Patent Application
20240026185
The present application belongs to the field of polymer materials, and particularly relates to a modified para-aramid polymer solution, a coating slurry, a lithium battery separator and preparation methods thereof.
At present, lithium battery separators are mostly made of polyolefin materials, e.g., polyethylene and polypropylene separators. However, such materials have poor heat resistance and wettability, and thus are usually coated on one or both sides of polyolefin separators. Commercially available are ceramic-coated films and PVDF-coated films. However, inorganic ceramics have poor adhesion to polyolefins and easily suffer from powder falling. Although PVDF improves the adhesion between separator and electrode, the high temperature resistance of the separator has not been greatly improved, which has impact on the safety of lithium batteries.
Para-aramid, i.e., poly (p-phenylene terephthalamide), which has the characteristics of intrinsic flame retardancy, high strength and high modulus, is widely used in bulletproof, personal protection and similar fields, and thus is a very important special high-performance polymer material. The application of para-aramid to membrane manufacturing fields such as water treatment membranes, lithium ion battery separators and like is one of application directions of para-aramid. The membrane made of para-aramid has the characteristics of both intrinsic flame retardancy and high strength, which makes it have a good application prospect in the fields of high-temperature filtration, fireproof coating and high-temperature lithium ion battery separators. However, it is extremely difficult for para-aramid to dissolve in polar solvents, which limits its processing and application in the field of membranes.
The inherent viscosity (Iv value) of the polymer solution required for the traditional manufacture of para-aramid fiber is greater than 5.0 dL/g, and the molecular weight is generally greater than 30,000. However, in view of the stability of the polymer solution and the processability of the membrane, the synthesis method thereof is slightly different from that of the polymer for fiber. Since the solubility of para-aramid fiber of a high molecular weight in traditional solvents is very small, and it is difficult to form a homogeneous solution with a high stability, it is difficult for para-aramid fiber to form a uniform membrane in the membrane-producing process. The problems of difficult processing and low preparation efficiency are particularly prominent especially in the application of a coated film. Therefore, it is particularly necessary to develop a lithium battery separator coated with modified para-aramid and a preparation method thereof, which is very important for developing high-temperature resistant, flame retardant and high-strength lithium battery membranes.
At present, the synthesis methods of para-aramid polymer for fiber usually include low-temperature solution polycondensation, interfacial polycondensation, direct polycondensation, etc. Among them, low-temperature solution polycondensation is applied in large-scale industrialization, and its polymerization equipment is usually a twin-screw extruder, which is suitable for the synthesis of high-viscosity polymers that have a large molecular weight and need to dissipate heat in time. In view of the characteristics of the relatively low molecular weight, solubility in traditional solvents and low viscosity of polymerization solution, the polymerization method of the para-aramid polymer for membranes, which is different from that of the para-aramid polymer for fibers, is more flexible in synthesis methods and processes.
Micro-reaction technology originated in Europe in the early 1990s, and its reactor channel size is micron-scale. Compared with traditional reactors, a micro-reactor has the advantages of short molecular diffusion distance, fast mass transfer, laminar flow in the channel, narrow residence time distribution, no backmixing, large specific surface area per unit volume, fast heat transfer speed, strong heat transfer ability and easy temperature control.
In the micro-channel reaction synthesis of meta-aramid and para-aramid, patents such as CN104667846A and CN110605079A have applied for micro-reaction systems for preparing meta-aramid and para-aramid resins, but so far there is no continuous synthesis method of a para-aramid coating slurry for a lithium battery separator.
Therefore, it is very important and desirable to use an efficient and convenient method to realize continuous and industrial synthesis of a para-aramid slurry for a membrane.
In view of the problems that the coated film of para-aramid is difficult to prepare and the production efficiency is low, the present application provides a modified para-aramid polymer solution, a coating slurry, a lithium battery separator and a preparation method thereof. The inherent viscosity (with an Iv value of 0.2-3) of the prepared para-aramid polymer solution is less than 15,000, with a good solution stability, and the inherent viscosity of the solution will not change within 3 months. In addition, the present application adopts a microchannel reactor to continuously synthesize a high-stability para-aramid coating slurry for a lithium battery separator, so as to solve the problems that para-aramid is difficult to dissolve in polar organic solvents, the processability is poor, and the preparation efficiency is low.
