基于CFD的Venlo型温室多环境因子优化策略研究

doi:10.12133/j.smartag.SA202502002

摘要/Abstract

摘要：

【目的/意义】 该研究结合计算流体力学（Computational Fluid Dynamics, CFD）模型与多目标粒子群优化（Multi-Objective Particle Swarm Optimization, MOPSO）算法搭建联合优化框架，期望解决Venlo型连栋玻璃温室在夏季机械通风时因调控策略模糊造成的环境不均匀性及运行能耗偏大的问题。 【方法】 通过温室内部布设的环境监测传感器，采集温度、湿度、风速及CO₂浓度等环境数据进行温室环境场的仿真与验证。通过在CFD模型中调整特定范围内的风机-湿帘系统运行参数，自定义3种环境评价函数用以平衡环境偏差与能耗投入的多目标冲突问题，进而得到该场景下温室环控策略的最佳范围。 【结果和讨论】 CFD模型的环境场仿真精度较高，温度与风速的平均相对误差分别为4.6%和6.8%。提出的优化策略可以对温室内部环境实现闭环迭代评价，输出结果中风机出口风速为2.8~5.4 m/s，湿帘入口温度为295.3~299.7 K。 【结论】 该环控策略下的各评价函数均为互不支配的理想情况，组合策略有助于优化作物生长环境，降低温室运行能耗。该研究可为温室机械通风的均匀性、经济性调控提供参考。

关键词: 温室, 环控策略, 多目标优化, CFD, 机械通风, 多目标粒子群优化

Abstract:

[Objective] In the context of modern agricultural practices, regulating the indoor microclimate of Venlo-type greenhouses during the summer months through mechanical ventilation remains a significant challenge. This is primarily due to the nonlinear dynamics and strong coupling characteristics inherent in greenhouse environmental systems, where variables such as temperature, humidity, and CO₂ concentration interact in complex, interdependent ways. Traditional control strategies, which often rely heavily on empirical knowledge and manual intervention, are insufficient to cope with such dynamic conditions. These approaches tend to result in imprecise control, substantial time delays in response to environmental fluctuations, and unnecessarily high energy consumption during ventilation operations. Therefore, this study combines computational fluid dynamics (CFD) model with a multi-objective particle swarm optimization (MOPSO) algorithm to establish a joint optimization framework, aiming to address the issues of significant time delays and excessive operational energy consumption caused by vague environmental control strategies in this scenario. [Methods] To build a reliable simulation and optimization framework, environmental parameters such as temperature, wind speed, and CO₂ concentration were continuously collected via a network of environmental monitoring sensors installed at various positions inside the greenhouse. These real-time data served as validation benchmarks for the CFD model and supported the verification of mesh independence. In the CFD model construction, the internal structure of the Venlo-type greenhouse was precisely reconstructed, and appropriate boundary conditions were set based on empirical data. The airflow dynamics and thermal field were simulated using a finite volume-based solver. Four grid resolutions were evaluated for grid independence by comparing the variations in output metrics. The controllable parameters in the model included fan outlet wind speed and cooling pad condensation temperature. These parameters were systematically varied within predefined ranges. To evaluate the greenhouse environmental quality and energy consumption under different control conditions, three custom-defined objective functions were proposed: temperature suitability, CO₂ uniformity, and fan operating energy consumption. The MOPSO algorithm was then applied to conduct iterative optimization over the defined parameter space. At each step, the objective functions were recalculated based on CFD outputs, and Pareto-optimal solutions were identified using non-dominated sorting. After iterative optimization using the algorithm, the conflicting objectives of environmental deviation and energy consumption were balanced, leading to the optimal range for the greenhouse environmental control strategy in this scenario. [Results and Discussions] The experimental results showed that the environmental field simulation accuracy of the CFD model was high, with an average relative error of 5.7%. In the grid independence test, three grid types, coarse, medium, and fine, were selected. The variations in the grid divisions were 1.7% and 0.6%, respectively. After considering both computational accuracy and efficiency, the medium grid division standard was adopted for subsequent simulations. The optimization strategy proposed in this study allows for closed-loop evaluation of the environment. The algorithm set the population size to 100 particles, and within the specified range of fan outlet wind speed and cooling pad condensation temperature, each particle iterates 5 times for optimization. The position updated in each iteration was used to calculate the values of the three objective evaluation functions, followed by non-dominated comparison and adaptation of the solutions, until the optimization was complete. In the Pareto surface fitted by the output results, the fan outlet wind speed ranges from 2.8 to 5.4 m/s, and the inlet temperature ranges from 295.3 to 299.7 K. Since the evaluation functions under the environmental control strategy were all in an ideal, non-dominated state, two sets of boundary control conditions were randomly selected for simulation: operating Condition A [296 K, 3.5 m/s] and operating Condition B [299 K, 5 m/s]. Post-processing contour plots showed that both operating conditions achieve good environmental optimization uniformity. The approximate ranges for each parameter were: temperature from 300.3 to 303.9 K, wind speed from 0.7 to 2.3 m/s, and CO₂ concentration from 2.43 × 10^-5 to 3.56 × 10^-5 kmol/m³. Based on environmental uniformity optimization, operating Condition A focused on adjusting the suitable temperature for crops by lowering the cooling pad condensation temperature, but there was a relative stagnation of CO₂. Operating Condition B, by increasing the fan outlet wind speed, focused on regulating CO₂ flow and diffusion, but the gradient change of airflow near the two side walls was relatively abrupt. [Conclusions] This study complements the research on the systematic adjustment of greenhouse environmental parameters, while its closed-loop iterative features also enhance the simulation efficiency. The simulation results show that by arbitrarily combining the optimal solution set within the theoretical range of the strategy output, optimization of the targeted objectives can be achieved by appropriately discarding other secondary objectives, providing a reference for regulating the uniformity and economy of mechanical ventilation in greenhouses. Subsequent research can further quantify the coupling effects and weight settings of each objective function to improve the overall optimization of the functions.

