催化剂对基于动态酯交换Vitrimers材料性能的影响

doi:10.19595/j.cnki.1000-6753.tces.230908

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摘要传统环氧树脂作为干式变压器、电压互感器和复合绝缘子等电工装备的主要原材料,有着良好的力学性能和电学性能,但是其固化后形成的交联网络难溶难熔。随着环氧树脂基电工装备运行年限的增长,大量退役设备的处理面临巨大的挑战。该文制备了基于酯交换的酸酐固化类玻璃化环氧树脂材料（Vitrimers）,系统地研究了催化剂对树脂力学、电学、热学以及动态交换性能的影响规律,并使用醇类溶液探索其降解性能。研究结果显示,与传统环氧树脂相比,Vitrimers体系的断裂伸长率较高,表现出良好的韧性。在Vitrimers体系中以1,5,7-三叠氮双环(4.4.0)癸-5-烯（TBD）为催化剂的Vitrimers具有较佳的综合特性,在高温下表现出良好的应力弛豫特性,且能够在7 h（190℃）全部溶解于乙二醇（EG）溶液中。该文研究结果表明,类玻璃化环氧树脂有较综合的力-热-电特性,能够快速溶解于降解溶液,有望用作电工装备的新型环保树脂基体。

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关键词 ：类玻璃化环氧树脂材料, 环氧树脂, 催化剂, 降解, 电工装备

Abstract：Epoxy resins are widely used in electrotechnical equipment because of their dimensional stability, resistance to cracking, and excellent electrical insulation and mechanical properties after curing. However, the irreversible crosslinking network of traditional thermosetting epoxy resins makes it difficult to degrade and recycle. As the operating life of epoxy resin-based electrotechnical equipment increases, the management of large quantities of thermoset waste faces great difficulties. Current recycling methods of resin waste are environmentally polluting, energy intensive, and do not meet the eye of sustainable development. In order to elimate thermosetting epoxy resin waste from the source, this paper investigates the effect of catalyst type on the performance of glass-like epoxy resins (Vitrimers) and explores the degradation rate of different resin systems in alcohol solutions.
Firstly, different Vitrimers systems, named V-TBD, V-TEOA, V-Sn, V-Zn, were prepared using 1,5,7-triazabicyclo(4.4.0)dec-5-ene (TBD), triethanolamine (TEOA), stannous isooctanoate (Sn(Oct)₂), and zinc acetylacetonate (Zn(acac)₂) as catalysts in this paper. Comparatively, we analyzed the conventional resins (T-DMP) and different Vitrimers for their mechanical, electrical and thermal properties. The results showed that compared with the conventional epoxy resin, the tensile strength, flexural strength and electrical properties of Vitrimers were reduced, but its elongation at break was higher and showed good toughness. Among them, the comprehensive mechanical properties of V-TEOA was second only to T-DMP. Its tensile strength, bending strength and elongation at break were 77.33 MPa, 23.08 MPa and 10.98%, respectively. V-TBD had high retention rate of electrical insulation properties. It had only 5.2% decrease in breakdown strength, and the leakage current and dielectric loss factor were slightly higher than those of T-DMP. Catalysts containing metal ions led to a serious degradation of the electrical properties of Vitrimers. In addition, the thermal stability of all Vitrimers systems was lower than that of conventional resin, which was caused by the weak bonding of the dynamic bonds. However, V-TBD and V-Zn had higher glass transition temperatures than the conventional resin, which were 163.89℃ and 158.65℃. Then, the stress relaxation of the conventional resin and Vitrimers was investigated. Unlike the conventional resin, Vitrimers showed good stress relaxation at high temperatures due to the activation of exchange reactions between the dynamic ester bonds contained in the crosslinked network. Among them, V-TBD had the shortest stress relaxation time at the same temperature, indicating the fastest rate of ester exchange reaction. Finally, the degradation characteristics of conventional resins and Vitrimers were studied in a solution of ethylene glycol (EG). The conventional epoxy resin could not be dissolved, while Vitrimers can be able to achieve dissolution. Among them, V-TBD showed the best dissolution effect.
In conclusion, the introduction of dynamic bonds in the cross-linking network after the curing of epoxy resins makes the degradation and recycling of resins possible, which provides a base material for new green electrotechnical equipment. Vitrimers using TBD as a catalyst has good mechanical, electrical, and thermal properties, can be fast dissolved in ethylene glycol solution, and is expected to be used as a matrix resin in the field of electrical equipment.

