Mg-xSm-0.3Zn散热镁合金压铸工艺数值模拟

何伟; 胡文鑫; 李媛; 刘峰

doi:10.15980/j.tzzz.2022.04.007

研究·计算机应用 | 浏览量 : 0 下载量: 51 CSCD: 0

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Mg-xSm-0.3Zn散热镁合金压铸工艺数值模拟
Numerical Simulation of Die Casting Process for Mg-xSm-0.3Zn Magnesium Alloys
2022年42卷第4期页码：428-436
纸质出版日期： 2022 ，
DOI： 10.15980/j.tzzz.2022.04.007

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何伟, 胡文鑫, 李媛, 等. Mg-xSm-0.3Zn散热镁合金压铸工艺数值模拟[J]. 特种铸造及有色合金, 2022,42(4):428-436.

He Wei, Hu Wenxin, Li Yuan, et al. Numerical Simulation of Die Casting Process for Mg-xSm-0.3Zn Magnesium Alloys[J]. Special Casting & Nonferrous Alloys, 2022,42(4):428-436.
何伟, 胡文鑫, 李媛, 等. Mg-xSm-0.3Zn散热镁合金压铸工艺数值模拟[J]. 特种铸造及有色合金, 2022,42(4):428-436. DOI： 10.15980/j.tzzz.2022.04.007.

He Wei, Hu Wenxin, Li Yuan, et al. Numerical Simulation of Die Casting Process for Mg-xSm-0.3Zn Magnesium Alloys[J]. Special Casting & Nonferrous Alloys, 2022,42(4):428-436. DOI： 10.15980/j.tzzz.2022.04.007.

摘要

利用ProCAST软件对Mg-xSm-0.3Zn系列镁合金进行压铸过程模拟计算，设置初始压力为0.2 MPa

增压比压为40 MPa

模具温度为200～280℃、浇注温度为680～740℃、压射速度为1.5～6.0 m/s

研究模具温度、浇注温度、压射速度、合金成分对含稀土镁合金压铸过程的影响。结果表明，模具温度、浇注温度适当降低可以改善铸件的缩孔、缩松，且模具温度对合金的充型过程影响更大；压射速度适当提高可以使铸件更好地进行补缩，但压射速度太高会降低模具使用寿命；Sm含量为0.8%时，充型过程最为平稳，充型及完全凝固所需时间最短，并且随着Sm含量增加，合金的固、液相温差由70℃降低到46℃

铸件缩孔、缩松缺陷得到改善。

Abstract

The ProCAST software was used to simulate the die-casting process of Mg-xSm-0.3 Zn series magnesium alloy. The initial parameters

such as pressure

specific pressure

mold temperature casting temperature and injection rate were set as 0.2 MPa

40 MPa

200～280 ℃

680～740 ℃ and 1.5～6.0 m/s

respectively

to understand the effects of these parameters on the die-casting process of rare earth magnesium alloy. The results indicate that the distribution of shrinkage porosity can be improved when the mold temperature and casting temperature are appropriately low

and the difference of mold temperature has a more obvious effect on the filling process of alloy. Proper increase in injection speed can make the casting better feeding

however should not be too high in order to reduce the service life of the metal mold. When the content of rare earth is 0.8%

the filling process is the most stable

and the time needed for filling and complete solidification reaches the peak. With the increase of rare earth content

the temperature difference between solid and liquid is decreased from 70 ℃ to 46 ℃

and the shrinkage cavity and porosity of the castings are effectively improved.