Lithium-selective permeable membrane and method for manufacturing the lithium-selective permeable membrane
The lithium-selective permeable membrane with a surface roughened sintered lithium-ion conductor addresses manufacturing complexity and cost by ensuring uniform surface composition and structure, enhancing lithium ion recovery efficiency.
Patent Information
- Authority / Receiving Office
- JP · JP
- Patent Type
- Applications
- Current Assignee / Owner
- JAPAN FINE CERAMICS
- Filing Date
- 2026-03-25
- Publication Date
- 2026-06-11
AI Technical Summary
Existing lithium-selective permeable membranes require acid treatment, complicating the manufacturing process and increasing the time and cost of lithium ion recovery, even with improved recovery rates.
A lithium-selective permeable membrane with a surface roughened surface, composed of a sintered lithium-ion conductor, where the outer surface structure is uniform and not affected by the firing atmosphere, enhancing lithium ion permeation rate and reducing recovery time and cost.
The membrane achieves a high lithium ion recovery rate with reduced time and cost by ensuring uniform surface composition and structure, avoiding permeation rate decreases and simplifying the manufacturing process.
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Figure 2026095490000001_ABST
Abstract
Description
[Technical Field]
[0001] The present invention relates to a lithium-selective permeable membrane that selectively allows lithium ions to pass through, and a method for manufacturing the lithium-selective permeable membrane. [Background technology]
[0002] Metals, such as rare metals, are found in smaller quantities in the Earth's crust compared to other substances, and their availability is limited due to the technical difficulties of mining and refining. On the other hand, these metals are used as additives in structural materials, as electronic and magnetic materials such as light-emitting diodes, batteries, and permanent magnets, or as functional materials such as photocatalysts and new glass, and have attracted considerable attention in recent years.
[0003] For example, lithium, a rare metal, is used in the production of lithium-ion batteries and nuclear fusion reactor fuel, and its demand has been expanding in recent years. To supply these applications, technology is needed to produce large quantities of lithium cheaply.
[0004] While rare metals such as lithium can be extracted from ores contained in the Earth's crust, as mentioned earlier, there are technical difficulties that make mass production challenging.
[0005] Therefore, in recent years, technologies for extracting ions derived from rare metals contained in seawater have been developing. Seawater contains multiple ions, and the amount of these ions is enormous compared to the reserves buried underground. Industrial waste (such as discarded lithium-ion batteries) is also known to contain large amounts of multiple ions. However, seawater and industrial waste contain not only ions represented by rare metals (such as lithium ions), but also other metal ions such as potassium, sodium, and calcium. For this reason, in order to recover the target ions, the development of membranes that separate the target ions from other metal ions (selective permeable membranes) is progressing.
[0006] On the other hand, the concentration of rare metal elements as ions in seawater or industrial waste (such as discarded lithium-ion batteries) is low, and the ion permeation rate for recovering the target ions in selective permeable membranes is also low. Therefore, conventional technology has the problem of requiring a lot of time and cost to recover the target ions from seawater or industrial waste (such as discarded lithium-ion batteries).
[0007] To address these challenges, Patent Document 1 discloses a technology for extracting lithium ions from salt lake brine or lithium ore with relatively high lithium concentrations, or from industrial waste (such as discarded lithium secondary batteries) or seawater with relatively low lithium concentrations. According to Patent Document 1, a lithium selective permeable membrane is disclosed in which a lithium adsorption layer, composed of a material different from the lithium selective permeable membrane body, is formed on one surface by acid treatment. It has been shown that such a lithium selective permeable membrane can recover lithium ions from the raw solution at a high recovery rate. [Prior art documents] [Patent Documents]
[0008] [Patent Document 1] Japanese Patent Publication No. 2017-131863 [Overview of the project] [Problems that the invention aims to solve]
[0009] However, while the lithium-selective permeable membrane described in Patent Document 1 can increase the lithium ion recovery rate, it requires acid treatment of one side of the lithium-selective permeable membrane, which makes the manufacturing process complicated. Furthermore, even if one side of the lithium-selective permeable membrane is acid-treated, the lithium recovery process still requires a lot of time and is costly, which remains a problem.
[0010] To solve the above-mentioned problems, the present invention aims to provide a lithium-selective permeable membrane and a method for manufacturing the lithium-selective permeable membrane that can recover lithium ions without requiring complicated processing of the membrane, reduces the time required for lithium ion recovery, and reduces the cost required. [Means for solving the problem]
[0011] To achieve the above objectives, the lithium selective permeable membrane of the present invention is characterized by having the following inventive features.
[0012] (1): The lithium selective permeable membrane of the present invention is A lithium-selective permeable film comprising a sintered lithium-ion conductor, characterized in that at least a portion of the outer surface of the lithium-selective permeable film is composed of a surface roughened surface.
[0013] Generally, when a lithium ion conductor is used as a lithium selective film, the lithium ion conductor is often used as a sintered body. In sintered bodies, the structure or composition near the outer surface, which is exposed to the firing atmosphere during sintering, often differs from the structure or composition inside, which is not affected by the firing atmosphere during sintering. According to the lithium selective permeable film described in (1), the portion with the structure or composition near the outer surface that changed during sintering is removed by surface roughening treatment, and the portion with a structure and composition not affected by the firing atmosphere during sintering is exposed on the surface of the lithium selective permeable film. Therefore, the structure or composition of the ion conductor can be made uniform on the outer surface and inside of the lithium selective permeable film.
[0014] Furthermore, near the outer surface that comes into contact with the firing atmosphere during sintering, the structure or composition changes during sintering, so the lithium ion permeation rate in this region becomes slower than the original lithium ion permeation rate (the lithium ion permeation rate in the part that is not affected by the firing atmosphere during sintering). With the lithium selective permeable film according to (1), a region having the structure or composition of an ion conductor that is not affected by the firing atmosphere during sintering is exposed on the outer surface of the selective permeable film, so a decrease in the lithium ion permeation rate can be avoided. As described above, with the lithium selective permeable film according to (1), the time required for lithium ion recovery can be reduced and the cost required can be reduced.
