WO2024097211A1 - Extraction de brome et de lithium à partir de sources aqueuses - Google Patents

Extraction de brome et de lithium à partir de sources aqueuses Download PDF

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Publication number
WO2024097211A1
WO2024097211A1 PCT/US2023/036452 US2023036452W WO2024097211A1 WO 2024097211 A1 WO2024097211 A1 WO 2024097211A1 US 2023036452 W US2023036452 W US 2023036452W WO 2024097211 A1 WO2024097211 A1 WO 2024097211A1
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Prior art keywords
lithium
stream
ions
aqueous
bromide
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PCT/US2023/036452
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English (en)
Inventor
Dominic Perroni
Florence Binet
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Schlumberger Technology Corporation
Schlumberger Canada Limited
Services Petroliers Schlumberger
Schlumberger Technology B.V.
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Priority claimed from US18/328,048 external-priority patent/US20240025767A1/en
Application filed by Schlumberger Technology Corporation, Schlumberger Canada Limited, Services Petroliers Schlumberger, Schlumberger Technology B.V. filed Critical Schlumberger Technology Corporation
Publication of WO2024097211A1 publication Critical patent/WO2024097211A1/fr

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    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22BPRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
    • C22B26/00Obtaining alkali, alkaline earth metals or magnesium
    • C22B26/10Obtaining alkali metals
    • C22B26/12Obtaining lithium
    • CCHEMISTRY; METALLURGY
    • C01INORGANIC CHEMISTRY
    • C01BNON-METALLIC ELEMENTS; COMPOUNDS THEREOF; METALLOIDS OR COMPOUNDS THEREOF NOT COVERED BY SUBCLASS C01C
    • C01B7/00Halogens; Halogen acids
    • C01B7/09Bromine; Hydrogen bromide
    • C01B7/096Bromine
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    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02F9/00Multistage treatment of water, waste water or sewage
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22BPRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
    • C22B3/00Extraction of metal compounds from ores or concentrates by wet processes
    • C22B3/20Treatment or purification of solutions, e.g. obtained by leaching
    • C22B3/22Treatment or purification of solutions, e.g. obtained by leaching by physical processes, e.g. by filtration, by magnetic means, or by thermal decomposition
    • C22B3/24Treatment or purification of solutions, e.g. obtained by leaching by physical processes, e.g. by filtration, by magnetic means, or by thermal decomposition by adsorption on solid substances, e.g. by extraction with solid resins
    • CCHEMISTRY; METALLURGY
    • C25ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
    • C25BELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
    • C25B1/00Electrolytic production of inorganic compounds or non-metals
    • C25B1/01Products
    • C25B1/18Alkaline earth metal compounds or magnesium compounds
    • C25B1/20Hydroxides
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    • C25ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
    • C25BELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
    • C25B1/00Electrolytic production of inorganic compounds or non-metals
    • C25B1/01Products
    • C25B1/24Halogens or compounds thereof
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    • C25ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
    • C25BELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
    • C25B1/00Electrolytic production of inorganic compounds or non-metals
    • C25B1/01Products
    • C25B1/24Halogens or compounds thereof
    • C25B1/26Chlorine; Compounds thereof
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D15/00Separating processes involving the treatment of liquids with solid sorbents; Apparatus therefor
    • B01D15/08Selective adsorption, e.g. chromatography
    • B01D15/10Selective adsorption, e.g. chromatography characterised by constructional or operational features
    • B01D15/18Selective adsorption, e.g. chromatography characterised by constructional or operational features relating to flow patterns
    • B01D15/1807Selective adsorption, e.g. chromatography characterised by constructional or operational features relating to flow patterns using counter-currents, e.g. fluidised beds
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    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02F1/00Treatment of water, waste water, or sewage
    • C02F1/02Treatment of water, waste water, or sewage by heating
    • C02F1/04Treatment of water, waste water, or sewage by heating by distillation or evaporation
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    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
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    • C02F1/00Treatment of water, waste water, or sewage
    • C02F1/20Treatment of water, waste water, or sewage by degassing, i.e. liberation of dissolved gases
    • CCHEMISTRY; METALLURGY
    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02F1/00Treatment of water, waste water, or sewage
    • C02F1/28Treatment of water, waste water, or sewage by sorption
    • C02F1/281Treatment of water, waste water, or sewage by sorption using inorganic sorbents
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    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
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    • C02F1/38Treatment of water, waste water, or sewage by centrifugal separation
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    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
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    • C02F1/42Treatment of water, waste water, or sewage by ion-exchange
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    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
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    • C02F1/00Treatment of water, waste water, or sewage
    • C02F1/44Treatment of water, waste water, or sewage by dialysis, osmosis or reverse osmosis
    • C02F1/441Treatment of water, waste water, or sewage by dialysis, osmosis or reverse osmosis by reverse osmosis
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    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02F1/00Treatment of water, waste water, or sewage
    • C02F1/46Treatment of water, waste water, or sewage by electrochemical methods
    • C02F1/461Treatment of water, waste water, or sewage by electrochemical methods by electrolysis
    • C02F1/467Treatment of water, waste water, or sewage by electrochemical methods by electrolysis by electrochemical disinfection; by electrooxydation or by electroreduction
    • C02F1/4672Treatment of water, waste water, or sewage by electrochemical methods by electrolysis by electrochemical disinfection; by electrooxydation or by electroreduction by electrooxydation
    • C02F1/4674Treatment of water, waste water, or sewage by electrochemical methods by electrolysis by electrochemical disinfection; by electrooxydation or by electroreduction by electrooxydation with halogen or compound of halogens, e.g. chlorine, bromine
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    • C02F1/46Treatment of water, waste water, or sewage by electrochemical methods
    • C02F1/469Treatment of water, waste water, or sewage by electrochemical methods by electrochemical separation, e.g. by electro-osmosis, electrodialysis, electrophoresis
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    • C02F1/00Treatment of water, waste water, or sewage
    • C02F1/72Treatment of water, waste water, or sewage by oxidation
    • C02F1/76Treatment of water, waste water, or sewage by oxidation with halogens or compounds of halogens
    • C02F1/763Devices for the addition of such compounds in gaseous form
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    • C02F2001/425Treatment of water, waste water, or sewage by ion-exchange using cation exchangers
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    • C02F2101/101Sulfur compounds
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    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
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    • C02F2101/20Heavy metals or heavy metal compounds
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    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
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    • C02F2101/30Organic compounds
    • C02F2101/32Hydrocarbons, e.g. oil
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    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02F2103/00Nature of the water, waste water, sewage or sludge to be treated
    • C02F2103/10Nature of the water, waste water, sewage or sludge to be treated from quarries or from mining activities
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    • C02TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02FTREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
    • C02F2201/00Apparatus for treatment of water, waste water or sewage
    • C02F2201/46Apparatus for electrochemical processes
    • C02F2201/461Electrolysis apparatus
    • C02F2201/46105Details relating to the electrolytic devices
    • C02F2201/46115Electrolytic cell with membranes or diaphragms

Definitions

  • This patent application relates to recovering metal ions, such as lithium, from an aqueous source, such as brine. Specifically, this patent application describes processes for direct aqueous extraction of ions that use methods of removing hydrocarbon and/or sulfide species, and also recovering bromine.
  • Lithium is a key element in energy storage. Electrical storage devices, such as batteries, supercapacitors, and other devices commonly use lithium to mediate the storage and release of chemical potential energy as electrical current. As demand for renewable, but non-transportable, energy sources such as solar and wind energy grows, demand for technologies to store energy generated using such sources also grows.
  • ions can be sourced from aqueous materials present at or near the surface of the earth. Ions such as lithium, manganese, nickel, cobalt, and others can be extracted using direct aqueous extraction. Aqueous materials subjected to such extraction can have different compositions that include various critical ions, as well as different contaminants. Some aqueous materials, for instance brines from the Smackover field and brine that has undergone prior bromine production, may include sulfides and/or hydrocarbons/organics, which are typically undesirable for efficient extraction using direct aqueous processes.
  • Bromine is a halogen element that is used mostly to manufacture flame retardant chemicals.
  • the market for bromine is forecast, by one estimate, to grow at more than 4% per year over the next five years. Efficient and effective ways of recovering lithium and bromine, and removing impurities such as sulfides and organic compounds, are needed.
