Subterranean oil recovery operations may involve the injection of an aqueous solution into the oil formation to help move the oil through the formation and to maintain the pressure in the reservoir as fluids are being removed. The injected water, either surface water (lake or river) or seawater (for operations offshore) generally contains soluble salts such as sulfates and carbonates. These salts may be incompatible with the ions already contained in the oil-containing reservoir.
The reservoir fluids may contain high concentrations of certain ions that are encountered at much lower levels in normal surface water, such as strontium, barium, zinc and calcium. Partially soluble inorganic salts, such as barium sulfate (or barite) and calcium carbonate, often precipitate from the production water as conditions affecting solubility, such as temperature and pressure, change within the producing well bores and topsides. This is especially prevalent when incompatible waters are encountered such as formation water, seawater, or produced water.
Some mineral scales have the potential to contain naturally occurring radioactive material (NORM). The primary radionuclides contaminating oilfield equipment include Radium-226 (226Ra) and Radium-228 (228Ra), which are formed from the radioactive decay of Uranium-238 (238U) and Thorium-232 (232Th). While 238U and 232Th are found in many underground formations, they are not very soluble in the reservoir fluid. However, the daughter products, 226Ra and 228Ra, are soluble and can migrate as ions into the reservoir fluids to eventually contact the injected water. While these radionuclides do not precipitate directly, they are generally co-precipitated in barium sulfate scale, causing the scale to be mildly radioactive.
Because barium and strontium sulfates are often co-precipitated with radium sulfate to make the scale mildly radioactive, handling difficulties are also encountered in any attempts to remove the scale from the equipment. Unlike common calcium salts, which have inverse solubility, barium sulfate solubility, as well as strontium sulfate solubility, is lowest at low temperatures, and this is particularly problematic in processing in which the temperature of the fluids decreases. Modern extraction techniques often result in drops in the temperature of the produced fluids (water, oil and gas mixtures/emulsions) (as low as by 5 C) and fluids being contained in production tubing for long periods of time (24 hrs or longer), leading to increased levels of scale formation. Because barium sulfate and strontium sulfate form very hard, very insoluble scales that are difficult to prevent, dissolution of sulfate scales is difficult (conventionally requiring high pH, long contact times, heat and circulation).
This summary is provided to introduce a selection of concepts that are further described below in the detailed description. This summary is not intended to identify key or essential features of the claimed subject matter, nor is it intended to be used as an aid in limiting the scope of the claimed subject matter.
In one aspect, embodiments disclosed herein relate to a method of decontaminating naturally occurring radioactive material (NORM) from downhole equipment that includes injecting a NORM dissolver into an isolated region of a wellbore in which NORM-contaminated production equipment is located; and removing the NORM contaminants from the production equipment.
In another aspect, embodiments disclosed herein relate to a method of decontaminating naturally occurring radioactive material (NORM) from downhole equipment that includes isolating NORM-contaminated production equipment from other regions of a wellbore; flushing diesel through the isolated region; injecting a wetting agent into the isolated region to render the NORM-contaminated production equipment water wet; injecting a NORM dissolver into the isolated region; and removing the NORM contaminants from the production equipment.
Other aspects and advantages of the claimed subject matter will be apparent from the following description and the appended claims.
In one aspect, embodiments disclosed herein relate to the in situ treatment of downhole equipment contaminated with NORM. Specifically, embodiments of the present disclosure relate to methods of treating downhole production equipment having NORM-containing scale thereon without retrieval of the equipment to the surface.
Conventionally, mineral scale (not containing NORM) may be treated in place, but occasionally, this scale contaminated tubing and equipment is simply removed and replaced with new equipment. However, when the old equipment is contaminated with NORM, the equipment is conventionally removed from the well and replaced, and the equipment is treated (a costly and hazardous affair) to remove the NORM scale therefrom. At present, a considerable amount of oilfield tubular goods and other equipment awaiting decontamination is sitting in storage facilities. Some equipment, once cleaned, can be reused, while other equipment must be disposed of as scrap. Once removed from the equipment, several options for the disposal of NORM exist, including canister disposal during well abandonment, deep well injection, landfill disposal, and salt cavern injection.
Conventional equipment decontamination processes have included both chemical and mechanical efforts, such as milling, high pressure water jetting, sand blasting, cryogenic immersion, and chemical chelants and solvents, all of which occur on topside, not downhole. Water jetting using pressures in excess of 140 MPa (with and without abrasives) has been the predominant technique used for NORM removal. However, use of high pressure water jetting generally requires that each pipe or piece of equipment be treated individually with significant levels of manual intervention, which is both time consuming and expensive, but sometimes also fails to thoroughly treat the contaminated area. When scale includes NORM, this technique also poses increased exposure risks to workers and the environment.