In order to achieve the above purpose, the present application adopts the following technical solution.
A modified para-aramid polymer solution is provided, which including following raw materials in percentage by mass: 4%-20% of a cosolvent, 70%-92% of an organic solvent, of p-phenylenediamine, 0.33%-2.4% of a monomer and 1.69%-8.53% of terephthaloyl chloride;
A method for preparing the modified para-aramid polymer solution is provided, which including the following:
Further, a volume ratio of the organic solution A in step (2), step (3) and step (4) is 1:1:1.
Further, the alkaline substance used in step (7) is calcium hydroxide, and a mass ratio of calcium hydroxide to terephthaloyl chloride is (0.8-1.2): 1.
A coating slurry for a lithium battery separator is provided, which including the modified para-aramid polymer solution and ceramic particles, where a weight percentage of the modified para-aramid polymer solution and ceramic particles is (30%-90%):(10%-70%).
Further, the ceramic particles are one or more of alumina, zirconia, magnesia, aluminum hydroxide, magnesium hydroxide, silica and titania, with a particle size of 10-1000 nm.
A method for preparing the coating slurry for a lithium battery separator is provided, which including: adding the ceramic particles into the modified para-aramid polymer solution and stirring uniformly to obtain the coating slurry for a lithium battery separator.
A lithium battery separator is provided, which including a substrate separator and a coated film; the substrate separator is one of polyethylene, polypropylene, a composite of polyethylene and polypropylene, polyethylene terephthalate nonwoven fabric, and cellulose nonwoven fabric; the coated film is obtained by coating the coating slurry on the substrate separator and performing post-treatment; in the coated film, the modified para-aramid forms a three-dimensional network structure, and the ceramic particles are wrapped in the three-dimensional network structure.
A method for preparing the lithium battery separator is provided, which including the following: coating the coating slurry on one side or both sides of the substrate separator, then immersing in a coagulation bath of an organic solvent for 10-300 seconds, and drying at to obtain the lithium battery separator coated with the modified para-aramid, where the organic solvent in the coagulation bath is any one or more of N,N-dimethylacetamide, N-methylpyrrolidone, N,N-dimethylformamide, and dimethyl phthalate.
Further, the prepared the lithium battery separator coated with the modified para-aramid has a thermal shrinkage of ≤2.0% after being placed in an oven at 130° C. for 1 h; the modified para-aramid in the prepared lithium battery separator coated with the modified para-aramid has an inherent viscosity of 0.3-3.0 and a molecular weight of 300-15000 Da.
Compared with the prior art, the present application has the following beneficial technical effects.
FIGURE is a schematic diagram of a microchannel reactor used in the present application.
In the FIGURE: 1, First inlet; 2, Second inlet; 3, Third inlet; 4, Fourth inlet; 5, Fifth inlet; 6, Sixth inlet; 7, Seventh inlet; 10, Second feed inlet; 11, Third feed inlet; 12, Fourth feed inlet; 13, Filter inlet; 14, Defoaming inlet; 15, Liquid storage inlet; 16, Refrigerant inlet; 17, Refrigerant outlet; T1, T2 and T3, Blending tanks; T5, Polymerization kettle; T6, Neutralization tank; T7, Liquid storage tank.
The present application will be described in further detail below:
A modified para-aramid polymer solution is provided, which including the following raw materials in percentage by mass: 4%-20% of a cosolvent, 70%-92% of an organic solvent, 0.63%-3.46% of p-phenylenediamine, 0.33%-2.4% of a monomer and 1.69%-8.53% of terephthaloyl chloride; the cosolvent is calcium chloride or lithium chloride; the organic solvent is any one of N,N-dimethylacetamide, N-methylpyrrolidone, N,N-dimethylformamide, N-methylformamide and N-ethylpyrrolidone; the monomer is one or two of 4,4′-diaminodiphenyl ether, 3,4′-diaminodiphenyl ether and polyether glycol.
A method for preparing the modified para-aramid polymer solution is provided, which including the following:
A coating slurry for a lithium battery separator is provided, which including the modified para-aramid polymer solution and ceramic particles, where a weight percentage of the modified para-aramid polymer solution and ceramic particles is (30%-90%):(10%-70%); he ceramic particles are one or more of alumina, zirconia, magnesia, aluminum hydroxide, magnesium hydroxide, silica and titania, with a particle size of 10-1000 nm.