[0015] (2): Furthermore, in the lithium selective permeable membrane of the present invention, It is preferable that at least one of the following requirements (A), (B), and (C) is met. (A) The arithmetic mean height Ra of all or part of the surface roughened is 0.8 μm or more and 20 μm or less. (B) The root mean square gradient Rdq on all or part of the surface roughened is 10° or more and 80° or less. (C) The unfolded area ratio Sdr on all or part of the surface roughened is 0.2 or more and 2 or less.
[0016] The lithium selective permeable film according to (2) satisfies at least one of the following requirements: the arithmetic mean height Ra on all or part of the surface roughened surface is 0.8 μm or more, the root mean square gradient Rdq is 10° or more, and the developed area ratio Sdr is 0.2 or more. Therefore, the surface area of the lithium ion conductor can be substantially increased. Consequently, lithium ions are taken into the lithium selective permeable film through the lithium ion conductor with a large surface area, and as a result, the lithium ion recovery rate can be increased.
[0017] From the perspective of the lithium ion recovery rate, the larger the values of Ra, Rdq, and Sdr described above, the more preferable. However, on the other hand, the greater the attempt to increase the values of Ra, Rdq, and Sdr, the higher the risk of damage to the lithium selective permeable membrane during the surface roughening treatment. Also, the time and cost required for the surface roughening treatment increase. Therefore, in order to stably manufacture a lithium selective permeable membrane including a lithium ion conductor with a large surface area, it is preferable to satisfy at least one of the requirements that the arithmetic mean height Ra on the surface roughened surface of the lithium ion conductor is 20 μm or less, the root mean square gradient Rdq is 80° or less, and the spread area ratio Sdr is 2 or less.
[0018] (3): Also, in the lithium selective permeable membrane of the present invention, it is preferable that the surface of the sintered body particles on all or part of the surface roughened surface does not have a step and terrace structure.
[0019] (3) The lithium selective permeable membrane according to this has no step and terrace structure formed on the surface of the sintered body particles exposed on all or part of the surface roughened surface by heat treatment in the sintering process or annealing process. For this reason, a surface that is not directly exposed to the firing atmosphere during the heat treatment is sufficiently exposed. Therefore, the lithium selective permeable membrane according to (3) can reduce the time and cost required for lithium ion recovery.
[0020] (4): Also, in the lithium selective permeable membrane of the present invention, it is preferable that the lithium ion conductor is a sintered body of lanthanum lithium titanate.
[0021] (4) According to the lithium selective permeable membrane according to this, the lithium ion conductor is a sintered body of lanthanum lithium titanate. Lanthanum lithium titanate, which is a lithium ion conductor, has excellent lithium ion conduction speed. Also, it can stably permeate lithium ions in an aqueous solution. For this reason, according to the lithium selective permeable membrane according to (4), the time and cost required for lithium recovery can be reduced.
[0022] (5): Furthermore, in the lithium selective permeable membrane of the present invention, In a lithium permeation test in the temperature range of 22°C to 24°C, the lithium permeation rate V, expressed by the following formula (1), is 0.4 mmol / (hr·cm). 2 It is preferable that the concentration is (mol / L) or higher. V = M / (T·S·C) ··(1) Here, M is the amount of lithium ions (mmol) that have permeated through the lithium-selective permeable membrane, T is the time (hr) required for the permeation of lithium ions of amount M, and S is the effective membrane area (cm²) of the lithium-selective permeable membrane. 2 ), C is the lithium ion concentration (mol / L) in the stock solution.
[0023] (5) According to the lithium selective permeable membrane, the lithium permeation rate V is 0.4 mmol / (hr·cm). 2 The concentration is (mol / L) or higher. Therefore, the lithium-selective permeable membrane described in (5) can reduce the time and cost required for lithium recovery.
[0024] Furthermore, the method for manufacturing a lithium-selective permeable membrane to solve the above problems is characterized by having the following specific features of the invention.
[0025] (6): The method for producing a lithium-selective permeable membrane of the present invention is as follows: The method is characterized by comprising a sintering step of sintering a molded body containing a lithium ion conductor, and a surface roughening step of removing at least a portion of the outer surface of the sintered body and roughening the surface after sintering.
[0026] According to the method for manufacturing a lithium selective permeable film described in (6), some or all of the parts on the outer surface of the lithium ion conductor that have undergone structural or compositional changes due to contact with the firing atmosphere during sintering can be removed in the surface roughening process, thus enabling the production of lithium selective permeable films described in (1) to (5). Therefore, the lithium selective permeable film produced by the manufacturing method described in (6) can reduce the time required for lithium ion recovery and reduce the associated costs.
[0027] (7): In addition, in the method for producing a lithium selective permeable membrane of the present invention, It is preferable that at least one of the following requirements (D), (E), and (F) is met. (D) The surface roughening process makes the arithmetic mean height Ra of all or part of the surface of the sintered body 0.8 μm or more and 20 μm or less. (E) The surface roughening process makes the root mean square gradient Rdq of all or part of the surface of the sintered body 10° or more and 80° or less. (F) The surface roughening process makes the developed area ratio Sdr of all or part of the surface of the sintered body 0.2 or more and 2 or less.
[0028] The lithium selective permeable membrane according to (7) can be manufactured according to (2). Therefore, the lithium selective permeable membrane manufactured by the manufacturing method according to (7) can reduce the time required for lithium ion recovery and reduce the cost.
[0029] (8): In addition, in the method for producing a lithium-selective permeable membrane of the present invention, It is preferable that the surface roughening treatment is a blast treatment.
