CN106941191A - Lithium ion battery and its nonaqueous electrolytic solution - Google Patents

Abstract

The invention discloses a kind of nonaqueous electrolytic solution, including：Non-aqueous organic solvent, lithium salts and additive, additive includes LiBF4 and with least one in formula I, the dinitrile compound containing unsaturated bond of formula II, wherein, the one or more of R1, R2, A1, A2 in the aliphatic alkyl with 05 carbon atoms；The one or more of R3, R4, A3, A4 in hydrogen atom, fluorine atom, chlorine atom, alkyl, phenyl.In addition, the invention also discloses a kind of lithium ion battery containing nonaqueous electrolytic solution of the present invention.

Description

Lithium ion battery and its nonaqueous electrolytic solution

Technical field

The invention belongs to field of lithium ion battery, it is more particularly related to a kind of lithium ion battery and Its nonaqueous electrolytic solution.

Background technology

Lithium ion battery has that energy density is high, operating voltage is high, self-discharge rate is low, had extended cycle life, nothing Unique advantage such as pollution, is widely used in the electronic products such as camera, mobile phone as power supply.

In recent years, the fast-developing endurance to lithium ion battery of smart electronicses product proposes higher It is required that, performance of the people using the mode of digital product also to lithium ion battery proposes extra requirement.Example Such as, when people use notebook computer, after often lithium ion battery is fully charged, full state is continuously in, When leaving power supply, can just the discharge working method of work, i.e. lithium ion battery of lithium ion battery is that intermittence is filled Discharge cycles.

In order to improve the energy density of lithium ion battery, exploitation high-voltage lithium ion batteries are one of effective ways. At present, operating voltage turns into numerous R＆D institutions and business research in more than 4.35V lithium ion battery Focus.However, under high voltages, positive pole oxidation activity is uprised, nonaqueous electrolytic solution is easily sent out in positive electrode surface Raw electrochemical oxidation reactions, and then generation gas is decomposed, cause irreversible capacity loss, cause lithium-ion electric The circulation volume conservation rate in pond declines.

It can be seen that, the stability of negative electrode and electrolyte interface is improved, it is to improve to suppress electrolyte in the decomposition of negative electrode The high-temperature storage performance of high-voltage lithium ion batteries, the key point of cycle performance.Especially for intermittence Charge and discharge cycles, extend the time of lithium ion battery high-voltage fully charged state storage, cloudy to lithium ion battery The interface stability of pole and electrolyte proposes higher requirement.

In view of this, it is a kind of with preferable high-temperature storage performance and the holding of intermittent cyclic capacity it is necessory to provide The lithium ion battery and its nonaqueous electrolytic solution of rate.

The content of the invention

It is an object of the invention to：A kind of lithium ion battery and its nonaqueous electrolytic solution are provided, there is reason to obtain Think the lithium ion battery of high-temperature storage performance and intermittent cyclic capability retention.

In order to realize foregoing invention purpose, the invention provides a kind of nonaqueous electrolytic solution, it includes non-aqueous organic Solvent, lithium salts and additive, wherein, additive include LiBF4 and with formula I, formula II containing not At least one in the dinitrile compound of saturated bond,

Wherein, R1, R2, A1, A2 in the aliphatic alkyl with 0-5 carbon atom one Plant or several；R3, R4, A3, A4 are independently selected from hydrogen atom, fluorine atom, chlorine atom, alkyl, benzene One or more in base.

Improved as one kind of nonaqueous electrolytic solution of the present invention, the dinitrile compound of Formulas I is Isosorbide-5-Nitrae-dicyano -2- fourths Alkene, the dinitrile compound of Formula II is 2,4- dicyano -1- butylene.