A method for preparing the coating slurry for a lithium battery separator is provided, which including: adding the ceramic particles into the modified para-aramid polymer solution and stirring uniformly to obtain the coating slurry for a lithium battery separator.
A lithium battery separator is provided, which including a substrate separator and a coated film; the substrate separator is one of polyethylene, polypropylene, a composite of polyethylene and polypropylene, polyethylene terephthalate nonwoven fabric, and cellulose nonwoven fabric; the coated film is obtained by coating the coating slurry on the substrate separator and performing post-treatment; in the coated film, the modified para-aramid forms a three-dimensional network structure, and the ceramic particles are wrapped in the three-dimensional network structure.
A method for preparing the lithium battery separator is provided, which including the following: coating the coating slurry on one side or both sides of the substrate separator, then immersing in a coagulation bath of an organic solvent for 10-300 seconds, and drying at 20-80° C. to obtain the lithium battery separator coated with the modified para-aramid; the organic solvent in the coagulation bath is any one or more of N,N-dimethylacetamide, N-methylpyrrolidone, N,N-dimethylformamide, and dimethyl phthalate.
The prepared the lithium battery separator coated with the modified para-aramid has a thermal shrinkage of ≤2.0% after being placed in an oven at 130° C. for 1 h; the modified para-aramid in the prepared lithium battery separator coated with the modified para-aramid has an inherent viscosity of 0.3-3.0 and a molecular weight of 300-15000 Da.
The present application will be explained in more detail with reference to examples. It should be understood that the implementation of the present application is not limited to the following examples, and any formal modifications and/or changes made to the present application shall fall within the scope of protection of the present application.
In the present application, unless otherwise specified, all equipment and raw materials can be commercially purchased or are those commonly used in the industry. Unless otherwise specified, the methods in the following examples are all conventional methods in the art.
Solid calcium chloride was dissolved in N,N-dimethylacetamide to prepare an organic solution of calcium chloride with a mass percentage of 4%;
P-phenylenediamine and the above organic solution of calcium chloride were continuously added into a blending tank T1 under stirring via the first inlet 1 and the second inlet 2, respectively, to prepare an organic solution of p-phenylenediamine with a weight percentage of 1.89%, and the temperature of the solution was kept at 0° C. after blending.
Terephthaloyl chloride and the above organic solution of calcium chloride were continuously added into a blending tank T3 via the fifth inlet 5 and the sixth inlet 6, respectively, to prepare an organic solution of terephthaloyl chloride with a weight percentage of 5.07%, and the temperature of the solution was kept at 0° C. after blending.
4,4′-diaminodiphenyl ether and the above organic solution of calcium chloride were continuously added into a blending tank T2 via the third inlet 3 and the fourth inlet 4, respectively, to prepare an organic solution of 4,4′-diaminodiphenyl ether with a weight percentage of 0.99%, and the temperature of the solution was kept at 0° C. after blending.
The prepared organic solution of p-phenylenediamine and the organic solution of 4,4′-diaminodiphenyl ether were respectively continuously added to the inlet of a first reaction plate of the microchannel reactor via the first feed inlet 9 by a delivery pump. At the same time, the prepared organic solution of terephthaloyl chloride was divided into three parts, which were continuously added via the first inlet 9, the second inlet 10 and the third inlet 11 according to a molar ratio of substances of 0.07:0.03:0.9 to be mixed and reacted. The reaction temperature was controlled at −15° C. by adjusting the flow rate of the refrigerant inlet 16. Reaction was carried out in the microchannel reactor for 10s, and then the reactants were introduced into a polymerization kettle T5. The molar ratio of added p-phenylenediamine and monomer to the total terephthaloyl chloride was 1:1. The polymerization solution entered a neutralization tank T6 from the polymerization kettle T5 in an overflow way, and then calcium hydroxide was continuously added into the neutralization tank T6 for reaction under stirring. The molar ratio of the added calcium hydroxide to terephthaloyl chloride was 0.8:1 to neutralize the by-product hydrogen chloride dissolved in the solution. After the reaction is completed, the mixture entered the filter and the defoamer via the defoaming inlet 14 to remove insoluble substances and bubbles therein. The filtered and defoamed polymer solution entered a liquid storage tank T7 via a liquid storage inlet 15, and the obtained solution was precisely a polymer synthetic solution containing 2% modified para-aramid. The polymer was tested to have a Ubbelohde viscosity of 500 mpa·s.
