Patent Description:
With the continuous breakthrough of science and technology, the electrical and electronic industry has developed rapidly. Lightweight, miniaturization and integration are the future development trends of electronic products. As an important part of electrical components, capacitors are widely used in electronic equipment, communication equipment and other pulse power equipment. Size and efficiency of capacitors are critical to the entire process, and high dielectric polymer-based composite materials, see for instance <CIT>, are an important way to miniaturize capacitors.

Conventional high dielectric materials are typically inorganic ceramic materials (such as barium titanate, copper calcium titanate, and zirconium titanate). Although these materials have very high dielectric constants, they also have a problem of high dielectric loss.

Embodiments of the present application provide a high dielectric liquid crystal polymer composite material and a preparation method thereof, so as to solve the technical problem of high dielectric loss in the existing high dielectric polymer composite material.

In a first aspect, embodiments of the present application provide a high dielectric liquid crystal polymer composite material, characterized by comprising liquid crystal polymer (LCP); poly(vinylidene fluoride-co-hexafluoropropylene); modified multi-walled carbon nanotubes; and modified dielectric ceramics;.

In some embodiments, the silane coupling agent comprises at least one of vinylmethyldimethoxysilane, <NUM>-(methacryloyloxy)propyltrimethoxysilane, and <NUM>-mercaptopropyltrimethoxysilane.

In some embodiments, the dielectric ceramics comprise at least one of barium titanate, strontium titanate and calcium titanate.

In some embodiments, the dopa-like compound comprises at least one of dopa, dopamine and dopamine hydrochloride.

In some embodiments, the liquid crystal polymer is wholly aromatic liquid crystal polymer.

In some embodiments, a mass ratio of the liquid crystal polymer, the poly(vinylidene fluoride-co-hexafluoropropylene), the modified multi-walled carbon nanotubes and the modified dielectric ceramics is (<NUM>-<NUM>) : (<NUM>-<NUM>) : (<NUM>-<NUM>) : (<NUM>-<NUM>).

In a second aspect, embodiments of the present application provide a preparation method of the high dielectric liquid crystal polymer composite material described in the first aspect, characterized by comprising:.

In some embodiments, the obtaining modified multi-walled carbon nanotubes comprises specifically:.

In some embodiments, the obtaining modified dielectric ceramics comprises specifically:.

In some embodiments, working parameters of the hot press molding comprise a temperature of <NUM> to <NUM> and a pressure of <NUM> MPa to <NUM> MPa.

Compared with the prior art, the above-mentioned technical solutions provided in the embodiments of the present application have the following advantages.

The embodiments of the present application provides a high dielectric liquid crystal polymer composite material, which is formed by complexing liquid crystal polymer with poly(vinylidene fluoride-co-hexafluoropropylene), modified multi-walled carbon nanotubes and modified dielectric ceramics. Since there is an obvious enhanced synergistic effect between the different fillers, the liquid crystal polymer composite material with both high dielectric properties and low dielectric loss is obtained. Specifically, the organosilane coupling agent improves the compatibility between the multi-walled carbon nanotubes and the matrix, making them evenly dispersed, and reduces the percolation threshold due to grafting of an insulating layer on the surface thereof; since the surface of the dielectric ceramic is coated with a polydopamine layer, the hydrogen bond between the PDA shell and the fluoropolymer greatly enhances the interfacial adhesion of the nanocomposite, meanwhile the Coulomb shielding effect of silver nanoparticles is successfully introduced; and by utilizing the synergy between the two modified fillers, the liquid crystal polymer composite material has the characteristics of low dielectric loss while ensuring high dielectric properties, which effectively solves the technical problem of high dielectric loss in existing high dielectric polymer composite materials.

The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments consistent with the present application and, together with the description, serve to explain the principles of the present application.

In order to illustrate the embodiments of the present application or the technical solutions in the prior art more clearly, the following briefly introduces the accompanying drawings that are required in the description of the embodiments or the prior art. Obviously, for those of ordinary skill in the art, other drawings can also be obtained from these drawings without any creative effort.

