CN103887563A - Lithium ion secondary battery electrolyte - Google Patents

Abstract

The invention discloses lithium ion secondary battery electrolyte comprising a non-aqueous solvent and lithium salt dissolved into the non-aqueous solvent, wherein non-aqueous solvent contains cyclic phosphoric ester accounting for 0.5-15% of the total mass of non-aqueous solvent. Cyclic phosphoric ester has the structural formula as the specification, wherein n is an integer ranging from 0 to 2, and R is a straight-chain or branched-chain alkyl from C1 to C4. A functional additive used by the lithium ion secondary battery electrolyte has a relatively high reduction potential and can be used for forming a layer of compact and stable solid electrolyte passive film (SEI) in the first charging process, so that the co-intercalation of propylene carbonate (PC) to graphite can be effectively inhibited, the initial discharging capacity of a battery can be effectively increased, the cycle life of the battery can be effectively prolonged, and the high-and-low temperature performance of the battery can be effectively improved.

Description

A kind of electrolyte of lithium-ion secondary battery

Technical field

The present invention relates to a kind of lithium rechargeable battery, especially improve lithium rechargeable battery and the electrolyte thereof of cycle performance of battery.

Background technology

Lithium ion battery is the green high-capacity environment-protecting battery occurring the nineties in 20th century, there is the advantages such as voltage is high, volume is little, quality is light, specific energy is high, memory-less effect, pollution-free, self discharge is little, the life-span is long due to it, emphasize in compact, multi-functional portable type electronic product application universal rapidly at mobile phone, notebook computer, video camera, digital camera etc.

Graphite is the most frequently used negative material of lithium ion battery, is also current application electrode material the most widely.Battery is in initial charge process, the lithium ion being discharged by the anodal lithium-transition metal oxide of battery, through electrolyte, sees through barrier film and arrives graphite cathode, and generate half lithium carbonate in graphite cathode generation reduction reaction, the lithium salts such as Sulfonic Lithium, form film in negative terminal surface thus.The film of this type is called as organic solid electrolyte interface (SEI) film.Peeling off of the graphite that the effect that this passivating film not only plays lithium ion passage also can stop solvent to be embedded into cause in graphite.Propene carbonate is as one of conventional electrolyte solvent, and it has wide liquid scope, and its fusing point is low, and boiling point is high, is conventional electrolyte solvent.In the time of propene carbonate and graphite collocation use, propylene carbonate solvent molecule can not form stable SEI film at graphite electrode surface, it together embeds graphite layers in company with solvation lithium ion, cause peeling off of graphite, and then destroy the lamellar structure of graphite, performance to graphite causes adverse influence, makes the degradation such as battery capacity, circulation.In view of this, be necessary to provide a kind of additive that can promote graphite cathode film forming, effectively improve initial discharge capacity, cycle life and the high temperature performance of lithium ion battery.

Summary of the invention

The problem existing for prior art, the invention provides a kind of electrolyte of lithium-ion secondary battery.This electrolyte solves battery in charging process, the reduction decomposition of organic solvent in electrolyte, the problem that causes graphite to be peeled off.

For achieving the above object, technical scheme of the present invention is as follows:

A kind of electrolyte of lithium-ion secondary battery, it comprises non-aqueous organic solvent and is dissolved in the lithium salts in non-aqueous organic solvent, wherein, non-aqueous organic solvent contains quality and accounts for the annular phosphonate of non-aqueous organic solvent gross mass 0.5%～15%; The structural formula of described annular phosphonate is as follows:

Wherein, the positive integer that n is 0～2, R is C1～C4 straight or branched alkyl.

Foregoing a kind of electrolyte of lithium-ion secondary battery, described annular phosphonate is preferably 1,3-PD methyl phosphonate, 1,2-ethylene glycol ethyl phosphonate ester or BDO methyl phosphonate.

Foregoing a kind of electrolyte of lithium-ion secondary battery, the quality percentage composition of described annular phosphonate in non-aqueous organic solvent is 5%～10%.

Foregoing a kind of electrolyte of lithium-ion secondary battery, described lithium salts is LiPF ₆, described lithium salt is 1M.

The present invention has added after the cyclic phosphonic acid ester additive that contains molecular structural formula of the present invention in electrolyte of lithium-ion secondary battery, because this cyclic phosphonic acid ester additive has higher reduction potential, in initial charge process, can form one deck densification, stable solid electrolyte passivating film (SEI), can effectively suppress the common embedding of propene carbonate (PC) to graphite, the initial discharge capacity, cycle life and the high temperature performance that effectively improve battery, effectively solve the battery problem that graphite is peeled off in charging process.

Embodiment

Below in conjunction with embodiment and comparative example, the invention will be further elaborated.

Lithium rechargeable battery of the present invention, comprises positive plate, negative plate, is interval in barrier film and electrolyte between adjacent positive/negative plate.