In contrast, embodiments of the present disclosure involve chemical treatment of the NORM-contaminated equipment downhole without retrieving the equipment to the surface to await a backlog of equipment needing NORM decontamination. However, in other embodiments, the equipment may be retrieved to the surface after the NORM decontamination occurs, in case, for example, the equipment needs to be repaired or replaced for reasons other than the NORM contamination. Though, by treating the equipment in situ prior to retrieving it to the surface, repair or disposal can commence immediately, rather than first waiting for NORM decontamination to occur.
Referring initially to
Pump string 108 extends further into casing 102 and includes a pump assembly 112. Pump assembly 112 may be configured to pump wellbore fluids from upper region 114 of casing 102, up through production tubing 104, and to a surface station above the well. Pump assembly 112 may be constructed as an electric submersible pump that includes an inlet 116 and an outlet 118 in communication with pump string 108. A check valve 119 ensures that fluids (e.g. NORM dissolving chemicals) from production tubing 104 and bypass string 110 will not flow into pump assembly 112 unless desired. Optionally, a sensor package 120 mounted to pump assembly 112 records and reports downhole conditions to a pump controller (not shown) or a surface station. Furthermore, a control and power line 122 extends from pump assembly 112, alongside production tubing 104 to a surface control station. Those having ordinary skill will appreciate that control and power line 122 may vary in construction depending on the pump assembly 112. For example, if pump assembly 112 is pressure driven, control and power line 122 may comprise one or more fluid conduits in communication with a surface pressure source and pump assembly 112.
Bypass string 110 may run alongside pump string 108 inside casing 102 and extend deeper into a production zone 124. Bypass string 110 may include a bypass section 126, an upper fluid gate 128, a packer assembly 130, and a lower fluid gate 132. Upper and lower fluid gates 128, 132 are devices designed to selectively allow and disallow fluids from outside bypass string 110 to communicate with a bore 136 of bypass string 110. Fluid gates 128 and 132 may be constructed as sliding sleeve type devices, but any remotely operable fluid gate devices can be used. Packer 130 may be expanded after production apparatus 100 is delivered to cased wellbore and acts to hydraulically seal off the annulus between bypass string 110 and cased wellbore and divide that annulus into upper 114 and lower regions 138. A plug 140 capable of being set into and retrieved from bypass tubing 110 selectively allows or blocks off direct communication between bypass tubing 110 and production tubing 104. Plug 140 can either be a physical device deployed and retrieved through production tubing 104 from the surface or can be an electrically or hydraulically operable shutoff valve. Furthermore, if plug 140 is a remotely operable valve, it may be configured to allow large diameter items to pass therethrough when open. For example, a remotely operable flapper valve can be used for plug 140.
With both upper and lower fluid gates 128, 132 open, fluid communication between upper and lower regions 114 and 138 is permitted. With upper fluid gate 128 open and lower fluid gate 132 closed, only upper region 114 is in communication with production tubing 104 and pump assembly 112. With upper fluid gate 128 closed and lower fluid gate 132 open, only lower region 138 is in communication with production tubing 104. By selectively manipulating upper fluid gate 128, lower fluid gate 132, and plug 140, numerous operations can be performed on cased wellbore and production zone 124, pump assembly 112, or other production string components without detrimentally effecting other components.
During production, pump assembly 112 pumps production fluids from lower zone 138 adjacent to production zone 124 to a surface location through production tubing 104. To retrieve or produce fluids which have flowed into lower zone 138 below packer 130, upper and lower fluid gates 128, 132 are opened and plug 140 is again re-set in bypass string 110. Pump assembly 112 is then activated and fluids from upper zone 114 are drawn into pump assembly 112 through inlet 116 and pumped up through pump string 108, Y-tool 106, and production tubing 104 to a surface destination. As fluids are removed from upper zone 114 by pump assembly 112, they are replenished by formation fluids entering lower zone 138 through perforations 146. These fluids travel through lower fluid gate 132, across packer 130, and out upper fluid gate 128 to upper zone 114. Because plug 140 prevents bypass string 110 from directly communicating with production tubing 104, pump assembly 112 is able to displace fluids from lower zone 138 to surface location through production tubing 104. Absent plug 140, pump assembly 112 would only circulate fluids between bypass string 110 and upper zone 114.
Further, in one or more embodiments, a work conduit (not shown) extends from within production tubing 104, through Y-tool 106, through bypass string 110, past upper fluid gate 128, through packer 130, and through lower fluid gate 132. Work conduit may be a wireline assembly, capillary tubing, slickline, fiber-optic line, or coiled tubing, etc. Work conduit can be deployed either to take measurements or to perform work operations. Such work operations can include the injection of treatment chemicals, the manipulation of downhole equipment (e.g. valves), and the cleansing of bores of the production apparatus 100. Such measurements can include temperature, pressure, density, and resistivity of downhole fluids.