<FIG> is a schematic flowchart of a preparation method of a high dielectric liquid crystal polymer composite material according to some embodiments of the present application.

The present application will be described in detail below with reference to specific embodiments and examples, and the advantages and various effects of the present application will be more clearly presented thereby. It should be understood by those skilled in the art that these specific embodiments and examples are used to illustrate, but not to limit, the present application.

Throughout the specification, unless specifically stated otherwise, terms used herein are to be understood as commonly used in the art. Therefore, unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the present application belongs. In case of conflict, the present specification takes precedence.

Unless otherwise specified, various raw materials, reagents, instruments and device used in the present application are commercially available or can be prepared by existing methods.

With the continuous breakthrough of science and technology, the electrical and electronic industry has developed rapidly. Lightweight, miniaturization and integration are the future development trends of electronic products. As an important part of electrical components, capacitors are widely used in electronic equipment, communication equipment and other pulse power equipment. Size and efficiency of capacitors are critical to the entire process, and high dielectric polymer-based composite materials are an important way to miniaturize capacitors.

Conventional high dielectric materials are typically inorganic ceramic materials (such as barium titanate, copper calcium titanate, and zirconium titanate). Although these materials have very high dielectric constants, they also have the problem of high dielectric loss.

The technical solutions provided by the embodiments of the present application are to solve the above-mentioned technical problems, and the general idea is as follows.

In a first aspect, embodiments of the present application provide a high dielectric liquid crystal polymer composite material. The high dielectric liquid crystal polymer composite material includes liquid crystal polymer (LCP); poly(vinylidene fluoride-co-hexafluoropropylene); modified multi-walled carbon nanotubes; and modified dielectric ceramics;.

The embodiments of the present application provides a high dielectric liquid crystal polymer composite material, which is formed by complexing liquid crystal polymer (LCP) with poly(vinylidene fluoride-co-hexafluoropropylene), modified multi-walled carbon nanotubes and modified dielectric ceramics. Since there is an obvious enhanced synergistic effect between the different fillers, the liquid crystal polymer composite material with both high dielectric properties and low dielectric loss is obtained. Specifically, the organosilane coupling agent improves the compatibility between the multi-walled carbon nanotubes and the matrix, making them evenly dispersed, and reduces the percolation threshold due to grafting of an insulating layer on the surface thereof; since the surface of the dielectric ceramic is coated with a polydopamine layer, the hydrogen bond between the PDA shell and the fluoropolymer greatly enhances the interfacial adhesion of the nanocomposite, meanwhile the Coulomb shielding effect of silver nanoparticles is successfully introduced; and by utilizing the synergy between the two modified fillers, the liquid crystal polymer composite material has the characteristics of low dielectric loss while ensuring high dielectric properties, which effectively solves the technical problem of high dielectric loss in existing high dielectric polymer composite materials.

In the present application, liquid crystal polymer is abbreviated as LCP. Commercial products such as Xydar&reg; G-<NUM> Titan&reg; LG431 Zenite&reg; <NUM> Zenite&reg; Vetra&reg; A130, Novaccurate&reg; E335G30; Sumikasuper&reg; and E7000 can be used in the present application.

In the present application, multi-walled carbon nanotubes have the characteristics of high strength and high toughness, and a <NPL>.

In the present application, polyvinyl pyrrolidone is abbreviated as PVP, and is a non-ionic polymer compound.

In the present application, dielectric ceramics have the characteristics of high insulation resistivity, small dielectric constant, low dielectric loss, good thermal conductivity, small expansion coefficient, good thermal stability, chemical stability and so on.

In the present application, dopa-like compounds refer to a class of compounds with the characteristic structure of dopa (<NPL>) compound, and may specifically include dopa, dopamine, dopamine hydrochloride, etc..

As an implementation of the embodiments of the present application, the silane coupling agent includes at least one of vinylmethyldimethoxysilane, <NUM>-(methacryloyloxy)propyltrimethoxysilane, and <NUM> -mercaptopropyltrimethoxysilane.

