The present invention relates generally to down hole remotely operated oil well wireline tools and, more specifically, to a down hole wireline tool release mechanism.
The ever increasing use of fossil fuels has led to the development of drilling technologies that were unimaginable in the recent past. For instance, the ability to drill a well to a desired depth and then steer the well, with respect to the drilling platform, from a vertical direction to a horizontal direction is now a common practice. The direction of a well can be changed based on factors such as the geological strata or a recovery design plan for optimizing the output from the well.
The multidirectional drilling capabilities described above have introduced a new series of problems related to determining the operational parameters of the well. For example, a common task in the startup and operation of a well is to deploy one or more wireline tools down a well to collect data. The wireline tools can measure well parameters, employ cameras for optical observation or even perform radioactive irradiations to evaluate the localized geological strata. The key difference is in a well with a straight vertical direction and a well with an orientation that shifts from a vertical direction to a horizontal direction and possibly upwards towards the surface.
As is easily imagined, retrieving a series of wireline tools from a well with changing direction of bore is more difficult than retrieving the same series of wireline tools from a straight vertical well. For example, the force of gravity combined with the bend of a turn in the well can cause a string of wireline tools to become stuck. This problem can occur either because one of the tools is physically stuck in a bend in the well or the force required to pull the series of wireline tools through the bend is greater than the tensile strength of the wire attached to the wireline tools.
In another example, when perforating charges are detonated the perforation canister can deform during the explosion and become lodged in the well bore. As described above, the force required to retrieve the deformed perforation canister can exceed the tensile strength of the wire attached to the wireline tools.
Under the above described circumstances, a system and associated methods are desired allowing the release of the wireline tools above the obstruction without disrupting the ability of the remaining wireline tools to continue performing their intended tasks as the tool string is removed from the well. Additionally, the ability to reconnect wireline tools without requiring replacement of all components retrieved from the well is desirable because the additional benefit of the ability to test a string of wireline tools before insertion into the well becomes possible.
Systems and methods according to the present invention address these needs by providing a multifunction down well release tool mechanism with a lost motion design and a flooding valve for disconnecting upper sections of the wireline tool string from lower sections of the tool string lodged in the well. After disconnection, the remainder of the wireline tool string, still attached to the wire, continues to function as the shortened string is removed from the well. The design also provides a nondestructive detachment allowing the wireline tool string to be reconnected with the remainder of the tool string removed from the well or to new elements of a tool string without replacing the elements of the tool string above the disconnect point.
According to an exemplary embodiment, a linear motion motor-driven reciprocating shaft actuates all aspects of the release process. These aspects include but are not limited to releasing the latching clamps, disconnecting the electrical connections passed to the subsequent tools in the string and actuating the flooding valve for pressure equalization of the release chamber.
According to another exemplary embodiment, a motor-driven rotating motion shaft rotates a cam mechanism that similarly actuates all aspects of the release process. As described above for the linear motion process, these aspects include but are not limited to releasing the latching clamps, disconnecting the electrical connections passed to the subsequent tools in the string and actuating the flooding valve for pressure equalization of the release chamber.
In various embodiments, the lost motion included in the actuation stroke protects the drive train from large pressure forces exerted by the well fluid when the tool is released. Accordingly, the design is robust and durable allowing for the reconnection of either new tools or disconnected tools recovered from the well.
The accompanying drawings illustrate exemplary embodiments, wherein:
The following detailed description of the exemplary embodiments refers to the accompanying drawings. The same reference numbers in different drawings identify the same or similar elements. Also, the following detailed description does not limit the invention. Instead, the scope of the invention is defined by the appended claims.
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In general, a release mechanism is comprised of a motor/gearbox assembly 102, a drive train chamber 104 and its associated components, a release chamber 106 and its associated components, a flooding valve 120 separating the release chamber 106 from the outside well fluid, a sealed bulkhead 126 separating the drive train chamber 104 and the release chamber 106, and a reciprocating shaft 108. The reciprocating shaft 108 is functionally connected to the motor/gearbox assembly 102 through the leadscrew 110 and leadscrew nut 112 assemblies and simultaneously actuates, according to this exemplary embodiment, the electrical spring contact 116, the latching dogs 124 and the flooding valve 120.
