a magnetic material that is also corrosion resistant. In the embodiment of control valve 48, the solenoid 120 may be placed in a sealed and clean 1-bar environment. In the embodiment of the device 48 in FIG. 3 and 4, plunger assembly 160 moves when the solenoid in the control valve 48 is energized. The plunger assembly also referred to as a plunger. While moving plunger assembly 160 slides in an environment that is flooded with fluid (mud). The presence of mud allows plunger assembly 160 to slide back and forth with relative low friction.
Sleeve member 66 includes a first end section 134 and a second end section 135. First end section 134 may include a plurality of threads 137 that engage first body portion 62. Second end section 135 may be mechanically linked to second body portion 64 through, for example, a press fit, a threaded connection, or a joining process such as welding. Sleeve member 66 includes an annular flange 140 extending radially inwardly from an inner surface (not separately labeled). Annular flange 140 together with housing 128 may define a plunger support 144. Sleeve member 66 may be formed from a high strength, non-magnetic material, such as steel or Inconel so as to withstand downhole fluids. Of course, it should be understood, that the particular materials employed for solenoid carrier 114, and sleeve member 66 may vary depending on desired operating parameters and downhole conditions.
In accordance with an aspect of an exemplary embodiment, CVA 48 includes a plunger assembly 160, also referred to as a plunger, including a valve portion 162 and an actuator shaft 164, also referred to as a drive portion of the plunger. Valve portion 162 is operatively connected with actuator shaft 164. Actuator shaft 164 may be formed from soft magnetic material. Valve portion 162 may be formed from hard abrasion resistant material such as Tungsten Carbide and may be provided with a diamond coating of may employ other processes to form a hardened outer surface. The use of hard abrasion resistant material allows valve portion 162 to withstand high pressure corrosive and abrasive downhole mud passing from MVA 50 at high downhole temperatures as will be discussed more fully below. Valve portion 162 includes a central chamber 167 fluidically connected with first passage portion 72. A fifth passage portion 169 and a sixth passage portion 170 extend through valve portion 162. A spring 174 biases plunger assembly 160 in a first position as shown in FIG. 3, wherein fifth and sixth passage portions 169 and 170 register with third and fourth passage portions 100 and 101 (control valve open position). Solenoid 120 is selectively activated to shift plunger assembly 160 to a second position (FIG. 4) wherein fifth and sixth passage portions 169 and 170 are offset from third and fourth passage portions 100 and 101 (control valve closed position). CVA 48 may also include a washout passage 180 that provides passage for particles to be guided out from a back side (not separately labeled) of actuator shaft 164. Plunger support 144 may be either incorporated into or abutting on housing 128. Plunger support 144 is formed from a magnetic material, e.g. a soft magnetic material, and is part of the magnetic circuit. Plunger support 144 slidingly supports plunger assembly 160 by slidingly supporting actuator shaft 164.
In accordance with an aspect of an exemplary embodiment, third and fourth passage portions 100, 101 and fifth and sixth passage portions 169,170 may extend at an angle of between about 20° and about 80° relative to a longitudinal axis (not separately labeled) of CVA 48. In accordance with another aspect, third and fourth passage portions 100, 101 and fifth and sixth passage portions 169,170 may extend at an angle of about 60° relative to the longitudinal axis. In this manner, shifting plunger assembly 160 between the first position and the second position shears mud flow passing from first passage portion 72 through valve portion 162 into mud flow outlet chamber 86. Further, with this arrangement, the amount of force necessary to shift plunger assembly 160 is reduced over that which would be needed if third, fourth, fifth and sixth passage portions 100, 101, 169, and 170 projected substantially perpendicularly relative to the longitudinal axis.
Further, second passage portion 74 may extend at an angle of between about 20° and about 80° relative to a longitudinal axis (not separately labeled) of CVA 48. In accordance with another aspect, second passage portion 74 may extend at an angle of about 60° relative to the longitudinal axis. The angle of second passage portion 74 reduces impact forces associated with pulses of mud passing from mud flow outlet 78 onto inner surface 40 may be reduced over those which would be realized if mud flow outlet 78 extended perpendicularly to the longitudinal axis.
In accordance with an aspect of an exemplary embodiment, alternator assembly 46 provides signals to selectively activate, e.g., energize through an application of electric energy, solenoid 120 creating a magnetic flux 200 in a magnetic circuit (not separately labeled) that flows through second body portion 64, actuator shaft 164, plunger supports 144, and housing 128. The magnetic circuit includes a gap 171 between actuator shaft 164 and axial end 110 of solenoid support 108. At this point, it should be understood that the term "magnetic circuit" defines a pathway of material within CVA 48 through which magnetic flux 200 will flow. Activating solenoid 120 causes a magnetic field (not separately labeled) across the gap 171. The magnetic field creates a magnetic force that acts across gap 171 causing plunger assembly 160 to move toward second body portion 64. More specifically actuator shaft 164 moves toward solenoid support 108 thereby shifting plunger assembly 160 from the first position (FIG. 3) to the second position (FIG. 4). Plunger assembly 160 moves along a longitudinal axis of the body towards solenoid support 108 narrowing gap 171. Gap 171 need not fully close in order to close the control valve.
Solenoid 120 may then be de-activated opening (interrupting) the magnetic circuit cutting off magnetic flux 200 allowing spring 174 to bias plunger assembly 160 back to the first position, opening the control valve. In the first position the width of gap 171 is larger than the width of gap 171 in the second position. The first position is also referred to as a gap open position, the second position is also referred to as a gap closed position. The gap closed position does not require that the gap to be fully closed.. In the first position, mud may flow from MVA 50, through plunger assembly 160, into mud flow outlet chamber 86 and be expelled from mud flow outlets 78. When CVA 48 is operated rapidly, MVA 50 creates mud pulses that travel through downhole string 20. An uphole receiver captures pressure waves created by the pulses of mud. The pressure pulses are presented in a pattern dictated by signals received from one or more sensors at alternator assembly 46. The pressure pulses may be decrypted to provide data regarding one or more downhole parameters to uphole operators.
Splitting the plunger assembly into at least two parts allows separating the valve portion from the magnetic circuit. Therefore, the valve portion 162 does not need to be made from magnetic material. The valve portion may be made from a material that is much better suited to withstand harsh downhole conditions, like high temperatures and corrosive and abrasive downhole fluids. The material of the valve portion of the plunger assembly may be high strength non-magnetic material, such as hardened steel, diamond, tungsten carbide, carbon nitride, or boron nitride or alternative hard and/or less corrosive material. The valve portion may as well be coated by a hard material, such a diamond coating.
The teachings of the present disclosure may be used in a variety of well operations. These operations may involve using one or more treatment agents to treat a formation, the fluids resident in a formation, a wellbore, and/or equipment in the wellbore, such as production tubing. The treatment agents may be in the form of liquids, gases, solids, semi-solids, and mixtures thereof. Illustrative treatment agents include, but are not limited to, fracturing fluids, acids, steam, water, brine, anticorrosion agents, cement, permeability modifiers, drilling muds, emulsifiers, demulsifiers, tracers, flow improvers etc.
The term "about" is intended to include the degree of error associated with measurement of the particular quantity based upon the equipment available at the time of filing the application. For example, "about" can include a range of ± 8% or 5%, or 2% of a given value.
While one or more embodiments have been shown and described, modifications and substitutions may be made thereto without departing from the scope of the claims. Accordingly, it is to be understood that the present invention has been described by way of illustrations and not limitation.