The present application uses vinylmethyldimethoxysilane, <NUM>-(methacryloyloxy)propyltrimethoxysilane, <NUM>-mercaptopropyltrimethoxysilane and the like as an organosilane coupling agent, which is beneficial to improve the compatibility between the multi-walled carbon nanotubes and the matrix, making them evenly dispersed.

As an implementation of the embodiments of the present application, the dielectric ceramics include at least one of barium titanate, strontium titanate and calcium titanate.

As an implementation of the embodiments of the present application, the dopa-like compound includes at least one of dopa, dopamine and dopamine hydrochloride.

As an implementation of the embodiments of the present application, the liquid crystal polymer is wholly aromatic liquid crystal polymer.

In some specific embodiments of the present application, the liquid crystal polymer (LCP) may be a commercially available wholly aromatic liquid crystal polymer such as Polyplastics A150 Vectra, or may be prepared by a method for preparing a wholly aromatic liquid crystal polymer disclosed in the prior art (Chinese Patent <CIT>).

As an implementation of the embodiments of the present application, the mass ratio of the liquid crystal polymer (LCP), the poly(vinylidene fluoride-co-hexafluoropropylene), the modified multi-walled carbon nanotubes and the modified dielectric ceramics is (<NUM>~<NUM>):(<NUM>~<NUM>):(<NUM>~<NUM>):(<NUM>~<NUM>).

In the present application, by selecting modified multi-walled carbon nanotubes and modified dielectric ceramics as modified fillers and optimizing the mass ratio of these fillers and the liquid crystal polymer, the liquid crystal polymer composite material with both high dielectric properties and low dielectric loss was prepared. If the amount of any of the above components is adjusted, the dielectric properties will be reduced or the dielectric loss will be increased to a certain extent.

In a second aspect, embodiments of the present application provide a preparation method of the high dielectric liquid crystal polymer composite material of the first aspect, as shown in <FIG>. The preparation method includes:.

In some specific embodiments of the present application, the above preparation method may include:.

As an implementation of the embodiments of the present application, the obtaining modified multi-walled carbon nanotubes includes specifically:.

In some specific embodiments of the present application, the specific process of obtaining the above modified multi-walled carbon nanotubes can be as follows: respectively dispersing/dissolving the multi-walled carbon nanotubes and polyvinyl pyrrolidone weighed based on the ratio into absolute ethanol, adding slowly PVP solution into the multi-walled carbon nanotube solution under stirring, and sealing the resulting mixture at room temperature after completion of the dropwise addition; after reaction, centrifuging and washing the precipitate for three times, wherein the precipitate after centrifuging and washing is labeled as MWCNTs-PVP (i.e., the first precipitate); adding ethanol to a three-necked flask, adjusting pH to <NUM>∼<NUM> with ammonia water, adding the silane coupling agent mixture into the MWCNTs-PVP solution using a constant pressure funnel dropwise, and after reaction, repeating centrifuging and washing for three times to obtain a precipitate labeled as MWCNTs@SiO<NUM> (i.e., the second precipitate); and drying this precipitate in a vacuum oven and grinding it to obtain multi-walled carbon nanotubes modified by the silane coupling agent (MWCNTs@SiO<NUM>).

As an implementation of the embodiments of the present application, the obtaining modified dielectric ceramics includes specifically:.

In some specific embodiments of the present application, the specific process of obtaining the above modified dielectric ceramics can be as follows: firstly, preparing a Tris buffer, adding dielectric ceramics into the Tris buffer, and dispersing them by sonication to form a stable suspension. Then a modifier was added, pH was adjusted to <NUM> with dilute HCl, then a sonication treatment was performed in an ice bath, the mixture was vigorously stirred at room temperature (stirring speed > <NUM> rpm) for reaction, and dielectric ceramics with core-shell structure were obtained after vacuum suction filtration, and washed with deionized water and absolute ethanol for several times. The resulting powder was dried in a vacuum oven. The dielectric ceramics were dispersed in deionized water, then sonicated in an ice bath, and then AgNO<NUM> solution was added rapidly, and the reaction was performed under vigorous stirring (stirring speed > <NUM> rpm) in the ice bath. After repeating centrifuging and washing for three times, finally the modified dielectric ceramics are dried under vacuum.