Key words： Vitrimers epoxy resin catalyst degradation electrotechnical equipment

收稿日期: 2023-06-13

PACS:

TM21

基金资助:国家自然科学基金（52007062）和中央高校基本科研业务费专项资金（20226934）资助项目

通讯作者: 刘云鹏男,1976年生,博士,教授,博士生导师,研究方向为特高压输电技术、电工装备在线检测和外绝缘。E-mail：liuyunpeng@ncepu.edu.cn

作者简介: 刘贺晨男,1989 年生,博士,副教授,研究方向为环保型环氧树脂及其复合材料研制、电工装备绝缘状态评估及聚合物电树枝特性研究等。E-mail：hc.liu@ncepu.edu.cn

引用本文:

刘贺晨, 魏利伟, 孙章林, 刘畅, 刘云鹏. 催化剂对基于动态酯交换Vitrimers材料性能的影响[J]. 电工技术学报, 2024, 39(16): 5134-5148. Liu Hechen, Wei Liwei, Sun Zhanglin, Liu Chang, Liu Yunpeng. Effect of Catalysts on the Performance of Vitrimers Based on Dynamic Ester Exchange. Transactions of China Electrotechnical Society, 2024, 39(16): 5134-5148.

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[1] 刘贺晨, 孙章林, 刘云鹏, 等. 基于酯交换的可回收类玻璃化环氧树脂制备与性能研究[J].电工技术学报, 2023, 38(15): 4019-4029.
Liu Hechen, Sun Zhanglin, Liu Yunpeng, et al.Preparation and properties of recyclable vitrified epoxy resin based on transesterification[J]. Transactions of China Electrotechnical Society, 2023, 38(15): 4019-4029.
[2] 王有元, 王施又, 黄炎光, 等. 干式变压器环氧树脂热老化特性研究[J]. 高电压技术, 2018, 44(1): 187-194.
Wang Youyuan, Wang Shiyou, Huang Yanguang, et al.Study on thermal aging characteristics of epoxy resin of dry-type transformer[J]. High Voltage Engineering, 2018, 44(1): 187-194.
[3] 关志成, 彭功茂, 王黎明, 等. 复合绝缘子的应用及关键技术研究[J]. 高电压技术, 2011, 37(3): 513-519.
Guan Zhicheng, Peng Gongmao, Wang Liming, et al.Application and key technical study of composite insulators[J]. High Voltage Engineering, 2011, 37(3): 513-519.
[4] Mamanpush S H, Li Hui, Englund K, et al.Extruded fiber-reinforced composites manufactured from recycled wind turbine blade material[J]. Waste and Biomass Valorization, 2020, 11(7): 3853-3862.
[5] Vincent G A, de Bruijn T A, Wijskamp S, et al. Shredding and sieving thermoplastic composite scrap: method development and analyses of the fibre length distributions[J]. Composites Part B: Engineering, 2019, 176: 107197.
[6] Beauson J, Madsen B, Toncelli C, et al.Recycling of shredded composites from wind turbine blades in new thermoset polymer composites[J]. Composites Part A: Applied Science and Manufacturing, 2016, 90: 390-399.
[7] Rahimizadeh A, Tahir M, Fayazbakhsh K, et al.Tensile properties and interfacial shear strength of recycled fibers from wind turbine waste[J]. Composites Part A: Applied Science and Manufacturing, 2020, 131: 105786.
[8] Hao Siqi, He Lizhe, Liu Jiaqi, et al.Recovery of carbon fibre from waste prepreg via microwave pyrolysis[J]. Polymers, 2021, 13(8): 1231.
[9] Meng F, McKechnie J, Turner T A, et al. Energy and environmental assessment and reuse of fluidised bed recycled carbon fibres[J]. Composites Part A: Applied Science and Manufacturing, 2017, 100: 206-214.
[10] Capelot M, Montarnal D, Tournilhac F, et al.Metal-catalyzed transesterification for healing and assembling of thermosets[J]. Journal of the American Chemical Society, 2012, 134(18): 7664-7667.
[11] Montarnal D, Capelot M, Tournilhac F, et al.Silica-like malleable materials from permanent organic networks[J]. Science, 2011, 334(6058): 965-968.
[12] Pei Zhiqiang, Yang Yang, Chen Qiaomei, et al.Mouldable liquid-crystalline elastomer actuators with exchangeable covalent bonds[J]. Nature Materials, 2014, 13(1): 36-41.
[13] Martin R, Rekondo A, de Luzuriaga A R, et al. The processability of a poly(urea-urethane) elastomer reversibly crosslinked with aromatic disulfide bridges[J]. Journal of Materials Chemistry A, 2014, 2(16): 5710-5715.
[14] Tsarevsky N V, Matyjaszewski K.Reversible redox cleavage/coupling of polystyrene with disulfide or thiol groups prepared by atom transfer radical polymerization[J]. Macromolecules, 2002, 35(24): 9009-9014.
[15] Michal B T, Jaye C A, Spencer E J, et al.Inherently photohealable and thermal shape-memory poly-disulfide networks[J]. ACS Macro Letters, 2013, 2(8): 694-699.
