“虚拟仿真”背景下畜牧兽医研究生实践教学改革探索研究

研究生教育位于国民教育体系的顶端，是国家高等教育发展水平的重要标志。为培养 既具有责任担当精神，又具有宽厚的专业知识和创新能力，还具有较高的英语水平和较强的计算机网络应用能力的高层次畜牧兽医人才，本研究对我校畜牧兽医专业研究生的培养现状进行了分析总结，提出了基于“虚拟仿真”背景下人才培养的新模式，总结了虚拟仿真研究生科研平台建设的优势和使用效果，为其它专业研究生的培养提出参考。     

基于CFD的蛋鸭舍内环境模拟分析与验证

为优化4层层叠式笼养鸭舍舍内环境,基于计算流体动力学(computational fluid dynamics,CFD)对鸭舍内气流场、温度场及CO_2浓度场进行模拟。将笼架简化,考虑其对气流的阻挡作用,将鸭笼及鸭只视为多孔介质。模拟结果显示,进风口为湿帘时,侧墙湿帘与端墙之间存在通风死区,风速低于0.5 m·s~(-1)。进风口为通风小窗时,鸭舍未安装通风小窗区域风速小,CO_2浓度大。改变纵墙湿帘位置对鸭舍结构进行改进,改进后气流不均匀系数降低了17%。改进通风小窗布置发现,提升通风小窗分布均匀性显著降低舍内温差;提升通风小窗安装高度将显著降低舍内CO_2浓度。该研究可为蛋鸭舍结构设计提供参考。     

基于FSEC赛车电池箱的结构设计与强度分析

以中国大学生电动方程式赛车的电池箱体研究为背景,对电池箱的结构设计和强度分析方面进行了研究论证,提出了电池箱设计的总体思路,使电池箱的结构设计紧凑合理,工作安全可靠,符合赛事规则。这对纯电动乘用车在电池箱的结构设计方面也具有参考和借鉴的价值。     

Estimation of irrigation requirements for drip-irrigated maize in a sub-humid climate

Drip-irrigation is increasingly applied in maize (Zea mays L.) production in sub-humid region. It is critical to quantify irrigation requirements during different growth stages under diverse climatic conditions. In this study, the Hybrid-Maize model was calibrated and applied in a sub-humid Heilongjiang Province in Northeast China to estimate irrigation requirements for drip-irrigated maize during different crop physiological development stages and under diverse agro-climatic conditions. Using dimensionless scales, the whole growing season of maize was divided into diverse development stages from planting to maturity. Drip-irrigation dates and irrigation amounts in each irrigation event were simulated and summarized in 30-year simulation from 1981 to 2010. The maize harvest area of Heilongjiang Province was divided into 10 agro-climatic zones based on growing degree days, arid index, and temperature seasonality. The simulated results indicated that seasonal irrigation requirements and water stress during different growth stages were highly related to initial soil water content and distribution of seasonal precipitation. In the experimental site, the average irrigation amounts and times ranged from 48 to 150 mm with initial soil water content decreasing from 100 to 20% of the maximum soil available water. Additionally, the earliest drip-irrigation event might occur during 3- to 8-leaf stage. The water stress could occur at any growth stages of maize, even in wet years with abundant total seasonal rainfall but poor distribution. And over 50% of grain yield loss could be caused by extended water stress during the kernel setting window and grain filling period. It is estimated that more than 94% of the maize harvested area in Heilongjiang Province needs to be irrigated although the yield increase varied (0 to 109%) in diverse agro-climatic zones. Consequently, at least 14% of more maize production could be achieved through drip-irrigation systems in Heilongjiang Province compared to rainfed conditions.     

Numerical study on wave attenuation inside and around a square array of biofouled net cages

In this study, waves propagating through a square array of 16 net cages with different levels of biofouling are numerically studied using a three-dimensional computational fluid dynamics (CFD) model. A porous-media fluid model is adopted to simulate both clean and biofouled netting of a cage array in waves. A numerical wave tank is built, and the oscillating-boundary method is adopted to generate waves. The flow motion is solved by the Navier-Stokes equations, and the free water surface is captured using the volume of fluid (VOF) method. The numerical model is validated by comparing the numerical data with corresponding experimental measurements of a net-cage model with clean netting. To analyze wave attenuation, a numerical analysis of wave elevation both inside and around the cage arrays is presented, which considers the effect of biofouling. Based on the results of the present study, the effect of biofouling on wave elevation is noticeable; the damping effect of the cage array increases with increasing level of biofouling. Furthermore, the incident angle of waves has a noticeable effect on the wave field inside and around the cage array.     

