In sub-terrain drilling, downhole tools are often provided with various sensors to detect various downhole parameters. Sensors may be used for measuring, logging, telemetry, steering, and the like. The sensor measurement data may be processed by electronic components to evaluate the data, transmit the data, or use the measurement values for direct control. The electronic components must be able to withstand high temperatures, accelerations and other downhole environment conditions. The electronic components are typically built in the form of multi-chip module (MCM) electronics that are provided in recesses that are disposed in the downhole tool. MCM electronics are composed of dies (integrated circuits). These dies are sensitive to various gases e.g. fluorine and chlorine and therefor require a separate housing. The MCM housing is designed to protect the MCM electronics from harmful gases. A sleeve, or coverplate, generally covers the MCM housing. The sleeve, or coverplate, encapsulates the MCM housing to provide protection from hydrostatic drilling load forces and drilling mud.
A downhole tool includes a tool body having an outer surface portion and an inner surface portion and a recess formed in one of the outer surface portion and inner surface portion. At least one removable electronic component access member is detachably mounted to the tool body. The removable electronic component access member provides access to electronic components housed in the recess. A metallic seal is provided on at least one of the tool body and the removable electronic component access member. The metallic seal prevents fluid ingress into the recess through the at least one removable electronic component access member.
Referring now to the drawings wherein like elements are numbered alike in the several Figures:
A downhole tool, in accordance with an exemplary embodiment, is indicated generally at 2, in
As shown in
In accordance with an exemplary aspect, MCM housing 24 is supported in recess 12 upon inner surface 18. Specifically, outer peripheral edge 53 and cantilevered end portions 58, 59 abut inner surface 18 and support portion 45. In this manner, MCM housing 24 is capable of withstanding hydrostatic loading and protects internal electronic components. Further, MCM housing 24 provides protection for the electronic components without increasing an overall radial thickness of downhole tool 2. Once in place, outer peripheral edge 53 may be bonded to tool body 4. For example, outer peripheral edge 53 may be welded or otherwise fused to edge 13 as shown in
Reference will now follow to
In accordance with the exemplary embodiment shown, MCM housing 70 is detachably mounted within recess 12 through a first seal 91. First seal 91 takes the form of a spring loaded radial seal 92 having a generally C-shaped cross-section. Of course, it should be understood that first seal 91 may take on a variety of geometries and may or may not be spring loaded. MCM housing 70 also includes a second seal 94. Second seal 94 takes the form of a spring loaded axial seal 96 similar to that described in connection with spring loaded radial seal 92. First and second seals 91 and 94 may be metallic seals formed from stainless steel, a metal alloy, silver, copper and gold, or may possess a metallic coating, such as stainless steel, a metal alloy, silver, copper and gold. The particular type of metallic coating may vary. The metallic coating is generally chosen to be non-reactive with downhole formation materials and/or mud. It should also be understood that MCM housing 70 may include a single continuous seal that extends both axially and radially. It should be further understood that MCM housing 70 may include an integral seal. Conversely, a seal may be built into tool body 4. Once installed, MCM housing 70 may be covered by outer sleeve 30. No longer required to accommodate all hydrostatic loading, outer sleeve 30 may now having a thinner cross section.
Reference will now be made to
In further accordance with the exemplary embodiment shown, downhole tool 2 includes a strengthening element 140 that extends across MCM housing 121. Strengthening element 140 includes a first surface portion 142 and an opposing, second surface portion 143. Second surface portion 143 includes a plurality of strengthening members, one of which is shown at 145, that correspond to each of the plurality of fortifying members 130. Strengthening element 140 provides a cover for MCM housing 121 as well as provides structure that may accommodate hydrostatic loading. Once in place, strengthening element 140 may be covered by a sleeve (not shown). No longer required to accommodate all hydrostatic loading, the sleeve may now have a thinner cross section. Strengthening element 140 may be bonded, such as through welding, or sealed with a metallic seal to fortifying members 130 to protect electronic components (not shown) in electronics receiving zones 134 from exposure to outgassing.
In accordance with an aspect of the exemplary embodiment, removable electronic component access member 179 may take the form of a detachable connector 180. Detachable connector 180 may take the form of a pressure feed through 184, arranged in first connector receiving zone 172. By “detachable”, it should be understood that connector 180 may be removed from connector receiving zone 172 without the need for severing welds, or other bonds, and that detachable connector 180 may be reused following removal. For example, detachable connector 180 may be threadably engaged with connector receiving zone 170, or may employ a shaped memory alloy material that may engage connector receiving zone 170 when exposed to elevated temperatures such as found in a downhole environment, clamping and the like. Detachable connector 180 may also be readily installed into first connector receiving zone 172 without the need for welds or other permanent means of attachment. For example, detachable connector 180 may be threadably engaged with connector receiving zone 170.
Pressure feed through 184 is connected to a conduit 190 that leads to an adjacent downhole component (not shown). As best shown in
In accordance with an exemplary embodiment, body 193 includes a step section 201 and a groove 204. Groove 204 extends circumferentially about body 193 and receives an electrical contact 207. Electrical contact 207 is radially outwardly biased to provide a connection between pressure feed through 184 and tool body 4 that may establish an electrical ground or a conductive pathway for other signals. In accordance with an exemplary aspect, electrical contact 207 defines a spring contact. Pressure feed through 184 also includes a seal 210 arranged at step section 201 of body 193. Seal 210 is positioned between step section 201 and first seal land 177 to prevent gasses from entering recess 168 while allowing connector 180 to be removed from tool body 4. In accordance with an aspect of the exemplary embodiment, seal may be formed from metal such as stainless steel, a metal alloy, silver, copper and gold, or may possess a metallic coating, such as stainless steel, a metal alloy, silver, copper and gold. The metallic coating is generally chosen to be substantially non-reactive with downhole formation materials.
In accordance with an aspect of an exemplary embodiment, detachable connector 180 not only facilitates easy and repeated installation and removal but also provides access to electronic components (not shown) housed in recess 168 in tool body 114. In further accordance with an aspect of an exemplary embodiment, tool body 114 may include a removable electronic component access member 300 in the form of a removable multi-chip module (MCM) housing 310 provided in recess 168. MCM housing 310 may be secured to tool body 114 in recess 168 through a metallic seal 320.
At this point it should be understood, that the exemplary embodiments describe a removable electronic component access member that provides access to electronic components provided in a downhole device. Allowing access to the electronic components enables repair and replacement without the need to discard and replace a downhole tool. It should also be understood, that the exemplary embodiments form part of an overall downhole system 400, illustrated in
While one or more embodiments have been shown and described, modifications and substitutions may be made thereto without departing from the spirit and scope of the invention. Accordingly, it is to be understood that the present invention has been described by way of illustrations and not limitation.
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