CaO/Ca（OH） 2 核壳结构颗粒的制备及其储热性能

doi:10.19799/j.cnki.2095-4239.2022.0400

摘要/Abstract

摘要：

热化学储热具有储热密度高，可实现跨季节储热的优点。在中高温储热领域，氧化钙/氢氧化钙储热系统目前仍存在储热材料易结块、难以流态化等问题。本文通过在氢氧化钙颗粒外包覆一层烧结的碳化硅陶瓷壳的方法，制备了一种可用于氧化钙/氢氧化钙储热系统的具有核壳结构的储热颗粒。研究表明，该核壳结构颗粒壳体和芯体的内部孔隙呈现出不同的孔径分布，壳体的孔径大于内部芯体的孔径，因此壳体的包裹对于内部氢氧化钙的储放热反应进程影响较小，相对于纯氢氧化钙，核壳结构颗粒在反应速率和力学性能方面也有所提升。表征结果显示，颗粒的壳体化学性质较为稳定，不会与氢氧化钙发生反应导致储热密度的降低。此外，该核壳结构颗粒具有较好的循环稳定性，在空气氛围下，对所制备颗粒进行了25次储放热循环，发现该颗粒储热密度的下降在20%以内且未发生开裂和破碎。颗粒储热密度的下降是由于氢氧化钙与空气中的二氧化碳反应生成了碳酸钙，经过高温煅烧除去碳酸钙后，颗粒的储热密度可恢复至初始储热密度的96.7%。综上，本工作制备储热颗粒对热化学储热技术的实际应用具有重要意义。

关键词: 热化学储热, 氢氧化钙, 造粒

Abstract:

High heat storage density and cross-seasonal heat storage are two advantages of thermochemical heat storage. In medium-and high-temperature heat storage, the heat storage material of the calcium oxide/calcium hydroxide heat-storage system is easy to accumulate but is challenging to fluidize. This study wrapped calcium hydroxide pellets in a sintered silicon carbide ceramic shell to create a heat storage pellet with a core-shell structure. Although the internal pores of the shell and core of this core-shell structure particles show different pore size distribution, the pore size of the shell is larger than the pore size of the internal calcium hydroxide core, so the wrapping of the shell has less impact on the internal calcium hydroxide storage and exothermic reaction process. Compared with pure calcium hydroxide, the core-shell structure particles' reaction rate and mechanical properties have also improved. The characterization results show that the shell of the pellets is chemically stable and does not react with calcium hydroxide to cause a decrease in the thermal storage density.In addition, the core-shell structure particles have good cycling stability, and the prepared particles were subjected to 25 exothermic and endothermic cycles under an air atmosphere. It was discovered that the particles' loss in heat storage density was 20% or less, and there was no cracking or fragmentation. However, the reaction of calcium hydroxide with carbon dioxide in the air decreased the heat storage density of the pellets. Still, after high-temperature calcination to make calcium carbonate decompose into calcium hydroxide again, the heat storage density of the pellets could be restored to 96.7% of the initial heat storage density. In summary, preparing heat storage particles in this study is significant for applying thermochemical heat storage technology.

Key words: thermochemical heat storage, calcium hydroxide, granulation

中图分类号:

TK 02

莫雅超, 闫君, 赵长颖. CaO/Ca（OH） ₂ 核壳结构颗粒的制备及其储热性能[J]. 储能科学与技术, 2022, 11(12): 3828-3835.

Yachao MO, Jun YAN, Changying ZHAO. Preparation and thermal storage properties of CaO/Ca（OH） ₂ core-shell-structured particles[J]. Energy Storage Science and Technology, 2022, 11(12): 3828-3835.

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温度/℃	导热系数/[W/(m·K)]
100	2.53
200	2.43
300	2.34
400	2.35
500	2.25

样品序号	压碎强度/N
1	6.02
2	9.61
3	6.11
4	5.92

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CaO/Ca（OH） ₂ 核壳结构颗粒的制备及其储热性能

Preparation and thermal storage properties of CaO/Ca（OH） ₂ core-shell-structured particles

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