Improved as one kind of nonaqueous electrolytic solution of the present invention, formula I, the dinitrile compound of formula II are in non-aqueous solution electrolysis Weight/mass percentage composition in liquid is 0.1%~3%, preferably 0.5%~2%.When the dinitrile compound of formula I or formula II When weight/mass percentage composition in nonaqueous electrolytic solution is less than 0.1%, it is limited in the absorption and polymerization of positive electrode surface, Transition metal ions dissolution can not effectively be suppressed, suppress oxidation Decomposition of the electrolyte in positive pole；When formula I or formula When weight/mass percentage composition of II dinitrile compound in nonaqueous electrolytic solution is higher than 3%, itself and positive electrode active materials In transition metal formation complexing layer it is blocked up, and produce substantial amounts of polymer and can seriously increase lithium ion The impedance of battery, is unfavorable for the dynamic performance and circulation volume conservation rate of lithium ion battery.

Improved as one kind of nonaqueous electrolytic solution of the present invention, LiBF4 (LiBF₄) in nonaqueous electrolytic solution Weight/mass percentage composition is 0.01%~0.5%.Work as LiBF₄Weight/mass percentage composition in nonaqueous electrolytic solution is less than When 0.01%, its improvement result to positive pole is not obvious；Work as LiBF₄Quality percentage in nonaqueous electrolytic solution contains When amount is higher than 0.5%, excessive LiBF₄The impedance of lithium ion battery can be increased, be unfavorable for lithium ion battery Circulation volume conservation rate.

Improved as one kind of nonaqueous electrolytic solution of the present invention, the lithium salts is selected from LiPF₆、LiClO₄、LiAsF₆、 LiN(CF₃SO₂)₂、LiCF₃SO₃, one or more in LiBOB.

As nonaqueous electrolytic solution of the present invention one kind improve, the non-aqueous organic solvent be selected from ethylene carbonate, Propene carbonate, dimethyl carbonate, diethyl carbonate, methyl ethyl carbonate, gamma-butyrolacton, methyl formate, One or more in Ethyl formate, ethyl propionate, propyl propionate, tetrahydrofuran.

In order to realize foregoing invention purpose, present invention also offers a kind of lithium ion battery, it includes：

Positive plate, including plus plate current-collecting body and be arranged on plus plate current-collecting body and containing positive electrode active materials just Pole diaphragm；

Negative plate, including negative current collector and be arranged at negative on negative current collector and containing negative active core-shell material Pole diaphragm；

Barrier film, is interval between positive plate and negative plate；

Nonaqueous electrolytic solution；And

Package foil；

Wherein, the nonaqueous electrolytic solution is foregoing nonaqueous electrolytic solution.

Improved as one kind of lithium ion battery of the present invention, the end of charge voltage of the lithium ion battery is 4.35V~5V.

Improved as one kind of lithium ion battery of the present invention, the positive electrode active materials include cobalt acid lithium and/or lithium Nickel manganese cobalt ternary material.

Improved as one kind of lithium ion battery of the present invention, the negative active core-shell material includes graphite and/or silicon.

Compared with prior art, LiBF is added simultaneously in nonaqueous electrolytic solution of the present invention₄With the two of formula I or formula II Nitrile compound, the two collaboration can stablize cathode surface oxygen atom and transition metal ions in cathode surface film forming, Reduce the oxidation activity under cathode high voltage and reduce transition metal ions dissolution, be effectively improved lithium ion battery High-temperature storage performance and intermittent cyclic capability retention：On the one hand, LiBF₄It is anti-in surface of positive electrode active material The boron-oxygen that should be generated can improve the stability of oxygen atom in positive electrode active materials under high voltage, and reduction is high The electro-chemical activity of cathode surface under voltage, suppresses oxidation Decomposition of the electrolyte in cathode surface；On the other hand, In two nitrile compounds containing unsaturated bond of formula I or formula II, many itrile groups can be with cathode material surface transition Metal ion forms multiple tooth complex compound, is conducive to suppressing transition metal ions dissolution, unsaturated double-bond occurs poly- Reaction is closed, finer and close protective layer is formed；LiBF₄Acted synergistically with the dinitrile compound of formula I or formula II, can Effectively improve cathode surface stability, suppress high voltage under electrolyte cathode surface reaction, and then The problem of suppressing high-temperature lithium ion battery storage aerogenesis and lithium ion battery interval charge and discharge cycles capacity attenuation.