  • Embodiments described herein provide a method, comprising generating chlorine gas in a conversion process that converts metal chloride from an aqueous medium obtained from a metal containing aqueous source into a hydroxide material; recovering the chlorine gas; and recovering bromine by reacting the chlorine gas with a bromide containing aqueous source.
  • FIG. 1 Another embodiments described herein provide a method, comprising reducing a concentration of at least one or more of sulfide species, transition metal ions, organic species, from an aqueous source comprising lithium ions and bromide ions; reacting a stream derived from the aqueous source with a chlorine gas stream to form bromine and a bromide depleted aqueous stream; extracting lithium ions from the stream resulting from removing organic species from the bromide depleted aqueous stream, using a direct extraction process, to form a lithium extract; and converting lithium of the lithium extract to lithium hydroxide in an electrochemical process that uses a lithium selective barrier to form the chlorine gas stream.
  • Fig. 1 is a schematic process diagram of a lithium and bromine recovery process according to one embodiment.
  • Fig. 2 is a schematic process diagram of a process for removing hydrocarbons and/or other organic species from an aqueous stream, according to one embodiment.
  • FIG. 3 is a schematic process diagram summarizing a method according to another embodiment.
  • Fig. 4 is a schematic process diagram of an ion recovery process according to another embodiment. DETAILED DESCRIPTION
  • Lithium can be recovered from an aqueous source bearing lithium ions by extraction and concentration methods. Most such aqueous streams also contain chloride ions and bromide ions. Extraction methods generally yield an aqueous stream with increased concentration of lithium ions and chloride ions by selectively withdrawing lithium ions from the aqueous source and re-dissolving them in an aqueous stream at a selected concentration. Concentration methods remove water, potentially with other species, to yield higher concentration of lithium and chloride ions.
  • Concentrated lithium bearing aqueous streams can be subjected to a membrane electrochemical process to convert lithium to lithium hydroxide, generating chlorine gas from the chloride ions in the aqueous stream.
  • the chlorine gas can be contacted with the aqueous source to recover bromine from the aqueous source. Additionally, the chlorine gas can be contacted with the aqueous source to remove sulfide species from the aqueous source.
  • Fig. 1 is a schematic process diagram of a lithium and bromine recovery process 100 according to one embodiment.
  • An aqueous source 102 that contains lithium ions, chloride ions, and bromide ions is routed to an extraction stage 104 where lithium is extracted by a withdrawal process.
  • the aqueous source 102 is contacted with a lithium selective medium, which may be solid or liquid or semi-solid fluid or gel.
  • a lithium selective medium which may be solid or liquid or semi-solid fluid or gel.
  • An example of such medium for lithium ions is a Lithium Aluminum Intercalate (LAI) sorbent but any known medium for removing a specific target ion may be used.
  • LAI Lithium Aluminum Intercalate
  • the lithium selective medium withdraws lithium ions, with or without withdrawing anions, such as chloride ions or other anions, depending on the medium, from the aqueous source 102 which is returned to the environment depleted of lithium (/.e. lithium depleted stream).
  • the withdrawal process may be an adsorption/desorption process such as a counter-current adsorption/desorption.
  • the lithium selective medium is a solid
  • the lithium selective medium, loaded with lithium ions withdrawn from the aqueous source 102 is contacted with an aqueous eluent 106, which unloads the lithium ions from the lithium selective medium to yield a lithium extract 108.
  • the lithium selective medium is a liquid
  • the lithium selective medium loaded with lithium ions withdrawn from the aqueous source 102
  • the medium is a liquid
  • a separate lithium unloading vessel may be used as part of the extraction stage to contact the loaded medium with the eluent.
  • the medium is a solid ion withdrawal material (such as metal oxide, metal hydroxide or such material mixed with a resin)
  • the medium may be stationary or fluidized within the vessel, or conveyed through one or more vessels or zones for contacting with the brine, for example in a counter-current format.
  • the medium may be contained in a plurality of vessels in flow communication with one another and the vessels may be fluidly connected with a plurality of zones (ie inlets/outlets) during the extraction process.
  • the extraction may therefore take place continuously, for instance loading resin in a first vessel with lithium by fluidly connecting this vessel with the brine source while unloading resin in a second vessel by fluidly connecting the second vessel with the eluent and washing a third vessel using a strip solution.
  • the extraction may be a continuous counter-current adsorption desorption (CCAD) process.
  • CCAD counter-current adsorption desorption
  • the extraction stage 104 yields an aqueous lithium extract 108 and a lithium depleted stream 110. Because the extraction stage 104 uses a lithium selective medium, impurities such as sodium, magnesium, and calcium remain in the lithium depleted stream 110.
  • the extract may have an arbitrary concentration of ions, up to the solubility limit of the ions, depending on how much eluent is used to contact the loaded withdrawal medium.
  • Flow rate of the eluent can be used to target a concentration of target ions (such a lithium) in the extract.
  • flow rate of the eluent can be set based on flow rate of aqueous material contacted with the withdrawal material.
  • the extraction stage that has been described hereinabove is performed using a ion withdrawal method but may include any techniques that extract lithium material directly from brines, and may include solvent extraction techniques and/or ion withdrawal, such as ion exchange and/or adsorption/desorption techniques.
  • Direct lithium extraction, or direct extraction of other critical ions may also be performed using an electrical separation process that employs a selective membrane. Direct extraction using the processes described herein can also recover nickel, cobalt, manganese, copper, potassium, iron and other ions.
  • aqueous ion containing stream ie aqueous source
  • an aqueous recovery material is disposed in a second volume contacting a second side of the membrane, opposite from the first side.
  • An electric field is established within the first and second volumes across the membrane to drive ion transport.
  • Selectivity of the membrane results in an aqueous stream having the ions of choice concentrated with respect to, or entirely separated from, other ions.
  • the lithium extract 108 is routed to a conversion stage 109 to convert lithium in the lithium extract 108 to lithium hydroxide.
  • the conversion stage 109 has a vessel 120 that contains a barrier 122, such as a membrane or diaphragm, which may be selective for lithium, and which separates the vessel 120 into a first volume 124 and a second volume 126.
  • a barrier 122 such as a membrane or diaphragm, which may be selective for lithium, and which separates the vessel 120 into a first volume 124 and a second volume 126.
  • the barrier 122 is a membrane
  • the membrane typically allows solutes to pass through more than water so little water passes through the membrane.
  • the barrier 122 is a diaphragm
  • the diaphragm typically allows more water to pass through than does a membrane.
  • the barrier 122 can be selective for lithium such that lithium is allowed to pass through at a higher rate or quantity than other species.
  • the membrane may be permselective.
  • the diaphragm may be microporous.
  • a cathode 130 is disposed in the first volume 124 and an anode 128 is disposed in the second volume 126.
  • the anode 128 and the cathode 130 are connected to an electric potential 131 to create a voltage within the vessel 120.
  • the lithium extract 108 is routed to the first volume 124, and a water stream 132 is routed to the second volume 126.
  • the powered cathode 130 oxidizes chloride ions to chlorine gas within the first volume 124.
  • the chlorine gas is collected at a first gas outlet 134 of the vessel 120. Lithium ions penetrate the barrier 122, selectively if the barrier is selective for lithium, traveling from the first volume 124 to the second volume 126.
  • the powered anode 128 electrolyzes water to protons and hydroxyl ions.
  • the hydroxyl ions react with the lithium ions in the second volume 126 to form lithium hydroxide which eventually precipitates within the second volume 126.
  • Hydrogen ions join to form hydrogen gas (H2), which is collected at a second gas outlet 136 of the vessel.
  • the hydrogen gas can be used for any suitable purpose. In one embodiment, the hydrogen gas can contribute to power generation for the process 100 to maximize energy efficiency.
  • Voltage applied to the materials in the vessel 120, and composition and residence time of the materials in the first volume 124 and the second volume 126 can be adjusted to control the rate of conversion of lithium ions to lithium hydroxide.
  • the rate at which the barrier 122 passes lithium ions depends on properties of the barrier 122 but also composition of the lithium extract 108 in the first volume 124 and the second volume 126. Larger concentration gradient of lithium ions across the barrier 122 boosts transport rate of lithium ions. Slower flow rate of the lithium extract 108 into the first volume 124 provides more time for lithium ions to migrate across the barrier 122, which tends to lower the concentration of lithium ions in the first volume 124. Larger electric potential tends to provide more hydroxyl ions to react with lithium ions, generally lowering the concentration of lithium ions in the second volume 126 and supporting an elevated rate of lithium transport across the barrier 122.
