CN106602140B - A kind of electrolyte improving polymer lithium ion secondary battery high-temperature behavior - Google Patents

Abstract

The present invention provides a kind of electrolyte for improving polymer lithium ion secondary battery high-temperature behavior, containing non-aqueous organic solvent, cathode film formation additive, lithium salts electrolyte, the electrolyte also contains the functional form additive of 0.5%-10% for accounting for the electrolyte gross mass indicated selected from structural formula I a kind of；Wherein R1 indicates the halogenated alkyl of optional carbon atom number 1-10；R2 and R3 be halogen atom ,-H ,-CN or be carbon atom number 1-10 alkyl (R1 and R2 may identical may also be different).The functional form additive can form stable Low ESR dielectric film in anode, the reactivity of anode be effectively reduced, to further suppress the decomposition of electrolyte.Electrolyte of the invention overcomes the shortcomings that serious polymer lithium ion secondary battery inflatable in high temperature storage and capacitance loss, the electrolyte system and lithium ion secondary battery positive and negative anodes have preferably compatibility, better high-temperature electrochemistry characteristic, high-temperature storage and multiplying power discharging property simultaneously.

Description

A kind of electrolyte improving polymer lithium ion secondary battery high-temperature behavior

Technical field

The present invention relates to high-energy battery technical fields, more particularly to a kind of improvement polymer lithium ion secondary battery high temperature The electrolyte of performance.

Background technique

Lithium ion polymer battery is state-of-the-art secondary cell in the world now, has gradually replaced ni-Cd, plumbic acid electricity Pond is applied in the digital products such as mobile phone, laptop, MP3, PDA, DV, and being increasingly becoming can not in people's Working Life Or scarce essential product.The safety of battery is to influence the main factor of battery applications, and the ballooning of lithium battery is to influence The principal element of battery security causes the performance of battery to decline.Lithium ion polymer battery using clad aluminum plastic film due to being made For housing material, biggish internal gas pressure cannot be born, therefore ballooning has increasingly constituted necessary solution factor. With the extension in lithium ion battery applications field, to chemical property after the high-temperature storage and storage of polymer Li-ion battery More stringent requirements are proposed.

Chinese patent 201110055393.2 proposes a kind of lithium ion polymer electrolyte comprising lithium salts, nonaqueous solvents And the polymer of dispersion.The program can reduce the thickness swelling of battery under the high temperature conditions by adding polymer, significantly change The high-temperature storage performance of kind battery.But the program improves the viscosity of electrolyte, electrolyte conductance using the copolymer of polymer Rate decline is more, and high rate performance is deteriorated.

Summary of the invention

The object of the present invention is to provide a kind of electrolyte, are effectively improved polymer lithium ion secondary battery high-temperature behavior, And the multiplying power discharging property of battery is not influenced, the present invention provides a kind of improvement polymer lithium ion secondary battery high-temperature behaviors Electrolyte improves the electrolyte of polymer lithium ion secondary battery high-temperature behavior, adds containing non-aqueous organic solvent, cathode film formation Agent, lithium salts electrolyte, the electrolyte also contain a kind of 0.5%- for accounting for the electrolyte gross mass indicated selected from structural formula I 10% functional form additive；

Its structural formula I is

Wherein R1 indicates the halogenated alkyl of optional carbon atom number 1-10；R2 and R3 is halogen atom ,-H ,-CN or is carbon original The alkyl of subnumber 1-10.

The non-aqueous organic solvent includes carbonate solvent, and the carbonate solvent is ethylene carbonate (EC), carbonic acid Acrylic ester (PC), dimethyl carbonate (DMC), methyl ethyl carbonate (EMC), diethyl carbonate (DEC), in methyl propyl carbonate (MPC) At least one；Further include non-carbonate solvent, the non-carbonate solvent be gamma-butyrolacton (GBL), methyl acetate (MA), Ethyl acetate (EA), propyl acetate (PA), methyl propionate (MP), ethyl propionate (EP), methyl butyrate (MB), ethyl butyrate (EB) At least one of.

Carbonate solvent in the non-aqueous organic solvent accounts for the 10%~50% of electrolyte gross mass, and non-carbonic ester is molten Agent accounts for the 10%~50% of electrolyte gross mass.