Embodiment

In order that the purpose of the present invention, technical scheme and technique effect become apparent from understanding, below in conjunction with implementation The present invention will be described in further detail with comparative example for example.It should be appreciated that described in this specification Embodiment and comparative example are not intended to limit the present invention just for the sake of explaining the present invention.

Comparative example 1

(1) preparation of nonaqueous electrolytic solution

In drying shed, EC in mass ratio:DEC=3:7 weigh non-aqueous organic solvent and mix, and add afterwards LiPF₆As lithium salts and make LiPF₆Concentration be 1mol/L, obtain nonaqueous electrolytic solution.

(2) preparation of positive plate

It is 10% to weigh 1.42kg Solvents N-methyls -2-Pyrrolidone (NMP), 1.2kg weight/mass percentage compositions Binding agent polyvinylidene fluoride (PVDF), 0.16kg conductive agents electrically conductive graphite and 7.2kg positive electrode active materials LiCoO₂It is sufficiently mixed stirring and obtains anode sizing agent, anode sizing agent is uniformly coated to thickness for 16 μm afterwards Plus plate current-collecting body aluminium foil on, afterwards 120 DEG C toast 1h obtain positive pole diaphragm, afterwards through overcompaction, point Cut and obtain positive plate.

(3) preparation of negative plate

Weigh 1.2Kg weight/mass percentage compositions be 1.5% thickener sodium carboxymethylcellulose (CMC) solution, Binding agent SBR emulsion, 2.4kg negative active core-shell material graphite powders that 0.07kg weight/mass percentage compositions are 50% End is sufficiently mixed stirring and obtains cathode size, and it is negative for 12 μm that cathode size is uniformly coated into thickness afterwards On the copper foil of affluxion body of pole, afterwards 120 DEG C toast 1h obtain cathode membrane, afterwards through overcompaction, cut To negative plate.

(4) preparation of lithium ion battery

Above-mentioned positive plate, negative plate are separated with thickness for 12 μm of polypropylene barrier film and squarely is wound Naked battery core, aluminum foil sack is loaded afterwards, 80 DEG C baking water removal after, injection nonaqueous electrolytic solution, sealing, Chemical conversion, exhaust and test capacity obtain the lithium ion battery of finished product.

Comparative example 2

Method according to comparative example 1 prepares lithium ion battery, the difference is that only：In nonaqueous electrolytic solution also Containing additive, the LiBF that additive is 0.2% for the weight/mass percentage composition in nonaqueous electrolytic solution₄。

Comparative example 3

Method according to comparative example 1 prepares lithium ion battery, the difference is that only：In nonaqueous electrolytic solution also Containing additive, additive is 1% to have a Formulas I structure for weight/mass percentage composition in nonaqueous electrolytic solution Dinitrile compound.

Comparative example 4

Method according to comparative example 1 prepares lithium ion battery, the difference is that only：In nonaqueous electrolytic solution also Containing additive, the LiBF that additive is 0.6% for the weight/mass percentage composition in nonaqueous electrolytic solution₄With non- The dinitrile compound with Formulas I structure that weight/mass percentage composition in water electrolysis liquid is 1%.

Comparative example 5

Method according to comparative example 1 prepares lithium ion battery, the difference is that only：In nonaqueous electrolytic solution also Containing additive, the LiBF that additive is 0.2% for the weight/mass percentage composition in nonaqueous electrolytic solution₄With non- The dinitrile compound with Formulas I structure that weight/mass percentage composition in water electrolysis liquid is 4%.

Embodiment 1

Method according to comparative example 1 prepares lithium ion battery, the difference is that only：In nonaqueous electrolytic solution also Containing additive, the LiBF that additive is 0.1% for the weight/mass percentage composition in nonaqueous electrolytic solution₄With non- The dinitrile compound with Formulas I structure that weight/mass percentage composition in water electrolysis liquid is 1%.

