CN100544110C - Lithium-ion polymer electrolyte membrane and method for manufacturing lithium-ion battery containing the membrane - Google Patents

Lithium-ion polymer electrolyte membrane and method for manufacturing lithium-ion battery containing the membrane Download PDF

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CN100544110C
CN100544110C CNB2007100546716A CN200710054671A CN100544110C CN 100544110 C CN100544110 C CN 100544110C CN B2007100546716 A CNB2007100546716 A CN B2007100546716A CN 200710054671 A CN200710054671 A CN 200710054671A CN 100544110 C CN100544110 C CN 100544110C
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lithium ion
ion polymer
polymer electrolyte
preparation
lithium
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CN101335365A (en
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贾晓林
刘新保
郭晓伟
刘宇飞
户赫龙
吴江峰
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ZHENGZHOU DELANGNENG BATTERY CO Ltd
Zhengzhou University
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ZHENGZHOU DELANGNENG BATTERY CO Ltd
Zhengzhou University
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Abstract

本发明涉及一种锂离子聚合物电解质膜及含该电解质膜的锂离子电池的制备方法。在本发明中以PEO大单体、烯类小单体、偶氮二异丁腈进行自由基共聚反应制备出高非晶相的聚合物基体,该基体与锂盐、快离子导体纳米粉复合后,以流延法制成锂离子聚合物电解质膜,该电解质膜机械性能良好、化学性能稳定、电导率高;再以磷酸铁锂为正极材料、所述电解质膜为隔膜制成锂离子聚合物电池;该电池电化学性能好、容量大,循环寿命长,充、放电过程安全可靠。本发明中的生产工艺简便,成品率高,成本低,所制备出的正、负极片质地均匀,产品性能均一,便于组合成电池组工作。The invention relates to a lithium ion polymer electrolyte membrane and a preparation method of a lithium ion battery containing the electrolyte membrane. In the present invention, a polymer matrix with high amorphous phase is prepared by free radical copolymerization with PEO macromonomer, ethylenic small monomer, and azobisisobutyronitrile, and the matrix is compounded with lithium salt and fast ion conductor nanopowder Finally, the lithium ion polymer electrolyte membrane is made by casting method, the electrolyte membrane has good mechanical properties, stable chemical properties, and high electrical conductivity; then lithium iron phosphate is used as the positive electrode material, and the electrolyte membrane is used as the separator to make the lithium ion polymer electrolyte membrane. Battery; the battery has good electrochemical performance, large capacity, long cycle life, safe and reliable charging and discharging process. The production process in the invention is simple, the yield is high, and the cost is low. The prepared positive and negative plates have uniform texture and uniform product performance, and are convenient to be combined into a battery pack to work.

Description

Lithium ion polymer electrolyte film and contain the manufacture method of the lithium ion battery of this film
(1) technical field
The present invention relates to the rechargeable lithium ion batteries technical field, relate in particular to a kind of lithium ion polymer electrolyte film and preparation method thereof, also relate to a kind of manufacture method that contains the lithium ion battery of this lithium ion polymer electrolyte film.
(2) background technology
Lithium ion battery is meant that embedding compound with lithium ion is the general name of positive electrode.The charge and discharge process of lithium ion battery is exactly the embedding of lithium ion and take off the embedding process.Research to lithium ion battery starts from the eighties in 20th century, nineteen ninety Japan to be developed into the petroleum coke be negative pole, LiCoO 2Be the lithium rechargeable battery of positive pole, and realize that commercialization, its appearance can deserve to be called the historical once leap of secondary cell.The positive electrode that lithium ion cell positive is commonly used lithium ion commonly used embeds compound, as LiCoO 2, LiNO 2, LiWO 2, LiMn 2O 4, LiFePO 4Deng, present LiCoO 2Use the most successful; Negative material lithium ion commonly used inserts compound, mainly contains: LixC 6, TiS 2, WO 3, NbS 2And V 2O 5Deng, LixC 6Most widely used general, use the graphite-structure carbon materials usually, also can use coke carbon element material; The electrolyte of lithium ion battery has two kinds: organic solvent-inorganic electrolyte plastidome and solid polymer electrolyte.
Lithium ion battery just develops towards light weight, high energy, ultra-thin, safe direction at present, and employing polymer (macromolecular material) is made the electrode of battery, the research of electrolyte becomes important developing direction.Liquid electrolyte battery must use firm metal shell, and model is fixed (being fixed size), lacks flexibility, and unavoidable individual cell is revealed in the batch process; Battery assembly program complexity, cost is higher; The lithium ion battery working voltage can not be too high, otherwise make the electrode instability in the battery.In order to overcome the above-mentioned shortcoming of liquid lithium ionic cell, developed the solid electrolyte lithium ion battery again.Nearest 20 years, the higher macromolecular material of ionic conductivity received much attention.1973, Wright etc. found that first polyoxyethylene (PEO) and alkali metal salt coordination have ionic conductivity.1978, Armand proposed PEO/ alkali metal salt complex as the ion conductor that has the novel rechargeable battery of alkali metal electrode, and this suggestion makes polymer solid electrolyte become macromolecule research field very noticeable heat subject over 20 years.The characteristics of polymer solid electrolyte are the ionic conductivities that has than higher, in the time of the broad current potential, also have easily film shaped, soft, light weight, advantage such as flexible, transparent, be contain ionic conductivity unorganic glass class solid electrolyte can't realize.And polyoxyethylene (PEO) has favorable mechanical performance and chemical stability, is to be expected to one of commercial polymer electrolyte system, but after slaine is dissolved in PEO, easily forms the crystalline state compound, and its conductivity is lower, far can not satisfy the needs of application.
Positive electrode also is one of key technology of development high performance lithium ion battery material, but the LiCoO that commercialization is used 2Shortage of resources, cost an arm and a leg and toxic LiNiO 2The preparation difficulty, and have safety issue, and LiMn 2O 4Cycle performance and high-temperature behavior be difficult to meet the demands.
(3) summary of the invention
The technical problem to be solved in the present invention provides the lithium ion polymer electrolyte film that a kind of machining property is good, chemical stability good, conductivity is high, and provided this dielectric film and contain this dielectric film with LiFePO 4Manufacture method for the lithium ion polymer battery of positive electrode.
For solving the problems of the technologies described above, the technical solution used in the present invention is:
Be equipped with the polymeric matrix of high amorphous phase with chemical blending method, macromonomer legal system, again with polymeric matrix and lithium salts, fast-ionic conductor nano powder compound after, make lithium ion polymer electrolyte film with The tape casting; With the LiFePO4 is that positive electrode, described lithium ion polymer electrolyte film are that barrier film is made lithium ion polymer battery.
