东北林业大学学报
東北林業大學學報
동북임업대학학보
JOURNAL OF NORTHEAST FORESTRY UNIVERSITY
2014年
11期
150-152,157
,共4页
张慧%郭艳玲%赵德金%于志祥
張慧%郭豔玲%趙德金%于誌祥
장혜%곽염령%조덕금%우지상
选择性激光烧结%木塑复合材料%松木粉/聚醚砜树脂复合粉末%力学性能%能量密度
選擇性激光燒結%木塑複閤材料%鬆木粉/聚醚砜樹脂複閤粉末%力學性能%能量密度
선택성격광소결%목소복합재료%송목분/취미풍수지복합분말%역학성능%능량밀도
Selective laser sintering%Wood plastic composite material%Pine/polyether sulfone composite powder%Mechanical properties%Energy density
以松木粉、聚醚砜树脂为材料,用SHR-10A型高速混合机制备松木粉/聚醚砜树脂复合粉末;用HRPS-ⅢA型激光粉末烧结快速成型机,遴选出复合粉末可用于选择性激光烧结工艺参数及适宜的预热温度,烧结成型。测量了不同松木粉质量比对复合粉末力学性能的影响,观察并测量了输入不同的能量密度时,烧结试件的成型效果和力学性能。结果表明:随着松木粉质量比的增加,木塑复合材料的力学性能降低。对于松木粉质量比为20%的木塑复合粉末,当输入的能量密度为0.128 J/mm3时,复合粉末即可成型;当输入的能量密度为0.312 J/mm3时,木塑复合材料的拉伸强度达到4.8465 MPa,弯曲强度为8.2152 MPa,冲击强度为1.2574 MPa,此时力学性能最强;若输入的能量密度大于0.312 J/mm3时,出现过烧现象,力学性能下降。采用扫描电镜对烧结件断面的形貌进行了表征。
以鬆木粉、聚醚砜樹脂為材料,用SHR-10A型高速混閤機製備鬆木粉/聚醚砜樹脂複閤粉末;用HRPS-ⅢA型激光粉末燒結快速成型機,遴選齣複閤粉末可用于選擇性激光燒結工藝參數及適宜的預熱溫度,燒結成型。測量瞭不同鬆木粉質量比對複閤粉末力學性能的影響,觀察併測量瞭輸入不同的能量密度時,燒結試件的成型效果和力學性能。結果錶明:隨著鬆木粉質量比的增加,木塑複閤材料的力學性能降低。對于鬆木粉質量比為20%的木塑複閤粉末,噹輸入的能量密度為0.128 J/mm3時,複閤粉末即可成型;噹輸入的能量密度為0.312 J/mm3時,木塑複閤材料的拉伸彊度達到4.8465 MPa,彎麯彊度為8.2152 MPa,遲擊彊度為1.2574 MPa,此時力學性能最彊;若輸入的能量密度大于0.312 J/mm3時,齣現過燒現象,力學性能下降。採用掃描電鏡對燒結件斷麵的形貌進行瞭錶徵。
이송목분、취미풍수지위재료,용SHR-10A형고속혼합궤제비송목분/취미풍수지복합분말;용HRPS-ⅢA형격광분말소결쾌속성형궤,린선출복합분말가용우선택성격광소결공예삼수급괄의적예열온도,소결성형。측량료불동송목분질량비대복합분말역학성능적영향,관찰병측량료수입불동적능량밀도시,소결시건적성형효과화역학성능。결과표명:수착송목분질량비적증가,목소복합재료적역학성능강저。대우송목분질량비위20%적목소복합분말,당수입적능량밀도위0.128 J/mm3시,복합분말즉가성형;당수입적능량밀도위0.312 J/mm3시,목소복합재료적랍신강도체도4.8465 MPa,만곡강도위8.2152 MPa,충격강도위1.2574 MPa,차시역학성능최강;약수입적능량밀도대우0.312 J/mm3시,출현과소현상,역학성능하강。채용소묘전경대소결건단면적형모진행료표정。
We developed pine/polyether sulfone composite powder ( PES) by SHR-10A high-speed mixer for selective laser sin-tering ( SLS) .The mechanical properties of wood plastic composite were reinforced with the increase of mass ratio of PES. We observed and tested deforming effect of sintered parts and the influence on the mechanical properties while putting in different energy density.The experiment showed that pine/PES wood composite could be shaped up when the energy densi-ty was 0.128 J/mm3 , when it reached 0.312 J/mm3 , the tensile strength of the material was 4.846 5 MPa, the bending strength was 8.215 2 MPa, the impact strength was 1.257 4 MPa, and the mechanical properties were the strongest.When the energy density was greater than 0.312 J/mm3 , pine would be carbonized during the process of sintering, therefore, the mechanical properties decreased.At last, we observed the section topography of sintered parts by scanning electron micros-copy ( SEM) .
