A preparation method of carbon-coated sn-co/graphene microsphere negative electrode material for lithium ion battery

A technology of lithium-ion batteries and negative electrode materials, applied in battery electrodes, nanotechnology for materials and surface science, circuits, etc., can solve the problems of lithium storage capacity, coulombic efficiency, high filling density, etc., and achieve excellent conductivity and high volume The effect of increasing the specific capacity and filling density

Active Publication Date: 2017-01-04
江苏嘉明碳素新材料有限公司
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Problems solved by technology

However, so far, people have not invented a lithium-ion battery anode material based on Sn-Co alloy that can simultaneously have high lithium storage capacity, high Coulombic efficiency, long cycle life and high filling density.

Method used

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  • A preparation method of carbon-coated sn-co/graphene microsphere negative electrode material for lithium ion battery

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preparation example Construction

[0027] The preparation method of graphene in the embodiment is: get the concentrated H of 18~25mL98% 2 SO 4 Add 1-1.5 g of natural flake graphite with a particle size of 10-30 μm and 3-4 g of KMnO into a reactor placed in an ice bath 4 Add it into the reactor, stir at 30-80rpm for 30-60min; then move the above-mentioned reactor into a warm water bath at 40±2°C and continue stirring for 30-60min; then raise the temperature of the reaction solution to 98±2°C, add 70 ~100mL deionized water and continue to stir for 30~60min; then add 8~15mL of 5% H 2 o 2 Mix well, filter while hot, wash the filter residue with HCl with a mass fraction of 5%, until there is no SO in the filtrate 4 2- (with BaC1 2 Solution detection), then fully washed with deionized water until neutral, filtered to obtain graphite oxide; then add 400-500mL deionized water to graphite oxide, ultrasonically treat at 60kHz for 60-90min at 80-90°C, and then use 3000 Centrifuge at ~4000rpm for 5~10min; take the su...

Embodiment 1

[0031] 1. Preparation of nano-intermediate: 26.07g of SnCl 4 and 16.79 g of CoSO 4 Add 1286mL deionized water, fully dissolve, then add 92.7mg graphene and 25.7g sodium dodecyl sulfate, ultrasonically disperse for 5min, then add 1mol / L NaBH 4 Ethanol solution 925mL, reacted for 20min, deposited Sn-Co nano-alloy on the surface of graphene, filtered the reaction solution, washed and dried the solid matter, and obtained the nano-intermediate;

[0032] 2. Preparation of composite microsphere intermediate: add 15mL of deionized water to every 10g of the nano-intermediate prepared in step 1, stir evenly, then add 3g of starch to each 10g of nano-intermediate, stir to form a slurry, and use The granulation is carried out by spray drying granulation method, the inlet temperature is 110°C, the outlet temperature is 80°C, the spray pressure is 0.5MPa, and the nozzle diameter is 0.7mm to obtain the composite microsphere intermediate;

[0033] 3. Preparation of carbon-coated composite m...

Embodiment 2

[0037] 1. Preparation of nano-intermediate: 42.94g of SnSO 4 and 33.58 g of CoSO 4 Add 1377mL deionized water, fully dissolve, then add 6.09g graphene and 48.2g sodium dodecyl sulfate, ultrasonically disperse for 10min, then add 0.5mol / L KBH 4 2467mL aqueous solution, react for 10min, deposit Sn-Co nano-alloy on the surface of graphene, filter the reaction solution, wash and dry the solid matter, and obtain the nano-intermediate;

[0038] 2. Preparation of composite microsphere intermediate: add 5mL of deionized water to every 10g of the nano-intermediate prepared in step 1, stir evenly, then add 1g of polyvinyl alcohol to every 10g of nano-intermediate, and stir to form a slurry , using the spray drying granulation method to granulate, the inlet temperature is 140°C, the outlet temperature is 87°C, the spray pressure is 1.5MPa, and the nozzle diameter is 0.5mm, to obtain a composite microsphere intermediate;

[0039] 3. Preparation of carbon-coated composite microspheres: A...

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Abstract

In view of the fact that there is no lithium-ion battery negative electrode material based on Sn-Co alloy that can simultaneously have high lithium storage capacity, high Coulombic efficiency, long cycle life and high filling density in the prior art, the present invention provides a lithium-ion battery carbon pack The invention discloses a preparation method of a Sn-Co alloy / graphene composite microsphere negative electrode material, which belongs to the field of lithium ion battery negative electrode materials. In this method, the Sn-Co nano-alloy is deposited on the surface of graphene by a wet method, and then the nano-intermediate is granulated by the spray-drying method, and then the composite microsphere intermediate is coated with pitch, and finally heated and carbonized. Carbon-coated Sn-Co alloy / graphene composite microsphere negative electrode material, the preparation process of this method is simple and suitable for large-scale industrial production; the carbon-coated Sn-Co alloy / graphene microsphere negative electrode material prepared by this method can store lithium High capacity, high coulombic efficiency, long cycle life, high filling density.

Description

technical field [0001] The invention belongs to the field of negative electrode materials for lithium ion batteries, in particular to a preparation method for carbon-coated Sn-Co / graphene microsphere negative electrode materials for lithium ion batteries. Background technique [0002] In recent years, with the development of electronic information technology, multimedia functions have increased, mobile phone 4G communication functions have been promoted, and the driving distance of electric vehicles on a single charge has been extended. Therefore, existing lithium-ion batteries are increasingly unable to meet people's increasing demand for capacity. Anode materials are one of the key factors affecting the capacity of lithium-ion batteries. At present, graphite anode materials widely used have the advantages of high charge and discharge efficiency and good cycle performance, but the theoretical lithium storage capacity is low, with a mass specific capacity of 372mAh / g and a ...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): H01M4/38H01M4/62B82Y30/00
Inventor 沈丁杨绍斌董伟王晓亮李思南孟阳
Owner 江苏嘉明碳素新材料有限公司
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