空气气氛下太阳盐与Hitec熔盐的高温稳定性

doi:10.19799/j.cnki.2095-4239.2025.0024

摘要/Abstract

摘要：

熔盐储能已经应用于聚光太阳能发电、煤电灵活性改造等，但近些年多种应用场景对熔盐的使用温度上限提出了更高的要求。本工作通过热重法、离子色谱法和电位滴定法系统研究了太阳盐和Hitec两种典型硝基熔盐在空气气氛下的高温稳定性和分解产物。通过热重测试，解释了文献中Hitec盐比太阳盐具有更高分解温度(按照3%失重判断)的原因，即：在高温下，Hitec盐由于初始亚硝酸根比例较高，在450 ℃会先与氧气反应增重，然后再分解失重，而太阳盐从500 ℃开始会持续分解生成氧气和氮氧化物失重。该分析也表明Hitec盐在高温空气气氛下组分会变化，并不能用在更高的温度下。进一步通过长时间高温稳定性测试发现，太阳盐和Hitec盐在高温平衡时会达到近似一致的亚硝酸根比例；在空气气氛下这一比例(摩尔分数)随着温度的升高而升高，从550 ℃时的4.36%逐渐升高到600 ℃的7.34%。在开口体系中，由于气体产物会直接排放走，因此Hitec盐在580 ℃会持续分解产生氧化物，200 h时氧化物质量分数达到9%以上，并且产生了明显的氧化物沉淀。硝基熔盐在更高温度下使用可能需要考虑采用密闭系统以抑制氧化物的生成。

关键词: 热储能, 熔盐, 高温稳定性, 太阳盐, Hitec盐

Abstract:

Molten salt energy storage is important for applications such as concentrated solar power generation and enhancing the flexibility of coal-fired power plants. However, various applications require these salts to operate at significantly higher temperatures. This study systematically investigates the high-temperature stability and decomposition products of two typical nitrate salts, Solar Salt and Hitec under air conditions. The salts were prepared by melting pure salts at low temperatures, then dried and stored in glove boxes to protect them from water and oxygen. The oxidation and decomposition processes were characterized by thermogravimetric analysis. Ion chromatography was used to measure the proportion of nitrite ions, and potentiometric titration was used to determine oxide content. Prior to the formal experiments, all three testing methods underwent error calibration to ensure the accuracy of the test results. The thermogravimetry test conducted in a synthetic air atmosphere explains the reason why Hitec salt has a higher decomposition temperature (with 3% weight loss) than Solar salt. At high temperatures, Hitec salt first reacts with oxygen and gains weight at 450 ℃ before decomposition and subsequent weight loss because of its high initial concentration of nitrite ions. In contrast, solar salts begin continuous decomposition and weight loss at 500 ℃, generating oxygen and nitrogen oxides. This analysis indicates that the components of Hitec salts are more prone to change at high temperatures, which increases their melting point. Therefore, it cannot be used at higher temperatures. Long-term stability tests conducted in a muffle furnace revealed that, at high temperatures, Solar and Hitec salts produce approximately the same nitrite ratio after equilibrium. This is attributed to their similar Na⁺ to K⁺ ratios, which lead to similar chemical equilibria. Under an air atmosphere, the proportion of nitrite ions increased with temperature, rising from 4.36% (molar fraction) at 550 ℃ to 7.34% at 600 ℃. The test results on the formation of oxides at high temperatures showed that, in the open system, the Hitec salt continuously decomposes and produces oxides at 580 ℃. This result can be attributed to the direct emission of gaseous products. At 200 h, the oxide mass fraction of Hitec salt reached more than 9%, with obvious oxide precipitation. These findings demonstrate that the use of nitrate molten salts at higher temperatures may require the consideration of a closed system to inhibit oxide formation.

Key words: thermal energy storage, molten salt, high-temperature stability, solar salt, Hitec salt

中图分类号:

TK 02

李永昭, 马添翼, 尤汉, 李小波, 杨荣贵. 空气气氛下太阳盐与Hitec熔盐的高温稳定性[J]. 储能科学与技术, 2025, 14(7): 2813-2819.

Yongzhao LI, Tianyi MA, Han YOU, Xiaobo LI, Ronggui YANG. High-temperature stability of solar salt and Hitec under air atmosphere[J]. Energy Storage Science and Technology, 2025, 14(7): 2813-2819.

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仪器名称	型号	技术参数
电子分析天平	SQF	最大秤量：120 g 最小秤量：1 mg 分度值：0.01 mg
马弗炉	XD 322-12	功率：4 kW 升温速率：≤10 ℃/min 温控精度：±1 ℃
同步热分析仪	SDT-650	升温速率：0.1～100 ℃/min 动态温度精度：±0.5 ℃ 称重精度：±1%
离子色谱仪	881 compact IC pro	最小检出限：0.04 mg/L 流量精度：<0.2%
自动电位滴定仪	ZDJ-5B	滴定体积精度：0.01 mL 电位分辨率：0.01 mV 最小检出限：20 ppm(1 ppm=10^-6)

样本	组分	理论NO₂^-/%	实测NO₂^-/%	误差%
0	纯水	0	0	0
1	NaNO₃ KNO₂	30	29.48	0.52
2	NaNO₃ KNO₂	40	40.84	0.84
3	Hitec	48.85	49.79	0.94
4	Hitec	48.85	49.91	1.06

样本	NaOH用量/mL	盐酸理论用量/mL	盐酸实际用量/mL	误差/%
1	8	8	7.95	0.63
2	8	8	7.93	0.88
3	8	8	7.95	0.63