The cathode film formation additive includes fluorinated ethylene carbonate (FEC), propane sultone (PS), vinylene carbonate (VC), trifluoromethyl ethylene carbonate (TFPC), sulfuric acid vinyl ester (DTD), ethylene sulfite (ES), vinyl ethylene carbonate At least one of ester (VEC), propene sultone (RPS).

The 0.5%~30% of the total electrolyte gross mass of cathode film formation additive Zhan.

The lithium salts electrolyte includes lithium hexafluoro phosphate (LiPF6), bis- (fluorine sulphonyl) imine lithium LiFSI, bis- (fluoroforms Base sulphonyl) imine lithium (LiTFSI), di-oxalate lithium borate (LiBOB), difluorine oxalic acid boracic acid lithium (LiODFB), LiBF4 (LiBF4), one of lithium carbonate Li2CO3, lithium perchlorate LiClO4 or several.

The percentage that the lithium salts electrolyte accounts for the total weight of electrolyte is 5%~30%.

The invention has the benefit that electrolyte of the invention overcomes polymer lithium ion secondary battery in high temperature storage When the shortcomings that inflatable is serious and capacitance loss, while the electrolyte system and lithium ion secondary battery positive and negative anodes have it is better simultaneous Capacitive, better high-temperature electrochemistry characteristic, high-temperature storage and multiplying power discharging property.The present invention by being added in the electrolytic solution The functional form additive in structural formula I is stated, which can form stable Low ESR dielectric film in anode, effectively Reduce anode reactivity, to further suppress the decomposition of electrolyte, and the additive does not influence the multiplying power of battery Discharge performance.Because the electrolyte of the invention overcomes, polymer lithium ion secondary battery inflatable in high temperature storage is serious and capacity The shortcomings that loss, while the electrolyte system and lithium ion secondary battery positive and negative anodes have preferably compatibility, better high temperature Electrochemical properties.

The present invention solves polymer lithium ion secondary battery, and full 85 DEG C of electricity state store 48 hours, integral battery thickness swelling Less than 5%, battery remaining power restores capacity greater than 98%, 10C multiplying power discharging capacity and is greater than 95% 95% or more, high temperature 45 DEG C of circulations, 800 weeks capacity are greater than 80%.

Specific embodiment

Below with reference to embodiment, comparative example, the present invention is described in detail.The present invention is not limited to implementation forms.

The present invention provides a kind of electrolyte for improving polymer lithium ion secondary battery high-temperature behavior to improve polymer lithium The electrolyte of ion secondary battery high-temperature behavior, it is described containing non-aqueous organic solvent, cathode film formation additive, lithium salts electrolyte Electrolyte also contains the functional form addition of 0.5%-10% for accounting for the electrolyte gross mass indicated selected from structural formula I a kind of Agent；

Structural formula I

Wherein R1 indicates the halogenated alkyl of optional carbon atom number 1-10；R2 and R3 is halogen atom ,-H ,-CN or is carbon original The alkyl of subnumber 1-10.

Functional form additive chooses typical structure formula (1)~(3) (as shown below), and naming structural formula (1) respectively is to add Add agent A, structural formula (2) is additive B, and structural formula (3) is addition of C.

Non-aqueous organic solvent is uniformly mixed by required quality proportioning, it is molten to mixing after -20 DEG C of low temperature freezings after 1 hour Electrolyte lithium salt is added in agent, is slowly added to for average mark 3 times, sufficiently shakes after addition to being completely dissolved, then adds cathode Film for additive shakes up, and is eventually adding functional form additive and is uniformly mixed.Entire process for preparation is in glove box or dry ring Border carries out under (dew-point temperature is lower than -60 DEG C, 20 DEG C of temperature or so), and electrolyte moisture controls within 5ppm, and electrolyte is infused Enter and is tested for the property into polymer battery.

Comparative example 1:EC/DMC=1/1 (mass ratio) LiPF6 mass fraction 10%, cathode film formation additive VC, additive amount 0.5%.

Comparative example 2:EC/EMC=1/2 (mass ratio) LiPF6 mass fraction is 10%, and cathode film formation additive VC, FEC add Dosage is respectively 0.5% and 1%.