A kind of lithium ion polymer electrolyte film, it is to be that 200~1000 the big monomer of PEO, alkene class minor comonomer, azodiisobutyronitrile carry out the high amorphous phase polymeric matrix that free radicals copolymerization reaction was generated with the mol ratio of 1:1~100:0.01~0.11 under 70~90 ℃ by mean molecule quantity, under the atmosphere of inert gas with LiBF 4, Li-β-Al 2O 3Behind the compound generation lithium ion polymer electrolyte of nano powder, again under the atmosphere of 40~60 ℃ inert gas after solvent is removed in the curtain coating volatilization made dielectric film, it contains LiBF 4O~20wt%, Li-β-Al 2O 3Nano powder 5~30wt%, conductivity is 3.5~6.2 * 10 under this dielectric film room temperature -3S/cm.Described alkene class minor comonomer is at least a in acrylonitrile, acrylic acid lithium, butyl acrylate, methyl methacrylate and the acrylamide.
A kind of method for preparing above-mentioned lithium ion polymer electrolyte film may further comprise the steps:
(1) high amorphous phase polymeric matrix preparation
Be 200~1000 the big monomer of PEO with mean molecule quantity: alkene class minor comonomer: azodiisobutyronitrile is dissolved in the methanol solvate in the reactor with the mol ratio of 1:1~100:0.01~0.11, the weight ratio of big monomer of PEO and methanol solvate is 1:11~15, above-mentioned reactant reacted 8~12 hours under the condition of 70~90 ℃ of temperature, magnetic agitation, nitrogen atmosphere, must contain the methanol solution of copolymerization product.Copolyreaction with acrylic acid lithium and the big monomer of PEO is an example, and its reaction equation can roughly be expressed as follows:
Figure C200710054671D0007134203QIETU
Or
Figure C200710054671D0007134224QIETU
M gets natural number in the above-mentioned reaction equation, and n is the natural number in 5~12 scopes, and wherein the product of first reaction equation is a cross-linked copolymer, is a kind of baroque network polymers; The product of second reaction equation is a comb copolymer, and main chain is a polyolefin, and side chain is PEO and carboxylic acid lithium.
(2) compound electrolyte material
In the above-mentioned methanol solution that contains copolymerization product, add LiBF 4, Li-β-Al 2O 3Nano powder stirs into uniform slurry, wherein LiBF 4Consumption is 0~20wt% of gained lithium ion polymer electrolyte film, Li-β-Al 2O 3Nano powder is 5~30wt%;
(3) casting film
After above-mentioned slurry leaves standstill the degassing, be to carry out casting film under 40~60 ℃ the nitrogen atmosphere in temperature, solvent is heated in this process and vapors away, and its curtain coating rotating speed is controlled at 0.18~0.60m/min.
In above-mentioned preparation process, described step (2) also can be: the described methanol solution that contains copolymerization product is filtered, and purifying gets copolymerization product after the vacuumize, the copolymerization product thermosol behind oxolane, is added LiBF again in this solution 4, Li-β-Al 2O 3Nano powder stirs into uniform slurry, wherein LiBF 4Consumption is 0~20wt% of gained lithium ion polymer electrolyte film, Li-β-Al 2O 3Nano powder is 5~30wt%.
Alkene class minor comonomer described in the above-mentioned electrolytic film preparation process is at least a in acrylonitrile, acrylic acid lithium, butyl acrylate, methyl methacrylate and the acrylamide.
The preparation method of above-mentioned lithium ion polymer electrolyte film, a kind of preparation method of the big monomer of described PEO may further comprise the steps:
It with mean molecule quantity 200~1000 polyethylene glycol, triethylamine, acryloyl chloride is got ready with the mol ratio of 1:1.8~3.0:2.8~4.0, and get toluene solvant ready with the weight ratio of polyethylene glycol: toluene=1:3~12, in magnetic agitation, temperature is under 35~45 ℃ the reaction condition, successively with polyethylene glycol, triethylamine joins in the toluene solvant in the reactor, slowly add acryloyl chloride again, add follow-up continuation of insurance temperature and stirred 4~8 hours, after finishing, reaction removes by filter the amine salt of generation, evaporated filtrate is removed partial solvent, adding volume then is 4~12 times ether sedimentation agent of residual filtrate volume, with the product suction filtration final vacuum drying that is settled out, promptly get the big monomer of polyoxyethylene that two ends contain two keys and have ether oxygen atom.Its reactional equation is expressed as follows:
Figure C200710054671D0009134253QIETU
The big monomer molecule amount of PEO is determined that by polymerization degree n the span of n is 5~12 in its Chinese style.
The preparation method of above-mentioned lithium ion polymer electrolyte film, another preparation method of the big monomer of described PEO may further comprise the steps:
It with mean molecule quantity 200~1000 poly glycol monomethyl ether, triethylamine, acryloyl chloride is got ready with the mol ratio of 1:1.0~1.8:1.6~2.2, and get toluene solvant ready with the weight ratio of poly glycol monomethyl ether: toluene=1:3~12, in magnetic agitation, temperature is under 35~45 ℃ the reaction condition, successively with poly glycol monomethyl ether, triethylamine joins in the toluene solvant in the reactor, slowly add acryloyl chloride again, add follow-up continuation of insurance temperature and stirred 4~6 hours, after finishing, reaction removes by filter the amine salt of generation, evaporated filtrate is removed partial solvent, adding volume then is 4~12 times ether sedimentation agent of residual filtrate volume, with the product suction filtration final vacuum drying that is settled out, promptly get the big monomer of polyoxyethylene that an end contains two keys and has ether oxygen atom.Its reactional equation is expressed as follows:
Figure C200710054671D0009134420QIETU
The big monomer molecule amount of PEO is determined that by polymerization degree n the span of n is 5~12 in its Chinese style.
Described Li-β-Al 2O 3Nano powder prepares with sol-gel process, and concrete steps are: with [Li +]/[Al 3+The ratio of]=1:5.0 is got aluminum nitrate and lithium nitrate and is mixed with the solution of 1mol/L and mixes, under the situation of vigorous stirring, dropwise drip the 1mol/L ammonium bicarbonate soln, regulate pH value to 4.10~4.20 of mixed solution, again through after 0.5~2 hour the vigorous stirring still aging 40~50 hours, grind dry back in 40~70 ℃ drying box, obtain dry gel powder, it is heat-treated under 800~1100 ℃ temperature, and be incubated 2~3 hours, behind the natural cooling, grind, be Li-β-Al 2O 3The fast-ionic conductor nano powder.
