CA2560479C - Distributed downhole drilling network - Google Patents
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- CA2560479C CA2560479C CA2560479A CA2560479A CA2560479C CA 2560479 C CA2560479 C CA 2560479C CA 2560479 A CA2560479 A CA 2560479A CA 2560479 A CA2560479 A CA 2560479A CA 2560479 C CA2560479 C CA 2560479C
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Classifications
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- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B47/00—Survey of boreholes or wells
- E21B47/12—Means for transmitting measuring-signals or control signals from the well to the surface, or from the surface to the well, e.g. for logging while drilling
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01V—GEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
- G01V1/00—Seismology; Seismic or acoustic prospecting or detecting
- G01V1/24—Recording seismic data
- G01V1/26—Reference-signal-transmitting devices, e.g. indicating moment of firing of shot
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01V—GEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
- G01V11/00—Prospecting or detecting by methods combining techniques covered by two or more of main groups G01V1/00 - G01V9/00
- G01V11/002—Details, e.g. power supply systems for logging instruments, transmitting or recording data, specially adapted for well logging, also if the prospecting method is irrelevant
Abstract
A high-speed downhole network providing real-time data from downhole components of drilling strings includes is shown in figure (2). The network includes a bottom-hole node (18e) interfacing to a bottom-hole assembly located proximate the bottom end of a drill string. A top-hole node (18a) is connected proximate the top end of the drill string. One or several intermediate nodes (18b-d) are located along the drill string between the top-and bottom-hole nodes. The intermediate nodes are configured to receive and transmit data packets between the bottom-hole nodes. A communication link, integrated into the drill string, is used to connect the nodes, A computer (28) may be connected to the top-hole node, to analyze data received.
Description
DISTRIBUTED DOWNHOLE DRILLING NETWORK
II
12 1. The Field of the Invention 13 This invention relates to oil and gas drilling, and more particularly to apparatus 14 and methods providing a downhole network for transmitting information between downhole drilling components, and from downhole drilling components to the ground's 16 surface.
18 2. The RelevantArt 19 MWD (measurement while drilling) involves the transmission of data from downhole drilling components to the earth's surface in real time. Once reaching ground 21 level, the data may be analyzed. The data may be used to adjust drilling parameters, such 22. as drilling direction, penetration speed, and the like. Data may originate from various 23 downhole components, including a bottom hole assembly comprising a drill bit and other 24 components, and from sensors and tools located farther up the drill string. What is lacking are apparatus and methods to effectively link or network various downhole 26 sensors and tools together such that they may communicate with one another, transmit 27 data at high speeds to the ground's surface, or receive commands originating from the 1 ground's surface.
2 The advantages of computer networks are well known. By interconnecting two or 3 more computers, computing resources, data storage devices, and peripherals may be 4 shared. Data and applications may be seamlessly transferred or accessed between computers connected to the network. Redundant components enable data to be backed up 6 from one computer to another. Moreover, the performance provided by modem 7 networking protocols provides for high-speed bi-directional transmission of data from 8 one location to another. Nevertheless, few if any instances of the prior art teach the 9 integration of a network into a downhole drill string.
U.S. Patent No. 6,218,959 to Smith describes a system and method for fail-safe 11 communication of information transmitted in the form of electromagnetic wave fronts.
12 These wave fronts propagate through the earth between surface equipment and downhole 13 components. The system comprises two or more repeaters disposed within a well bore 14 such that the two repeaters receive each signal carrying the telemetered information. The repeater that is farther from the source includes a memory device that stores information 16 carried in the signal. A timer device, in the repeater that is farther from the source, 17 triggers the retransmission of the information after a predetermined time period, unless 18 the repeater that is farther from the source has detected a signal carrying the information, 19 generated by the repeater that is closer to the source.
The repeaters taught by Smith are wireless repeaters and would not be suitable for 21 a hardwired network integrated into a drill string. Moreover, the repeaters are used 22 exclusively for receiving and forwarding data signals. These repeaters lack many 23 features, such as the ability to gather data or provide control signals at nodes along the 24 drill string.
U.S. Patent No. 5,959,547 to Tubel et al. teaches a plurality of downhole control 26 systems interconnected by a network including a server for monitoring and controlling 27 network communications. Each downhole control system is associated with a zone in one 1 or more wells. The downhole control systems communicate directly with each other 2 transferring information and commands as necessary. The downhole server monitors 3 network communications to resolve data collisions and provides supervisory functions.
4 The system taught by Tubel et al. is designed for production well systems and would not function in drill strings.
6 U. S . Patent Application No. 20030038734 to Hirsch et al. describes a reservoir 7 production control system includes a plurality of wells for producing a reservoir linked to 8 a central computer over a downhole communication network and a surface 9 communication network. Both the downhole and the surface communication networks are wireless communications paths for transmitting downhole data and surface data to the 11 central computer.
12 Both networks include a series of interconnected tubing or pipe that allows 13 transmission of data over electrically isolated portions of the pipe and tubing. After 14 integrating and analyzing all relevant data and comparing the data with a reservoir model, the central computer initiates changes in a plurality of downhole control devices 16 associated with the wells, thereby optimizing the production of the reservoir. Like the 17 Tubel et al. reference, the system taught by Hirsch et al. is designed for production well 18 systems and would not be suitable for integration into a drill string.
19 In view of the foregoing, what are needed are apparatus and methods to interconnect downhole-drilling components by way of a high-speed network. Such a 21 high-speed network may enable high-speed data transmission between downhole 22 components, and between downhole components and the ground's surface.
23 What are further needed are apparatus and methods to acquire or gather data at 24 various points or nodes along the drill string, for transmission along the network.
It would be a further advance to allow control or other signals to be transmitted 26 from the surface to downhole components or tools connected to the network.
1 It would be a further advance to provide downhole nodes, that not only repeat or 2 amplify a signal, but are also configured to gather data from sensors such as 3 inclinometers, pressure transducers, thermocouplers, accelerometers, imaging devices, 4 seismic devices, and the like.
7 In view of the foregoing, it is a primary object of the present invention to 8 interconnect downhole-drilling components by way of a high-speed network.
A high-9 speed network in accordance with the invention enables high-speed data transmission between downhole components, and between downhole components and the ground's 11 surface. It is a further object of the present invention to provide apparatus and methods to 12 acquire or gather data at various points or nodes along the drill string, for transmission 13 along the network. It is yet a further object to enable control or other signals to be 14 transmitted from the surface to downhole components or tools connected to the network.
Consistent with the foregoing objects, and in accordance with the invention as 16 embodied and broadly described herein, a downhole network is disclosed in one 17 embodiment of the present invention as including a bottom-hole node interfacing to a 18 bottom-hole assembly located proximate the bottom end of a drill string.
A top-hole node 19 is connected proximate the top end of the drill string. One or several intermediate nodes are located along the drill string between the bottom-hole node and the top-hole node.
21 The intermediate nodes are configured to receive and transmit data packets transmitted 22 between the bottom-hole node and the top-hole node. A communications link, integrated 23 into the drill string, is used to operably connect the bottom-hole node, the intermediate 24 nodes, and the top-hole node.
In selected embodiments, a personal or other computer may be connected to the 26 top-hole node, to analyze data received from the intermediate and bottom-hole nodes.
12 1. The Field of the Invention 13 This invention relates to oil and gas drilling, and more particularly to apparatus 14 and methods providing a downhole network for transmitting information between downhole drilling components, and from downhole drilling components to the ground's 16 surface.
18 2. The RelevantArt 19 MWD (measurement while drilling) involves the transmission of data from downhole drilling components to the earth's surface in real time. Once reaching ground 21 level, the data may be analyzed. The data may be used to adjust drilling parameters, such 22. as drilling direction, penetration speed, and the like. Data may originate from various 23 downhole components, including a bottom hole assembly comprising a drill bit and other 24 components, and from sensors and tools located farther up the drill string. What is lacking are apparatus and methods to effectively link or network various downhole 26 sensors and tools together such that they may communicate with one another, transmit 27 data at high speeds to the ground's surface, or receive commands originating from the 1 ground's surface.