The preparation method of described positive plate is: by cobalt acid lithium, conductive agent SuperP, bonding agent PVDF in mass ratio 96:2.0:2.0 mix the anode paste of Li-ion secondary battery of making certain viscosity, be coated on collector aluminium foil, its coating weight is 0.0194g/cm ², after drying at 85 DEG C, cold pressing; Then carry out after trimming, cut-parts, itemize, after itemize under vacuum condition 85 DEG C dry 4 hours, soldering polar ear, makes the lithium ion secondary battery positive electrode meeting the demands.

The preparation method of described negative plate is: by graphite and conductive agent SuperP, thickener CMC, bonding agent SBR in mass ratio 96.5:1.0:1.0:1.5 make slurry, be coated on copper foil of affluxion body and at 85 DEG C and dry, coating weight is 0.0089g/cm ²; Carry out after trimming, cut-parts, itemize, after itemize under vacuum condition 110 DEG C dry 4 hours, soldering polar ear, makes the lithium ion secondary battery negative pole meeting the demands.

Described barrier film adopts Celgard2400.

Electrolyte of lithium-ion secondary battery of the present invention contains wherein one or more the mixture in organic sulfoxide compounds, sulfonates compounds, halogenated cyclic carbonats compound, the sub-alkylene compound of carbonic acid, cyano compound.Described non-aqueous organic solvent contains cyclic carbonate and linear carbonate, can be selected from wherein one or more mixture of ethylene carbonate, propene carbonate, dimethyl carbonate, butyl lactone, butylene, diethyl carbonate, dipropyl carbonic ester, methyl ethyl carbonate, methyl propyl carbonate, diethyl carbonate or ethyl propyl carbonic acid ester.

The concrete preparation method of electrolyte of lithium-ion secondary battery of the present invention is:

Embodiment 1

By ethylene carbonate (EC), propene carbonate (PC), diethyl carbonate (DEC), fluorinated ethylene carbonate (FEC) (fluorinated ethylene carbonate is the one of halogenated cyclic carbonates) and annular phosphonate, mass ratio according to table 1 is mixed to get electrolyte solvent, dissolves in the LiPF of 1M in this electrolyte solvent ₆obtain nonaqueous electrolytic solution.

The preparation of lithium rechargeable battery: it is 4.2mm that the lithium-ion secondary battery positive plate of preparing according to aforementioned technique, negative plate and barrier film are made into thickness through winding process, width is 34mm, length is the lithium rechargeable battery of 82mm, vacuum bakeout 10 hours at 75 DEG C, inject above-mentioned nonaqueous electrolytic solution, leave standstill after 24 hours, with 0.1C(160mA) constant current charge to 4.2V, then drop to 0.05C(80mA with 4.2V constant voltage charge to electric current); Then with 0.1C(160mA) be discharged to 3.0V, repeat to discharge and recharge for 2 times, finally again with 0.1C(160mA) battery is charged to 3.8V, complete battery and make.

Embodiment 2

Method with reference to embodiment 1 is prepared lithium rechargeable battery, just, in the time preparing electrolyte of lithium-ion secondary battery, uses 1,2-ethylene glycol ethyl phosphonate ester to replace the 1,3-PD methyl phosphonate in embodiment 1.

Embodiment 3

Method with reference to embodiment 1 is prepared lithium rechargeable battery, just, in the time preparing electrolyte of lithium-ion secondary battery, uses BDO methyl phosphonate to replace the 1,3-PD methyl phosphonate in embodiment 1.

Embodiment 4

Method with reference to embodiment 1 is prepared lithium rechargeable battery, just in the time preparing electrolyte of lithium-ion secondary battery, service quality percentage composition is that 0.5% 1,3-PD methyl phosphonate replaces the 1,3-PD methyl phosphonate that the quality percentage composition in embodiment 1 is 5%.

Embodiment 5

Method with reference to embodiment 1 is prepared lithium rechargeable battery, just in the time preparing electrolyte of lithium-ion secondary battery, service quality percentage composition is that 10% 1,3-PD methyl phosphonate replaces the 1,3-PD methyl phosphonate that the quality percentage composition in embodiment 1 is 5%.

Embodiment 6

Method with reference to embodiment 1 is prepared lithium rechargeable battery, just in the time preparing electrolyte of lithium-ion secondary battery, service quality percentage composition is that 15% 1,3-PD methyl phosphonate replaces the 1,3-PD methyl phosphonate that the quality percentage composition in embodiment 1 is 5%.

Comparative example 1

Method with reference to embodiment 1 is prepared lithium rechargeable battery, is in the time preparing electrolyte of lithium-ion secondary battery, the fluorinated ethylene carbonate (FEC) that additive is only 5% for quality percentage composition.

For the lithium rechargeable battery of embodiment 1～6 and comparative example 1, carry out following high-temperature cycle test.The result of the capability retention (%) of reaction cell cycle performance is asked for an interview table 1.

