农业工程学报
農業工程學報
농업공정학보
Transactions of the Chinese Society of Agricultural Engineering
2015年
20期
34-40
,共7页
害虫防治%微结构%晶体%仿生设计%捕集滑板%猪笼草%月骨体%附着力测试
害蟲防治%微結構%晶體%倣生設計%捕集滑闆%豬籠草%月骨體%附著力測試
해충방치%미결구%정체%방생설계%포집활판%저롱초%월골체%부착력측시
pest control%micro-structure%crystal%biomimetic design%slippery trapping plate%Nepenthes pitcher%slippery zone%attachment force measurement
致灾农业昆虫光电诱导滑移捕集技术中,致使昆虫产生良好滑移行为的捕集滑板是获取该技术高效应用的关键.红瓶猪笼草(Nepenthes alata)叶笼滑移区依靠特殊形貌对昆虫附着系统表现出显著滑移功能,为致灾农业昆虫捕集滑板的研制提供了仿生原型.采用扫描电子显微镜(scanning electron microscope, SEM)与三维白光形貌干涉仪(scanning white light interferometer, SWLI)对滑移区表面微形貌进行观测分析并获取三维结构参数,据此构建了致灾农业昆虫捕集滑板表面结构的仿生模型;采用激光微纳加工技术和高压静电吸附技术实现捕集滑板的仿生制备.为验证仿生制备致灾农业昆虫捕集滑板功效,测试了蝗虫(Locusta migratoria manilensis)在捕集滑板和仿生原型的附着力,结果分别为(402.9±26.1)mN和(361.9±25.5)mN,相近的附着力预示研制的致灾农业昆虫捕集滑板具有与仿生原型类似的性能.
緻災農業昆蟲光電誘導滑移捕集技術中,緻使昆蟲產生良好滑移行為的捕集滑闆是穫取該技術高效應用的關鍵.紅瓶豬籠草(Nepenthes alata)葉籠滑移區依靠特殊形貌對昆蟲附著繫統錶現齣顯著滑移功能,為緻災農業昆蟲捕集滑闆的研製提供瞭倣生原型.採用掃描電子顯微鏡(scanning electron microscope, SEM)與三維白光形貌榦涉儀(scanning white light interferometer, SWLI)對滑移區錶麵微形貌進行觀測分析併穫取三維結構參數,據此構建瞭緻災農業昆蟲捕集滑闆錶麵結構的倣生模型;採用激光微納加工技術和高壓靜電吸附技術實現捕集滑闆的倣生製備.為驗證倣生製備緻災農業昆蟲捕集滑闆功效,測試瞭蝗蟲(Locusta migratoria manilensis)在捕集滑闆和倣生原型的附著力,結果分彆為(402.9±26.1)mN和(361.9±25.5)mN,相近的附著力預示研製的緻災農業昆蟲捕集滑闆具有與倣生原型類似的性能.
치재농업곤충광전유도활이포집기술중,치사곤충산생량호활이행위적포집활판시획취해기술고효응용적관건.홍병저롱초(Nepenthes alata)협롱활이구의고특수형모대곤충부착계통표현출현저활이공능,위치재농업곤충포집활판적연제제공료방생원형.채용소묘전자현미경(scanning electron microscope, SEM)여삼유백광형모간섭의(scanning white light interferometer, SWLI)대활이구표면미형모진행관측분석병획취삼유결구삼수,거차구건료치재농업곤충포집활판표면결구적방생모형;채용격광미납가공기술화고압정전흡부기술실현포집활판적방생제비.위험증방생제비치재농업곤충포집활판공효,측시료황충(Locusta migratoria manilensis)재포집활판화방생원형적부착력,결과분별위(402.9±26.1)mN화(361.9±25.5)mN,상근적부착력예시연제적치재농업곤충포집활판구유여방생원형유사적성능.