[0030] According to the method for manufacturing a lithium selective permeable film described in (8), the removal of the surface of the sintered body and the roughening treatment are performed simultaneously and in a short time by blast treatment. Furthermore, residual stress can be introduced into the lithium ion conductor, improving the strength and durability of the lithium ion conductor and, consequently, the lithium selective permeable film. Therefore, a lithium selective permeable film with excellent durability can be manufactured without complicating the manufacturing process. [Brief explanation of the drawing]
[0031] [Figure 1] Figure 1 is a schematic diagram of a lithium-ion recovery system using a lithium-selective permeable membrane. [Figure 2] Figure 2 shows the results of powder X-ray diffraction measurements taken after crushing the sintered lithium-ion conductor prepared in Example 1. [Figure 3] Figure 3 shows an SEM image of the lithium-ion conductor sintered body prepared in Example 1 before surface roughening treatment (az sintering). [Figure 4] Figure 4 shows an SEM image of the surface roughened surface of the lithium-ion conductor sintered body fabricated in Example 1 after surface roughening treatment. [Figure 5] Figure 5 shows the current-time profile when a Li recovery test was performed using the lithium-selective permeable membrane fabricated in Example 1. [Figure 6] Figure 6 shows an SEM image of the surface roughened surface of the lithium-ion conductor sintered body prepared in Comparative Example 3, after surface roughening treatment and subsequent annealing treatment. [Modes for carrying out the invention]
[0032] The present invention will be described in detail below with reference to embodiments and accompanying drawings.
[0033] (Configuration of a lithium-ion recovery system) Figure 1 is a diagram illustrating the configuration of a lithium ion recovery device 1 using a lithium selective permeable membrane 10. As shown in Figure 1, the lithium ion recovery device 1 comprises a lithium selective permeable membrane 10, a first electrode 121, and a second electrode 122. The lithium selective permeable membrane 10 has a configuration described later and selectively allows lithium ions 131 contained in the first liquid, the stock solution 111, to pass through. The lithium selective permeable membrane 10 moves the lithium ions 131 in the stock solution 111 to the second liquid, the recovery solution 112, by selectively allowing lithium ions 131 to pass through from the stock solution 111 which contains multiple ions. In this case, it is preferable that the lithium selective permeable membrane 10, which has high selective permeability, be used together with electrodes and the like that have a configuration that enhances this permeability.
[0034] The first electrode 121 and the second electrode 122 are positioned to face one main surface (left side) and the other main surface (right side) of the lithium selective permeable membrane 10 in Figure 1, respectively. Here, the first electrode 121 and the second electrode 122 are the anode and cathode, respectively, in the lithium ion recovery device 1, and the first electrode 121 and the second electrode 122 may or may not be in direct contact with the lithium selective permeable membrane 10. With this configuration, the potential difference between the one main surface and the other main surface of the lithium selective permeable membrane 10 is maintained at a constant potential difference. Preferably, the materials for the first electrode 121 and the second electrode 122 are components of the stock solution 111 or the recovery solution 112 and conductive materials that do not undergo chemical reactions, respectively. In this case, the materials of the first electrode 121 and the second electrode 122 may be the same, or they may be different from the viewpoint of ionization tendency.
[0035] The stock solution 111 is an aqueous solution containing lithium ions 131, such as brine from a salt lake, lithium ore, industrial waste (such as discarded lithium secondary batteries), or treated seawater. The stock solution 111 is supplied to the lithium ion recovery device 1 from the sea, a salt lake, or a stock solution storage tank by stock solution piping and a pump (not shown). Furthermore, the pH of the stock solution 111 may be adjusted from the viewpoint of increasing the lithium ion permeation rate and thus the lithium ion recovery rate. In this case, it is preferable to make the stock solution 111 alkaline as disclosed in Patent Document 1, but it may also be made non-alkaline. In addition, when seawater is used as the stock solution 111, a solution from which monovalent ions (lithium ions, sodium ions, etc.) have been separated in advance using a cation exchange membrane may be used as the stock solution 111.
[0036] The recovered liquid 112 is an aqueous solution containing lithium ions 131 that have permeated from the stock solution 111. The recovered liquid 112 can be discharged from the lithium ion recovery device 1 by recovery liquid piping and a pump (not shown), and stored in a recovery liquid storage tank or the like. Subsequently, CO2 bubbling or the like may be generated in the recovery liquid storage tank or the like to recover the lithium ions 131 as a carbonate precipitate.
[0037] The first electrode 121 and the second electrode 122 are connected via conductive lead wires, and a DC power supply 14 is interposed between the lead wires to maintain a constant potential difference between the first electrode 121 and the second electrode 122. The shapes of the first electrode 121 and the second electrode 122 are not particularly limited. For example, it is preferable that the first electrode 121 and the second electrode 122 have a mesh shape as disclosed in Patent Document 1 and be fixed to the lithium selective permeable film 10. Alternatively, for example, a current collector made of a carbon felt sheet or the like may be interposed between each of the mesh-shaped first electrode 121 and the second electrode 122 and the lithium selective permeable film 10. Furthermore, as in existing Daniell cells, each of the first electrode 121 and the second electrode 122 may be formed in a substantially plate shape.
[0038] Furthermore, the lithium-ion recovery device 1 using the lithium-selective permeable membrane 10 of this embodiment can recover lithium ions 131 by applying a voltage, or it can be used as a battery to extract power without applying an external voltage. In this case, during the process of moving lithium ions 131 from the raw solution 111 to the recovery solution 112, a voltage is generated in which the first electrode 121 becomes the negative electrode and the second electrode 122 becomes the positive electrode. On the other hand, when a voltage is applied to the lithium-ion recovery device 1, the flow of lithium ions 131 can be increased compared to when no voltage is applied, thereby improving the recovery efficiency of lithium ions 131.
[0039] The lithium-selective permeable film 10 may be composed solely of lithium ion conductors, or it may be composed of a composite of lithium ion conductors and other materials that do not conduct lithium ions. For the purpose of improving flexibility, the lithium-selective permeable film 10 may be a composite of lithium ion conductor particles and a resin. Furthermore, for the purpose of improving strength, the lithium-selective permeable film 10 may be a composite of a thin film lithium ion conductor and a porous support that supports it. From the standpoint of complexity of the manufacturing process and manufacturing costs, it is preferable that the lithium-selective permeable film 10 be composed solely of a sintered lithium ion conductor.
