Preparation method of PdAg/TiO2 nanotube direct methanol fuel cell anode catalyst

A methanol fuel cell and nanotube technology, which is applied in physical/chemical process catalysts, battery electrodes, metal/metal oxide/metal hydroxide catalysts, etc., to improve the anti-CO poisoning ability and reduce costs.

Inactive Publication Date: 2012-12-26
NANTONG UNIVERSITY
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

As reported the preparation of PtRuTiO X / C and Au / TiO 2 PtRu catalyst, TiO 2 Combination can reduce the amount of noble metal Pt in the catalyst, improve catalytic performance and anti-CO poisoning ability, but TiO 2 Composite powder as an anode catalyst for direct methanol fuel cells has not been reported yet

Method used

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Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0022] A PdAg / TiO 2 The preparation method of nanotube direct methanol fuel cell anode catalyst comprises the following steps:

[0023] (1) TiO 2 Preparation of nanotubes: Dissolve butyl titanate in absolute ethanol, add dropwise a mixture of absolute ethanol, glacial acetic acid and deionized water under stirring, hydrolyze to form a sol, continue stirring, and let stand for 2-3 hours after forming a gel. Day, vacuum drying at 80°C for 8-10 hours, the obtained powder is ground and calcined in air at 400-600°C (for example, 400°C, 500°C, 600°C) in a muffle furnace for 3 hours to obtain TiO 2 Nano powder; the molar ratio of the above-mentioned butyl titanate, dehydrated alcohol, glacial acetic acid, and deionized water is: n 钛酸丁酯 :n 无水乙醇 :n 冰醋酸 :n 去离子水 =1:20~40:1~2.5:2~6 (eg 1:20:2:4, 1:30:1:6, 1:40:2.5:2); the prepared TiO 2 Add the nano powder into the reflux cooling device, add 10mol / L NaOH solution, stir, heat to 120-150°C, reflux for 24 hours, centrifuge, wash with d...

Embodiment 2

[0037] In step (4), according to the final synthesized catalyst W PdAg =3%, molar ratio n Pd :n Ag =1:1 ratio to measure PdCl 2 / Ethylene glycol solution; In step (12), according to the last synthesized catalyst W PdAg =3%, molar ratio n Pd :n Ag =1:1 ratio to measure AgNO 3 / ethylene glycol solution; all the other are with embodiment 1.

Embodiment 3

[0039] In step (4), according to the final synthesized catalyst W PdAg =5%, molar ratio n Pd :n Ag =1:1 ratio to measure PdCl 2 / Ethylene glycol solution; In step (12), according to the last synthesized catalyst W PdAg =5%, molar ratio n Pd :n Ag =1:1 ratio to measure AgNO 3 / ethylene glycol solution; all the other are with embodiment 1.

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PUM

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Abstract

The invention discloses a preparation method of a PdAg / TiO2 nanotube direct methanol fuel cell anode catalyst. The PdAg / TiO2 nanotube direct methanol fuel cell anode catalyst consists of a TiO2 nanotube and nano-PdAg. The method comprises the following steps of: preparing a TiO2 nanotube; and preparing a TiO2 nanotube dispersion liquid; preparing Pd / TiO2 and the like. The electric conductivity of TiO2 and the catalytic performance of TiO2 on methanol are enhanced through PdAg compounding, intermediate products such as CO and the like produced by methanol oxidation are adsorbed and transferred onto the surface of a composite catalyst and are directly oxidized into a final product, i.e., CO2 deeply, the price of PdAg is much lower than those of noble metals such as Pt, Ru and the like, and the using amount of PdAg in the catalyst is small, so that the catalytic oxidation performance of the catalyst on methanol can be enhanced greatly, the cost of the catalyst is reduced, and the CO poisoning resistance of the catalyst is enhanced.

Description

technical field [0001] The invention relates to a preparation method of an anode catalyst of a direct methanol fuel cell. Background technique [0002] Direct Methanol Fuel Cell (DMFC) has the advantages of low energy consumption, high energy density, abundant sources of methanol, low price, simple system, convenient operation and low noise, and is considered to be the most promising future vehicle power and other vehicles. Promising chemical power sources have attracted widespread attention. One of the most critical materials of DMFC is the electrode catalyst, which directly affects the performance, stability, service life and manufacturing cost of the battery. The noble metal Pt has excellent catalytic performance at low temperature (less than 80°C). At present, the electrode catalysts of DMFC all use Pt as the main component, and the PtRu catalyst has stronger CO poisoning resistance and higher catalytic activity than pure Pt. It is considered to be the best catalyst fo...

Claims

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Application Information

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IPC IPC(8): B01J23/50H01M4/88H01M4/90H01M4/92B82Y30/00
CPCY02E60/50
Inventor 朱昌来鞠剑峰汪冬庚章琴贺小琴张天一
Owner NANTONG UNIVERSITY
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