CN1599103A

CN1599103A - Method for preparing gradient covered LiNiO2 plus plate material for lithium ion battery

Info

Publication number: CN1599103A
Application number: CNA200410043772XA
Authority: CN
Inventors: 顾大明; 史鹏飞; 王虹
Original assignee: Harbin Institute of Technology
Current assignee: Harbin Institute of Technology
Priority date: 2004-08-04
Filing date: 2004-08-04
Publication date: 2005-03-23
Anticipated expiration: 2024-08-04
Also published as: CN1284255C

Abstract

The invention relates to a preparation method of the anode material of the LiNiO2 lithium ion battery covered in gradients. The invention is realized through the following steps: a. add the NiSO4 solution and the mixed solution of the NH3.H2O and NaOH with adulterated ions to the reaction vessel, make them react for between 2 hours and 2 days; b. when the volume of the NiSO4 solution is between 10% and 40% of the original volume, add between 0.5mol/L and 2.5 mol/L of the X2(SO4)y solution to the rest NiSO4 solution, put the mixed liquor into the reaction vessel to form a X(OH)y layer on the surface of the Ni(OH)2 grain in gradients and let them react for between 3 hours and 3 days; c. mix the X(OH)y adulterated with the Ni(OH)2 with the LiOH, skive them, burn it, then grind it and get the final product. The invention has simple technique. The product as the anode material of the lithium ion battery is featured by high specific capacity, low cost, little pollution and good cycle performance.

Description

A kind of gradient coats LiNiO 2The preparation method of anode material for lithium-ion batteries

Technical field:

The present invention relates to a kind of preparation method of anode material for lithium-ion batteries.

Background technology:

LiCoO ₂The stable electrochemical property of (cobalt acid reason) is so Li-ion rechargeable pond positive electrode is used LiCoO more at present ₂But, LiCoO ₂Specific capacity low, cost is high, pollution level is big; And LiNiO ₂Specific capacity height, the cost of (nickel acid reason) is low, pollution level is little, but performance (cycle performance) instability.There are shortcomings such as cost height, complex process, unstable properties in the anode material for lithium-ion batteries that existing method is prepared.

Summary of the invention:

The purpose of this invention is to provide a kind of gradient and coat LiNiO ₂The preparation method of anode material for lithium-ion batteries, it can be prepared, and cost is low, pollution level is little, specific capacity is high, take off/anode material for lithium-ion batteries of embedding lithium stable performance.The present invention is achieved in that a, adds the NiSO that contains dopant ion in reaction vessel ₄Solution and NH ₃H ₂O and NaOH mixed solution reacted 2 hours～2 days, and wherein the pH value is 9.5～12.5, temperature is 40～70 ℃, NiSO ₄Solution concentration is 0.5～2.5mol/L; B, when the residue NiSO ₄The volume of solution is 10 of initial volume～40% o'clock, to residue NiSO ₄Solution adds 0.5～2.5mol/LX gradually ₂(SO ₄) _ySolution joins mixed solution in the reaction vessel simultaneously gradually, makes Ni (OH) ₂Grain surface forms the X (OH) that gradient coats _yLayer reacted 3 hours～3 days; C, will be by surface graded coating X (OH) _yNi doped (OH) ₂With LiOH be Ni/X: Li=(1.0～1.15) according to mol ratio: 1 mixed, grind well, sintering, grind again, obtain final products.Technology of the present invention is simple, and products obtained therefrom is as the positive electrode of lithium ion battery, its specific capacity height (first specific capacity＞200mAh/g), cost is low (is LiCoO ₂1/2～2/3), pollute little (being bordering on pollution-free), good cycle (each average cycle efficieny＞99.5%).

Embodiment:

Embodiment one: present embodiment is achieved in that a, adds the NiSO that contains dopant ion in reaction vessel ₄Solution and NH ₃H ₂O and NaOH mixed solution reacted 2 hours～2 days, and wherein the pH value is 9.5～12.5, temperature is 40～70 ℃, NiSO ₄Solution concentration is 0.5～2.5mol/L; B, when the residue NiSO ₄The volume of solution is 10 of initial volume～40% o'clock, to residue NiSO ₄Solution adds 0.5～2.5mol/L X gradually ₂(SO ₄) y solution, simultaneously mixed solution is joined in the reaction vessel gradually, make Ni (OH) ₂Grain surface forms the X (OH) that gradient coats _yLayer reacted 3 hours～3 days; C, will be by surface graded coating X (OH) _yNi doped (OH) ₂With LiOH be Ni/X: Li=(1.0～1.15) according to mol ratio: 1 mixed, grind well, sintering, grind again, obtain final products, the chemical formula of products obtained therefrom is: LiNi _1-a-bX _aM _bO ₂, wherein a=0～0.4, b=0～0.1, M is a dopant ion.Described X is Co, Mg, Ti, Zr, Al or B; Described dopant ion is Co ²⁺, Zn ²⁺, Mg ²⁺, Mn ²⁺, Al ³⁺And NH ⁺ ₄In one or more; Described dopant ion is Ni ²⁺1～40% of weight.

