Not applicable.
Not applicable.
Not applicable.
The present invention generally relates to a method of synthesizing a high-purity phosphate salt of a metal. Although the invention will be illustrated, explained and exemplified by phosphate salts of Fe and Mn useful as an electrode active material for a lithium secondary battery, it should be appreciated that the present invention can also be applied to other fields.
The microminiaturization of electronic components has created widespread growth in the use of portable electronic devices such as cellular phones, pagers, video cameras, facsimile machines, portable stereophonic equipment, personal organizers and personal computers. As a result, the demand of improved power sources for these devices has been increased. Moreover, telecommunication backup batteries, hybrid electric vehicles, and electric vehicles also require advanced battery materials to meet the high demand and performance. Preferably, the battery materials are environmentally benign and relatively low cost to make these expanded battery applications practical. Relevant batteries include primary batteries, i.e., batteries designed for use through a single charging cycle, and secondary batteries, i.e., batteries designed to be rechargeable. Some batteries designed essentially as primary batteries may be rechargeable to some extent.
Batteries based on lithium have been the subject of considerable development effort and are being sold commercially. Lithium-based batteries have become commercially successful due to their relatively high energy density. Lithium-based batteries generally use electrolytes containing lithium ions. The negative electrodes for these batteries can include lithium metal or alloy (lithium batteries), or compositions that intercalate lithium (lithium ion batteries). Preferred electroactive materials for incorporation into the positive electrodes are compositions that intercalate lithium. For example, metal phosphates are candidates for the production of cathode materials that intercalate lithium.
An example of lithium-ion battery is the lithium ferrophosphate (LiFePO4, LFP) battery, in which LiFePO4 is used as the cathode material. LFP exhibits some advantages such as low cost, non-toxicity, natural abundance, excellent thermal stability, safety characteristics, electrochemical performance, and specific capacity (170 mA·h/g, or 610 C/g). As such, LFP battery is even finding a number of roles in vehicle use and backup power, among others. However, LFP batteries are still expensive to produce. For instance, in order to manufacture LFP active material and its dopant, one major production method is using iron oxalate as Fe source precursor and NH4H2PO4 as PO4 source precursor. The drawback is that the manufacturing process for iron oxalate and NH4H2PO4 generates hazardous gas, and the processing cost is very high. Another method is the use of fine quality iron phosphate as precursor for both Fe and PO4 source. However, the manufacturing cost for iron phosphate is also very high.
The manufacture of FePO4 also wastes a huge amount of water, and is therefore not environmentally friendly. More than one billion people in the world is water stressed, and do not have access to potable water. About 700 million people in 43 countries face water scarcity, since their annual water supplies drop below 1,000 cubic meters per person per year. In China, more than 538 million people are living in a water-stressed region.
Thus, there is a need of a new method or process of producing LFP and FePO4 at a lower cost and using less water. Advantageously, the present invention provides a novel method of synthesizing a phosphate salt that can overcome the problem.
One aspect of the present invention provides a method of synthesizing a phosphate salt of a metal. The phosphate salt of the metal can be used in many applications, including active electrode composite materials. The method comprises: (i) providing an aqueous solution of the metal M having a first valence value Va (e.g. metal ion MVa, such as Fe2+), wherein the aqueous solution contains a first impurity Ta (such as SO42−); (ii) adding a precipitating composition containing a second impurity Tb to the aqueous solution to form a mixture of a liquid phase and a precipitate composition comprising one or more water-insoluble compounds of the metal having a first valence value M(Va), wherein the liquid phase contains both the first impurity Ta and the second impurity Tb; (iii) separating the precipitate composition and the liquid phase, wherein a residual amount of the first impurity Ta and the second impurity Tb remains in the precipitate composition after the separation; (iv) decreasing the residual amount of the first impurity Ta and the second impurity Tb present in the precipitate composition; and (v) oxidizing the metal having a first valence value M(Va) in the precipitate composition with an oxidizing composition to produce a phosphate salt of the metal having a second valence value Vb, wherein the second valence value Vb is greater than the first valence value Va.
The above features and advantages and other features and advantages of the present invention are readily apparent from the following detailed description of the best modes for carrying out the invention when taken in connection with the accompanying drawings.