Key words: greenhouse, environmental control strategy, multi-objective optimization, CFD, mechanical ventilation, multi-objective particle swarm optimization

中图分类号:

S625.5+1

聂鹏程, 陈禹霏, 黄璐, 李雪寒. 基于CFD的Venlo型温室多环境因子优化策略研究[J]. 智慧农业(中英文), 2025, 7(3): 199-209.

NIE Pengcheng, CHEN Yufei, HUANG Lu, LI Xuehan. Multi Environmental Factor Optimization Strategies for Venlo-type Greenhouses Based on CFD[J]. Smart Agriculture, 2025, 7(3): 199-209.

图/表 15

图1

图2

表1

温室CFD模型材料参数

材料属性		数值
玻璃	密度/（kg/m³）	2 500
	导热系数/［W/（m·K）^-1］	0.71
	厚度/mm	6
	温度/℃	38.2
空气	密度/（kg/m³）	1.165
	相对湿度/%	76.3
	导热系数/［W/（m·K）^-1］	2.71 $×$ 10^-2
	动力黏度/Pa·s	1.81 $×$ 10^-5
CO₂	浓度/（mg/m³）	700
地面	导热系数/［W/（m·K）^-1］	1.4
	厚度/m	0.1
	温度/℃	32.8
作物	冠层阻力系数	0.322
	叶面积指数/（m²/m³）	2.8
	冠层温度/℃	34.3
	冠层气流速度/（m/s）	0.67
	气孔阻抗/（s/m）	640

表1

图3

图4

图5

图6

表2

图7

图8

图9

图10

图11

表3

温室多环境因子优化效果

工况类型	$J T$	$J C O 2$	$J e n e r g y$
初始工况	4.74	63	5.6
工况A	1.49	37	2.7
工况B	2.36	26	3.5

