Mathematical model of continuous working process of marine steam accumulator and its performances simulation

doi:10.3969/j.issn.0438-1157.2014.z1.056

CIESC Journal ›› 2014, Vol. 65 ›› Issue (S1): 346-352.DOI: 10.3969/j.issn.0438-1157.2014.z1.056

Previous Articles Next Articles

Mathematical model of continuous working process of marine steam accumulator and its performances simulation

GUO Jiamin, SUN Baozhi, LEI Yu, ZHANG Guolei, YANG Longbin, LI Yanjun

College of Power and Energy Engineering, Harbin Engineering University, Harbin 150001, Heilongjiang, China

Received:2014-02-24 Revised:2014-03-04 Online:2014-05-30 Published:2014-05-30
Supported by:
supported by the National Defense Basic Scientific Research (B2420110004).

船用蒸汽蓄热器连续工作过程数学模型及其性能仿真

郭家敏, 孙宝芝, 雷雨, 张国磊, 杨龙滨, 李彦军

哈尔滨工程大学动力与能源工程学院, 黑龙江哈尔滨 150001

通讯作者: 孙宝芝
基金资助:
国防基础科研项目（B2420110004）。

Abstract

Abstract: According to the characteristics of marine steam accumulator, the mathematical model of continuous working process of marine steam accumulator which considered the evaporation (condensation) relaxation time is established. The accuracy of the model is validated by the experimental results of the marine steam accumulator. On this basis, the influence of the key parameters on the dynamic characteristics of the continuous charging and discharging process is studied with the simulation model. The water filling coefficient of marine steam accumulator determines the heat storage capacity of marine steam accumulator and restricts the maneuverability of the system. However, the charge and discharge pressure not only influence energy storage and conversion efficiency, but also play a key role for optimizing the volume of steam accumulator. So the relationship of the water filling coefficient and the charge and discharge pressure should be matched reasonably by taking into account the requirements of steam catapult system about the launch cycle, steam pressure and the quantity of steam, to make it not only satisfy the launch efficiency but also achieve the required steam parameters for aircraft take-off.

Key words: marine steam accumulator, continuous charging and discharging steam, the evaporation (condensation) relaxation time, mathematical model

摘要： 根据船用蒸汽蓄热器的特点，建立了考虑蒸发（冷凝）相变弛豫时间的船用蒸汽蓄热器连续工作过程数学模型，并利用实验结果验证了模型的准确性，在此基础上利用仿真模型研究了关键参数对于连续充、放汽过程动态特性的影响。船用蒸汽蓄热器的充水系数决定蓄热器的蓄热能力，同时制约着系统的机动性，而充、放汽压力在影响蒸汽能量的储存与转化效率的同时，对于能否优化蓄热器的容积起到关键作用，因此应充分考虑弹射系统对弹射周期、弹射蒸汽压力、弹射所需蒸汽量等参数的要求匹配好两者的关系，使其既能满足弹射效率又能达到舰载机起飞所需的蒸汽参数。

关键词: 船用蒸汽蓄热器, 连续充放汽, 蒸发（冷凝）弛豫时间, 数学模型

CLC Number:

U664.5

GUO Jiamin, SUN Baozhi, LEI Yu, ZHANG Guolei, YANG Longbin, LI Yanjun. Mathematical model of continuous working process of marine steam accumulator and its performances simulation[J]. CIESC Journal, 2014, 65(S1): 346-352.

郭家敏, 孙宝芝, 雷雨, 张国磊, 杨龙滨, 李彦军. 船用蒸汽蓄热器连续工作过程数学模型及其性能仿真[J]. 化工学报, 2014, 65(S1): 346-352.

References 13

[1]	Cheng Gang(程刚),Ni He(倪何),Sun Fengrui(孙丰瑞).Modeling and simulation research on naval steam-power aircraft launch system [J].Journal of Wuhan University of Technology(武汉理工大学学报),2010,34(2):301-305
[2]	Zhao Xianfeng(赵险峰).The research on the mathematical simulation of aircraft carrier steam ejection system [J].Shipborne Weapons(舰载武器),1996,3:45-49
[3]	Hu Jimin(胡继敏),Jin Jiashan(金家善),Yan Zhiteng(严志腾).Modeling and simulation for thermodynamic process steam accumulator system [J].Journal of Shanghai Jiao Tong University(上海交通大学学报),2012,46(4):545-549
[4]	Wolf-Dieter Steinmann,Markus Eck. Buffer storage for direct steam generation[J].Solar Energy,2006,80:1277-1282
[5]	Shnaider D A,Divnich P N,Vakhromeev I E. Modeling the dynamic mode of steam accumulator [J].Automation and Remote Control,2010,71(9):1994-1998
[6]	Stevanovic Vladimir D,Maslovaric Blazenka,Prica Sanja. Dynamics of steam accumulation [J].Applied Thermal Engineering,2012,37:73-79
[7]	Xu Ershu(徐二树),Gao Wei(高维),Xu Hui(徐蕙),et al.Simulation of dynamic characteristics of steam accumulators in the Badaling solar power tower plant [J].Proceedings of the CSEE(中国电机工程学报),2012,32(8):112-115
[8]	Sun Baozhi(孙宝芝),Guo Jiamin(郭家敏),Lei Yu(雷雨),et al.Non-equilibrium thermodynamics process of marine steam accumulator [J].CIESC Journal(化工学报),2013,64(S1):59-65
[9]	Hu Jimin,Jin Jiashan,Yan Zhiteng. Fluid-solid coupling numerical simulation of charge process in variable-mass thermodynamics system[J].Journal of Central South University,2012,19:1063-1072P
[10]	Hu Jimin(胡继敏),Jin Jiashan(金家善),Yan Zhiteng(严志腾).Measuring method for thermodynamic performance of marine steam accumulator during quick charge process [J].Ship Engineering(船舶工程),2012,34(S2):55-59
[11]	Hu Jimin(胡继敏),Jin Jiashan(金家善),Yan Zhiteng(严志腾).Influence steam supply parameters variation on performances of steam accumulator system [J].Journal of Naval University of Engineering(海军工程大学学报),2012,24(5):102-107
[12]	Yan Zhiteng,Jin Jiashan,Hu Jimin. Analysis on the variable operating status characteristic of steam accumulator system//Proceedings of Asia-Pacific Power and Energy Engineering Conference[C]. Shanghai, 2012
[13]	Wu Shude(吴树德).The reasonable application of steam supply system of steam accumulator [J]. Energy Research & Utilization(能源研究与利用),1989,12:14-18