As an implementation of the embodiments of the present application, working parameters of the hot press molding include a temperature of <NUM> to <NUM> and a pressure of <NUM> MPa to <NUM> MPa.

In some specific embodiments of the present application, the working parameters of the hot press molding are preferably a temperature of <NUM> and a pressure of <NUM> MPa.

To sum up, the present application utilizes the synergistic effect between ceramic particles and conductive fillers to prepare the high dielectric liquid crystal polymer composite material. The dielectric ceramics with core-shell structure are obtained by adding different types and amount of the silane coupling agent and grafting with polyvinyl pyrrolidone-multiwall carbon nanotubes, and the dielectric ceramics according to the present application are firstly surface modified by different modifiers, and then embedded with silver nanoparticles on the surface of the polydopamine layer. Finally, the high dielectric liquid crystal polymer composite material is prepared by optimizing the mass ratio of the fillers and the liquid crystal polymer.

The present application will be further described below in conjunction with specific examples.

The experimental methods that do not specify specific conditions in the following examples are usually determined according to national standards. If there is no corresponding national standard, follow the general international standards, conventional conditions, or the conditions suggested by the manufacturer.

The embodiment <NUM> provides a high dielectric liquid crystal polymer composite material and a preparation method thereof. The preparation method includes:.

<NUM> of MWCNTs and <NUM> of PVP were weighed, placed in <NUM> of absolute ethanol, respectively, and dispersed by sonication for <NUM>. After the multi-walled carbon nanotube solution was completely dispersed, the PVP solution was added slowly into the multi-walled carbon nanotube solution under stirring, and then the mixture was sealed and stirred for <NUM> at room temperature after completion of this dropwise addition; after reaction, a precipitate was centrifuged and washed for three times, and the precipitate after centrifugation and washing was labeled as MWCNTs-PVP; <NUM> of ethanol was added into a three-necked flask, and adjusted to pH <NUM>∼<NUM> with ammonia water, and under stirring, <NUM> of vinylmethyldimethoxysilane mixture was added dropwise into the MWCNTs-PVP solution with a constant pressure funnel, and stirred for <NUM>; centrifugation and washing were repeated for three times to obtain a precipitate labeled as MWCNTs@SiO<NUM>; and this precipitate was dried in a <NUM> vacuum oven for <NUM> and ground to obtain multi-walled carbon nanotubes modified by the silane coupling agent, i.e., MWCNTs@SiO<NUM>.

<NUM> mmol/L Tris buffer was prepared by <NUM> of deionized water, then <NUM> of barium titanate was added into the Tris buffer, and ultrasonically dispersed for <NUM> to form a stable suspension. Next, <NUM> of dopa modifier (specifically dopamine) was added into the suspension, pH value was adjusted to <NUM> with dilute HCl, then a sonication treatment was performed in an ice bath for <NUM>, the mixture was vigorously stirred at room temperature for <NUM>, and barium titanate with core-shell structure was obtained after vacuum suction filtration, and washed with deionized water and absolute ethanol for several times. The resulting powder (i.e., the barium titanate powder with core-shell structure) was dried in a <NUM> vacuum oven for <NUM>. <NUM> of the barium titanate powder obtained after above drying was dispersed in <NUM> of deionized water, and then sonicated in an ice bath for <NUM>, then <NUM> AgNO<NUM> solution (<NUM> mol/L) was quickly added, and reacted for <NUM> under vigorous stirring in an ice bath. After repeating centrifugation and washing for three times, finally the modified dielectric ceramics was dried under vacuum at <NUM> for <NUM>.

