CN1648156A - Process for preparing blended micrometer TiO2 polymer electrolyte - Google Patents

Process for preparing blended micrometer TiO2 polymer electrolyte Download PDF

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Publication number
CN1648156A
CN1648156A CNA2004101018899A CN200410101889A CN1648156A CN 1648156 A CN1648156 A CN 1648156A CN A2004101018899 A CNA2004101018899 A CN A2004101018899A CN 200410101889 A CN200410101889 A CN 200410101889A CN 1648156 A CN1648156 A CN 1648156A
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film
hfp
solvent
pvdf
polymer
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CN1260278C (en
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王新东
刘伯文
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University of Science and Technology Beijing USTB
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University of Science and Technology Beijing USTB
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Abstract

The present invention relates to the preparation process of electrolyte for polymer lithium ion cell. The present invention uses micron level TiO2 powder as stuffing for polymer electrolyte film, and prepares PVDF-HFP base polymer electrolyte film via phase transfer process. In the weight ratio of PVDF-HFP to TiO2 in 9-49, weight ratio of PVDF-HFP to deionized water to acetone in 1 to 0.25-1.25 to 5-15, the mixture of solvent and non-solvent is added into the mixture of polymer matrix PVDF-HFP and micron stuffing TiO2 to obtain while homogeneous porous polymer film, which is then soaked in electrolyte liquid for lithium ion cell to obtain electrolyte film with ionic conducting performance and finally heat treated. The present invention has improved and stabilized pore structure of polymer electrolyte film and raised electrochemical performance and mechanical performance of electrolyte film.

