Extendable/collapsible apparatus for fracture imaging and use of same
Abstract
Fracture imaging modules having one or more 3-component sensors, are incorporated into a tool comprising two or more of the modules for detecting microseismic events in a formation from the same wellbore as is being stimulated. The modules are locked together in a compact mode to permit injection into the wellbore through a conventional lubricator which has a fixed length. Once injected into the wellbore, the modules are spaced from one another in an extended mode to form an axially spaced sensor array which increases the measurement window in the wellbore compared to sensor arrays conventionally injected through a fixed length lubricator. Following the operation, the modules are actuated to return to the compact mode for pulling out of the hole through the lubricator.
Claims
exact text as granted — not AI-modifiedEmbodiments in which an exclusive property or privilege is claimed are defined as follows:
1 . A fracture imaging module (FIM) for detecting microseismic events when deployed in a directional wellbore, comprising:
a housing; one or more 3-component microseismic sensors housed in the housing; apparatus for connecting axially between the housing and a housing of a like module, actuable between an extended mode, wherein the modules are spaced apart for detecting the microseismic events, and a compact mode, wherein space between the modules is minimized for running into and pulling out of the wellbore; and a locking mechanism for locking the module to the like module when in the compact mode.
2 . The module of claim 1 wherein the apparatus for connecting is actuated by a pulling force applied thereto, the module further comprising:
drag means connected to the housing for engaging the wellbore and resisting movement therein when the pulling force is applied thereto.
3 . The module of claim 1 wherein the apparatus for connecting spaces the module 10's of meters apart from the like module in the extended mode than in the compact mode.
4 . The module of claim 1 wherein the apparatus for connecting spaces the module from about 50 meters to about 100 meters from the like module.
5 . The module of claim 1 further comprising electronic circuitry for actuating the locking mechanism to lock the module to adjacent like modules in the compact mode and to release the module to permit spacing of the module from the like modules in the extended mode.
6 . The module of claim 5 wherein the electronic circuitry receives a coded signal for actuating the locking mechanism, wherein the coded signal is an acoustic signal, an electronic signal, pressure pulsing or a sequence of movements of a conveyance string connected to the module.
7 . The module of claim 2 wherein the apparatus for connecting comprises a tether mechanism having
a return spring, biased to an original shape, and wound about a first sprocket;
a tether wound about a second sprocket, a free end thereof extending through a port in the housing for connection to the housing of the like module; and
an endless drive chain for connecting between the first and second sprockets, wherein
when the pulling force is applied to the tether, the tether is payed-out from the second sprocket for extending a length of the tether and the return spring is tightened about the first sprocket, the tether being placed in constant tension; and
when the pulling force is released, the return spring returns to the original shape, driving the endless chain to rotate the second sprocket for winding the tether thereon.
8 . The module of claim 1 wherein the locking mechanism comprises one or more of magnets, latches, collet fingers, a stinger or a brake applied to the apparatus for connecting between the housing and the housing of the like module.
9 . The module of claim 1 , wherein a neck end of the housing comprises a profiled neck extending axially therefrom; and an opposing latch end of the housing comprises a shaped recess therein, the locking mechanism comprising:
a latch mechanism for engaging between the shaped recess of the module and a profiled neck of a like module when engaged in the shaped recess.
10 . The module of claim 9 wherein the latch mechanism comprises:
opposing notches formed on the profiled neck; and
opposing, pivoting latch fingers connected to the housing and biased radially inward into the recess to engage the opposing notches on a like module in a latched position.
11 . The module of claim 10 further comprising electronic circuitry to overcome the biasing and cause the latch fingers to pivot to release from the opposing notches.
12 . The modules of claim 1 wherein data from the one or more 3-component microseismic sensors is stored in the module for retrieval at surface, the module further comprising:
data storage means housed in the housing; and
one or more batteries for powering the data storage.