In one or more embodiments, the system of
Further, while the Y-tool and bypass equipment described in
Referring to
An electric submersible pumping system 26 is suspended below pump string 34. For example, a hydrocarbon-based fluid may flow from formation 30 through perforations 40 and into wellbore 28 adjacent electric submersible pumping system 26. Upon fluids entering wellbore 28, pumping system 26 is able to produce the fluid upwardly through pump string 34, Y-tool 22, and production tubing 20 to wellhead (not shown) and on to a desired collection point.
Although electric submersible pumping system 26 may comprise a wide variety of components, the example in
In addition to a pump assembly, other production equipment that may be treated in accordance with methods of the present disclosure include, but are not limited to, subsurface safety valves, packers, injection mandrels, gas lifts, monitoring equipment, cables, etc.
For example, referring to
Referring now to
Mineral scale that may be effectively removed from oilfield equipment in embodiments disclosed herein includes oilfield scales, such as, for example, salts of alkaline earth metals or other divalent metals, including sulfates of barium, strontium, radium, and calcium, carbonates of calcium, magnesium, and iron, metal sulfides, iron oxide, and magnesium hydroxide. That is, the scale may include NORM, and may also include other mineral scale precipitated therewith. The NORM may also include radioactive plating that has occurred on the production equipment from non-farrous radioactive metals such as Lead 210 and Pollonium 210.
In one or more embodiments, NORM dissolver may include a chelating agent. The chelating agent that may be used in the solution to dissolve the metal scale may be a polydentate chelator so that multiple bonds with the metal ions may be formed in complexing with the metal. Polydentate chelators suitable for use in embodiments disclosed herein include, for example, ethylenediaminetetraacetic acid (EDTA), diethylenetriaminepentaacetic acid (DTPA), nitrilotriacetic acid (NTA), ethyleneglycoltetraacetic acid (EGTA), 1,2-bis(o-aminophenoxy)ethane-N,N,N′,N′-tetraacetic acid (BAPTA), cyclohexanediaminetetraacetic acid (CDTA), triethylenetetraaminehexaacetic acid (TTHA), salts thereof, and mixtures thereof. However, this list is not intended to have any limitation on the chelating agents suitable for use in the embodiments disclosed herein. One of ordinary skill in the art would recognize that selection of the chelating agent may depend on the metal scale to be dissolved. In particular, the selection of the chelating agent may be related to the specificity of the chelating agent to the particular scaling cation, the log K value, the optimum pH for sequestering and the commercial availability of the chelating agent.
In a particular embodiment, the chelating agent used to dissolve metal scale is EDTA, and/or DTPA, or salts thereof. Salts of EDTA and DTPA may include, for example, alkali metal salts and depending on the pH of the dissolving solution different salts or the acid may be present in the solution.
In one or more embodiments, the NORM dissolver may be a metal nitrate (the metal having a lower electronegativity than the contaminants). In a particular embodiment, the NORM dissolver may be zirconium nitrate, which may optionally be used in conjunction with an oxidizing agent such as H2O2.
Further, as mentioned, the NORM dissolver may be preceded by circulation of diesel and/or a wetting agent to render the tool surfaces (and NORM scale) water wet. Further, following the NORM dissolver treatment, a fluid (such as diesel or water) may be flushed through the region to remove the NORM dissolver. The dissolved NORM may be removed from the wellbore either by production or by flushing the material back into the formation (such as by opening the isolation).
Following treatment, a gamma tool may be used to verify that the NORM material has been dissolved and removed from the tool on which it had precipitated. This logging may be compared to a log conducted prior to NORM treatment. Further, after treatment, production of hydrocarbons may resume, though, in some embodiments, it is envisioned that a tool could be replaced (even the tool having been decontaminated) if the tool is not operational for other reasons. However, the downhole treatment of the tool will present fewer risks to the operator and avoid a backlog of equipment topside needing NORM decontamination.
Although only a few example embodiments have been described in detail above, those skilled in the art will readily appreciate that many modifications are possible in the example embodiments without materially departing from this invention. Accordingly, all such modifications are intended to be included within the scope of this disclosure as defined in the following claims. In the claims, means-plus-function clauses are intended to cover the structures described herein as performing the recited function and not only structural equivalents, but also equivalent structures. Thus, although a nail and a screw may not be structural equivalents in that a nail employs a cylindrical surface to secure wooden parts together, whereas a screw employs a helical surface, in the environment of fastening wooden parts, a nail and a screw may be equivalent structures. It is the express intention of the applicant not to invoke 35 U.S.C. § 112, paragraph 6 for any limitations of any of the claims herein, except for those in which the claim expressly uses the words ‘means for’ together with an associated function.
The present application claims priority to U.S. Application Ser. No. 62/325,198, filed Apr. 20, 2016, which is incorporated herein by reference in its entirety
Filing Document | Filing Date | Country | Kind |
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PCT/US2017/028471 | 4/20/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2017/184793 | 10/26/2017 | WO | A |
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Number | Date | Country | |
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20200355047 A1 | Nov 2020 | US |
Number | Date | Country | |
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62325198 | Apr 2016 | US |