Multielement-reinforced heat-resistant magnesium alloy and manufacturing method thereof

A manufacturing method and technology for magnesium alloys, applied in the field of magnesium alloys, can solve the problems of weakening the impurity removal and purification of rare earth elements, limiting the potential of magnesium alloy materials, affecting the quality of rare earth magnesium alloys, etc., so as to avoid crystallization temperature interval and improve high temperature corrosion resistance. , Improve the effect of room temperature mechanical properties

Active Publication Date: 2014-11-26
YANGZHOU FENG MING METAL PROD
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

[0004] In addition, the high content of inclusions and gases in magnesium alloys limits the potential of magnesium alloy materials.
The traditional flux refining process is easy to produce flux inclusions, which is easy to corrode equipment and pollute the environment at high temperature, and the magnesium chloride in the flux can react with rare earth elements, resulting in the loss of expensive rare earths, weakening the impurity removal and purification of rare earth elements, and the ability to refine grains effect, affecting the quality of rare earth magnesium alloys

Method used

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  • Multielement-reinforced heat-resistant magnesium alloy and manufacturing method thereof
  • Multielement-reinforced heat-resistant magnesium alloy and manufacturing method thereof

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Embodiment 1

[0020] The manufacturing method of the multi-component reinforced heat-resistant magnesium alloy of the present invention comprises the following steps in sequence:

[0021] ⑴ Prepare the ingredients required for the preparation of heat-resistant magnesium alloys, including pure magnesium ingots, pure aluminum ingots, pure zinc ingots, aluminum-manganese alloys, aluminum-silver alloys, magnesium-silicon alloys, magnesium-yttrium alloys, magnesium-cerium alloys, magnesium-neodymium alloys, magnesium Calcium alloy, magnesium strontium alloy and boron carbide particles, the weight ratio between the above elements is as follows, magnesium: 1000 parts; aluminum: 65 parts; zinc: 5 parts; yttrium: 10 parts; manganese: 1.5 parts; neodymium: 5 parts ; cerium: 3 parts; calcium: 1 part; strontium: 0.4 parts; silicon: 0.1 parts; silver: 3 parts;

[0022] (2) Pretreatment of boron carbide particles: Soak the boron carbide particles in 10% by weight HCl aqueous solution for 30 minutes, then...

Embodiment 2

[0032] ⑴ Prepare the ingredients required for the preparation of heat-resistant magnesium alloys, including pure magnesium ingots, pure aluminum ingots, pure zinc ingots, aluminum-manganese alloys, aluminum-silver alloys, magnesium-silicon alloys, magnesium-yttrium alloys, magnesium-cerium alloys, magnesium-neodymium alloys, magnesium Calcium alloy, magnesium strontium alloy and boron carbide particles, the weight ratio between the above elements is as follows, magnesium: 1000 parts; aluminum: 75 parts; zinc: 7 parts; yttrium: 20 parts; manganese: 3 parts; neodymium: 10 parts ; Cerium: 6 parts; Calcium: 3 parts; Strontium: 0.7 parts; Silicon: 0.3 parts; Silver: 5 parts;

[0033] (2) Pretreatment of boron carbide particles: Soak the boron carbide particles in 10% by weight HCl aqueous solution for 35 minutes, then rinse repeatedly with distilled water until the pH value of the aqueous solution is 7.0, and let it stand to filter off the excess water in the upper part. Dry in an ...

Embodiment 3

[0043] The manufacturing method of the multi-component reinforced heat-resistant magnesium alloy of the present invention comprises the following steps in sequence:

[0044] ⑴ Prepare the ingredients required for the preparation of heat-resistant magnesium alloys, including pure magnesium ingots, pure aluminum ingots, pure zinc ingots, aluminum-manganese alloys, aluminum-silver alloys, magnesium-silicon alloys, magnesium-yttrium alloys, magnesium-cerium alloys, magnesium-neodymium alloys, magnesium Calcium alloy, magnesium strontium alloy and boron carbide particles, the weight ratio between the above elements is as follows, magnesium: 1000 parts; aluminum: 85 parts; zinc: 8 parts; yttrium: 30 parts; manganese: 5 parts; neodymium: 15 parts ; Cerium: 8 parts; Calcium: 4 parts; Strontium: 1 part; Silicon: 0.5 parts; Silver: 6 parts;

[0045](2) Pretreatment of boron carbide particles: Soak the boron carbide particles in 10% by weight HCl aqueous solution for 40 minutes, then rin...

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Abstract

The invention discloses a multielement-reinforced heat-resistant magnesium alloy and a manufacturing method thereof. The multielement-reinforced heat-resistant magnesium alloy is prepared from the following raw materials in parts by weight: 1000 parts of magnesium, 65-85 parts of aluminum, 5-8 parts of zinc, 10-30 parts of yttrium, 1.5-5 parts of manganese, 5-15 parts of neodymium, 3-4 parts of cerium, 1-4 parts of calcium, 0.4-1 part of strontium, 0.1-0.5 part of silicon, 3-6 parts of silver and 10-40 parts of boron carbide. The manufacturing method comprises the following steps: carrying out acid washing, drying and preoxidation on the boron carbide, preheating the materials, smelting the magnesium and aluminum while introducing protective gas, adding an aluminum-manganese alloy and a pure zinc ingot to carry out alloying, adding an aluminum-silver alloy, a magnesium-silicon alloy, a magnesium-yttrium alloy, a magnesium-cerium alloy, a magnesium-neodymium alloy, a magnesium-calcium alloy and a magnesium-strontium alloy, smelting, adding the boron carbide particles for reinforcement, carrying out gas refinement on the melt by using argon, carrying out extrusion casting, and finally, carrying out solid solution aging treatment to obtain the heat-resistant magnesium alloy finished product. The magnesium alloy has excellent comprehensive properties under high-temperature conditions.

Description

technical field [0001] The invention relates to a magnesium alloy, in particular to a multi-component reinforced heat-resistant magnesium alloy. The invention also relates to a manufacturing method of the multi-component reinforced heat-resistant magnesium alloy. Background technique [0002] Magnesium alloys have attracted much attention because of their light weight. Magnesium alloys also have high dimensional stability, damping and shock absorption performance, electromagnetic shielding performance, excellent casting and cutting performance, and easy recycling and regeneration. They are widely used in automobiles. , electronic communications, aerospace and national defense military and other fields have broad application prospects. Among them, the Mg-Al-Zn series magnesium alloy has excellent mechanical properties, good fluidity, low thermal cracking tendency, relatively simple casting process, and low cost, and has become a hot spot in the field of magnesium alloy resea...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): C22C23/02C22C1/03C22C1/06B22D18/02C22F1/06
Inventor 眭怀明赵宇宏王养云蔡鑫梅王堃
Owner YANGZHOU FENG MING METAL PROD
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