新型相同钠离子混合熔盐相图预测及物性测量

doi:10.19799/j.cnki.2095-4239.2021.0320

摘要/Abstract

摘要：

为了提高第三代聚光式太阳能热发电技术的效率，降低系统的运行成本，需要开发出具有更高使用温度的新型高温储热/蓄热材料。本文基于相同阳离子的原则，选取3种相同钠离子熔盐NaNO₃、NaCl、Na₂CO₃作为基盐，借助相图原理指导混合熔盐的配制，通过FactSage软件对NaNO₃-NaCl-Na₂CO₃三元体系进行相图热力学计算，利用差示扫描量热仪对预测最低共熔点附近多组共晶盐进行热物性分析。结果发现，当三元体系熔盐NaNO₃∶NaCl∶Na₂CO₃物质的量比例为0.92∶0.064∶0.016时熔点最低，测得最低共熔点为279.9 ℃，相变潜热值为194.1 J/g，与相图预测结果(291 ℃)基本一致，验证了相图计算的准确性。对该体系其他热物性进行测量，得到其分解温度为595 ℃(质量损失率为3%)，比热容为1.60 J/(g·K)(500 ℃)，平均比热容为1.62 J/(g·K)，相比于Solar Salt和Hitec平均比热容分别增加了0.12 J/(g·K)和0.28 J/(g·K)。该新型三元体系熔盐具有潜热、比热容大和使用温度范围较宽的优点，在制备复合材料潜热储热方面有很大潜力，为开发新型太阳能热发电储热/蓄热材料提供了借鉴，也为借助相图理论指导混合熔盐的开发提供了参考。

关键词: 熔盐, 相图, 太阳能热发电, 热物性

Abstract:

New high-temperature thermal storage/storage materials with higher service temperatures must be developed to improve the efficiency of third-generation concentrated solar thermal power generation technology and reduce the system's operating costs. Based on the same-cation principle, three molten salts, i.e., sodium nitrate (NaNO₃), sodium chloride (NaCl), and sodium carbonate (Na₂CO₃) of the same sodium ion, were selected as base salts, and the phase diagram principle guided the preparation of mixed molten salts. The phase diagram thermodynamic calculation of the NaNO₃-NaCl-Na₂CO₃ ternary system was carried out using the FactSage software program. The thermophysical analysis of several groups of eutectic salts near the lowest eutectic point was carried out using a differential scanning calorimeter. The results showed that when the molar ratio of the molten salts in the ternary system(NaNO₃:NaCl:Na₂CO₃) was 0.92:0.064:0.016, the melting point of the system was the lowest, the lowest eutectic point was 279.9 ℃, and the latent heat was 194.1 J/g. These results were essentially consistent with the theoretical calculation result (291 ℃), verifying the model's accuracy. Other thermophysical properties of the system at the lowest eutectic point were measured. The decomposition temperature of the system at this ratio was 648 ℃ (the mass loss rate was 5%), and the specific heat value was 1.60 J/(g·K) (500 ℃). The measured specific heat value increased by 0.12 compared with Solar Salt and 0.28 compared with Hitec salt. The new ternary system had large latent heat of molten salts and a broad temperature range. It showed significant potential in the preparation of latent heat storage involving composite materials. The system can be used as a reference for developing new thermal storage/storage materials for solar power generation and as a guide for the development of mixed molten salts using phase diagram theory.

Key words: molten salt, phase diagram, concentrating solar power, thermophysical properties

中图分类号:

TK 512

何聪, 鹿院卫, 宋文兵, 陈晓彤, 吴玉庭, 樊占胜. 新型相同钠离子混合熔盐相图预测及物性测量[J]. 储能科学与技术, 2021, 10(5): 1729-1734.

Cong HE, Yuanwei LU, Wenbing SONG, Xiaotong CHEN, Yuting WU, Zhansheng FAN. The phase diagram prediction and experimental study of ternary same cation systems[J]. Energy Storage Science and Technology, 2021, 10(5): 1729-1734.

图/表 8

表1

表2

纯组元热力学性质表"

相	状态	H⁰_298.15K/(J·mol^-1)	S⁰_298.15K/(J·mol^-1·K^-1)	温度范围/K	比热容/(J·mol^-1·K^-1)
NaNO₃	S1	-467980.0	116.315	298.1～549.0	$22.62 + 0.222 T$
	S1	-467980.0	116.315	549.0～579.0	139.000
	S2	-464360.0	122.908	298.1～549.0	$22.62 ? + 0.222 T$
	S2	-464360.0	122.908	549.0～579.0	139.000
	L1	-449380.0	148.781	298.1～549.0	$22.62 ? + 0.222 T$
	L1	-449380.0	148.781	549.0～579.0	139.000
NaCl	S1	-411119.8	72.132	298.1～2000.0	$45.940 + 1.63176 × 10 - 2 T$
NaCl	L1	-394956.0	76.076	298.1～1500.0	$77.763 - 7.5312 × 10 - 3 T$
Na₂CO₃	S	-1130768.0	138.797	298～758	$87.121919 + 2.629 × 10 - 2 T + 110904.53 ? T - 21.6668 × 10 - 4 T 2$
Na₂CO₃	L	-1104433.7	161.706	298～723	$87.12 + 2.629 × 10 - 2 T + 110904.53 ? T - 2 + 1.66 × 10 - 4 T 2$

表2

图1

表3

图2

图3

图4

表4

参考文献 16

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熔盐组成(质量分数)/%	熔点/℃	稳定性/℃	比热容/[kJ?(kg?K)^-1]	成本/(USD?kg^-1)
KNO₃/NaNO₃(40/60)	220	530～565	～1.5(400 ℃)	0.50～0.8
KNO₃/NaNO₃/NaNO₂(53/7/40)	142	450～535	1.34(400 ℃)	～0.90
K₂CO₃/Li₂CO₃/Na₂CO₃(32/35/33)	397	>650	1.9(700 ℃)	1.30～2.50
KF/LiF/NaF(59/29/12)	454	>700	1.9(700 ℃)	> 2.00
KCl/MgCl₂/NaCl(17.8/68.2/14.0)	380	>800	～1.0(500 ℃)	< 0.35

NaNO₃:NaCl:Na₂CO₃组成/%		预测值/℃	实验值/℃	潜热/(J·g^-1)	误差/℃
配比1	0.90:0.08:0.02	291.2	280.7	209.0	10.5
配比2	0.92:0.064:0.016		279.9	194.1	11.3
配比3	0.91:0.075:0.015		289.2	195.2	2.0
配比4	0.90:0.085:0.015		288.1	196.3	3.1

熔盐组成(质量分数)/%	熔点/℃	稳定性/℃	比热容/(kJ·kg·K)^-1	比热容提高比例/%
40%KNO₃+60%NaNO₃	240	530～565	～1.5(400 ℃)	8.0
53%KNO₃+7%NaNO₃+40%NaNO₂	142	450～535	1.34(400℃)	20.8
48%Ca(NO₃)₂+7%NaNO₃+45% KNO₃	130.61	554.39	1.272	27.3
20%LiNO₃+52%KNO₃+28% NaNO₃	130.15	600.05	1.091	48.5
30%LiNO₃+10%Ca(NO₃)₂+60% KNO₃	132.15	567.18	1.395	16.1
10%LiNO₃+10%Ca(NO₃)₂+60% KNO₃+20% NaNO₃	132.08	580.36	1.517	6.8
NaNO₃-NaCl-Na₂CO₃(本研究)	279.9	598	1.62	—

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