Description

A kind of blended micrometer TiO 2Method for preparing polymer electrolytes
Technical field
The present invention relates to method for preparing polymer electrolytes, specially refer to the preparation of polymer lithium ion battery electrolyte.
Background technology
Polymer Li-ion battery is the characteristics such as high-voltage, high-energy-density, long circulation life and environmental protection of tool usefulness liquid lithium ionic cell not only, and because it adopts all solid state soft packaging, thereby can be made into thin, light and shape battery arbitrarily, these characteristics have satisfied just in time that portable electronics is light to its power supply, the requirement of thinning.At present, the gordian technique of polymer Li-ion battery is the preparation of polymer dielectric film.As the barrier film and the ionogen of lithium ion battery, polymer dielectric should possess characteristics such as the electrochemical window of higher room-temperature ion electric conductivity, good electrode interface stability, broad and favorable mechanical performance.Polymer dielectric can be divided into three types by structure: pure solid polymer electrolyte (DSPE), gel-type polymer electrolyte (GSPE) and porous polymer ionogen (PSPE).The electrolytical ionic conductivity of DSPE is lower, and maximum is 10 -5~10 -4Scm -1The order of magnitude can not satisfy the requirement of lithium ion battery.Two kinds of electrolytical ionic conductivities of GSPE and PSPE all can reach 10 -3Scm -1More than the order of magnitude, but its mechanical property but can not be satisfactory, and the porosity of film is high more, and mechanical property is poor more.Studies show that, in polymer electrolyte matrices, mix a spot of small size inorganic ceramic powder and can improve ionic conductivity effectively, increase stability of physical strength and raising and electrode interface or the like.In the 249th~257 page of " PlasticPVDF-HFP electrolyte laminates prepared by a phase-inversion process " article of delivering of " Solid State Ionics " 2000 the 135th volumes, adopt the phase inversion process preparation to add nanometer SiO 2Vinylidene-hexafluoropropylene copolymer (PVDF-HFP) hole, Quito dielectric film, the ionic conductivity of this film reaches 3.09mScm -1Employing extraction process preparation interpolation nanometer Al reported in the article of " electroconductibility of nano-filled PVDF-HFP composite electrolyte " in " SCI " 2003 the 24th volumes o. 11th 2O 3PVDF-HFP base electrolyte film, the ionic conductivity of this film reaches 1.7mScm -1Because what these two kinds of methods all adopted is that nano material is made weighting agent, and the surfactivity height of nano material is difficult for disperseing, and causes the ununiformity of dielectric film, thereby has influenced the performance of dielectric film.
Summary of the invention
The present invention proposes with small size micron TiO 2Powder is made the weighting agent of polymer dielectric film, adopt phase inversion process to prepare PVDF-HFP (model LBG-1) base polymer electrolyte film, and polymer dielectric film heat-treated, improve the pore texture of polymer dielectric film, thereby improve chemical property, mechanical property and the stability of dielectric film.
Preparation process of the present invention is:
(1) by weight PVDF-HFP: TiO 2=49~9: 1 ratio takes by weighing polymeric matrix PVDF-HFP and weighting agent micron TiO 2, by weight PVDF-HFP: deionized water: the proportioning of acetone=1: 0.25~1.25: 5~15 takes by weighing non-solvent deionized water and solvent acetone, and the mixed solution of solvent and non-solvent is joined polymeric matrix PVDF-HFP and weighting agent micron TiO 2Mixture in;
(2) said mixture is placed homo(io)thermism 40 ℃~80 ℃ water-bath, heated and stirred is cooled to room temperature after 2~6 hours while stirring, obtains the heavy-gravity film-casting liquid;
(3) above-mentioned film-casting liquid is fully disperseed once more after, obtain milky film-casting liquid;
(4) this oyster white film-casting liquid is cast in the mould, treat promptly to obtain white apertured polymeric film uniformly after the volatilization of solvent and non-solvent;
(5) apertured polymeric film that obtains is placed in 50~80 ℃ the baking oven and heat-treated 5~10 hours;
(6) under dry environment, the apertured polymeric film after the vacuum-drying be impregnated in the electrolytic solution of lithium ion battery 30~60 minutes, take out and inhale the electrolytic solution that goes to the surface unnecessary, obtain having the dielectric film of ionic conducting property.
Compared with prior art, characteristics of the present invention are: adopt phase inversion process preparation interpolation micron TiO 2The PVDF-HFP base polymer electrolyte.Add an amount of micron TiO in the film-casting liquid 2, the micropore of dielectric film is evenly distributed, and the aperture is less.This little and many pore texture had both helped the absorption of polymer dielectric film to electrolytic solution, can improve the mechanical property of polymer dielectric film again.Simultaneously, polymeric film is carried out the stress that appropriate thermal treatment can be eliminated film inside, improve the stability of polymer dielectric film.Table 1 is the blank assay sample and adds TiO 2The performance comparison of polymer electrolytic quality sample.
The performance comparison of table 1 polymer dielectric film
Example Ionic conductivity σ/Scm -1 Pick up/% Transference number of ions t Li+ Porosity/%
No TiO 2 ????1.65×10 -3 ????244.5 ????0.309 ????72.4
Contain TiO 2 ????2.04×10 -3 ????297 ????0.377 ????73.3