The present invention is illustrated by way of example, and not by way of limitation, in the figures of the accompanying drawings and in which like reference numerals refer to similar elements. All the figures are schematic and generally only show parts which are necessary in order to elucidate the invention. For simplicity and clarity of illustration, elements shown in the figures and discussed below have not necessarily been drawn to scale. Well-known structures and devices are shown in simplified form, omitted, or merely suggested, in order to avoid unnecessarily obscuring the present invention.
In the following description, for the purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the present invention. It is apparent, however, to one skilled in the art that the present invention may be practiced without these specific details or with an equivalent arrangement.
Where a numerical range is disclosed herein, unless otherwise specified, such range is continuous, inclusive of both the minimum and maximum values of the range as well as every value between such minimum and maximum values. Still further, where a range refers to integers, only the integers from the minimum value to and including the maximum value of such range are included. In addition, where multiple ranges are provided to describe a feature or characteristic, such ranges can be combined. As used in the description herein and throughout the claims that follow, the meaning of “a”, “an”, and “the” includes plural reference unless the context clearly dictates otherwise. In a reaction equation, “aq” stands for “aqueous”, and “s” stands for solid. Also, as used in the description herein and throughout the claims that follow, the meaning of “in” includes “in” and “on” unless the context clearly dictates otherwise.
In various embodiments, the present invention provides a method of synthesizing a phosphate salt of a metal M. Examples of the metal M includes, but is not limited to, any suitable metal that has multiple (e.g. two) valence values such as Fe, Co, Ni, Mn, Ti, V, or any combination thereof. In specific embodiments, metal M includes, but is not limited to, a transitional metal with multiple valence values such as Fe, Mn, Co, Ni, or any combination thereof.
The term “multiple valence values” is intended to mean that metal M has at least two valence value, defined as a first valence value Va and a second valence value Vb. The second valence value Vb is greater than the first one Va. Vb is an integer greater than 1. Va may be 1, 2, 3, 4, and 5 etc., while Vb may be 2, 3, 4, 5 and 6 etc. For example, Va of Fe, Co, Ni and Mn may be II or +2, and Vb of Fe, Co, Ni and Mn may be III or +3. The present invention provides a method of synthesizing a phosphate salt of a metal M that has the second valence value Vb, represented as M(Vb), M(+Vb), MVb or M+Vb. The salt can therefore be represented as M3(PO4)Vb.
As shown in
In some embodiments, the method as shown in
As described above, the present invention provides a method of synthesizing a phosphate salt of a metal M. Examples of the metal M includes, but is not limited to, any suitable metal that has multiple (e.g. two) valence values such as Fe, Co, Ni, Mn, Ti, V, or any combination thereof. The term “any combination thereof” is intended to mean that two metals M1 and M2 or more are present in the phosphate salt (a “co-salt”) product of M1(Vb1) and M2(Vb2), for example, Fe(III)xMn(III)(1-x)PO4, wherein 0<x<1.
As shown in
In another branch of the method as shown in
Next, step (pre-v) is mixing the first precipitate composition obtained from step (iv-1) and the second precipitate composition obtained from step (iv-2) to form a mixed precipitate composition. Step (v) is oxidizing the first metal and the second metal having their first valence values, i.e. M1(Va1) and M2(Va2), in the mixed precipitate composition with an oxidizing composition to produce a phosphate co-salt of the first metal and the second metal having their second valence values M1(Vb1) and M2(Vb2), i.e. M1uM2v(PO4)w, wherein u>0, v>0, w>0, and u×Vb1+v×Vb2=w×3. The second valence value Vb1 is greater than the first valence value Va1, and the second valence value Vb2 is greater than the first valence value Va2. An example of the product is Fe(III)xMn(III)(1-x)PO4, wherein 0<x<1.
In some embodiments, the method as shown in
The embodiments as shown in
In step (i)/(i-1)/(i-2), an aqueous solution of the metal M having a first valence value M(Va), represented as M(Va), or M+Va, is provided. The aqueous solution is a solution in which the solvent is water. It is usually shown in chemical equations by appending (aq) to the relevant chemical formula. For example, a solution of table salt or sodium chloride (NaCl) in water is represented as Na+ (aq)+Cl− (aq). The word aqueous means pertaining to, related to, similar to, or dissolved in water. The aqueous solution in step (i) of the present invention contains M+Va(aq). The counter ions of the metal cations M+Va(aq) may include one or more anions selected from SO42−, Cl−, and any other suitable anions. In embodiments, the aqueous solution of M(Va) in step (i)/(i-1)/(i-2) includes a sulfate salt of M(Va), a chloride salt of M(Va), or any mixture thereof.