[1]	Guoze CHEN, Dong WEI, Qian GUO, Zhiping XIANG. Optimal power point optimization method for aluminum-air batteries under load tracking condition [J]. CIESC Journal, 2023, 74(8): 3533-3542.
[2]	Zhaoguang CHEN, Yuxiang JIA, Meng WANG. Modeling neutralization dialysis desalination driven by low concentration waste acid and its validation [J]. CIESC Journal, 2023, 74(6): 2486-2494.
[3]	Laiming LUO, Jin ZHANG, Zhibin GUO, Haining WANG, Shanfu LU, Yan XIANG. Simulation and experiment of high temperature polymer electrolyte membrane fuel cells stack in the 1—5 kW range [J]. CIESC Journal, 2023, 74(4): 1724-1734.
[4]	Yifang DONG, Yingying YU, Xuegong HU, Gang PEI. Electric field effect on wetting and capillary flow characteristics in vertical microgrooves [J]. CIESC Journal, 2022, 73(7): 2952-2961.
[5]	Ziyi CHI, Chengwei LIU, Yuling ZHANG, Xuegang LI, Wende XIAO. Reactor simulation and optimization for CO oxidative coupling to dimethyl oxalate reactions [J]. CIESC Journal, 2022, 73(11): 4974-4986.
[6]	Huiyan WANG, Yiqin CHEN, Jinghong ZHOU, Yueqiang CAO, Xinggui ZHOU. Numerical simulation of cathode coating of lithium-ion battery for porosity optimization [J]. CIESC Journal, 2022, 73(1): 376-383.
[7]	JIANG Jiatong, HU Bin, WANG Ruzhu, LIU Hua, ZHANG Zhiping, LI Hongbo. Dynamic simulation of horizontal condenser of R1233zd(E) high temperature heat pump [J]. CIESC Journal, 2021, 72(S1): 98-105.
[8]	Yuanxin FANG, Wu XIAO, Xiaobin JIANG, Xiangcun LI, Gaohong HE, Xuemei WU. Process design and simulation of membrane separation coupled with CO₂ electrocatalytic hydrogenation to formic acid [J]. CIESC Journal, 2021, 72(9): 4740-4749.
[9]	Xuming LIANG, Yongchao SHEN, Dong WEI, Qian GUO, Zhi GAO. Analysis of output characteristics of aluminum-air battery based on DC internal resistance and AC impedance characteristics [J]. CIESC Journal, 2021, 72(8): 4361-4370.
[10]	LI Mingchuan, FAN Shuanshi, XU Fuhai, YAN Ke, HUANG Aixian. Mathematical modeling of Stefan phase change for thermal dissociation of natural gas hydrate [J]. CIESC Journal, 2021, 72(6): 3252-3260.
[11]	CHEN Yiqin, XU Yu, ZHOU Jinghong, SUI Zhijun, ZHOU Xinggui. Heterogeneous modeling and internal mass transfer mechanism of lithium-ion batteries: effect of particle size distribution [J]. CIESC Journal, 2021, 72(2): 1078-1088.
[12]	Huachen QIU, Junhong HAO, Jianxun REN. Influence on performance of thermoelectric cooling devices of thermal conductance distribution between hot and cold ends [J]. CIESC Journal, 2020, 71(S2): 39-45.
[13]	Jie ZHANG, Liping PANG, Hongquan QU, Tianbo WANG. Multi-condition thermal models of avionics pod using stochastic configuration network [J]. CIESC Journal, 2020, 71(S1): 441-447.
[14]	Shuangchen MA, Quan ZHOU, Jianzong CAO, Qi LIU, Wentong CHEN, Shuaijun FAN, Yakun YAO, Chenyu LIN, Caini MA. Modeling and simulation of wet desulfurization system dynamic process [J]. CIESC Journal, 2020, 71(8): 3741-3751.
[15]	Xianyi YU, Jianghong WU, Yunhui GAO. Research on refrigerant leakage identification for heat pump system based on PCA-SVM models [J]. CIESC Journal, 2020, 71(7): 3151-3164.

Mathematical model of continuous working process of marine steam accumulator and its performances simulation

船用蒸汽蓄热器连续工作过程数学模型及其性能仿真

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References 13

Related Articles 15

Recommended Articles

Metrics

Comments