As can be seen from Table 1, add an amount of micron order TiO 2After, the porosity of polymer dielectric film does not change, but its pick up, ionic conductivity and transference number of ions all are significantly improved.This explanation micron TiO 2Interpolation and thermal treatment process can obviously improve pore texture and chemical property with the stabilization of polymer dielectric film.
Fig. 1 is the surperficial SEM photo of blank assay sample, and Fig. 2 adds TiO 2The surperficial SEM photo of polymer electrolytic quality sample.From Fig. 1 and Fig. 2 as can be seen: the internetwork hole of polymer dielectric film is bigger among Fig. 1, has formed more complete pore structure, and its aperture is about 6~8 μ m, and the physical strength of this network structure is relatively poor; Contain a micron TiO among Fig. 2 2The microtexture of polymer dielectric film more even, do not form complete pore structure, hole between staggered-mesh is less, and this structure more helps absorption and the maintenance of dielectric film to electrolytic solution, thereby improves the ionic conductivity and the transference number of ions of dielectric film.Simultaneously, because polymer network structure is finer and close, make this physical strength improve greatly with dielectric film of little and many hole.Polymeric film is carried out the stress that appropriate thermal treatment can be eliminated film inside, improve the stability of polymer dielectric film.
Description of drawings
Fig. 1 makes the SEM figure of sample for blank assay
Fig. 2 makes the SEM figure of sample for embodiment 1
Fig. 3 makes membranous Li/ ionogen/LiCoO for making sample with embodiment 1 2The 0.2C charging and discharging curve of battery
Embodiment
Embodiment 1:
(1) takes by weighing PVDF-HFP (U.S. Elf atochem LBG-1) 3g and D 50The TiO of=1.4 μ m 2(analytical pure) 0.13g puts into Erlenmeyer flask, takes by weighing deionized water 1.5g, acetone 30g, joins after the mixing and fills polymeric matrix PVDF-HFP and TiO 2Erlenmeyer flask in;
(2) said mixture places homo(io)thermism 60 ℃ water-bath, and the heating magnetic agitation is after 2 hours, and the limit is stirred and is cooled to room temperature, obtains white heavy-gravity film-casting liquid;
(3) above-mentioned film-casting liquid is carried out ultrasonic dispersing after 8 minutes, obtain milky film-casting liquid;
(4) this oyster white film-casting liquid is cast in the mould, treat promptly to obtain white porous polymer electrolyte film uniformly after the volatilization of solvent and non-solvent;
(5) apertured polymeric film that obtains is placed in 50 ℃ the baking oven and heat-treated 6 hours;
(6) under dry environment, the apertured polymeric film after the vacuum-drying be impregnated in the electrolytic solution of lithium ion battery 45 minutes, take out and inhale the electrolytic solution that goes to the surface unnecessary, obtain having the dielectric film of ionic conducting property.
The SEM microcosmic picture of the polymer dielectric film that embodiment 1 makes is seen Fig. 2.As can be seen from the figure: contain micron order TiO 2The microtexture of polymer dielectric film more even, do not form complete pore structure, hole between staggered-mesh is less, and this structure more helps absorption and the maintenance of dielectric film to electrolytic solution, thereby improves the ionic conductivity and the transference number of ions of dielectric film.Simultaneously, because polymer network structure is finer and close, make this physical strength improve greatly with dielectric film of little and many hole.Polymeric film is carried out the stress that appropriate thermal treatment can be eliminated film inside, improve the stability of polymer dielectric film.
Fig. 3 is to be membranous LiCoO with the dielectric film that embodiment 1 makes 2The first charge-discharge curve of electrode/electrolyte/Li simulated battery, its efficiency for charge-discharge are 84.4%, and this illustrates that this dielectric film is suitable as the electrolyte membrance of lithium ion battery.
Embodiment 2:
(1) takes by weighing PVDF-HFP (U.S. Elf atochem LBG-1) 3g and D 50The TiO of=1.4 μ m 2(analytical pure) 0.08g puts into Erlenmeyer flask, takes by weighing deionized water 1.5g, acetone 30g, joins after the mixing and fills polymeric matrix PVDF-HFP and TiO 2Erlenmeyer flask in;
(2) said mixture is placed homo(io)thermism 50 ℃ water-bath, the heating magnetic agitation is after 4 hours, and the limit is stirred and is cooled to room temperature, obtains white heavy-gravity film-casting liquid;
(3) above-mentioned film-casting liquid is carried out ultrasonic dispersing after 16 minutes, obtain milky film-casting liquid;
(4) this oyster white film-casting liquid is cast in the mould, treat promptly to obtain white porous polymer electrolyte film uniformly after the volatilization of solvent and non-solvent;
(5) apertured polymeric film that obtains is placed in 80 ℃ the baking oven and heat-treated 10 hours;
(6) under dry environment, the apertured polymeric film after the vacuum-drying be impregnated in the electrolytic solution of lithium ion battery 60 minutes, take out and inhale the electrolytic solution that goes to the surface unnecessary, obtain having the dielectric film of ionic conducting property.
The dielectric film that makes with embodiment 2 is barrier film, LiCoO 2For positive electrode material, Li are that negative material is assembled into simulated battery, its gram volume of 0.2C discharge first is 127.4mAh/g, and first charge-discharge efficiency is 87.8%, and this illustrates that this dielectric film is suitable as the electrolyte membrance of lithium ion battery.