The aqueous solution in step (i)/(i-1)/(i-2) contains a level of a first impurity. The term “first impurity” is defined relative to the final product of the entire process, i.e. the phosphate salt of M(Vb) in or after step (iv), and not relative to the aqueous solution in step (i)/(i-1)/(i-2). The first impurity is not necessarily an impurity for the aqueous solution in step (i)/(i-1)/(i-2). For example, the aqueous solution in step (i)/(i-1)/(i-2) may be a solution of FeSO4, FeCl2, MnSO4, MnCl2, or any mixture thereof. In this example, SO42− and/or Cl− (or “S and/or Cl”) is/are actually the major component(s) in the aqueous solution, but it is (they are) the first impurity for the final product of the method, i.e. the phosphate salt of metal M(Vb).
Step (ii)/(ii-1)/(ii-2) is adding a precipitating composition to the aqueous solution from step (i)/(i-1)/(i-2) to form an precipitate composition comprising one or more water-insoluble compounds of the metal M(Va). In various embodiments, the precipitating composition may be in solid form, liquid form (e.g. an aqueous solution), or a mixture of solid and liquid. The precipitating composition comprises a phosphate salt, a hydrogen phosphate salt, or any mixture thereof, and may therefore constitute a source of phosphate ion PO43− in the final product of the entire process, i.e. the phosphate salt of M(Vb) in or after step (v). In some embodiments, the precipitating composition comprises a phosphate salt of A, a hydrogen phosphate salt of A, a hydroxide of A, a carbonate of A, an oxalate salt of A, or any mixture thereof. Examples of element A include, but are not limited to NH4; an alkali metal ion such Na, K, Rb, Cs, Li; or any mixture thereof. In preferred embodiments, A+ is NH4+, Na+, K+, or any mixture thereof.
The precipitating composition may include a level of a second impurity. The term “second impurity” is also defined relative to the final product of the entire process, i.e. the phosphate salt of M(Vb) in or after step (v). It is not defined relative to the precipitating composition in step (ii)/(ii-1)/(ii-2), or the reaction mixture it formed with the aqueous solution in step (i)/(i-1)/(i-2). For example, element A such as Li, Na, K, Rb, Cs, NH4, or a mixture thereof is (are) actually the major component(s) (not an impurity) in the precipitating composition first, but it/they will become the second impurity for the final product of the method, i.e. the phosphate salt of metal M(Vb). In preferred embodiments, A+ is NH4+, an alkali metal ion such as Na+ and K+, or any mixture thereof. As a result, the second impurity is NH4+, an alkali metal ion such as Na+ and K+, or any mixture thereof.
In step (ii)/(ii-1)/(ii-2), when the precipitating composition is added to the aqueous solution from step (i)/(i-1)/(i-2), a precipitation reaction takes place to convert a reaction mixture that includes a liquid phase or aqueous phase, and a precipitate phase or a solid phase defined as an precipitate composition. In the precipitation process, the valence value Va of M is maintained the same when possible without further oxidization or with minimal oxidization. The liquid phase may have pH greater than 4, such as 5-10 and 6-8. The precipitate composition may contain one or more water-insoluble compounds of the metal M(Va) selected from a phosphate salt of the metal M(Va), a hydrogen phosphate salt of the metal M(Va), a hydroxide of the metal M(Va), a carbonate of the metal M(Va), the metal salt of NH4PO42−, and an oxalate salt of the metal M(Va). The liquid phase now contains a large amount of the first impurity and the second impurity.
