肖苡辀, 王文娥, 胡笑涛. 基于FLOW-3D的田间便携式短喉槽水力性能数值模拟[J]. 农业工程学报, 2016, 32(3): 55-61. DOI: 10.11975/j.issn.1002-6819.2016.03.009
    引用本文: 肖苡辀, 王文娥, 胡笑涛. 基于FLOW-3D的田间便携式短喉槽水力性能数值模拟[J]. 农业工程学报, 2016, 32(3): 55-61. DOI: 10.11975/j.issn.1002-6819.2016.03.009
    Xiao Yizhou, Wang Wen'e, Hu Xiaotao. Numerical simulation of hydraulic performance for portable short-throat flume in field based on FLOW-3D[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2016, 32(3): 55-61. DOI: 10.11975/j.issn.1002-6819.2016.03.009
    Citation: Xiao Yizhou, Wang Wen'e, Hu Xiaotao. Numerical simulation of hydraulic performance for portable short-throat flume in field based on FLOW-3D[J]. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2016, 32(3): 55-61. DOI: 10.11975/j.issn.1002-6819.2016.03.009

    基于FLOW-3D的田间便携式短喉槽水力性能数值模拟

    Numerical simulation of hydraulic performance for portable short-throat flume in field based on FLOW-3D

    • 摘要: 田间量水是实现灌区计划用水和节水农业的关键技术,但由于试验条件、测量方法和精度的限制,传统的水工模型试验分析田间量水设施的水力性能存在一定局限性。该文基于FLOW-3D软件,采用RNG k-ε三维湍流模型、TruVOF方法、FAVOR(fractional area volume obstacle representation)技术模拟喉口宽度为51 mm的田间便携式短喉槽过槽水流的三维流场。与试验结果对比表明:过流能力、水流流态以及水深与试验结果较为吻合,误差小于10%,采用的数值模拟方法能够有效地模拟田间便携式短喉槽水力性能,在确定数值模拟可靠性的前提下,对其水力性能进行分析。数值模拟结果显示:佛汝德数、流速在自由出流工况下沿程增大,在淹没出流条件下先增大后减小,并由佛汝德数分析结果确定了临界水深断面所在区域为喉口段后半部分;通过回归分析得到的田间便携式短喉槽上游水深与流量计算公式最大测流误差为?5.63%,满足灌区量水精度的要求;该量水槽最大水头损失占总水头的12.10%,相比于长喉道量水槽的13%较小。该研究对提高量水设备研发效率、降低研发成本与周期、促进中国灌区流量精准测量设备的推广具有实用价值。

       

      Abstract: Abstract: Improvement of water management can encourage conservation and make best use of our limited water resources. The measurement of flow rates is an important element of water management. Many devices and structure have been developed for the measuring discharge but measuring flume is one of the most accepted and used structure. According to the practical situation of irrigated areas in northern China, use of portable short-throat flume in field to measure the discharge of water inlet in the field is an emerging technique developed for water discharge measurement of inlet in the field, which contributes to control of irrigation water consumption and water conservation. Based on FLOW-3D software in this study, RNG k-ε three-dimensional turbulence model, TruVOF technique and FAVOR (fractional area volume obstacle representation) method were employed to simulate three-dimension flow field in portable short-throat flume in field with a 51 mm width throat under 18 working conditions. Experimental results about portable short-throat flume in field were also obtained based on a new test to validate the simulation results. It verified discharge capacity of the flume. The parameter settings and boundary conditions used in the CFD models provided an efficient approach for simulation of the flow through portable short-throat flume in field. Combined with hydraulic experiments, hydraulic performance was obtained from simulation analyses on water surface profiles, Froude number, velocity distribution and head loss. Comparison between experiments and simulations showed that measured and simulated flow capacity, flow field and flow depth have a good consistency, and relative errors were less than 10%, and gave a solid agreement between experimental and numerical simulation results. Hence, it can be used to simulate flow state of portable short-throat flume in field effectively and visually. On the basis of reliable numerical simulated consequents, analyses of hydraulic performances in detail were carried out. The simulation results showed that both Froude number and velocity accelerated along the flume with free flow condition, and in submerged flow condition increased at first and then decreased. The cross-section of critical depth was located at throat section by Froude number analyses. The flow surface profile in throat section of portable short-throat flume in field was highly curvilinear in both free and submerged outflow working conditions as the flow accelerated from the subcritical regime to the supercritical regime. Equations of upstream depth versus discharge under free and submerged outflow working conditions were fitted by regression analyses, respectively. The maximum relative error between measured discharge and calculated discharge by equations was -5.63%, which met the requirements of water measurement for irrigation. Further, maximum head loss of portable short-throat flume with a flat base for the field accounted for 12.10% of total upstream head. Compared with long-throat flume, the head loss of portable short-throat flume in field was less. The three-dimensional turbulence model along with the TruVOF technique allowed one to reproduce the hydraulic characteristics of flow through portable short-throat flume in field. Due to shorter time demand and lower cost of numerical simulations compared to experimental studies in predicting the hydraulic characteristics, simulation of the portable short-throat flume in field flows based on a properly validated model provided the flow characteristics of these flumes for various flow configurations encountered in the field. This study provides a reference for flow-measurement of final stage of canal in irrigation areas in North China.

       

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