2 The advantages of computer networks are well known. By interconnecting two or 3 more computers, computing resources, data storage devices, and peripherals may be 4 shared. Data and applications may be seamlessly transferred or accessed between computers connected to the network. Redundant components enable data to be backed up 6 from one computer to another. Moreover, the performance provided by modem 7 networking protocols provides for high-speed bi-directional transmission of data from 8 one location to another. Nevertheless, few if any instances of the prior art teach the 9 integration of a network into a downhole drill string.
U.S. Patent No. 6,218,959 to Smith describes a system and method for fail-safe 11 communication of information transmitted in the form of electromagnetic wave fronts.
12 These wave fronts propagate through the earth between surface equipment and downhole 13 components. The system comprises two or more repeaters disposed within a well bore 14 such that the two repeaters receive each signal carrying the telemetered information. The repeater that is farther from the source includes a memory device that stores information 16 carried in the signal. A timer device, in the repeater that is farther from the source, 17 triggers the retransmission of the information after a predetermined time period, unless 18 the repeater that is farther from the source has detected a signal carrying the information, 19 generated by the repeater that is closer to the source.
The repeaters taught by Smith are wireless repeaters and would not be suitable for 21 a hardwired network integrated into a drill string. Moreover, the repeaters are used 22 exclusively for receiving and forwarding data signals. These repeaters lack many 23 features, such as the ability to gather data or provide control signals at nodes along the 24 drill string.
U.S. Patent No. 5,959,547 to Tubel et al. teaches a plurality of downhole control 26 systems interconnected by a network including a server for monitoring and controlling 27 network communications. Each downhole control system is associated with a zone in one 1 or more wells. The downhole control systems communicate directly with each other 2 transferring information and commands as necessary. The downhole server monitors 3 network communications to resolve data collisions and provides supervisory functions.
4 The system taught by Tubel et al. is designed for production well systems and would not function in drill strings.
6 U. S . Patent Application No. 20030038734 to Hirsch et al. describes a reservoir 7 production control system includes a plurality of wells for producing a reservoir linked to 8 a central computer over a downhole communication network and a surface 9 communication network. Both the downhole and the surface communication networks are wireless communications paths for transmitting downhole data and surface data to the 11 central computer.
12 Both networks include a series of interconnected tubing or pipe that allows 13 transmission of data over electrically isolated portions of the pipe and tubing. After 14 integrating and analyzing all relevant data and comparing the data with a reservoir model, the central computer initiates changes in a plurality of downhole control devices 16 associated with the wells, thereby optimizing the production of the reservoir. Like the 17 Tubel et al. reference, the system taught by Hirsch et al. is designed for production well 18 systems and would not be suitable for integration into a drill string.
19 In view of the foregoing, what are needed are apparatus and methods to interconnect downhole-drilling components by way of a high-speed network. Such a 21 high-speed network may enable high-speed data transmission between downhole 22 components, and between downhole components and the ground's surface.
23 What are further needed are apparatus and methods to acquire or gather data at 24 various points or nodes along the drill string, for transmission along the network.
It would be a further advance to allow control or other signals to be transmitted 26 from the surface to downhole components or tools connected to the network.
1 It would be a further advance to provide downhole nodes, that not only repeat or 2 amplify a signal, but are also configured to gather data from sensors such as 3 inclinometers, pressure transducers, thermocouplers, accelerometers, imaging devices, 4 seismic devices, and the like.
7 In view of the foregoing, it is a primary object of the present invention to 8 interconnect downhole-drilling components by way of a high-speed network.
A high-9 speed network in accordance with the invention enables high-speed data transmission between downhole components, and between downhole components and the ground's 11 surface. It is a further object of the present invention to provide apparatus and methods to 12 acquire or gather data at various points or nodes along the drill string, for transmission 13 along the network. It is yet a further object to enable control or other signals to be 14 transmitted from the surface to downhole components or tools connected to the network.
Consistent with the foregoing objects, and in accordance with the invention as 16 embodied and broadly described herein, a downhole network is disclosed in one 17 embodiment of the present invention as including a bottom-hole node interfacing to a 18 bottom-hole assembly located proximate the bottom end of a drill string.
A top-hole node 19 is connected proximate the top end of the drill string. One or several intermediate nodes are located along the drill string between the bottom-hole node and the top-hole node.
21 The intermediate nodes are configured to receive and transmit data packets transmitted 22 between the bottom-hole node and the top-hole node. A communications link, integrated 23 into the drill string, is used to operably connect the bottom-hole node, the intermediate 24 nodes, and the top-hole node.
In selected embodiments, a personal or other computer may be connected to the 26 top-hole node, to analyze data received from the intermediate and bottom-hole nodes.
1 The personal computer may include a user interface to display data received from the 2 intermediate and bottom-hole nodes.
3 The bottom hole assembly may include various sensors or tools, including but not 4 limited to pressure sensors, inclinometers, temperature sensors, thermocouplers, accelerometers, imaging devices, and seismic devices. In selected embodiments, the 6 intermediate nodes may function primarily as repeaters. In other embodiments, the 7 intermediate nodes may perform functions such as signal amplification, filtering, error 8 checking, routing, and switching.
3 The bottom hole assembly may include various sensors or tools, including but not 4 limited to pressure sensors, inclinometers, temperature sensors, thermocouplers, accelerometers, imaging devices, and seismic devices. In selected embodiments, the 6 intermediate nodes may function primarily as repeaters. In other embodiments, the 7 intermediate nodes may perform functions such as signal amplification, filtering, error 8 checking, routing, and switching.
9 In selected embodiments, a module, housing the intermediate node, may be designed such that it may be inserted at a point along the drill string. The intermediate node may be further configured to gather data from at least one of a downhole sensor and 12 a downhole tool, located along the drill string, proximate the intermediate node.
13 As with most networks, the top-hole node, the intermediate nodes, and the 14 bottom-hole node may be assigned a unique network address. Likewise, data packets transmitted between the nodes may include a source address, identifying the source of a 16 packet, and a destination address, identifying the destination of a packet. Data packets 17 may carry various types of information, such as data originating from pressure sensors, 18 inclinometers, temperature sensors, thermocouplers, accelerometers, imaging devices, 19 and seismic devices.
In another aspect of the present invention, a method for transmitting information 21 along a drill string includes transmitting, from a bottom-hole node, data packets along a 22 communications link integrated into the drill sting. The method further includes 23 receiving, by an intermediate node, the data packets. The intermediate node is located at 24 an intermediate location along the drill string, and operably connected to the communications link. The method further includes amplifying, by the intermediate node, 26 the data packets, and forwarding the data packets to a top-hole node operably connected 27 to the communications link.
In certain embodiments, a method in accordance with the invention may 2 further include receiving, by a personal computer, data packets from the top-hole 3 node, for analysis. The personal computer may display, on a user interface, data 4 received from the intermediate and bottom-hole nodes. A method may also include processing, by the intermediate node, data packets that are received.
Processing may 6 include tasks such as filtering, error checking, routing, and switching.
The top-hole 7 node, the intermediate node, and the bottom-hole node may each be assigned a 8 unique network address.
9 In selected embodiments, a method in accordance with the invention may include gathering, by the intermediate node, a data packets containing data gathered 11 from downhole sensors or downhole tools located near the intermediate node along 12 the drill string. Each data packet may include a source address, identifying the 13 source of a packet, and a destination address, identifying the destination of a packet.
14 Data packets may carry data originating from devices or sensors such as pressure sensors, inclinometers, temperature sensors, thermocouplers, accelerometers, 16 imaging devices, and seismic devices.
17 In one aspect, the invention provides a downhole network integrated into a 18 drill string comprising a plurality of drill pipes, each of the plurality of pipes having 19 electrically coupled inductive coils at its respective ends, the pipes being connected end-to-end and passing data packets by electromagnetic data communication through 21 the coils;
22 a bottom-hole node interfacing to a bottom-hole assembly located proximate 23 a bottom end of the drill string;
24 a top-hole node connected proximate a top end of the drill string;
an intermediate node located along the drill string between the bottom-hole 26 node and the top-hole node, the intermediate node configured to receive and 27 transmit the data packets transmitted between the bottom-hole node and the top-hole 28 node; and -7.
1 a communications link, integrated in the drill string, operably connecting the 2 bottom-hole node to the intermediate node, and the intermediate node to the top-3 hole node wherein timing of at least two of the nodes is synchronized.