Exemplary reactions in step (ii)/(ii-1)/(ii-2) include, but are not limited to, one or more of the following reactions, wherein (s) stands for (solid):
M(II)SO4(aq)+AxH(3-x)PO4(aq)+AOH→M(II)3(PO4)2.nH2O(s)+A2SO4(aq)(wherein A is NH4, Na, K or mixture thereof; x is an integer 1, 2 or 3);
M(II)Cl2(aq)+AxH(3-X)PO4(aq)+NaOH(aq)→M(II)3(PO4)2.nH2O(s)+ACl(aq) (wherein A is NH4, Na, K or mixture thereof; x is an integer 1, 2 or 3);
M(II)SO4(aq)+NH4H2PO4(aq) or(NH4)2HPO4(aq)+NH4OH→NH4M(II)PO4.nH2O(s)+(NH4)2SO4(aq);
M(II)Cl2(aq)+NH4H2PO4(aq) or(NH4)2HPO4(aq)+NH4OH→NH4M(II)PO4.nH2O(s)+NH4Cl(aq);
M(II)SO4(aq)+A2CO3(aq)+AOH(aq)→M(II)CO3.H2O(s)+A2SO4(aq) (wherein A is Na, K or mixture thereof);
M(II)Cl2(aq)+A2CO3(aq)+AOH(aq)→M(II)CO3.H2O(s)+ACl(aq) (wherein A is Na, K or mixture thereof);
M(II)SO4(aq)+AOH→M(II)(OH)2.nH2O(s)+A2SO4(aq) (wherein A is Na, K or mixture thereof);
M(II)Cl2(aq)+AOH→M(II)(OH)2.nH2O(s)+ACl(aq) (wherein A is Na, K or mixture thereof);
M(II)SO4(aq)+A2C2O4(aq)+AOH(aq)→M(II)C2O4.H2O(s)+A2SO4(aq) (wherein A is Na, K or mixture thereof); and
M(II)Cl2(aq)+A2C2O4(aq)+AOH(aq)→M(II)C2O4.H2O(s)+ACl(aq) (wherein A is Na, K or mixture thereof).
In this step, the liquid phase is separated from the reaction mixture formed in step (ii)/(ii-1)/(ii-2) using any known chemical separation techniques, such as filtering. After the separation, the precipitate composition may become a solid amorphous and/or crystallized material. However, it should be appreciated that there remains a level of the first impurity residue and a level of the second impurity residue in the precipitate composition.
For example, the residual amount of the first impurity and the second impurity that remains in the precipitate composition after the separation may be less than 40%, 30%, 20%, 10%, or 5% of the total amount of the first impurity and the second impurity in the reaction mixture before the separation.
This step is to decrease the level of the first impurity and the level of the second impurity in the precipitate composition that has been separated from the reaction mixture of step (iii)/(iii-1)/(iii-2). In certain embodiments, this step may be carried out by washing the one or more water-insoluble compounds of the metal M(Va) with DI water for one or more times until the total amount of the first impurity and the second impurity present in the precipitate composition drops lower than a predetermined level. The predetermined level depends on specific product requirement, and it can be lower than <5000 ppm, <2000 ppm, <1000 ppm, <500 ppm, or <200 ppm.
In preferred embodiments, the washing DI water used in this step is dramatically reduced compared to the washing step in other method in the prior art, the present invention therefore exhibits technical merits such as less consumption of natural resource, and cost-effectiveness.
Step (v) is oxidizing the metal M(Va) present in the high purity product from step (iv)/(iv-1)/(iv-2), to produce a phosphate salt of the metal (M(Vb), wherein Vb>Va. In some embodiments, the oxidization may be carried out with an oxidizing composition comprising hydrogen peroxide, phosphoric acid, and water, at an elevated temperature such as >50° C., e.g. 50-120° C. The pH of reaction mixture in step (v) may go down to as low as 0.5, such as 0.5-1, 0.5-1.5, 1.5-2.5, 1-2, 2.5-3.5, 2-3, or 3-4. In preferred embodiment, step (v) does not increase the level of the first impurity and the level of the second impurity in the reaction mixture.
In preferred embodiments, the final product, i.e. the phosphate salt of the metal having a second valence value, such as M3(PO4)Vb or M1uM2v(PO4)w (wherein u>0, v>0, w>0, and u×Vb1+v×Vb2=w×3), contains 50-500 ppm of the first impurity and the second impurity combined.
