KR19990019008A - Manufacturing method of high flow rate reverse osmosis membrane - Google Patents

Abstract

The present invention relates to the preparation of a reverse osmosis membrane having a function such as water purification or solute concentration, in particular, while maintaining the intrinsic properties such as salt removal rate,

It aims at manufacturing the polyamide type reverse osmosis membrane shown.

Specifically, the present invention is a multifunctional acid halogen using a hydrocarbon solvent in the process of preparing a reverse osmosis membrane by applying a polyfunctional amine solution to the surface of a microporous substrate, drying the surface, and then interfacially polymerizing the polyfunctional acid halide compound solution. The present invention relates to a method for producing a polyamide reverse osmosis membrane, comprising adding 2-methoxyethanol or 2-butoxyethanol as an additive to a compound solution to give a wave during interfacial polymerization. In particular, it exhibits high flow performance.

Description

Manufacturing method of high flow rate reverse osmosis membrane

The present invention relates to the production of a polyamide reverse osmosis composite membrane, and more particularly to a method for producing a reverse osmosis membrane having a high flow rate performance compared to the conventional reverse osmosis membrane. Recently, due to industrial development and urban concentration of the population, it is necessary to secure water sources and produce high-quality pure water due to water pollution due to water pollution and lack of precipitation due to industrial wastewater and domestic sewage. In order to meet this need, the use of reverse osmosis membranes is on the rise. The reverse osmosis process is mainly used for water purification functions such as desalination of seawater and brine, manufacturing of ultra pure water for semiconductor industry, and treatment of various industrial wastewater. It can be distinguished by the concentration function such as the concentration of juice and the production of beer and wine. Properties required as a reverse osmosis membrane are, first of all, high pressure resistance, heat resistance, chlorine resistance, hydrophilicity, high permeability to water, and the like.

Reverse osmosis membranes have been developed since Loeb and Sourirajan in 1964 to produce asymmetric membranes with cellulose acetate, and now they are aromatic polyamides or polymer materials with more stable structures. Dozens of commercial reverse osmosis membranes have been developed. The material of the reverse osmosis membrane can be largely divided into cellulose and non-cellulose based from the viewpoint of chemical structure, and is classified into an integral asymmetric structure and a composite structure according to the membrane type. Among them, a non-cellulose composite structure is more preferred. In particular, among non-cellulose composite membranes, composite membranes having aromatic polyamides as porous support membranes and aromatic polyamides as active layers have been developed and commercialized. The composite membrane consists of a support layer for maintaining mechanical strength and an active layer with selective permeability. Since the composite membrane can select an optimal active layer material, the overall performance of the membrane can be improved, and since the crosslinking can be imparted to the active layer, higher chemical resistance can be obtained. The active layer material is coated in the form of a thin film on the surface of the support (mainly polysulfone) having excellent water permeability using an interfacial polymerization method. In addition, a conventional dipping method or a plasma polymerization method may be used as a thin film manufacturing method. The start of the reverse osmosis composite membrane by the interfacial polymerization method was prepared by reacting the porous polysulfone support with an aqueous polyethyleneamine solution and toludia isocyanate in hexane with NS-100 of North Star Research Institute. Subsequently, PA-300 by epiamine and phthaloyl chloride reaction was introduced, followed by commercialization of FT-30 which interfacially polymerizes meta-phenylenediamine and trimezoyl chloride as described in US Pat. No. 4,277,344.

The method described in US Pat. No. 4,277,344 is a method of impregnating a polysulfone-based microporous substrate with a meta-phenylenediamine aqueous solution and applying a trimezoyl chloride solution on the substrate to cause crab polymerization. Membranes are known to have the best performance among currently known reverse osmosis composite membranes. However, this crosslinked polyamide composite membrane has a problem in its manufacturing process, that is, hexane or freon is used as the most common solvent of the polyfunctional acid halide solution. Due to the high risk, it is unsuitable for general processes due to safety problems, and recently, a mixed solvent mainly containing a hydrocarbon solvent having 8 or more carbon atoms of relatively high stability as a solvent of an acid halide compound has been used. However, such a hydrocarbon solvent is difficult to control the mixing ratio between each component due to problems such as boiling point, flash point, evaporation rate, compatibility with additives. Freon-based solvents are the most widely used because they are highly safe and easy to manufacture good performance membranes. However, their use has recently become a problem due to the global environmental pollution caused by the ozone layer destruction.