  • a lithium and chloride depleted aqueous stream 138 is withdrawn at a first liquid outlet 140 of the vessel and a lithium hydroxide material 142 is withdrawn at a second liquid outlet 144 of the vessel 120.
  • the lithium and chloride depleted aqueous stream 138 can optionally be returned to the extraction stage 104 for use as the eluent 106, or a portion thereof, in a recycle eluent 146. Some or all of the recycle eluent 146 can be recycled into the lithium extract 108, instead of being recycled to the extraction stage 104.
  • the conversion stage 109 converts lithium ions, in solution with mostly chloride ions, into lithium hydroxide.
  • the lithium hydroxide stream 142 is typically a solution of lithium hydroxide in an aqueous medium that bears some dissolved lithium hydroxide.
  • the lithium hydroxide material 142 can be routed to uses suitable for such a product, such as battery manufacturing. If desired, water can be removed from the lithium hydroxide material 142, by evaporation, membrane separation, or other convenient process, in a water removal stage 150 to yield a solid or paste lithium hydroxide product 154.
  • the removed water 152 can be routed to the extraction stage 104 to be used with, or as, the eluent 106, optionally along with the recycle eluent 146.
  • An optional concentration stage (not shown) can be used between the extraction stage 104 and the conversion stage 109 to increase concentration of lithium and chloride provided to the conversion stage 109.
  • the concentration stage can remove water from the lithium extract 108, for example by evaporation or membrane separation such as counter-flow reverse osmosis, either of which may utilize lithium selection techniques such as lithium selective membranes, use of ion separation media such as lithium selective beads, particles, or gels, solids removal, precipitation, or a combination thereof, to form a lithium concentrate that is routed to the conversion stage 109.
  • Water removed from the lithium extract 108 can be recycled to the extraction stage 104 in a manner similar to recycling of the lithium and chloride depleted aqueous stream 138.
  • a membrane separation operation used in a concentration stage can include a reverse osmosis process, a counter-flow reverse osmosis process, or both to produce the concentrate and a diluted stream.
  • the diluted stream may be used in other parts of the process such as the extraction stage.
  • the diluted stream may be for instance used as eluent in the extraction stage. Recycling useful aqueous streams generally limits the need to use fresh water at various stages of the process.
  • the concentration stage is typically configured to produce a concentrate having TDS (total dissolved solids) of at least 100,000 mg/l, such as 100,000 - 200,000 mg/l, for example 120,000 mg/l.
  • TDS in the concentrate may be over 200,000 mg/l.
  • the concentration stage may be configured to produce a concentrate having lower TDS, for example as low as 35,000 mg/l. Any configuration can be used to produce a concentrate having TDS from 35,000 to 200,000 mg/l.
  • Counter-flow reverse osmosis is a separation process that uses multiple stages of separation medium to accomplish stagewise separation of ions from water in an aqueous medium.
  • Each stage has a separation medium, which can be any of the media described above, in any of the physical configurations described above, many of which are known.
  • the concentrated output of one stage, produced by separation of ions, penetration of water through a barrier, or other separation process, is routed to the next stage in a first direction.
  • the remaining stream which is diluted with respect to a target ion, is routed to the next stage in a second direction opposite from the first direction.
  • the progressively concentrated streams flow in a concentration direction through the process and the progressively diluted streams flow in a dilution direction through the process.
  • An optional impurity removal stage (not shown) can be used between the extraction stage 104 and the conversion stage 109, in order to reduce the quantity of species other than lithium in the lithium extract and/or concentrate.
  • Such impurity removal stage may include removal of transition metals, silica, and/or divalent ions such as calcium, magnesium, aluminum, manganese or iron, to the extent such ions are not target ions for recovery.
  • the impurity removal stage can be before or after the concentration stage or the extraction stage, and may use any suitable chemical or physical method, depending on the nature of the impurities to be removed. Methods such as chemical reaction, precipitation (via concentration or coagulation-flocculation), solids removal, ion exchange, filtration, digestion, and any combination thereof, can be used.
  • the method may also include optional concentration and/or impurity removal before the extraction stage 104, as will be for instance described in more details in relationship with Fig. 2.
  • chlorine gas is collected at the outlet 134 of the conversion stage into a chlorine gas stream 112.
  • the chlorine gas is contacted with the lithium depleted stream 110 in a bromine production stage 114, where chlorine is reduced to chloride ions and bromide ions are oxidized to elemental bromine (Br2).
  • Chlorine gas for the bromine production stage 114 may be entirely sourced from the conversion stage 109 or other gases may be mixed with the chlorine gas from the conversion stage 109 to make the chlorine gas stream 112.
  • chlorine gas from another source may be added to the chlorine gas stream 112 to adjust the amount of chlorine gas in the chlorine gas stream 112.
  • a gas that is not reactive in the process 100 for example nitrogen gas or carbon dioxide, can be added to the chlorine gas stream 112 to adjust the total flow rate of the chlorine gas stream 112.
  • the bromine production stage 114 may include a vessel 116 in the lithium depleted stream 110 is contacted with the chlorine gas stream 112.
  • the vessel can be a container like a tank or drum with inlet and outlet flow ports, or the vessel can be a pipe. Mixing can be applied, if desired, using any mixing process or equipment, such as a powered agitator for a tank or drum or an in-line mixer (static or dynamic) for a pipe reactor.
  • the bromine production stage 114 can be operated at a temperature above the boiling point of bromine to provide easy separation of bromine gas from the liquid contents of the bromine production stage 114. Where the vessel 116 is a tank, a vapor space can be maintained inside the vessel 116 to support removal of bromine gas from the vessel 116.
  • the bromine gas is removed from the vessel in a bromine stream 118.
  • the bromine stream 118 may be removed from a high point of the vessel 116, or since brom ine gas is relatively dense from a location below the high point of the vessel 116 that does not risk entraining liquid from the vessel 116 with the bromine gas.
  • the bromine gas can be condensed such that the bromine stream 118 is a liquid material. Since bromine is only slightly soluble in most aqueous media, any co-condensed materials are likely to be immiscible with liquid bromine so that the condensed liquid bromine can be withdrawn as a separate liquid phase.
  • the bromine production stage 114 may include additional vessels and treatments, for example to purify bromine recovered from the vessel 116 or to convert the recovered bromine into a solid product such as sodium bromide.
  • Purification of bromine gas can include condensing the bromine gas and separating liquid phases to remove water or other impurities.
  • Conversion of bromine into a solid bromide product typically includes adding a redox reagent to reduce the bromine to bromide ions, potentially using cations likely to precipitate bromide.
  • Sodium salts such as sodium sulfate can be used.
  • Lithium hydroxide from the conversion stage 109 can also be reacted with the bromine gas to form solid lithium bromide.
  • An aqueous lithium and bromide depleted stream 119 is removed from the bromine production stage 114.
  • the lithium and bromide depleted stream 119 comprises mainly metal cations such as sodium, potassium, calcium, and magnesium, along with chloride anions and trace other components.
  • the process 100 uses, as general inputs, an aqueous stream comprising lithium ions and bromide ions, water stream 132, and eluent 106, which can be water or a dilute solution of lithium or other ions.
  • total ions concentration total dissolved solids, or “TDS”
  • concentration of chloride ions may be lower as well.
  • the process 100 uses power to generate an electric potential difference in the vessel 120 of the conversion stage 109.
  • the hydrogen gas stream withdrawn from the conversion stage 109 may be used to generate power for the conversion stage 109 to increase energy efficiency.
  • the process 100 uses, as inputs, the aqueous source 102, the water stream 132, the eluent 106, and power from any reasonable power sources and generates, as outputs, the lithium hydroxide material 142 or optionally the lithium hydroxide product 154, the bromine product 118, the lithium and bromide depleted stream 119, and potentially the lithium and chloride depleted stream 138.
  • the process 100 can, optionally, include a bromine removal stage 160 to treat an aqueous lithium and bromide containing stream 101 and remove bromine to a bromine product 162.
  • a portion, or all, of the chlorine gas stream 112 can be routed to the optional bromine removal stage 160.
  • the chlorine gas stream 112 can be used to produce bromine from any brom ide-containing aqueous stream of the process 100 or of another process.