Claims (1)

1, a kind of blended micrometer TiO 2Method for preparing polymer electrolytes, it is characterized in that the step of preparation is:
1) by weight PVDF-HFP: TiO 2=49~9: 1 ratio takes by weighing polymeric matrix PVDF-HFP and weighting agent micron TiO 2, by weight PVDF-HFP: deionized water: the proportioning of acetone=1: 0.25~1.25: 5~15 takes by weighing non-solvent deionized water and solvent acetone, and the mixed solution of solvent and non-solvent is joined polymeric matrix PVDF-HFP and weighting agent micron TiO 2Mixture in;
2) said mixture is placed homo(io)thermism 40 ℃~80 ℃ water-bath, heated and stirred is cooled to room temperature after 2~6 hours while stirring, obtains the heavy-gravity film-casting liquid;
3) above-mentioned film-casting liquid is fully disperseed once more after, obtain milky film-casting liquid;
4) this oyster white film-casting liquid is cast in the mould, treat promptly to obtain white apertured polymeric film uniformly after the volatilization of solvent and non-solvent;
5) apertured polymeric film that obtains is placed in 50~80 ℃ the baking oven and heat-treated 5~10 hours;
6) under dry environment, the apertured polymeric film after the vacuum-drying be impregnated in the electrolytic solution of lithium ion battery 30~60 minutes, take out and inhale the electrolytic solution that goes to the surface unnecessary, obtain having the dielectric film of ionic conducting property.
CNB2004101018899A 2004-12-30 2004-12-30 Process for preparing blended micrometer TiO2 polymer electrolyte Expired - Fee Related CN1260278C (en)

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Cited By (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN100365056C (en) * 2006-08-24 2008-01-30 北京科技大学 Method for preparing electrolyte of porous compound polymer doped by titanium dioxide through hydrolysis method in situ
CN100465225C (en) * 2006-10-24 2009-03-04 北京科技大学 Process for preparing hybridized porous lithium ion cell electrolyte film
CN101153084B (en) * 2006-09-28 2010-12-08 万向电动汽车有限公司 Polyalcohol microporous barrier for high ratio polyalcohol lithium ion power cell
CN101280065B (en) * 2008-05-29 2011-06-29 复旦大学 Polymer film having micropore structure, preparation and application thereof
CN102195092A (en) * 2010-03-19 2011-09-21 深圳市比克电池有限公司 Gel polymer lithium ion battery and preparation method thereof
CN102286158A (en) * 2011-06-23 2011-12-21 中南大学 Method for preparing porous composite polymer electrolyte film through gas volatilization
CN103840112B (en) * 2012-11-19 2017-04-12 东莞东阳光科研发有限公司 PVDF-HFP-based composite porous polymer diaphragm and preparation method thereof
CN104650375B (en) * 2015-03-17 2017-08-11 长沙理工大学 Preparation method of composite polymer electrolyte membrane
CN113587803A (en) * 2021-08-04 2021-11-02 郑州轻工业大学 Capacitive polymer strain sensor, preparation method and application

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN100365056C (en) * 2006-08-24 2008-01-30 北京科技大学 Method for preparing electrolyte of porous compound polymer doped by titanium dioxide through hydrolysis method in situ
CN101153084B (en) * 2006-09-28 2010-12-08 万向电动汽车有限公司 Polyalcohol microporous barrier for high ratio polyalcohol lithium ion power cell
CN100465225C (en) * 2006-10-24 2009-03-04 北京科技大学 Process for preparing hybridized porous lithium ion cell electrolyte film
CN101280065B (en) * 2008-05-29 2011-06-29 复旦大学 Polymer film having micropore structure, preparation and application thereof
CN102195092A (en) * 2010-03-19 2011-09-21 深圳市比克电池有限公司 Gel polymer lithium ion battery and preparation method thereof
CN102286158A (en) * 2011-06-23 2011-12-21 中南大学 Method for preparing porous composite polymer electrolyte film through gas volatilization
CN102286158B (en) * 2011-06-23 2012-12-12 中南大学 Method for preparing porous composite polymer electrolyte film through gas volatilization
CN103840112B (en) * 2012-11-19 2017-04-12 东莞东阳光科研发有限公司 PVDF-HFP-based composite porous polymer diaphragm and preparation method thereof
CN104650375B (en) * 2015-03-17 2017-08-11 长沙理工大学 Preparation method of composite polymer electrolyte membrane
CN113587803A (en) * 2021-08-04 2021-11-02 郑州轻工业大学 Capacitive polymer strain sensor, preparation method and application

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