TWI322131B - Method for purifying electronic grade phosphoric acid - Google Patents

Description

1322131 IX. Description of the invention: [Technical field to which the invention pertains] The present invention relates to a phosphoric acid purification technology 'particularly relates to a low-cost and fast purification method for phosphoric acid for electronic use' for use in electronic grade products (Na, Zhen Metal ions such as Ming, Shu, and iron are required to be below 1.0 ppm. [Prior Art] It is often necessary to use phosphoric acid in the manufacturing process of electronic products, for example, an etching liquid for forming a metal wiring (such as an aluminum wiring) for manufacturing a liquid crystal panel, that is, more than 70% of highly purified phosphoric acid is mixed, but due to electrons The grade specification of phosphoric acid is quite expensive, so the current practice is that the electronic grade specification of phosphoric acid is a large proportion of 'mixed with industrial grade or food grade phosphoric acid to reduce costs, but the quality is not well controlled.

Please refer to Figure 1. Currently, the electronic grade specification of phosphoric acid requires sodium (Na), magnesium (Mg), aluminum (A1), potassium (K), calcium (Ca) and iron (Fe) and other metal ions to be required. Below the ppm, but the industrial grade and food grade phosphoric acid, although low in price, has been tested and found to be unable to meet this requirement. The plant A in Figure 1 is provided by a factory in Taiwan, and the plant B is provided by a factory in China. A known method of purifying phosphoric acid is to pass a gas of hydrogen sulfide and hydrogen peroxide into phosphoric acid to precipitate a heavy metal precipitate (as disclosed in U.S. Patent No. 4,804,526). Another method of purifying phosphoric acid is to extract heavy metals from the phosphoric acid using an organic solvent (as disclosed in U.S. Patent No. 4,780,295). However, the current manufacturing cost of the phosphoric acid purification method is too high, resulting in an expensive electronic grade phosphoric acid which cannot be used universally and in large quantities. (5) 5 1322131 SUMMARY OF THE INVENTION The main object of the present invention is to provide a method for purifying phosphoric acid for electronic use, which is characterized in that an industrial grade or food grade phosphoric acid solution is diluted to reduce the phosphoric acid content to 5 ~20wt%, or 5~20wt before the final concentration in the general • phosphoric acid process. /. Phosphoric acid dilution, liquid, and the phosphoric acid solution has good deionization work, can be efficiently passed through the ion exchange resin or / and the nanofiltration membrane to remove the diluted phosphoric acid. It is less than 0.2 ppm, and is dehydrated by distillation or other means after deionization, and the acid structuring for electrons can be obtained at low cost and in large quantities for the purpose required for electronic specifications. A second object of the present invention is to provide a method for purifying a dish acid for electrons, wherein the bismuth acid content is reduced to 5 to 20 wt% of the diluted dish acid solution or the 5-20 wt% phosphoric acid dilution solution in the bismuth process. The effect of removing metal ions in the phosphoric acid solution by ion exchange resin, through one or more nanofiltration membranes (NF membrane), or through the nanofiltration membrane and then through the ion exchange tree-Φ lipid. Among them, the order of passing through the nanofiltration membrane and the ion exchange resin is the best and the mass production is practical. According to the method for purifying phosphoric acid for electronic use according to the present invention, first, a technical grade or food grade phosphoric acid solution to be purified, which contains 50 to 90% by weight of a disc acid, and then 'diluted the above-mentioned dish acid solution' is obtained. The acid content of the dish is reduced to 5~20wt% or in the general phosphoric acid production process, the final concentration of 5~20wt ° / 磷酸 phosphoric acid solution is carried out; and then filtered by ion exchange resin or / and nano. The membrane removes the single metal ion contained in the released phosphoric acid solution to 6 1^22131 0.2 ppm or less 'final' by distillation or other means to remove the water-containing damage in the phosphoric acid solution, so that the electron can be filled at a low cost and in a large amount. acid. [Embodiment] The present invention discloses a method for purifying phosphoric acid for electrons, mainly for removing sodium phosphate (Na), magnesium (Mg), aluminum (A1), potassium (κ), calcium (Ca) and iron (Fe). When the metal ion is less than 1.0 ppm, phosphoric acid for electrons which can be produced at a low cost and which can be obtained in a large amount is obtained. Referring to Fig. 2, the process for purifying the phosphoric acid for electronic use mainly comprises a phosphoric acid obtaining step u, a diluting step 12, a deionizing step 13 and a distillation dehydrating step 14. It is described in detail with the following examples and experimental data. First, in the dish acid obtaining step U, an industrial grade or food grade phosphoric acid solution to be purified containing 5 Torr to 9 Å wt% phosphoric acid is obtained. Then in the dilution step 12, the phosphoric acid solution can be diluted with deionized water to reduce the phosphoric acid content to 5 to 20 wt%, and the diluted phosphoric acid solution has good deionization