In some specific embodiments as shown in
Exemplary reactions in step (v) include, but are not limited to, one or more of the following reactions:
M(II)3(PO4)2.nH2O(s)+H3PO4(aq)+H2O2(aq)→M(II)PO4.nH2O(s)+H2O;
NH4M(II)PO4.nH2O(s)+H3PO4(aq)+H2O2(aq)→M(III)PO4.nH2O(s)+H2O+NH3.H2O;
M(II)CO3.H2O(s)+H3PO4(aq)+H2O2(aq)→M(III)PO4.nH2O(s)+H2O+CO2;
M(II)(OH)2.nH2O(s)+H3PO4(aq)+H2O2(aq)→M(III)PO4.nH2O(s)+H2O.
In various embodiments, the phosphate salt of M(Vb) as the final product may contain less than 500 ppm of the first and second impurities, e.g. <300 ppm, <100 ppm, and <50 ppm. These impurities can be measured using any technique, instrument, and method as known to a skilled artisan in the field. For example, the level of Na and K can be measured by ICP metal analysis, or atomic absorption spectroscopy.
In certain embodiments, the pH value of the reaction mixture in step (v) is maintained between 1.0 and 2.0. In certain embodiments, the temperature of the solution in this step is maintained above 50° C., above 70° C., above 80° C., above 90° C., above 95° C., or above 100° C. In this step, according to the requirements of the product and manufacturing process, the S and Cl may be controlled to be less than about 100 ppm, or less than 80 ppm, or less than 50 ppm, or even lower than that. The amount of S and Cl may be measured using high frequency IR C and S analyzer, and chlorine ion analyzer, as known to a skilled artisan in the field.
In embodiments, the phosphate salt of M(Vb) as the final product in crystal form, in amorphous form, or in a mixture of the two.
In preferred embodiments, the phosphate salt of M(Vb) as the final product is FexMn(1-x)PO4, wherein 0≦x≦1.
In some embodiments, the method of the invention may optionally include two extra steps, (a)/(A) and (b)/(B). Use steps (a) and (b) to illustrate the points that can apply to steps (A)/(B), mutatis mutandis. Step (a) is reacting the metal in substantially pure element form with phosphoric acid to produce a supplemental composition comprising a phosphoric acid, a phosphate salt of the metal having a first valence value, a hydrogen phosphate salt of the metal having a first valence value, a dihydrogen phosphate salt of the metal having a first valence value, or any mixture thereof. Step (b) is mixing the supplemental composition with the precipitate composition after step (iv), but before step (v) and/or during step (v). In this case, the supplemental composition preferably comprises a level of the first impurity that is not higher than that of the already-purified precipitate composition, and a level of the second impurity that is not higher than that of the already-purified precipitate composition either. The supplemental composition may be substantially free of the first impurity and the second impurity.
It should be appreciated that, to synthesize the final product (i.e. highly purified phosphate salt of M(Vb)), both a source of phosphate PO4 and a source of metal M are needed in the method of the invention. The source of phosphate may be the precipitating composition, the oxidizing composition (if contains phosphoric acid), the supplemental composition (if any), or any combination thereof. The source of metal M may be the aqueous solution of the metal M(va) in step (i), the supplemental composition, or both. For example, M(II)NH4PO4 in the precipitate composition (e.g. a precipitate) can be oxidized to M(III)PO4 without the need to supplement any P source material (e.g. phosphoric acid). In this case, the oxidizing composition and/or the supplemental composition (if any) do/does not need to contain any P source material such as phosphoric acid. However, when other M(II) precipitates such as M(II)CO3, M(II)(OH)2, and M(II)C2O4 in the precipitate composition (e.g. a precipitate) are oxidized to M(III)PO4, supplement P source material (e.g. phosphoric acid) is needed from the oxidizing composition and/or the supplemental composition.
In some embodiments, the precipitating composition may not contain any phosphate salt or hydrogen phosphate salt. For example, the precipitating composition may include only a hydroxide of A, a carbonate of A, an oxalate salt of A, or any mixture thereof. In such embodiments, the precipitate composition may not include phosphate, and the method of the invention must include one or more other steps to supplement phosphate. For example, additional step (a) may be needed to provide a supplemental composition comprising a phosphoric acid, a phosphate salt of the metal having a first valence value, a hydrogen phosphate salt of the metal having a first valence value, a dihydrogen phosphate salt of the metal having a first valence value, or any mixture thereof. Alternatively or additionally, the oxidizing composition may function as a source of phosphate, or another source of phosphate.