Embodiment 2

Method according to comparative example 1 prepares lithium ion battery, the difference is that only：In nonaqueous electrolytic solution also Containing additive, the LiBF that additive is 0.2% for the weight/mass percentage composition in nonaqueous electrolytic solution₄With non- The dinitrile compound with Formulas I structure that weight/mass percentage composition in water electrolysis liquid is 1%.

Embodiment 3

Method according to comparative example 1 prepares lithium ion battery, the difference is that only：In nonaqueous electrolytic solution also Containing additive, the LiBF that additive is 0.3% for the weight/mass percentage composition in nonaqueous electrolytic solution₄With non- The dinitrile compound with Formulas I structure that weight/mass percentage composition in water electrolysis liquid is 1%.

Embodiment 4

Method according to comparative example 1 prepares lithium ion battery, the difference is that only：In nonaqueous electrolytic solution also Containing additive, the LiBF that additive is 0.5% for the weight/mass percentage composition in nonaqueous electrolytic solution₄With non- The dinitrile compound with Formulas I structure that weight/mass percentage composition in water electrolysis liquid is 1%.

Embodiment 5

Method according to comparative example 1 prepares lithium ion battery, the difference is that only：In nonaqueous electrolytic solution also Containing additive, the LiBF that additive is 0.2% for the weight/mass percentage composition in nonaqueous electrolytic solution₄With non- The dinitrile compound with Formulas I structure that weight/mass percentage composition in water electrolysis liquid is 0.5%.

Embodiment 6

Method according to comparative example 1 prepares lithium ion battery, the difference is that only：In nonaqueous electrolytic solution also Containing additive, the LiBF that additive is 0.2% for the weight/mass percentage composition in nonaqueous electrolytic solution₄With non- The dinitrile compound with Formulas I structure that weight/mass percentage composition in water electrolysis liquid is 2%.

Embodiment 7

Method according to comparative example 1 prepares lithium ion battery, the difference is that only：In nonaqueous electrolytic solution also Containing additive, the LiBF that additive is 0.2% for the weight/mass percentage composition in nonaqueous electrolytic solution₄With non- The dinitrile compound with Formulas I structure that weight/mass percentage composition in water electrolysis liquid is 3%.

Embodiment 8

Method according to comparative example 1 prepares lithium ion battery, the difference is that only：In nonaqueous electrolytic solution also Containing additive, the LiBF that additive is 0.2% for the weight/mass percentage composition in nonaqueous electrolytic solution₄With non- Weight/mass percentage composition in water electrolysis liquid is that 0.5% dinitrile compound with Formulas I structure and quality percentage contain Measure the dinitrile compound with Formula II structure for 0.5%.

Embodiment 9

Method according to comparative example 1 prepares lithium ion battery, the difference is that only：In nonaqueous electrolytic solution also Containing additive, the LiBF that additive is 0.2% for the weight/mass percentage composition in nonaqueous electrolytic solution₄With non- The dinitrile compound with Formula II structure that weight/mass percentage composition in water electrolysis liquid is 1%.

Table 1 is the electrolyte addition manner of each comparative example and embodiment.

The electrolyte addition manner of table 1

Comparative example 1-5 and embodiment 1-9 performance test process and test result

(1) high-temperature storage performance of lithium ion battery is tested

At 25 DEG C, with 0.5C multiplying powers constant-current charge to 4.4V, afterwards under 4.4V constant-voltage charge to 0.05C, Test the thickness of lithium ion battery and be designated as h0；Lithium ion battery is put into 60 DEG C of insulating box afterwards, is incubated 30 days, and tested the thickness of lithium ion battery every 5 days and be designated as hn, n is that high-temperature lithium ion battery is stored Number of days.

High-temperature lithium ion battery store n days after thickness swelling (%)=(hn-h0)/h0 × 100%.