Solid calcium chloride was dissolved in N,N-dimethylacetamide to prepare an organic solution of calcium chloride with a mass percentage of 10%;
P-phenylenediamine and the above organic solution of calcium chloride were continuously added into a blending tank T1 under stirring via the first inlet 1 and the second inlet 2, respectively, to prepare an organic solution of p-phenylenediamine with a weight percentage of 7.5%, and the temperature of the solution was kept at 15° C. after blending.
Terephthaloyl chloride and the above organic solution of calcium chloride were continuously added into a blending tank T3 via the fifth inlet 5 and the sixth inlet 6, respectively, to prepare an organic solution of terephthaloyl chloride with a weight percentage of 15.2%, and the temperature of the solution was kept at 15° C. after blending.
4,4′-diaminodiphenyl ether and the above organic solution of calcium chloride were continuously added into a blending tank T2 via the third inlet 3 and the fourth inlet 4, respectively, to prepare an organic solution of 4,4′-diaminodiphenyl ether with a weight percentage of 2.5%, and the temperature of the solution was kept at 15° C. after blending.
The prepared organic solution of p-phenylenediamine and the organic solution of 4,4′-diaminodiphenyl ether were respectively continuously added to the inlet of a first reaction plate of the microchannel reactor via the first feed inlet 9 by a delivery pump. At the same time, the prepared organic solution of terephthaloyl chloride was divided into three parts, which were continuously added via the first inlet 9, the second inlet 10 and the third inlet 11 according to a molar ratio of substances of 0.1:0.05:0.8 to be mixed and reacted. The reaction temperature was controlled at −7° C. by adjusting the flow rate of the refrigerant inlet 16. Reaction was carried out in the microchannel reactor for 60s, and then the reactants were introduced into a polymerization kettle T5. The molar ratio of added p-phenylenediamine and monomer to the total terephthaloyl chloride was 1:1. The polymerization solution entered a neutralization tank T6 from the polymerization kettle T5 in an overflow way, and then calcium hydroxide was continuously added into the neutralization tank T6 for reaction under stirring. The molar ratio of the added calcium hydroxide to terephthaloyl chloride was 1:1 to neutralize the by-product hydrogen chloride dissolved in the solution. After the reaction is completed, the mixture entered the filter and the defoamer via the defoaming inlet 14 to remove insoluble substances and bubbles therein. The filtered and defoamed polymer solution entered a liquid storage tank T7 via a liquid storage inlet 15, and the obtained solution was precisely a polymer synthetic solution containing 6% modified para-aramid. The polymer was tested to have a Ubbelohde viscosity of 4000 mpa·s.
Solid calcium chloride was dissolved in N,N-dimethylacetamide to prepare an organic solution of calcium chloride with a mass percentage of 20%;
P-phenylenediamine and the above organic solution of calcium chloride were continuously added into a blending tank T1 under stirring via the first inlet 1 and the second inlet 2, respectively, to prepare an organic solution of p-phenylenediamine with a weight percentage of 10.38%, and the temperature of the solution was kept at 30° C. after blending.
Terephthaloyl chloride and the above organic solution of calcium chloride were continuously added into a blending tank T3 via the fifth inlet 5 and the sixth inlet 6, respectively, to prepare an organic solution of terephthaloyl chloride with a weight percentage of 25.59%, and the temperature of the solution was kept at 30° C. after blending.
4,4′-diaminodiphenyl ether and the above organic solution of calcium chloride were continuously added into a blending tank T2 via the third inlet 3 and the fourth inlet 4, respectively, to prepare an organic solution of 4,4′-diaminodiphenyl ether with a weight percentage of 7.2%, and the temperature of the solution was kept at 30° C. after blending.