In a specific embodiment as shown in
M(II)SO4(aq)+A3PO4(aq)+NaOH→M(II)3(PO4-nH2O)2(s)+A2SO4(aq) (here A is NH4, Na, K or mixture thereof)
M(II)Cl2(aq)+APO4(aq)+NaOH(aq)→M(II)3(PO4)2-nH2O(s)+ACl(aq) (here A is NH4, Na, K or mixture thereof)
M(II)SO4(aq)+NH4H2PO4(aq)/or(NH4)2HPO4(aq)+NH4OH→NH4MPO4-nH2O(s)+NH4SO4(aq)
M(II)Cl2(aq)+NH4H2PO4(aq)/or(NH4)2HPO4(aq)+NH4OH→NH4MPO4-nH2O(s)+NH4SO4(aq)
M(II)SO4(aq)+A2CO3(aq)→M(II)CO3-nH2O)2(s)+A2SO4(aq) (here A could be Na, K or mixture thereof)
M(II)Cl2(aq)+A2CO3(aq)+NaOH(aq)→M(II)CO3-H2O(s)+ACl(aq) (here A could be Na, K or mixture thereof)
M(II)SO4(aq)+NaOH→M(II)(OH)2-nH2O)2(s)+A2SO4(aq) (here A could be Na, K or mixture of)
M(II)Cl2(aq)+NaOH(aq)→M(II)(OH)2-H2O(s)+ACl(aq) (here A could be Na, K or mixture thereof)
The S or/and Cl element/component in the liquid phase is removed by solid-liquid separation. The solid phase is further washed to remove remnant S and Cl. The solid precipitant includes the divalent M precipitation without further oxidization, and the content of S or/and C is very low. In this step, according to the requirements of the product and manufacturing process, the S or/and Cl may be controlled to be less than about 1000 ppm, or less than 500 ppm, or less than 200 ppm, or even lower than that.
In the second stage, one or more of water, P source compound, P2O5, phosphoric acid or its ammonium salt, hydrogen peroxide are added to the solid phase precipitant from which impurities have removed, and react under certain temperature, to produce MPO4:
M(II)3(PO4.nH2O)2(s)+H3PO4(aq)+H2O2(aq)→M(III)PO4-nH2O(s)(crystalline)+H2O@T>70° C.;
NH4MPO4-nH2O(s)+H3PO4(aq)+H2O2(aq)→M(III)PO4-nH2O(s)(crystalline)+H2O @T>70° C.;
M(II)CO3(s)+H3PO4(aq))+H2O2(aq)→M(III)PO4-nH2O(s)(crystalline)+H2O+CO2@T>70° C.;
M(II)3(OH-nH2O)2(s)+H3PO4(aq)+H2O2(aq)→M(III)PO4-nH2O(s)(crystalline)+H2O@T>70° C.
In certain embodiments, the pH value of the solution in this stage is maintained between 1.0 and 2.0; and the temperature of the solution in this stage is maintained above 70, 80, 90, 95 or 100° C.
In this stage, according to the requirements of the product and manufacturing process, the S and Cl may be controlled to be less than about 100 ppm, or less than 80 ppm, or less than 50 ppm, or less than 20 ppm, or less than 10 ppm, or even lower than that.
Without intent to limit the scope of the invention, exemplary methods and their related results according to the embodiments of the present invention are given below. Note again that titles or subtitles may be used in the examples for convenience of a reader, which in no way should limit the scope of the invention. Moreover, certain theories are proposed and disclosed herein; however, in no way they, whether they are right or wrong, should limit the scope of the invention.
Fifty mM aqueous solution of FeSO4 was oxidized with hydrogen peroxide, in the presence of 55 mM 85% H3PO4, and with a pH adjusted to between 1 and 2 using NaOH, to yield amorphous FePO4.nH2O precipitate slurry. The amorphous mixture was heated and maintained at constant reflux temperature with continuous stirring for 0.5 to 3 hours to yield crystallized FePO4.2H2O.
FeSO4(aq)+½H2O2(aq)+H3PO4(aq)+NaOH(aq)→FePO4.xH2O(s)(amorphous)+Na2SO4(aq)
FePO4.nH2O(s)(amorphous)→FePO4.nH2O(s)(crystalline)@T>70° C.
