1. Field of the Disclosure
The present invention is related to a system, apparatus and method of altering a burn rate of a fuel source in a wellbore, and in particular, a system and apparatus of altering a burn rate of a fuel source for equipment used in a wellbore.
2. Background of the Art
Various downhole operations, such as production, fracturing operations, etc., require downhole fuel sources. In such applications, packers and other setting tools, may be actuated and expanded by combustion of fuel sources. Certain applications may require different burn rates to allow for optimal operation. However, downhole fuel sources that burn at selected rates may have complex formulations and other manufacturing challenges.
In one aspect, the present disclosure provides an apparatus for use in a wellbore, including an apparatus body defining a volume, a propellant disposed within the volume, wherein the propellant has a first burn rate, and at least one propellant insert disposed within the propellant, wherein the propellant insert has a second burn rate, and the second burn rate is different than the first burn rate.
In another aspect, the present disclosure provides a system for use in a wellbore, including a tool, and a fuel source associated with the tool, the fuel source including a fuel source body defining a volume, a propellant disposed within the volume, wherein the propellant has a first burn rate, and at least one propellant insert disposed within the propellant, wherein the propellant insert has a second burn rate, and the second burn rate is different than the first burn rate.
Examples of certain features of the apparatus and method disclosed herein are summarized rather broadly in order that the detailed description thereof that follows may be better understood. There are, of course, additional features of the apparatus and method disclosed hereinafter that will form the subject of the claims appended hereto.
The disclosure herein is best understood with reference to the accompanying figures in which like numerals have generally been assigned to like elements and in which:
The tool 108 is schematically illustrated in
Fuel source 150 may be used to actuate tool 108. In exemplary embodiments, fuel source 150 may be a multi-stage charge or a single stage charge. Details of the fuel source are discussed below with respect to
In the illustrated embodiment, the fuel source 250 is contained within the body 262. In the illustrated embodiment, the body 262 defines a volume 264 that contains the propellant 270. The body 262 can be formed from a polymeric material, cellulosic material or any other suitable material. In certain embodiments, the body 262 is formed from a cardboard material. In the illustrated embodiment, the body 262 can include a cap 266 to enclose the volume 264.
In the illustrated embodiment, the propellant 270 is contained within the volume 264. The propellant 270 is an energetic material that can release energy and gasses upon activation. The propellant 270 can be a slurry or dough that is disposed within the volume 264. In the illustrated embodiment, the propellant 270 can include a mixture including, but not limited to a mixture of the following chemical components: gilsonite resin, strontium nitrate, diatomaceous earth, toluene, hydroxyl-terminated polybutadiene, polyurethane resins, potassium nitrate, and polyesters such as dioctyl adipate.
In the illustrated embodiment, the propellant 270 has an inherent burn rate based on the chemical properties of the propellant 270 selected. In certain applications, it is desired to alter the inherent burn rate of the propellant 270 to allow for a faster burn rate or a slower burn rate. A faster burn rate can allow for a peak pressure to be applied to the tool 108 for a shorter time period, while a slower burn rate can allow for a peak pressure to be applied to a tool 108 for a longer time period.
In the illustrated embodiment, propellant inserts 280 are disposed within the volume 264 to alter the inherent burn rate of the propellant 270. The propellant inserts 280 can alter the burn rate of the propellant 270 by creating divided volumes 281 and further burning at a different rate from the propellant 270 to create an effective altered burn rate of the fuel source 250.
In certain embodiments, propellant inserts 280 are disposed within the volume 264 to create divided volumes 281. In the illustrated embodiment, propellant 270 is disposed within the divided volumes 281. By locating the propellant 270 in divided volumes 281, portions of the propellant 270 are burned in discrete time intervals. This can allow for a desired pressure output over a desired time interval. By disposing the propellant 270 within the divided volumes 281, the natural burn rate of the propellant 270 is altered to be accelerated or decelerated depending on the desired burn rate.
In certain embodiments, the chemical composition and inherent burn rate of the propellant inserts 280 can be utilized to slow the effective burn rate of the fuel source 250. In the illustrated embodiment, slow burning propellant inserts 280 can be formed from cannon fuse material, including, but not limited to slow match, punks, black match, quick match, visco fuse, safety fuse, paper, rope, etc. In certain embodiments, the propellant insert 280 is formed from waxed or lacquered paper containing fine black powder. In other embodiments, the propellant inserts 280 can be formed from oxamide, melamine, azodicarbonamide and derivatives thereof.
In certain embodiments, these propellant inserts 280 have a burn rate that is slower than the propellant 270. Therefore, in certain embodiments, as the propellant 270 in a single divided volume 281 is burned, the propellant insert 280 is then burned to expose the propellant 270 in the next divided volume 281. In the illustrated embodiment, by selectively exposing the propellant 270 via the propellant inserts 280, stepwise or otherwise more controlled pressure output is achieved by ignition of the fuel source 250. In certain embodiments, the fuel source 250 can provide a desired pressure characteristic over 4 minutes.
