碳点的宏量制备及其对聚酰胺66阻燃与力学性能协同增强机制

doi:10.13475/j.fzxb.20250908101

纺织学报 ›› 2026, Vol. 47 ›› Issue (02): 37-46.doi: 10.13475/j.fzxb.20250908101

碳点的宏量制备及其对聚酰胺66阻燃与力学性能协同增强机制

魏建斐¹^,²^,³, 魏艳颖¹, 马超慧¹, 胡晓鹏¹, 邴琳涵¹, 樊瑜¹, 林彬泽¹, 董振峰¹, 朱志国¹, 王锐¹^,²^,³()

¹ 北京服装学院材料设计与工程学院, 北京 100029
² 北京服装学院服装材料研究开发与评价北京市重点实验室, 北京 100029
³ 北京市纺织纳米纤维工程技术研究中心, 北京 100029

收稿日期:2025-09-22 修回日期:2025-12-11 出版日期:2026-02-15 发布日期:2026-04-24
通讯作者: 王锐(1963—),女,教授,博士。主要研究方向为功能纤维材料。E-mail:clywangrui@bift.edu.cn。
作者简介:魏建斐(1986—),男,副教授,博士。主要研究方向为纺织废弃物的高值利用及功能化纤维材料制备。
说明:本文入选中国纺织工程学会第26届陈维稷论文卓越行动计划
基金资助:
国家科技重大专项(2024ZD0603700)

Scalable synthesis of carbon dots from polyethylene terephthalate waste for synergistical enhancement of flame retardancy and mechanical properties of polyamide 66 fibers

WEI Jianfei¹^,²^,³, WEI Yanying¹, MA Chaohui¹, HU Xiaopeng¹, BING Linhan¹, FAN Yu¹, LIN Binze¹, DONG Zhenfeng¹, ZHU Zhiguo¹, WANG Rui¹^,²^,³()

¹ School of Materials Design and Engineering, Beijing Institute of Fashion Technology, Beijing 100029, China
² Beijing Key Laboratory of Research, Development and Evaluation of Clothing Materials, Beijing Institute of Fashion Technology, Beijing 100029, China
³ Beijing Engineering Research Center of Textile Nanofibers, Beijing 100029, China

Received:2025-09-22 Revised:2025-12-11 Published:2026-02-15 Online:2026-04-24

摘要/Abstract

摘要：

传统阻燃剂虽能提升聚酰胺(PA66)的阻燃性能,但较高的添加量往往会使PA66可纺性变差并导致纤维力学性能显著下降。为提高PA66纤维的阻燃性能同时兼顾其力学性能,以聚对苯二甲酸乙二醇(PET)废弃物为前驱体使用无溶剂的一步热解法实现了PET废弃物基碳点(rPET-CDs)的宏量制备,单釜(5 L)产量可达1 796 g,产率达72.6%;并系统探究了rPET-CDs对PA66阻燃性、可纺性及纤维性能的影响。结果表明:当添加3%的rPET-CDs时,PA66/rPET-CDs复合物的LOI值达29%,热释放速率峰值下降10.64%;在可纺性方面,rPET-CDs的加入使PA66的纺丝温度从285 ℃降至270 ℃,同时实现了PA66纤维断裂强度和断裂伸长率的协同提升。

关键词: 阻燃纤维, 聚对苯二甲酸乙二醇酯废弃物, 碳点, 聚酰胺66, 阻燃性, 可纺性, 功能纤维

Abstract:

Objective Polyamide 66 (PA66) fiber is widely used in textiles, automotive, and electronics due to its excellent mechanical properties and heat resistance, but with insufficient flame retardancy. Although traditional flame retardants can improve the flame retardancy of PA66, a high loading amount often deteriorates the spinnability of PA66 and significantly reduces the mechanical properties of the fiber. Carbon dots (CDs), as a typical organic-inorganic hybrid zero-dimensional carbon nanomaterial, are expected to enhance the flame retardancy of PA66 while improving its spinnability and strengthening the mechanical properties of PA66 fiber. Specifically, heteroatoms (e.g., N, O, P) in CDs scavenge combustion free radicals to terminate chain reactions, while their carbon-rich core promotes dense char layer formation, blocking heat and oxygen transfer for efficient flame retardancy at low addition levels. Moreover, CDs’ nanoscale size and surface functional groups form hydrogen bonds with PA66 molecular chains, ensuring homogeneous dispersion to maintain melt fluidity and spinnability, and constructing strong interfacial interactions to transfer stress and restrict molecular chain slippage, thus reinforcing mechanical properties.