表3

图12

参考文献 38

[1]	丁小明, 魏晓明, 李明, 等. 世界主要设施园艺国家发展现状[J]. 农业工程技术, 2016, 36(1): 22-32.
	DING X M, WEI X M, LI M, et al. Development status of major horticultural facilities in the world [J]. Agricultural engineering technology, 2016, 36(1): 22-32.
[2]	徐航, 李雄彦, 徐开亮. 大型连栋温室的研究现状[J]. 建筑结构, 2021, 51(S2): 393-398.
	XU H, LI X Y, XU K L. Research status of large connected greenhouses [J]. Building structure, 2021, 51(S2): 393-398.
[3]	赵杰强, 赵云. 机械通风连栋温室的温度场CFD模拟[J]. 中国农机化学报, 2014, 35(6): 76-79.
	ZHAO J Q, ZHAO Y. Computational fluid dynamics simulation on temperature field of mechanical ventilation for multi-span greenhouse[J]. Journal of Chinese agricultural mechanization, 2014, 35(6): 76-79.
[4]	OKUSHIMA L, SASE S, NARA M. A support system for natural ventilation design of greenhouses based on computational aerodynamics[J]. Acta horticulture, 1989(248): 129-136.
[5]	乌日力格, 崔世茂, 宋阳, 等. 蓄热水管对日光温室温度环境的影响[J]. 中国蔬菜, 2018(9): 54-59.
	WU R, CUI S M, SONG Y, et al. Effect of heat-accumulated water pipe on thermal environment of solar greenhouse[J]. China vegetables, 2018(9): 54-59.
[6]	SI C Q, QI F, DING X M, et al. CFD analysis of solar greenhouse thermal and humidity environment considering soil–crop–back wall interactions[J]. Energies, 2023, 16(5): ID 2305.
[7]	ALAOUI MEL, CHAHIDI L O, ROUGUI M, et al. Evaluation of CFD and machine learning methods on predicting greenhouse microclimate parameters with the assessment of seasonality impact on machine learning performance[J]. Scientific African, 2023, 19: ID e01578.
[8]	LYU X, XU Y Q, WEI M, et al. Effects of vent opening, wind speed, and crop height on microenvironment in three-span arched greenhouse under natural ventilation[J]. Computers and electronics in agriculture, 2022, 201: ID 107326.
[9]	ABDERRAHMAN M, ABDELAZIZ B, ABDELKADER O. CFD modeling of an even-span greenhouse dryer under natural and forced convection modes[J]. Journal of physics: conference series, 2021, 2022(1): ID 012030.
[10]	KIM R W, LEE I B, KWON K S. Evaluation of wind pressure acting on multi-span greenhouses using CFD technique, Part 1: Development of the CFD model[J]. Biosystems engineering, 2017, 164: 235-256.
[11]	严露露, 荆海薇, 鲍恩财, 等. 不同自然通风方式对日光温室性能的影响[J]. 中国农业大学学报, 2020, 25(3): 71-78.
	YAN L L, JING H W, BAO E C, et al. Effects of different natural ventilation methods on the performance of solar greenhouse[J]. Journal of China agricultural university, 2020, 25(3): 71-78.
[12]	李亮亮, 王新忠, 洪亚杰, 等. 不同遮阳工况下温室作物冠层辐射场与温度场的CFD分析[J]. 农机化研究, 2019, 41(11): 192-197.
	LI L L, WANG X Z, HONG Y J, et al. Analysis of canopy radiation and temperature field in greenhouse under different shading conditions based on CFD[J]. Journal of agricultural mechanization research, 2019, 41(11): 192-197.
[13]	ABID H, KETATA A, LAJNEF M, et al. Impact of greenhouse roof height on microclimate and agricultural practices: CFD and experimental investigations[J]. Journal of thermal analysis and calorimetry, 2024, 149(11): 5483-5495.
[14]	VIVEKANANDAN M, PERIASAMY K, DINESH BABU C, et al. Experimental and CFD investigation of six shapes of solar greenhouse dryer in no load conditions to identify the ideal shape of dryer[J]. Materials today: Proceedings, 2021, 37: 1409-1416.
[15]	陆清清. 内遮阳保温幕在冬夏季对温室内部环境影响的研究[D]. 上海: 东华大学, 2022.
	LU Q Q. Study on the effect of internal thermal screens on the internal environment of greenhouse in winter and summer[D]. Shanghai: Donghua University, 2022.
[16]	万敏, 杨魏, 刘竹青, 等. 不同通风方式日光温室微环境模拟与作物蒸腾研究[J]. 农业机械学报, 2024, 55(1): 328-338, 349.
	WAN M, YANG W, LIU Z Q, et al. Microenvironment simulation and crop transpiration analysis of solar greenhouse with different ventilation modes[J]. Transactions of the Chinese society for agricultural machinery, 2024, 55(1): 328-338, 349.
[17]	张国祥, 刘星星, 张领先, 等. 基于CFD的日光温室温度与卷帘开度关系研究[J]. 农业机械学报, 2017, 48(9): 279-286.
	ZHANG G X, LIU X X, ZHANG L X, et al. Relationship between indoor temperature and rolling shutter opening of solar greenhouse based on CFD[J]. Transactions of the Chinese society for agricultural machinery, 2017, 48(9): 279-286.
[18]	AISSA M, BOUTELHIG A. CFD comparative study between different forms of solar greenhouses and orientation effect[J]. International journal of heat and technology, 2021, 39(2): 433-440.
[19]	成珂, 马晓瑶, 孙琦琦. 光伏温室大棚组件布置CFD模拟研究[J]. 太阳能学报, 2021, 42(8): 159-165.
	CHENG K, MA X Y, SUN Q Q. CFD simulation study on module layout of photovoltaic greenhouse[J]. Acta energiae solaris sinica, 2021, 42(8): 159-165.