<NUM> of P(VDF-HFP) was dissolved in DMF and stirred at <NUM> for <NUM>∼<NUM>. Simultaneously, <NUM> of MWCNTs@SiO<NUM> and <NUM> of modified dielectric ceramics were dispersed into another DMF by sonication and vigorously stirred at room temperature for <NUM>. The P(VDF-HFP) solution was then slowly added into this suspension, and a resulting mixture was stirred at room temperature for <NUM>. After mixing evenly, <NUM> of liquid crystal polymer particles (specifically, Polyplastics A150 Vectra) were added into the mixed solution and stirred slowly for <NUM>∼<NUM>, the mixture was poured into a large amount of deionized water, washed repeatedly with deionized water, dried in a <NUM> vacuum oven for <NUM>, and finally prepared by hot press molding at <NUM> and <NUM> MPa into a nanocomposite film with a thickness of <NUM>∼<NUM> (i.e., the high dielectric liquid crystal polymer composite material) for test use.

<NUM> of MWCNTs and <NUM> of PVP were weighed, placed in <NUM> of absolute ethanol, respectively, and dispersed by sonication for <NUM>. After the multi-walled carbon nanotube solution was completely dispersed, the PVP solution was added slowly into the multi-walled carbon nanotube solution under stirring, and then the mixture was sealed and stirred for <NUM> at room temperature after completion of this dropwise addition; after reaction, a precipitate was centrifuged and washed for three times, and the precipitate after centrifugation and washing was labeled as MWCNTs-PVP; <NUM> of ethanol was added into a three-necked flask, and adjusted to pH <NUM>∼<NUM> with ammonia water, and under stirring, <NUM> of <NUM>-(methacryloyloxy)propyltrimethoxysilane mixture was added dropwise into the MWCNTs-PVP solution with a constant pressure funnel, and stirred for <NUM>; centrifugation and washing were repeated for three times to obtain a precipitate labeled as MWCNTs@SiO<NUM>; and this precipitate was dried in a <NUM> vacuum oven for <NUM> and ground to obtain multi-walled carbon nanotubes modified by the silane coupling agent, i.e., MWCNTs@SiO<NUM>.

<NUM> mmol/L Tris buffer was prepared by <NUM> of deionized water, then <NUM> of strontium titanate was added into the Tris buffer, and ultrasonically dispersed for <NUM> to form a stable suspension. Next, <NUM> of dopamine modifier (specifically dopa) was added into the suspension, pH value was adjusted to <NUM> with dilute HCl, then a sonication treatment was performed in an ice bath for <NUM>, the mixture was vigorously stirred at room temperature for <NUM>, and then strontium titanate with core-shell structure was obtained after vacuum suction filtration, and washed with deionized water and absolute ethanol for several times. The resulting powder was dried in a <NUM> vacuum oven for <NUM>. <NUM> of the strontium titanate obtained after above drying was dispersed in <NUM> of deionized water, and then sonicated in an ice bath for <NUM>, then <NUM> AgNO<NUM> solution (<NUM> mol/L) with a certain Ag+ concentration was quickly added, and reacted for <NUM> under vigorous stirring in an ice bath. After repeating centrifugation and washing for three times, finally the modified strontium titanate was dried under vacuum at <NUM> for <NUM>.

<NUM> of P(VDF-HFP) was dissolved in DMF and stirred at <NUM> for <NUM>. Simultaneously, <NUM> of MWCNTs@SiO<NUM> and <NUM> of modified dielectric ceramics were dispersed in another DMF by sonication and vigorously stirred at room temperature for <NUM>. The P(VDF-HFP) solution was then slowly added into this suspension, and a resulting mixture was stirred at room temperature for <NUM>. After mixing evenly, <NUM> of liquid crystal polymer particles (specifically, Polyplastics A150 Vectra) were added into the mixed solution and stirred slowly for <NUM>, the mixture was poured into a large amount of deionized water, washed repeatedly with deionized water, dried in a <NUM> vacuum oven for <NUM>, and finally prepared by hot press molding at <NUM> and <NUM> MPa into a nanocomposite film with a thickness of <NUM>∼<NUM> (i.e., the high dielectric liquid crystal polymer composite material) for test use.

