The invention relates generally to use of a telemetry subsystem to enable communication between plural downhole modules associated with local power sources.
To complete a well, various operations are performed downhole in a wellbore. Examples of such operations include firing perforating guns to form perforations in a surrounding formation, setting packers, actuating valves, collecting measurement data from sensors, and so forth. An issue associated with performing such operations with various downhole modules is the ability to efficiently communicate with such downhole modules.
A typical arrangement includes a surface controller that is able to control the operations of the various downhole modules using pressure pulse signals. Alternative techniques of activating downhole modules include techniques that employ hydraulic pressure activation or mechanical activation.
In general, according to an embodiment, a system for use in a wellbore includes plural modules for positioning in the wellbore and including respective interfaces and being associated with local power sources, where the plural modules are configured to perform predefined downhole tasks in the wellbore. A telemetry subsystem enables communication between at least two of the plural modules, where the communication between the at least two plural modules allows one of the two modules to affect an operation of another of the two modules.
Other or alternative features will become apparent from the following description, from the drawings, and from the claims.
In the following description, numerous details are set forth to provide an understanding of the present invention. However, it will be understood by those skilled in the art that the present invention may be practiced without these details and that numerous variations or modifications from the described embodiments are possible.
As used here, the terms “above” and “below”; “up” and “down”; “upper” and “lower”; “upwardly” and “downwardly”; and other like terms indicating relative positions above or below a given point or element are used in this description to more clearly describe some embodiments of the invention. However, when applied to equipment and methods for use in wells that are deviated or horizontal, such terms may refer to a left to right, right to left, or diagonal relationship as appropriate.
In accordance with some embodiments, interface circuits are added to downhole modules (positioned in a wellbore) to allow the downhole modules to communicate with each other, as well as with a surface controller that is located at the earth surface. A downhole module is a module that performs downhole tasks in the wellbore. The downhole modules are remotely powered—in other words, the downhole modules include or are associated with respective local power sources. One example of a local power source is a battery. A local power source differs from a power source supplied from the earth surface (such as over an electrical cable). The local power source enables an electrical downhole module to operate even though no power is supply from the earth surface to the downhole module.
Communication between the downhole modules through the interface circuits occurs through a “telemetry subsystem,” where the telemetry subsystem can include wires to interconnect the interface circuits, or alternatively, the telemetry subsystem can include components such as routers, switches, and other telemetry circuitry to enable communication between the interface circuits. The ability to communicate between downhole modules allows for one downhole module to communicate information to another downhole module (where the information can include data or commands). Communicating information between downhole modules allows the operation of one downhole module to be affected by information from another downhole module. In this manner, the surface controller does not always have to be involved in activities associated with the downhole modules. Also, one downhole module can condition its operation on another downhole module.
Thus, there are two communication regimes. The first communication regime is between the downhole modules. The second regime is to/from surface from/to the downhole modules.
As discussed further below, the telemetry subsystem 108 also communicates with various downhole modules that are part of the tool 102. The downhole modules that can communicate with the telemetry subsystem 108 include a firing head module 116, a valve module 118, and a sensor module 120. Other or alternative modules can also be part of the tool 102 in other implementations. The firing head module 116 is used to fire a perforating gun 122. The valve module 118 includes a valve that is actuatable between an open position, a closed position, and possibly an intermediate position (a partially open position). The sensor module 120 includes one or more sensors to sense various characteristics associated with the wellbore 100 and surrounding formation. As examples, the sensor module 120 can include sensors to detect temperature, pressure, a chemical property, resistivity, and so forth.
The telemetry subsystem 108 allows the various modules of the tool 102 to communicate with the surface controller 110 (or other surface equipment) through the carrier structure 104 (or using wireless communication). Also, according to some embodiments, the telemetry subsystem 108 allows the modules of the tool 102 to communicate with each other.