In certain embodiments, propellant inserts 280 that slow the burn rate of the propellant 270 can be utilized in tools such as composite plugs or elastomeric packers to provide a controlled pressure build up to allow for proper setting without causing damage to the tool. Advantageously, by slowing the burn rate of the propellant 270 via propellant inserts 280, propellants 270 do not need to be chemically altered or substituted to provide a desired pressure release characteristic. In certain embodiments, slow burning propellants are often complex and difficult to manufacture, store and transport. Advantageously, by using propellant inserts 280 more readily available propellants 270 can be utilized with a desired burn rate.
In certain embodiments, the chemical composition and inherent burn rate of the propellant inserts 280 can be utilized to accelerate the effective burn rate of the fuel source 250. In certain embodiments fast burning propellant inserts 280 can be formed from 5-aminotetrazole, potassium perchlorate, sulphur, carbon, or any other suitable fuse material. These fast burning propellant inserts 280 can decompose into hot gasses, including oxygen that accelerate the burn rate of the propellant 270 accelerating the burn rate of the fuel source 250. In certain embodiments, the fuel source can provide a desired pressure characteristic in less than 10 seconds. Advantageously, by utilizing the propellant inserts 280 described herein materials which require special handling, transportation, storage and export control requirements can be avoided.
Referring to
In the illustrated embodiment, the barriers 368 are formed from a same or similar material as the remainder of the body 362. In certain embodiments, the barriers 368 are polymeric discs to divide the volume 364 as previously described. In the illustrated embodiment, the divided volumes 381 can alter the burn rate of the propellant 370 as previously described.
In the illustrated embodiment, the vertically disposed propellant insert 382 is disposed within the propellant 370. In the illustrated embodiment, the vertically disposed propellant insert 382 can ignite the propellant 370 within each divided volume 381 and propagate ignition to each divided volume 381. In the illustrated embodiment, the vertically disposed propellant insert 382 can be utilized to ensure that ignition is achieved in all divided volumes 281. In the illustrated embodiment, by selectively exposing the propellant 370 by the controlled ignition of the vertically disposed propellant insert 382, stepwise or otherwise more controlled pressure output is achieved by ignition of the fuel source 350.
Referring to
In the illustrated embodiment, the vertically disposed propellant insert 482 is disposed within the propellant 470. In certain embodiments, the vertically disposed propellant insert 482 can be at least one wire, screen or foil. In certain embodiments, the vertically disposed propellant insert 482 is formed from a conducting metal, including, but not limited to copper. In the illustrated embodiment, the vertically disposed propellant insert 482 can ignite the propellant 470 and propagate ignition within the volume 464. In the illustrated embodiment, the vertically disposed propellant insert 482 can be utilized to ensure that complete ignition is achieved. In the illustrated embodiment, by exposing the propellant 470 to the ignition of the vertically disposed propellant insert 482 the effective burn rate of the propellant 470 can be accelerated.
Therefore in one aspect, the present disclosure provides an apparatus for use in a wellbore, including an apparatus body defining a volume, a propellant disposed within the volume, wherein the propellant has a first burn rate, and at least one propellant insert disposed within the propellant, wherein the propellant insert has a second burn rate, and the second burn rate is different than the first burn rate. In various embodiments, the apparatus body is polymeric. In various embodiments, the propellant is at least one of potassium perchlorate, gilsonite resin, strontium nitrate, diatomaceous earth, and toluene. In various embodiments, the volume includes a plurality of divided volumes. In various embodiments, the plurality of divided volumes is defined by at least one polymeric barrier within the apparatus body. In various embodiments, the plurality of divided volumes is defined by the at least one propellant insert. In various embodiments, the at least one propellant insert is vertically disposed within the apparatus body. In various embodiments, the second burn rate is slower than the first burn rate. In various embodiments, the propellant insert is at least one of slow match, punks, black match, quick match, visco fuse, safety fuse, paper and rope. In various embodiments, the second burn rate is faster than the first burn rate. In various embodiments, the propellant insert is at least one of 5-aminotetrazole and azodicarbonamide.
In another aspect, the present disclosure provides a system for use in a wellbore, including a tool, and a fuel source associated with the tool, the fuel source including a fuel source body defining a volume, a propellant disposed within the volume, wherein the propellant has a first burn rate, and at least one propellant insert disposed within the propellant, wherein the propellant insert has a second burn rate, and the second burn rate is different than the first burn rate. In various embodiments, the apparatus body is polymeric. In various embodiments, the propellant is at least one of potassium perchlorate, gilsonite resin, strontium nitrate, diatomaceous earth, and toluene. In various embodiments, the volume includes a plurality of divided volumes. In various embodiments, the plurality of divided volumes is defined by at least one polymeric barrier within the apparatus body. In various embodiments, the plurality of divided volumes is defined by the at least one propellant insert. In various embodiments, the at least one propellant insert is vertically disposed within the apparatus body. In various embodiments, the second burn rate is slower than the first burn rate. In various embodiments, the second burn rate is faster than the first burn rate.
While the foregoing disclosure is directed to the certain exemplary embodiments of the disclosure, various modifications will be apparent to those skilled in the art. It is intended that all variations within the scope and spirit of the appended claims be embraced by the foregoing disclosure.
Number | Name | Date | Kind |
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5396951 | Ross | Mar 1995 | A |
20160053561 | Carr | Feb 2016 | A1 |
20160258242 | Hayter | Sep 2016 | A1 |
Number | Date | Country | |
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20180120066 A1 | May 2018 | US |