[0040] The lithium-selective permeable membrane 10 is provided to separate the stock solution 111, which contains multiple ions including lithium ions 131 and unspecified ions 132 (ions other than lithium ions 131), from the recovery solution 112, which is the destination for the recovery of lithium ions 131. In this case, the lithium-selective permeable membrane 10 must be provided so that the surface roughened surface 101, which is roughened by the surface roughening treatment described later, faces the stock solution 111. The lithium-selective permeable membrane 10 may also be formed in the shape of a sphere, cylinder, or octahedron, or it may be plate-shaped or have at least one recess or protrusion on a part of the aforementioned shape. In this case, the lithium-selective permeable membrane 10 only needs to be able to separate the stock solution 111 and the recovery solution 112, and the shape of the lithium-selective permeable membrane 10 is not particularly limited. Furthermore, the surface roughened surface 101, which will be described later, may be provided according to the electric field generated in the lithium ion recovery device 1. For example, the surface roughening surface 101 may be provided on the surface facing the undiluted solution 111, in a region where the electric flux density perpendicular to that surface is relatively large when a voltage is applied to the lithium ion recovery device 1.
[0041] The lithium selective permeable membrane 10 has a surface roughened surface 101 (indicated by the thick line in Figure 1). The surface roughened surface 101 is provided on part or all of the outer surface of the lithium selective permeable membrane 10. As mentioned above, the surface roughened surface 101 must be provided so as to face the raw solution 111. In Figure 1, the unprocessed surface 102, which has not undergone surface roughening treatment, is provided on the main surface of the lithium selective permeable membrane 10 that faces the recovered liquid 112. However, it is not limited to this, and in this case, the main surface of the lithium selective permeable membrane 10 that faces the recovered liquid 112 may have the surface roughened surface 101 provided on part or all of it, or the unprocessed surface 102, which has not undergone surface roughening treatment, may be provided on all of it.
[0042] The surface roughened surface 101 is roughened by removing the sintered body surface layer and performing surface roughening by an arbitrary surface roughening treatment method described later. The arithmetic mean height Ra of the surface on all or part of the surface roughened surface 101 is preferably 0.8 μm to 20 μm, more preferably 1.5 μm to 15 μm, and even more preferably 2.0 μm to 10 μm. In this embodiment, the surface roughness is expressed in Ra, but is not limited to this and may be expressed in root mean square gradient Rdq. In this case, the root mean square gradient Rdq of the surface on all or part of the surface roughened surface 101 is preferably 10° to 80°, more preferably 12° to 70°, and even more preferably 14° to 60°. These Ra and Rdq values can be calculated using a stylus-type surface roughness meter. The measurement conditions for all or part of the surface are preferably evaluated using the reference length, measurement length, and cutoff value recommended in JIS B 0601-2001 or ISO 4287-1997, according to the degree of surface roughness.
[0043] Furthermore, the surface of all or part of the surface roughened surface 101 in this embodiment may be expressed by the surface roughness parameter, the unfolded area ratio Sdr. In this case, the unfolded area ratio Sdr is preferably 0.2 or more and 2 or less, more preferably 0.3 or more and 1.8 or less, and even more preferably 0.5 or more and 1.5 or less. The surface roughness parameter, the unfolded area ratio Sdr, can be calculated using a non-contact surface roughness meter.
[0044] Furthermore, it is preferable that all or part of the surface roughened surface 101 in this embodiment does not have a step-and-terrace structure on the surface of the sintered body particles. The presence or absence of a step-and-terrace structure on the surface roughened surface 101 can be determined, for example, by examining the SEM image of the surface.
[0045] In this embodiment, the surface roughened surface 101 preferably has a uniform surface that satisfies the above conditions, but is not limited to this. For example, it may include two or more surface roughened surfaces 101 having different configurations. In this case, it is preferable that at least one surface roughened surface 101 satisfies the conditions regarding surface roughness or the presence or absence of a step-and-terrace structure. In this case, the plurality of surface roughened surfaces 101 may vary intermittently or continuously in the horizontal direction of the surface. The conditions on these surface roughened surfaces 101 can be adjusted according to the design of the lithium-ion recovery device 1.
[0046] The material of the lithium selective permeable membrane 10 in this embodiment is not particularly limited as long as it is a material that can selectively permeate lithium ions 131. As the material of the lithium selective permeable membrane 10, it is preferable to use lithium lanthanum titanate, which is a superlithium ion conductor that has high ionic conductivity to lithium ions 131 and does not react with water and components in aqueous solutions, from the viewpoint of permeating lithium ions 131 and suppressing reactions with water and other aqueous solutions. As lithium lanthanum titanate, Li x La (2-x) / 3 It is preferable to use lithium lanthanum titanate TiO3 such that x < 2 / 3, and more preferably Li 0.29 La 0.57 It is TiO3.
[0047] The lithium-selective permeable membrane 10 can be a lithium-ion conductor having a perovskite-type crystal structure, such as lithium lanthanum titanate, as well as a lithium-ion conductor having a NASICON-type crystal structure, a lithium-ion conductor having a garnet-type crystal structure, or any other type of lithium-ion conductor. Furthermore, it is not limited to the above crystal structures; any ion conductor having high lithium-ion conductivity and that can stably exist in the stock solution 111 and the recovery solution 112 used for lithium-ion recovery can be used as the lithium-selective permeable membrane 10.
[0048] In addition, from the viewpoint of sufficiently recovering lithium ions 131, the lithium ion permeation rate in the lithium selective permeation membrane 10 in the present embodiment is 0.4 mmol / (hr·cm 2 ·(mol / L)) or more, preferably 0.5 mmol / (hr·cm 2 ·(mol / L)) or more, more preferably 0.6 mmol / (hr·cm 2 ·(mol / L)) or more in a lithium permeation test within a temperature range of 22°C or higher and 24°C or lower. The above-mentioned lithium permeation rate is calculated from the following formula (1).
[0049] V = M / (T·S·C) ··(1)
[0050] Here, M is the permeation amount (mmol) of lithium ions 131 that have permeated through the lithium selective permeation membrane 10, T is the time (hr) required for the lithium ions 131 with the permeation amount M to permeate, S is the effective membrane area (cm 2 ) of the lithium selective permeation membrane 10, and C is the lithium ion concentration (mol / L) in the stock solution 111.
