以两个成形齿轮作为辊压模具,用与瓦楞板外轮廓参数完全相同的齿形模具作为校形模,采用辊压/校形复合工艺制备了钛合金蜂窝瓦楞板;运用 Ansys/Ls-Dyna软件对瓦楞板的成形过程进行有限元模拟,探讨了上下成形齿轮间隙与成形质量的关系,得到了优化工艺,并用试验对成形工艺进行了验证.结果表明:用辊压/校形复合工艺制备高精度钛合金瓦楞板是可行的,瓦楞板尺寸的最大误差仅为1.8%;辊压成形时齿轮的最大间隙值是影响瓦楞板成形精度的关键参数之一,当最大间隙值为0.2 mm、校形压力为3000 MPa、校形时间为30 s 时,瓦楞板的成形质量最好;采用可调式箱体来控制成形齿轮的平行度及最大间隙值,可有效降低对辊压装置的加工及装配精度要求.
Two forming gears were used for roll mold and another tooth profile mould which is exactly the same as that of corrugated sheet in design parameters was used for sizing.Titanium alloy corrugated sheet was manufactured by the composited process of roll forming and sizing.Through Ansys/Ls-Dyna software,finite element modeling of the forming process was performed to analyze the relationship between gear clearance and quality of corrugated sheet.And then,the experimentation was carried out to validate reliability of the composited process.The results show that,it was feasible to fabricate the corrugated sheet with high precision by this composited process,the maximum value of dimension error was only 1 .8%.Furthermore,maximum value of gear clearance were one of the key factors affecting the quality of corrugated sheet,the optimized values were maximum value of gear clearance of 0.2 mm,sizing stress of 3 000 MPa and sizing time of 30 s.It′s also found that it can highly reduce the accuracy requirement of manufacturing and assembly by using adj ustable body to control parallelism and maximum value of gear clearance.
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