The prepared organic solution of p-phenylenediamine and the organic solution of 4,4′-diaminodiphenyl ether were respectively continuously added to the inlet of a first reaction plate of the microchannel reactor via the first feed inlet 9 by a delivery pump. At the same time, the prepared organic solution of terephthaloyl chloride was divided into three parts, which were continuously added via the first inlet 9, the second inlet 10 and the third inlet 11 according to a molar ratio of substances of 0.13:0.07:0.8 to be mixed and reacted. The reaction temperature was controlled at 0° C. by adjusting the flow rate of the refrigerant inlet 16. Reaction was carried out in the microchannel reactor for 100s, and then the reactants were introduced into a polymerization kettle T5. The molar ratio of added p-phenylenediamine and monomer to the total terephthaloyl chloride was 1:1.05. The polymerization solution entered a neutralization tank T6 from the polymerization kettle T5 in an overflow way, and then calcium hydroxide was continuously added into the neutralization tank T6 for reaction under stirring. The molar ratio of the added calcium hydroxide to terephthaloyl chloride was 1.2:1 to neutralize the by-product hydrogen chloride dissolved in the solution. After the reaction is completed, the mixture entered the filter and the defoamer via the defoaming inlet 14 to remove insoluble substances and bubbles therein. The filtered and defoamed polymer solution entered a liquid storage tank T7 via a liquid storage inlet 15, and the obtained solution was precisely a polymer synthetic solution containing 10% modified para-aramid. The polymer was tested to have a Ubbelohde viscosity of 70000 mpa·s.
Solid calcium chloride was dissolved in N,N-dimethylacetamide to prepare an organic solution of calcium chloride with a mass percentage of 10%;
P-phenylenediamine and the above organic solution of calcium chloride were continuously added into a blending tank T1 under stirring via the first inlet 1 and the second inlet 2, respectively, to prepare an organic solution of p-phenylenediamine with a weight percentage of 4.93%, and the temperature of the solution was kept at 20° C. after blending.
Terephthaloyl chloride and the above organic solution of calcium chloride were continuously added into a blending tank T3 via the fifth inlet 5 and the sixth inlet 6, respectively, to prepare an organic solution of terephthaloyl chloride with a weight percentage of 12.8%, and the temperature of the solution was kept at 20° C. after blending.
4,4′-diaminodiphenyl ether and the above organic solution of calcium chloride were continuously added into a blending tank T2 via the third inlet 3 and the fourth inlet 4, respectively, to prepare an organic solution of 4,4′-diaminodiphenyl ether with a weight percentage of 2.89%, and the temperature of the solution was kept at 20° C. after blending.
The prepared organic solution of p-phenylenediamine and the organic solution of 4,4′-diaminodiphenyl ether were respectively continuously added to the inlet of a first reaction plate of the microchannel reactor via the first feed inlet 9 by a delivery pump. At the same time, the prepared organic solution of terephthaloyl chloride was divided into three parts, which were continuously added via the first inlet 9, the second inlet 10 and the third inlet 11 according to a molar ratio of substances of 0.09:0.04:0.85 to be mixed and reacted. The reaction temperature was controlled at −7° C. by adjusting the flow rate of the refrigerant inlet 16. Reaction was carried out in the microchannel reactor for 10s, and then the reactants were introduced into a polymerization kettle T5. The molar ratio of added p-phenylenediamine and monomer to the total terephthaloyl chloride was 1:1.05. The polymerization solution entered a neutralization tank T6 from the polymerization kettle T5 in an overflow way, and then calcium hydroxide was continuously added into the neutralization tank T6 for reaction under stirring. The molar ratio of the added calcium hydroxide to terephthaloyl chloride was 1:1 to neutralize the by-product hydrogen chloride dissolved in the solution. After the reaction is completed, the mixture entered the filter and the defoamer via the defoaming inlet 14 to remove insoluble substances and bubbles therein. The filtered and defoamed polymer solution entered a liquid storage tank T7 via a liquid storage inlet 15, and the obtained solution was precisely a polymer synthetic solution containing 5% modified para-aramid. The polymer was tested to have a Ubbelohde viscosity of 30000 mpa·s.