<NUM> of MWCNTs and <NUM> of PVP were weighed, placed in <NUM> of absolute ethanol, respectively, and dispersed by sonication for <NUM>. After the multi-walled carbon nanotube solution was completely dispersed, the PVP solution was added slowly into the multi-walled carbon nanotube solution under stirring, and then the mixture was sealed and stirred at room temperature for <NUM> after completion of this dropwise addition; after reaction, a precipitate was centrifuged and washed for three times, and the precipitate after centrifugation and washing was labeled as MWCNTs-PVP; <NUM> of ethanol was added into a three-necked flask, and adjusted to pH <NUM>∼<NUM> with ammonia water, and under stirring, <NUM> of <NUM>-mercaptopropyltrimethoxysilane mixture was added dropwise into the MWCNTs-PVP solution with a constant pressure funnel, and stirred for <NUM>; centrifugation and washing were repeated for three times to obtain a precipitate labeled as MWCNTs@SiO<NUM>; and this precipitate was dried in a <NUM> vacuum oven for <NUM> and ground to obtain multi-walled carbon nanotubes modified by the silane coupling agent, i.e.,MWCNTs@SiO<NUM>.

<NUM> mmol/L Tris buffer was prepared by <NUM> of deionized water, then <NUM> of strontium titanate was added into the Tris buffer, and ultrasonically dispersed for <NUM> to form a stable suspension. Next, <NUM> of dopamine hydrochloride modifier (specifically dopamine) was added into the suspension, pH value was adjusted to <NUM> with dilute HCl, then a sonication treatment was performed in an ice bath for <NUM>, the mixture was vigorously stirred at room temperature for <NUM>, and then strontium titanate with core-shell structure was obtained after vacuum suction filtration, and washed with deionized water and absolute ethanol for several times. The resulting powder was dried in a <NUM> vacuum oven for <NUM>. <NUM> of strontium titanate was dispersed in <NUM> of deionized water, and then sonicated in an ice bath for <NUM>∼<NUM>, then <NUM>∼<NUM> AgNO<NUM> solution with a certain Ag+ concentration was quickly added, and reacted for <NUM> under vigorous stirring in an ice bath. After repeating centrifugation and washing for three times, finally the modified strontium titanate was dried under vacuum at <NUM> for <NUM>.

<NUM> of P(VDF-HFP) was dissolved in DMF and stirred at <NUM> for <NUM>. Simultaneously, <NUM> of MWCNTs@SiO<NUM> and <NUM> of modified strontium titanate were dispersed into another DMF by sonication and vigorously stirred at room temperature for <NUM>. The P(VDF-HFP) solution was then slowly added into this suspension, and a resulting mixture was stirred at room temperature for <NUM>. After mixing evenly, <NUM> of liquid crystal polymer particles (specifically, Polyplastics A150 Vectra) were added into the mixed solution and stirred slowly for <NUM>, the mixture was poured into a large amount of deionized water, washed repeatedly with deionized water, dried in a <NUM> vacuum oven for <NUM>, and finally prepared by hot press molding at <NUM> and <NUM> MPa into a nanocomposite film with a thickness of <NUM>∼<NUM> (i.e., the high dielectric liquid crystal polymer composite material) for test use.

<NUM> of MWCNTs and <NUM> of PVP were weighed, placed in <NUM> of absolute ethanol, respectively, and dispersed by sonication for <NUM>. After the multi-walled carbon nanotube solution was completely dispersed, the PVP solution was added slowly into the multi-walled carbon nanotube solution under stirring, and then the mixture was sealed and stirred for <NUM> at room temperature after completion of this dropwise addition; after reaction, a precipitate was centrifuged and washed for three times, and the precipitate after centrifugation and washing was labeled as MWCNTs-PVP; <NUM> of ethanol was added into a three-necked flask, and adjusted to pH <NUM>∼<NUM> with ammonia water, and under stirring, <NUM> of <NUM>-mercaptopropyltrimethoxysilane mixture was added dropwise into the MWCNTs-PVP solution with a constant pressure funnel, and stirred for <NUM>; centrifugation and washing were repeated for three times to obtain a precipitate labeled as MWCNTs@SiO<NUM>; and this precipitate was dried in a <NUM> vacuum oven for <NUM> and ground to obtain multi-walled carbon nanotubes modified by the silane coupling agent, i.e., MWCNTs@SiO<NUM>.