The drive train chamber 104 houses the leadscrew 110 and the leadscrew nut 112 in an open area of lost motion 114 of the reciprocating shaft 108. The lost motion area 114 allows the reciprocating shaft 108 to strike the end of the drivetrain chamber 104 closest to the motor/gearbox 102 when the flooding valve 120 opens and the reciprocating shaft 108 is subjected to the full pressure of the well fluid. This protects the leadscrew 110 and the motor/gearbox 102 from damage.
In another aspect, the end of the drive train chamber 104 adjacent to the flooding valve 120 provides a conductive ring 118 around the perimeter of the drive train chamber 104. The conductive ring 118 provides power and data communications conductivity to the reciprocating shaft 108 for connection to additional wireline tools and release mechanisms 100 further along the wireline tool string. When the release mechanism is in the connected position, an electrical spring contact 116 engages with the conductive ring 118 providing a circuit for power and data communications connectivity. The electrical spring contact 116 is connected to the reciprocating shaft 108 and disconnects from the conductive ring 118 as the reciprocating shaft 108 begins to move towards the motor/gearbox 102.
A further aspect provides for a sealed bulkhead 126 that prevents well fluid from entering the drivetrain chamber 104 when the release mechanism 100 opens the flooding valve 120 and allows well fluid into the release chamber 106. Similarly, seals at the release end of the reciprocating shaft 108 located around the sealed electrical connector 128, prevent well fluid from entering the reciprocating shaft 108.
The release chamber 106 houses the fishing neck 122 and the latching dog 124 mechanism for retaining the fishing neck 122 in the release chamber 106 during connected operation. Only one latching dog 124 is shown in the section view of
The seals on the flooding valve 120 at the end closest to the drive train chamber 104 remain engaged to ensure that the flooding valve 120 is driven by well pressure into the fully open position, therefore accelerating the flooding process and also protecting the more delicate actuating components from damage.
In another aspect of release mechanism 100, an electric motor 102 rotates a leadscrew 110 through a high ratio gearbox 102. The leadscrew 110 drives a leadscrew nut 112 either up or down the axis of the reciprocating shaft 108. When the leadscrew nut 112 is driven away from the motor/gearbox 102 to the end of travel, the wireline tool attached to the fishing neck 122 is connected. When the leadscrew nut 112 is driven towards the motor/gearbox 102 to the end of travel, the wireline tool attached to the fishing neck 122 is released. Of course those skilled in the art will recognize that according to other, alternative exemplary embodiments it may be possible to reverse the relationship between the direction in which the leadscrew nut 112 is driven and the connected/released mode of the fishing neck 122.
The leadscrew nut 112 is captive within a contained area of the reciprocating shaft 108 but is not held rigidly according to this exemplary embodiment. The release mechanism design 100 includes free space on either side of the leadscrew nut 112 producing lost motion 114 or backlash in the actuating stroke. The reciprocating shaft 108 passes through a sealed bulkhead 126, which defines two different chambers within the release mechanism 100. The drive train chamber 104, on the motor/gearbox 102 side of the sealed bulkhead 126 is never entered by well fluid. The release chamber 106, on the other side of the sealed bulkhead 126 from the drive train chamber 104 becomes flooded with well fluid when a wireline tool disconnect is performed.
In the drive train chamber 104, the reciprocating shaft 108 is held within an insulated housing fitted with a conductive ring 118 at the end near the sealed bulkhead 126. When the reciprocating shaft 108 is in the connected position, the reciprocating shaft 108 is aligned such that an electrical spring contact 116 is in conductive contact with the conductive ring 118. This allows electrical power and data communications through the center of the reciprocating shaft 108 to the wireline tool attached to the fishing neck 122. When the reciprocating shaft 108 begins to move to the released position, the electrical spring contact 116 is pulled away from the conductive ring 118, thereby breaking the electrical and data communication connection to the exposed end of the reciprocating shaft 108 and the wireline tools connected to the fishing neck 122. This allows tools located above the release tool to continue operating after a tool disconnect is perform.
In the release chamber 106, the reciprocating shaft 108 passes through the center of a flooding valve 120 then enters through the top of a fishing neck 122 subassembly. At the other end of the fishing neck 122 subassembly are three latching dogs 124. The latching dogs 124 are used to hold the fishing neck 122 subassembly in the release chamber 106. The latching dogs 124 are driven into the latched position by the conical dog actuator 130 attached to the reciprocating shaft 108. When the reciprocating shaft 108 is in the connected position, the cone of the conical dog actuator 130 pushes outwards on the inside faces of the latching dogs 124, holding them locked into the release chamber 106 housing. As the reciprocating shaft 108 is moved to the released position, the conical dog actuator 130 is pulled out from under the inside faces of the latching dogs 124, allowing them to drop out of the locking sleeve in the release chamber 106 and releasing the fishing neck 122 subassembly from the release chamber 106.