A kind of manufacture method that contains the lithium ion polymer battery of aforementioned lithium ion polymer electrolyte film, it may further comprise the steps:
(1) positive plate preparation
A stirred 1 hour after LiFePO4, acetylene black, Kynoar, N-N-2-methyl pyrrolidone are mixed with the weight ratio of 100:1.0~5.0:2.8~15.0:80~150 at least, made its viscosity reach 2000~20000mPa.s;
B will go up step gained slurry and be coated on equably on the aluminium foil, coating density 50~200g/m 2, at 80~150 ℃ down after the oven dry, with its roll to bulk density be 1.5~3.0g/cm 3
C presses the size cutting, soldering polar ear, and do insulation and handle;
(2) negative plate preparation
A with graphite, saturated polyester, the methylcellulose that contracts receive, styrene-butadiene: after mixing with the weight ratio of 100:0.5~3:0.5~2:2~6:100~150, stirred at least 1 hour, make its viscosity reach 2000~20000mPa.s;
B evenly is coated on the Copper Foil, coating density 25~150g/m 2, at 80~150 ℃ down after the oven dry, with its roll to bulk density be 1.0~1.8g/cm 3
C presses the size cutting, soldering polar ear, and do insulation and handle;
(3) battery assembling
Positive and negative plate is over against lamination, and middle metal-back or aluminum-plastic composite membrane are put in the compound back of hot pressing with described polymer dielectric film isolation, sealing, and activate.
The lithium ion polymer battery of above-mentioned lithium ion polymer electrolyte film can be made square or reel and make column type.
The present invention has actively useful effect:
1. (conductivity can reach 3.5~6.2 * 10 under the room temperature for the lithium ion polymer electrolyte film satisfactory mechanical property of preparing, stable chemical performance, conductivity height -3S/cm).
2. positive plate, negative plate production technology are easy, and the positive plate of preparation, negative plate quality are more even, and the homogeneity of properties of product is improved, and is convenient to be combined into battery pack.
3. be positive electrode with the LiFePO4, LiFePO4 Stability Analysis of Structures, theoretical capacity are 170mAh/g, aboundresources, security performance is good, nontoxic environmentally friendly, and along with temperature raises, material specific capacity increases, and is suitable for using under ask for something comparison exacting terms.LiFePO 4Lithium ion battery can be widely used on high security, high potential and the chargeable electric equipment, and for example, electronic and hybrid-electric car moves into formula medical device and standby power system; Especially its low-cost avirulent characteristics have broken through the technical bottleneck of its commercial applications especially, have expanded the application of lithium ion battery.
4. this lithium ion polymer battery charge and discharge process is safe and reliable, has extended cycle life, and 1C cycle life can reach more than 1000 times.Security performance test index (comprise overcharge, short circuit, acupuncture, extruding, heavy impact, hot case etc.) has reached the requirement of electrokinetic cell fully, and because its good security performance, be particularly suitable for making battery pack work, overcome other batteries and done safety defect when being used in combination.
5. the product chemical property is good, capacity is big, and cost is low.With 18650 batteries is example, its capacity 1000~1200mAh, and the 10C discharge capacity is 85~96% of a 0.5C discharge capacity.
6. the technology of the present invention is suitable for large-scale industrial production, the rate that manufactures a finished product height, and production cost is low.
(4) description of drawings
Fig. 1 is the performance diagram of a kind of polymer lithium ion chargeable battery PLB552242H.
(5) embodiment
Embodiment 1: a kind of lithium ion polymer electrolyte film, it is to be 600 the big monomer of PEO, acrylic acid lithium minor comonomer, azodiisobutyronitrile with the big monomer of PEO by mean molecule quantity: acrylic acid lithium minor comonomer: the mol ratio of azodiisobutyronitrile=1:50:0.05 is carried out the high amorphous phase polymeric matrix that free radicals copolymerization reaction was generated, under the atmosphere of nitrogen again with LiBF 4, Li-β-Al 2O 3After nano powder carries out compound generation lithium ion polymer electrolyte, the dielectric film of making through curtain coating, wherein LiBF 4, Li-β-Al 2O 3The percentage by weight of nano powder in described lithium ion polymer electrolyte is respectively 10%, 20%.
A kind of method step for preparing above-mentioned lithium ion polymer electrolyte film:
(1) the big monomer preparation of polyoxyethylene is with polyethylene glycol (PEG, mean molecule quantity is 600), triethylamine, acryloyl chloride is got ready with the mol ratio of 1:2:3, and get toluene solvant ready with the weight ratio of polyethylene glycol: toluene=1:6, in magnetic agitation, temperature is under 40 ℃ the reaction condition, successively with polyethylene glycol, in the toluene solvant in the triethylamine adding reactor, slowly add acryloyl chloride again, add follow-up continuation of insurance temperature and stirred 6 hours, after finishing, reaction removes by filter the amine salt of generation, evaporated filtrate is removed partial solvent, adding volume then is 8 times ether sedimentation agent of residual filtrate volume, product suction filtration final vacuum drying with being settled out promptly gets the big monomer of the double bond containing polyoxyethylene in two ends.
(2) preparation of high amorphous phase polymeric matrix is with the big monomer of polyoxyethylene: the acrylic acid lithium: azodiisobutyronitrile is dissolved in the methanol solvate in the reactor with the mol ratio of 1:50:0.05, the weight ratio of big monomer of PEO and methanol solvate is 1:13, reaction is 10 hours under the condition of 80 ℃ of temperature, magnetic agitation, nitrogen atmosphere, must contain the methanol solution of copolymerization product;
(3) Li-β-Al 2O 3The nano powder preparation is according to [Li +]/[Al 3+The ratio of]=1:5.0 gets aluminum nitrate and lithium nitrate is mixed with [NO 3 -The solution of]=1mol/L also mixes, under the situation of vigorous stirring, dropwise dripping the 1mol/L ammonium bicarbonate soln, to regulate pH value be 4.15, passed through after the vigorous stirring of 30min still aging 48 hours, dry in 60 ℃ drying box, grind, obtain dry gel powder, its heat treatment under 1000 ℃ temperature, be incubated 2 hours, behind the natural cooling, grind, promptly obtain Li-β-Al 2O 3The fast-ionic conductor nano powder.
