农业工程学报
農業工程學報
농업공정학보
2013年
5期
25-30
,共6页
谢晨%何雄奎%宋坚利 %Andreas.Herbst
謝晨%何雄奎%宋堅利 %Andreas.Herbst
사신%하웅규%송견리 %Andreas.Herbst
喷头%雾化%可视化%液膜%植保
噴頭%霧化%可視化%液膜%植保
분두%무화%가시화%액막%식보
spraying%comminution%visualization%liquid film%crop protection
为了探究标准扇形雾喷头(ST)与防飘喷头(IDK)的雾化特性,利用雾滴粒径分析仪(PDIA)对以上2种类型喷头的雾化过程进行了试验研究与可视化图形分析.结果表明:ST喷头具有面积较大的液膜区,且具有波纹结构,破裂区内的破裂孔洞呈现不规则撕裂状;IDK 喷头液膜区面积较 ST 喷头小,具有气泡状结构,但并未发现波纹区.随着ST与IDK喷头孔径的增大,液膜长度、破裂区长度分别由20 mm增长至40 mm、10 mm增长至20 mm.随着压力的增加,ST110-03型喷头的液膜长度由35 mm降低至22 mm,雾滴体积中径由128.2μm降低至92.4μm;IDK120-03型喷头的液膜-破裂区长度由40 mm降低至30 mm,雾滴体积中径由366.4μm降低至285.3μm.该研究可为进一步研究新型防飘喷头的雾化特性以及新型喷雾设备的生产提供参考.
為瞭探究標準扇形霧噴頭(ST)與防飄噴頭(IDK)的霧化特性,利用霧滴粒徑分析儀(PDIA)對以上2種類型噴頭的霧化過程進行瞭試驗研究與可視化圖形分析.結果錶明:ST噴頭具有麵積較大的液膜區,且具有波紋結構,破裂區內的破裂孔洞呈現不規則撕裂狀;IDK 噴頭液膜區麵積較 ST 噴頭小,具有氣泡狀結構,但併未髮現波紋區.隨著ST與IDK噴頭孔徑的增大,液膜長度、破裂區長度分彆由20 mm增長至40 mm、10 mm增長至20 mm.隨著壓力的增加,ST110-03型噴頭的液膜長度由35 mm降低至22 mm,霧滴體積中徑由128.2μm降低至92.4μm;IDK120-03型噴頭的液膜-破裂區長度由40 mm降低至30 mm,霧滴體積中徑由366.4μm降低至285.3μm.該研究可為進一步研究新型防飄噴頭的霧化特性以及新型噴霧設備的生產提供參攷.
위료탐구표준선형무분두(ST)여방표분두(IDK)적무화특성,이용무적립경분석의(PDIA)대이상2충류형분두적무화과정진행료시험연구여가시화도형분석.결과표명:ST분두구유면적교대적액막구,차구유파문결구,파렬구내적파렬공동정현불규칙시렬상;IDK 분두액막구면적교 ST 분두소,구유기포상결구,단병미발현파문구.수착ST여IDK분두공경적증대,액막장도、파렬구장도분별유20 mm증장지40 mm、10 mm증장지20 mm.수착압력적증가,ST110-03형분두적액막장도유35 mm강저지22 mm,무적체적중경유128.2μm강저지92.4μm;IDK120-03형분두적액막-파렬구장도유40 mm강저지30 mm,무적체적중경유366.4μm강저지285.3μm.해연구가위진일보연구신형방표분두적무화특성이급신형분무설비적생산제공삼고.
The objectives of this research were to study the atomization characteristics of normal flat fan nozzles and air induction flat fan nozzles which were made by the LECHLER Company by a particle droplet image analysis system (PDIA) with visualized features. Images of ST110-03 and IDK120-03 nozzles’spraying fan from orifice to 30 mm below nozzle were taken at 0.3 MPa to observe the structure of the spraying fan. Spraying visualizations were conduct from 10 to 70 mm with the interval of 10 mm below the nozzle in the spraying fan centerline of ST110-01、02、03、04 and IDK120-01、02、03、04 at 0.3 MPa to analyze the influence of orifice width on spraying sheet length. To research the influence of spraying pressure on liquid sheet length and droplet size, spraying visualizations were performed from 10 to 70mm with the interval 10mm below the nozzle in the spraying fan centerline of ST110-03 and IDK120-03 at 0.2、0.3、0.4、0.5、0.6 MPa. The results showed that there was a larger liquid sheet in the ST110-03 spraying fan. It was very easy to observe the wave formation and irregular atomization holes in the ST110-03 spraying fan. There was a smaller spraying sheet in the IDK120-03 spraying fan than in the ST110-03. There were many bubbles in the spraying sheet of the IDK120-03. The data showed that the spraying sheet length of the ST110-03 was increased from 20 to 40 mm and the atomization length of the IDK120-03 was increased from 10 to 20 mm, and also resulted in increasing intensity of bubbles with the orifice width increasing. The liquid sheet length of the ST110-03 was decreased from 35 to 22 mm and the droplets volume mean diameter was decreased from 128.2 to 92.4 μm. Also, the wave’s amplitude was increased by increasing the spray pressure. The liquid sheet-atomization length of the IDK120-03 was decreased from 40 to 30 mm and the droplets volume mean diameter was decreased from 366.4 to 285.3μm with increased spray pressure. The conclusion of the research was that there are huge differences between the spraying sheet and atomization region of IDK and ST nozzles. The air bubble existed in the liquid sheet of the IDK, and the liquid sheet length showed negative correlation with the droplets volume mean diameter.