4 In one aspect, the invention provides a method for transmitting information along a drill string, comprising a plurality of drill pipes, each of the plurality of 6 pipes having electrically coupled inductive coils at its respective ends, the pipes 7 being connected end-to-end and passing data packets by electromagnetic data 8 communication through the coils, the method comprising:
9 transmitting, from a bottom-hole node, a first data packet along a communications link integrated into the drill sting;
11 receiving, by an intermediate node located at an intermediate location along 12 the drill string;
13 operably connected to the communications link, the first data packet;
14 amplifying, by the intermediate node, the first data packet; and forwarding, by the intermediate node, the first data packet to a top-hole node 16 operably connected to the communications link.
18 The foregoing and other features of the present invention will become more fully 19 apparent from the.following description, taken in conjunction with the accompanying drawings. Understanding that these drawings depict only typical embodiments in 21 accordance with the invention and are, therefore, not to be considered limiting of its 22 scope, the invention will be described with additional specificity and detail throngh use of 23 the accompanying drawings in which:
24 Figure 1 is a profile view of a drill rig illustrating a context for using an apparatus and method in accordance with the invention;
26 Figure 2 is a profile view illustrating one configuration of various nodes used to 27 implement a dovvnhole network in accordance with the invention;
-7a-Figure 3 is a schematic block diagram illustrating certain embodiments of 2 hardware and corresponding functions provided by a node in accordance with the 3 invention;
4 Figure 4 is a profile view illustrating high-level functionality of one embodiment of a downhole network;
6 Figure 5 is a schematic block diagram illustrating one embodiment of nodes used 7 to implement a downhole network in accordance with the invention, and various devices, 8 sensors, and tools interfacing with the nodes.
9 Figure 6 is a schematic block diagram illustrating additional detail of one io embodiment of a node in accordance with the invention;
11 Figure 7 is a schematic block diagram illustrating one embodiment of a packet 12 used to transmit data between nodes; and 13 Figure 8 is perspective view illustrating one embodiment of a downhole module 14 that may be physically installed into a drill string to implement a node in accordance with the invention.
17 It will be readily understood that the components of the present invention, as 18 generally described and illustrated in the Figures herein, could be arranged and designed 19 in a wide variety of different configurations. Thus, the following more detailed description of embodiments of apparatus and methods of the present invention, as 21 represented in the Figures, is not intended to limit the scope of the invention, as claimed, 22 but is merely representative of various selected embodiments of the invention.
23 The illustrated embodiments of the invention will be best understood by 24 reference to the drawings, wherein like parts are designated by like numerals throughout.
Those of ordinary skill in the art will, of course, appreciate that various modifications to 26 the apparatus and methods described herein may easily be made without departing from 27 the essential characteristics of the invention, as described in connection with the Figures.
I Thus, the following description of the Figures is intended only by way of example, and 2 simply illustrates certain selected embodiments consistent with the invention as claimed 3 herein.
4 Referring to Figure 1, a drill rig 10 may include a derrick 12 and a drill string 14 comprised of multiple sections of drill pipe 16 and other downhole tools 16. A
bottom-6 hole assembly 20, connected to the bottom of the drill string 14, may include a drill bit, 7 sensors, and other downhole tools. Because a drill string 14 may penetrate into the 8 ground 20,000 feet or more, receiving and transmitting data from a bottom-hole assembly 9 20 to the surface may present numerous obstacles. Data must be transmitted along what may be hundreds of sections of drill pipe, and across each tool joint.
11 Signal loss may occur at each of the tool joints due to coupling losses and 12 mismatched transmission elements. For example, in selected embodiments, an electrical 13 signal transmitted along the drill string 14 may be transmitted as a magnetic field across 14 tool joints, losing energy each time it is converted. Signal loss may also occur because of voltage drops, or other factors, in cable, wires, or other transmission media extending the 16 length of the drill string 14. Thus, apparatus and methods are needed to ensure that data 17 received from a bottom-hole assembly 20 or other downhole tools 16 is safely transmitted 18 to the surface.
19 In selected embodiments in accordance with the invention, network nodes 18 may be inserted at desired intervals along the drill string 14, such as every 1000 to 5000 feet, 21 to perform various functions. For example, the network nodes 18 may function as signal 22 repeaters 18 to regenerate data signals traveling up and down the drill string 14. These 23 nodes 18 may be integrated into an existing drill pipe 16 or downhole tool 16, or may be 24 independent downhole tools 18.
Referring to Figure 2, in selected embodiments a downhole network 17 may be 26 used to transmit information along a drill string 14. A downhole network 17 may include 27 multiple nodes 18a-e spaced up and down a drill string 14. The nodes 18a-e may be 7 Other intermediate nodes 18b-d may be located or spaced to act as relay points for 12 Communication links 24a-d may be used to connect the nodes 18a-e to one 19 As in most networks, packets 22a, 22b may be transmitted between nodes 18a-e.
13 As with most networks, the top-hole node, the intermediate nodes, and the 14 bottom-hole node may be assigned a unique network address. Likewise, data packets transmitted between the nodes may include a source address, identifying the source of a 16 packet, and a destination address, identifying the destination of a packet. Data packets 17 may carry various types of information, such as data originating from pressure sensors, 18 inclinometers, temperature sensors, thermocouplers, accelerometers, imaging devices, 19 and seismic devices.
In another aspect of the present invention, a method for transmitting information 21 along a drill string includes transmitting, from a bottom-hole node, data packets along a 22 communications link integrated into the drill sting. The method further includes 23 receiving, by an intermediate node, the data packets. The intermediate node is located at 24 an intermediate location along the drill string, and operably connected to the communications link. The method further includes amplifying, by the intermediate node, 26 the data packets, and forwarding the data packets to a top-hole node operably connected 27 to the communications link.
In certain embodiments, a method in accordance with the invention may 2 further include receiving, by a personal computer, data packets from the top-hole 3 node, for analysis. The personal computer may display, on a user interface, data 4 received from the intermediate and bottom-hole nodes. A method may also include processing, by the intermediate node, data packets that are received.
Processing may 6 include tasks such as filtering, error checking, routing, and switching.
The top-hole 7 node, the intermediate node, and the bottom-hole node may each be assigned a 8 unique network address.
9 In selected embodiments, a method in accordance with the invention may include gathering, by the intermediate node, a data packets containing data gathered 11 from downhole sensors or downhole tools located near the intermediate node along 12 the drill string. Each data packet may include a source address, identifying the 13 source of a packet, and a destination address, identifying the destination of a packet.
14 Data packets may carry data originating from devices or sensors such as pressure sensors, inclinometers, temperature sensors, thermocouplers, accelerometers, 16 imaging devices, and seismic devices.
17 In one aspect, the invention provides a downhole network integrated into a 18 drill string comprising a plurality of drill pipes, each of the plurality of pipes having 19 electrically coupled inductive coils at its respective ends, the pipes being connected end-to-end and passing data packets by electromagnetic data communication through 21 the coils;
22 a bottom-hole node interfacing to a bottom-hole assembly located proximate 23 a bottom end of the drill string;
24 a top-hole node connected proximate a top end of the drill string;
an intermediate node located along the drill string between the bottom-hole 26 node and the top-hole node, the intermediate node configured to receive and 27 transmit the data packets transmitted between the bottom-hole node and the top-hole 28 node; and -7.
1 a communications link, integrated in the drill string, operably connecting the 2 bottom-hole node to the intermediate node, and the intermediate node to the top-3 hole node wherein timing of at least two of the nodes is synchronized.
4 In one aspect, the invention provides a method for transmitting information along a drill string, comprising a plurality of drill pipes, each of the plurality of 6 pipes having electrically coupled inductive coils at its respective ends, the pipes 7 being connected end-to-end and passing data packets by electromagnetic data 8 communication through the coils, the method comprising:
9 transmitting, from a bottom-hole node, a first data packet along a communications link integrated into the drill sting;
11 receiving, by an intermediate node located at an intermediate location along 12 the drill string;
13 operably connected to the communications link, the first data packet;
14 amplifying, by the intermediate node, the first data packet; and forwarding, by the intermediate node, the first data packet to a top-hole node 16 operably connected to the communications link.