(4) compound electrolyte material adds LiBF in the above-mentioned methanol solution that contains copolymerization product 4, Li-β-Al 2O 3Nano powder stirs into uniform slurry, wherein LiBF 4Consumption is the 10wt% of gained lithium ion polymer electrolyte, Li-β-Al 2O 3Nano powder is 20wt%;
(5) after the above-mentioned slurry of casting film leaves standstill the degassing, be to carry out casting film under 50 ℃ the nitrogen atmosphere in temperature, solvent is removed in the volatilization of also being heated of this process, and its curtain coating rotating speed is controlled at 0.40m/min.
The manufacture method of lithium ion polymer battery that contains above-mentioned lithium ion polymer electrolyte film is as follows:
(1) after 1. the positive plate preparation mixes LiFePO4, acetylene black, Kynoar, N-N-2-methyl pyrrolidone with the weight ratio of 100:2:6:115, stirred 2 hours, make its viscosity reach 2000~20000mPa.s; 2. will go up step gained slurry and be coated on equably on the aluminium foil that thickness is 0.02mm, coating density 130g/m 2, at 120 ℃ down after the oven dry, with its roll to bulk density be 2.0g/cm 33. press the size cutting, soldering polar ear, and do insulation and handle.
(2) the negative plate preparation is 1. with graphite: SP (Saturated polyester saturated polyester): the methylcellulose that contracts is received: SBR (Styrene Butadiene styrene-butadiene): after pressing the 100:2:1:4:120 mixing, stirred 2 hours, and made slurry viscosity reach 2000~20000mPa.s; 2. evenly be coated on the Copper Foil coating density 80g/m 2, at 120 ℃ down after the oven dry, with its roll to bulk density be 1.5g/cm 33. press the size cutting, soldering polar ear, and do insulation and handle.
(3) battery assembling
Positive and negative plate is over against lamination, and middle metal-back is put in the compound back of hot pressing with described polymer dielectric film isolation, sealing, and activate.The important technological parameters of this product sees Table 1, and its indicatrix is seen Fig. 1.
Embodiment 2: a kind of lithium ion polymer electrolyte film, it is to be 600 the big monomer of PEO, acrylic acid lithium minor comonomer, azodiisobutyronitrile with the big monomer of PEO by mean molecule quantity: acrylic acid lithium minor comonomer: the mol ratio of azodiisobutyronitrile=1:80:0.08 is carried out the high amorphous phase polymeric matrix that free radicals copolymerization reaction was generated, under the atmosphere of nitrogen again with LiBF 4, Li-β-Al 2O 3After nano powder carries out compound generation lithium ion polymer electrolyte, the dielectric film of making through curtain coating, wherein LiBF 4, Li-β-Al 2O 3The percentage by weight of nano powder in described lithium ion polymer electrolyte is respectively 10%, 15%.
A kind of method step for preparing above-mentioned lithium ion polymer electrolyte film:
(1) the big monomer preparation of polyoxyethylene is with poly glycol monomethyl ether (mPEG, mean molecule quantity is 600), triethylamine, acryloyl chloride (AC) is got ready with the mol ratio of 1:1.5:1.8, and get toluene solvant ready with the weight ratio of poly glycol monomethyl ether: toluene=1:8, in magnetic agitation, temperature is under 45 ℃ the reaction condition, successively with poly glycol monomethyl ether, triethylamine joins in the toluene solvant in the reactor, slowly add acryloyl chloride again, add follow-up continuation of insurance temperature and stirred 5 hours, after finishing, reaction removes by filter the amine salt of generation, evaporated filtrate is removed partial solvent, adding volume then is 8 times ether sedimentation agent of residual filtrate volume, product suction filtration final vacuum drying with being settled out promptly gets the big monomer of the double bond containing polyoxyethylene of an end.
(2) preparation of high amorphous phase polymeric matrix is with the big monomer of PEO: the acrylic acid lithium: after azodiisobutyronitrile is dissolved in the methanol solvate (weight ratio of big monomer of PEO and methanol solvate is 1:14) with the mol ratio of 1:80:0.08, put in the reactor, reaction is 10 hours under the condition of 80 ℃ of temperature, magnetic agitation, nitrogen atmosphere, must contain the methanol solution of copolymerization product;
(3) Li-β-Al 2O 3The nano powder preparation is according to [Li +]/[Al 3+The ratio of]=1:5.0 gets aluminum nitrate and lithium nitrate is mixed with [NO 3 -The solution of]=1mol/L also mixes, under the situation of vigorous stirring, dropwise dripping the 1mol/L ammonium bicarbonate soln, to regulate the pH value be 4.12, through after 0.5 hour the vigorous stirring still aging 40 hours, dry in 50 ℃ drying box, grind, obtain dry gel powder, its heat treatment under 1100 ℃ temperature, be incubated 3 hours, behind the natural cooling, grind, promptly obtain Li-β-Al 2O 3The fast-ionic conductor nano powder.
(4) compound electrolyte material filters the described methanol solution that contains copolymerization product, and purifying gets copolymerization product after the vacuumize, the copolymerization product thermosol behind oxolane, is added LiBF again in this solution 4, Li-β-Al 2O 3Nano powder stirs into uniform slurry, wherein LiBF 4Consumption is the 10wt% of gained lithium ion polymer electrolyte, Li-β-Al 2O 3Nano powder is 15wt%.
(5) after the above-mentioned slurry of casting film leaves standstill the degassing, be to carry out casting film under 50 ℃ the nitrogen atmosphere in temperature, solvent is removed in the volatilization of also being heated of this process, and its curtain coating rotating speed is controlled to be 0.60m/min.
The manufacture method that contains the lithium ion polymer battery of above-mentioned lithium ion polymer electrolyte film:
(1) after 1. the positive plate preparation mixes LiFePO4, acetylene black, Kynoar, N-N-2-methyl pyrrolidone with the weight ratio of 100:5:15:150, stirred 3 hours, make its viscosity reach 2000~20000mPa.s; 2. will go up step gained slurry and be coated on equably on the aluminium foil, coating density 50g/m 2, at 150 ℃ down after the oven dry, with its roll to bulk density be 3.0g/cm 33. press the size cutting, soldering polar ear, and do insulation and handle.
(2) negative plate preparation 1. graphite, SP (Saturated polyester saturated polyester), the methylcellulose that contracts are received, SBR (Styrene Butadiene styrene-butadiene): after press the 100:3:2:6:150 mixing, stirred 4 hours, and made slurry viscosity at 2000~20000mPa.s; 2. above-mentioned slurry evenly is coated on the Copper Foil coating density 25g/m 2, 150 ℃ down after the oven dry, with its roll to bulk density be 1.8g/cm 33. press the size cutting, soldering polar ear, and do insulation and handle.
