This application is the National Stage of, and therefore claims the benefit of, International Application No. PCT/US2014/033222 filed on Apr. 7, 2014, entitled “IN-LINE RECEIVER AND TRANSMITTER FOR DOWNHOLE ACOUSTIC TELEMETRY,” which was published in English under International Publication Number WO 2015/156769 on Oct. 15, 2015. The above application is commonly assigned with this National Stage application and is incorporated herein by reference in its entirety.
The present disclosure relates to in-well acoustic telemetry systems for communications in subterranean well systems.
In-well type acoustic telemetry systems have difficulty transmitting adequate acoustic output, for example, when applied external pressure on a housing of the in-well type acoustic telemetry system can alter system response. There is a need to remove external factors that can alter acoustic transmission and reception in in-well type acoustic telemetry systems.
Like reference symbols in the various drawings indicate like elements.
The well system 10 is also shown having a well telemetry system for sending and receiving telemetric communication signals encoded as acoustic vibrations carried on the well string 22 as vibrations in the materials of the well string 22 components. The well telemetry system includes in-well type telemetry elements 26 (three shown, but can include one, two, or four or more) and a surface telemetry station 28. In some instances, the well telemetry system is communicably coupled or otherwise associated with the well tool 24 to encode communications from the well tool 24 and decode communications to the well tool 24. The well tool 24 includes a sensor or sensors (e.g., LWD sensor, pressure sensor, accelerometer, rotational sensor, etc.) that generates an electrical signal that is received by a controller of the telemetry element 26, encoded (e.g., via pulse width modulator), and transformed into an acoustic signal. Communication to the well tool 24 is received at the in-well telemetry element 26, transformed to electrical signal, decoded by the controller of the telemetry element 26, and communicated to the well tool 24. Additional in-well type telemetry elements (not shown) can be provided for communication with other well tools, sensors and/or other components in the wellbore 12. The well telemetry system is acoustically coupled to the remainder of the well string 22 so that acoustic vibrations produced by the telemetry elements 26 go into the well string 22 and acoustic vibrations of the well string 22 are received by the telemetry elements 26. Although shown on the well string 22 and well tool 24, the well telemetry elements 26 of the telemetry system can be additionally or alternatively provided on other components in the well, including the casing 20. The in-well type telemetry elements 26 can communicate with each other and with the surface telemetry station 28 outside of the wellbore 12. For example, an uppermost well telemetry element 26 is electrically coupled to the surface telemetry station 28 via a wired connection 30 or wireless connection. The surface telemetry station 28 collects transmission signals from the well telemetry element(s) 26, and provides an interface for a user or computer to communicate with the well telemetry system. One example well telemetry system that the concepts herein can be applied to is the DynaLink® system, produced by and a registered trademark of Halliburton Energy Services, Inc.
In the example shown in
The transmitter 102 is shown in
In some instances, the transmitter 102 is in acoustic series with the receiver 104. For example, the transmitter 102 and the receiver 104 can be a laminated stack of piezoceramic wafers or other electrically responsive material, where a first portion of the wafers in the laminated stack make up the transmitter 102 and a second portion of the wafers in the laminated stack make up the receiver 104. The receiver 104 includes about ten percent of the wafers in the laminated stack, and the transmitter 102 includes a remainder of the wafers in the laminated stack. In some instances, the receiver 104 includes a different percentage of the wafers in the laminated stack. In certain instances, the transmitter 102 and the receiver 104 are separated by a spacer 108, such that the transmitter 102 is electrically isolated from the receiver 104. For example, the spacer 108 can include insulation, an open space, or a different electrically isolating material.
In certain instances, the transmitter 102 and receiver 104 are configured as a unitary transceiver. The transmitter 102 and the receiver 104 can include the same material, have the same orientation, stack adjacently, be linearly and/or axially aligned, and/or be configured in another way that allows reception and transmission of acoustic signal with the unitary transceiver. In some instances, the unitary transceiver includes the transmitter 102 and the receiver 104 configured in mechanical series and acoustic series to form a single part, such that the single part of the transceiver allows for individual or simultaneous reception and transmission of acoustic signal. The transmitter 102 and the receiver 104 are affixed or formed together to form the single part of the transceiver. In other instances, the unitary transceiver is a single stack of electrically responsive material that is alternately used for transmitting and receiving acoustic signal. For example, the single stack of the transceiver is used for a first time interval as a receiver, and the single stack of the transceiver is used for a second, different time interval as a transmitter.
The example in-well type acoustic element 100 of
The spring 110 presses against a portion of the receiver cap 112, and the receiver cap 112 presses against the receiver 104 and/or transmitter 102 to bias the transmitter 102 into acoustic coupling to a portion of the housing 106 (described below). The housing nut 114 clamps the spring 110 against the receiver cap 112 such that the spring 110 is under compression and tends to want to expand, thus biasing the transmitter 102 against the housing 106. The spring 110 is (substantially or directly) in line with the transmitter axis B-B of the transmitter 102, such that the spring 110 allows the receiver cap 112 to follow the fluctuations of the transmitter 102 while keeping the transmitter 102 in acoustic coupling with the housing 106. The spring 110 has a spring rate and spring force sufficient to provide consistent force against the receiver cap 112 to ensure contact between the receiver cap 112 and the transmitter 102, and acoustic contact of the transmitter 102 with the housing 106, for example, as the transmitter 102 fluctuates along its transmitter axis B-B. In some instances, the example in-well type acoustic element 100 includes a washer on one or both longitudinal ends of the spring 110, for example, to keep the spring 110 from binding. In some instances, the example in-well type acoustic element 100 includes two or more springs. The spring 110 can take many forms, for example, a compression spring, a torsion spring, a tension spring, a polymer spring, a gas spring, an expanding material, and/or another type of material adapted to provide a force against the receiver cap 112.