[0051] (Method for manufacturing a lithium selective permeation membrane) Next, a method for manufacturing the lithium selective permeable membrane 10 of this embodiment will be described. The lithium selective permeable membrane 10 may be composed solely of a lithium ion conductor, or it may be composed of a composite of a lithium ion conductor and another material that does not have lithium ion conductivity. The structure of the lithium selective permeable membrane 10 must be a structure without through holes, as it is necessary to separate the raw solution 111 and the recovered solution 112 using the lithium selective permeable membrane 10. There are no particular restrictions on the method for producing the lithium selective permeable membrane 10 without through holes, but it is preferable to use a densified sintered body as the lithium ion conductor. The procedure for producing this sintered body is to crush particles that can constitute the sintered body as the target lithium ion conductor to a desired particle size range, granulate them as necessary, and then mix them with any additives such as a sintering aid, dispersant, pore-forming agent, mold release agent and binder, and mold them into any shape (a shape that fits the lithium ion recovery device 1 used). There are no particular restrictions on the molding method, and it can be appropriately selected according to the shape of the molded product, such as sheet molding, uniaxial press, cold isostatic pressing, or warm isostatic pressing. The molded product may be further processed into any desired shape by machining as needed.
[0052] Next, the molded body is sintered, but a degreasing step may be performed before sintering to decompose or remove organic matter contained in the binder of the mixture. The sintering temperature and sintering time in the sintering process are set to conditions suitable for obtaining a sintered body as a lithium ion conductor. For example, to obtain a sintered body of lithium lanthanum titanate as a lithium ion conductor, it is preferable to sinter at a temperature range of 1100°C to 1500°C for a holding time of 5 hours to 100 hours. At temperatures below 1100°C, sintering does not progress even with time, so a dense body cannot be obtained, and at temperatures above 1500°C, the molded body and the sintered member fuse and react, making it impossible to obtain a good sintered body. Furthermore, from the viewpoint of suppressing changes in the surface structure or composition of the molded body due to the influence of the firing atmosphere during sintering, the molded body may be embedded in the same powder as the molded body, such as mother powder or cover powder, before the molded body is sintered.
[0053] Next, a roughened surface 101 is provided on the outer surface of the lithium selective permeable film 10 by surface roughening treatment on part or all of the outer surface of the obtained sintered body (az sintered body). At this time, it is preferable that the arithmetic mean height Ra of the roughened surface 101 is 0.8 μm or more and 20 μm or less, or the root mean square gradient Rdq is 10° or more and 80° or less, or the developed area ratio Sdr is 0.2 or more and 2 or less, but it is not limited to these, and may be within the numerical ranges mentioned above.
[0054] Furthermore, while there are no particular limitations on the depth to which the surface layer is removed in the surface roughening treatment of the outer surface of the obtained sintered body (az sintered body), it is preferable to remove at least 5 μm. From the viewpoint that changes in structure and composition occur due to the influence of the firing atmosphere during sintering, it is preferable to vary the removal depth according to the material type or composition of the ion conductor or the temperature or time of the sintering process. For example, the removal depth may be adjusted according to the sintering time, or according to the sintering temperature and sintering time. In this case, it is preferable to remove the surface layer to a depth where the surface roughened surface 101 has the desired structure, composition, or particle size distribution.
[0055] The above surface roughening method is preferably performed based on blasting, and more preferably based on sandblasting, from the viewpoint of simultaneously removing the surface layer and forming a surface roughened surface 101 with a surface roughness of Ra of 0.8 μm to 20 μm, or root mean square gradient Rdq of 10° to 80°, or developed area ratio Sdr of 0.2 to 2. In this case, residual stress can be imparted to the sintered body, thereby improving the strength and durability of the sintered body. Furthermore, this embodiment is not limited to sandblasting, and may also be performed using blasting such as wet blasting or shot blasting, as well as dry or wet mechanical polishing, chemical etching, etc. The abrasive grains used in the blasting are not particularly limited, but may include alumina abrasive grains, SiC abrasive grains, glass abrasive grains, zircon abrasive grains, etc.
[0056] If a sintered body is subjected to the surface roughening treatment described above, followed by a high-temperature heat treatment process such as annealing, changes in the surface structure or composition may occur due to the influence of the firing atmosphere during the heat treatment, similar to the sintering process. Therefore, it is preferable to use the lithium selective permeable film 10 without performing a high-temperature heat treatment process (generally above the Debye temperature of the material) that allows the atoms constituting the lithium ion conductor to diffuse after the surface roughening treatment.
[0057] By observing the surface morphology of the lithium selective permeable film 10, it is determined whether the surface of the lithium selective permeable film 10 is a surface that has undergone surface roughening treatment after the final heat treatment process, or a surface that has not undergone surface roughening treatment after the final heat treatment process. For example, in the case of a sintered body of lithium lanthanum titanate, on the surface of the sintered body after sintering, steps exist at the interfaces (grain boundaries) of the crystal grains on the surface of the ceramic particles constituting the sintered body, and a step-and-terrace structure is observed on the surface of the crystal grains as a trace of grain growth due to sintering. On the other hand, on the surface roughened surface 101 after heat treatment, since the surface layer has been physically removed, steps along the grain boundaries and step-and-terrace structures as growth traces of crystal grains are not observed, and a surface morphology corresponding to the surface roughening method is observed. For example, in the case of blast treatment, a rough surface without regularity is formed. Also, in the case of mechanical polishing, linear scratches similar to those seen in polishing scratches are observed.
[0058] Therefore, since it is necessary to reliably remove any parts of the surface roughened surface 101 that were affected by the firing atmosphere during heat treatment, it is preferable that the surface roughened surface 101 does not have a step-and-terrace structure of sintered body particle surface formed during heat treatment. As described above, it is easy to determine whether the surface is as it was after heat treatment (sintering process or annealing process) or whether it is a surface that has been sufficiently surface roughened after the final heat treatment.
[0059] The lithium-selective permeable film 10 of this embodiment can be obtained by the method described above. However, the method for manufacturing the lithium-selective permeable film 10 is not limited to the method described above, and can be modified within a range that can achieve the objectives of this embodiment.
[0060] (Evaluation of lithium permeation rate) By installing the lithium-selective permeable membrane 10, fabricated using the method described above, into the lithium-ion recovery apparatus 1 with the configuration described above, and applying a voltage to the first electrode 121 and the second electrode 122, lithium can be recovered.