(3) the pole piece positive/negative plate after the battery assembling will be dried is over against lamination, and the centre isolates with polymer dielectric film, is wound into electric core after the hot pressing, in the battery case of packing into, and sealing, and activate.The important technological parameters of this product sees Table 2.
Embodiment 3: a kind of lithium ion polymer electrolyte film, it is to be initator with the azodiisobutyronitrile, carry out big monomer of PEO and acrylic acid lithium monomer free-radical polymerized, the big monomer of PEO wherein: acrylic acid lithium monomer: the mol ratio of azodiisobutyronitrile is 1:100:0.11, adds Li-β-Al of 30wt% again in the gained copolymer 2O 3After nano powder is combined into lithium ion polymer electrolyte, casting film under the nitrogen atmosphere.
A kind of method step for preparing above-mentioned lithium ion polymer electrolyte film:
(1) the big monomer preparation of polyoxyethylene is with polyethylene glycol (PEG, mean molecule quantity is 400), triethylamine, acryloyl chloride (AC) is got ready with the mol ratio of 1:1.8:2.8, in magnetic agitation, water bath heating temperature is under 35 ℃ the reaction condition, successively with polyethylene glycol, in the toluene solvant (weight ratio of polyethylene glycol and toluene solvant is 1:3) in the triethylamine adding reactor, slowly add acryloyl chloride again, add follow-up continuation of insurance temperature and stirred 4 hours, after finishing, reaction removes by filter the amine salt of generation, evaporated filtrate is removed partial solvent, add ether sedimentation agent (for 4 times of filtrate volume) then, be settled out product, with its suction filtration final vacuum drying, promptly get the big monomer of the double bond containing polyoxyethylene in two ends.
(2) preparation of high amorphous phase polymeric matrix is with the big monomer of polyoxyethylene: the acrylic acid lithium: after azodiisobutyronitrile is dissolved in the methanol solvate (weight ratio of big monomer of PEO and methanol solvate is 1:11) with the mol ratio of 1:100:0.11, put in the reactor, reaction is 8 hours under the condition of 70 ℃ of temperature, magnetic agitation, nitrogen atmosphere, must contain the methanol solution of copolymerization product;
(3) Li-β-Al 2O 3The nano powder preparation is according to [Li +]/[Al 3+The ratio of]=1:5.0 gets aluminum nitrate and lithium nitrate is mixed with [NO 3 -The solution of]=1mol/L also mixes, under the situation of vigorous stirring, dropwise dripping the 1mol/L ammonium bicarbonate soln, to regulate the pH value be 4.17, through after 2 hours the vigorous stirring still aging 50 hours, dry in 70 ℃ drying box, grind, obtain dry gel powder, its heat treatment under 1100 ℃ temperature, be incubated 3 hours, behind the natural cooling, grind, promptly obtain Li-β-Al 2O 3The fast-ionic conductor nano powder.
(4) compound electrolyte material is with Li-β-Al 2O 3Nano powder joins in the methanol solution that contains copolymerization product with the proportioning of 5wt%, stirs into uniform slurry; In above-mentioned solution, add Li-β-Al again 2O 3Nano powder stirs into uniform slurry, wherein Li-β-Al 2O 3The nano powder consumption is the 30wt% of gained lithium ion polymer electrolyte.
(5) after the above-mentioned slurry of casting film leaves standstill the degassing, be to carry out casting film under 40 ℃ the nitrogen atmosphere in temperature, its curtain coating rotating speed is controlled at 0.18m/min.
The manufacture method of lithium ion polymer battery that contains above-mentioned lithium ion polymer electrolyte film is as follows:
(1) after 1. the positive plate preparation mixes LiFePO4, acetylene black, Kynoar, N-N-2-methyl pyrrolidone with the weight ratio of 100:1:2.8:80, stirred 1 hour, make its viscosity reach 2000~20000mPa.s; 2. will go up step gained slurry and be coated on equably on the thick aluminium foil of 0.025mm, coating density 200g/m 2, adopt a large amount of hot air circulation of 80 ℃, after the pole piece oven dry, it is 1.5g/cm that the pole piece after the coating is rolled into bulk density 33. press the size cutting, soldering polar ear, and do insulation and handle.
(2) the negative plate preparation is 1. with graphite: SP (Saturated polyester saturated polyester): the methylcellulose that contracts is received: SBR (Styrene Butadiene styrene-butadiene): after pressing the 100:0.5:0.5:2:100 mixing, stirred 1 hour, and made slurry viscosity reach 2000~20000mPa.s; 2. evenly be coated on the Copper Foil coating density 150g/m 2, at 80 ℃ down after the oven dry, with its roll to bulk density be 1.0g/cm 33. press the size cutting, soldering polar ear, and do insulation and handle.
(3) the battery assembling is with embodiment 1.
Embodiment 4: substantially the same manner as Example 1, difference is: 1. in the big monomer preparation of polyoxyethylene, polyethylene glycol (PEG, mean molecule quantity is 800): triethylamine: the mol ratio=1:3:4 of acryloyl chloride (AC), the weight ratio of polyethylene glycol and toluene solvant is 1:12, and the volume that adds the ether sedimentation agent is 12 times of filtrate volume; 2. in high amorphous phase polymeric matrix preparation, used alkene class minor comonomer is an acrylonitrile, the big monomer of polyoxyethylene: acrylonitrile: azodiisobutyronitrile reaction mol ratio is 1:1:0.01, and the weight ratio of big monomer of PEO and methanol solvate is 1:15; 3. prepared compound electrolyte material contains 15wt%LiBF 4, 20wt%Li-β-Al 2O 3Nano powder; 4. in the preparation process of positive plate, LiFePO4, acetylene black, Kynoar, N-N-2-methyl pyrrolidone mix with the weight ratio of 100:2:4:90; 5. in the preparation process of negative plate, graphite: SP: the methylcellulose that contracts is received: SBR: weight ratio be 100:0.4:1.5:5:110.