Solid calcium chloride was dissolved in N,N-dimethylacetamide to prepare an organic solution of calcium chloride with a mass percentage of 20%;
P-phenylenediamine and the above organic solution of calcium chloride were continuously added into a blending tank T1 under stirring via the first inlet 1 and the second inlet 2, respectively, to prepare an organic solution of p-phenylenediamine with a weight percentage of 6.57%, and the temperature of the solution was kept at 0° C. after blending.
Terephthaloyl chloride and the above organic solution of calcium chloride were continuously added into a blending tank T3 via the fifth inlet 5 and the sixth inlet 6, respectively, to prepare an organic solution of terephthaloyl chloride with a weight percentage of 12.44%, and the temperature of the solution was kept at 0° C. after blending.
4,4′-diaminodiphenyl ether and the above organic solution of calcium chloride were continuously added into a blending tank T2 via the third inlet 3 and the fourth inlet 4, respectively, to prepare an organic solution of 4,4′-diaminodiphenyl ether with a weight percentage of 3.8%, and the temperature of the solution was kept at 0° C. after blending.
The prepared organic solution of p-phenylenediamine and the organic solution of 4,4′-diaminodiphenyl ether were respectively continuously added to the inlet of a first reaction plate of the microchannel reactor via the first feed inlet 9 by a delivery pump. At the same time, the prepared organic solution of terephthaloyl chloride was divided into three parts, which were continuously added via the first inlet 9, the second inlet 10 and the third inlet 11 according to a molar ratio of substances of 0.1:0.06:0.85 to be mixed and reacted. The reaction temperature was controlled at −7° C. by adjusting the flow rate of the refrigerant inlet 16. Reaction was carried out in the microchannel reactor for 60s, and then the reactants were introduced into a polymerization kettle T5. The molar ratio of added p-phenylenediamine and monomer to the total terephthaloyl chloride was 1:1.02. The polymerization solution entered a neutralization tank T6 from the polymerization kettle T5 in an overflow way, and then calcium hydroxide was continuously added into the neutralization tank T6 for reaction under stirring. The molar ratio of the added calcium hydroxide to terephthaloyl chloride was 1.2:1 to neutralize the by-product hydrogen chloride dissolved in the solution. After the reaction is completed, the mixture entered the filter and the defoamer via the defoaming inlet 14 to remove insoluble substances and bubbles therein. The filtered and defoamed polymer solution entered a liquid storage tank T7 via a liquid storage inlet 15, and the obtained solution was precisely a polymer synthetic solution containing 5% modified para-aramid. The polymer was tested to have a Ubbelohde viscosity of 25000 mpa·s.
N-methylpyrrolidone in Example 2 was replaced by “N,N-dimethylformamide” and “4,4′-diaminodiphenyl ether” was replaced by “3,4′-diaminodiphenyl ether”. Other conditions such as preparation processes, process parameters and equipment types were the same as in Example 2.
N-methylpyrrolidone in Example 3 was replaced by “N-methylformamide” and “4,4′-diaminodiphenyl ether” was replaced by “3,4′-diaminodiphenyl ether”. Other conditions such as preparation processes, process parameters and equipment types were the same as in Example 3.
N-methylpyrrolidone in Example 4 was replaced by “N-ethylpyrrolidone” and “4,4′-diaminodiphenyl ether” was replaced by “polyether glycol”. Other conditions such as preparation processes, process parameters and equipment types were the same as in Example 4.
Ceramic particles were added into the liquid storage tank T7, and the modified para-aramid polymer solution obtained in Example 1 and alumina particles were evenly stirred according to a weight percentage of 30:70 to obtain a coating slurry.
Ceramic particles were added into the liquid storage tank T7, and the modified para-aramid polymer solution obtained in Example 2 and magnesium particles were evenly stirred according to a weight percentage of 60:40 to obtain a coating slurry.
Ceramic particles were added into the liquid storage tank T7, and the modified para-aramid polymer solution obtained in Example 3 and zirconia particles were evenly stirred according to the weight percentage of 90:10 to obtain a coating slurry.
Ceramic particles were added into the liquid storage tank T7, and the modified para-aramid polymer solution obtained in Example 4 and silicon dioxide particles were evenly stirred according to a weight percentage of 60:40 to obtain a coating slurry.
Ceramic particles were added into the liquid storage tank T7, and the modified para-aramid polymer solution obtained in Example 5 and titanium dioxide particles were evenly stirred according to a weight percentage of 90:10 to obtain a coating slurry.