13 . A tool for detecting microseismic events when deployed in a directional wellbore using a conveyance string, comprising:
two or more modules, each module having
a housing;
one or more 3-component microseismic sensors housed in the housing;
apparatus for connecting between the housing and a housing of each adjacent module, actuable between an extended mode, wherein the two or more modules are spaced apart for detecting the microseismic events, and a compact mode, wherein space between the two or more modules is minimized for running into and pulling out of the wellbore; and
a locking mechanism for locking the two or more modules together when in the compact mode
wherein a first, proximal module is connected to a distal end of the conveyance string and the remaining of the two or more modules are connected therebetween for forming an axial array of modules.
14 . The tool of claim 13 further comprising:
drag means connected to the modules' housings for engaging the wellbore and resisting movement therein when a pulling force is applied thereto; and
wherein the apparatus for connecting comprises a tether mechanism housed in the housing and having
a return spring, biased to an original shape, and wound about a first sprocket;
a tether wound about a second sprocket, a free end thereof extending through a port in the housing or connection to the housing of the adjacent module; and
an endless drive chain for connecting between the first and second sprockets, wherein
when the pulling force is applied to the tether, the tether is payed-out from the second sprocket for extending a length of the tether and the return spring is tightened about the first sprocket, the tether being placed in constant tension and the modules being spaced apart; and
when the pulling force is released, the return spring returns to the original shape, driving the endless chain to rotate the second sprocket for winding the tether thereon for minimizing the spacing between the modules.
15 . The tool of claim 13 wherein the first, proximal module is connected to the conveyance string using a non-acoustically transmissive connection therebetween for decoupling the tool from the conveyance string.
16 . The tool of claim 13 wherein apparatus for connecting between the two or modules spaces the modules 10 's of meters apart in the extended mode compared to the compact mode.
17 . The tool of claim 13 wherein the apparatus for connecting between the two or modules spaces the modules from about 50 meters to about 100 meters apart.
18 . A method for measuring microseismic events in a directional wellbore comprising:
connecting a tool having two or more modules therein to a distal end of a conveyance string, each module comprising one or more 3-component microseismic sensors, the modules being locked together in a compact mode; injecting the conveyance string and tool in the compact mode into the wellbore through a lubricator; signaling the tool to actuate from the compact mode to an extended mode in the wellbore, wherein the two or modules are spaced apart in an axial array; detecting the microseismic signals in the wellbore at one or more stages in the wellbore; signaling the tool to actuate from the extended mode to the compact mode; and pulling the conveyance string and the tool in the compact mode from the wellbore through the lubricator.
19 . The method of claim 18 wherein the signaling to actuate from the compact mode to the extended mode and from the extended mode to the compact mode comprises:
sending a coded signal to the two or more modules to actuate a locking mechanism therein to release the modules or to lock the modules, the coded signal being an acoustic signal, an electronic signal, pressure pulsing or a sequence of movements of the conveyance string connected to the twmodule.
20 . The method of claim 19 wherein the coded signal comprises a sequence of movements of the conveyance string, comprising:
following injecting the conveyance string and tool into the wellbore in the compact mode,
advancing the tool to approach total depth in the wellbore;
moving the conveyance string and tool a coded series of downhole incremental movements with pauses or stops therebetween for signaling a latching mechanism in the tool to unlock the two or more modules;
pulling the conveyance string and tool uphole to overcome a drag force of at least a first proximal module for spacing the first proximal module from remaining of the two or more modules;
continuing pulling the conveyance string and tool uphole, using an incrementally increasing pulling force for overcoming the drag force of the spaced modules and each of the adjacent modules for spacing therebetween to the extended mode; and
following detecting the microseismic signals in the wellbore at one or more stages in the wellbore,
moving the conveyance string and tool in a coded sequence of uphole incremental movements with pauses or stops therebetween for signaling the latching mechanism to lock the modules together;
moving the conveyance string and tool downhole for engaging the first proximal module for locking thereto; and
continuing to move the conveyance string and tool downhole for engaging each of the remaining modules for locking the two or more modules together in the compact mode for pulling out of hole through the lubricator.Cited by (0)
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