Embodiment 5: substantially the same manner as Example 2, difference is: 1. in the big monomer preparation of polyoxyethylene, with molar ratio computing, poly glycol monomethyl ether (mPEG, mean molecule quantity is 500): triethylamine: acryloyl chloride (AC)=1:1:1.6, by weight, poly glycol monomethyl ether: toluene solvant=1:3, the volume that adds the ether sedimentation agent is 5 times of filtrate volume; 2. in high amorphous phase polymeric matrix preparation, used alkene class minor comonomer is a butyl acrylate, the big monomer of polyoxyethylene: butyl acrylate: azodiisobutyronitrile reaction mol ratio is 1:20:0.10, and the weight ratio of big monomer of PEO and methanol solvate is 1:14; 3. prepared compound electrolyte material contains 5wt%LiBF 4, 10wt%Li-β-Al 2O 3Nano powder; 4. in the preparation process of positive plate, LiFePO4, acetylene black, Kynoar, N-N-2-methyl pyrrolidone mix with the weight ratio of 100:4:14:100; 5. in the preparation process of negative plate, graphite: SP: the methylcellulose that contracts is received: SBR: weight ratio be 100:2.5:1:3:140.
Embodiment 6: substantially the same manner as Example 2, difference is: 1. in the big monomer preparation of polyoxyethylene, with molar ratio computing, poly glycol monomethyl ether (mPEG, mean molecule quantity is 400): triethylamine: acryloyl chloride (AC)=1:1.8:2.2, by weight, poly glycol monomethyl ether: toluene solvant=1:12, the volume that adds the ether sedimentation agent is 10 times of filtrate volume; 2. in high amorphous phase polymeric matrix preparation, used alkene class minor comonomer is a butyl acrylate, the big monomer of polyoxyethylene: butyl acrylate: azodiisobutyronitrile reaction mol ratio is 1:30:0.02, and the weight ratio of big monomer of PEO and methanol solvate is 1:12; 3. prepared compound electrolyte material contains 15wt%LiBF 4, 25wt%Li-β-Al 2O 3Nano powder; 4. in the preparation process of positive plate, LiFePO4, acetylene black, Kynoar, N-N-2-methyl pyrrolidone mix with the weight ratio of 100:3:5:140; 5. in the preparation process of negative plate, graphite: SP: the methylcellulose that contracts is received: SBR: weight ratio be 100:1:0.8:4:120.
Embodiment 7: substantially the same manner as Example 1, difference is: 1. in the big monomer preparation of polyoxyethylene, with molar ratio computing, polyethylene glycol (PEG, mean molecule quantity is 1000): triethylamine: acryloyl chloride (AC)=1:2.5:3.5, the weight ratio of polyethylene glycol and toluene solvant is 1:8, and the volume that adds the ether sedimentation agent is 11 times of filtrate volume; 2. in high amorphous phase polymeric matrix preparation, used alkene class minor comonomer is acrylonitrile and acrylic acid lithium, the big monomer of polyoxyethylene: acrylonitrile: acrylic acid lithium: azodiisobutyronitrile reaction mol ratio is 1:20:50:0.07, and the weight ratio of big monomer of PEO and methanol solvate is 1:13; 3. prepared compound electrolyte material contains 5wt%LiBF 4, 28wt%Li-β-Al 2O 3Nano powder; 4. in the preparation process of positive plate, LiFePO4, acetylene black, Kynoar, N-N-2-methyl pyrrolidone mix with the weight ratio of 100:4.5:10:130; 5. in the preparation process of negative plate, graphite: SP: the methylcellulose that contracts is received: SBR: weight ratio be 100:1.5:1.8:3:130.
Embodiment 8: substantially the same manner as Example 3, difference is: difference is: 1. in the big monomer preparation of polyoxyethylene, in, polyethylene glycol (PEG, mean molecule quantity is 900): triethylamine: the mol ratio of acryloyl chloride (AC) is 1:1.9:3.5, and the weight ratio of polyethylene glycol and toluene solvant is 1:5; 2. in high amorphous phase polymeric matrix preparation, used alkene class minor comonomer is acrylamide and acrylic acid lithium, the big monomer of polyoxyethylene: acrylamide: acrylic acid lithium: azodiisobutyronitrile reaction mol ratio is 1:40:35:0.06, and the weight ratio of big monomer of PEO and methanol solvate is 1:11; 3. prepared compound electrolyte material contains 18wt%LiBF 4, 8wt%Li-β-Al 2O 3Nano powder.
Embodiment 9: substantially the same manner as Example 2, difference is: 1. in the big monomer preparation of polyoxyethylene, with molar ratio computing, poly glycol monomethyl ether (mPEG, mean molecule quantity is 950): triethylamine: acryloyl chloride (AC)=1:1.1:2.1, by weight, poly glycol monomethyl ether: toluene solvant=1:4, the volume that adds the ether sedimentation agent is 7 times of filtrate volume; 2. in high amorphous phase polymeric matrix preparation, used alkene class minor comonomer is methyl methacrylate and acrylic acid lithium, the big monomer of polyoxyethylene: methyl methacrylate: acrylic acid lithium: azodiisobutyronitrile reaction mol ratio is 1:15:10:0.02, and the weight ratio of big monomer of PEO and methanol solvate is 1:13; 3. prepared compound electrolyte material contains 2wt%LiBF 4, 6wt%Li-β-Al 2O 3Nano powder.
Embodiment 10: substantially the same manner as Example 1, difference is: 1. in the big monomer preparation of polyoxyethylene, with molar ratio computing, polyethylene glycol (PEG, mean molecule quantity is 600): triethylamine: AC=1:2.8:2.9, the weight ratio of polyethylene glycol and toluene solvant is 1:7, and the volume that adds the ether sedimentation agent is 9 times of filtrate volume; 2. in high amorphous phase polymeric matrix preparation, used alkene class minor comonomer is acrylamide and acrylic acid lithium, the big monomer of polyoxyethylene: acrylamide: acrylic acid lithium: azodiisobutyronitrile reaction mol ratio is 1:60:25:0.08; 3. prepared compound electrolyte material contains 17wt%LiBF 4, 24wt%Li-β-Al 2O 3Nano powder.
Embodiment 11: substantially the same manner as Example 2, difference is: 1. in the big monomer preparation of polyoxyethylene, with molar ratio computing, poly glycol monomethyl ether (mPEG, mean molecule quantity is 800): triethylamine: acryloyl chloride (AC)=1:1.6:1.8, by weight, poly glycol monomethyl ether: toluene solvant=1:9, the volume that adds the ether sedimentation agent is 6 times of filtrate volume; 2. in high amorphous phase polymeric matrix preparation, used alkene class minor comonomer is butyl acrylate and acrylic acid lithium, the big monomer of polyoxyethylene: butyl acrylate: acrylic acid lithium: azodiisobutyronitrile reaction mol ratio is 1:28:48:0.05; 3. prepared compound electrolyte material contains 13wt%LiBF 4, 19wt%Li-β-Al 2O 3Nano powder.