18 The foregoing and other features of the present invention will become more fully 19 apparent from the.following description, taken in conjunction with the accompanying drawings. Understanding that these drawings depict only typical embodiments in 21 accordance with the invention and are, therefore, not to be considered limiting of its 22 scope, the invention will be described with additional specificity and detail throngh use of 23 the accompanying drawings in which:
24 Figure 1 is a profile view of a drill rig illustrating a context for using an apparatus and method in accordance with the invention;
26 Figure 2 is a profile view illustrating one configuration of various nodes used to 27 implement a dovvnhole network in accordance with the invention;
-7a-Figure 3 is a schematic block diagram illustrating certain embodiments of 2 hardware and corresponding functions provided by a node in accordance with the 3 invention;
4 Figure 4 is a profile view illustrating high-level functionality of one embodiment of a downhole network;
6 Figure 5 is a schematic block diagram illustrating one embodiment of nodes used 7 to implement a downhole network in accordance with the invention, and various devices, 8 sensors, and tools interfacing with the nodes.
9 Figure 6 is a schematic block diagram illustrating additional detail of one io embodiment of a node in accordance with the invention;
11 Figure 7 is a schematic block diagram illustrating one embodiment of a packet 12 used to transmit data between nodes; and 13 Figure 8 is perspective view illustrating one embodiment of a downhole module 14 that may be physically installed into a drill string to implement a node in accordance with the invention.
17 It will be readily understood that the components of the present invention, as 18 generally described and illustrated in the Figures herein, could be arranged and designed 19 in a wide variety of different configurations. Thus, the following more detailed description of embodiments of apparatus and methods of the present invention, as 21 represented in the Figures, is not intended to limit the scope of the invention, as claimed, 22 but is merely representative of various selected embodiments of the invention.
23 The illustrated embodiments of the invention will be best understood by 24 reference to the drawings, wherein like parts are designated by like numerals throughout.
Those of ordinary skill in the art will, of course, appreciate that various modifications to 26 the apparatus and methods described herein may easily be made without departing from 27 the essential characteristics of the invention, as described in connection with the Figures.
I Thus, the following description of the Figures is intended only by way of example, and 2 simply illustrates certain selected embodiments consistent with the invention as claimed 3 herein.
4 Referring to Figure 1, a drill rig 10 may include a derrick 12 and a drill string 14 comprised of multiple sections of drill pipe 16 and other downhole tools 16. A
bottom-6 hole assembly 20, connected to the bottom of the drill string 14, may include a drill bit, 7 sensors, and other downhole tools. Because a drill string 14 may penetrate into the 8 ground 20,000 feet or more, receiving and transmitting data from a bottom-hole assembly 9 20 to the surface may present numerous obstacles. Data must be transmitted along what may be hundreds of sections of drill pipe, and across each tool joint.
11 Signal loss may occur at each of the tool joints due to coupling losses and 12 mismatched transmission elements. For example, in selected embodiments, an electrical 13 signal transmitted along the drill string 14 may be transmitted as a magnetic field across 14 tool joints, losing energy each time it is converted. Signal loss may also occur because of voltage drops, or other factors, in cable, wires, or other transmission media extending the 16 length of the drill string 14. Thus, apparatus and methods are needed to ensure that data 17 received from a bottom-hole assembly 20 or other downhole tools 16 is safely transmitted 18 to the surface.
19 In selected embodiments in accordance with the invention, network nodes 18 may be inserted at desired intervals along the drill string 14, such as every 1000 to 5000 feet, 21 to perform various functions. For example, the network nodes 18 may function as signal 22 repeaters 18 to regenerate data signals traveling up and down the drill string 14. These 23 nodes 18 may be integrated into an existing drill pipe 16 or downhole tool 16, or may be 24 independent downhole tools 18.
Referring to Figure 2, in selected embodiments a downhole network 17 may be 26 used to transmit information along a drill string 14. A downhole network 17 may include 27 multiple nodes 18a-e spaced up and down a drill string 14. The nodes 18a-e may be 7 Other intermediate nodes 18b-d may be located or spaced to act as relay points for 12 Communication links 24a-d may be used to connect the nodes 18a-e to one 19 As in most networks, packets 22a, 22b may be transmitted between nodes 18a-e.
1 Referring to Figure 3, a network node 18 in accordance with the invention may 2 include hardware 29 providing functionality to the node 18, as well as functions 30 3 performed by the node 18. The functions 30 may be provided strictly by the hardware 29, 4 applications executable on the hardware 29, or a combination thereof. For example, hardware 29 may include one or several processors 31 capable of processing or executing 6 instructions or other data. Processors 31 may include hardware such as busses, clocks, 7 cache, or other supporting hardware.
8 Likewise, hardware 29 may include volatile 34 and non-volatile 36 memory 9 providing data storage and staging areas for data transmitted between hardware components 29. Volatile memory 34 may include random access memory (RAM) or 11 equivalents thereof, providing high-speed memory storage. Memory 32 may also include 12 selected types of non-volatile memory 36 such as read-only-memory (ROM), or other 13 long term storage devices, such as hard drives and the like. Ports 38 such as serial, 14 parallel, or other ports 38 may be used to input and output signals uphole or downhole from the node 18, provide interfaces with sensors or tools located proximate the node 18, 16 or interface with other tools or sensors located in a drilling environment.
17 A modem 40 may be used to modulate digital data onto a carrier signal for 18 transmission uphole or downhole along the network 17. Likewise, the modem 40 may 19 demodulate digital data from signals transmitted along the network 17. A
modem 40 may provide various built in features including but not limited to error checking, data 21 compression, or the like. In addition, the modem 40 may use any suitable modulation 22 type such as QPSK, 00K, PCM, FSK, QAM, or the like. The choice of a modulation 23 type may depend on a desired data transmission speed, as well as unique operating 24 conditions that may exist in a downhole environment. Likewise, the modem 40 may be configured to operate in full duplex, half duplex, or other mode. The modem 40 may also 26 use any of numerous networking protocols currently available, such as collision-based I protocols, such as Ethernet, or token- based protocols such as are used in token ring 2 networks.
3 A node 18 may also include one or several switches 42 or multiplexers 42 to filter 4 and forward packets between nodes 18 of the network 17, or combine several signals for transmission over a single medium. Likewise, a demultiplexer may be included with the 6 multiplexer 42 to separate multiplexed signals received on a transmission line.
7 A node 18 may include various sensors 44 located within the node 18 or 8 interfacing with the node 18. Sensors 44 may include data gathering devices such as 9 pressure sensors, inclinometers, temperature sensors, thermocouplers, accelerometers, imaging devices, seismic devices, or the like. Sensors 44 may be configured to gather 11 data for transmission up the network 17 to the grounds surface, or may also receive 12 control signals from the surface to control selected parameters of the sensors 44. For 13 example, an operator at the surface may actually instruct a sensor 44 to take a particular 14 measurement. Likewise, other tools 46 located downhole may interface with a node 18 to gather data for transmission uphole, or follow instructions received from the surface.
16 Since a drill string may extend into the earth 20,000 feet or more, signal loss or 17 signal attenuation that occurs when transmitting data along the downhole network 17, 18 may be an important or critical issue. Various hardware or other devices of the downhole 19 network 17 may be responsible for causing different amounts of signal attenuation. For example, since a drill string is typically comprised of multiple segments of drill pipe or 21 other drill tools, signal loss may occur each time a signal is transmitted from one 22 downhole tool to another. Since a drill string may include several hundred sections of 23 drill pipe or other tools, the total signal loss that occurs across all of the tool joints may be 24 quite significant. Moreover, a certain level of signal loss may occur in the cable or other transmission media extending from the bottom-hole assembly 20 to the surface.
26 To reduce data loss due to signal attenuation, amplifiers 48, or repeaters 48, may 27 be spaced at various intervals along the downhole network 17. The amplifiers 48 may 1 receive a data signal, amplify it, and transmit it to the next node 18.
Like an amplifier 48, 2 a repeater 48 may be used to receive a data signal and retransmit it at a higher power.
