液下泵内部非定常流动及噪声特性

为研究液下泵内部流动的非定常特性及噪声规律,通过采用计算流体动力学软件ANSYS CFX15.0与LMS Virtual.lab声学仿真软件相结合的一种间接混合计算方法,对液下泵内部流场及其声场进行求解.在该计算方法中,对流场进行求解得到监测点的非定常压力脉动,从而获得非稳态的压力脉动频域特性规律;基于声学边界元法,对液下泵蜗壳偶极子内场噪声和叶片偶极子内场噪声进行求解,获得了边界元表面的声压级分布以及典型场点的声压频率曲线.计算结果表明:叶片扫掠过程中与蜗壳隔舌的相互作用产生较大的压力脉动,隔舌附近的噪声是流动噪声的主要噪声源;声压级在叶片通过频率及其谐频时达到极大值,随频率的增大,声压级极大值都呈现衰减状态.研究结果可为液下泵的后续降噪分析提供一定的理论基础.     

支管射流三通结构优化与试验

为了提高支管射流三通水力性能,改善滴灌的灌水均匀性,基于CFX数值模拟技术,对进口宽度为15 mm的支管射流三通进行结构优化.选取位差、劈距、劈尖半径和侧壁倾角为影响因素,通过四因素三水平正交设计了9组模型,边界条件设定为进口压力100 kPa.选取支管射流三通出口设计流量为评价标准,支管射流三通最优结构尺寸为位差5.5 mm、劈距113 mm、劈尖半径13 mm、侧壁倾角10°.此结构尺寸参数下的支管射流三通水力性能试验结果表明:在进口水压为100 kPa时,支管射流三通脉冲频率为148次/min,水头压力振幅为37.9 kPa,水头压力损失为16.7 kPa,出口流量为0.698 L/s;支管射流三通所接滴灌带长度为60 m时,与普通支管三通相比,支管射流三通的灌水均匀系数提高了2.78%,流量偏差率降低了4.72%.该研究可为射流技术在脉冲滴灌系统的研究、开发与应用提供理论依据.     

基于可控气流-激光检测技术的鸡肉嫩度评估方法

以鸡肉嫩度为研究对象，采用可控气流-激光检测技术的瞬态、蠕变回复和应力松弛等动静态检测模态，并使用支持向量机分类器和全局变量偏最小二乘算法，结合不同预处理方法，对鸡肉嫩度进行定性判别和定量预测。结果表明3个激励模态结合不同预处理算法均可实现鸡肉嫩度的定性定量评估。在定性方面，瞬态模态对嫩度具有最佳的分类效果；S-G卷积平滑算法表现出最佳的预处理性能，校正集嫩/老分类精度分别为1和0.98，马修斯相关系数为0.97；而验证集分类精度也达到了0.95和0.84。在定量预测方面，S-G卷积平滑算法在提升原始数据的信噪比上同样具有最佳效果；瞬态模态校正集和验证集模型相关系数分别为0.948和0.913，均方根误差分别为0.736N和1.013N。因此，在组织结构引起的品质预测动态模态较静态模态更适用。本研究开展的可控气流-激光技术在鸡肉嫩度评估的应用，为肉品检测领域提供了新的解决方案。     

水肥一体化中水肥混合效果数值模拟研究

为研究水肥一体化技术中的水肥混合特性,以流体力学中的两相流理论为基础,针对水肥混合过程中混合时间、混合区间长度、流速及管径对其混合效果的影响进行相应的数值模拟研究。结果表明,混合时间及混合区间长度越长有利于提高水肥混合效果及最终水肥混合均匀性;水肥流速比较低时管内水肥混合的均匀性较好,且水肥流速越大则其混合效果及均匀性越好;水肥流速较低时输水管及输肥管的管径比对水肥混合均匀性的影响较大,两者管径比越小则混合效果越好,随着流速的提高两者管径比对其混合效果的影响逐渐减弱。     

Nutrient cycling and biomass flows in a low-quality forest stand improvement system in the Lesser Khingan Range of China

