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Micro-nano dual-stage porous copper and preparing method thereof

A nano-porous, micro-nano technology, applied in the field of porous metal preparation, can solve the problems of high precursor alloy structure requirements, no continuous ligaments formed by metal materials, complex preparation process, etc., and achieve controllable structure, simple method and high preparation process. short process effect

Inactive Publication Date: 2018-06-22
XIAN UNIV OF TECH
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

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Problems solved by technology

Chinese patent (publication number: 1068841909A) discloses a method of electrochemical oxidation or thermal oxidation in oxygen combined with electrochemical reduction to prepare hierarchical porous metal materials. The pore structure prepared by this method is composed of metal nanoparticles The formed primary pore aggregates are aggregated again and the secondary pore aggregates formed are connected to each other, but in essence, the two-level pore structure is formed by accumulation, and the metal material does not form a continuous ligament microscopically.
Chinese Patent (Publication No.: 105543531A) and Chinese Patent (Publication No.: 106591619A) respectively disclose methods for preparing two-stage porous copper materials by dealloying copper and aluminum alloys with NaOH and HCl. The organization requirements are high, and the preparation process is relatively complicated
However, the preparation of microporous metal materials by sintering and the preparation of nanoporous metal materials by dealloying have been developed to a relatively high degree in their respective fields, but the design of a material containing two pore structures of sintered micropores and dealloyed nanopores is scarce. There are reports

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  • Micro-nano dual-stage porous copper and preparing method thereof
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  • Micro-nano dual-stage porous copper and preparing method thereof

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preparation example Construction

[0025] The present invention also provides a method for preparing micro-nano dual-stage porous copper, comprising the following steps:

[0026] Step 1, mix Cu powder and Mn powder with a molar ratio of 4:6-5:5 evenly, press under 3-10MPa to form a billet, place it in a tube furnace and raise the temperature to 820-900°C under an argon atmosphere, and keep it warm for 4h Then cool down to room temperature with the furnace to obtain the precursor CuMn alloy;

[0027] In step 2, the precursor is placed in a 0.1 mol / L hydrochloric acid solution for dealloying until no obvious bubbles escape, and micro-nano dual-stage porous copper is prepared.

Embodiment 1

[0029] After mixing Cu powder and Mn powder with a molar ratio of 4:6 evenly, press it into a billet at 10 MPa, place it in a tube furnace under an argon atmosphere and raise the temperature to 820°C, keep it for 4 hours, and then cool it to room temperature with the furnace to obtain the precursor Cu 40 mn 60 Alloy; then place the precursor in 0.1mol / L hydrochloric acid solution for dealloying until no obvious bubbles escape, and prepare micro-nano dual-stage porous copper with an average pore diameter of 2.46um for micropores and 66nm for nanopores.

Embodiment 2

[0031] After mixing Cu powder and Mn powder with a molar ratio of 4:6 evenly, press it at 10 MPa to form a billet, place it in a tube furnace and raise the temperature to 840 °C under an argon atmosphere, keep it for 4 hours, and then cool it to room temperature with the furnace to obtain the precursor Cu 40 mn 60 Alloy; then place the precursor in a 0.1mol / L hydrochloric acid solution for dealloying until no obvious bubbles escape, and prepare micro-nano dual-stage porous copper, with an average pore diameter of micropores of 2.20um and an average pore diameter of nanopores of 64nm.

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Abstract

The invention discloses micro-nano dual-stage porous copper. The copper is characterized in that a sintered porous Cu framework serves as a base body, a bicontinuous nano porous structure is formed onthe framework, the average hole diameter of a micro hole ranges from 2.2 micrometers to 3.7 micrometers, the average hole diameter of a nano hole ranges from 60 nm to 113 nm. The preparing method comprises the specific steps that firstly, Cu powder and Mn powder with a certain proportion are evenly mixed and then are pressed into a blank, and are placed in an atmosphere tubular furnace to be subject to temperature rise to a certain temperature, heat preservation is carried out for a certain time, cooling to the room temperature is achieved, and a precursor CuMn alloy is obtained; secondly, the precursor is placed in hydrochloric acid to be subject to dealloying until no obvious bubbles are escaped, and the micro-nano dual-stage porous copper is prepared. The prepared micro-nano dual-stageporous copper has the uniform micro hole / nano hole composite hole structure, a three-dimensional bicontinuous tough belt / hole way structure and the like, the preparing process is short in flow, the method is simple, the structure is controllable, and the functionization production prospect is achieved.

Description

technical field [0001] The invention belongs to the technical field of porous metal preparation, and in particular relates to a micro-nano dual-stage porous copper; the invention also relates to a preparation method of the micro-nano dual-stage porous copper. Background technique [0002] Nanoporous metal materials have nanoscale pores and huge specific surface area, and their unique microstructure makes them have excellent physical and chemical properties, which can be applied in many fields such as catalysis, sensing and fuel cells. The precursor alloy is prepared by powder metallurgy, and the micron pores formed are conducive to the percolation and dealloying of corrosive liquid. The introduction of microporous structures can improve gas-liquid flow and ion exchange, which is expected to further enhance the catalytic sensing performance of nanoporous metals. Cu and Mn form a single solid solution phase after sintering, which is conducive to the formation of a uniform nan...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): B22F3/11
Inventor 杨卿马研孙少东梁淑华
Owner XIAN UNIV OF TECH
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