  • bromine could be generated using an aqueous bromide source from another process, or using an intermediate stream withdrawn from the vessel used to contact the aqueous source 102 with the lithium selective medium in the extraction stage 104.
  • the extraction stage 104 could also be omitted in some cases, and the conversion stage 109 used to directly convert lithium chloride from the aqueous source 102 into lithium hydroxide using the electrochemical process described above for generating the chlorine gas stream 112.
  • the chlorine gas can also be used to remove sulfides from any sulfide-containing stream of the process 100 by reacting with sulfide species to form sulfur and hydrochloric acid (HCI) or of another process described herein or another process not specifically described herein.
  • HCI sulfur and hydrochloric acid
  • the sulfur can subsequently be filtered out of the bromide depleted stream
  • the chlorine gas can be mixed with the aqueous source 102 in the optional bromine removal stage 160 to remove sulfide species and bromide ions in a single treatment or in a staged treatment.
  • the chlorine gas can also remove sulfide species in the bromine production stage 114 or in the optional bromine removal stage 160, or in other units.
  • the process 100 can also be configured to deliver a lithium carbonate final product by providing a second conversion stage (not shown) in which the lithium hydroxide material 142 is reacted with sodium carbonate to form lithium carbonate, which can be precipitated, filtered, concentrated, and/or solidified by removing water using any convenient process.
  • aqueous source may contain ions of interest such as lithium, manganese, nickel, cobalt, magnesium, iron, copper, zinc, vanadium, molybdenum, or other critical and non-critical ions, and may have sulfide species, dissolved gases, bacteria, species that can cause scaling, fouling, or corrosion, organic species (ie species containing carbon atoms such as but not limited to hydrocarbons and carbon dioxide), or a combination thereof.
  • ions of interest such as lithium, manganese, nickel, cobalt, magnesium, iron, copper, zinc, vanadium, molybdenum, or other critical and non-critical ions
  • sulfide species dissolved gases, bacteria, species that can cause scaling, fouling, or corrosion
  • organic species ie species containing carbon atoms such as but not limited to hydrocarbons and carbon dioxide
  • Methods of recovering critical ions such as lithium from an aqueous source typically include several stages and in particular a direct aqueous extraction stage. An example of such method has been disclosed in relationship with Fig. 1 . Methods described herein also include reducing the concentration of sulfide species such as hydrogen sulfide (H2S), bisulfide (HS _ ), and/or sulfide (S 2- ) species in an aqueous material to be used in the extraction stage.
  • H2S hydrogen sulfide
  • HS _ bisulfide
  • S 2- sulfide
  • Methods described herein also include reducing the concentration of organic species, including hydrocarbons, bacteria, and salts in an aqueous material to be used in the extraction stage.
  • Some methods include a combination of methods such as reducing (including, reducing to zero) sulfide species and/or reducing organic species such as hydrocarbons.
  • Such methods can also be combined with bromine removal and recovery as described above as bromide species may be present along those species. For instance, Smackover brine includes bromide and sulfide species.
  • sulfide species and/or organics species and/or transition metal ions can be removed from the aqueous source before the extraction stage 104 of Fig. 1 and/or before the bromine removal stage 114 or 160.
  • Such impurities may indeed be detrimental in the extraction stage as they may reduce efficiency of the extraction process. They may also be detrimental in the bromine production process.
  • the chlorine gas may react with other compounds, such as sulfide species as indicated above and/or transition metals ions that it can fully oxidize. It generally reacts with those compounds before reacting with bromide ions. In order to maximize the reaction of chlorine gas and bromide ions, said other compounds may be removed before producing bromine.
  • Reducing concentration of sulfide species in an aqueous material may include use of gas sparging in an open or closed system, membranes, adsorber media (such as the product SULFATREATTM available from Schlumberger, Ltd.) chemical treatment, or any combination thereof.
  • Reducing concentration of sulfides may include displacing sulfide species, oxidizing sulfide species using a chemical agent, or both.
  • Displacing sulfide species can use air or inert gas, such as nitrogen, or both for displacing sulfide species out of the aqueous source or other aqueous stream to be used for direct aqueous extraction.
  • Gas sparging is an example of a displacement technique in which a gas is flowed into a liquid containing sulfides, causing the sulfides to leave the liquid with the gas as the gas bubbles out of the liquid.
  • the gas emerging from the liquid, and bearing sulfide species can be routed to a flare or other combustion device, or to a sequestration system such as the SULFATREATTM (mark of Schlumberger or a Schlumberger company) system available from Schlumberger, Ltd., of Houston, Texas, or an amine scrubbing system.
  • Sulfide species may also react with other native species found in the brine for example iron. This may involve a redox couple between a sulfur containing species and iron species or mediated by a biological agent.
  • Reducing concentration of sulfide species in an aqueous material may also include use of a bio treatment process in which a biological agent, such as an organism, enzyme, or molecule that is a biologically active or living agent or derived from a biologically active or living agent, is used to remove sulfide species, or facilitate removal of sulfide species, from the aqueous material.
  • a biological agent such as an organism, enzyme, or molecule that is a biologically active or living agent or derived from a biologically active or living agent
  • bromine removal and recovery can be performed before or after removal of other impurities such as organics and sulfides.
  • Oxidizing sulfide species using a chemical agent may be configured so that the chemical agent reacts with sulfide species, such as H2S, to yield in some reactions sulfuric acid (H2SO4).
  • sulfide species such as H2S
  • H2SO4 sulfuric acid
  • Any appropriate chemical agent may be used to oxidize sulfide species, and such chemical agent may be combined with other additives or catalysts, of which iron is one example.
  • An exemplary composition that could be used to treat the brine is described in US Patent Application 2014/0374104, herein incorporated by reference.
  • Triazines are also known sulfide removal agents, so various triazines, such as hexahydro- 1 ,3,5-tris(hydroxyethyl)-s-triazine (MEA triazine) or hexahydro-1 ,3,5-trimethyl-s-triazine (MMA triazine) could be used to scavenge sulfide species from an aqueous stream.
  • MEA triazine hexahydro-1 ,3,5-tris(hydroxyethyl)-s-triazine
  • MMA triazine hexahydro-1 ,3,5-trimethyl-s-triazine
  • Another chemical agent known to remove sulfide species is (ethylenedioxy)dimethanol. Different chemical agents in combination may also be used to treat different sulfide species.
  • the sulfide species could be temporarily sequestered from the aqueous source, or a stream derived from the aqueous source such as the extract, and then mixed with the ion depleted stream of the extraction stage. Such methods may be particularly applicable when displacement and/or gas sparging techniques are used. “Derived,” here, means that the stream can be the same stream or a stream that is obtained from processing in another stage. So here, a stream derived from the aqueous source can be a stream of the aqueous source itself, in other words the aqueous source itself, or a stream obtained from processing the aqueous source.
  • the sulfide species may be chemically converted to a reagent, for example an acid, and the reagent used in any stage of the method to adjust properties of a stream for processing.
  • An acid formed from the sulfide species may for instance be used to adjust pH of one of the extraction feed and/or of the stream derived from the extraction feed, i.e. before lithium extraction.
  • derived means a stream obtained from processing the extraction feed in some respect.
  • sulfide species can be converted to sulfuric acid using an oxidant such as sodium hypochlorite. The reaction produces sodium chloride as a byproduct, which can easily be removed at any stage of the methods described herein.
  • Reducing concentration of organic species can use one or more processes of gravity separation, gas flotation, filtering (e.g. membrane filtering), inducing coalescence, adsorption/desorption, and bacterial or microbial cleaning.
  • Fig. 2 is a process diagram of an example process 200 for removing hydrocarbons and/or other organic species from an aqueous stream.
  • Emulsified oil or an oil phase can be removed using one or more of the techniques listed in Table 1. For instance, bulk oil can be removed using a gravity separator 202, for example by use of one or more hydrocyclones 204.
  • Such bulk oils can include, or can be, condensate, light crude oil, medium viscosity crude oil, high viscosity crude oil, Heavy oil or a combination thereof.
  • Free oil can be removed using a filtration unit 206, which may be a cross-flow scrubber.
  • a cross-flow scrubber can be obtained from Schlumberger Ltd., of Houston, TX.
  • Dispersed oil can be removed by a gas flotation unit 208, which may be an EPCON dual compact flotation unit available from Schlumberger, Ltd.