The material flow and bulk internal flow analyses were used to establish a material accumulation and cycling model for a low-quality forest stand improvement system and a series of processes were considered. The model was applied in a one-hectare low-quality forest plot in the Lesser Khingan Range of China. Results showed that during 1997–2007, the stands absorbed 270.19 kg of N, 74.28 kg of P, and 124.39 kg of K from soils, 51.82 kg of N and 2.38 kg of P were directly absorbed by foliage, and 16.25 kg of K was released to soils by eluviation. Until 2007, the accumulated nutrients in the stands included 236.91 kg of N, 65.28 kg of P, and 108.55 kg of K. When horizontal strip clearcutting was applied in 2007, 50% accumulated nutrients in the stands were shifted due to harvesting operations, and 212.74 kg of N, 26.97 kg of P, and 98.88 kg of K were accumulated in soils, declining by 9.47% for N, 3.68% for P, and 17.60% for K, respectively, compared with year 1997. 94.61 t per hectare of biomass was generated, of which the biomass in stands accounted for 87.36%. The felled tree biomass was 36.89 t per hectare, of which 84.90% and 10.03% of biomass were utilized in terms of logs and other means, and the rest was left on site.     

Sap flow characteristics and physiological adjustments of two dominant tree species in pure and mixed plantations in the semi-arid Loess Plateau of China

It is essential to understand the water consumption characteristics and physiological adjustments of tree species under drought conditions, as well as the effects of pure and mixed plantations on these characteristics in semi-arid regions. In this study, the normalized sap flow (SF_n), leaf water potential, stomatal conductance (g_s), and photosynthetic rate (P_r) were monitored for two dominant species, i.e., Pinus tabuliformis and Hippophae rhamnoides, in both pure and mixed plantations in a semi-arid region of Chinese Loess Plateau. A threshold-delay model showed that the lower rainfall thresholds (R^L) for P. tabuliformis and H. rhamnoides in pure plantations were 9.6 and 11.0 mm, respectively, and the time lags (τ) after rainfall were 1.15 and 1.76 d for corresponding species, respectively. The results indicated that P. tabuliformis was more sensitive to rainfall pulse than H. rhamnoides. In addition, strong stomatal control allowed P. tabuliformis to experience low g_s and P_r in response to drought, while maintaining a high midday leaf water potential (Ψ_m). However, H. rhamnoides maintained high g_s and P_r at a low Ψ_m expense. Therefore, P. tabuliformis and H. rhamnoides can be considered as isohydric and anisohydric species, respectively. In mixed plantation, the values of R^L for P. tabuliformis and H. rhamnoides were 6.5 and 8.9 mm, respectively; and the values of τ were 0.86 and 1.61 d for corresponding species, respectively, which implied that mixed afforestation enhanced the rainfall pulse sensitivity for both two species, especially for P. tabuliformis. In addition, mixed afforestation significantly reduced SF_n, g_s, and P_r for P. tabuliformis (P<0.05), while maintaining a high leaf water potential status. However, no significant effect of mixed afforestation of H. rhamnoides was observed at the expense of leaf water potential status in response to drought. Although inconsistent physiological responses were adopted by these species, the altered water consumption characteristics, especially for P. tabuliformis indicated that the mixed afforestation requires further investigation.     

鄂尔多斯高原沙地柏液流通量及其影响因子

[目的]分析沙地柏液流通量变化特征及主要影响因子,为沙地植被的保护提供理论依据。[方法]以鄂尔多斯高原沙地植被的优势种沙地柏为研究对象,利用热扩散(TDP)技术监测生长季沙地柏的液流动态,通过相关分析和回归分析等研究其与气象因子的关系。[结果]晴天沙地柏的液流通量为单峰曲线,干旱时为双峰曲线。雨天沙地柏的液流通量为单峰或双峰曲线。晴天沙地柏液流通量的最大值是2.30～23.38 g/(cm~2·h)。沙地柏液流通量对降雨的响应具有1～4 d的时滞。生长季沙地柏液流通量与光合有效辐射、水汽压亏缺、气温和风速均呈显著正相关,而与相对湿度和降雨量呈显著负相关。[结论]鄂尔多斯高原沙地柏的液流通量随天气而变化。太阳辐射和水分是沙地柏液流通量的主要影响因子。建议当地加强对沙地柏灌丛的保护,防止由于过度水分消耗导致的植被退化。     