Comparative example 3:EC/EMC/DEC=1/1/1 (mass ratio) LiPF6 mass fraction is 12%, cathode film formation additive PS, FEC additive amount are respectively 1% and 2%.

Comparative example 4:EC/EMC/DEC=1/1/1 (mass ratio) LiFSi mass fraction is 12%, cathode film formation additive PS, FEC additive amount are respectively 1% and 2%.

Comparative example 5:EC/MPC=1/2 (mass ratio) LiPF6 mass fraction is the addition of 10%, LiBOB, 2% cathode film formation Agent DTD additive amount is 1%.

Comparative example 6:EC/PC/EMC=1/1/3 (mass ratio) LiPF6 mass fraction be 10%, LiODFB5%, cathode at Film additive DTD additive amount is 1%.

Comparative example 7:EC/GBL/EP=1/1/8 (mass ratio) LiPF6 mass fraction is 10%, Li2CO30.5%, cathode Film for additive RPS additive amount is respectively 2%.

Comparative example 8:EC/DMC/DEC=2/1/7 (mass ratio) LiPF6 mass fraction is 15%, cathode film formation additive VEC and FEC additive amount is respectively 1% and 5%.

Comparative example 9:EC/EA/PC=1/2/7 (mass ratio) LiPF6 mass fraction is 12%, LiTFSi mass fraction 2%, Cathode film formation additive VC, PS, FEC additive amount is 1%, 2% and 5%.

Embodiment 1

The functional form additive A for accounting for electrolyte total mass ratio 0.5% is added on the basis of comparative example 1, is modulated into electrolysis Liquid.

Embodiment 2

The functional form additive A for accounting for electrolyte total mass ratio 1.0% is added on the basis of comparative example 2, is modulated into electrolysis Liquid.

Embodiment 3

The functional form additive B for accounting for electrolyte total mass ratio 0.5% is added on the basis of comparative example 3, is modulated into electrolysis Liquid.

Embodiment 4

The function of the functional form additive B and 3% that account for electrolyte total mass ratio 2.0% is added on the basis of comparative example 4 Type addition of C, is modulated into electrolyte.

Embodiment 5

The functional form addition of C for accounting for electrolyte total mass ratio 5.0% is added on the basis of comparative example 5, is modulated into electrolysis Liquid.

Embodiment 6

The functional form addition of C for accounting for electrolyte total mass ratio 10.0% is added on the basis of comparative example 6, is modulated into electrolysis Liquid.

Embodiment 7

It is added on the basis of comparative example 7 and accounts for the functional form additive A of electrolyte total mass ratio 2.0% and 3% function Type additive B, is modulated into electrolyte.

Embodiment 8

It is added on the basis of comparative example 8 and accounts for the functional form additive A of electrolyte total mass ratio 1.0% and 3% function Type addition of C, is modulated into electrolyte.

Embodiment 9

The function of the functional form additive B and 5% that account for electrolyte total mass ratio 0.5% is added on the basis of comparative example 9 Type addition of C, is modulated into electrolyte.

The performance test and explanation of comparative example and embodiment

Electrolyte is prepared using the method for above-mentioned comparative example and embodiment, and carries out electrolyte moisture, acidity, coloration, close Electrolyte is injected into polymer Li-ion battery according to cell making process after detection is qualified, passes through by the basic tests such as degree After aging, chemical conversion, partial volume, following project testing is carried out to battery:

The polymer Li-ion battery of experimental cell model 054595, battery core are a length of 95 millimeters, wide with a thickness of 5 millimeters It is 45 millimeters；Integral battery nominal capacity 2.5Ah.

(1) high temperature storage is tested

It is placed in 85 degree of baking oven after will be filled with the polymer battery vernier caliper measurement thickness (being recorded as A) of electricity, Thickness test was as a child quickly carried out by 48 and is made a record and (is recorded as B).

Expansion rate=(B-A)/A*100%

(2) high temperature volume test

Battery is placed in insulating box, after 85 DEG C save 48 hours, 0.2C multiplying power carries out being discharged to 2.75 volts, discharge capacity The as residual capacity of battery；After 0.2C rate charge-discharge recycles 3 weeks, the discharge capacity of integral battery 0.2C multiplying power is to restore Capacity.