workability and can be quickly passed through the ion exchange resin or With the nanofiltration membrane "or directly in the manufacturing process of the general phosphoric acid, the phosphoric acid dilution has not been subjected to final concentration before the final concentration of the phosphoric acid is 5 to 2% by weight. Then in the deionization step 13, there are several ways to remove the metal ions. In the first embodiment, 'obtaining an 85 wt% industrial grade/food grade phosphoric acid solution' is set to be diluted to 1 wt% phosphoric acid, and then the resin is replaced by an ion parent to remove the metal ions contained therein, before treatment. The content of the contained metal ions is measured after the treatment. Please refer to Fig. 3, which contains sodium (Na) and magnesium as the amount of the acid solution in the bed volume of the ion exchange resin changes. Metal ions such as (Mg), aluminum (A1), potassium (K), calcium (Ca) and iron (Fe) 7 (S) 1322131 have obvious removal rates before and after treatment, and single ions can be used. Reduced to below 0.2ppm. The difference in the removal rates between test i and test 2 is related to the type of ion exchange resin selected. Finally, in the step 14, the water content in the phosphoric acid solution is removed by distillation or other means, and the phosphoric acid content is increased to 8 〇wt% or more, so that the phosphoric acid for electrons can be obtained at a low cost and in a large amount. A single metal ion is about i 〇ppm). In a second embodiment, a 85 wt% industrial grade/food grade # phosphoric acid solution is obtained, which is set to be diluted to contain 1% by weight of phosphoric acid, first passed through the nanometer; and the membrane (Nanofiltration membrane, NF membrane) is passed again. The ion exchange resin is used to remove metal ions contained therein. Usually, the m〇iecuiar weight cutoff (MWCO) of the nanometer membrane is between 100 and 300. In this embodiment, the selected nanofiltration membrane has acid and alkali resistance, and the available pH value is between 〇~14, which can be supplied by Koch Membrane Systems, Inc. Cut off SelPO® MPS-34 pH Stable Membrane with a molecular weight of 200). Next, through the ion exchange resin, in this embodiment, the ion exchange resin selected is Bayer's LEWATIT® MonoPlus SP 112, and the substrate is styrene-divinylbenzene copolymer. . Measure the metal ion content of the diluted phosphoric acid before and after treatment. The values are as shown in Figure 4, and the single metal ions such as nano (Na), magnesium (Mg), aluminum (A1), and potassium are contained. (K), calcium (Ca) and iron (Fe), etc., as the amount of scaly acid solution that passes through the bed bed can be reduced to less than 2 ppm, so compared with the first implementation In the example, the stability of the removed ions is better, and it can be applied to actual mass production. Finally, in step 14, the water content in the linonic acid solution can be removed by 8 (S) 1322131 distillation or other dehydration method. And the electrons are used at low cost, even with the same level of acid filling. In the second embodiment, 'obtaining a 185 wt% food grade phosphoric acid/trough liquor' is set to dilute to 2 〇 wt%, 14 wt% and 1 〇 wt ° / 〇 酸 acid, respectively, at least once Nano filter membrane. Referring to Figure 5, after the first pass of the nanofiltration membrane to remove metal ions, the metal ion removal rate is between _ 65 and 85, regardless of whether the phosphoric acid is diluted to 20 wt%, 14 wt% or 1 wt%. %, but the phosphoric acid concentration is too high, which will affect the filtration ratio, making the metal ion removal time longer. The phosphoric acid solution diluted to 1% by weight is passed through the first nano-passing membrane, and the removal rate is between 75 and 9%, which is the residual amount of metal ions that will pass through the first nanofiltration membrane. After removing about 8〇%, the content of metal ions such as sodium (Na), magnesium (Mg), aluminum (A1), potassium (κ), calcium (Ca) and iron (Fe) can be reduced to below ppm2ppm. . Finally, in step 14, the water content in the phosphoric acid solution is removed by distillation or other means, and the phosphoric acid for electrons can be obtained in a large amount at a low cost. The scope of the present invention is defined by the scope of the appended claims, and any changes and modifications made by those skilled in the art without departing from the spirit and scope of the invention are within the scope of the present invention. . [Simple diagram of the diagram] Figure 1. Chart of metal ion content and electronic grade specifications for industrial grade and food grade dish acid solutions. Second Circle The main flow chart of the purification method of the dish acid for electronic use of the present invention. Fig. 3 is a table showing the content of metal ions removed by ion exchange 9 1322131 in accordance with one embodiment of the present invention. Fig. 4 is a view showing the content of metal ions removed by a nanofiltration membrane and an ion exchange resin according to a second embodiment of the present invention. Fig. 5 is a table showing the removal of metal ions by a nanofiltration membrane according to a third embodiment of the present invention. [Main component symbol description] 11 Obtain industrial grade or food grade phosphoric acid solution φ 12 Dilute the phosphoric acid solution 13 Remove the metal ions contained in the diluted phosphoric acid solution Distillation and dehydration 14

