压缩空气储能驱动反渗透海水淡化系统

doi:10.19799/j.cnki.2095-4239.2021.0231

储能科学与技术 ›› 2021, Vol. 10 ›› Issue (5): 1597-1606.doi: 10.19799/j.cnki.2095-4239.2021.0231

• 物理储能十年专刊·压缩空气 • 上一篇下一篇

压缩空气储能驱动反渗透海水淡化系统

郑澳辉¹(), 曹峥¹, 徐玉杰², 陈海生², 邓建强¹()

^1.西安交通大学化学工程与技术学院，陕西西安 710049
^2.中国科学院工程热物理研究所，北京 100190

收稿日期:2021-05-27 修回日期:2021-07-03 出版日期:2021-09-05 发布日期:2021-09-08
作者简介:郑澳辉（1999—），男，硕士研究生，研究方向为化工机械与设备，E-mail： wind0802@stu.xjtu.edu.cn|邓建强，教授，研究方向为压缩空气储能技术，高效化工机械与设备，E-mail：dengjq@xjtu.edu.cn。
基金资助:
国家重点研发计划资助项目(2017YFB0903600)

A compressed air energy storage system driving reverse osmosis desalination system

Aohui ZHENG¹(), Zheng CAO¹, Yujie XU², Haisheng CHEN², Jianqiang DENG¹()

^1.School of Chemical Engineering and Technology, Xi'an Jiaotong University, Xi'an 710049, Shaanxi, China
^2.Institute of Engineering Thermophysics, Chinese Academy of Sciences, Beijing 100190, China

Received:2021-05-27 Revised:2021-07-03 Online:2021-09-05 Published:2021-09-08

摘要/Abstract

摘要：

为解决传统反渗透海水淡化系统高能耗、高成本等问题，利用压缩空气储能系统对电力资源削峰填谷的作用并依据其能量输出特点，进行能量配比分析，提出了绝热压缩空气储能与反渗透海水淡化集成系统新构型。建立了系统各部件的数学模型，以20 s为时间步长，对系统的不同设计工况进行了动态模拟，并采用经典龙格库塔算法进行求解，分析了储罐充能释能结束压力和季节变化对系统性能的影响，最后对系统部件的投资成本进行估算，获得了系统在不同设计工况点的淡水生产成本。结果表明，在所有的模拟工况点中，储罐释能结束压力在3～7 MPa内变化时，无论储罐充能结束压力在8～12 MPa内取何值，释能结束压力均存在最优值5 MPa，使系统淡水生产比能耗最低；相比于冬季低温环境，夏季高温环境淡水的生产比能耗能减少约30%；在所有的模拟工况点中，当充能结束压力为12 MPa，释能结束压力为5 MPa时，系统淡水生产成本最低，为1.72 $/m³。与传统反渗透海水淡化系统相比，本储能驱动的淡水生产成本最大能够降低4.4%，具有更好的经济效益。本研究有助于推动绝热压缩空气储能系统在反渗透海水淡化领域的应用，并为工厂的投资建设提供理论依据。

关键词: 绝热压缩空气储能, 反渗透海水淡化, 淡水生产比能耗, 淡水产量, 淡水生产成本

Abstract:

To solve the problems of high-energy consumption and the high cost of traditional reverse osmosis (RO) desalination systems, an innovative hybrid adiabatic compressed air energy storage system (ACAES) and RO desalination was proposed. The system was based on the improvement of adiabatic compressed air energy storage on the fluctuation of grid load and its output characteristics. The mathematical model of each part of the hybrid system was established, and the dynamic simulation of the system under different design conditions was carried out using 20 s time steps. The classic Runge-Kutta algorithm was used to solve the problem. Then, the effect of the storage pressure range and seasonal variation on the system's performance was analyzed. Meanwhile, the investment cost was estimated, and the economy of the hybrid system was evaluated under different design conditions. The results showed that, in all of the simulated working conditions, when the end pressure of discharge (EPD) changed within 3～7 MPa, regardless of whether the end pressure of charge (EPC) was within 8～12 MPa, the optimal value of the EPD was 5 MPa; this rendered the specific energy consumption (SEC) of freshwater production by the system the lowest. SEC in high summer temperatures could be reduced by approximately 30% compared to low temperatures in winter. In all simulated working conditions, when the EPC was 12 MPa and the EPD was 5 MPa, the SEC had a minimum value of 1.72 USD/m³. Compared with a traditional RO desalination system, the unit price for producing freshwater using this hybrid system could be reduced by a maximum of 4.4%, thereby achieving better economic performance. This study helps promote the application of A-CAES in the field of RO desalination and provides a theoretical basis for the construction of such a power plant.

Key words: ACAES, RO desalination, SEC of fresh water production, fresh water production, unit price of freshwater

中图分类号:

TK 02

郑澳辉, 曹峥, 徐玉杰, 陈海生, 邓建强. 压缩空气储能驱动反渗透海水淡化系统[J]. 储能科学与技术, 2021, 10(5): 1597-1606.

Aohui ZHENG, Zheng CAO, Yujie XU, Haisheng CHEN, Jianqiang DENG. A compressed air energy storage system driving reverse osmosis desalination system[J]. Energy Storage Science and Technology, 2021, 10(5): 1597-1606.

