US2007044672A1PendingUtilityA1
Methods and systems to activate downhole tools with light
Est. expiryAug 30, 2022(expired)· nominal 20-yr term from priority
Inventors:David R. Smith
F42C 11/00G01V 11/002E21B 23/00F42B 3/113E21B 47/135E21B 43/1185
42
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Claims
Abstract
The present invention comprises a system and methods to actuate downhole tools by transmitting an optical signal through an optical fiber to the downhole tool. The optical signal can comprise a specific optical signal frequency, signal, wavelength or intensity. The downhole tool can comprise packers, perforating guns, flow control valves, such as sleeve valves and ball valves, samplers, sensors, pumps, screens (such as to expand), chemical cutters, plugs, detonators, or nipples.
Claims
exact text as granted — not AI-modified1 - 109 . (canceled)
110 . A system to actuate downhole tools by light, comprising:
a downhole tool adapted to be deployed in a wellbore; an optical transmitter optically connected to the downhole tool through an optical fiber; the optical transmitter adapted to transmit an optical signal through the optical fiber; and wherein the downhole tool is activated in response to reception of the optical signal.
111 . The system of claim 110 , wherein the optical signal comprises a specific number of optical pulses.
112 . The system of claim 111 , wherein the optical signal comprises at least one pulse with a specific time duration.
113 . The system of claim 111 , wherein the optical signal comprises at least one pulse of light at a specific intensity, frequency, wavelength, or amount.
114 . The system of claim 110 , wherein the downhole tool is selected from the group consisting of a packer, a perforating gun, a valve, a sampler, a sensor, a pump, a screen, a chemical cutter, a plug, a detonator, or a nipple.
115 . The system of claim 110 , wherein a receptor receives the optical signal, verifies the optical signal is a valid triggering signal, and subsequently enables the activation of the downhole tool.
116 . The system of claim 115 , wherein:
the receptor comprises a microprocessor, storage, and a controller; the valid triggering signal is stored in the storage; the microprocessor compares the optical signal to the valid triggering signal; and the microprocessor activates the controller when the optical signal matches the stored valid triggering signal.
117 . The system of claim 110 , wherein a plurality of downhole tools are functionally connected to the optical fiber so that each of the downhole tools may be activated in response to the reception of the optical signal.
118 . The system of claim 117 , wherein a different optical signal activates different downhole tools.
119 . The system of claim 117 , further comprising at least one optical filter functionally connected to the optical fiber that allows only light at a specific wavelength to pass therethrough to activate a downhole tool.
120 . The system of claim 117 , further comprising at least one coupler functionally connected to the optical fiber that diverts only light at a specific wavelength towards a downhole tool to activate such downhole tool.
121 . The system of claim 110 , wherein:
the optical signal is received by at least one photodiode; the at least one photodiode converts the optical signal into electrical energy; and the electrical energy is transmitted to an initiator circuit to activate the downhole tool.
122 . The system of claim 110 , wherein:
the optical signal is transmitted into an optically reactive chemical chamber; the chamber contains an optically reactive substance that chemically reacts when subjected to light; and the chemical energy is transferred to activate the downhole tool.
123 . The system of claim 122 , wherein the chamber includes an environment conducive to chemical reaction of the substance to light.
124 . The system of claim 122 , wherein the reaction is one of heating, exploding, or deteriorating.
125 . The system of claim 110 , wherein:
the optical signal is converted into an electrical signal and is then transmitted into a piezoelectric stack that expands when exposed to electrical energy; and the expansion of the stack is used to activate the downhole tool.
126 . The system of claim 110 , further comprising a casing collar locator used to determine the depth of the downhole tool.
127 . A method to actuate downhole tools by light, comprising:
deploying a downhole tool in a wellbore; optically connecting the downhole tool to an optical transmitter through an optical fiber; transmitting an optical signal from the optical transmitter through the optical fiber; activating the downhole tool in response to reception of the optical signal.
128 . The method of claim 127 , wherein the transmitting step comprises transmitting an optical signal including a specific number of optical pulses.
129 . The method of claim 127 , wherein the deploying step comprises deploying the downhole tool as part of a logging system.
130 . The method of claim 127 , wherein the deploying step comprises deploying the downhole tool as part of a permanent completion.
131 . The method of claim 127 , wherein the deploying step comprises deploying the downhole tool as part of a coiled tubing system.
132 . The method of claim 127 , further comprising functionally connecting a plurality of downhole tools to the optical fiber so that each of the downhole tools may be activated in response to the reception of the optical signal.
133 . The method of claim 132 , further comprising functionally connecting at least one optical filter to the optical fiber, the optical filter allowing only light at a specific wavelength to pass therethrough to activate a downhole tool.
134 . The method of claim 132 , further comprising functionally connecting at least one coupler to the optical fiber, the coupler diverting only light at a specific wavelength towards a downhole tool to activate such downhole tool.
135 . The method of claim 127 , further comprising:
receiving the optical signal at an at least one photodiode, the at least one photodiode converting the optical signal into electrical energy; and transmitting the electrical energy to an initiator circuit to activate the downhole tool.
136 . The method of claim 127 , further comprising:
transmitting the optical signal into an optically reactive chemical chamber; providing an optically reactive substance in the chamber that chemically reacts when subjected to light; and transferring the chemical energy to activate the downhole tool.
137 . The method of claim 127 , further comprising:
converting the optical signal into an electrical signal; transmitting the electrical signal into a piezoelectric stack that expands when exposed to electrical energy; and utilizing the expansion of the stack to activate the downhole tool.
138 . The method of claim 127 , further comprising determining the depth of the downhole tool by using a casing collar locator.Cited by (0)
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