农业工程学报
農業工程學報
농업공정학보
2015年
2期
66-71
,共6页
傅渝亮%费良军%聂卫波%王博
傅渝亮%費良軍%聶衛波%王博
부투량%비량군%섭위파%왕박
灌溉%土壤%数值方法%波涌灌%间歇入渗%水分运动%Hydrus-1D
灌溉%土壤%數值方法%波湧灌%間歇入滲%水分運動%Hydrus-1D
관개%토양%수치방법%파용관%간헐입삼%수분운동%Hydrus-1D
irrigation%numerical method%soils%surge flow%intermittent infiltration%water movement%Hydrus-1D
考虑到地下水浅埋对上层包气带水分分布造成一定影响,该研究结合波涌灌技术,对地下水浅埋下间歇入渗的土壤水分分布特征和运动规律进行了分析,建立了基于饱和-非饱和土壤条件下一维间歇入渗水分运动模型,根据试验实测资料采用Hydrus-1D软件反推土壤水分运动参数,并对入渗过程进行了模拟。在此基础上,确定了饱和导水率的估算模型。结果表明:所建参数估算模型较好地反映了饱和导水率与间歇周期数、循环率以及周期时间之间的相关关系,所建水分运动模型模拟值与实测值比较,累计入渗量、土壤含水率以及湿润体运移距离总体相关系数高于0.96,均方差在0.5以内,吻合度较高,能够较好地描述了地下水影响条件下波涌灌间歇入渗饱和-非饱和土壤水分运动特征。该研究为波涌灌技术进一步发展奠定了科学基础。
攷慮到地下水淺埋對上層包氣帶水分分佈造成一定影響,該研究結閤波湧灌技術,對地下水淺埋下間歇入滲的土壤水分分佈特徵和運動規律進行瞭分析,建立瞭基于飽和-非飽和土壤條件下一維間歇入滲水分運動模型,根據試驗實測資料採用Hydrus-1D軟件反推土壤水分運動參數,併對入滲過程進行瞭模擬。在此基礎上,確定瞭飽和導水率的估算模型。結果錶明:所建參數估算模型較好地反映瞭飽和導水率與間歇週期數、循環率以及週期時間之間的相關關繫,所建水分運動模型模擬值與實測值比較,纍計入滲量、土壤含水率以及濕潤體運移距離總體相關繫數高于0.96,均方差在0.5以內,吻閤度較高,能夠較好地描述瞭地下水影響條件下波湧灌間歇入滲飽和-非飽和土壤水分運動特徵。該研究為波湧灌技術進一步髮展奠定瞭科學基礎。
고필도지하수천매대상층포기대수분분포조성일정영향,해연구결합파용관기술,대지하수천매하간헐입삼적토양수분분포특정화운동규률진행료분석,건립료기우포화-비포화토양조건하일유간헐입삼수분운동모형,근거시험실측자료채용Hydrus-1D연건반추토양수분운동삼수,병대입삼과정진행료모의。재차기출상,학정료포화도수솔적고산모형。결과표명:소건삼수고산모형교호지반영료포화도수솔여간헐주기수、순배솔이급주기시간지간적상관관계,소건수분운동모형모의치여실측치비교,루계입삼량、토양함수솔이급습윤체운이거리총체상관계수고우0.96,균방차재0.5이내,문합도교고,능구교호지묘술료지하수영향조건하파용관간헐입삼포화-비포화토양수분운동특정。해연구위파용관기술진일보발전전정료과학기출。
Studies have showed that the high water-saving rate and optimal irrigation can be realized by using the surge flow irrigation. However, the investigation is not sufficient in the rule of water movement under intermittent infiltration in saturated-unsaturated soil condition. In order to explore the effect rule of surge irrigation on the water distribution in the aeration zone under the condition of shallow groundwater, we studied the water distribution and the effect law of infiltration through the combinations of intermittent infiltration and indoor water infiltration with model simulation. The laboratory test aimed to observe and analyze the data about soil moisture, cumulative infiltration and wetting front by irrigation with shallow groundwater during surge flow irrigation (step1). The part of numerical simulation mainly included the determination of the design parameters of soil water movement (step2) and the establishment of the mathematical modeling for intermittent infiltration (step3). Finally, a case was used to test the rationality and validity of the numerical simulation results (step4).The laboratory test included three cycling rate levels of treatment (1/2, 1/3 and 1/4, respectively) and each level of treatment included 3 repeats. Based on the theory of soil water dynamics and the technology of surge flow irrigation method, the one-dimensional water movement model in the intermittent infiltration under the saturated-unsaturated soil condition was established. With the application of the measured data for three treatment levels in the Hydrus-1D software based on finite element modeling for the analysis of water flow and solute transport in variably saturated porous media, the water movement parameters (the parameters of Van-Genuchten model) were calculated with the Hydrus-1D software. Furthermore, according to determined optimal parameters, we established a saturated hydraulic conductivity estimation model under different circulation rates and different intermittent cycles in the process of the intermittent infiltration. At last, by comparing the data of simulation and the data measured in the experiment, the validity of the proposed model was tested by the analysis of the relationship among the soil moisture content, cumulative infiltration and wetting front respectively. The results showed that after the simulation, the estimation model could reflect the correlativity among the three parameters (circulation rate, cycle number and cycle time), and the saturated hydraulic conductivity coefficient was calculated with these parameters. To verify the estimation model, the result of calculated values was compared with the simulated ones, and the relative deviation of saturated hydraulic conductivity was as small as -7.7%-8.9%, showing good consistency between the calculated and simulated data. From the comparison between the spot observation and the simulation data of soil moisture, cumulative infiltration and wetting front, we drew the conclusion that the calculated and simulated data had a similar change tendency by using two commonly-used criteria: root mean square error and coefficient of determination. The coefficient of determination of soil moisture was upon 0.952 and the one of cumulative infiltration was up to 0.953. The coefficient of determination of wetting front was 0.93 at least; root mean square error above was all less than 0.5, reaching an extremely remarkable level. The result of simulation could describe the characteristics of the saturated-unsaturated soil water movement in intermittent infiltration well under the condition of shallow groundwater level. The study of the paper laid a scientific basis for the further development of the surge irrigation.