The product was separated by filtration to remove the majority of impurities S and Na. The residual impurities were then removed by washing with a big amount of DI water. Using around 500 ml of water for continuous filtration can reduce the impurities to 2000 ppm level. Using 500 ml more water can reduce the impurities to 1000 ppm level. Using 500 ml even more water can reduce the impurities to 700 ppm level. This can go one and on, as more and more water is needed to further decrease the level of impurities.
In the following Examples 2-8, the amount of water used was much lower than that in Example 1. Moreover, the level of impurity S and Na in the final product can be controlled lower than that in Example 1.
50 mM FeSO4.7H2O and 50 mM NH4HPO4 were weighted and dissolved into 100 ml of distilled water in a 500-ml triangular beaker. NH3.H2O solution was then added drop wise into the triangular beaker at a constant rate to adjust pH to a range of from 6.0 to 7.5. NH4FePO4.H2O was precipitated as green material from the solution.
The solid phase NH4FePO4.H2O was separated from the liquid phase by filtration. The majority of the S impurity was gone with the liquid phase. The residual impurities were then removed by washing the solid phase NH4FePO4.H2O with 250 ml of DI water with continuous filtration, and S impurity was decreased below 500 ppm.
The washed NH4FePO4.H2O was placed back into 100 mL DI water, and was then stirred and heated. At the same time, hydrogen peroxide was added dropwise into the mixture to make all Fe(II) turn to Fe(III), and pH was adjusted to 1.5 with H3PO4.
The mixture was heated to, and maintained at, constant reflux temperature with continuous stirring for 0.5 to 3 hours to yield crystallized FePO4.2H2O. The product was separated by filtration, simply washed with 50 mL DI water during continuous filtration, and then dried in an oven at 105° C. for 3 hours to obtain FePO4.2H2O product with 120 ppm of S impurity.
50 mM FeSO4.7H2O was weighted and dissolved into 100 ml of distilled water in a 500 ml triangular beaker. 1M NaOH solution was then added drop wise into the triangular beaker at a constant rate to adjust pH to 6.0-7.5. Bluish Fe(OH)2 was precipitated from the solution.
The solid phase Fe(OH)2 was separated from the liquid phase by filtration. The majority of the S impurity was gone with the liquid phase. The residual impurities was then removed by washing the solid phase Fe(OH)2 with 300 ml of DI water with continuous filtration, decreasing S and Na impurities below 1000 ppm.
The washed Fe(OH)2 was put back into 100 mL DI water containing 55 mM 85% H3PO4, and was stirred and heated. At the same time, hydrogen peroxide was added dropwise into the mixture to convert all Fe(II) turn to Fe(III), and pH was adjusted to 1.5 with H3PO4.
The mixture was heated to and maintained at constant reflux temperature with continuous stirring for 0.5 to 3 hours to yield crystallized FePO4.2H2O. The product was separated by filtration, and simply washed with 50 mL DI water in continuous filtration. The product was then dried in an oven at 105° C. for 3 hours to obtain FePO4.2H2O product containing only 180 ppm of S and Na impurities combined.
50 mM FeSO4.7H2O and 30 mM H3PO4 were weighted and dissolved into 100 ml of distilled water in a 500 ml triangular beaker. 35 mM H3PO4 solution was added into the beaker, and certain amount of 1M NaOH solution was then added drop wise into the triangular beaker at a constant rate to adjust pH between 6.0 and 7.5. Bluish Fe3(PO4)2.8H2O was precipitated from the solution.
The solid phase Fe3(PO4)2.8H2O was separated from the liquid phase by filtration. The majority of the S and Na impurities were gone with the liquid phase. The residual impurities was then removed by washing the solid phase Fe3(PO4)2 with 300 ml DI water by continuous filtration, decreasing S and Na impurities below 1000 ppm.
The washed Fe3(PO4)2.8H2O was put back to 100 mL DI water in a 500 ml beaker, and 25 mM H3PO4 was added into the beaker. The mixture was stirred and heated, and at the same time, hydrogen peroxide was added dropwise into the mixture to oxidize all Fe(II) to Fe(III), and pH was adjusted to 1.5 with H3PO4. The mixture was heated and maintained at constant reflux temperature with continuous stirring for 0.5 to 3 hours to yield crystallized FePO4.2H2O.
