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小麦超窄行免耕播种与均间隙高产栽培技术研究
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作者 潘滨 李云 《中国农机装备》 2023年第2期52-55,共4页
常规小麦播种亩穗数在35-50万穗,为了实现小麦高产,增加小麦亩穗数是其主要途径之一,但是人工小麦乱散播种虽然增大了小麦亩穗数,但是成穗率低、水肥消耗大,小麦植株平均间隙也没有减少,土地水肥资源得不到充分利用。因此,有必要研究一... 常规小麦播种亩穗数在35-50万穗,为了实现小麦高产,增加小麦亩穗数是其主要途径之一,但是人工小麦乱散播种虽然增大了小麦亩穗数,但是成穗率低、水肥消耗大,小麦植株平均间隙也没有减少,土地水肥资源得不到充分利用。因此,有必要研究一种小麦超窄行均间隙全苗免耕播种机,适度增加小麦亩穗数,提高小麦植株平均间隙,平均利用土壤水肥资源,提高小麦单产。小麦均间隙全苗高产栽培技术机械化播种,实现农机与农艺相结合,满足均间隙全苗高产栽培技术的农艺要求。 展开更多
关键词 小麦 超窄行 免耕播种 均间隙栽培技术 农机农艺结合
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超窄行棉花精量排种器设计与性能试验 被引量:11
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作者 康建明 陈学庚 +1 位作者 王士国 颜利民 《甘肃农业大学学报》 CAS CSCD 北大核心 2016年第2期134-139,共6页
【目的】针对目前新疆棉花播种行距大,喷洒脱叶剂受药效果差,导致机械采收采净率偏低的问题,研制了一种播种行距更窄,能实现高度密植的超窄行棉花精量排种器.【方法】对超窄行精量棉花排种器的结构及参数进行理论分析,确定排种器的主要... 【目的】针对目前新疆棉花播种行距大,喷洒脱叶剂受药效果差,导致机械采收采净率偏低的问题,研制了一种播种行距更窄,能实现高度密植的超窄行棉花精量排种器.【方法】对超窄行精量棉花排种器的结构及参数进行理论分析,确定排种器的主要结构与性能参数.以排种器的单粒率、重播率、漏播率为排种性能评价指标,在PSY-1200鸭嘴滚筒式排种器性能实验台上进行排种器转速、负压区相对压力、落种角等运行参数的单因素及正交试验.【结果】经田间测试,当排种器转速为41r/min,负压区相对压力为-4500Pa,落种角为60°时,排种器单粒率为93.5%,重播率为3.8%,漏播率为4.2%,单行株距均匀性变异系数为5.82%,双行行距稳定性变异系数为6.04%.【结论】该排种器最小行距可调至4cm,满足超窄行种植农艺要求且能实现精量播种. 展开更多
关键词 棉花 精量排种器 超窄行
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三七超窄行气吸式精密排种器设计与试验 被引量:21
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作者 赖庆辉 于庆旭 +1 位作者 苏微 孙凯 《农业机械学报》 EI CAS CSCD 北大核心 2019年第4期102-112,共11页
三七播种行株距均为50 mm左右,属于密集型精密播种。为实现三七超窄行精密播种,设计一种超窄行气吸式精密排种器。通过理论计算与数值模拟,确定主要结构参数;以云南文山三七种子为播种对象,基于EDEM离散元软件,对水滴形窝眼孔加工倾角... 三七播种行株距均为50 mm左右,属于密集型精密播种。为实现三七超窄行精密播种,设计一种超窄行气吸式精密排种器。通过理论计算与数值模拟,确定主要结构参数;以云南文山三七种子为播种对象,基于EDEM离散元软件,对水滴形窝眼孔加工倾角影响充种性能进行仿真模拟试验,得出较佳加工倾角为50°;以吸孔负压、排种轮转速和种层高度为影响因素,以合格指数、重播指数、漏播指数和各行排量一致性变异系数为试验指标,进行三因素二次回归正交旋转组合试验。试验结果表明:影响合格指数的主次顺序为吸孔负压、排种轮转速、种层高度;当种层高度为50 mm、排种轮转速为34~48 r/min、吸孔负压为560~660 Pa时,合格指数大于93. 0%,重播指数小于3. 5%,漏播指数小于3. 5%,各行排量一致性变异系数小于3. 0%,满足三七播种要求。 展开更多
关键词 三七 超窄行 气吸式精密排种器 离散元法 试验
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Planting Geometry Effects on the Growth and Yield of Dryland Cotton
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作者 R. L. Baumhardt R. C. Schwartz +1 位作者 G. W. Marek J. M. Bell 《Agricultural Sciences》 2018年第1期99-116,共18页
The declining Ogallala Aquifer beneath the Southern High Plains may necessitate dryland crop production and cotton (Gossypium hirsutum L.) is a well-adapted and potentially profitable alternative crop. The limited gro... The declining Ogallala Aquifer beneath the Southern High Plains may necessitate dryland crop production and cotton (Gossypium hirsutum L.) is a well-adapted and potentially profitable alternative crop. The limited growing season duration of the Texas Panhandle and southwestern Kansas, however, imposes significant production risk due to incomplete boll maturation. Emphasizing earlier boll production that is usually confined to sites on lower fruiting branches may reduce risk, but offsetting high planting densities are needed to maintain desirable lint yield. Our objectives were to quantify planting: 1) row width and 2) in-row spacing effects on growth, yield, and fiber quality of dryland cotton. Field tests of row widths from 0.25 to 0.76 m and plant densities with in-row spacing ranging from 0.075 to 0.15 m were conducted from 1999 to 2005 on a nearly level Pullman clay loam (fine, mixed, superactive, thermic Torrertic Paleustoll) managed in a wheat (Triticum aestivum L.), cotton, fallow (W-Ctn-F) rotation. To expand the basis of comparison, cotton growth and yields were simulated using GOSSYM and long-term (1958-2000) weather records from Bushland, TX, as input for all combinations of 0.38 or 0.76 m row widths and plant spacing of 0.075, 0.10 and 0.15 m. Experimental and computer simulated plant height and harvested boll number increased significantly with increased row spacing and, occasionally, in-row plant spacing. Modeled lint yield for 0.38 m rows decreased by approximately 50% compared with the 582 kg·ha-1 yield for conventional row spacing, which was practically duplicated by field observations in 2001 and 2004. Measured fiber quality occasionally improved with conventional row spacing over ultra-narrow rows, but was unaffected by plant spacing. Because narrow rows and frequent plant spacing did not improve lint yield or fiber quality of dryland cotton, we do not recommend this strategy to overcome a thermally limited growing season. 展开更多
关键词 DRYLAND Crop Production Thermally Limited Growing SEASON Ultra-Narrow Row SPACING
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