[0061] At this time, it is known that the permeation rate of lithium ions 131 that permeate the lithium selective permeable membrane 10 mainly depends on the temperature of the lithium selective permeable membrane 10, the pH of the stock solution 111, and the lithium ion concentration in the stock solution 111. Therefore, when evaluating the lithium permeation rate, the lithium permeation rate is calculated as the amount of lithium ions permeated per unit area of the lithium selective permeable membrane 10, per unit time, and per unit volume of lithium ion concentration in the stock solution 111, under constant temperature and constant pH of the stock solution 111 (unit: mmol / (hr·cm)). 2 It is preferable to calculate it as (mol / L). If the lithium permeation rate is as defined above, the lithium permeation rate can be compared and evaluated as the performance of the lithium selective permeation membrane 10 itself.
[0062] The amount of lithium ions permeated can be directly determined by evaluating the lithium ion concentration of the raw solution 111 and the recovered solution 112 before and after the lithium permeation test using ICP analysis or other methods. Alternatively, it can be determined from the current value that flows when a voltage is applied to the lithium ion recovery device 1 using the following equation (2).
[0063] M = Itα / nF ··(2)
[0064] Here, M is the number of moles of lithium ions 131 that have permeated the lithium-selective permeable membrane 10, I is the current value flowing through the device, t is time, F is the Faraday constant, and n is the valence (1 for lithium ions). α represents the current efficiency, a parameter indicating the proportion of the current value attributable to the permeation of lithium ions 131 out of the total current value flowing through the device, and takes a value between 0 and 1. For example, the amount of lithium ions 131 that have moved can be determined from the value obtained by multiplying the area enclosed by the current-time curve (obtained by measuring and recording the current at regular intervals while a constant voltage is applied) by the current efficiency and dividing by the Faraday constant.
[0065] The current efficiency α is affected by the configuration of the lithium-ion recovery device 1 or the presence or absence of electronic conductivity of the lithium selective permeable membrane 10. The current efficiency α can be determined by calculating the actual lithium-ion permeation amount by determining the amount of lithium ions 131 contained in the recovered liquid 112 by ICP analysis, etc., and also by calculating the theoretical lithium-ion permeation amount from the total current value that flowed assuming α=1 using equation (2), and then dividing the actual lithium-ion permeation amount by the theoretical value.
[0066] The lithium ion permeation rate defined above can be determined by dividing the lithium ion permeation amount calculated by the above method by the total time required for permeation, further by the effective membrane area of the lithium selective permeation membrane 10, and further by the lithium ion concentration in the stock solution 111. [Examples]
[0067] Next, examples of this embodiment will be described with reference to the experimental results. The experimental results described for each example and comparative example are summarized in Table 1.
[0068] (Fabrication of lithium-selective permeable membranes) Lithium lanthanum titanate powder (manufactured by Toho Titanium Co., Ltd.) was processed using a ball mill to adjust its particle size. A binder, dispersant, plasticizer, and solvent were then added to prepare a slurry. The resulting slurry was formed into a sheet and dried to obtain a green sheet with a thickness of approximately 700 μm.
[0069] The obtained green sheet was sandwiched between porous ceramic plates and subjected to a heat treatment at 1000°C for 3 hours under atmospheric conditions to degrease and calcinate. For comparison, in Comparative Example 3, described later, both sides of the prepared green sheet were sandwiched between #200 nylon mesh sheets, and then both sides were sandwiched between metal plates while uniaxial pressure pressing was performed. This created #200 mesh marks on both sides of the green sheet, resulting in a surface textured finish. After the textured finish of the green sheet, it was subjected to a heat treatment at 1000°C for 3 hours under atmospheric conditions to degrease and calcinate.
[0070] Next, the obtained calcined body was sandwiched between dense ceramic plates and sintered by heat treatment at 1230°C for 72 hours under atmospheric conditions. The relative density of the obtained sintered body was over 98%, and a dense ceramic sheet without through-holes was obtained. Figure 2 shows the results of powder X-ray diffraction measurements (CuKα source) taken by crushing the obtained ceramic sheet and adding silicon powder as an internal standard. From the results in Figure 2, it was confirmed that the obtained ceramic sheet consists of the crystalline phase of lithium lanthanum titanate (the target ion conductor).
[0071] (Surface roughening treatment) Next, the obtained sintered ceramic sheet was cut to approximately 50 mm x 50 mm, and the central 40 mm x 40 mm area on both sides was subjected to surface roughening treatment using the method described in Table 1, thereby obtaining Examples 1 to 4 and Comparative Examples 1 to 4. At this time, the depth of surface layer removal was calculated by measuring the difference in thickness of the ceramic sheet before and after blasting. In Comparative Example 3, after surface roughening treatment, the surface roughened ceramic sheet was again heat-treated at 1230°C for 72 hours and annealed. Figure 3 is an SEM image of the surface of the sintered body in Example 1 before surface roughening treatment, and Figure 4 is an SEM image of the surface roughened surface 101 of the sintered body after surface roughening treatment. As can be seen in Figure 3, on the surface of the lithium lanthanum titanate sintered body after sintering, steps exist along the interfaces (grain boundaries) of the ceramic crystal grains, and on the surface of some crystal grains, a stepped pattern consisting of step-and-terrace structures was observed as traces of grain growth during sintering. On the other hand, as shown in Figure 4, on the surface roughened surface 101, which was treated with blasting, no steps along the grain boundaries or step-and-terrace structures on the crystal grain surfaces, as shown in Figure 3, were observed, and a rough surface without regularity was observed. Also, although not shown, similarly, on the surface roughened surface 101 of Examples 2-4 and Comparative Examples 1-2, no steps along the grain boundaries or step-and-terrace structures on the crystal grain surfaces, as shown in Figure 3, were observed, as shown in Figure 3.
[0072] Figure 6 shows an SEM image of the surface roughened in Comparative Example 3, after surface roughening treatment followed by annealing with a second heat treatment at 1230°C for 72 hours. Even in the surface roughened surface 101, which was roughened by blast treatment, the subsequent annealing treatment rearranged the atoms, resulting in the observation of a step-and-terrace structure as steps along grain boundaries and crystalline grain-like growth marks, similar to the surface after sintering. A similar step-and-terrace structure was also observed in Comparative Example 4, although it is not shown.