Embodiment 12: substantially the same manner as Example 2, difference is: 1. in the big monomer preparation of polyoxyethylene, with molar ratio computing, poly glycol monomethyl ether (mPEG, mean molecule quantity is 450): triethylamine: acryloyl chloride (AC)=1:1.7:1.7, by weight, poly glycol monomethyl ether: toluene solvant=1:4, the volume that adds the ether sedimentation agent is 10 times of filtrate volume; 2. in high amorphous phase polymeric matrix preparation, used alkene class minor comonomer is butyl acrylate and acrylonitrile, the big monomer of polyoxyethylene: butyl acrylate: acrylonitrile: azodiisobutyronitrile reaction mol ratio is 1:40:58:0.15; 3. prepared compound electrolyte material contains 29wt%Li-β-Al 2O 3Nano powder.
Embodiment 13: substantially the same manner as Example 1, difference is: 1. in the big monomer preparation of polyoxyethylene, with molar ratio computing, polyethylene glycol (PEG, mean molecule quantity is 200): triethylamine: AC=1:1.9:3.5, the weight ratio of polyethylene glycol and toluene solvant is 1:4, and the volume that adds the ether sedimentation agent is 11 times of filtrate volume; 2. in high amorphous phase polymeric matrix preparation, used alkene class minor comonomer is the acrylic acid lithium, the big monomer of polyoxyethylene: acrylic acid lithium: azodiisobutyronitrile reaction mol ratio is 1:15:0.08; 3. prepared compound electrolyte material contains 20wt%LiBF 4, 28wt%Li-β-Al 2O 3Nano powder.
Embodiment 14: substantially the same manner as Example 2, difference is: 1. in the big monomer preparation of polyoxyethylene, with molar ratio computing, poly glycol monomethyl ether (mPEG, mean molecule quantity is 200): triethylamine: acryloyl chloride (AC)=1:1.7:2.1, by weight, poly glycol monomethyl ether: toluene solvant=1:5, the volume that adds the ether sedimentation agent is 6 times of filtrate volume; 2. in high amorphous phase polymeric matrix preparation, used alkene class minor comonomer is the acrylic acid lithium, the big monomer of polyoxyethylene: acrylic acid lithium: azodiisobutyronitrile reaction mol ratio is 1:95:0.10, and the weight ratio of big monomer of PEO and methanol solvate is 1:12; 3. prepared compound electrolyte material contains 2wt%LiBF 4, 5wt%Li-β-Al 2O 3Nano powder; 4. in the preparation process of positive plate, LiFePO4, acetylene black, Kynoar, N-N-2-methyl pyrrolidone mix with the weight ratio of 100:1.1:3.0:85; 5. in the preparation process of negative plate, graphite: SP: the methylcellulose that contracts is received: SBR: weight ratio be 100:0.6:0.7:2.5:105.
Embodiment 15: substantially the same manner as Example 2, difference is: 1. in the big monomer preparation of polyoxyethylene, with molar ratio computing, poly glycol monomethyl ether (mPEG, mean molecule quantity is 250): triethylamine: acryloyl chloride (AC)=1:1.2:1.7, by weight, poly glycol monomethyl ether: toluene solvant=1:11, the volume that adds the ether sedimentation agent is 5 times of filtrate volume; 2. in high amorphous phase polymeric matrix preparation, used alkene class minor comonomer is the acrylic acid lithium, the big monomer of polyoxyethylene: acrylic acid lithium: butyl acrylate: azodiisobutyronitrile reaction mol ratio is 1:10:65:0.04, and the weight ratio of big monomer of PEO and methanol solvate is 1:14; 3. prepared compound electrolyte material contains 20wt%LiBF 4, 29wt%Li-β-Al 2O 3Nano powder; 4. in the preparation process of positive plate, LiFePO4, acetylene black, Kynoar, N-N-2-methyl pyrrolidone mix with the weight ratio of 100:4.5:14.5:140; 5. in the preparation process of negative plate, graphite: SP: the methylcellulose that contracts is received: SBR: weight ratio be 100:2.5:1.5:5:145.
Embodiment 16: substantially the same manner as Example 1, difference is: 1. in the big monomer preparation of polyoxyethylene, with molar ratio computing, polyethylene glycol (PEG, mean molecule quantity is 250): triethylamine: AC=1:2.8:2.9, the weight ratio of polyethylene glycol and toluene solvant is 1:12, and the volume that adds the ether sedimentation agent is 4 times of filtrate volume; 2. in high amorphous phase polymeric matrix preparation, used alkene class minor comonomer is the acrylic acid lithium, the big monomer of polyoxyethylene: acrylic acid lithium: azodiisobutyronitrile reaction mol ratio is 1:50:0.10; 3. prepared compound electrolyte material contains 15wt%LiBF 4, 15wt%Li-β-Al 2O 3Nano powder.4. in the preparation process of positive plate, LiFePO4, acetylene black, Kynoar, N-N-2-methyl pyrrolidone mix with the weight ratio of 100:1.5:3:100; 5. in the preparation process of negative plate, graphite: SP: the methylcellulose that contracts is received: SBR: weight ratio be 100:0.6:1.0:3:100.