The downhole modules can have primary interfaces and secondary interfaces. The firing head module 116 includes a detonator 140 that when activated causes the perforating gun 122 (
At least some of the modules, including the firing head module 116 and valve module 118, can include a respective primary interface 128, 130. The primary interface allows the respective downhole module to receive commands directly from the surface controller 110 or via alternative techniques, such as pressure pulses generated using rig pumps without passing through the telemetry subsystem 108. In one example, the primary interface can be an interface that communicates with pressure pulse signals. Thus, the primary interface 128, 130 can communicate with a sequence of pressure pulses (low-level pressure pulses) that are encoded with signatures to communicate desired information (data and/or commands). One example technique that employs low-level pressure pulse communication is the IRIS technology from Schlumberger. The primary interface 128, 130 includes a pressure sensor and associated electronic circuitry to allow for detection of pressure pulse sequences having corresponding signatures.
In other implementations, the primary interface can communicate using a different mechanism.
Note that the sensor module 120 in the example depicted in
The telemetry subsystem 108 includes inter-module communication circuitry 132 to allow the downhole modules 116, 118, 120 to communicate with each other. Also, the telemetry subsystem 108 includes surface communication circuitry 134 to allow communication between the telemetry subsystem 108 and the surface controller 110 (or other surface equipment) through the carrier structure 104 (or over a wireless medium). The telemetry subsystem 108 in the example of
In one implementation, the inter-module communication circuitry 132 can include one or more routers, switches, or other telemetry circuitry to allow inter-module communications. In an alternative implementation, as depicted in
Thus, a “telemetry subsystem” can refer to a subsystem that includes routers, switches, and/or other telemetry circuitry to interconnect the downhole modules, or to wires (e.g., electrical wires or optical wires) that interconnect the secondary interface circuits of the downhole modules. Alternatively, “telemetry subsystem” can also refer to a subsystem that enables wireless communication between the secondary interface circuits 122, 124, and 126.
In operation, the ability to communicate between the downhole modules allows for the task performed by one downhole module to be affected by another downhole module. For example, the control logic 146 in the firing head module 116 can send an indication to the valve module 118 when the firing head module 116 has been activated to fire the perforating gun 122. In response to the valve module 118 receiving an indication that the firing head module 116 has been activated, the control logic 148 in the valve module 118 can actuate its valve 142 to set the valve in a predefined position (open or closed or partially open). Thus, generally, at least some of the downhole modules can include control logic to detect for a task performed by another downhole module, where the control logic can affect an operation based on the detection of an indication sent from the other downhole module.
As another example operation, a user at the surface controller 110 (or other surface equipment) can send an activate message downhole through the carrier structure 104. The telemetry subsystem 108 forwards the control message to the firing head module 116 through the secondary interface 122. Upon receipt of the control message by the firing head module 116, the control message can be validated, such as by verifying certain downhole parameters such as pressure and/or temperature. This can be accomplished by the firing head module 116 sending a request through the inter-module communication circuitry 132 to the sensor module 120 to retrieve the desired information from the sensor(s) 144 of the sensor module 120. If the control logic 146 of the firing head module 116 validates that the downhole parameters are within desired ranges, then the control logic 146 can activate the detonator 140 of the firing head module 116 to fire the perforating gun 122.
Also, the firing head module 116 can communicate some status information regarding activation of the firing head module 116 through the telemetry subsystem 108 to the surface controller 110. The firing head module 116 can also cause measured parameters collected from the sensor module 120 to be communicated through the telemetry subsystem 108 to the surface controller 110 so that the user can see the measured downhole parameters when the firing head module 116 was activated.
Note that the sensor module 120 can also include a sensor (such as a casing collar locator) to detect the depth of the tool 102. The control logic 146 of the firing head module 116 can ensure that the tool 102 is at the appropriate depth before allowing activation of the detonator 140.
While the invention has been disclosed with respect to a limited number of embodiments, those skilled in the art, having the benefit of this disclosure, will appreciate numerous modifications and variations therefrom. It is intended that the appended claims cover such modifications and variations as fall within the true spirit and scope of the invention.
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