The product was separated by filtration, by simply washing with 50 mL DI water in continuous filtration, and by drying in an oven at 105° C. for 3 hours, to obtain FePO4.2H2O product with only 180 ppm of the S and Na impurities combined.
50 mM FeSO4.7H2O was weighted and dissolved into 100 ml of distilled water in a 500 ml triangular beaker. 1M NaOH solution was then added drop wise into the triangular beaker at a constant rate to adjust pH between 6.0 and 7.5. Bluish Fe(OH)2 was precipitated from the solution.
The solid phase Fe(OH)2 was separated from the liquid phase by filtration. The majority of the S impurity was gone with the liquid phase. The residual impurity was then removed by washing the solid phase Fe(OH)2 with DI water and repeated filtration, until S and Na impurities were below 1000 ppm combined.
50 mM MnSO4 and 50 mM NH4H2PO4 were weighted and dissolved into 100 ml of distilled water in a 500 ml triangular beaker. NH3.H2O solution was then added drop wise into the triangular beaker at a constant rate to adjust pH between 6.0 and 7.5. Bluish NH4MnPO4.H2O was precipitated from the solution.
The solid phase NH4MnPO4.H2O was separated from the liquid phase by filtration. The majority of the S impurity was gone with the liquid phase. The residual impurity was then removed by washing the solid phase NH4MnPO4.H2O with DI water and with the repeated filtration, until the level of S impurity was below 500 ppm.
The washed Fe(OH)2 from Example 5, the washed NH4MnPO4.H2O from Example 6, and 55 mM 85% H3PO4 were mixed into 200 mL DI water. The mixture was stirred and heated, and at the same time, hydrogen peroxide was added drop wise into the mixture to convert all Fe(II) turn to Fe(Ill). The pH was adjusted to 1.5 with H3PO4 at this point.
The mixture was heated and maintained at constant reflux temperature with continuous stirring for 0.5 to 3 hours to yield crystallized FexMn(1−x)PO4.nH2O. The product was separated by filtration, and then by simple washing. The product was then dried in an oven at 105° C. for 3 hours to obtain FexMn(1−x)PO4.nH2O product.
2 g pure Fe metal was added to 100 ml 55 mM H3PO4 solution in a 300 ml beaker. The H3PO4 solution with Fe metal was stirred and heated to temperature of 85° C. The reaction was stopped at pH 2.0. Green Fe2(PO4)3.nH2O clear solution was obtained after filtering out any residual Fe metal. The washed Fe(OH)2 from Example 5 was then mixed to the green solution. The mixture was stirred and heated, and in the meanwhile, hydrogen peroxide was added dropwise into the mixture to oxidize all Fe(II) turn to Fe(III). The pH value was adjusted to 1.5 by H3PO4. The mixture was heated and maintained at constant reflux temperature with continuous stirring for 0.5 to 3 hours to yield crystallized FePO4.2H2O. The product was separated by filtration, simply washing with 50 mL DI water with continuous filtration. The product was dried in an oven at 105° C. for 3 hours to obtain FePO4.2H2O product containing 120 ppm of the S and Na impurities combined.
In the foregoing specification, embodiments of the present invention have been described with reference to numerous specific details that may vary from implementation to implementation. The specification and drawings are, accordingly, to be regarded in an illustrative rather than a restrictive sense. The sole and exclusive indicator of the scope of the invention, and what is intended by the applicant to be the scope of the invention, is the literal and equivalent scope of the set of claims that issue from this application, in the specific form in which such claims issue, including any subsequent correction.
This application claims priority to and the benefit of, pursuant to 35 U.S.C. Section 119(e), U.S. provisional patent application Ser. No. 62/334,129, filed May 10, 2016, entitled “PREPARATION OF METAL PHOSPHATE PRECURSOR OF ACTIVE CATHODE LIMPO4 USING HIGH PURITY METAL PHOSPHATE MATERIAL” by Guiqing Huang, the disclosure of which is incorporated herein in their entirety by reference.
Number | Date | Country | |
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62334129 | May 2016 | US |