Embodiment two: present embodiment is achieved in that a, adds the NiSO that contains dopant ion in reaction vessel ₄Solution and NH ₃H ₂O and NaOH mixed solution reacted 2 hours～2 days, and wherein the pH value is 11.20 ± 0.05, temperature is 57 ± 0.5 ℃, NiSO ₄Solution concentration is 1.5mol/L, and dopant ion is Ni ²⁺2～5% of weight; B, as Ni (OH) ₂When the particle diameter of crystal grain is 100mm～20 μ m, remain NiSO this moment ₄The volume of solution is 10 of initial volume～40% o'clock, to residue NiSO ₄Solution adds 1.5mol/L CoSO gradually ₄Solution joins mixed solution in the reaction vessel simultaneously gradually, makes Ni (OH) ₂Grain surface forms the Co (OH) that gradient coats ₂Layer reacted 3 hours～3 days; C, will be by surface graded coating Co (OH) ₂Ni doped (OH) ₂With LiOH be Ni/Co: Li=(1.0～1.15) according to mol ratio: 1 mixed, grind well, sintering, grind again, obtain final products, the chemical formula of products obtained therefrom is: LiNi _1-a-bCo _aM _bO ₂, wherein a=0～0.4, b=0～0.1, M is a dopant ion.The present invention prepares predecessor [Ni _1-a-bCo _aM _b(HO) ₂] use coprecipitation, to LiNiO ₂Mix, then at its surface graded coating one deck LiCoO ₂, this coating layer is that gradient coats, and can improve LiNiO greatly ₂The cycle performance of material.

Embodiment three: present embodiment is achieved in that a, adds in reaction vessel and contain Co ²⁺NiSO ₄Solution and NH ₃H ₂O and NaOH mixed solution reacted 2 hours～2 days, and wherein the pH value is 11.20 ± 0.05, temperature is 57 ± 0.5 ℃, NiSO ₄Solution concentration is 1.5mol/L; B, when the residue NiSO ₄The volume of solution is 10 of initial volume～40% o'clock, to residue NiSO ₄Solution adds 1.5mol/LMgSO gradually ₄Solution joins mixed solution in the reaction vessel simultaneously gradually, makes Ni (OH) ₂Grain surface forms the Mg (OH) that gradient coats ₂Layer reacted 3 hours～3 days; C, will be by surface graded coating Mg (OH) ₂Ni doped (OH) ₂With LiOH be Ni/Co: Li=(1.0～1.15) according to mol ratio: 1 mixed, grind well, sintering, grinding, obtain final products, the chemical formula of products obtained therefrom is: LiNi _1-a-bMg _aCo _bO ₂, wherein a=0～0.4, b=0～0.1.

Embodiment four: present embodiment is achieved in that a, adds in reaction vessel and contain Co ²⁺NiSO ₄Solution and NH ₃H ₂O and NaOH mixed solution reacted 2 hours～2 days, and wherein the pH value is 11.20 ± 0.05, temperature is 57 ± 0.5 ℃, NiSO ₄Solution concentration is 1.5mol/L; B, when the residue NiSO ₄The volume of solution is 10 of initial volume～40% o'clock, to residue NiSO ₄Solution adds 1.5mol/L Al gradually ₂(SO ₄) ₃Solution joins mixed solution in the reaction vessel simultaneously gradually, makes Ni (OH) ₂Grain surface forms the Al (OH) that gradient coats ₃Layer reacted 3 hours～3 days; C, will be by surface graded coating Al (OH) ₃Ni doped (OH) ₂With LiOH be Ni/Al: Li=(1.0～1.15) according to mol ratio: 1 mixed, grind well, sintering, obtain final products, the chemical formula of products obtained therefrom is: LiNi _1-a-bAl _aM _bO ₂, wherein a=0～0.4, b=0～0.1, M is Co ²⁺

Claims

1, a kind of gradient coats LiNiO ₂The preparation method of anode material for lithium-ion batteries is characterized in that it is achieved in that a, adds the NiSO that contains dopant ion in reaction vessel ₄Solution and NH ₃H ₂O and NaOH mixed solution reacted 2 hours～2 days, and wherein the pH value is 9.5～12.5, temperature is 40～70 ℃, NiSO ₄Solution concentration is 0.5～2.5mol/L; B, when the residue NiSO ₄The volume of solution is 10 of initial volume～40% o'clock, to residue NiSO ₄Solution adds 0.5～2.5mol/LX gradually ₂(SO ₄) _ySolution joins mixed solution in the reaction vessel simultaneously gradually, makes Ni (OH) ₂Grain surface forms the X (OH) that gradient coats _yLayer reacted 3 hours～3 days; C, will be by surface graded coating X (OH) _yNi doped (OH) ₂With LiOH be Ni/X: Li=(1.0～1.15) according to mol ratio: 1 mixed, grind well, sintering, grind again, obtain final products.

2, a kind of gradient according to claim 1 coats LiNiO ₂The preparation method of anode material for lithium-ion batteries is characterized in that described X is Co, Mg, Ti, Zr, Al or B.

3, a kind of gradient according to claim 1 coats LiNiO ₂The preparation method of anode material for lithium-ion batteries is characterized in that described dopant ion is Co ²⁺, Zn ²⁺, Mg ²⁺, Mn ²⁺, Al ³⁺And NH ⁺ ₄In one or more.

4, coat LiNiO according to claim 1 or 3 described a kind of gradients ₂The preparation method of anode material for lithium-ion batteries is characterized in that described dopant ion is Ni ²⁺1～40% of weight.