  • Polishing oil can removed using a second filtration unit 210, which can be a vessel holding a nutshell filter medium such as the HYDROMATION walnut shell filter media available from Schlumberger, Ltd.
  • Chemical additives can be used to control scale, bacteria, corrosion, formation of emulsions, sulfur species, pH, alkalinity, or other characteristics.
  • Bacterial or microbial treatment as known in the art, can be used in addition to, or instead of, the techniques described above.
  • Reducing the concentration of organic species may also include use of granular activated carbon (GAC) as a medium in a filtering process and/or a counter-current adsorption desorption (CCAD) process.
  • GAC granular activated carbon
  • CCAD counter-current adsorption desorption
  • Such processes can use media selective to organic species as withdrawal material to withdraw organic species, such as specific target hydrocarbons, from an aqueous stream.
  • Another such media that can be used, in addition or instead, is walnut shell media.
  • Other media that can be used include zeolites, metal-organic frameworks, and/or activated or nonactivated nanotubes. Such media can be used alone, or with other media described herein.
  • Such media can be used in adsorption-desorption processes, for example, to separate organics, including hydrocarbons, from the aqueous stream.
  • the stage shown here is an example and may comprise additional operations or some operations may be removed depending on the nature of the contaminants. For instance, in some cases only bulk oil and dispersed oil may be removed, or only bulk oil and free oil, or only polishing oil, etc. Any combination of the operations above is covered by the present disclosure, and the equipment described below for each operation represents examples of equipment that can be used to perform the16ariouss operations.
  • Appropriate additives can be added to the aqueous material (containing some type of oil) before one or more of the operations in order to enhance removal operations.
  • Such additives may include any of the chemical additives enabling one or more of scale control, prevent bacteria or corrosion development, destabilize emulsions, adjusting pH or alkalinity, etc.
  • the additives used may include any conventional additives and may be chosen in view of characteristics, such as temperature and impurity type and quantity, of the aqueous material.
  • Table 1 shows characteristics of types of non-dissolved oil (ie emulsified oil or oil phase) that can be removed or reduced in an aqueous material by the units of Fig. 2.
  • Each type of oil is characterized by a particle size (first column) and a concentration in the brine (second column). When there are different types of oil in the brine, the oil that has the larger particle size is generally removed first.
  • the products that are indicated in the third column of Table 1 are commercial products, some of them available from Schlumberger, Ltd., that can perform the specified oil removal operations.
  • dissolved organic materials can also be removed using organic selective media, which can be solid, liquid, or gel. Many such materials are known in the art, and can be used for contacting with an aqueous stream containing dissolved organic materials.
  • organic selective media can include materials that partition from oil to water phase, such as acids and amines, and organic inhibitors for scale prevention, corrosion management, bacterial control, and emulsion control.
  • Reducing organics in the aqueous material to be used for ion recovery can also be performed by membrane processes, which can utilize electrical, chemical, pressure, vacuum, biological agents such as bacteria, or surface modification of a medium for removing organic species, including hydrocarbons,
  • reducing concentration of hydrocarbons/organics can be performed before reducing concentration of sulfide species. Alternately reducing concentration of sulfide species can be performed before reducing concentration of hydrocarbons/organics. Depending on the processes used for the two removal operations, it may be preferable, in some cases, to perform one removal before the other, but the two operations can generally be performed in any order.
  • Removing suspended solids may include any appropriate technique, for instance filtering techniques and /or use of desanders, desilters, and/or hydrocyclones.
  • Removing transition metals may include methods such as chemical reaction, precipitation (via concentration or coagulationflocculation), solids removal, ion exchange, filtration, digestion, and any combination thereof.
  • the methods described herein may also include reducing the concentration of dissolved silica before extraction (and/or after extraction). When performed before extraction, this is preferably performed after reducing the concentration of hydrocarbons and/or organics and/or reducing the concentration of sulfide species but the stages before lithium extraction can generally be performed in any order. Any conventional technique for removing silica may be implemented including use of chemical agent such as lime softening or iron hydroxide or adsorption methods. Other minerals that may have detrimental impact on the extraction process can also be removed using known processes.
  • the aqueous material may be subjected to a concentration operation to increase concentration of a detrimental species beyond its solubility limit to cause that species to precipitate as a solid that can then be removed from the aqueous material.
  • the aqueous stream can also be combined with fresh water to dilute detrimental species, such as scaling species, that can be tolerated below a threshold concentration.
  • heat maybe added or removed from the brine entering or leaving the process via heat exchangers plus any other stream in the process.
  • aqueous source that can be advantageously treated using the methods described herein is Smackover brine, which can contain sulfide species and bromide species. Such a brine may be treated to remove bromine and/or bromide species prior to ion recovery.
  • Other brines that can be treated using these methods generally include salar brines, continental brines, oilfield brines, produced water streams, geothermal brines, seawater sources, or any combination thereof. The methods herein are useful for reducing sulfide and organic species that can be found in such brines and for then recovering target ions from the aqueous source.
  • FIG. 3 is a process diagram summarizing a method 300 according to one embodiment.
  • An aqueous source 302 contains an aqueous material that is to be treated using the process of the method 300.
  • a pump 304 which may be a submersible pump, obtains aqueous material from the aqueous source 302 and disposes the aqueous material in a tank 306 for storage and/or buffering.
  • the aqueous material is withdrawn from the tank 306 and routed (e.g. using a pump, not shown) to a preparation stage 308 for removal of sulfide species and organic species, such as hydrocarbons, as well as transition metals.
  • the preparation stage 308 may have a reaction part 310 and a filtration part 312, substantially as described above.
  • an additive stream 314 is provided to the reaction part 310 to react with sulfide species in the aqueous material.
  • the aqueous material is contacted with filtration media, such as nutshells, granulated activated carbon, and/or bacterial organic consumers, in the filtration part 312 to remove or reduce organic species. Any or all of the units described in connection with Fig. 2 may be included in the preparation stage 308 to remove organic species or transition metals. .
  • a purified aqueous material 316 exits the preparation stage 308 and is provided to an extraction stage 318, which can be any embodiment of extraction stage described herein.
  • a withdrawal material is used to withdraw ions from the purified aqueous material 316 in a loading process such as any of the loading processes described herein, resulting in a depleted stream 320, which can be returned to the environment.
  • impurities and water can be separated in the depleted stream 320, and the water can be used elsewhere in the process of the method 300, or for any suitable purpose.
  • an endpoint of the loading process for example when the withdrawal material is saturated with target ions, such as lithium, or at a time before such saturation point, contacting the withdrawal material with the purified aqueous material 316 is discontinued.
  • the purified aqueous material 316 can be recycled to the tank 306 during such phase.
  • An eluent 322 is used to unload ions from the withdrawal material to yield an extract 324.
  • the eluent 322 is sourced, at least in part, from a fresh water tank 325, and may be treated in a purification stage 326 to remove any impurities that might negatively impact the extraction process.
  • the extract 324 is routed to an impurity removal stage 328 to remove impurities such as dissolved silica, hardening species, and transition metals, if desired, as described elsewhere herein.
  • the impurity removal stage 328 yields a purified extract 330 that is provided to a concentration stage 332, which produces a concentrate 334 significantly higher in concentration of target ions.
  • Water separated in the concentration stage 332 emerges as a diluted stream 336, which may include small amounts of ions and is recycled, in this case, to the extraction stage 318 to combine with water from the fresh water tank 324 to form the eluent 322.
  • the concentration stage 332 may utilize energy recovery and integration between hot streams and cool streams to minimize energy input into the concentration operation.
  • the concentration stage 332 produces a concentrate that may for instance be 4 wt% or more, for example 5 wt% or 10 wt% or 15 wt%, target ions, depending on the solubility of the target ions in water.
  • the concentrate may have 4 wt% lithium, but could have more lithium because the solubility limit of lithium ions in water is much higher than 4 wt%.
  • the concentration stage 332 can use membrane separation, evaporation, or a combination thereof. Heat can be recovered from the liquid remaining after evaporation, and streams subjected to membrane processes can be depressured to yield energy.
  • the concentrate 334 obtained from the concentration stage 332 is routed to a storage tank 338, where the concentrate 334 can be used as a product 340 or routed to a conversion stage 342 for conversion to carbonate, hydroxide, or both as described above.
  • a conversion process is used that forms chlorine gas, CI2, such as an electrochemical conversion to hydroxide
  • the chlorine gas can be used to recover bromine in any part of the process containing bromide ions.
