融合光谱与图像信息的河套蜜瓜糖度在线检测试验系统

针对蜜瓜糖度在线检测的需求,设计了融合漫透射光谱与图像信息的河套蜜瓜糖度在线检测试验系统,该系统包括硬件平台和软件系统两部分。硬件平台主要包括蜜瓜输送装置、光谱采集装置、图像采集装置和控制系统4部分。软件系统基于Microsoft Visual C++6.0语言,结合Omni Driver软件、Fly Capture2及Open CV软件开发。系统可实现蜜瓜光谱与图像信息的自动采集、显示及保存,可实现对漫透射光谱预处理,获取糖度检测所需光谱数据,对图像预处理,提取蜜瓜外观特征图像信息(R、G、B颜色值和蜜瓜体积)。在此基础上,系统可通过融合漫透射光谱与图像信息的蜜瓜糖度检测模型,计算蜜瓜糖度。系统同时可实现检测个数统计,外观特征信息及糖度的实时显示、保存等功能。测试试验表明,该试验系统检测1个样品用时1.2 s,糖度检测均方根误差为1.22,可满足河套蜜瓜糖度在线检测试验需求,为进一步开展河套蜜瓜糖度在线检测研究奠定了基础。     

一种新的能量叠加点火系性能匹配研究

在能量叠加点火系电路分析的基础上，对其进行了匹配发动机的试验研究。试验结果表明，能量叠加点火系可有效改善发动机的点火性能，从而使发动机的动力性能提高约2％～5％，经济性能改善4％左右，怠速排放特性改善幅度达10％左右，外特性排放改善幅度达8％～20％；与传统点火系相比，还可以使发动机最低稳定运转速度降低30％左右，同时使发动机的起动变得迅速、容易。试验结果与理论分析完全吻合，证明了能量叠加点火系确实可以缩短可燃混合气的着火延迟期，有利于混合气的快速燃烧，这种技术特别适合于稀薄燃烧与快速燃烧系统。     

表面油流法显示螺旋离心泵内部流动的研究

对螺旋离心泵叶轮、进水节和进水节与蜗壳交界处的部分端面做了表面油膜、油点试验。通过流谱分析，揭示了表面奇点、分离线与再附着线等流动特征，研究了螺旋离心泵内部流动规律，进而提出了改进螺旋离心泵结构的设想。     

osCOMC系统的体系结构与设计原理的研究

提出了一个功能划分合理、各部件联系简洁、规模可动态伸缩的单元体系模型——osCOMC单元系统,并对其总体体系结构和设计原理进行了详细描述。遵循COM技术思想和开放性原则,通过总线数据传输、核心构件与应用构件动态装配的设计思想,可完成osCOMC整个系统规模可动态伸缩。     

农用柴油机喷油泵预行程调整的重要性

通过对Ⅱ型喷油泵凸轮型结构特点和柱塞运动规律的研究,在说明柱塞预行程与供油提前角关系的基础上,通过试验分析了柱塞预行程对排放和发动机性能的影响,指出了预行程(供油正时、供油速率)调整的重要性。     

汽油机转速反馈自适应控制

对汽油机转速反馈自适应点火微机控制进行了研究，对发动机点火采用开环与自适应相结合的控制方法，以发动机的转速变化为反馈信号，将发动机点火提前角控制在最佳值，试验结果表明，转速反馈自适应点火控制是可行的，它能提高控制精度和响应速度，能提高发动机的综合性能。     

基于UEGO的柴油机EGR系统空燃比MAP的制取

在柴油机稳态工况下,通过试验测定了不同空燃比时,NOx、HC、CO、烟度和油耗的变化.通过对测试数据的分析,确定了最佳空燃比MAp.为基于UEGO的柴油机EGR系统的闭环控制奠定了基础.     

步进式水稻钵苗摆植机送秧机构的研究

研究了步进式水稻钵苗摆植机总体设计方案，分析了送秧机构的工作原理，对送秧机构的齿距、齿高、转速、曲柄、摇杆等结构参数进行了确定。理论分析和台架实验表明，步进式水稻钵苗摆植机送秧机构结构简单，工作可靠，排序效果好。     

干燥系统室体结构传热特征参数及其试验方法

依据传热的基本原理，提出了分析干燥系统室体结构传热特性的特征参数新概念，实现了干燥室隔热体传热系数的非稳态测量，并可同时确定蓄热当量系数。在建立室体传热非稳态分析理论的基础上，提出了相应的试验分析方法，并进行了理论分析及试验验证。     

Incorporation of ridge and furrow method of rainfall harvesting with mulching for crop production under semiarid conditions

A plastic-covered ridge and furrow rainfall harvesting (PRFRH) system combined with mulches was designed to increase water availability to crops for improving and stabilizing agricultural production in the semiarid Loess region of northwest China. The system was built by shaping the soil surface with alternate ridges and furrows along the contour. The plastic-covered ridges served as a rainfall harvesting zone and furrows as a planting zone. Some materials were also used to mulch the furrows to increase the effectiveness of the harvested water. This system can make better utilization of light rain by harvesting rainwater through the plastic-covered ridge. The field experiment (using corn as an indicator crop) showed that grain yields in the PRFRH system with mulches in 1998 and 1999 were significantly higher than the controls, with an increase of 4010–5297 kg per ha (108–143%). In most treatments, the water use efficiencies (WUE) were in excess of 2.0 kg m⁻³. The WUE values of corn in this system were 1.9 times greater than the controls in 1998 and 1.4 times greater than the controls in 1999. The plastic-covered ridge led to a yield increase of 3430 kg per ha (92%) in 1998 and of 1126 kg per ha (21%) in 1999 compared with the uncovered ridge. On average, the additional mulches in the furrow brought about a yield increase of 8–25%. Based on the results of this study and other researches, this technique can increase corn grain yield by 60–95% in drought and average years, 70–90% in wet years, and 20–30% in very wet years. The PRFRH system had the potential to increase crop yield and produced greater economic benefit, therefore it could be used in regions dominated by light rainfall of low intensity where crops generally fail due to water stress.