Wells – With heating – refrigerating or heat insulating means
Reexamination Certificate
1997-12-17
2001-04-17
Suchfield, George (Department: 3672)
Wells
With heating, refrigerating or heat insulating means
C166S066000, C166S241500, C166S243000, C166S381000
Reexamination Certificate
active
06216779
ABSTRACT:
BACKGROUND OF THE INVENTION
The present invention relates to the field of tools run downhole in a borehole. More particularly, the invention relates to an improved actuator for operating the tool at a selected location within the borehole. The invention is particularly useful in narrow slimholes and in wells having multiple lateral lines.
Tools are run in boreholes to perform various functions and to identify certain data relevant to subsurface geologic formations and entrained hydrocarbons. For example, logging tools are run in borehole to determine the orientation, structure and composition of the borehole and subsurface geologic formations, and to identify the presence of hydrocarbons within the geologic formations. To prevent such tools from becoming stuck within a borehole, such tools are typically run “slick” with a lubricating fluid such as a drilling mud. However, lubricating fluid reduces log quality by interfering with the detection signals generated and received by the downhole tools.
Logging tools are typically centered within a borehole with articulated arms which extend outwardly to engage the borehole wall. The arms are stored in a collapsed position as the tool is lowered into the borehole and are moved outwardly from the housing by electric motors or hydraulic mechanisms. The downhole motor operates a gearbox, mechanical drive jackscrew, and actuation shoulder to open the engagement arms. The motor is powered through a cable extending to the wellbore surface. The jackscrew is engaged with cam pivots for moving the arms outwardly from the housing. A thrust bearing prevents axial movement of the motor relative to the housing, and high pressure dynamic seals prevent fluid intrusion into the housing. Such dynamic seals are subject to failure, and the resulting fluid intrusion can damage motors and electrical connections, and can pack off internal spaces with fluid solids.
Advanced drilling techniques and new completion procedures have increased the complexity of downhole boreholes. Multilateral and horizontal completions shorten the turning radius in deviated wellbores and in the transition between connecting borehole sections. Such boreholes require compact tools which are manueverable through tight borehole turns and intersections. To navigate narrow boreholes, new tool designs must be smaller than conventional systems. However, the systems must be smaller without reducing the data acquisition and processing capabilities of the tool. Improved downhole tools should be able to carry increased instrumentation capabilities and to carry high resolution equipment.
Materials such as shape memory alloy (“SMA”) provide actuators for different applications, however SMAs are not conventionally used downhole in boreholes because of operating temperature limitations. SMAs comprise special alloys having the ability to transform from a relatively hard, austenitic phase at high temperature to a relatively flexible, martensitic phase at a lower temperature. SMAs comprise highly thermally sensitive elements which can be heated directly or indirectly to deform the SMA, and can be produced with one-way or two-way memory. An electrical current can resistively heat the SMA to a phase activation threshold temperature by the application of a small electric current through contact leads. Alloy materials providing SMA characteristics include titanium
ickel, copper/zinc/aluminum, and copper/aluminum
ickel compositions.
An SMA in a wire form has two states separated only by temperature. When cool, the SMA is in the martensitic state where the wire is relatively soft and easily deformable. When warmed above the activation temperature, the SMA wire is transformed into the austenitic state wherein the wire is stronger, stiffer and shorter than in the martensitic state. In the martensitic state, an SMA wire is deformed under a relatively low load. When heated above the activation temperature, the SMA wire remembers the original shape and tends to return to such shape. As the SMA wire is heated and contracts, internal stresses opposing the original deformation are created so that the SMA wire can perform work. SMA actuators can use SMA wire in tension as a straight wire or in torsion as a helical wire coil.
The SMA phase transition occurs at a temperature known as the activation temperature. For a titanium
ickel (TiNi) composition, activation temperatures in a range between plus one hundred degrees and minus one hundred degrees C have been demonstrated. In the lower temperature martensitic phase, the SMA is relatively soft and has a Young's modulus of 3000 Mpa. After the SMA is heated above the activation temperature, the phase transition to a relatively hard austenite phase has a Young's modulus of 6,900 Mpa. If the SMA is not overly deformed or strained, the SMA will return to the original, memorized shape. If the SMA is then cooled, the SMA mechanically deforms to the original martensitic phase. In an SMA formed as a coil spring, heating of the SMA shortens the spring, and cooling the SMA permits the SMA to return to the longer original configuration.
During the manufacture of an SMA, the SMA material is annealed at high temperature to define the structure in the parent, austenitic phase. For TiNi, the annealing temperature can be 510 degrees C. for one hour. Upon cooling, the SMA will automatically deflect away from the programmed shape to the configuration assumed by the SMA in the martensitic phase. The SMA can then be alternately heated or cooled with conductive or internal resistance heating techniques to convert the SMA between the austenitic and martensitic phase structures.
As the SMA is heated and cooled, the SMA structurally contracts up to 5% in typical cyclic applications. Contractions up to 16% have been demonstrated, however the number of useful cycles are limited. Deflection of the SMA between the austenitic and martensitic phases can be harnessed with mechanical linkages to perform work. Although 5% contraction provides a relatively small range of motion, the recovery force can provide forces in excess of 35 to 60 tons per square inch for linear contractions. The rate of mechanical deformation depends of the rate of heating and cooling. In conventional applications, the SMA can be mechanically returned by a restoring force to the configuration of the martensitic shape. This use of a restoring force impacts the geometry and size of mechanisms proposed for a particular use.
SMA materials can be formed into different shapes and configurations by physically constraining the element as the element is heated to the annealing temperature. SMA alloys are available in wire, sheet and tube forms and can be designed to function at different activation temperatures. Large SMAs require relatively high electric current to provide the necessary heating, and correspondingly large electrical conductors to provide high electric current. Efforts have been made to combine SMA elements with different mechanical devices to accomplish the desired work.
SMAs are used in medical devices, seals, eyeglasses, couplings, springs, actuators, and switches. Typically, SMA devices have a single SMA member deformable by heating and have a bias spring for returning the SMA to the original position when cooled. Other actuators termed “differential type actuators” are connected in series so that heating of one SMA deforms the other, and heating of the other SMA works against the first SMA.
U.S. Pat. No. 4,556,934 to Lemme et al. (1985) disclosed a shape memory actuator having an end fitting thickness forty percent of the original thickness. The end thickness was reduced so that less current through the end section was required to raise the end temperature above the activation temperature, and the end was cold rolled to strengthen such end against failure.
In U.S. Pat. No. 4,899,543 to Romanelli et al. (1990), a pretensioned shape memory actuator provided a clamping device for compressing an object. The actuator comprised a two-way shape memory alloy pre-tensioned to a selected position, and then pa
Baker Hughes Incorporated
Maden, Mossman & Sriram P.C.
Suchfield George
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