3 However, unlike an amplifier 48, a repeater 48 may remove noise from the data signal.
4 Likewise, a node 18 may include various filters 50. Filters 50 may be used to filter out undesired noise, frequencies, and the like that may be present or introduced into 6 a data signal traveling up or down the network 17. Likewise, the node 18 may include a 7 power supply 52 to supply power to any or all of the hardware 29. The node 18 may also 8 include other hardware 54, as needed, to provide desired functionality to the node 18.
9 The node 18 may provide various functions that are implemented by software, hardware, or a combination thereof. For example, functions 30 of the node 18 may 11 include data gathering 56, data processing 58, control 60, data storage 62, and other 12 functions 64. Data may be gathered 56 from sensors 66 located downhole, tools 68, or 13 other nodes 70 in communication with a selected node 18. This data 56 may be 14 transmitted or encapsulated within data packets transmitted up and down the network 17.
Likewise, the node 18 may provide various data processing functions 58. For 16 example, data processing may include data amplification 72 or repeating 72, routing 74 or 17 switching 74 data packets transmitted along the network 17, error checking 76 of data 18 packets transmitted along the network 17, filtering 78 of data, as well as data compression 19 79 or decompression 79. Likewise, a node 18 may process various control signals 60 transmitted from the surface to tools 80, sensors 82, or other nodes 84 located downhole.
21 Likewise, a node 18 may store data that has been gathered from tools, sensors, or other 22 nodes 18 within the network 17. Likewise, the node 18 may include other functions 64, 23 as needed, 24 Referring to Figure 4, in one embodiment, a downhole network 17 in accordance with the invention may include various nodes 18 spaced at selected intervals along the 26 network 17. Each of the nodes 18 may be in operable communication with a bottom-hole 27 assembly 20. As data signals or packets travel up and down the network 17, transmission I elements 86a-e may be used to transmit signals across tool joints of a drill string 14.
2 As illustrated, in selected embodiments, inductive coils 86a-e may be used to 9 In selected embodiments, when using inductive coils 86a-e, consistent spacing 13 Referring to Figure 5, in one embodiment, a downhole network 17 in accordance 19 The bottom-hole interface 18e may communicate with an intermediate node 18c 26 A physical interface 90 may be provided to connect network components to a drill 1 other transmission media integrated directly into drill pipe or other drill string 2 components, the physical interface 90 provides a physical connection to the drill string so 3 data may be routed off of the drill string 14 to network components, such as a top-hole 4 interface 18a, or personal computer 28.
For example, a top-hole interface 18a may be operably connected to the physical 6 interface 90. The top-hole interface 18a may be connected to an analysis device 28 such 7 as a personal computer 28. The personal computer 28 may be used to analyze or examine 8 data gathered from various downhole tools or sensors. Likewise, DWD tool data 18a may 9 be saved or output from the personal computer 28. Likewise, in other embodiments, DWD tool data 88b may be extracted directly from the top-hole interface 18a for analysis.
11 Referring to Figure 6, in selected embodiments, a node 18 may include various 12 components to provide desired functionality. For example switches 42, multiplexers 42, 13 or a combination thereof may be used to receive, switch, and multiplex or demultiplex 14 signals, received from other uphole 110b and dovvnhole 110a nodes 18.
The switches/multiplexers 42 may direct traffic such as data packets or other signals into and 16 out of the node 18, and may ensure that the packets or signals are transmitted at proper 17 time intervals, frequencies, or a combination thereof.
18 In certain embodiments, the multiplexer 42 may transmit several signals 19 simultaneously on different carrier frequencies. In other embodiments, the multiplexer 42 may coordinate the time-division multiplexing of several signals. Signals or packets 21 received by the switch/multiplexer 42 may be amplified 48 and filtered 50, such as to 22 remove noise. In certain embodiments received signals may simply be amplified 48. In 23 other embodiments, the signals may be received, data may be demodulated therefrom and 24 stored, and the data may be remodulated and retransmitted on a selected carrier frequency having greater signal strength. A modem 40 may be used to demodulate analog signals 26 received from the switch/multiplexer into digital data and modulate digital data onto I carriers for transfer to the switches/multiplexer where they may be transmitted uphole or 2 downhole 3 The modem 40 may also perform various tasks such as error-checking 76.
The 4 modem 40 may also communicate with a microcontroller 104. The microcontroller 104 may execute any of numerous applications 106. For example, the microcontroller 6 may run applications 106 whose primary function is acquire data from one or a plurality 7 of sensors 44a-c. For example, the microcontroller 104 may interface to sensors 44 such 8 as inclinometers, thermocouplers, accelerometers, imaging devices, seismic data 9 gathering devices, or other sensors. Thus, the node 18 may include circuitry that functions as a data acquisition tool.
11 In other embodiments, the microcontroller 104 may run applications 106 that may 12 control various devices 46 located downhole. That is, not only may the node 18 be used 13 as a repeater, and as a data gathering device, but may also be used to receive or provide 14 control signals to control selected devices as needed. The node 18 may include a memory device 34 such as a FIFO 34 that may be used to store data needed by or transferred 16 between the modem 40 and the microcontroller 104.
8 Likewise, hardware 29 may include volatile 34 and non-volatile 36 memory 9 providing data storage and staging areas for data transmitted between hardware components 29. Volatile memory 34 may include random access memory (RAM) or 11 equivalents thereof, providing high-speed memory storage. Memory 32 may also include 12 selected types of non-volatile memory 36 such as read-only-memory (ROM), or other 13 long term storage devices, such as hard drives and the like. Ports 38 such as serial, 14 parallel, or other ports 38 may be used to input and output signals uphole or downhole from the node 18, provide interfaces with sensors or tools located proximate the node 18, 16 or interface with other tools or sensors located in a drilling environment.
17 A modem 40 may be used to modulate digital data onto a carrier signal for 18 transmission uphole or downhole along the network 17. Likewise, the modem 40 may 19 demodulate digital data from signals transmitted along the network 17. A
modem 40 may provide various built in features including but not limited to error checking, data 21 compression, or the like. In addition, the modem 40 may use any suitable modulation 22 type such as QPSK, 00K, PCM, FSK, QAM, or the like. The choice of a modulation 23 type may depend on a desired data transmission speed, as well as unique operating 24 conditions that may exist in a downhole environment. Likewise, the modem 40 may be configured to operate in full duplex, half duplex, or other mode. The modem 40 may also 26 use any of numerous networking protocols currently available, such as collision-based I protocols, such as Ethernet, or token- based protocols such as are used in token ring 2 networks.
3 A node 18 may also include one or several switches 42 or multiplexers 42 to filter 4 and forward packets between nodes 18 of the network 17, or combine several signals for transmission over a single medium. Likewise, a demultiplexer may be included with the 6 multiplexer 42 to separate multiplexed signals received on a transmission line.
7 A node 18 may include various sensors 44 located within the node 18 or 8 interfacing with the node 18. Sensors 44 may include data gathering devices such as 9 pressure sensors, inclinometers, temperature sensors, thermocouplers, accelerometers, imaging devices, seismic devices, or the like. Sensors 44 may be configured to gather 11 data for transmission up the network 17 to the grounds surface, or may also receive 12 control signals from the surface to control selected parameters of the sensors 44. For 13 example, an operator at the surface may actually instruct a sensor 44 to take a particular 14 measurement. Likewise, other tools 46 located downhole may interface with a node 18 to gather data for transmission uphole, or follow instructions received from the surface.
16 Since a drill string may extend into the earth 20,000 feet or more, signal loss or 17 signal attenuation that occurs when transmitting data along the downhole network 17, 18 may be an important or critical issue. Various hardware or other devices of the downhole 19 network 17 may be responsible for causing different amounts of signal attenuation. For example, since a drill string is typically comprised of multiple segments of drill pipe or 21 other drill tools, signal loss may occur each time a signal is transmitted from one 22 downhole tool to another. Since a drill string may include several hundred sections of 23 drill pipe or other tools, the total signal loss that occurs across all of the tool joints may be 24 quite significant. Moreover, a certain level of signal loss may occur in the cable or other transmission media extending from the bottom-hole assembly 20 to the surface.
26 To reduce data loss due to signal attenuation, amplifiers 48, or repeaters 48, may 27 be spaced at various intervals along the downhole network 17. The amplifiers 48 may 1 receive a data signal, amplify it, and transmit it to the next node 18.