Claims (1)

1322131, the scope of patent application: A method for purifying phosphoric acid for electronic use, comprising: obtaining an industrial grade or food grade dish acid solution to be purified, which contains 50 to 90 wt% of acid filling; diluting the above phosphoric acid solution to make it The phosphoric acid content is reduced to 5 to 20% by weight; the single metal ion contained in the diluted phosphoric acid solution is removed to below 2 ppm; and the aqueous portion of the phosphoric acid solution is removed; wherein the above-mentioned single metal ion contained in the acid filling solution is removed The step comprises: at least one filtration step of passing the diluted phosphoric acid solution through a nanofiltration membrane; wherein the nanofiltration membrane has a molecular weight cutoff (MWCO) of between 100 and 300. 2. The method for purifying phosphoric acid for electrons according to claim 1, wherein the step of removing the single metal ion contained in the phosphoric acid solution comprises: passing the ion exchange resin after passing through the nanofiltration membrane. The method for purifying phosphoric acid for electronic use according to claim 1, wherein the nanofiltration membrane has acid resistance. 4 g/fr氺- & A method for purifying phosphoric acid for electrons as described in claim 1, wherein the phosphoric acid content after dilution is about 1 〇wt〇/. . The method for purifying phosphoric acid for electronic use according to the above aspect of the invention, wherein the tank acid content is increased to 80% by weight or more after the step of removing the water content in the above-mentioned acid solution. The method for purifying the acid dish for electronic use according to claim 1, wherein the metal ion contained in the phosphoric acid solution comprises sodium, money, aluminum, potassium, dance and iron, which are The step of removing the single metal ion contained in the phosphoric acid solution is 0.2 ppm or less. 7. The method for purifying phosphoric acid for electronic use according to claim 1, wherein the step of removing moisture in the phosphoric acid solution comprises a distillation method. 8. A method for purifying phosphoric acid for electronic use, comprising: Obtaining a 5~2〇wt〇/0 phosphoric acid dilution in the phosphoric acid process; removing the single metal ion contained in the diluent to below 〇2ρρπι; and removing the single metal ion contained in the diluent after the step The step of removing the single metal ion contained in the diluent comprises: at least one filtration step of passing the diluent through a nanofiltration membrane; The molecular weight cutoff (MWCO) of the nanofiltration membrane is between loo and 300. 9. The method for purifying spheroidal acid for electronic use according to claim 8, wherein the step of removing the single metal ion contained in the diluent comprises: after passing through the nanofiltration membrane, and then through ion exchange. Resin. The method for purifying phosphoric acid for electrons as described in claim 8 wherein the nanofiltration membrane has acid and alkali resistance. 11. The method for purifying phosphoric acid for electronic use according to claim 8, wherein the phosphoric acid content of the diluent is increased to 80% by weight or more after the step of removing the moisture in the diluent. 12 1322131 12. The method for purifying phosphoric acid for electronic use according to claim 8, wherein the metal ion contained in the diluent comprises sodium, smectite, shovel, unloading, calcium and iron, and the diluent is removed as described above. The step of containing a single metal ion is followed by less than 0.2 ppm. 13. The method for purifying phosphoric acid for electronic use according to item 8 of the patent application, wherein the step of removing moisture in the diluent comprises a distillation method of 0 13