[16] Pepels M, Filot I, Klumperman B, et al.Self-healing systems based on disulfide-thiol exchange reactions[J]. Polymer Chemistry, 2013, 4(18): 4955-4965.
[17] Canadell J, Goossens H, Klumperman B.Self-healing materials based on disulfide links[J]. Macromolecules, 2011, 44(8): 2536-2541.
[18] Stefani H A, Costa I M, de O Silva D. An easy synthesis of enaminones in water as solvent[J]. Synthesis, 2000(11): 1526-1528.
[19] Denissen W, Rivero G, Nicolaÿ R, et al.Vinylogous urethane vitrimers[J]. Advanced Functional Materials, 2015, 25(16): 2451-2457.
[20] Lu Yixuan, Guan Zhibin.Olefin metathesis for effective polymer healing via dynamic exchange of strong carbon-carbon double bonds[J]. Journal of the American Chemical Society, 2012, 134(34): 14226-14231.
[21] Vougioukalakis G C, Grubbs R H.Ruthenium-based heterocyclic carbene-coordinated olefin metathesis catalysts[J]. Chemical Reviews, 2010, 110(3): 1746-1787.
[22] Taynton P, Yu Kai, Shoemaker R K, et al.Heat- or water-driven malleability in a highly recyclable covalent network polymer[J]. Advanced Materials, 2014, 26(23): 3938-3942.
[23] Yang Bin, Zhang Yaling, Zhang Xiaoyong, et al.Facilely prepared inexpensive and biocompatible self-healing hydrogel: a new injectable cell therapy carrier[J]. Polymer Chemistry, 2012, 3(12): 3235-3238.
[24] Deng Guohua, Li Fuya, Yu Hongxia, et al.Dynamic hydrogels with an environmental adaptive self-healing ability and dual responsive sol-gel transitions[J]. ACS Macro Letters, 2012, 1(2): 275-279.
[25] Yu Kai, Shi Qian, Dunn M L, et al.Carbon fiber reinforced thermoset composite with near 100% recyclability[J]. Advanced Functional Materials, 2016, 26(33): 6098-6106.
[26] Mu Quanyi, An Le, Hu Zhiqiang, et al.Fast and sustainable recycling of epoxy and composites using mixed solvents[J]. Polymer Degradation and Stability, 2022, 199: 109895.
[27] Demongeot A, Mougnier S J, Okada S, et al.Coordination and catalysis of Zn²+ in epoxy-based vitrimers[J]. Polymer Chemistry, 2016, 7(27): 4486-4493.
[28] Hao Cheng, Liu Tuan, Zhang Shuai, et al.Triethanolamine-mediated covalent adaptable epoxy network: excellent mechanical properties, fast repairing, and easy recycling[J]. Macromolecules, 2020, 53(8): 3110-3118.
[29] Poutrel Q A, Blaker J J, Soutis C, et al.Dicarboxylic acid-epoxy vitrimers: influence of the off-stoichiometric acid content on cure reactions and thermo-mechanical properties[J]. Polymer Chemistry, 2020, 11(33): 5327-5338.
[30] Liu Wenhao, Schmidt D F, Reynaud E.Catalyst selection, creep, and stress relaxation in high-performance epoxy vitrimers[J]. Industrial & Engineering Chemistry Research, 2017, 56(10): 2667-2672.
[31] Capelot M, Unterlass M M, Tournilhac F, et al.Catalytic control of the vitrimer glass transition[J]. ACS Macro Letters, 2012, 1(7): 789-792.
[32] Bhusal S, Oh C, Kang Y, et al.Transesterification in vitrimer polymers using bifunctional catalysts: modeled with solution-phase experimental rates and theoretical analysis of efficiency and mechanisms[J]. The Journal of Physical Chemistry B, 2021, 125(9): 2411-2424.
[33] 刘贺晨, 郭展鹏, 李岩, 等. 衣康酸基环氧树脂和双酚A环氧树脂性能对比研究[J]. 电工技术学报, 2022, 37(9): 2366-2376.
Liu Hechen, Guo Zhanpeng, Li Yan, et al.Comparative study on the performance of itaconic acid based epoxy resin and bisphenol A epoxy resin[J]. Transactions of China Electrotechnical Society, 2022, 37(9): 2366-2376.
[34] Bao Chunyang, Guo Zhiwei, Sun Haoxiang, et al.Nitrogen-coordinated boroxines enable the fabrication of mechanically robust supramolecular thermosets capable of healing and recycling under mild conditions[J]. ACS Applied Materials & Interfaces, 2019, 11(9): 9478-9486.