[0073] [Table 1]
[0074] (Evaluation of surface roughness of lithium-selective permeable film) The linear roughness of the surface (surface roughened surface 101) of the ceramic sheets (Examples 1-4 and Comparative Examples 1-4) prepared using the method described above was measured. In Comparative Examples 1 and 4, which were not subjected to surface roughening treatment, the linear roughness of the unprocessed surface 102 was measured. When determining the linear roughness, the arithmetic mean height Ra and the root mean square gradient Rdq were measured using a stylus-type surface roughness meter (Taylor Hobson Form Talysurf PGI1250A). The evaluation length and cutoff value (λc) were adopted according to the recommended values in JIS B 0601-2001 or ISO 4287-1997 standards, depending on the degree of surface roughness. Measurements were taken at five arbitrary points on the surface roughened surface 101 of the ceramic sheet. The direction in which the stylus was scanned was also selected arbitrarily each time a measurement was taken. From the five measurement results obtained, the average value was calculated, and this average value was evaluated as the line roughness value.
[0075] Next, the surface roughness of the ceramic sheets (all surfaces) of Examples 1-4 and Comparative Examples 1-4, which were prepared using the method described above, was measured. In Comparative Examples 1 and 4, which were not subjected to surface roughening treatment, the surface roughness of the unprocessed surface 102 was measured. Surface roughness was measured using an optical interference non-contact three-dimensional surface roughness measuring instrument (Taylor Hobson Talisurf CCI HD-XL). The measurement was performed in a mode that evaluates "low reflectivity rough surfaces" and with a 20x magnification objective lens (evaluation area 0.82 mm x 0.82 mm). The measurement was performed at three arbitrary points on the surface roughened surface 101 of the ceramic sheet to be measured. The average value was calculated from the measurement results of the three points, and this average value was evaluated as the surface roughness. Table 2 shows the line roughness and surface roughness obtained for Examples 1-4 and Comparative Examples 1-4.
[0076] [Table 2]
[0077] (Evaluation of lithium permeation rate using lithium selective permeable membrane) The ceramic sheets of Examples 1-4 and Comparative Examples 1-4 obtained by the method described above were used as lithium-selective permeable membranes 10 (effective membrane area: 40 mm x 40 mm) and installed in the lithium-ion recovery apparatus 1 as shown in Figure 1, and a lithium recovery test was conducted. The temperature during the test was in the range of 22°C to 24°C. The stock solution 111 used in the test was a mixed aqueous solution consisting of lithium hydroxide, sodium hydroxide, and potassium hydroxide, adjusted to have lithium ion concentrations of 0.1 mol / L, sodium ion concentrations of 0.1 mol / L, and potassium ion concentrations of 0.1 mol / L, respectively. The recovered solution 112 was pure water. The first electrode 121 (anode side electrode) and the second electrode 122 (cathode side electrode) were metal electrodes that are resistant to corrosion by the stock solution 111 and the recovered solution 112, respectively. At this time, the first electrode 121 and the second electrode 122 were electrically connected to the lithium-selective permeable membrane 10 with carbon felt during the test. The voltage applied to the lithium-selective permeable membrane 10 was set to 5V. During the test, the solutions were thoroughly stirred to ensure that the lithium ion concentration in the stock solution 111 and the recovered solution 112 was uniform. Current values were recorded at approximately 30-second intervals from the start of voltage application, and the test continued for approximately 4 days (times shown in Table 3 below). Figure 5 shows the results of plotting the recorded current value divided by the effective membrane area (current density) in Example 1. As shown in Figure 5, the current density decreased monotonically from the start of voltage application. This is because the lithium ion concentration in the stock solution 111 decreases as lithium ions 131 permeate.
[0078] The stock solution 111 before the start of the test and the recovered solution 112 after the test time described in Table 3 below were sampled and subjected to ICP analysis. The recovery rates (the ratio of each ion amount in the stock solution 111 to the amount recovered in the recovered solution 112) of lithium ions 131, sodium ions (unspecified ions 132), and potassium ions (unspecified ions 132) after the test time described in Table 3 below were measured. At this time, the recovery rates of sodium ions and potassium ions were 0% in all of Examples 1-4 and Comparative Examples 1-4. In addition, the theoretical value of lithium ion permeation, calculated using formula (1) from the total amount of current flowed up to the end of the test time, and the current efficiency α, calculated from the measured value of lithium ion permeation by ICP analysis were measured.
[0079] Furthermore, using α obtained by the above method, the lithium ion permeation amount (unit: mmol) from the start of voltage application to 1 hour later can be calculated from equation (2), and the time required (1 hr) and effective film area (16 cm²) can also be calculated. 2 The lithium ion permeation rate at the beginning of the test was calculated by dividing the result by the lithium ion concentration in the stock solution 111 (approximately 0.1 mol / L as it was immediately after the start of the test). Table 3 shows the lithium ion recovery rate, theoretical lithium permeation amount, measured lithium permeation amount, current efficiency, and lithium permeation rate for Examples 1-4 and Comparative Examples 1-4, based on the calculation method described above.
[0080] [Table 3]
[0081] Referring to Table 3, the lithium ion permeation rate of the lithium selective permeable membrane 10 prepared in Comparative Example 1 was (0.31 mmol / (hr·cm)). 2 The lithium ion permeation rate of the lithium selective permeable membrane 10 prepared in Examples 1-4 was 0.47-1.42 mmol / (hr·cm) relative to (mol / L). 2It was found that the (mol / L) ratio was significantly larger. This indicates that a superior lithium ion permeation rate can be obtained by surface roughening the surface of the sintered body. Furthermore, referring to Tables 2 and 3, it was shown that the lithium ion permeation rate increases as the arithmetic mean height Ra of the surface roughened surface increases, or as the root mean square gradient Rdq increases, or as the developed area ratio Sdr increases.
