碱性电解水制氢系统建模与仿真

黄柳燕; 巫志华; 张晨曦; 陶加银; 刘姣姣; 韩涛; 赵桦粮

doi:10.19666/j.rlfd.202505080

欢迎来到能源电力期刊网！

您当前的位置：

首页 >

文章列表页 >

碱性电解水制氢系统建模与仿真

新型发电技术 | 更新时间：2026-03-24

- 碱性电解水制氢系统建模与仿真
- 碱性电解水制氢系统建模与仿真
- 热力发电 2026年55卷第3期页码：110-118
- 作者机构：
  
  1. 西安航天科技工业有限公司
  2. 西安航天动力研究所
  3. 西安航天远征流体控制股份有限公司
  4. 北京合工仿真技术有限公司
  5. 武汉理工大学现代汽车零部件技术湖北省重点实验室
- 作者简介：
- 基金信息：
- DOI：10.19666/j.rlfd.202505080
  中图分类号： TQ116.21
- 纸质出版：2026
- 稿件说明：
移动端阅览
[1]黄柳燕,巫志华,张晨曦,等.碱性电解水制氢系统建模与仿真[J].热力发电,2026,55(03):110-118.
[1]黄柳燕,巫志华,张晨曦,等.碱性电解水制氢系统建模与仿真[J].热力发电,2026,55(03):110-118. DOI： 10.19666/j.rlfd.202505080.

DOI：10.19666/j.rlfd.202505080.

摘要

针对现有碱性电解水制氢技术主要聚焦于电解槽性能试验、电解小室流场优化等方面，鲜有关注制氢系统的整体描述与关键设备的机理建模仿真。采用g PROMS过程模拟软件，参考化工流程模拟方法，以某200 m3/h（标况，下同）碱性电解水制氢系统为研究对象，建立了基于机理分析的分布式参数模型，对系统关键设备进行精细化建模与仿真计算。通过将仿真结果与实验数据进行对比验证，结果表明系统主要性能参数的模拟值与实测数据具有良好的一致性，经计算平均误差小于5%，验证了模型的有效性，所建立的模型能够描述和预测系统参数的变化，为后续系统设计、优化及控制提供方法及支撑。

Abstract

The existing alkaline electrolysis hydrogen production technology primarily focuses on performance testing of electrolyzers and optimization of flow fields in electrolysis cells

and little attention is paid to overall description of the hydrogen production system as well as the mechanism modeling and simulation of key equipment. To solve this problem

using gPROMS process simulation software and referencing chemical process simulation methods

a distributed parameter model based on mechanism analysis was established for a 200 m³/h(standard condition) alkaline water electrolysis hydrogen production system. The key equipment of the system was finely modeled and simulated. By comparing the simulation results with experimental data

the results show that the simulated values of the main performance parameters of the system have good consistency with the measured data. The calculated average error is less than 5%

which verifies the effectiveness of the model. The established model can describe and predict the changes in system parameters

providing methods and support for subsequent system design

optimization

and control.

关键词

Keywords

references

刘冰.京能鄂托克前旗250 MW光伏电站及氢能综合利用示范项目可行性研究报告[R].北京:北京能源集团, 2022:7-8.LIU Bing. Feasibility study report on Jingneng Ejin Horo Front Banner 250 MW photovoltaic power station and hydrogen energy comprehensive utilization demonstration project[R]. Beijing:Beijing Energy Group, 2022:7-8.

聂知力.新型碱性电解槽实验研究[D].北京:北京化工大学, 2023:1.NIE Zhili. Experimental study of a new alkaline electrolyzer[D]. Beijing:Beijing University of Chemical Technology, 2023:1.

黄登高,尹玉国,胡石林,等.碱液流量对水电解槽运行的影响[J].河南化工, 2013(33):26-28.HUANG Denggao, YIN Yuguo, HU Shilin, et al. Effect of alkali solution flow rate on water electrolyzer operation[J]. Henan Chemical Industry, 2013(33):26-28.

石航博.碱水制氢电解槽的开发与流场仿真及优化研究[D].北京:北京化工大学, 2023:1.SHI Hangbo. Development and flow field simulation of alkaline electrolyzer for hydrogen production[D]. Beijing:Beijing University of Chemical Technology, 2023:1.

李军.压滤式电解槽电解单元内流动特性的模拟研究[D].北京:中国石油大学, 2020:1.LI Jun. Simulation study on flow characteristics in the unit of filter-press water electrolyzer[D]. Beijing:China University of Petroleum, 2020:1.

GAO L Y, YANG L, WANG C H, et al. Three-dimensional two-phase CFD simulation of alkaline electrolyzers[J].Journal of Electrochemistry, 2023, 29(9):1-16.

赵欢欢.碱性固体聚合物水电解槽流道模拟与优化设计[D].哈尔滨:哈尔滨工业大学, 2010:1.ZHAO Huanhuan. Simulation and optimization design on flow channel of alkaline solid polymer electrolyte cell[D].Harbin:Harbin Institute of Technology, 2010:1.

SCHILLINGS J, DOCHE O, DESEURE J. Modeling of electrochemically generated bubbly flow under buoyancydriven and forced convection[J]. International Journal of Heat and Mass Transfer, 2015, 85:292-299.