  • the chlorine gas can be recovered at the conversion stage 342 and routed to the tank 306 or into the conduit through which aqueous material from the source 302 flows into the tank 306.
  • the chlorine gas will react with bromide ions to produce elemental bromine, which can be collected as a liquid at the bottom of the tank 306 and recovered.
  • the chlorine gas produced at the conversion stage 342 can be routed to another stream containing bromide ions to recover bromine.
  • the lithium-selective extraction processes described herein can be used to extract, concentrate, and purify other elements, such as nickel, manganese, magnesium, and cobalt, zinc, aluminum, copper, molybdenum, vanadium, or any combination thereof.
  • materials can be used to make the same processes selective for other target ions, such as those listed above.
  • the preparation stage may include removal of sulfides and/or organics as well as a combination of any impurity that is described in a specification as has been described in relationship with lithium.
  • the resulting extract can then be subjected to impurity removal stage and/or concentration stage that is substantially the same as the processes described herein.
  • Fig. 4 is a schematic process diagram of an ion recovery process 400 according to another embodiment.
  • the process 400 is a general process that includes stages described elsewhere herein.
  • An aqueous source 402 is provided to a preparation stage 410.
  • the preparation stage 410 includes a solids removal unit 406, an organic removal unit 408, a sulfide removal unit 412, and a bromine recovery unit 414.
  • the preparation stage 410 can also include an optional concentrator 416.
  • the preparation stage 410 can also optionally include a divalent removal unit 418, which can remove divalent cations from the aqueous source 402 prior to downstream ion recovery operations if such removal is suitable and advantageous.
  • the concentrator 416 can be used to manage performance of downstream ion recovery operations.
  • the various units of the preparation stage 410 can be aligned and/or configured to operate in any suitable order, depending on the needs of particular processes. Treatments can be performed on streams within the preparation stage 410 to adjust characteristics of any stream for suitable processing. For example, temperature, pH, ionic strength, salt content, and other characteristics can be adjusted at any suitable point.
  • the preparation stage 410 yields an extraction feed 422, which is routed to an extraction stage 420.
  • target ions are extracted using any of the methods described herein.
  • the optional concentrator 416 can adjust concentration of ions in the extraction feed for optimal processing in the extraction stage 420.
  • the extraction stage 420 can perform direct ion extraction using a medium to remove ions from the extraction feed 422 and an eluent to remove ions from the medium.
  • the extraction stage 420 generally yields an extract 424, which can be an eluate of a direct ion extraction process as described herein, containing a target concentration of the target ions, and a depleted stream 426, which is generally depleted of the target ions.
  • the target ions may be substantially completely removed from the extraction feed 422 to yield a depleted stream 426 having undetectable amounts of the target ions.
  • the extract 424 can be used for any suitable purpose.
  • an optional conversion preparation stage 430 can be used to prepare the extract for optimal conversion to one or more products.
  • the conversion preparation stage 430 can include an impurity removal unit 432.
  • the conversion preparation stage 430 can also include a concentration unit 434.
  • the conversion preparation stage 430 can include one or both of the impurity removal unit 432 and the concentration unit 434.
  • the units of the conversion preparation stage 430 are described elsewhere herein, and can be utilized within the conversion preparation stage 430 in any suitable order.
  • the extract 424 can be provided to the conversion preparation stage 430, which yields a conversion feed 436.
  • the extract 424, the conversion feed 436, or both, or any portion of either, in any combination, can be provided to a conversion stage 440 that generally converts target ions in the extract 424, the conversion feed 436, or both into products.
  • a target ion is lithium, which can be converted, in the conversion stage 440, into lithium carbonate, lithium sulfate, lithium nitrate, lithium hydroxide, or any suitable product. Units of the conversion stage 440 are described elsewhere herein.
  • a source of chlorine gas 450 is provided to the preparation stage to convert bromide ions in the aqueous source 402, or a stream derived from the aqueous source 402 by processing in the preparation stage 404, into bromine.
  • the source of chlorine gas 450 can be any source, but where lithium in the extract 424, the conversion feed 436, or both is converted to lithium hydroxide in the conversion stage 440 according to methods described herein, the source of chlorine gas 450 can be provided by the conversion stage 440, as shown in Fig. 4. As such, chlorine gas can be recovered in the conversion stage 440 and routed to the preparation stage 404 for use in recovering bromine from the aqueous source 402.
  • the conversion stage 440 produces one or more products 460, which may be utilized in any convenient way.
  • any of the stages and units of the process 400 may form aqueous streams, which may be dilute ion streams or substantially pure water streams.
  • concentrators, impurity removal units, and the like can form aqueous streams that can range from substantially pure water to dilute brines. Any of these streams can be recycled to a convenient upstream part of the process 400.
  • aqueous streams produced by downstream processing can be routed to the preparation stage 404 to manage the concentration of target ions in any stream of the preparation stage 404, including the extraction feed 420.
  • aqueous streams produced by downstream processing can be routed to the extraction stage 404 to be used as, or as part of, an eluent for direct ion extraction.
  • the methods described herein thus, include generating chlorine gas in a conversion process that converts metal chloride from an metal containing aqueous medium obtained from an aqueous source into a hydroxide material; recovering the chlorine gas; and recovering bromine by reacting the chlorine gas with a bromide containing aqueous source.
  • the conversion process can be a lithium conversion process that converts lithium chloride to a lithium hydroxide material.
  • the lithium conversion process is an electrochemical process, in one case, that uses an anode and a cathode, wherein chlorine gas is generated at the anode from chloride ions of the aqueous medium.
  • the anode and cathode can be separated by a selective barrier, for instance selective for lithium.
  • the methods herein can also include separating a target metal, such as lithium of an extraction feed derived from the metal containing aqueous source using a direct extraction process to form an extract, wherein the aqueous medium is derived from the extract and wherein the metal of the metal chloride is the target metal.
  • the methods can also include concentrating a stream derived from the extract to form a concentrate, wherein the aqueous medium is derived from the concentrate.
  • the extraction feed can be the aqueous source.
  • the direct extraction process yields a lithium depleted stream, and the lithium depleted stream can be the aqueous source in some cases.
  • reacting the chlorine gas with the bromide containing aqueous source yields a bromine product and a bromide depleted stream, wherein the extraction feed is derived from the bromide depleted stream.
  • Water can be removed from the hydroxide material, for instance lithium hydroxide material, to form a solid hydroxide product.
  • the hydroxide material may also be in one embodiment further converted into a carbonate product.
  • the methods include one or more of reducing a concentration of sulfide species, optionally hydrogen sulfide (H2S), bisulfide (HS-), sulfide (S2-), or any combination thereof, or reducing a concentration of organic species, optionally a hydrocarbon, or reducing a concentration of transition metal ions, preferably other than the target metal, in a first stream, wherein the bromide containing aqueous source and/or the extraction feed is derived from the first stream.
  • H2S hydrogen sulfide
  • HS- bisulfide
  • S2- sulfide
  • the bromide depleted stream includes sulfide species, wherein reacting the chlorine gas with the bromide depleted stream also yields a sulfur product, wherein the method includes removing the sulfur product from the bromide depleted stream.
  • Reducing the concentration of organic species may use one or more of gravity separation, electrochemical separation, chemical treatment, bacterial treatment, gas flotation, filtering, inducing coalescence and adsorption-desorption.
  • the organic species includes non-dissolved oil (such as emulsified oil or an oil phase) and reducing the concentration of non-dissolved oil uses a gravity separation process, a filtering process, a gas flotation process, or a combination thereof.
  • the organic species includes bulk oil, free oil, dispersed oil, polishing oil, or any combination thereof.
  • the organic species includes bulk oil and reducing the concentration of bulk oil uses a gravity separation process.
  • the organic species includes free oil and reducing the concentration of free oil uses a filtering process.
  • the organic species includes dispersed oil and reducing the concentration of dispersed oil uses a gas flotation process.
  • the organic species includes polishing oil and reducing the concentration of polishing oil uses a filtering process.
  • the organics species includes dissolved organic materials and reducing the concentration of dissolved organics includes using organic selective media, which can be solid, liquid, or gel.
  • reducing the concentration of organic species includes using granular activated carbon in a filtering process, a counter-current adsorption-desorption process, or both.