In another aspect, loosely positioned around the reciprocating shaft 108 between the flooding valve 120 and the conical dog actuator 130 is the flooding valve actuating cylinder 132. As the reciprocating shaft 108 moves to the released position, the flooding valve actuating cylinder 132 becomes trapped between the conical dog actuator 130 and the flooding valve 120 and pushes the flooding valve towards the sealed bulkhead 126. Once the seal on the flooding valve 120 exits the seal bores in the release chamber 106 wall, well fluid is allowed to enter the release chamber 106. The flooding valve 120 also has lost motion on either side, allowing it to move rapidly to the flooding position as well fluid begins to enter the release chamber 106.
In another embodiment, the fishing neck 122 subassembly with its associated wireline tools is reconnected to the to the release mechanism 100 by manually pushing the fishing neck 122 subassembly into the release chamber 106. The motor/gearbox 102 is then run in the reverse direction from a disconnect operation. The leadscrew nut 112 first takes up the lost motion in the opposite direction. After the lost motion is recovered, the reciprocating shaft 108 is then pushed in the direction of the release chamber 106. The lost motion of the flooding valve 120 is now recovered and the flooding valve 120 is pushed to the closed position. As the reciprocating shaft 108 reaches the end of travel, the flooding valve 120 has completely closed, the conical dog actuator 130 forces the latching dogs 124 back into the locking sleeve in the release chamber 106 and the electrical spring contact 116 engages with the conductive ring 118 restoring power and data communications to wireline tools further along the wireline tool string. Although both the reciprocating shaft 108 and the flooding valve 120 experience lost motion while moving, both are driven to hard stops when in the connected position. This hard stop lockup prevents either from moving accidentally under the effects of shock or vibration.
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At step 704, all lost motion is recovered and the reciprocating shaft 108 begins to retract towards the uphole end of the release mechanism 100. The initial reciprocating shaft 108 retraction simultaneously disconnects power and data connectivity through the release chamber 106 by separating the electrical spring contact 116 from the conductive ring 118 and disengages the latching dogs 124 by moving the conical dog actuator 130 towards the uphole end of the release mechanism 100. After the power is disconnected and the latching dogs 124 are released, the method proceeds to step 706.
Continuing at step 706, the reciprocating shaft 108 continues retracting and opens the flooding valve 120 allowing well fluid into the release chamber 106. As the high pressure well fluid enters the release chamber 106 the method proceeds to step 708 and the reciprocating shaft 108 and the flooding valve 120 are forced to the protective hard stop at the uphole end of the drivetrain chamber 104. The flooding valve 120 is now fully open and the entering well fluid has equalized the pressure on the inside and outside of the release chamber 106. Finally, at step 710, the release mechanism 100 can be pulled from the fishing neck 602 subassembly allowing removal of the remaining functional wireline tools and providing access to the fishing neck 602 subassembly for attachment of a cable suitable to pull the disconnected wireline tools from the well hole.
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Continuing to step 806, the reciprocating shaft begins extending towards the downhole end of the release mechanism 100 and drives the flooding valve to the fully closed position. Next at step 808, further extending the reciprocating shaft towards the downhole end of the release mechanism engages the latching dogs 124 into the fishing neck 602 subassembly and forces the electrical spring contact 116 against the conductive ring 118. This step results in a mechanical lockup of the fishing neck 602 subassembly and the release mechanism and provides electrical and data connectivity to the wireline tools connected to the fishing neck 602 subassembly. The wireline tool string is now prepared for insertion into the well hole.
The above-described exemplary embodiments are intended to be illustrative in all respects, rather than restrictive, of the present invention. Thus the present invention is capable of many variations in detailed implementation that can be derived from the description contained herein by a person skilled in the art. All such variations and modifications are considered to be within the scope and spirit of the present invention as defined by the following claims. No element, act, or instruction used in the description of the present application should be construed as critical or essential to the invention unless explicitly described as such. Also, as used herein, the article “a” is intended to include one or more items.
Number | Name | Date | Kind |
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3045081 | Hanes | Jul 1962 | A |
Number | Date | Country | |
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20120132439 A1 | May 2012 | US |