农业工程学报
農業工程學報
농업공정학보
2015年
11期
228-235
,共8页
马旭%林超辉%齐龙%江立凯%谭永炘%梁仲维%鹿芳媛
馬旭%林超輝%齊龍%江立凱%譚永炘%樑仲維%鹿芳媛
마욱%림초휘%제룡%강립개%담영흔%량중유%록방원
光%发光二极管(LED)%温室%光照度%红蓝光通量比%人工补光%立体育秧%秧层间距
光%髮光二極管(LED)%溫室%光照度%紅藍光通量比%人工補光%立體育秧%秧層間距
광%발광이겁관(LED)%온실%광조도%홍람광통량비%인공보광%입체육앙%앙층간거
light%light emitting diodes%greenhouses%light intensity%flux ratio of red to blue light%artificial lighting%stereoscopic seedlings nursing%frame spacing
水稻温室立体育秧技术具有节省秧田、减少土地浪费,利于标准化集中育秧等特点,但立体育秧中秧架各层之间光线互相遮挡造成的秧苗采光不足的问题,需要采用补光技术来改善秧架内光照条件以保证秧苗生长。该文基于植物光学理论分析确定水稻秧苗生长所需的红蓝光通量比(简称红蓝光比)范围,运用光照分析理论确定温室内光照度,并采用Ecotect软件进行温室内光环境模拟仿真。在理论分析和仿真结果的基础上研究不同补光条件对水稻秧苗生长质量的影响,采用LED植物补光灯分别对立体秧架上除顶层外的各层秧苗进行补光,设计红蓝光比、光照度及秧层间距3个因素的正交试验,分析不同红蓝光比、光照度和秧层间距对水稻秧苗素质的影响。试验结果表明,红蓝光比10:1、光照度2500 lx的光处理对水稻苗茎伸长生长促进作用更好;红蓝光比8:1的光处理则对水稻幼苗干物质积累和根系盘结作用更好,而且比红蓝光比10:1和6:1的光处理的壮苗指数要高。分析得出各个因素对水稻秧苗素质影响的主次顺序为:红蓝光比>光照度>秧层间距,最佳的补光条件为:红蓝光比8:1,光照度2500 lx,秧层间距45 cm。该文的研究结果为水稻工厂化立体育秧技术提供了参考。
水稻溫室立體育秧技術具有節省秧田、減少土地浪費,利于標準化集中育秧等特點,但立體育秧中秧架各層之間光線互相遮擋造成的秧苗採光不足的問題,需要採用補光技術來改善秧架內光照條件以保證秧苗生長。該文基于植物光學理論分析確定水稻秧苗生長所需的紅藍光通量比(簡稱紅藍光比)範圍,運用光照分析理論確定溫室內光照度,併採用Ecotect軟件進行溫室內光環境模擬倣真。在理論分析和倣真結果的基礎上研究不同補光條件對水稻秧苗生長質量的影響,採用LED植物補光燈分彆對立體秧架上除頂層外的各層秧苗進行補光,設計紅藍光比、光照度及秧層間距3箇因素的正交試驗,分析不同紅藍光比、光照度和秧層間距對水稻秧苗素質的影響。試驗結果錶明,紅藍光比10:1、光照度2500 lx的光處理對水稻苗莖伸長生長促進作用更好;紅藍光比8:1的光處理則對水稻幼苗榦物質積纍和根繫盤結作用更好,而且比紅藍光比10:1和6:1的光處理的壯苗指數要高。分析得齣各箇因素對水稻秧苗素質影響的主次順序為:紅藍光比>光照度>秧層間距,最佳的補光條件為:紅藍光比8:1,光照度2500 lx,秧層間距45 cm。該文的研究結果為水稻工廠化立體育秧技術提供瞭參攷。
수도온실입체육앙기술구유절성앙전、감소토지낭비,리우표준화집중육앙등특점,단입체육앙중앙가각층지간광선호상차당조성적앙묘채광불족적문제,수요채용보광기술래개선앙가내광조조건이보증앙묘생장。해문기우식물광학이론분석학정수도앙묘생장소수적홍람광통량비(간칭홍람광비)범위,운용광조분석이론학정온실내광조도,병채용Ecotect연건진행온실내광배경모의방진。재이론분석화방진결과적기출상연구불동보광조건대수도앙묘생장질량적영향,채용LED식물보광등분별대입체앙가상제정층외적각층앙묘진행보광,설계홍람광비、광조도급앙층간거3개인소적정교시험,분석불동홍람광비、광조도화앙층간거대수도앙묘소질적영향。시험결과표명,홍람광비10:1、광조도2500 lx적광처리대수도묘경신장생장촉진작용경호;홍람광비8:1적광처리칙대수도유묘간물질적루화근계반결작용경호,이차비홍람광비10:1화6:1적광처리적장묘지수요고。분석득출각개인소대수도앙묘소질영향적주차순서위:홍람광비>광조도>앙층간거,최가적보광조건위:홍람광비8:1,광조도2500 lx,앙층간거45 cm。해문적연구결과위수도공엄화입체육앙기술제공료삼고。
The technique of greenhouse stereoscopic seedling nursing in rice seedlings has many benefits, such as achieving the efficient use of seedling land and promoting standard centralized rice seedling. However, since multiple layers of seedbeds are stacked together and block light from each other, the problem of insufficient lighting arises from greenhouse stereoscopic nursing. Therefore, artificial supplemental lighting technology needs to be applied in the greenhouse in order to improve the illumination conditions of the seedbed layers, thus to enhance the quality of rice seedlings. In this paper, the range of flux ratio of red to blue light required for rice seedlings growth optimally was determined based on fundamental findings of the plant optical theoretical analysis; the light intensity distribution inside the greenhouse was calculated based on the theory of illumination analysis; and the light environment among the layers of seedbeds inside the greenhouse was simulated using the Ecotect software. Simulation results showed that, without artificial supplemental lighting, except the top layer, the light intensity on each seedbed layer couldn’t meet the requirements of the rice seedlings growth. Based on the theoretical analysis and simulation results, the effects of different artificial lighting conditions on the growth quality of rice seedling were studied. In the study, LED plant lights were adopted to provide supplemental lighting to all seedbed layers except the top layer, and orthogonal experimental design was implemented to study the effects of the flux ratio of red to blue light, the light intensity and the frame spacing among the seedbed layers on rice seedlings quality. Experimental results from this study showed that the lighting condition with a flux ratio of red to blue light of 10:1 and a light intensity of 2 500 lx was beneficial to promoting rice stem elongation and growth; the lighting condition with a flux ratio of red to blue light of 8:1 was beneficial to retaining dry matters in rice seedlings and ensuring the tangle of the roots; and the rice seedlings processed by the lighting with a flux ratio of red to blue light of 8:1 had a higher healthy index compared to the rice seedlings processed by the lighting with a flux ratio of red to blue light of 6:1 or 10:1. The analysis of this study showed that the order of significance of the aforementioned 3 factors’ effects on the quality of rice seedlings was: flux ratio of red to blue light>light intensity>frame spacing. The best artificial lighting condition was shown to be with a flux ratio of red to blue light of 8:1, a light intensity of 2 500 lx and a frame spacing of 45 cm. The conclusions of this study may serve as a technical reference for industrialized stereoscopic rice seedlings applications and provide guidance to the greenhouse stereoscopic rice seedling nursing.