  • Such processes can use media selective to organic species as withdrawal material to withdraw organic species, such as specific target hydrocarbons, from an aqueous stream.
  • Another such media that can be used, in addition or instead, is walnut shell media.
  • Other media that can be used include zeolites, metal-organic frameworks, and/or activated or nonactivated nanotubes.
  • the methods herein can also include removing suspended solids from the aqueous source, extraction feed, a stream obtained from the extraction feed, or any combination thereof.
  • removing suspended solids may be performed before reducing the concentration of organic species.
  • Removing suspended solids may include filtering the lithium aqueous source and/or extraction feed. Concentration of dissolved silica can also be reduced in the aqueous source, the extraction feed, the stream obtained from the extraction feed, the extraction feed, or any combination thereof.
  • reducing the concentration of sulfide species includes displacing the sulfide species, optionally using air or an inert gas, withdrawing the sulfide species using a withdrawal material, oxidizing the sulfide species using a chemical agent or a biological agent, or any combination thereof.
  • the withdrawn sulfide can be routed to a combustion stage, or a sequestration stage, or an amine scrubbing stage. When routed to a sequestration stage, it can be mixed with the ion depleted stream obtained from the extraction stage.
  • reducing the concentration of sulfide species can include oxidizing the sulfide species using a chemical or biological agent that reacts with the sulfide species, withdrawing the sulfide species using withdrawal material in an adsorption-desorption process, such as a counter-current adsorption-desorption (CCAD) process, or any combination thereof.
  • CCAD counter-current adsorption-desorption
  • the sulfides can be chemically converted to a reagent that can be recycled in some cases.
  • the reagent may be used, for example, to adjust pH of the extraction feed, a stream obtained from the extraction feed, or both. Additionally or alternately, the sulfides can be removed by gas sparging, membranes, adsorber media, chemical treatment, or any combination thereof.
  • direct aqueous extraction of ions can include an adsorption/desorption process that may be a counter-current adsorption/desorption.
  • the direct extraction can use a selective withdrawal material configured to selectively withdraw one or more ions into the withdrawal material yield a loaded withdrawal material and an ion depleted stream.
  • direct aqueous extraction also includes passing an eluent through the loaded withdrawal material to remove ions from the withdrawal material and yield the extract.
  • the withdrawal material is selective to lithium.
  • the sulfide species is removed from the stream derived from the aqueous source and mixed with the ion depleted stream.
  • Direct aqueous extraction of ions can, additionally or alternately, use an electrochemical separation process having a membrane selective for the target ion to yield the extract. The electrochemical separation may also yield a lithium depleted stream.
  • Methods herein may further include concentrating a stream derived from an extract, obtained from an ion extraction process described herein, in a concentration stage to yield a concentrate.
  • Concentrating the extract may include membrane separation, evaporation, or any combination thereof.
  • concentrating the extract includes membrane separation, and the membrane separation includes a reverse osmosis, a counter-flow reverse osmosis, or both to yield the concentrate and a diluted stream.
  • the method may further comprise recycling the diluted stream to the extraction stage.
  • the concentration stage produces a concentrate having total dissolved solids (TDS) over 120,000mg/l.
  • the methods may further comprise routing the extract, a stream derived from the extract, or both, to an impurity removal stage to reduce concentration of one or more hardness species, one or more transition metals, one or more divalent impurities, or a combination thereof.
  • the impurity removal stage may reduce concentration of calcium, magnesium, aluminum, manganese, iron, barium, boron, scale-forming salts, or any combination thereof.
  • the aqueous source is a salar brine, a continental brine, an oilfield brine, a produced water, a geothermal brine, a seawater source, or a combination thereof.
  • the aqueous source may be a Smackover brine.
  • the aqueous source may be a Bakken brine.
  • the methods described herein can include withdrawing lithium ions from an aqueous medium comprising lithium ions using a direct extraction process to form an aqueous lithium extract; converting lithium ions of the lithium extract to lithium hydroxide using an electrochemical process; converting chloride ions of the lithium extract to chlorine gas using the electrochemical process; and reacting the chlorine gas with an aqueous source comprising bromide ions to form bromine gas from the bromide ions.
  • the electrochemical process can use a lithium selective barrier. Reacting the chlorine gas with the aqueous source can form a bromine depleted stream, and the aqueous medium can be derived from the bromine depleted stream.
  • the direct extraction process can yield a lithium depleted stream, and the aqueous source comprising bromide ions can be derived from the lithium depleted stream.
  • the methods can also include one or more of reducing a concentration of sulfide species, optionally hydrogen sulfide (H2S), bisulfide (HS-), sulfide (S2-), or any combination thereof, or reducing a concentration of organic species, optionally a hydrocarbon, or reducing a concentration of at least one transition metal ion, in an aqueous source comprising lithium and bromide ions to form the aqueous medium.
  • H2S hydrogen sulfide
  • HS- bisulfide
  • S2- sulfide
  • Reducing the concentration of organic species may use one or more of gravity separation, electrochemical separation, chemical treatment, bacterial treatment, gas flotation, filtering, inducing coalescence and adsorption-desorption.
  • the organic species includes non-dissolved oil (such as emulsified oil or an oil phase) and reducing the concentration of non-dissolved oil uses a gravity separation process, a filtering process, a gas flotation process, or a combination thereof.
  • the organic species includes bulk oil, free oil, dispersed oil, polishing oil, or any combination thereof.
  • the organic species includes bulk oil and reducing the concentration of bulk oil uses a gravity separation process.
  • the organic T1 species includes free oil and reducing the concentration of free oil uses a filtering process.
  • the organic species includes dispersed oil and reducing the concentration of dispersed oil uses a gas flotation process.
  • the organic species includes polishing oil and reducing the concentration of polishing oil uses a filtering process.
  • the organics species includes dissolved organic materials and reducing the concentration of dissolved organics includes using organic selective media, which can be solid, liquid, or gel.
  • reducing the concentration of organic species includes using granular activated carbon in a filtering process, a counter-current adsorption-desorption process, or both.
  • Such processes can use media selective to organic species as withdrawal material to withdraw organic species, such as specific target hydrocarbons, from an aqueous stream.
  • organic species such as specific target hydrocarbons
  • Another such media that can be used, in addition or instead, is walnut shell media.
  • Other media that can be used include zeolites, metal-organic frameworks, and/or activated or nonactivated nanotubes.
  • the methods herein can also include removing suspended solids from the aqueous source, extraction feed, a stream obtained from the extraction feed, or any combination thereof.
  • removing suspended solids may be performed before reducing the concentration of organic species.
  • Removing suspended solids may include filtering the lithium aqueous source and/or extraction feed. Concentration of dissolved silica can also be reduced in the aqueous source, the extraction feed, the stream obtained from the extraction feed, the extraction feed, or any combination thereof.
  • reducing the concentration of sulfide species includes displacing the sulfide species, optionally using air or an inert gas, withdrawing the sulfide species using a withdrawal material, oxidizing the sulfide species using a chemical agent or a biological agent, or any combination thereof.
  • the withdrawn sulfide can be routed to a combustion stage, or a sequestration stage, or an amine scrubbing stage. When routed to a sequestration stage, it can be mixed with the ion depleted stream obtained from the extraction stage.
  • reducing the concentration of sulfide species can include oxidizing the sulfide species using a chemical or biological agent that reacts with the sulfide species, withdrawing the sulfide species using withdrawal material in an adsorption-desorption process, such as a counter-current adsorption-desorption (CCAD) process, or any combination thereof.
  • CCAD counter-current adsorption-desorption
  • the sulfides can be chemically converted to a reagent that can be recycled in some cases.
  • the reagent may be used, for example, to adjust pH of the extraction feed, a stream obtained from the extraction feed, or both. Additionally or alternately, the sulfides can be removed by gas sparging, membranes, adsorber media, chemical treatment, or any combination thereof.
  • direct aqueous extraction of ions can include an adsorption/desorption process that may be a counter-current adsorption/desorption.
  • the direct extraction can use a selective withdrawal material configured to selectively withdraw one or more ions into the withdrawal material yield a loaded withdrawal material and an ion depleted stream.
  • direct aqueous extraction also includes passing an eluent through the loaded withdrawal material to remove ions from the withdrawal material and yield the extract.
  • the withdrawal material is selective to lithium.
  • the sulfide species is removed from the stream derived from the aqueous source and mixed with the ion depleted stream.