The technology of photoelectric inducing-trapping can kill agricultural insect (locust, ant, etc.) and protect the agricultural production from being destroyed effectively, and avoid the environment pollution caused by spraying pesticide. The key factor of this technology is to develop a kind of slippery trapping plate which can restrict insects' excellent attachment ability generated by rigid claw and adhesive pad. To obtain structural information for biomimetic developing the slippery trapping plate, surface morphology of bionic prototype (slippery zone ofNepenthes alata pitcher) was detailedly examined in August and September of 2013. Several sections (1 cm2) were cut from the slippery surface and rinsed in distilled water before being air-dried, then mounted on aluminum blocks and sputter coated, and observed with a scanning electron microscope (SEM). Fresh sample (2 cm2) was cut from slippery surface and glued to an aluminum block, and examined with a scanning white-light interferometer (SWLI). The structural parameters of slippery surface were statistically acquired via analyzing the saved images with the software belonging to the SEM and SWLI equipment. The results showed that the slippery surface is covered by a layer of dense and irregular wax crystals, along with numerous downward-directed lunate cells. Length and thickness of the platelet-shaped wax crystals was 1 109.6±68.5 nm and 89.11±5.17 nm, respectively; the height and interval distance of the lunate cells was 20.41± 1.73μm and 71.53±3.86μm, respectively; the angles of the lunate cell's slope and precipice was 23.1±2.4° and 76.1±4.0°, respectively. These obtained parameters suggested that the slippery zone bears micro-nano scaled surface architectures. Based on acquired structural parameters, biomimetic model of the slippery trapping plate was designed with CAXA software. The biomimetic model consisted of a substrate and an epicuticular layer, the substrate was covered by micro-scaled triangular prisms (simplified lunate cells) and numerous blind holes, and the epicuticular layer was composed of massive flaky graphite (simplified wax coverings) possessing the physical properties of lubrication and slippage. To prepare the slippery trapping plate, laser micro-fabrication technology was adopted to machine the micro-scaled architectures (triangular prisms and blind holes) of the substrate (alloy steel, 100 mm×50 mm×5 mm, length×width×thickness), and high voltage electrostatic incorporation technology was used to attach the flaky graphite (mesh number 1 500-2 000, dimension 6.5-10μm) to the machined substrate. The flaky graphite was put on an organic glass box (95 mm×45 mm×30 mm, length×width×height); and put the laser-machined substrate and an alloy plate on the top and bottom of the box, respectively. The positive and negative electrode of high voltage electrostatic source was respectively connected to the substrate and alloy plate, and applied high voltage electrostatic (16.0-18.0 KV) for 100-120 s. With the incorporation of the high voltage electrostatic, the flaky graphite was absorbed to the blind holes of substrate and attached tightly. To test the function of the biomimetic slippery trapping plate, attachment forces of adult locust (Locusta migratoria manilensis) were measured with an insect micro-force measurement system in July 2015. The system mainly consisted of a force transducer (1-PW4C3), a signal conditioning module (SCXI-1520), a data acquisition platform (PCI-6221), and data-processing & displaying software. The locust was connected to the force transducer (along load direction) using a thin thread (12 cm long) fastened its neck position, and then put on the tested surface. The locust climbed on the tested surface along the load direction of the force transducer. When the thin thread started to pull, the locust crawled ahead frantically to attempt to break away from this restriction, so generated attachment forces and their maximal values were recorded. The results showed that values of attachment force provided by locust on bionic slippery trapping plate ranged from 328.7 mN to 458.3 mN, whereas on slippery surface ranged from 307.3 mN to 397.1 mN. Attachment force of locust on bionic slippery trapping plate (402.9±26.1 mN) was barely 1.1 times than that on slippery surface (361.9±25.5 mN), suggesting the biomimetic slippery trapping plate bore rather similar function as the slippery surface, thereby achieved the protected biomimetic results. The obtained conclusion provides theoretical and technical references to biomimetic development of slippery trapping plate used for controlling agricultural insect.