图/表 14

图1

表1

设备投资成本"

设备	投资成本/USD
压缩机	$I C c = 71.1 × m a 0.92 - η c × π c × l n π c$
膨胀机	$I C e = 6000 × W e / 1000 0.7$
换热器	$I C h x = 130 × A h x / 0.093 0.78$
储罐	$I C p = 4042 × V s t 0.506$
反渗透海水淡化模块	$I C R O = 8000 / 6.4 × Q i n$

表1

表2

图2

表3

表4

图3

图4

图5

图6

图7

图8

图9

图10

参考文献 17

1	ELIMELECH M, PHILLIP W A. The future of seawater desalination: Energy, technology, and the environment[J]. Science, 2011, 333(6043): 712-717.
2	LUO J Q, CAO W F, DING L H, et al. Treatment of dairy effluent by shear-enhanced membrane filtration: The role of foulants[J]. Separation and Purification Technology, 2012, 96: 194-203.
3	EKE J, YUSUF A, GIWA A, et al. The global status of desalination: An assessment of current desalination technologies, plants and capacity[J]. Desalination, 2020, 495: doi: 10.1016/j.desal.2020.114633.
4	KIM J, PARK K, YANG D R, et al. A comprehensive review of energy consumption of seawater reverse osmosis desalination plants[J]. Applied Energy, 2019, 254: doi: 10.1016/j.apenergy.2019.113652.
5	VENKATARAMANI G, PARANKUSAM P, RAMALINGAM V, et al. A review on compressed air energy storage—A pathway for smart grid and polygeneration[J]. Renewable and Sustainable Energy Reviews, 2016, 62: 895-907.
6	GALLO A B, SIMÕES-MOREIRA J R, COSTA H K, et al. Energy storage in the energy transition context: A technology review[J]. Renewable and Sustainable Energy Reviews, 2016, 65: 800-822.
7	LUO X, WANG J H, DOONER M, et al. Overview of current development in electrical energy storage technologies and the application potential in power system operation[J]. Applied Energy, 2015, 137: 511-536.
8	GUO H, XU Y J, CHEN H S, et al. Corresponding-point methodology for physical energy storage system analysis and application to compressed air energy storage system[J]. Energy, 2018, 143: 772-784.
9	ZHOU Q, DU D M, LU C, et al. A review of thermal energy storage in compressed air energy storage system[J]. Energy, 2019, 188: doi: 10.1016/j.energy.2019.115993.
10	GUDE V G. Energy consumption and recovery in reverse osmosis[J]. Desalination and Water Treatment, 2011, 36(1/2/3): 239-260.
11	ZHANG N, CAI R X. Analytical solutions and typical characteristics of part-load performances of single shaft gas turbine and its cogeneration[J]. Energy Conversion and Management, 2002, 43(9/10/11/12): 1323-1337.
12	WANG W, CAI R X, ZHANG N. General characteristics of single shaft microturbine set at variable speed operation and its optimization[J]. Applied Thermal Engineering, 2004, 24(13): 1851-1863.
13	HE Y, ZHOU S H, XU Y J, et al. The influence of charging process on trigenerative performance of compressed air energy storage system[J]. International Journal of Energy Research, 2020, doi: 10.1002/er.5366.
14	QI B W, WANG Y, XU S C, et al. Operating energy consumption analysis of RO desalting system: Effect of membrane process and energy recovery device (ERD) performance variables[J]. Industrial & Engineering Chemistry Research, 2012, 51(43): 14135-14144.
15	YAO E R, WANG H R, WANG L G, et al. Multi-objective optimization and exergoeconomic analysis of a combined cooling, heating and power based compressed air energy storage system[J]. Energy Conversion and Management, 2017, 138: 199-209.
16	吴云奇, 贾麟, 闫玉莲, 等. 大型海水淡化工程投资和成本分析[J]. 盐科学与化工, 2021, 50(3): 6-9.
	WU Y Q, JIA L, YAN Y L, et al. Investment and cost analysis of large scale seawater desalination project[J]. Journal of Salt Science and Chemical Industry, 2021, 50(3): 6-9.
17	叶晓琰, 许国乐, 胡敬宁. 反渗透海水淡化高压泵的优化选择[J]. 水处理技术, 2008, 34(9): 79-81, 91.
	YE X Y, XU G L, HU J N. The selection and optimization of high-pressure pump in reverse osmosis seawater desalination[J]. Technology of Water Treatment, 2008, 34(9): 79-81, 91.

参数	数值
环境压力/kPa	101
压缩机额定气体流量/(kg·s^-1)	10
压缩机额定效率	85%
压缩机额定进气温度/℃	25
膨胀机额定气体流量/(kg·s^-1)	10
膨胀机额定效率	88%
膨胀机额定进气温度/℃	25
冷却水流量/(kg·s^-1)	5
预热水流量/(kg·s^-1)	5

压缩机组背压/MPa	额定压比	额定功率/MW
8	3.056	1.460
9	3.144	1.504
10	3.225	1.543
11	3.301	1.580
12	3.371	1.670

膨胀机组进气压力/MPa	额定膨胀比	额定功率/MW
3	1.895	0.547
4	2.015	0.597
5	2.112	0.635
6	2.195	0.665
7	2.267	0.691

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压缩空气储能驱动反渗透海水淡化系统

A compressed air energy storage system driving reverse osmosis desalination system

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