[35] Miao Xuepei, Meng Yan, Li Xiaoyu.Epoxide-terminated hyperbranched polyether sulphone as triple enhancement modifier for DGEBA[J]. Journal of Applied Polymer Science, 2015, 132(17): 41910.
[36] Ding Xiaomin, Chen Li, Guo Deming, et al.Controlling cross-linking networks with different imidazole accelerators toward high-performance epoxidized soybean oil-based thermosets[J]. ACS Sustainable Chemistry & Engineering, 2021, 9(8): 3267-3277.
[37] 尹立, 张翀, 杨威, 等. 复合绝缘子伞裙护套材料耐冲击力学特性研究[J]. 高压电器, 2023, 59(4): 44-53.
Yin Li, Zhang Chong, Yang Wei, et al.Research on impact-resistance mechanical characteristics of shed sheath material of composite insulator[J]. High Voltage Apparatus, 2023, 59(4): 44-53.
[38] 来文青, 樊浩楠, 王永红, 等. 脂环族环氧树脂材料湿热老化特性研究[J]. 高压电器, 2022, 58(6): 104-111.
Lai Wenqing, Fan Haonan, Wang Yonghong, et al.Study on damp heat aging characteristics of the alicyclic epoxy resin[J]. High Voltage Apparatus, 2022, 58(6): 104-111.
[39] Liu Yunpeng, Li Le, Liu Hechen, et al.Hollow polymeric microsphere-filled silicone-modified epoxy as an internally insulated material for composite cross-arm applications[J]. Composites Science and Technology, 2020, 200: 108418.
[40] Lv Zongtang, Yang Hongkun, Wang Dong.Catalyst control of interfacial welding mechanical properties of vitrimers[J]. Chinese Journal of Polymer Science, 2022, 40(6): 611-617.
[41] Zhang Huan, Zhou Lin, Zhang Fengtian, et al.Aromatic disulfide epoxy vitrimer packaged electronic devices: nondestructive healing and recycling[J]. Polymer, 2022, 255: 125163.
[42] Zhou Gang, Zhang Jian, Wang Ziqing, et al.A novel epoxy vitrimer with low dielectric constant at high-frequency[J]. Journal of Applied Polymer Science, 2023, 140(14): e53713.
[43] Qiu Guorong, Ma Wenshi, Wu Li.Low dielectric constant polyimide mixtures fabricated by polyimide matrix and polyimide microsphere fillers[J]. Polymer International, 2020, 69(5): 485-491.
[44] 刘贺晨, 董鹏, 周松松, 等. 不同分子量聚醚胺共混对环氧复合泡沫绝缘材料热性能及电气性能的影响分析[J]. 电工技术学报, 2023, 38(10): 2589-2601.
Liu Hechen, Dong Peng, Zhou Songsong, et al.Analysis of the effect of blending different molecular weight polyetheramines on the thermal and electrical properties of epoxy composite foam insulation materials[J]. Transactions of China Electrotechnical Society, 2023, 38(10): 2589-2601.
[45] 王威望, 李睿喆, 何杰峰, 等. 快速陡脉冲重复电场下高频变压器绝缘介质损耗与冲击能量积聚特性[J]. 电工技术学报, 2023, 38(5): 1206-1216.
Wang Weiwang, Li Ruizhe, He Jiefeng, et al.Dielectric loss and impact energy accumulation of high frequency transformer insulation under rapidly repetitive pulsed voltages[J]. Transactions of China Electrotechnical Society, 2023, 38(5): 1206-1216.
[46] Kuang Xiao, Zhou Yunying, Shi Qian, et al.Recycling of epoxy thermoset and composites via good solvent assisted and small molecules participated exchange reactions[J]. ACS Sustainable Chemistry & Engineering, 2018, 6(7): 9189-9197.
[47] Hamel C M, Kuang Xiao, Chen Kaijuan, et al.Reaction-diffusion model for thermosetting polymer dissolution through exchange reactions assisted by small-molecule solvents[J]. Macromolecules, 2019, 52(10): 3636-3645.
[48] Kuang Xiao, Shi Qian, Zhou Yunying, et al.Dissolution of epoxy thermosets via mild alcoholysis: the mechanism and kinetics study[J]. RSC Advances, 2018, 8(3): 1493-1502.
[49] Simón L, Goodman J M.The mechanism of TBD-catalyzed ring-opening polymerization of cyclic esters[J]. The Journal of Organic Chemistry, 2007, 72(25): 9656-9662.
[50] Nederberg F, Lohmeijer B G G, Leibfarth F, et al. Organocatalytic ring opening polymerization of trimethylene carbonate[J]. Biomacromolecules, 2007, 8(1): 153-160.
[51] Pratt R C, Lohmeijer B G G, Long D A, et al. Triazabicyclodecene: a simple bifunctional organo-catalyst for acyl transfer and ring-opening polymerization of cyclic esters[J]. Journal of the American Chemical Society, 2006, 128(14): 4556-4557.