Like an amplifier 48, 2 a repeater 48 may be used to receive a data signal and retransmit it at a higher power.
3 However, unlike an amplifier 48, a repeater 48 may remove noise from the data signal.
4 Likewise, a node 18 may include various filters 50. Filters 50 may be used to filter out undesired noise, frequencies, and the like that may be present or introduced into 6 a data signal traveling up or down the network 17. Likewise, the node 18 may include a 7 power supply 52 to supply power to any or all of the hardware 29. The node 18 may also 8 include other hardware 54, as needed, to provide desired functionality to the node 18.
9 The node 18 may provide various functions that are implemented by software, hardware, or a combination thereof. For example, functions 30 of the node 18 may 11 include data gathering 56, data processing 58, control 60, data storage 62, and other 12 functions 64. Data may be gathered 56 from sensors 66 located downhole, tools 68, or 13 other nodes 70 in communication with a selected node 18. This data 56 may be 14 transmitted or encapsulated within data packets transmitted up and down the network 17.
Likewise, the node 18 may provide various data processing functions 58. For 16 example, data processing may include data amplification 72 or repeating 72, routing 74 or 17 switching 74 data packets transmitted along the network 17, error checking 76 of data 18 packets transmitted along the network 17, filtering 78 of data, as well as data compression 19 79 or decompression 79. Likewise, a node 18 may process various control signals 60 transmitted from the surface to tools 80, sensors 82, or other nodes 84 located downhole.
21 Likewise, a node 18 may store data that has been gathered from tools, sensors, or other 22 nodes 18 within the network 17. Likewise, the node 18 may include other functions 64, 23 as needed, 24 Referring to Figure 4, in one embodiment, a downhole network 17 in accordance with the invention may include various nodes 18 spaced at selected intervals along the 26 network 17. Each of the nodes 18 may be in operable communication with a bottom-hole 27 assembly 20. As data signals or packets travel up and down the network 17, transmission I elements 86a-e may be used to transmit signals across tool joints of a drill string 14.
2 As illustrated, in selected embodiments, inductive coils 86a-e may be used to 9 In selected embodiments, when using inductive coils 86a-e, consistent spacing 13 Referring to Figure 5, in one embodiment, a downhole network 17 in accordance 19 The bottom-hole interface 18e may communicate with an intermediate node 18c 26 A physical interface 90 may be provided to connect network components to a drill 1 other transmission media integrated directly into drill pipe or other drill string 2 components, the physical interface 90 provides a physical connection to the drill string so 3 data may be routed off of the drill string 14 to network components, such as a top-hole 4 interface 18a, or personal computer 28.
For example, a top-hole interface 18a may be operably connected to the physical 6 interface 90. The top-hole interface 18a may be connected to an analysis device 28 such 7 as a personal computer 28. The personal computer 28 may be used to analyze or examine 8 data gathered from various downhole tools or sensors. Likewise, DWD tool data 18a may 9 be saved or output from the personal computer 28. Likewise, in other embodiments, DWD tool data 88b may be extracted directly from the top-hole interface 18a for analysis.
11 Referring to Figure 6, in selected embodiments, a node 18 may include various 12 components to provide desired functionality. For example switches 42, multiplexers 42, 13 or a combination thereof may be used to receive, switch, and multiplex or demultiplex 14 signals, received from other uphole 110b and dovvnhole 110a nodes 18.
The switches/multiplexers 42 may direct traffic such as data packets or other signals into and 16 out of the node 18, and may ensure that the packets or signals are transmitted at proper 17 time intervals, frequencies, or a combination thereof.
18 In certain embodiments, the multiplexer 42 may transmit several signals 19 simultaneously on different carrier frequencies. In other embodiments, the multiplexer 42 may coordinate the time-division multiplexing of several signals. Signals or packets 21 received by the switch/multiplexer 42 may be amplified 48 and filtered 50, such as to 22 remove noise. In certain embodiments received signals may simply be amplified 48. In 23 other embodiments, the signals may be received, data may be demodulated therefrom and 24 stored, and the data may be remodulated and retransmitted on a selected carrier frequency having greater signal strength. A modem 40 may be used to demodulate analog signals 26 received from the switch/multiplexer into digital data and modulate digital data onto I carriers for transfer to the switches/multiplexer where they may be transmitted uphole or 2 downhole 3 The modem 40 may also perform various tasks such as error-checking 76.
The 4 modem 40 may also communicate with a microcontroller 104. The microcontroller 104 may execute any of numerous applications 106. For example, the microcontroller 6 may run applications 106 whose primary function is acquire data from one or a plurality 7 of sensors 44a-c. For example, the microcontroller 104 may interface to sensors 44 such 8 as inclinometers, thermocouplers, accelerometers, imaging devices, seismic data 9 gathering devices, or other sensors. Thus, the node 18 may include circuitry that functions as a data acquisition tool.
11 In other embodiments, the microcontroller 104 may run applications 106 that may 12 control various devices 46 located downhole. That is, not only may the node 18 be used 13 as a repeater, and as a data gathering device, but may also be used to receive or provide 14 control signals to control selected devices as needed. The node 18 may include a memory device 34 such as a FIFO 34 that may be used to store data needed by or transferred 16 between the modem 40 and the microcontroller 104.
17 Other components of the node 18 may include non-volatile memory 36, which 18 may be used to store data, such as configuration settings, node addresses, system settings, 19 and the like. One or several clocks 102 may be provided to provide clock signals to the modem 40, the microcontroller 104, or any other device. A power supply 52 may receive 21 power from an external power source such as batteries. The power supply 52 may 22 provide power to any or all of the components located within the node 18. Likewise, an 23 RS232 port 38 may be used to provide a serial connection to the node circuit 18.
24 Thus, the node 18 described in Figure 6 may have many more functions than those supplied by a simple signal repeater. The node 18 may provide many of the advantages 26 of an addressable node on a local area network. The addressable node may amplify 27 signals received from uphole 110b or downhole 110a sources, be used as a point of data 1 acquisition, and be used to provide control signals to desired devices 46. These represent 2 only a few examples of the versatility of the node 18. Thus, the node 18, although useful 3 and functional as a repeater 30, may have a greatly expanded capability.
4 Referring to Figure 7, a packet 112 containing data, control signals, network protocols, and the like may be transmitted up and down the drill string. For example, in 6 one embodiment, a packet 112 in accordance with the invention may include training 7 marks 114. Training marks 114 may include any overhead, synchronization, or other data 8 needed to enable another node 18 to receive a particular data packet 112.
9 Likewise, a packet 112 may include one or several synchronization bytes 116.
The synchronization byte 116 or bytes may be used to synchronize the timing of a node 11 18 receiving a packet 112. Likewise, a packet 112 may include a source address 118, 12 identifying the logical or physical address of a transmitting device, and a destination 13 address 120, identifying the logical or physical address of a destination node 18 on a 14 network 17.
A method for synchronizing the timing of a node 18 receiving a packet 112 16 comprises determining a total signal latency between a control device and the node and then sending a synchronizing time from the control device to the node adjusted for the signal latency. Electronic time stamps may be used to measure latency between the control device and the node.
19 A method for triggering an action of the node synchronized to an event else where on the network comprises determining latency, sending a latency adjusted signal, and 21 performing the action. The latency may be determined between a control device located 22 near the surface and the node. The latency adjusted signal for triggering an action is sent 23 to the node and the action is performed downhole synchronized to the event.
An apparatus for fixing computational latency within a deterministic region in a node may comprise a network interface modem, a high priority module and at least one deterministic peripheral device. The network interface modem is in communication with the network. The high priority module is in communication with the network interface 27 modem. The at least one deterministic peripheral device is connected to the high priority 1 module. The high priority module comprises a packet assembler/disassembler, and 2 hardware for performing at least one operation.
3 A packet 112 may also include a command byte 122 or bytes 122 to provide 4 various commands to nodes 18 within the network 17. For example, commands 122 may include commands to set selected parameters, reset registers or other devices, read 6 particular registers, transfer data between registers, put devices in particular modes, 7 acquire status of devices, perform various requests, and the like.