In some instances, the receiver cap 112 includes a centralizer, for example, a centering element (e.g., O-ring) in a shaped indentation 118 on a surface of the receiver cap 112 adjacent to the transmitter 102 and/or receiver 104, to stabilize the transmitter 102 and/or receiver 104 against the receiver cap 112. The receiver cap 112 generally includes a dense material, such as tungsten, aluminum, steel, and/or other, in order to optimize reactive mass. The receiver cap 112 acts against fluctuations of the transmitter 102 such that acoustic energy from the fluctuations of the transmitter transfers more into the housing 106 than the receiver cap 112. The receiver cap 112 resists reactive motion from the fluctuations of the transmitter 102 depending on the density of the receiver cap 112. For example, a high density receiver cap is more difficult to oscillate than a lower density receiver cap, so a high density receiver cap promotes more acoustic energy from a transmitter to a housing than a lower density receiver cap.
As shown in
As depicted in
Referring to
Referring again to
Certain aspects may provide various advantages. In some instances, the spring ensures acoustic coupling between the transmitter 102 and the housing 106 as the housing 106 expands, contracts, and/or bends in response to environmental factors, such as thermal expansion, thermal contraction, torsional and tension forces, and/or other factors. In other instances, the centralizers in the receiver cap 112 and the cup 122 ensure axial alignment of the transmitter 102 and/or receiver 104. Axial alignment of the transmitter 102 and receiver can reduce sensitivity to environmental conditions, and increase acoustic sensitivity in reception and transmission in a specific direction. In certain instances, a pressure sealed housing 106 allows for better acoustic sensitivity in reception and transmission. In some instances, configuring the transmitter 102 and receiver 104 as a unitary transceiver allows for both reception and transmission of acoustic communication signal with a single unit. A receiver part of the unitary transceiver is sensitive to acoustic signal in the same axial direction as a transmitted acoustic signal from the transmitter part of the unitary transceiver.
In view of the discussion above, certain aspects encompass, an in-well type acoustic telemetry system including an elongate tubular housing, an elongate transmitter in the tubular housing, and a receiver in the tubular housing. The transmitter is adapted to generate an output acoustic signal by linearly fluctuating along a transmitter axis in response to an electrical signal. The receiver is adapted to generate a second electrical signal by linearly fluctuating along a receiver axis that is parallel to or coincides with the transmitter axis.
Certain aspects encompass, a method where an input acoustic telemetric signal is received in a subterranean well by linearly fluctuating a receiver along a receiver axis in response to the input acoustic telemetric signal. An output acoustic telemetric signal is generated in the subterranean well by linearly fluctuating a transmitter along a transmitter axis in response to an electrical signal. The transmitter axis is parallel to or coincides with the receiver axis.
Certain aspects encompass, an in-well type transceiving device including a transmitter oriented with its greatest transmission efficiency along an axis, and a receiver oriented with its greatest receiver efficiency along the axis.
The aspects above can include some, none, or all of the following features. The transmitter includes a laminated stack of an electrically responsive material adapted to strain along the transmitter axis in response to the electrical signal. The receiver includes a laminated stack of electrically responsive material adapted to convert strain along the receiver axis into the second electrical signal. The transmitter and the receiver are configured as a unitary transceiver. The electrically responsive material includes at least one item selected from the group consisting of piezoceramic wafers, a piezoelectric, a piezopolymer, an electrostrictor, and a ferroelectric material. The transmitter and receiver each include an electrically responsive material including an electromagnetic voice coil or a magnetostrictor. The transmitter is adjacent the receiver. The transmitter is in acoustic series with the receiver. The in-well type acoustic telemetry system includes a spring between the transmitter and the housing, and a receiver cap between the transmitter and the spring. The spring presses against a portion of the receiver cap, and the receiver cap presses against the transmitter to bias the transmitter into acoustic coupling to a portion of the housing. The portion of the housing is a longitudinal end facing surface of the housing, and the transmitter abuts the longitudinal end facing surface of the housing. The portion of the housing includes a metal cup receiving an end of the transmitter. The spring abuts the receiver cap on one end and abuts a housing nut on another end. The housing nut is adapted to threadably secure to the housing. The receiver cap includes tungsten. The transmitter axis coincides with a center longitudinal axis of the tubular housing. The transmitter and receiver are configured as a unitary transceiver. The method includes clamping the transmitter against a housing with a spring, where the spring is oriented along the transmitter axis. Generating, in the subterranean well, an acoustic telemetric signal by linearly fluctuating the transmitter along the transmitter axis in response to an electrical signal includes imparting vibrations from the transmitter out of a housing. The transmitter is in acoustic series with the receiver. The transmitter and the receiver are configured as a unitary transceiver.
A number of embodiments have been described. Nevertheless, it will be understood that various modifications may be made. Accordingly, other embodiments are within the scope of the following claims.
Filing Document | Filing Date | Country | Kind |
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PCT/US2014/033222 | 4/7/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/156769 | 10/15/2015 | WO | A |
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2015156769 | Oct 2015 | WO |
Number | Date | Country | |
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20170016319 A1 | Jan 2017 | US |