丙三醇对硅酸钾凝胶发泡性能的影响

doi:10.16552/j.cnki.issn1001-1625.2025.1004

摘要/Abstract

摘要：

硅酸钾凝胶兼具室温下的高透光性与高温下的发泡特性，这使其成为复合防火玻璃夹层材料的理想选择。凝胶发泡体的性能参数是表征硅酸钾基复合防火玻璃隔热性能的关键指标。本文采用阿基米德法计算凝胶发泡体的气孔率，通过Turbiscan Lab Expert、热流法、TG-DSC等测试方法，研究了丙三醇含量对硅酸钾凝胶发泡性能的影响。结果表明：丙三醇含量在10%~20%（质量分数）时，凝胶发泡体的膨胀体积相对较小，同时气孔率较高；丙三醇含量为15%时，凝胶发泡体开始出现碳化有机物相的分离，表面易产生开气孔；丙三醇含量为20%时，凝胶发泡体出现严重的碳化有机物相分离，发泡效果比较差，厚度膨胀倍率仅约4倍。综合比较，丙三醇含量为10%时，硅酸钾凝胶膨胀层体积膨胀倍率为13.62倍，复合防火玻璃的耐火完整性失效风险性小，气孔率为92.23%，且发泡相貌均匀致密，导热系数增高不明显，隔热性能与发泡性能最优。

关键词: 硅酸钾凝胶, 丙三醇, 气孔率, 发泡体积, 导热系数

Abstract:

Potassium silicate gel， which combines high optical transparency at room temperature with excellent foaming capability at elevated temperatures，is an ideal choice for the interlayer material of composite fire-resistant glass.The performance parameters of the foamed gel are key indicators for characterizing the thermal insulation performance of potassium silicate-based laminated glass. In this study， the porosity of the foamed gel was calculated using the Archimedes method. The influence of glycerol content on the foaming performance of potassium silicate gel was investigated using methods including Turbiscan Lab Expert analysis， the heat flow method， and TG-DSC. The results indicate that when the glycerol content ranges from 10% to 20% by mass， the foamed gel exhibits a relatively smaller expansion volume but a relatively higher porosity. At a glycerol content of 15%， phase separation of carbonized organic components begins to occur in the foamed gel， leading to the formation of open pores on its surface. When the glycerol content reaches 20%， severe phase separation of carbonized organics takes place， resulting in poor foaming performance. This is evidenced by a thickness expansion ratio of only about 4 times. Comprehensive comparison shows that at a glycerol content of 10%， the sample demonstrates optimal overall performance： the potassium silicate gel expansion layer achieves a volume expansion ratio of 13.62 times， the risk of compromising the fire resistance integrity of the laminated glass is low， the porosity is 92.23%， and the foam morphology is uniform and dense. Moreover， the thermal conductivity remains low. Under these conditions， both the thermal insulation and foaming performance are at their best.

Key words: potassium silicate gel, glycerol, porosity, foaming volume, thermal conductivity

中图分类号:

TQ171

张康, 徐磊, 张凡, 何坤, 苏诗戈, 于常胜, 范亮亮, 徐宁, 祖成奎. 丙三醇对硅酸钾凝胶发泡性能的影响[J]. 硅酸盐通报, 2026, 45(3): 1038-1046.

ZHANG Kang, XU Lei, ZHANG Fan, HE Kun, SU Shige, YU Changsheng, FAN Liangliang, XU Ning, ZU Chengkui. Effect of Glycerol on Foaming Performance of Potassium Silicate Gel[J]. BULLETIN OF THE CHINESE CERAMIC SOCIETY, 2026, 45(3): 1038-1046.

图/表 13

表1 硅酸钾凝胶样品组成

Table 1 Sample composition of potassium silicate gel

Sample No.	Silica sol （SiO₂ content of 55%） mass/g	Glycerol mass/g	KOH solution（aq， 50%） mass/g
S1	100	0	41.07
S2	95	5	39.01
S3	90	10	36.96
S4	85	15	34.91
S5	80	20	32.86
S6	75	25	30.80

图1 硅酸钾凝胶的制备工艺图

Fig.1 Preparation process diagram of potassium silicate gel

图2 硅酸钾凝胶及其在不同温度下发泡体的外观形貌

Fig.2 Appearance morphology of potassium silicate gel and its foamed gel at different temperatures

图3 热流法测试样品的制作过程

Fig.3 Preparation process of testing samples for heat flow method

图4 不同丙三醇含量硅酸钾凝胶的照片及透光度

Fig.4 Photograph and transmittance of potassium silicate gel with different glycerol content

表2 硅酸钾凝胶样品发泡后的体积

Table 2 Volume of potassium silicate gel samples after foaming

Sample No.	Volume after foaming at different temperatures/cm³
Sample No.	150 ℃	350 ℃	550 ℃	750 ℃	950 ℃
S1	10.50	45.60	51.84	8.69	3.08
S2	8.12	19.50	29.31	9.24	9.38
S3	4.22	10.66	13.62	7.58	10.08
S4	1.85	7.60	10.41	7.22	7.50
S5	3.12	7.18	7.21	7.18	7.02
S6	1.85	6.41	6.43	5.59	5.89

图5 丙三醇含量与温度对硅酸钾凝胶发泡体积的协同影响

Fig.5 Synergistic effects of glycerol content and temperature on foaming volume of potassium silicate gel

表3 550 ℃下硅酸钾凝胶发泡体的气孔率

Table 3 Porosity of potassium silicate foaming gel at 550 ℃

Sample No.	S1	S2	S3	S4	S5	S6
Porosity/%	98.95	94.24	92.23	90.13	86.73	74.69

图6 550 ℃下丙三醇含量对硅酸钾凝胶发泡体气孔率与体积的协同影响

Fig.6 Synergistic effect of glycerol content on porosity and volume of potassium silicate foaming gel at 550 ℃

图7 不同丙三醇含量硅酸钾凝胶在350和550 ℃的发泡状态

Fig.7 Foaming state of potassium silicate gel with different glycerol content at 350 and 550 ℃

图8 丙三醇含量与温度对硅酸钾凝胶膨胀层厚度与导热系数的协同影响

Fig.8 Synergistic effects of glycerol content and temperature on thickness and thermal conductivity of expansion layer in potassium silicate gel

图9 不同含量丙三醇的硅酸钾凝胶的热重-差热曲线

Fig.9 TG-DSC curves of potassium silicate gel with different glycerol content

图10 不同温度硅酸钾凝胶发泡试样的气孔显微形貌

Fig.10 Pore micromorphology of potassium silicate gel foaming samples at different temperatures

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