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Baozhu sand particles with size between 75 μm and 150 μm were coated by resin with the ratio of 1.5 wt.% of sands. Laser sintering experiments were carried out to investigate the effects of laser energy density(E = P/v), with different laser power(P) and scanning velocity(v), on the dimensional accuracy and tensile strength of sintered parts. The experimental results indicate that with the constant scanning velocity, the tensile strength of sintered samples increases with an increase in laser energy density; while the dimensional accuracy apparently decreases when the laser energy density is larger than 0.032 J·mm-2. When the laser energy density is 0.024 J·mm-2, the tensile strength shows no obvious change; but when the laser energy density is larger than 0.024 J·mm-2, the sample strength is featured by the initial increase and subsequent decrease with simultaneous increase of both laser power and scanning velocity. In this study, the optimal energy density range for laser sintering is 0.024-0.032 J·mm-2. Moreover, samples with the best tensile strength and dimensional accuracy can be obtained when P = 30-40 W and v = 1.5-2.0 m·s-1. Using the optimized laser energy density, laser power and scanning speed, a complex coated sand mould with clear contour and excellent forming accuracy has been successfully fabricated.
Baozhu sand particles with size between 75 μm and 150 μm were coated by resin with the ratio of 1.5 wt.% Of sands. Laser sintering experiments were carried out to investigate the effects of laser energy density (E = P / v), with different laser power (P) and scanning velocity (v), on the dimensional accuracy and tensile strength of sintered parts. The experimental results that with the constant scanning velocity, the tensile strength of sintered samples increases with an increase in laser energy density; while the dimensional accuracy apparently decreases when the laser energy density is larger than 0.032 J · mm-2. When the laser energy density is 0.024 J · mm-2, the tensile strength shows no obvious change; but when the laser energy density is larger than 0.024 J · mm-2, the sample strength is featured by the initial increase and the subsequent decrease with simultaneous increase of both laser power and scanning velocity. In this study, the optimal energy density range for laser sinter ing is 0.024-0.032 J · mm-2. Furthermore, samples with the best tensile strength and dimensional accuracy can be obtained when P = 30-40 W and v = 1.5-2.0 m · s-1. Using the optimized laser energy density , laser power and scanning speed, a complex coated sand mold with clear contour and excellent forming accuracy has been successfully fabricated.