As a specific example of the use of Freon in the method for producing a composite reverse osmosis membrane, Japanese Patent Application No. 63-36803 uses meta-phenylenediamine or para-phenylenediamine as the polysulfone substrate by using trimezoyl chloride or isophthaloyl chloride. A method of interfacial polymerization was presented, in which trichloro trifluoroethane was used as a solvent of an acid chloride. In addition, U.S. Pat. However, the use of such hydrocarbon-based solvents presents a problem of low flux, as set forth in US Pat. No. 5,258,203. That is, at the time of interfacial polymerization, the rate of diffusion of amines into the organic layer is faster than that of acid halide compounds in the water layer, resulting in the Ritz end valley structure peculiar to the polyamide coating layer. Larger flow rates increase and roughness decreases flow rates. The reason why the flow rate is low when using a hydrocarbon solvent is that in the case of freon, the diffusion rate of the amine into the freon layer is faster than the diffusion rate into the hydrocarbon layer, thereby creating a structure of greater roughness, whereas the hydrocarbon solvent is generally used in the amine. This is because the solubility in water is not good to make a thin film having a flatter structure. Therefore, in order to increase the roughness, there is a method of adding waves to the interface by adding an additive to increase the dispersibility of the amine in the hydrocarbon layer or the water layer, as in US Pat. Nos. 4,948,507, 5,258,203. However, this method is difficult to select a suitable additive and it is important to uniformly disperse the solution in a small amount, so very precise control is required for the actual interfacial polymerization. On the other hand, in addition to improving the roughness during interfacial polymerization, there is also a method for improving the roughness by changing the morphology of the film in the post-treatment process, such as US Patent 4,783,346, 4,983,291, 5,178,766.

According to the present invention, a hydrocarbon solvent is used to add an additive having improved compatibility to conventionally added ethers when preparing a reverse osmosis membrane, causing waves at the interface during interfacial polymerization, thereby giving a suitable roughness to the synthesized coating layer, thereby providing a high flow rate membrane. It is for the purpose to manufacture.

The present invention specifically applies a polyfunctional amine solution to the surface of a microporous substrate, and after drying the surface, polyfunctional acid halide compound solution using a hydrocarbon solvent is surface polymerized to prepare a polyamide reverse osmosis membrane. 2-methoxyethanol or 2-butoxyethanol is added to the solution as an additive to generate waves during interfacial polymerization, and the present invention will be described in detail below.

Diethyl ether and methyl t-butyl ether, which have been used as conventional additives, have very low boiling point, so it is difficult to maintain a proper concentration during crab polymerization, and also due to the lack of compatibility in hydrocarbons, particularly coating uniformity in a continuous process. There is a problem that sex is difficult to maintain.

However, the present invention solves the above problem by preparing a high flow rate reverse osmosis membrane using 2-methoxyethanol and 2-butoxyethanol having a suitable boiling point and improved compatibility. Two characteristics of reverse osmosis membranes, salt rejection rate and flow rate, are inversely related to each other. That is, as the flow rate increases, the salt rejection rate decreases, and when the salt rejection rate improves, the flow rate decreases. However, as in the present invention, if the wave is applied during crab polymerization using an additive, the salt excretion rate does not decrease even though the flow rate is increased, because the surface area is increased by increasing the surface roughness.

The amount of the additive used in the present invention is preferably in the range of 0.01 to 10% by weight of the polyfunctional compound solution, but when used in less than 0.01% by weight, the additive effect is insignificant, and when used in excess of 10% by weight, the reactivity decreases. do.