8 Likewise, a packet 112 may include data or information 124 with respect to the 9 length 124 of data transmitted within the packet 112. For example, the data length 124 may be the number of bits or bytes of data carried within the packet 112. The packet 112 may then include data 126 comprising a number of bytes. The data 126 may include data 12 gathered from various sensors or tools located downhole, or may contain control data to 13 control various tools or devices located downhole. Likewise one or several bytes 128 14 may be used to perform error checking of other data or bytes within a packet 112.
Trailing marks 129 may trail other data of a packet 112 and provide any other overhead or 16 synchronization needed after transmitting a packet 112. One of ordinary skill in the art 17 will recognize that network packets 112 may take on many forms and contain varied 18 information. Thus, the example presented herein simply represents one contemplated 19 embodiment in accordance with the invention, and is not intended to limit the scope of the invention.
21 Referring to Figure 8, a module 130 housing the node 18 may include a cylindrical 22 housing 134 defining a central bore 132. The cylindrical housing 134 may be 23 substantially circular, or in other embodiments, may be polygonal. The central bore 132 24 may have a diameter that is slightly smaller than the inner bore diameter of a typical section of drill pipe 16 to accommodate and provide space to components of the node 26 158.
27 Nevertheless, in selected embodiments, as batteries and electronic components 1 become more compact, it is feasible that the central bore 132 of the module 130 could be 2 substantially equal to that normally encountered in sections of drill pipe 16 or other 3 downhole tools 16. The module 130 may be configured for insertion into a host 4 downhole tool 16. Thus, the module 130 may be removed or inserted as needed to access or service components located therein.
6 In selected embodiments, the module 130 may include one or several grooves 136 7 or seal contact surfaces 136 to seal the module 130 within a host downhole tool. Seals 8 inserted into the seal contact surfaces 136 or grooves 136 may prevent fluids such as 9 drilling mud, lubricants, oil, water, and the like from contaminating circuitry or components inside the module 130. Moreover, the entry of other substances such as dirt, 11 rocks, gasses, and the like, may also be prevented.
12 In selected embodiments, the module 130 may include one or several recesses 13 138a-c to house various components contained in the module 130. Selected recesses 138 14 may contain circuitry 158 while others 138 may be used for batteries 154 or other components. One or several channels 141 may be milled or formed into the cylindrical 16 housing 134 to provide for the routing of wires between recesses 138. In selected 17 embodiments, a connector 140 may be used to connect node circuitry 158 to a cable, wire, 18 or other link, traveling up or down the drill string 14.
19 As illustrated, the module 130 may be characterized by a general wall thickness 148. Likewise, in regions proximate recesses 138 or other channels 141, a thinner wall 21 thickness may be present. Nevertheless, a critical wall thickness should be maintained to 22 provide structural reliability to the module 130 to support stresses encountered in a 23 downhole environment. The cylindrical housing 134 may be constructed of any suitable 24 material including steel, aluminum, plastics, and the like, capable of withstanding the pressures, stresses, temperatures, and abrasive nature of a downhole environment.
26 As illustrated, one or several transmission paths 142 may be milled or formed into 27 the wall of the module 130 to provide an outlet for cables, wires, or other transmission I media exiting the recess 138. In selected embodiments, a connector 140 may be provided 2 to simply link up with or connect to node circuitry 158, or in other embodiments, a 3 channel 142a may enable the routing of cables, wires, and the like from a node circuit 4 158, within the recess 1380, to a transmission element 152. A
transmission element 152 may be provided in an annular recess 144 milled or otherwise formed into the end of the 6 cylindrical housing 134.
7 As illustrated, a module 130 is equipped with components or circuitry 158 needed 8 to provide fwactionality to the module 130. For example, batteries 154 connected in 9 series or parallel may be inserted into selected recesses 138 of the module 130. Wires 156 may be routed through channels 141 interconnecting the recesses 138 to connect the 11 batteries 154 together, or to connect the batteries to node circuitry 158.
12 Likewise, node circuitry 158, or components 158, may be located within other 13 recesses 138. As was previously stated, a conductor 160, cable 160, or other transmission 14 media 160, may travel from the node circuitry 158 to a transmission element 152. The transmission dement 152 may transmit energy to another transmission element in contact 16 therewith. The transmission element 152 may have an annular shape and may transmit 17 energy by direct electrical contact, or may convert an electrical current to a magnetic 18 field. The magnetic field may then be detected by another transmission element in close 19 proximity thereto located on a subsequent downhole tool 16.
The scope of the invention is indicated by the appended claims, rather 21 than by the foregoing description. All changes within the meaning and range of 22 equivalency of the claims are to be embraced within their scope.
24 Thus, the node 18 described in Figure 6 may have many more functions than those supplied by a simple signal repeater. The node 18 may provide many of the advantages 26 of an addressable node on a local area network. The addressable node may amplify 27 signals received from uphole 110b or downhole 110a sources, be used as a point of data 1 acquisition, and be used to provide control signals to desired devices 46. These represent 2 only a few examples of the versatility of the node 18. Thus, the node 18, although useful 3 and functional as a repeater 30, may have a greatly expanded capability.
4 Referring to Figure 7, a packet 112 containing data, control signals, network protocols, and the like may be transmitted up and down the drill string. For example, in 6 one embodiment, a packet 112 in accordance with the invention may include training 7 marks 114. Training marks 114 may include any overhead, synchronization, or other data 8 needed to enable another node 18 to receive a particular data packet 112.
9 Likewise, a packet 112 may include one or several synchronization bytes 116.
The synchronization byte 116 or bytes may be used to synchronize the timing of a node 11 18 receiving a packet 112. Likewise, a packet 112 may include a source address 118, 12 identifying the logical or physical address of a transmitting device, and a destination 13 address 120, identifying the logical or physical address of a destination node 18 on a 14 network 17.
A method for synchronizing the timing of a node 18 receiving a packet 112 16 comprises determining a total signal latency between a control device and the node and then sending a synchronizing time from the control device to the node adjusted for the signal latency. Electronic time stamps may be used to measure latency between the control device and the node.
19 A method for triggering an action of the node synchronized to an event else where on the network comprises determining latency, sending a latency adjusted signal, and 21 performing the action. The latency may be determined between a control device located 22 near the surface and the node. The latency adjusted signal for triggering an action is sent 23 to the node and the action is performed downhole synchronized to the event.
An apparatus for fixing computational latency within a deterministic region in a node may comprise a network interface modem, a high priority module and at least one deterministic peripheral device. The network interface modem is in communication with the network. The high priority module is in communication with the network interface 27 modem. The at least one deterministic peripheral device is connected to the high priority 1 module. The high priority module comprises a packet assembler/disassembler, and 2 hardware for performing at least one operation.
3 A packet 112 may also include a command byte 122 or bytes 122 to provide 4 various commands to nodes 18 within the network 17. For example, commands 122 may include commands to set selected parameters, reset registers or other devices, read 6 particular registers, transfer data between registers, put devices in particular modes, 7 acquire status of devices, perform various requests, and the like.
8 Likewise, a packet 112 may include data or information 124 with respect to the 9 length 124 of data transmitted within the packet 112. For example, the data length 124 may be the number of bits or bytes of data carried within the packet 112. The packet 112 may then include data 126 comprising a number of bytes. The data 126 may include data 12 gathered from various sensors or tools located downhole, or may contain control data to 13 control various tools or devices located downhole. Likewise one or several bytes 128 14 may be used to perform error checking of other data or bytes within a packet 112.
Trailing marks 129 may trail other data of a packet 112 and provide any other overhead or 16 synchronization needed after transmitting a packet 112. One of ordinary skill in the art 17 will recognize that network packets 112 may take on many forms and contain varied 18 information. Thus, the example presented herein simply represents one contemplated 19 embodiment in accordance with the invention, and is not intended to limit the scope of the invention.
21 Referring to Figure 8, a module 130 housing the node 18 may include a cylindrical 22 housing 134 defining a central bore 132. The cylindrical housing 134 may be 23 substantially circular, or in other embodiments, may be polygonal. The central bore 132 24 may have a diameter that is slightly smaller than the inner bore diameter of a typical section of drill pipe 16 to accommodate and provide space to components of the node 26 158.