[0082] The experimental results of Comparative Example 2 support the above. The lithium-selective permeable film 10 prepared in Comparative Example 2, like the lithium-selective films prepared in Examples 1 to 4, has a surface roughened surface 101 in which approximately 10 μm of the surface layer was removed by surface roughening treatment after sintering. However, the lithium ion permeation rate of the lithium-selective permeable film 10 prepared in Comparative Example 2 was significantly lower than that of the lithium ion permeation rate of the lithium-selective permeable films 10 prepared in Examples 1 to 4. This indicates that even with a surface roughened surface 101 in which the surface layer from sintering is removed by surface roughening treatment, if the surface roughened surface 101 does not have a sufficiently large arithmetic mean height Ra (0.8 μm or more), or root mean square gradient Rdq (10° or more), or developed area ratio Sdr (0.2 or more), the excellent lithium ion permeation rate obtained in Examples 1 to 4 cannot be obtained. In other words, the importance of surface roughness of the surface roughened surface 101 has been demonstrated.
[0083] Furthermore, the lithium selective permeable film 10 prepared in Comparative Example 3 was surface roughened using the same method as in Example 3, but after the surface roughening treatment, an annealing treatment was performed, resulting in the formation of a crystalline grain surface with a step-and-terrace structure influenced by the sintering atmosphere during heat treatment on the surface-treated surface. Consequently, the lithium permeation rate of Comparative Example 3 is drastically lower than that of Example 3. This result indicates that, in order to obtain an excellent lithium permeation rate, it is undesirable for the surface of the sintered body contained in the lithium selective permeable film 10 to be in an as-sintered or as-annealed state, and that it is necessary to remove the surface layer portion influenced by the sintering atmosphere during heat treatment.
[0084] The lithium-selective permeable film 10 prepared in Comparative Example 4 had a sintered surface with an extremely large arithmetic mean height Ra, root mean square gradient Rdq, and unfolded area ratio Sdr, achieved by roughening the green sheet. However, similar to Comparative Example 3, it had the surface state of an az sintered film without surface roughening treatment after sintering, and therefore, a good lithium permeation rate could not be obtained.
[0085] The above results indicate that in order to obtain a lithium selective permeable film 10 having an excellent lithium permeation rate, it is necessary to remove the surface layer portion that is affected by the firing atmosphere during heat treatment such as sintering or annealing by surface roughening treatment. In other words, these results indicate that the surface roughened surface 101 must be reliably removed so that the step-and-terrace structure formed as growth marks on the surface of the sintered body surface particles during heat treatment does not appear, and in addition, it is necessary to form a surface roughened surface 101 with a relatively large arithmetic mean height Ra, root mean square gradient Rdq, or developed area ratio Sdr.
[0086] This embodiment has been described based on the examples above. From this description, it has been shown that the lithium-selective permeable membrane 10 of this embodiment reduces the time required for lithium ion recovery and also reduces the cost. Therefore, the lithium-selective permeable membrane 10 of this embodiment can be a suitable component for recovering lithium ions 131 from seawater or industrial waste (such as discarded lithium secondary batteries).
[0087] The lithium selective permeable membrane 10 and the method for manufacturing the lithium selective permeable membrane 10 of this embodiment have been described based on the embodiment and examples. However, this embodiment can be used in addition to the above-described embodiments and examples of use, within the scope of its intended purpose and technical scope. Furthermore, the embodiments and examples of use of this embodiment can be easily modified and altered by those skilled in the art. [Explanation of Symbols]
[0088] 1...Lithium ion recovery device, 10...Lithium selective permeable membrane, 101...Surface roughened surface, 102...Unprocessed surface, 111...First liquid (stock solution), 112...Second liquid (recovered solution), 121...First electrode (anode), 122...Second electrode (cathode), 131...Lithium ions, 132...Unspecified ions.
Claims
1. A lithium-selective permeable film comprising a sintered body of a lithium-ion conductor, characterized in that at least a portion of the outer surface of the lithium-selective permeable film is composed of a surface roughened surface.
2. A lithium-selective permeable membrane according to claim 1, characterized in that it satisfies at least one of the following requirements (A), (B), and (C). (A) The arithmetic mean height Ra on all or part of the surface roughened is 0.8 μm or more and 20 μm or less. (B) The root mean square gradient Rdq on all or part of the surface roughened is 10° or more and 80° or less. (C) The unfolded area ratio Sdr on all or part of the surface roughened is 0.2 or more and 2 or less.
3. A lithium-selective permeable membrane according to claim 1, A lithium-selective permeable film characterized in that the surface of the sintered body particles on all or part of the surface roughened surface does not have a step-and-terrace structure.
4. A lithium-selective permeable membrane according to claim 1, A lithium-selective permeable film characterized in that the lithium ion conductor is a sintered body of lithium lanthanum titanate.
5. A lithium-selective permeable membrane according to any one of claims 1 to 4, In a lithium permeation test in a temperature range of 22°C to 24°C, the lithium permeation rate V, expressed by the following formula (1), was 0.4 mmol / (hr·cm). 2 A lithium-selective permeable membrane characterized by having a concentration of (mol / L) or higher. V = M / (T・S・C)...(1) Here, M is the amount of lithium ions that have permeated through the lithium-selective permeable membrane (millimoles), T is the time required for the permeation of lithium ions of amount M (hr), and S is the effective membrane area (cm²) of the lithium-selective permeable membrane. 2 ), C is the lithium ion concentration (mol / L) in the undiluted solution.
6. A method for manufacturing a lithium selective permeable film including a sintered body of a lithium ion conductor, characterized by comprising a sintering step of sintering a molded body including a lithium ion conductor, and a surface roughening step of removing the surface layer of at least a portion of the outer surface of the sintered body and roughening the surface after sintering.
7. A method for producing a lithium-selective permeable membrane according to claim 6, characterized in that it satisfies at least one of the following requirements (D), (E), and (F). (D) The arithmetic mean height Ra of all or part of the surface of the sintered body processed by the surface roughening process is 0.8 μm or more and 20 μm or less. (E) The root mean square gradient Rdq of all or part of the surface of the sintered body processed by the surface roughening process is 10° or more and 80° or less. (F) The undeveloped area ratio Sdr of all or part of the surface of the sintered body processed by the surface roughening process is 0.2 or more and 2 or less.
8. A method for producing a lithium-selective permeable membrane according to any one of claims 6 to 7, A method for manufacturing a lithium selective permeable film, characterized in that the surface roughening step is performed by blast treatment.