(3) high rate performance is tested

After battery partial volume, battery is carried out to be discharged to 2.75V with 10C electric current, discharge capacity is multiplying power than partial volume capacity Discharge performance.

Comparative example is in embodiment high-temperature behavior test result

Table 1 be comparative example 1-9 and embodiment 1-9 expansion rate, residual capacity, restore capacity, high rate performance, 45 DEG C 800 weeks Cycle performance data significantly reduce battery after storage at high temperatures by adding functional form additive as can be seen from the table Expansion rate, residual capacity, recovery capacity and 45 DEG C of cycle performances are also significantly increased, this shows that the functional additive obviously inhibits Electrolyte is decomposed in high temperature storage, while also playing certain protective effect to cathode SEI.In addition, passing through addition function Energy type additive polymer battery does not decline on high rate performance, is correspondingly improved instead, shows the additive in anode It forms and compares Low ESR, the conductivity of electrolyte is not influenced significantly.

The above is only a preferred embodiment of the present invention, it is noted that for the common skill of the art For art personnel, without departing from the principle of the present invention, several improvement can also be made, these improvement also should be regarded as this hair Bright protection scope.

Claims (7)

1. a kind of electrolyte for improving polymer lithium ion secondary battery high-temperature behavior, including non-aqueous organic solvent, cathode film formation Additive, lithium salts electrolyte further include a kind of 0.5%-10% for accounting for the electrolyte gross mass indicated selected from structural formula I Functional form additive；

Its structural formula I is

The R1 indicates the halogenated alkyl of optional carbon atom number 1-10；R2 and R3 is halogen atom ,-H ,-CN or is carbon atom number The alkyl of 1-10.

2. a kind of electrolyte for improving polymer lithium ion secondary battery high-temperature behavior described in accordance with the claim 1, feature It is that the non-aqueous organic solvent includes carbonate solvent, the carbonate solvent is ethylene carbonate (EC), propylene carbonate Ester (PC), dimethyl carbonate (DMC), methyl ethyl carbonate (EMC), diethyl carbonate (DEC), in methyl propyl carbonate (MPC) extremely Few one kind；It further include non-carbonate solvent, the non-carbonate solvent is gamma-butyrolacton (GBL), methyl acetate (MA), acetic acid Ethyl ester (EA), propyl acetate (PA), methyl propionate (MP), ethyl propionate (EP), methyl butyrate (MB), in ethyl butyrate (EB) extremely Few one kind.

3. a kind of electrolyte for improving polymer lithium ion secondary battery high-temperature behavior according to claim 2, feature It is, the carbonate solvent in the non-aqueous organic solvent accounts for the 10%~50% of electrolyte gross mass, non-carbonate solvent Account for the 0%~50% of electrolyte gross mass.

4. a kind of electrolyte for improving polymer lithium ion secondary battery high-temperature behavior described in accordance with the claim 1, feature It is, the cathode film formation additive includes fluorinated ethylene carbonate (FEC), propane sultone (PS), vinylene carbonate (VC), trifluoromethyl ethylene carbonate (TFPC), sulfuric acid vinyl ester (DTD), ethylene sulfite (ES), vinyl ethylene carbonate At least one of ester (VEC), propene sultone (RPS).

5. a kind of electrolyte for improving polymer lithium ion secondary battery high-temperature behavior according to claim 4, feature It is the 0.5%~30% of the total electrolyte gross mass of cathode film formation additive Zhan.

6. a kind of electrolyte for improving polymer lithium ion secondary battery high-temperature behavior described in accordance with the claim 1, feature It is, the lithium salts electrolyte includes lithium hexafluoro phosphate (LiPF6), bis- (fluorine sulphonyl) imine lithium LiFSI, bis- (trifluoromethyls Sulphonyl) imine lithium (LiTFSI), di-oxalate lithium borate (LiBOB), difluorine oxalic acid boracic acid lithium (LiODFB), LiBF4 (LiBF4), one of lithium carbonate Li2CO3, lithium perchlorate LiClO4 or several.

7. a kind of electrolyte for improving polymer lithium ion secondary battery high-temperature behavior according to claim 6, feature It is, the percentage that the lithium salts electrolyte accounts for the total weight of electrolyte is 5%~30%.