27 Nevertheless, in selected embodiments, as batteries and electronic components 1 become more compact, it is feasible that the central bore 132 of the module 130 could be 2 substantially equal to that normally encountered in sections of drill pipe 16 or other 3 downhole tools 16. The module 130 may be configured for insertion into a host 4 downhole tool 16. Thus, the module 130 may be removed or inserted as needed to access or service components located therein.
6 In selected embodiments, the module 130 may include one or several grooves 136 7 or seal contact surfaces 136 to seal the module 130 within a host downhole tool. Seals 8 inserted into the seal contact surfaces 136 or grooves 136 may prevent fluids such as 9 drilling mud, lubricants, oil, water, and the like from contaminating circuitry or components inside the module 130. Moreover, the entry of other substances such as dirt, 11 rocks, gasses, and the like, may also be prevented.
12 In selected embodiments, the module 130 may include one or several recesses 13 138a-c to house various components contained in the module 130. Selected recesses 138 14 may contain circuitry 158 while others 138 may be used for batteries 154 or other components. One or several channels 141 may be milled or formed into the cylindrical 16 housing 134 to provide for the routing of wires between recesses 138. In selected 17 embodiments, a connector 140 may be used to connect node circuitry 158 to a cable, wire, 18 or other link, traveling up or down the drill string 14.
19 As illustrated, the module 130 may be characterized by a general wall thickness 148. Likewise, in regions proximate recesses 138 or other channels 141, a thinner wall 21 thickness may be present. Nevertheless, a critical wall thickness should be maintained to 22 provide structural reliability to the module 130 to support stresses encountered in a 23 downhole environment. The cylindrical housing 134 may be constructed of any suitable 24 material including steel, aluminum, plastics, and the like, capable of withstanding the pressures, stresses, temperatures, and abrasive nature of a downhole environment.
26 As illustrated, one or several transmission paths 142 may be milled or formed into 27 the wall of the module 130 to provide an outlet for cables, wires, or other transmission I media exiting the recess 138. In selected embodiments, a connector 140 may be provided 2 to simply link up with or connect to node circuitry 158, or in other embodiments, a 3 channel 142a may enable the routing of cables, wires, and the like from a node circuit 4 158, within the recess 1380, to a transmission element 152. A
transmission element 152 may be provided in an annular recess 144 milled or otherwise formed into the end of the 6 cylindrical housing 134.
7 As illustrated, a module 130 is equipped with components or circuitry 158 needed 8 to provide fwactionality to the module 130. For example, batteries 154 connected in 9 series or parallel may be inserted into selected recesses 138 of the module 130. Wires 156 may be routed through channels 141 interconnecting the recesses 138 to connect the 11 batteries 154 together, or to connect the batteries to node circuitry 158.
12 Likewise, node circuitry 158, or components 158, may be located within other 13 recesses 138. As was previously stated, a conductor 160, cable 160, or other transmission 14 media 160, may travel from the node circuitry 158 to a transmission element 152. The transmission dement 152 may transmit energy to another transmission element in contact 16 therewith. The transmission element 152 may have an annular shape and may transmit 17 energy by direct electrical contact, or may convert an electrical current to a magnetic 18 field. The magnetic field may then be detected by another transmission element in close 19 proximity thereto located on a subsequent downhole tool 16.
The scope of the invention is indicated by the appended claims, rather 21 than by the foregoing description. All changes within the meaning and range of 22 equivalency of the claims are to be embraced within their scope.
Claims (20)
1. A downhole network integrated into a drill string comprising a plurality of drill pipes, each of the plurality of pipes having electrically coupled inductive coils at its respective ends, the pipes being connected end-to-end and passing data packets by electromagnetic data communication through the coils;
a bottom-hole node interfacing to a bottom-hole assembly located proximate a bottom end of the drill string;
a top-hole node connected proximate a top end of the drill string;
an intermediate node located along the drill string between the bottom-hole node and the top-hole node, the intermediate node configured to receive and transmit the data packets transmitted between the bottom-hole node and the top-hole node; and a communications link, integrated in the drill string, operably connecting the bottom-hole node to the intermediate node, and the intermediate node to the top-hole node wherein timing of at least two of the nodes is synchronized.
a bottom-hole node interfacing to a bottom-hole assembly located proximate a bottom end of the drill string;
a top-hole node connected proximate a top end of the drill string;
an intermediate node located along the drill string between the bottom-hole node and the top-hole node, the intermediate node configured to receive and transmit the data packets transmitted between the bottom-hole node and the top-hole node; and a communications link, integrated in the drill string, operably connecting the bottom-hole node to the intermediate node, and the intermediate node to the top-hole node wherein timing of at least two of the nodes is synchronized.
2. The downhole network of claim 1, further comprising a personal computer, operably connected to the top-hole node, for analyzing data received from the intermediate and bottom-hole nodes.
3. The downhole network of claim 2, wherein the personal computer comprises a user interface to display data received from the intermediate and bottom-hole nodes.
4. The downhole network of any one of claims 1 to 3, wherein the bottom hole assembly includes a pressure sensor, an inclinometer, a temperature sensor, a thermocoupler, an accelerometer, an imaging device, and/or a seismic device.
5. The downhole network of any one of claims 1 to 4, wherein the intermediate node functions as a repeater.
6. The downhole network of any one of claims 1 to 5, wherein the intermediate node performs at least one task of signal amplification, filtering, error checking, routing, or switching.
7. The downhole network of any one of claims 1 to 6, further comprising a module, housing the intermediate node, insertable at a point along the drill string.
8. The downhole network of any one of claims 1 to 7, wherein the intermediate node is further configured to gather data from at least one of a downhole sensor and a downhole tool, located along the drill string, proximate the intermediate node.
9. The downhole network of any one of claims 1 to 8, wherein at least one of the top-hole node, the intermediate node, and the bottom-hole node is assigned a unique network address.
10. The downhole network of any one of claims 1 to 9, wherein the packets include a source address, identifying the source of a packet, and a destination address, identifying the destination of a packet.
11. The downhole network of any one of claims 1 to 10, wherein the packets carry data originating from at least one of pressure sensors, inclinometers, temperature sensors, thermocouplers, accelerometers, imaging devices, or seismic devices.
12. A method for transmitting information along a drill string, comprising a plurality of drill pipes, each of the plurality of pipes having electrically coupled inductive coils at its respective ends, the pipes being connected end-to-end and passing data packets by electromagnetic data communication through the coils, the method comprising:
transmitting, from a bottom-hole node, a first data packet along a communications link integrated into the drill sting;
receiving, by an intermediate node located at an intermediate location along the drill string;
operably connected to the communications link, the first data packet;
amplifying, by the intermediate node, the first data packet; and forwarding, by the intermediate node, the first data packet to a top-hole node operably connected to the communications link.
transmitting, from a bottom-hole node, a first data packet along a communications link integrated into the drill sting;
receiving, by an intermediate node located at an intermediate location along the drill string;
operably connected to the communications link, the first data packet;
amplifying, by the intermediate node, the first data packet; and forwarding, by the intermediate node, the first data packet to a top-hole node operably connected to the communications link.
13. The method of claim 12, further comprising receiving, by a personal computer, the first data packet from the top-hole node, for analysis.
14. The method of claim 13, wherein the receiving, by a personal computer, further comprises displaying, on a user interface, data received from the intermediate and bottom-hole nodes.
15. The method of any one of claims 12 to 14, further comprising processing, by the intermediate node, the first data packet, wherein processing includes at least one task of filtering, error checking, routing, or switching.
16. The method of any one of claims 12 to 15, further comprising housing the intermediate node in a module insertable at a point along the drill string.
17. The method of any one of claims 12 to 16, wherein at least one of the top-hole node, the intermediate node, and the bottom-hole node is assigned a unique network address.
18. The method of any one of claims 12 to 17, further comprising gathering, by the intermediate node, a second data packet containing data gathered from at least one of a downhole sensor and a downhole tool, located along the drill string, proximate the intermediate node.
19. The method of claim 18, wherein the first and second packets include a source address, identifying the source of the packet, and a destination address, identifying the destination of the packet.
20. The method of claim 18, wherein the first and second data packets carry data originating from at least one of pressure sensors, inclinometers, temperature sensors, thermocouplers, accelerometers, imaging devices, or seismic devices.
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CA2560479A1 (en) | 2005-06-09 |
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