温度对住宅区气体污染物扩散的影响

温度在气体污染物扩散的过程中起一定的作用。在现实生活中,由于日晒和地表辐射的存在,使得地面、建筑物外表面都与空气存在一定的温差。温差的存在会改变地表及壁面附近的流场,从而对住宅区污染物的扩散产生影响。利用理论推导对热力因素及扩散因素的关系进行了研究,并且与数值模拟的试验结果进行比较。结果发现理论推导与试验结果整体趋势相一致。这表明在与无温差情况相比较,温差存在时,地表及壁面附近流场更加紊乱;温差与气体污染物的扩散具有正相关性,对住宅区污染物的稀释起积极作用。     

日光温室墙体一维导热的MATLAB模拟与热流分析

为探明日光温室墙体层间温度变化及热量传递动态规律,采用有限差分法建立墙体一维非稳态导热模型,利用MATLAB编制相应的模拟程序,计算出日光温室墙体各点的温度和热流。结果表明:该模型能够比较准确模拟日光温室土墙的温度。墙体内侧存在有效蓄热层,它对日光温室室内热环境有积极的作用。墙体有效蓄热层的热流白天指向墙体外侧,夜间指向墙体内侧,因此它的厚度直接根据热流的方向确定。有效蓄热层与天气、墙体总厚度以及墙体热特性参数有关。2012-12—2013-01期间有效蓄热层厚度为0.26~0.45m不等,最大值出现在连续雪天。同时从理论上验证了3.0m厚的温室土墙内部存在热流相对稳定的"热稳定层"。     

利用荚果厚度模拟大豆鼓粒进程的研究

大豆籽粒发育可分为鼓粒期和籽粒归圆期,探究无损伤检测鼓粒进程的指标对大豆相关研究具有重要意义。本研究以青鲜819-4、冀豆17、鲁96150和V94-3971为试验材料,通过分期播种、连续测定标记花荚的荚果厚度,分期收获同日标记的大豆籽粒并进行发芽率测定,研究大豆鼓粒期荚果厚度变化。结果表明:1)鼓粒期鲜荚皮厚度基本保持恒定,因此荚果厚度可用于度量籽粒厚度的变化。荚果厚度(y)与开花后日数(x)的关系可以用二次函数(y=ax2+bx+c)进行有效模拟。利用模拟函数可以对大豆鼓粒始期、最大荚果厚度出现期、鼓粒持续期以及平均鼓粒速率等进行有效预测。荚果最大厚度可用作判定大豆籽粒开始具备发芽能力的外观指标。2)荚果厚度变化受材料特性和外界环境的共同影响。同一材料不同时期标记的花荚,荚果厚度增速趋势可能有差异,因此在大豆籽粒灌浆特性研究中,同日标记花荚是籽粒灌浆特性研究中一项必要的控制措施。3)不同材料鼓粒特性存在差异,选择鼓粒启动早、鼓粒速度快的大豆品种是可行的。荚果厚度有望成为研究大豆灌浆特性和适时早收的无损伤选择指标。     

基于玻璃化转变的稻谷变温热风干燥工艺研究

为保证稻谷干燥后品质、提高干燥效率,基于不同含水率稻谷的玻璃化转变温度,提出变温热风干燥工艺。采用三因素五水平中心组合试验方法,以稻谷温度、初始含水率和热风风速为影响因素,以稻谷爆腰指数、整精米率和干燥时间为评价指标,研究稻谷玻璃化转变温度、恒温和变温干燥特性,模拟解析稻谷干燥过程中传热传质规律,以5、10、15℃的变温幅度进行变温干燥试验。结果表明,稻谷玻璃化转变温度与其含水率呈负相关,恒温干燥最佳工艺参数为稻谷温度47℃、初始含水率22.0%、热风风速0.50 m/s,干燥后稻谷爆腰指数70、整精米率57.67%、干燥时间195 min;与恒温干燥相比,以5℃和10℃为变温幅度的变温干燥工艺,干燥后稻谷爆腰指数分别降低了20和10,整精米率提高12.6、7.7个百分点,干燥时间缩短30 min和60 min。研究表明,基于玻璃化转变的稻谷变温热风干燥工艺明显改善了稻谷干燥后品质,提高了干燥效率。     

冷热破碎工艺对小包装番茄酱贮藏期间非酶褐变的影响

为探究冷破碎工艺和热破碎工艺对番茄酱贮藏期间非酶褐变的影响,将制备的番茄酱在20℃和35℃条件下进行12个月的贮藏。通过对番茄酱的褐变指数、还原糖、番茄红素、5-HMF、VC含量、氨基酸态氮含量、可滴定酸含量和pH变化的测定以及相关性分析得出美拉德反应与VC氧化分解反应是导致番茄酱在贮藏期间发生非酶褐变的主要原因,番茄红素不是引起番茄酱色泽变化的主要原因,美拉德反应的主要产物是5-HMF。经过液相色谱分析,番茄酱中糖类主要由果糖、葡萄糖和蔗糖组成,冷破、热破番茄酱中的三种糖类含量有差异。通过模拟体系,进一步确定了美拉德反应是导致番茄酱在贮藏期间发生非酶褐变的根本原因,且糖是5-HMF生成的必要条件,5-HMF的产生主要由果糖决定,VC氧化分解反应对5-HMF的生成贡献微弱。因冷破碎工艺温度较低,产品果糖含量较多,更容易褐变,所以冷破番茄酱的贮藏环境应尽可能的保证低温。