The important technological parameters one of table 1 polymer lithium ion chargeable battery
Figure C200710054671D00221
The important technological parameters two of table 2 polymer lithium ion chargeable battery

Claims (8)

1. lithium ion polymer electrolyte film, it is characterized in that: it is to be that 200~1000 the big monomer of PEO, alkene class minor comonomer, azodiisobutyronitrile carry out the high amorphous phase polymeric matrix that free radicals copolymerization reaction was generated with the mol ratio of 1:1~100:0.01~0.11 under 70~90 ℃ by mean molecule quantity, under the atmosphere of inert gas with LiBF 4, Li-β-Al 2O 3Behind the compound generation lithium ion polymer electrolyte of nano powder, again under the atmosphere of 40~60 ℃ inert gas after solvent is removed in the curtain coating volatilization made dielectric film, it contains LiBF 4O~20wt%, Li-β-Al 2O 3Nano powder 5~30wt%, conductivity is 3.5~6.2 * 10 under this dielectric film room temperature -3S/cm, described alkene class minor comonomer is at least a in acrylonitrile, acrylic acid lithium, butyl acrylate, methyl methacrylate and the acrylamide.。
2. method for preparing the described lithium ion polymer electrolyte film of claim 1 is characterized in that it may further comprise the steps:
(1) high amorphous phase polymeric matrix preparation
Be 200~1000 the big monomer of PEO with mean molecule quantity: alkene class minor comonomer: azodiisobutyronitrile is dissolved in the methanol solvate in the reactor with the mol ratio of 1:1~100:0.01~0.11, the weight ratio of big monomer of PEO and methanol solvate is 1:11~15, above-mentioned reactant reacted 8~12 hours under the condition of 70~90 ℃ of temperature, magnetic agitation, nitrogen atmosphere, the methanol solution that must contain copolymerization product, described alkene class minor comonomer is at least a in acrylonitrile, acrylic acid lithium, butyl acrylate, methyl methacrylate and the acrylamide;
(2) compound electrolyte material
In the above-mentioned methanol solution that contains copolymerization product, add LiBF 4, Li-β-Al 2O 3Nano powder stirs into uniform slurry, wherein LiBF 4Consumption is 0~20wt% of gained lithium ion polymer electrolyte film, Li-β-Al 2O 3Nano powder is 5~30wt%;
(3) casting film
After above-mentioned slurry leaves standstill the degassing, being to carry out curtain coating under 40~60 ℃ the nitrogen atmosphere in temperature, is film forming after the solvent evaporates, and its curtain coating rotating speed is controlled at 0.18~0.60m/min.
3. the preparation method of lithium ion polymer electrolyte film according to claim 2, it is characterized in that, replace described step (2) with following step: the described methanol solution that contains copolymerization product is filtered, purifying, get copolymerization product after the vacuumize, the copolymerization product thermosol behind oxolane, is added LiBF again in this solution 4, Li-β-Al 2O 3Nano powder stirs into uniform slurry, wherein LiBF 4Consumption is 0~20wt% of gained lithium ion polymer electrolyte film, Li-β-Al 2O 3Nano powder is 5~30wt%.
4. the preparation method of lithium ion polymer electrolyte film according to claim 2 is characterized in that, described Li-β-Al 2O 3Nano powder prepares with sol-gel process, and concrete steps are as follows:
With [Li +]/[Al 3+The ratio of]=1:5.0 is got aluminum nitrate and lithium nitrate and is mixed with the solution of 1mol/L and mixes, under the situation of vigorous stirring, dropwise drip the 1mol/L ammonium bicarbonate soln, regulate pH value to 4.10~4.20 of mixed solution, again through after 0.5~2 hour the vigorous stirring still aging 40~50 hours, grind dry back in 40~70 ℃ drying box, obtain dry gel powder, it is heat-treated under 800~1100 ℃ temperature, and be incubated 2~3 hours, after the cooling, grind, be Li-β-Al 2O 3The fast-ionic conductor nano powder.
5. according to the preparation method of any described lithium ion polymer electrolyte film of claim 2 to 4, it is characterized in that the preparation of the big monomer of described PEO may further comprise the steps:
It with mean molecule quantity 200~1000 polyethylene glycol, triethylamine, acryloyl chloride is got ready with the mol ratio of 1:1.8~3.0:2.8~4.0, and get toluene solvant ready with the weight ratio of polyethylene glycol: toluene=1:3~12, in magnetic agitation, temperature is under 35~45 ℃ the reaction condition, successively with polyethylene glycol, triethylamine joins in the toluene solvant in the reactor, slowly add acryloyl chloride again, add follow-up continuation of insurance temperature and stirred 4~8 hours, after finishing, reaction removes by filter the amine salt of generation, evaporated filtrate is removed partial solvent, adding volume then is 4~12 times ether sedimentation agent of residual filtrate volume, product suction filtration final vacuum drying with being settled out promptly gets the big monomer of the double bond containing polyoxyethylene in two ends.
6. according to the preparation method of any described lithium ion polymer electrolyte film of claim 2 to 4, it is characterized in that the preparation of the big monomer of described PEO may further comprise the steps:
It with mean molecule quantity 200~1000 poly glycol monomethyl ether, triethylamine, acryloyl chloride is got ready with the mol ratio of 1:1.0~1.8:1.6~2.2, and get toluene solvant ready with the weight ratio of poly glycol monomethyl ether: toluene=1:3~12, in magnetic agitation, temperature is under 35~45 ℃ the reaction condition, successively with poly glycol monomethyl ether, triethylamine joins in the toluene solvant in the reactor, slowly add acryloyl chloride again, add follow-up continuation of insurance temperature and stirred 4~6 hours, after finishing, reaction removes by filter the amine salt of generation, evaporated filtrate is removed partial solvent, adding volume then is 4~12 times ether sedimentation agent of residual filtrate volume, product suction filtration final vacuum drying with being settled out promptly gets the big monomer of the double bond containing polyoxyethylene of an end.
7. manufacture method that contains the lithium ion polymer battery of the described lithium ion polymer electrolyte film of claim 1, it may further comprise the steps:
(1) positive plate preparation
A stirred 1 hour after LiFePO4, acetylene black, Kynoar, N-N-2-methyl pyrrolidone are mixed with the weight ratio of 100:1.0~5.0:2.8~15.0:80~150 at least, made its viscosity reach 2000~20000mPa.s;
B will go up step gained slurry and be coated on equably on the aluminium foil, coating density 50~200g/m 2, at 80~150 ℃ down after the oven dry, with its roll to bulk density be 1.5~3.0g/cm 3
C presses the size cutting, soldering polar ear, and do insulation and handle;
(2) negative plate preparation
A with graphite, saturated polyester, the methylcellulose that contracts receive, styrene-butadiene: after mixing with the weight ratio of 100:0.5~3:0.5~2:2~6:100~150, stirred at least 1 hour, make its viscosity reach 2000~20000mPa.s;
B evenly is coated on the Copper Foil, coating density 25~150g/m 2, at 80~150 ℃ down after the oven dry, with its roll to bulk density be 1.0~1.8g/cm 3
C presses the size cutting, soldering polar ear, and do insulation and handle;
(3) battery assembling
Positive and negative plate is over against lamination, and middle metal-back or aluminum-plastic composite membrane are put in the compound back of hot pressing with described polymer dielectric film isolation, sealing, and activate.
8. the manufacture method of lithium ion polymer battery according to claim 7, it is characterized in that: lithium ion polymer battery is made square or is reeled and make column type.
CNB2007100546716A 2007-06-27 2007-06-27 Lithium-ion polymer electrolyte membrane and method for manufacturing lithium-ion battery containing the membrane Expired - Fee Related CN100544110C (en)

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