[20]	方慧, 杨其长, 张义, 等. 基于CFD的不同走向大跨度保温型温室温度场模拟[J]. 中国农业大学学报, 2017, 22(11): 133-139.
	FANG H, YANG Q C, ZHANG Y, et al. Prediction model on air temperature in large-span greenhouse with different orientation based on CFD[J]. Journal of China agricultural university, 2017, 22(11): 133-139.
[21]	ZHANG G X, FU Z T, YANG M S, et al. Nonlinear simulation for coupling modeling of air humidity and vent opening in Chinese solar greenhouse based on CFD[J]. Computers and electronics in agriculture, 2019, 162: 337-347.
[22]	MAO C, SU Y P. CFD based heat transfer parameter identification of greenhouse and greenhouse climate prediction method[J]. Thermal science and engineering progress, 2024, 49: ID 102462.
[23]	CHENG X, LI D M, SHAO L M, et al. A virtual sensor simulation system of a flower greenhouse coupled with a new temperature microclimate model using three-dimensional CFD[J]. Computers and electronics in agriculture, 2021, 181: ID 105934.
[24]	高振军, 李斯亮, 司长青, 等. 湿帘风机安装高度对Venlo温室降温效果分析[J]. 农业工程学报, 2022, 38(S1): 257-264.
	GAO Z J, LI S L, SI C Q, et al. Analysis of cooling effect on the Venlo greenhouse depending on the installation height of wet curtain and fan[J]. Transactions of the Chinese society of agricultural engineering, 2022, 38(S1): 257-264.
[25]	YIN H R, WANG K J, ZENG J D, et al. CFD analysis and optimization of a plastic greenhouse with a semi-open roof in a tropical area[J]. Agronomy, 2024, 14(4): ID 876.
[26]	HE X L, WANG J, GUO S R, et al. Ventilation optimization of solar greenhouse with removable back walls based on CFD[J]. Computers and electronics in agriculture, 2018, 149: 16-25.
[27]	VILLAGRÁN E A, BAEZA ROMERO E J, BOJACÁ C R. Transient CFD analysis of the natural ventilation of three types of greenhouses used for agricultural production in a tropical mountain climate[J]. Biosystems engineering, 2019, 188: 288-304.
[28]	MAO Q J, JI C C, LI H W, et al. Dynamic temperature distribution characteristics of a large glasshouse with cooling system during the start-stop stage[J]. Computers and electronics in agriculture, 2024, 220: ID 108913.
[29]	DAHLAN N Y, AMIRUDDIN A, LUONG NDUC, et al. Energy and climate analysis of greenhouse system for tomatoes cultivation using CFD and open studio energy plus software[J]. International journal of engineering & technology, 2018, 7(3.11): ID 183.
[30]	周伟. 温室环境CFD非稳态模型构建及其在温室温度控制中的应用研究[D]. 南京: 南京农业大学, 2014.
	ZHOU W. CFD unsteady modeling for greenhouse environment and its application in greenhouse temperature control[D]. Nanjing: Nanjing Agricultural University, 2014.
[31]	李明高, 李明主编, 李国清, 韩璐等编著. ANSYS 13.0流场分析技术及应用实例[M]. 北京: 机械工业出版社, 2012.
	LI M G, LI M Ed., LI G Q, HAN L, et al. ANSYS 13.0: Flow field analysis techniques and practical application examples[M]. Beijing: China Machine Press, 2012.
[32]	ABIBOU S, BOURAKADI DEL, YAHYAOUY A, et al. Optimizing hydrogen refueling station recommendations: A comparative analysis between genetic algorithm and particle swarm optimization[J]. SN computer science, 2024, 5(8): ID 991.
[33]	QOMARIYAH N N, KAZAKOV D. A genetic-based pairwise trip planner recommender system[J]. Journal of big data, 2021, 8(1): ID 77.
[34]	丁青锋, 尹晓宇. 差分进化算法综述[J]. 智能系统学报, 2017, 12(4): 431-442.
	DING Q F, YIN X Y. Research survey of differential evolution algorithms[J]. CAAI transactions on intelligent systems, 2017, 12(4): 431-442.
[35]	周黎, 周承恩, 李海滨. 寻求“理想” 解的改进多目标粒子群优化算法[J]. 控制与决策, 2015, 30(9): 1653-1659.
	ZHOU L, ZHOU Cheng'en, LI H B. Improved multi-objective particle swarm optimization algorithm that can give "ideal" solution[J]. Control and decision, 2015, 30(9): 1653-1659.
[36]	SCHOTT J. Fault tolerant design using single and multicriteria genetic algorithm optimization[D]. Cambridge: Department of Aeronautics and Astronautics. Massachusetts Institute of Technology, 1995: 76-77.
[37]	LEE J, LEE H, LEE S, et al. Effects of environmental substrate composition on the growth and yield of hydroponically grown tomato[J]. Journal of environmental science international, 2019, 28(9): 729-735.
[38]	徐立鸿, 孟凡峥, 蔚瑞华. 秒尺度温室番茄作物-环境互作模型构建与验证[J]. 农业工程学报, 2021, 37(8): 212-222.
	XU L H, MENG F Z, WEI R H. Development and verification of tomato crop-environment interaction model in second timescale greenhouse[J]. Transactions of the Chinese society of agricultural engineering, 2021, 37(8): 212-222.

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