(2) the intermittent cyclic performance test of lithium ion battery

45 DEG C of volume tests：At 45 DEG C, lithium ion battery is stood 30 minutes, afterwards with 0.5C multiplying powers Constant-current charge is to 4.4V, and constant-voltage charge, to 0.05C, and stands 5 minutes under 4.4V afterwards, afterwards with 0.5C Multiplying power constant-current discharge records battery initial discharge capacity C0 to 3.0V；

45 DEG C of intermittent cyclic tests：At 45 DEG C, lithium ion battery is stood 30 minutes；With 0.5C multiplying powers Constant-current charge is to 4.4V, and constant-voltage charge is to 0.05C under 4.4V；It is small that battery stands 20 in 45 DEG C of environment When；Battery records discharge capacity of the cell with 0.5C multiplying powers Model For Transverse-discharge Flow Type to 3.0V；This is between one complete Have a rest charge and discharge cycles, battery charge and discharge cycles 120 times in the same manner.

The discharge capacity of capability retention (%)=n-th circulation after the n-th circulation of lithium ion battery/first Discharge capacity × 100%.

The storage test of lithium ion battery and intermittent cyclic test result are as shown in table 2.

The battery storage of table 2 is tested and intermittent cyclic test result

It can be seen that from comparative example 1-3 and embodiment 2 test result and be individually added into the electrolytic solution quality hundred Divide the LiBF that content is 0.2%₄Or weight/mass percentage composition is the dinitrile compound of 1% Formulas I structure, lithium ion The high-temperature storage performance of battery under high voltages has certain improvement, but effect is not notable, and the interval of battery is followed Ring performance also has certain improvement, but is recycled to the failure of latter stage battery core flatulence.And in embodiment 2, electrolyte In simultaneously add weight/mass percentage composition be 0.2% LiBF₄It is the two of 1% Formulas I structure with weight/mass percentage composition Nitrile compound, the storage performance of lithium ion battery under high voltages improves notable, and battery stores 30 at 60 DEG C Its thickness swelling is smaller, is not apparent from flatulence, and lithium ion battery intermittent cyclic capability retention is also obviously improved. LiBF is added in electrolyte₄Boron-oxygen can be generated in negative electrode, reduce the oxidation activity of negative electrode；Electrolyte The middle dinitrile compound for adding Formulas I structure, can be complexed and aggregate into the protective layer of densification, suppression in cathode surface Reaction of the electrolyte processed in negative electrode.Therefore it is individually added into LiBF in electrolyte₄Or the dinitrile compound of Formulas I structure The stability of negative electrode and electrolyte interface under high voltage can be improved, improve the high temperature storage of lithium ion battery Can be with intermittent cyclic capability retention；LiBF is added in electrolyte simultaneously₄With the dinitrile compound of Formulas I structure, In LiBF₄While reducing that negative electrode is to the oxidation activity of electrolyte under high voltage, the dinitrile compound of Formulas I structure Fine and close protective layer is generated, the stability of negative electrode and electrolyte interface is more efficiently improved, improves lithium The high-temperature storage performance and intermittent cyclic capability retention of ion battery.

Addition quality percentage in the electrolytic solution is can be seen that from embodiment 1-4 and comparative example 4 test result to contain Measure after the dinitrile compound for 1% Formulas I structure, while adding the LiBF of different quality percentage composition₄, lithium The high-temperature storage performance of ion battery is with LiBF₄Content increase and improve, still, LiBF₄Content reaches When 0.6% (comparative example 4), the intermittent cyclic capability retention of lithium ion battery is significantly reduced.Therefore, LiBF₄ Addition be preferably 0.1%~0.3%.