库姆塔格沙漠东南部胡杨液流变化及其对环境因子的响应

于2018年4月?10月(春季4月、夏季7月、秋季9月)利用PS-TDP8树木茎流监测系统对库姆塔格沙漠东南部胡杨(Populus euphratica)的液流速率变化进行监测,采用相关分析及逐步回归法分析气象因子(太阳总辐射、空气温度、风速、空气相对湿度)对胡杨液流的影响。结果表明:胡杨茎干液流日变化趋势呈几字“宽峰型”;夏季液流的启动时间最早,液流启动在06:00,秋季液流启动时间最晚,不同季节夜间存在较高液流(10.994~26.035 cm·h^?1);树干液流速率与太阳总辐射、空气温度、风速、饱和水气压差呈正相关关系,与空气湿度呈负相关关系;影响春季、秋季胡杨液流速率的主要气象因子是太阳总辐射和空气温度,夏季为太阳总辐射和空气相对湿度;不同季节胡杨液流速率与空气温度、空气相对湿度、风速、饱和水气压差的日变化响应呈顺时针环状,与太阳辐射响应呈逆时针环状;不同季节胡杨液流速率对气象因子的响应规律存在差异。这表明胡杨为了保持水分平衡应对水分亏缺的策略不同,在一定条件下(极端干旱)通过气孔调节降低水分损失。研究结果对于明确干旱沙漠环境中胡杨水分传输对环境因子的响应规律及更深入地认识胡杨适应干旱环境的水分利用策略具有重要意义。     

颗粒肥料质量流量传感器设计与试验

变量施肥具有提高肥料利用率、保护生态环境、节约农业生产成本等优点，但目前还没有得到广泛的应用，除了难以获得变量施肥的处方图之外，缺乏闭环检测也是原因之一。闭环控制是实现变量施肥的关键之一，与间接测量排肥轴的转速相比，实时检测肥料的质量流量更为准确。本文基于静电感应原理，设计了一种颗粒肥料质量流量传感器。由于颗粒肥料之间、颗粒肥料与空气、颗粒肥料与排肥管之间的摩擦和碰撞，颗粒肥料会携带一定量的电荷，因此本研究设计了环形电极来检测电荷强度，并利用电流放大电路输出感应电流。通过标定质量流量与感应电流的关系，获得了实时的肥料质量流量。搭建试验台对该颗粒肥料质量流量传感器进行检测，试验台主要包括动态信号采集系统、肥料箱、电流放大器和环形电极传感器。以大颗粒尿素（CO(NH2)2）、过磷酸钙（Ca(H2PO4)2·H2O）和氯化钾（KCl）为研究对象，其平均容重分别为0.7、1.2、1.1g/cm3。根据施肥装置的物理参数，通过调整排肥轴转速可获得近似的目标质量流量，目标质量流量的范围是3~15g/s，增量为1g/s。对于每个质量流量，进行了4次重复。每次重复30s，施肥装置与信号采集系统同时启动。利用平均感应电流和平均质量流量建立回归方程，采用插值法得到实时质量流量。随后，对每种肥料进行25次试验，从而检验本文中颗粒肥料质量流量传感器的测量精度，每次试验的目标质量流量由5个随机质量流量组成，每个质量流量下持续排肥6s，用天平称量30s内的实际质量，通过积分质量流量和时间曲线计算检测质量。采用SPSS 22.0软件对试验结果进行统计分析，分析表明，大颗粒尿素、过磷酸钙、氯化钾的检测误差分别为3.9%、5.1%、5.9%，相应的标准差分别为5.21、7.98、11.29。检测质量与实际质量无显著性差异（P>0.1），大颗粒尿素、过磷酸钙和氯化钾检测误差的数学期望值分别为3.74%、4.93%、5.22%。本文的研究结果表明，检测误差随颗粒肥料粒径的减小而增大。