WEDIN R, DAHLKILD A A. On the transport of small bubbles under developing channel flow in a Buoyant gasevolving electrochemical cell[J]. Industrial&Engineering Chemistry Research, 2001, 40:5228-5233.

BOISSONNEAU P, BYRNE P. An experimental investigation of bubble-induced free convection in a small electrochemical cell[J]. Journal of Applied Electrochemistry, 2000, 30:767-775.

OKONKWO C P, BHOWMIK H, MANSIR B I, et al.Effect of electrode spacing on hydrogen production using a home-made alkaline electrolyzer[J]. Materials Letters,2022, 36:130841.

FABRIZIO G, LOMBARDO S, SUNSERI C, et al.Nanostructured electrodes for hydrogen production in alkaline electrolyzer[J]. Renewable Energy, 2018, 123:117-124.

王琦.风能光能发电制氢系统的仿真模拟及性能分析[D].广州:华南理工大学, 2021:1.WANG Qi. Simulation and performance analysis of wind and solar power to hydrogen system[D]. Guangzhou:South China University of Technology, 2021:1.

王侃宏,赵政通,罗景辉,等.风光互补发电制氢储能系统模拟研究及性能分析[J].节能, 2019(11):79-84.WANG Kanhong, ZHAO Zhengtong, LUO Jinghui, et al.Simulation and performance analysis of hydrogen storage system for wind and solar complementary power generation[J]. Energy Conservation, 2019(11):79-84.

苗伟杰,窦真兰,张春雁,等.风-光-氢多能互补系统仿真建模方法综述[J].上海节能, 2022(1):46-55.MIAO Weijie, DOU Zhenlan, ZHANG Chunyan, et al.Overview of simulation modeling methods on wind-solarhydrogen multi-energy complementary system[J].Shanghai Energy Conservation, 2022(1):46-55.

李洋洋,邓欣涛,古俊杰,等.碱性水电解制氢系统建模综述及展望[J].汽车工程, 2022, 44(4):567-582.LI Yangyang, DENG Xintao, GU Junjie, et al.Comprehensive review and prospect of modeling of alkaline water electrolysis system for hydrogen production[J]. Automotive Engineering, 2022, 44(4):567-582.

OLIVIER P, BOURASSEAU C, BOUAMAMA B. Lowtemperature electrolysis system modeling:a review[J].Renewable and Sustainable Energy Reviews, 2017, 78:280-300.

SHEN X J, ZHANG X Y, LIE T T, et al. Mathematical modeling and simulation for external electrothermal characteristics of an alkaline water electrolyzer[J]. Energy Research, 2018, 42:3899-3914.

ZOUHRI K, LEE S. Evaluation and optimization of the alkaline water electrolysis ohmic polarization:energy study[J]. International Journal of Hydrogen Energy, 2016,41:7253-7263.

NIROULA S, CHAUDHARY C, SUBEDI A, et al.Parametric modelling and optimization of alkaline electrolyzer for the production of green hydrogen[J]. IOP Conference Series:Materials Science and Engineering,2023, 1279:012005.

ABDIN Z, WEBB C J, GRAY E M. Modelling and simulation of an alkaline electrolyser cell[J]. Energy,2017, 138:316-331.

WANG Y, REN S L, CHE X J, et al. Dynamic simulation of wind-powered alkaline water electrolysis system for hydrogen production[J]. International Journal of Hydrogen Energy, 2025, 97:391-405.

张立栋,陈怡冰,龚明,等.质子交换膜电解水制氢影响因素的过程模拟[J].综合智慧能源, 2022, 33(5):88-94.ZHANG Lidong, CHEN Yibing, GONG Ming, et al.Process simulation of factors affecting proton exchange membrane water electrolysis for hydrogen production[J].Integrated Intelligent Energy, 2022, 33(5):88-94.

IREM F E. Thermodynamic and electrochemical assessment of an alkaline electrolyzer(AE)at different operating parameters[J]. Journal of Environmental Chemical Engineering, 2022, 10(2):107225.

SANCHEZ M, AMORES E, RODRIGUEZ L, et al. Semiempirical model and experimental validation for the performance evaluation of a 15 k W alkaline water electrolyzer[J]. International Journal of Hydrogen Energy,2018, 43:20332-20345.

刘浩.调节阀机理模型的建模与参数辨识[D].杭州:杭州电子科技大学, 2016:1.LIU Hao. Mechanism modeling and parameter identigication of regulating valve[D]. Hangzhou:Hangzhou Dianzi University, 2016:1.

WHITE M K. Fluid mechanics[M]. 7th ed. New York:Mc Graw-Hill Series in Mechanical Engineering, 2009:347-453.

胡寿松.自动控制原理[M]. 7版北京:科学出版社,2019:252-288.HU Shousong. Automatic control principles[M]. 7th ed.Beijing:Science Press, 2019:252-288.

浏览量

下载量

CSCD

文章被引用时，请邮件提醒。

提交

工具集

关联资源

基于系统动力学的省煤器建模与仿真

基于神经网络的大型轴流风机能耗特性分析

采用序贯模块法建立余热锅炉动态模型研究

一种炉膛压力测量信号的处理方法

基于Blink的UCC控制系统仿真