It can be seen that and add in the electrolytic solution from embodiment 5-8, embodiment 2 and comparative example 5 test result Weight/mass percentage composition is 0.2% LiBF₄Afterwards, at the same add different quality percentage composition have Formulas I structure Dinitrile compound, the high-temperature storage performance of lithium ion battery is with the increasing of the dinitrile compound content of Formulas I structure Plus and improve, still, when the content of the dinitrile compound of Formulas I structure reaches 4% (comparative example 5), lithium ion The intermittent cyclic capability retention of battery declines rapidly with cycle-index.Therefore, the dinitrile compound of Formulas I structure Content in the electrolytic solution is preferably 0.5%~2%.Contrasted from the test result of embodiment 8-9 and embodiment 2 As can be seen that Formula II structure dinitrile compound substitution or part substitution Formulas I structure dinitrile compound and LiBF₄Be added to simultaneously in electrolyte, can play similar improvement high-temperature storage performance of lithium ion battery and Have a rest the effect of cycle performance.

In summary, LiBF is added simultaneously in nonaqueous electrolytic solution₄With two nitrilations with formula I and/or formula II Compound can make lithium ion battery under high voltages while having preferable high-temperature storage performance and intermittent cyclic capacity Conservation rate.

According to above-mentioned principle, the present invention can also carry out appropriate change and modification to above-described embodiment.Therefore, The invention is not limited in specific embodiment disclosed and described above, to some modifications and changes of the present invention It should also be as falling into the scope of the claims of the present invention.Although in addition, having used one in this specification A little specific terms, but these terms are merely for convenience of description, do not constitute any limitation to the present invention.

Claims (10)

1. a kind of nonaqueous electrolytic solution, including non-aqueous organic solvent, lithium salts and additive, it is characterised in that institute Stating additive includes：LiBF4 and with formula I, the dinitrile compound containing unsaturated bond of formula II At least one,

Wherein, R1, R2, A1, A2 in the aliphatic alkyl with 0-5 carbon atom one Plant or several；R3, R4, A3, A4 are independently selected from hydrogen atom, fluorine atom, chlorine atom, alkyl, benzene One or more in base.

2. nonaqueous electrolytic solution according to claim 1, it is characterised in that the dinitrile compound of Formulas I is Isosorbide-5-Nitrae-dicyano -2- butylene, the dinitrile compound of Formula II is 2,4- dicyano -1- butylene.

3. nonaqueous electrolytic solution according to claim 1, it is characterised in that the dintrile of formula I and/or formula II Weight/mass percentage composition of the compound in nonaqueous electrolytic solution is 0.1%~3%, preferably 0.5%~2%.

4. nonaqueous electrolytic solution according to claim 1, it is characterised in that LiBF4 is in non-water power It is 0.01%~0.5% to solve the weight/mass percentage composition in liquid.

5. nonaqueous electrolytic solution according to claim 1, it is characterised in that the lithium salts is selected from LiPF₆、 LiClO₄、LiAsF₆、LiN(CF₃SO₂)₂、LiCF₃SO₃, one or more in LiBOB.

6. nonaqueous electrolytic solution according to claim 1, it is characterised in that the non-aqueous organic solvent choosing From ethylene carbonate, propene carbonate, dimethyl carbonate, diethyl carbonate, methyl ethyl carbonate, γ-Ding Nei One or more in ester, methyl formate, Ethyl formate, ethyl propionate, propyl propionate, tetrahydrofuran.

7. a kind of lithium ion battery, including：

Positive plate, including plus plate current-collecting body and be arranged on plus plate current-collecting body and containing positive electrode active materials just Pole diaphragm；

Negative plate, including negative current collector and be arranged at negative on negative current collector and containing negative active core-shell material Pole diaphragm；

Barrier film, is interval between positive plate and negative plate；

Nonaqueous electrolytic solution；And

Package foil；

Characterized in that, the nonaqueous electrolytic solution is the non-aqueous solution electrolysis any one of claim 1 to 6 Liquid.

8. lithium ion battery according to claim 7, it is characterised in that the lithium ion battery fills Electric final voltage is 4.35V~5V.

9. lithium ion battery according to claim 7, it is characterised in that the positive electrode active materials bag Include cobalt acid lithium and/or lithium-nickel-manganese-cobalt ternary material.

10. lithium ion battery according to claim 7, it is characterised in that the negative active core-shell material bag Include graphite and/or silicon.