Ceramic Filter Cff is widely used in the production of large aluminum processing enterprises in Russia, the Middle East and Southeast Asia.
During use, it is not only necessary to remove the aluminum melt inclusions, but also to avoid the blockage of the Ceramic Filter Cff and improve the service life of the ceramic foam filter.
The melt is not filtered, which contains a large number of inclusions of different sizes. The coarse inclusions often form micropores first, which promotes the propagation of cracks, so the performance of the alloy is reduced.
If the melt is filtered, the inclusions in the alloy will decrease, the average spacing will increase, and the plastic zone at the crack tip will expand, which will lead to an increase in the resistance to crack propagation, which ultimately manifests as the performance of the alloy.
The filtering principle of Ceramic Filter Cff
The filtering of aluminum alloy melt includes surface filtering and internal filtering.
Surface filtration means that solid impurities are mainly deposited on the surface of the filter medium.
Internal filtration means that the molten aluminum carries inclusions in the Foam Ceramic Filter media along the tortuous channels and pores, which are directly intercepted, adsorbed, deposited, etc., collide with the pore wall and firmly adhere to the pore wall.
As the filtration progresses, the effective filtration section of the pores gradually decreases, the permeability decreases, and the filtration accuracy improves.
Ceramic Filter Cff and deep bed filtration belong to internal filtration, while tubular filtration belongs to dual capture of impurities on the surface and inside.
When the aluminum alloy melt is not filtered, a large number of inclusions will increase the viscosity of the aluminum alloy liquid and reduce the fluidity. During solidification, the interdendritic feeding channel is easily blocked, forming microscopic shrinkage and porosity.
At the same time, these impurity spots will also adsorb bubbles, form pores in the sample, become the source of microcracks, and reduce the performance of the alloy.
In addition, because the inclusions are mostly distributed in the grain boundaries after the alloy is solidified, the interface bonding force between the grains is reduced, resulting in intergranular fracture after the sample is stressed, which can be observed from the oxide film of the dendritic adhesion on the fracture Or inclusions can be confirmed.