<NUM> mmol/L Tris buffer was prepared by <NUM> of deionized water, then <NUM> of barium titanate was added into the Tris buffer, and ultrasonically dispersed for <NUM> to form a stable suspension. Next, <NUM> of dopamine modifier was added into the suspension, pH value was adjusted to <NUM> with dilute HCl, then a sonication treatment was performed in an ice bath for <NUM>, the mixture was vigorously stirred at room temperature for <NUM>, and then barium titanate with core-shell structure was obtained after vacuum suction filtration, and washed with deionized water and absolute ethanol for several times. The resulting powder was dried in a <NUM> vacuum oven for <NUM>. <NUM> of barium titanate was dispersed in <NUM> of deionized water, and then sonicated in an ice bath for <NUM>, then <NUM> AgNO<NUM> solution (<NUM> mol/L) with a certain Ag+ concentration was quickly added, and reacted for <NUM> under vigorous stirring in an ice bath. After repeating centrifugation and washing for three times, finally the modified barium titanate was dried under vacuum at <NUM> for <NUM>.

<NUM> of P(VDF-HFP) was dissolved in DMF and stirred at <NUM> for <NUM>. Simultaneously, <NUM> of MWCNTs@SiO<NUM> and <NUM> of modified barium titanate were dispersed in another DMF by sonication and vigorously stirred at room temperature for <NUM>. The P(VDF-HFP) solution was then slowly added into this suspension, and a resulting mixture was stirred at room temperature for <NUM>. After mixing evenly, <NUM> of liquid crystal polymer particles (specifically, Polyplastics A150 Vectra) were added into the mixed solution and stirred slowly for <NUM>, the mixture was poured into a large amount of deionized water, washed repeatedly with deionized water, dried in a <NUM> vacuum oven for <NUM>, and finally prepared by hot press molding at <NUM> and <NUM> MPa into a nanocomposite film with a thickness of <NUM>∼<NUM> (i.e., the high dielectric liquid crystal polymer composite material) for test use.

<NUM> of MWCNTs and <NUM> of PVP were weighed, placed in <NUM> of absolute ethanol, respectively, and dispersed by sonication for <NUM>. After the multi-walled carbon nanotube solution was completely dispersed, the PVP solution was added slowly into the multi-walled carbon nanotube solution under stirring, and then the mixture was sealed and stirred at room temperature for <NUM> after completion of this dropwise addition; after reaction, a precipitate was centrifuged and washed for three times, and the precipitate after centrifugation and washing was labeled as MWCNTs-PVP; <NUM> of ethanol was added into a three-necked flask, and adjusted to pH <NUM>∼<NUM> with ammonia water, and under stirring, <NUM> of <NUM>-(methacryloyloxy)propyltrimethoxysilane mixture was added dropwise into the MWCNTs-PVP solution with a constant pressure funnel, and stirred for <NUM>; centrifugation and washing were repeated for three times to obtain a precipitate labeled as MWCNTs@SiO<NUM>; and this precipitate was dried in a <NUM> vacuum oven for <NUM> and ground to obtain multi-walled carbon nanotubes modified by the silane coupling agent, i.e., MWCNTs@SiO<NUM>.