Claims

A control valve assembly (48) for a downhole wellbore (21) comprising:
a body (60) including a first fluid passage (72) defining a fluid inlet (76) and a second fluid passage (100, 101) defining a fluid outlet (78), wherein a portion of the body (60) is formed from a magnetic material;

a plunger (160) moveably mounted within the body (60), the plunger (160) including a third fluid passage including a plunger fluid inlet and a plunger fluid outlet (169, 170), the plunger fluid outlet (169, 170) configured to selectively align and misalign with the second fluid passage (100, 101), wherein a portion of the plunger (160) is formed from a magnetic material;

a magnetic circuit having a gap (171) arranged within the control valve assembly (48), wherein the portion of the body (60) formed from a magnetic material defines a first portion of the magnetic circuit and the portion of the plunger (160) formed from a magnetic material forms another portion of the magnetic circuit;

a solenoid (120) mounted at the body (60) about at least a part of the magnetic material in at least one of the body (60) and the plunger (160), the solenoid (120) being selectively activated to create a magnetic field across the gap (171) in the magnetic circuit, the magnetic field causing the plunger (160) to move thereby narrowing the gap (171) to produce a pressure pulse in the wellbore (21); and

a housing (128) extending about the solenoid (120),
characterized in that:
the housing (128) is formed from soft magnetic material.
The control valve assembly according to claim 1, wherein the body (60) includes a first body portion (62) mechanically linked to a second body portion (64) by a sleeve member (66), the first body portion (62) including a central passage (82) receptive of the plunger (160).
The control valve assembly according to claim 2, further comprising a fluid sleeve (90) arranged in the central passage (82), the third fluid passage being formed in the fluid sleeve (90).
The control valve assembly according to claim 2 or 3, wherein the first body portion (62) includes a fourth fluid passage (74) fluidically connected to the second fluid passage (100, 101).
The control valve assembly according to claim 2, 3 or 4, wherein the central passage (82) includes an increased diameter portion (84) defining a fluid outlet chamber (86) fluidically connected to the second fluid passage (74).
The control valve assembly according to any of claims 2 to 5, wherein the second body portion (64) includes a solenoid support (108) and a solenoid carrier (114) mounted to the solenoid support (108), the solenoid (120) being carried by the solenoid carrier (114).
The control valve assembly according to claim 6, wherein the plunger (160) includes an actuator shaft (164) formed from soft magnetic material, the actuator shaft (164) being movable towards the solenoid support (108) when the solenoid (120) is activated.
The control valve assembly according to claim 7, further comprising a spring acting upon the plunger (160) arranged between the actuator shaft (164) and the solenoid support (108).
The control valve assembly according to claim 7 or 8, further comprising a plunger support (144) slidingly supporting the actuator shaft (164), the plunger support (144) being formed from a magnetic material and part of the magnetic circuit.
The control valve assembly according to claim 9, wherein the plunger support (144) is either incorporated into or abutting the housing (128).
The control valve assembly according to any preceding claim, wherein the portion of the plunger (160) is formed from soft magnetic material.
The control valve assembly according to any preceding claim, wherein the second fluid passage (100, 101) includes at least two second fluid passages (100, 101) and the third fluid passage includes at least two plunger fluid outlets (169, 170).
A resource exploration system (2) comprising:
an uphole system (4); and

a downhole system (6) including a downhole tool (24) in a wellbore (21) operatively connected to the uphole system (4), the downhole tool (24) including a pulser (28) having the control valve assembly (48) of any preceding claim.