Meanwhile, in the present invention, when immersing the polyfunctional amine solution on the surface of the microporous substrate in a continuous process, the amine is evenly distributed on the substrate surface by immersing for 1-30 seconds in the presence of ultrasonic waves to reduce the immersion time and improve the flow rate. It's a good idea to do this.

In addition, isophthaloyl chloride, terephthaloyl chloride, trimesoyl chloride, etc. may be used as the acid halogen compound, and the solvent used here is n-alkane having 5 to 12 carbon atoms and saturated and unsaturated hydrocarbons having 8 carbon atoms. Structural isomers are mixed or used alone, or a cyclic hydrocarbon having 5 to 7 carbon atoms.

Hereinafter, the present invention will be described in more detail with reference to Examples and Comparative Examples. In the measurement of the performance of the prepared reverse osmosis membrane, the flow rate was measured at 25 ° C. and 225 psig of sodium chloride (NaCl) solution having a concentration of 2000 ppm, and the salt excretion rate was calculated by the following equation. Where R is the salt excretion rate, C _f is the concentration of solute in feed water and C _p is the concentration of solute in permeate.

(Examples 1-6)

A 19% by weight solution of dimethylformamide and polysulfone on a polyester nonwoven fabric was cast to a thickness of about 100 to 150 μm, immediately immersed in a distilled water bath at 15 ° C. to solidify, and the nonwoven reinforced polysulfone microporous substrate was then solidified. After washing sufficiently with water, the solvent and water in the substrate were replaced, and then stored in pure water. The polysulfone microporous substrate thus obtained was immersed for 10 seconds in an aqueous solution of 2% by weight meta-phenylenediamine and removed from water on the surface, followed by 0.15% by weight of trimezoyl chloride n containing the additive according to the present invention as shown in Table 1. Immerse in hexane solution for 2 minutes. It was taken out, dried in air for 1 minute, washed with 60 ° C weak alkaline aqueous solution and washed with distilled water again. The performance of the finally obtained reverse osmosis membrane was measured and shown in Table 1.

(Comparative Example 1-5)

A 19% by weight solution of dimethylformamide and polysulfone on a polyester nonwoven fabric was cast to a thickness of about 100-150 μm, immediately immersed in a distilled water bath at 15 ° C. to solidify, and the nonwoven reinforced polysulfone microporous substrate was then solidified. After washing sufficiently with water, the solvent and water in the substrate were replaced, and then stored in pure water. The polysulfone microporous substrate thus obtained was soaked for 10 seconds in 2 wt% meta-phenylenediamine aqueous solution by ultrasonic wave and then impregnated for 2 min in 0.15 wt% trimezoyl chloride n-hexane solution containing conventional additives as shown in Table 2. The rest was performed in the same manner as in Example, and the performance of the finally obtained reverse osmosis membrane was measured and shown in Table 2.

As can be seen from the examples and comparative examples, when the reverse osmosis membrane is prepared according to the present invention, a membrane having excellent performance showing a high flow rate without decreasing the salt excretion rate can be obtained.

Claims (4)

Applying a multifunctional amine solution to the surface of the microporous substrate, drying the surface, and then interfacially polymerizing the solution into a polyfunctional acid halide compound solution using a hydrocarbon solvent to prepare a crosslinked polyamide reverse osmosis membrane. Method for producing a high flow rate reverse osmosis membrane, characterized in that to give a wave during the interfacial polymerization by adding 2-methoxy ethanol or 2-butoxy ethanol as an additive to the halogen compound solution The method of claim 1, wherein the additive is 0.01-10% by weight of the total weight of the acid halide compound solution. The method of claim 1, wherein the acid halogen compound is a compound selected from isophthaloyl chloride, terephthaloyl chloride or trimesoyl chloride. The method of claim 1, wherein a hydrocarbon solvent is used alone or a mixed solvent selected from the structural isomers of n-alkane of 5-12 carbon atoms and saturated and unsaturated hydrocarbons of 8 carbon atoms or cyclic hydrocarbons of 5-7 carbon atoms. Method of manufacturing high flow rate reverse osmosis membrane