<NUM> mmol/L Tris buffer was prepared by <NUM> of deionized water, then <NUM> of calcium titanate was added into the Tris buffer, and ultrasonically dispersed for <NUM> to form a stable suspension. Next, <NUM> of dopamine hydrochloride modifier was added into the suspension, pH value was adjusted to <NUM> with dilute HCl, then a sonication treatment was performed in an ice bath for <NUM>, the mixture was vigorously stirred at room temperature for <NUM>, and then calcium titanate with core-shell structure was obtained after vacuum suction filtration, and washed with deionized water and absolute ethanol for several times. The resulting powder was dried in a <NUM> vacuum oven for <NUM>. <NUM> of calcium titanate was dispersed in <NUM> of deionized water, and then sonicated in an ice bath for <NUM>, then <NUM> AgNO<NUM> solution (<NUM> mol/L) with a certain Ag+ concentration was quickly added, and reacted for <NUM> under vigorous stirring in an ice bath. After repeating centrifugation and washing for three times, finally the modified dielectric ceramics was dried under vacuum at <NUM> for <NUM>.

<NUM> of P(VDF-HFP) was dissolved in DMF and stirred at <NUM> for <NUM>. Simultaneously, <NUM> of MWCNTs@SiO<NUM> and <NUM> of modified calcium titanate were dispersed into another DMF by sonication and vigorously stirred at room temperature for <NUM>. The P(VDF-HFP) solution was then slowly added into this suspension, and a resulting mixture was stirred at room temperature for <NUM>. After mixing evenly, <NUM> of liquid crystal polymer particles (specifically, Polyplastics A150 Vectra) were added into the mixed solution and stirred slowly for <NUM>, the mixture was poured into a large amount of deionized water, washed repeatedly with deionized water, dried in a <NUM> vacuum oven for <NUM>, and finally prepared by hot press molding at <NUM> and <NUM> MPa into a nanocomposite film with a thickness of <NUM>∼<NUM> (i.e., the high dielectric liquid crystal polymer composite material) for test use.

This example provides a high dielectric liquid crystal polymer composite material, the preparation method of which was different from Embodiment <NUM> only in that: the dielectric ceramics (i.e., barium titanate) were not modified, and the barium titanate was directly used as the raw material for preparing the high dielectric liquid crystal composite material in step (<NUM>). The remaining steps and parameters were the same.

This example provides a high dielectric liquid crystal polymer composite material, the preparation method of which was different from Embodiment <NUM> only in that: the multi-walled carbon nanotubes were not modified, and the multi-walled carbon nanotubes were directly used as the raw material for preparing the high dielectric liquid crystal composite material in step (<NUM>). The remaining steps and parameters were the same.

This example provides a high dielectric liquid crystal polymer composite material, the preparation method of which was different from Embodiment <NUM> only in that: in step (<NUM>), the amount of modified dielectric ceramics was <NUM>, and the amount of modified multi-walled carbon nanotubes was <NUM>. The remaining steps and parameters were the same.

In this test example, the properties of the liquid crystal polymer composite materials obtained in Embodiments <NUM>-<NUM> and Comparative Examples <NUM>-<NUM> and pure LCP were tested, and the test results are shown in Table <NUM>.

It is understood that the endpoints of the ranges and any values disclosed herein are not limited to the precise ranges or values, which are understood as encompassing values proximate to those ranges or values. For ranges of values, combination between the endpoints of each range, between the endpoints of each range and the individual point values, and between the individual point values can be made to yield one or more new ranges of values, which should be considered as specifically disclosed herein.

Claim 1:
A high dielectric liquid crystal polymer composite material, characterized by comprising: liquid crystal polymer (LCP); poly(vinylidene fluoride-co-hexafluoropropylene); modified multi-walled carbon nanotubes; and modified dielectric ceramics;
wherein the modified multi-walled carbon nanotubes comprise following components metered by mass:
<NUM>-<NUM> parts of multi-walled carbon nanotubes; <NUM>~<NUM> parts of polyvinyl pyrrolidone; and <NUM>-<NUM> parts of a silane coupling agent; and
the modified dielectric ceramics comprise following components metered by mass:
<NUM>∼<NUM> parts of dielectric ceramics; and <NUM>∼<NUM> parts of a dopa-like compound.