  • Direct aqueous extraction of ions can, additionally or alternately, use an electrochemical separation process having a membrane selective for the target ion to yield the extract. The electrochemical separation may also yield a lithium depleted stream.
  • Methods herein may further include concentrating a stream derived from an extract, obtained from an ion extraction process described herein, in a concentration stage to yield a concentrate.
  • Concentrating the extract may include membrane separation, evaporation, or any combination thereof.
  • concentrating the extract includes membrane separation, and the membrane separation includes a reverse osmosis, a counter-flow reverse osmosis, or both to yield the concentrate and a diluted stream.
  • the method may further comprise recycling the diluted stream to the extraction stage.
  • the concentration stage produces a concentrate having total dissolved solids (TDS) over 120,000mg/l.
  • the methods may further comprise routing the extract, a stream derived from the extract, or both, to an impurity removal stage to reduce concentration of one or more hardness species, one or more transition metals, one or more divalent impurities, or a combination thereof.
  • the impurity removal stage may reduce concentration of calcium, magnesium, aluminum, manganese, iron, barium, boron, scale-forming salts, or any combination thereof.
  • the aqueous source is a salar brine, a continental brine, an oilfield brine, a produced water, a geothermal brine, a seawater source, or a combination thereof.
  • the aqueous source may be a Smackover brine.
  • the aqueous source may be a Bakken brine.
  • the methods described herein also include removing sulfide species, organic species, or both from an aqueous source comprising lithium ions and bromide ions; reacting a stream derived from the aqueous source with a chlorine gas stream to form bromine and a bromide depleted aqueous stream; extracting lithium ions from a stream derived from the bromide depleted using a direct extraction process to a lithium extract; and converting lithium of the lithium extract to lithium hydroxide in an electrochemical process that uses a lithium selective barrier to form the chlorine gas stream.
  • the methods can further include converting at least a portion of the lithium hydroxide to lithium carbonate, removing water from at least a portion of the lithium hydroxide to form a solid lithium hydroxide product, or both.
  • the methods described herein can also include reducing a concentration of at least one or more of a sulfide species, organic species, and transition metal ions from an aqueous source to form a purified aqueous source; extracting lithium ions from a stream derived from the purified aqueous using a direct extraction process to form a lithium depleted stream comprising bromide ions and a lithium extract comprising lithium ions; converting lithium of the lithium extract to lithium hydroxide in an electrochemical process that uses a lithium selective barrier to form a chlorine gas stream; and reacting the lithium depleted stream with the chlorine gas stream to form bromine and a bromide depleted aqueous stream.
  • the methods can also include converting at least a portion of the lithium hydroxide to lithium carbonate, removing water from at least a portion of the lithium hydroxide to form a solid lithium hydroxide product, or both.
  • the methods disclosed herein also include Reducing the concentration of one or more of sulfide species, organic species, and transition metal ions, from an aqueous source to form a purified aqueous source; extracting lithium ions from a stream derived from the purified aqueous using a direct extraction process to form a lithium depleted stream comprising bromide ions and a lithium extract comprising lithium ions; converting lithium of the lithium extract to lithium hydroxide in an electrochemical process that uses a lithium selective barrier to form a chlorine gas stream; and reacting the lithium depleted stream with the chlorine gas stream to form bromine and a bromide depleted aqueous stream.

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  • Organic Chemistry (AREA)
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  • Inorganic Chemistry (AREA)
  • Environmental & Geological Engineering (AREA)
  • Life Sciences & Earth Sciences (AREA)
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Abstract

Les procédés comprennent la génération de chlore gazeux dans un procédé de conversion qui convertit le chlorure métallique d'un milieu aqueux dérivé d'une source aqueuse contenant un métal en un matériau hydroxyde ; la récupération du chlore gazeux ; et la récupération du brome par réaction du chlore gazeux avec une source aqueuse contenant du bromure. Les procédés et l'appareil décrits ici permettent également d'éliminer des espèces de sulfure et/ou des espèces organiques et/ou des métaux de transition, entre autres. Les procédés peuvent être applicables par exemple à la conversion de lithium et peuvent être couplés à un procédé d'extraction directe pour l'extraction de lithium.
PCT/US2023/036452 2022-10-31 2023-10-31 Extraction de brome et de lithium à partir de sources aqueuses WO2024097211A1 (fr)

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US202263381611P 2022-10-31 2022-10-31
US63/381,611 2022-10-31
US202263386356P 2022-12-07 2022-12-07
US63/386,356 2022-12-07
US18/328,048 2023-06-02
US18/328,048 US20240025767A1 (en) 2022-12-07 2023-06-02 Hydrocarbon and sulfide removal in direct aqueous extraction
IBPCT/IB2023/030928 2023-08-23
IB2023030928 2023-08-23
IBPCT/IB2023/030949 2023-08-23
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Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3084028A (en) * 1961-02-21 1963-04-02 Electro Chimie Metal Process for recovering bromine
US4127989A (en) * 1978-01-25 1978-12-05 Union Oil Company Of California Method for separating metal values from brine
US20140374104A1 (en) 2013-06-24 2014-12-25 Baker Hughes Incorporated Composition and method for treating oilfield water
US10604414B2 (en) * 2017-06-15 2020-03-31 Energysource Minerals Llc System and process for recovery of lithium from a geothermal brine
US20210079497A1 (en) * 2019-09-16 2021-03-18 InCoR Lithium Selective lithium extraction from brines
US20210346822A1 (en) * 2020-05-07 2021-11-11 Prairie Lithium Corporation Methods and systems for recovery of valuable target species from brine solutions
WO2021231894A1 (fr) * 2020-05-15 2021-11-18 Winner Water Services Procédés d'extraction de lithium ou de magnésium
US20220055910A1 (en) * 2020-08-21 2022-02-24 Schlumberger Technology Corporation Lithium extraction improvements
JP7084669B1 (ja) * 2022-01-14 2022-06-15 株式会社アサカ理研 廃リチウムイオン電池からリチウムを回収する方法
US11365128B2 (en) 2017-06-15 2022-06-21 Energysource Minerals Llc Process for selective adsorption and recovery of lithium from natural and synthetic brines

Patent Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3084028A (en) * 1961-02-21 1963-04-02 Electro Chimie Metal Process for recovering bromine
US4127989A (en) * 1978-01-25 1978-12-05 Union Oil Company Of California Method for separating metal values from brine
US20140374104A1 (en) 2013-06-24 2014-12-25 Baker Hughes Incorporated Composition and method for treating oilfield water
US10604414B2 (en) * 2017-06-15 2020-03-31 Energysource Minerals Llc System and process for recovery of lithium from a geothermal brine
US11365128B2 (en) 2017-06-15 2022-06-21 Energysource Minerals Llc Process for selective adsorption and recovery of lithium from natural and synthetic brines
US20210079497A1 (en) * 2019-09-16 2021-03-18 InCoR Lithium Selective lithium extraction from brines
US20210346822A1 (en) * 2020-05-07 2021-11-11 Prairie Lithium Corporation Methods and systems for recovery of valuable target species from brine solutions
WO2021231894A1 (fr) * 2020-05-15 2021-11-18 Winner Water Services Procédés d'extraction de lithium ou de magnésium
US20220055910A1 (en) * 2020-08-21 2022-02-24 Schlumberger Technology Corporation Lithium extraction improvements
JP7084669B1 (ja) * 2022-01-14 2022-06-15 株式会社アサカ理研 廃リチウムイオン電池からリチウムを回収する方法

Non-Patent Citations (2)

* Cited by examiner, † Cited by third party
Title
TABELIN CARLITO BALTAZAR ET AL: "Towards a low-carbon society: A review of lithium resource availability, challenges and innovations in mining, extraction and recycling, and future perspectives", MINERALS ENGINEERING, ELSEVIER, AMSTERDAM, NL, vol. 163, 9 February 2021 (2021-02-09), XP086502118, ISSN: 0892-6875, [retrieved on 20210209], DOI: 10.1016/J.MINENG.2020.106743 *
WARREN IAN: "Techno-Economic Analysis of Lithium Extraction from Geothermal Brines", 31 May 2021 (2021-05-31), Golden, CO 80401, pages 1 - 48, XP055983166, Retrieved from the Internet <URL:https://www.nrel.gov/docs/fy21osti/79178.pdf> [retrieved on 20221119] *

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