Ceramic particles were added into the liquid storage tank T7, and the modified para-aramid polymer solution obtained in Example 6 and magnesium oxide particles were evenly stirred according to a weight percentage of 60:40 to obtain a coating slurry.
Ceramic particles were added into the liquid storage tank T7, and the modified para-aramid polymer solution obtained in Example 7 and zirconia particles were evenly stirred according to a weight percentage of 90:10 to obtain a coating slurry.
Ceramic particles were added into the liquid storage tank T7, and the modified para-aramid polymer solution obtained in Example 8 and silicon dioxide particles were evenly stirred according to a weight percentage of 60:40 to obtain a coating slurry.
The coating slurry obtained in Example 9 was coated on one side of a polyethylene substrate separator, which was then immersed in a coagulation bath of N-methylpyrrolidone for 10 seconds, followed by drying at 20° C., thereby obtaining a modified para-aramid coated lithium battery separator.
The coating slurry obtained in Example 10 was coated on both sides of polyethylene terephthalate nonwoven fabric, which was then immersed in a coagulation bath of N-methylpyrrolidone for 160 seconds, followed by drying at 52° C., thereby obtaining a modified para-aramid coated lithium battery separator.
The coating slurry obtained in Example 11 was coated on one side of a polypropylene substrate separator, which was then immersed in a coagulation bath of N,N-dimethylformamide for 300 seconds, followed by drying at 80° C., thereby obtaining a modified para-aramid coated lithium battery separator.
The coating slurry obtained in Example 12 was coated on one side of cellulose non-woven fabric, which was then immersed in a coagulation bath of dimethyl phthalate for 160 seconds, followed by drying at 52° C., thereby obtaining a modified para-aramid coated lithium battery separator.
The coating slurry obtained in Example 13 was coated on one side of a composite of polyethylene and polypropylene, which was then immersed in a coagulation bath of N,N-dimethylacetamide for 300 seconds, followed by drying at 80° C., thereby obtaining a modified para-aramid coated lithium battery separator.
The coating slurry obtained in Example 14 was coated on both sides of polyethylene terephthalate nonwoven fabric, which was then immersed in a coagulation bath of N-methylpyrrolidone for 160 seconds, followed by drying at 52° C., thereby obtaining a modified para-aramid coated lithium battery separator.
The coating slurry obtained in Example 15 was coated on one side of a polypropylene substrate separator, which was then immersed in a coagulation bath of N,N-dimethylformamide for 300 seconds, followed by drying at 80° C., thereby obtaining a modified para-aramid coated lithium battery separator.
The coating slurry obtained in Example 16 was coated on one side of cellulose non-woven fabric, which was then immersed in the coagulation bath of dimethyl phthalate for 160 seconds, followed by drying at 52° C., thereby obtaining a modified para-aramid coated lithium battery separator.
The substrate separator was immersed in a coagulation bath of N,N-dimethylacetamide, with other conditions being the same as those in Example 1, to prepare a separator.
The substrate separator was coated with ceramics and then immersed in the coagulation bath of N,N-dimethylacetamide, with other conditions being the same as those in Example 1, to prepare a separator.
A traditional twin-screw was used polymerization reaction, with other conditions being the same as those in Example 1, to prepare an aramid coated film.
An aramid coated film was prepared without addition of 4,4′-diaminodiphenyl ether, with other conditions being the same as those in Example 1.
A traditional twin screw was used for polymerization reaction, with other conditions being the same as those in Example 5, to prepare an aramid coated film.
Indices of Polymerization Solution
The polymer solutions and membranes obtained in the above examples and comparative examples 1-8 were tested for performance, and the test results were as follows:
As can be seen from the above table, the stability and membrane thermal shrinkage index of the polymer solution prepared by the present application are obviously better than those of the substrate separator, and the ceramic particles can be bonded without adding an adhesive.
The above examples are only preferred examples of the present application, and are not intended to limit the present application. For those skilled in the art, various modifications and variations may be made to the present application. Any modification, equivalent substitution, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.
| Number | Date | Country | Kind |
|---|---|---|---|
| 202011500608.2 | Dec 2020 | CN | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/CN2021/112534 | 8/13/2021 | WO |