High temperature cyclic performance test

For the lithium rechargeable battery of embodiment 1～6 and comparative example 1, under 45 DEG C of conditions first with 0.7C(1120mA) constant current lithium rechargeable battery is charged to 4.2V, further be less than 0.05C(80mA at 4.2V constant-potential charge to electric current), then with 0.5C(800mA) constant current lithium rechargeable battery is discharged to 3.0V.Current discharge capacity is cyclic discharge capacity for the first time.Battery carries out cycle charge discharge electrical testing in a manner described, gets the discharge capacity of the 500th circulation.

Carry out par high temperature cyclic performance by the capability retention of lithium rechargeable battery, capability retention is calculated as follows, and the result of gained is listed table 1 in.

Capability retention (%)=[discharge capacity/discharge capacity of circulation for the first time of the 500th circulation] * 100%.

The configuration of table 1 electrolyte (each component in non-aqueous organic solvent comprises mass percent and the capability retention (%) of the additive in non-aqueous organic solvent)

Table 1 is depicted as lithium rechargeable battery embodiment 1～6 lithium rechargeable battery of the present invention and comparative example 1 lithium rechargeable battery cycle performance under 45 DEG C, 0.7C charging/0.5C electric discharge, 3.0-4.2V condition.Can find out from embodiment 1～6 and comparative example 1: the lithium rechargeable battery that has added the cyclic phosphonic acid ester additive that contains molecular structural formula of the present invention electrolyte of lithium-ion secondary battery can effectively improve the high temperature cyclic performance of lithium rechargeable battery.

Although it is pointed out that in the embodiment of this specification only with 1,3-PD methyl phosphonate

, 1, 2-ethylene glycol ethyl phosphonate ester and 1, 4-butanediol methyl phosphonate is that example is illustrated the additive of electrolyte of lithium-ion secondary battery of the present invention, but, other execution mode of lithium rechargeable battery according to the present invention, electrolyte of lithium-ion secondary battery additive can be also 1, ammediol ethyl phosphonate, 1, ammediol propyl phosphonous acid ester, 1, ammediol butyl phosphine acid esters, 1, 2-ethylene glycol propyl phosphonous acid, 1, 4-butanediol ethyl phosphonate, 1, 4-butanediol propyl phosphonous acid ester and 1, wherein one or more the mixture such as 4-butanediol butyl phosphine acid esters.

Although it is pointed out that in the embodiment of this specification only with LiPF ₆for example is illustrated electrolyte of lithium-ion secondary battery of the present invention, still, other execution mode of lithium rechargeable battery according to the present invention, in electrolyte, lithium salts can be also LiN (C _xf2 _x+1sO ₂) (C _yf _2y+1sO ₂), LiPF ₆, LiBF ₄, LiBOB, LiAsF ₆, Li (CF ₃sO ₂) ₂n, LiCF ₃sO ₃, LiClO ₄wherein one or more mixture; 1M is to be only also lithium salts LiPF in lithium rechargeable battery ₆typical concentrations, the concentration of lithium salts can be the arbitrary value between 0.5M～1.5M; In addition, non-aqueous organic solvent can be selected from wherein one or more mixture of ethylene carbonate, propene carbonate, dimethyl carbonate, butyl lactone, butylene, diethyl carbonate, dipropyl carbonic ester, methyl ethyl carbonate, methyl propyl carbonate, ethyl propyl carbonic acid ester.。

According to announcement and the instruction of above-mentioned specification, those skilled in the art in the invention can also change and revise above-mentioned execution mode.Therefore, the present invention is not limited to embodiment disclosed and described above, also should fall in the protection range of claim of the present invention modifications and changes more of the present invention.In addition,, although used some specific terms in this specification, these terms just for convenience of description, do not form any restriction to the present invention.

Claims (7)

1. an electrolyte of lithium-ion secondary battery, it comprises non-aqueous organic solvent and be dissolved in the lithium salts in non-aqueous organic solvent, wherein, non-aqueous organic solvent contains quality and accounts for the annular phosphonate of non-aqueous organic solvent gross mass 0.5%～15%; The structural formula of described annular phosphonate is as follows:

Wherein, the positive integer that n is 0～2, R is C1～C4 straight or branched alkyl.

2. a kind of electrolyte of lithium-ion secondary battery according to claim 1, is characterized in that: described annular phosphonate is preferably 1,3-PD methyl phosphonate, 1,2-ethylene glycol ethyl phosphonate ester or BDO methyl phosphonate.

3. a kind of electrolyte of lithium-ion secondary battery according to claim 1 and 2, is characterized in that: the quality percentage composition of described annular phosphonate in non-aqueous organic solvent is 5%～10%.

4. a kind of electrolyte of lithium-ion secondary battery according to claim 1 and 2, is characterized in that: described lithium salts is LiPF ₆.

5. a kind of electrolyte of lithium-ion secondary battery according to claim 3, is characterized in that: described lithium salts is LiPF ₆.

6. electrolyte of lithium-ion secondary battery according to claim 4, is characterized in that: described lithium salt is 1M.

7. a kind of electrolyte of lithium-ion secondary battery according to claim 5, is characterized in that: described lithium salt is 1M.