Method Polyethylene terephthalate (PET) waste was used as a precursor to achieve large-scale preparation of PET waste-based carbon dots (rPET-CDs) via a solvent-free one-step pyrolysis method. Specifically, 1 500 g of PET bottle flakes and 975 mL of ethanolamine were added to a 5 L high-pressure quick-release reaction kettle. The reaction was carried out at 260 ℃ for 56 h, followed by cooling to approximately 80 ℃ and dispersion with ethanol. Subsequently, the mixture was filtered to remove larger particles (>220 nm), and ethanol was recovered. Finally, the product was vacuum-dried and pulverized to obtain rPET-CDs powder, with a yield of 1 796 g.

Results The prepared rPET-CDs exhibited a spherical structure with an average particle size of 2.07 nm and surface functional groups such as —OH and —NH₂, demonstrating good thermal stability. Using rPET-CDs as a flame retardant, flame-retardant PA66 composites (PA66/rPET-CDs) were prepared via melt blending. The addition of rPET-CDs improved the flame retardancy of PA66. When the loading amount of rPET-CDs was 3%, the limiting oxygen index (LOI) of the PA66/rPET-CDs composite reached 29%, and the peak heat release rate (pHRR) decreased by 10.64%. Flame retardancy mechanism studies revealed that the incorporation of rPET-CDs into PA66 reduced the pore size of the char residue after combustion and made the char layer more continuous, demonstrating a certain solid-phase flame retardant effect. SEM images showed that the char layer of pure PA66 contained numerous interconnected pores, whereas when the loading amount of rPET-CDs increased to 3%, the pores in the char layer significantly decreased, and the structure became denser, exhibiting superior thermal-oxygen shielding properties. This effectively inhibited the diffusion of heat and flammable gases, thereby enhancing the flame retardancy of the material. The addition of rPET-CDs reduced the spinning temperature of PA66 from 285 ℃ to 270 ℃. This is likely because the abundant oxygen-containing functional groups on the surface of rPET-CDs formed hydrogen bonds with PA66 molecular chains, reducing the hydrogen bonding interactions between PA66 molecular chains. This decreased the apparent viscosity of the melt, lowered the spinning temperature, and moved it away from the thermal degradation-sensitive region, thereby mitigating thermal degradation and gelation during spinning and improving the stability of PA66 spinning. In terms of mechanical properties, the addition of rPET-CDs synergistically enhanced the tensile strength and elongation at break of PA66 fibers, which may be attributed to the abundant —OH/—NH₂ groups on the surface of rPET-CDs. The functional groups on the surface of rPET-CDs formed hydrogen bonds with the amide bonds of PA66 molecular chains, creating cross-linking points between the molecular chains and enhancing the mechanical properties of the fiber. Additionally, rPET-CDs acted as a plasticizer in PA66, increasing the elongation at break of PA66 fibers. The reduction in spinning temperature further corroborates the plasticizing effect of rPET-CDs in PA66.

Conclusion The addition of rPET-CDs improved the flame retardancy of PA66. Flame retardancy mechanism studies indicated that the incorporation of rPET-CDs into PA66 reduced the pore size of the char residue and made the char layer more continuous, contributing to a solid-phase flame retardant effect. However, the decreased densification degree of the char residue limited the improvement in flame retardancy. Furthermore, the addition of rPET-CDs significantly enhanced the spinnability and mechanical properties of PA66. The spinning temperature was reduced from 285 ℃ to 270 ℃, which helped mitigate thermal degradation and gelation, thereby improving the stability of PA66 spinning. Mechanically, the addition of rPET-CDs synergistically increased the tensile strength and elongation at break of PA66 fibers, likely due to the abundant —OH/—NH₂ groups on the surface of rPET-CDs. These functional groups formed hydrogen bonds with the amide bonds of PA66 molecular chains, creating cross-linking points and enhancing the mechanical properties of the fiber. Additionally, rPET-CDs acted as a plasticizer, increasing the elongation at break of PA66 fibers.

Key words: flame-retardant fiber, PET waste, carbon dot, polyamide 66, flame retardancy, spinnability, functional fiber

中图分类号:

TQ342.12

魏建斐, 魏艳颖, 马超慧, 胡晓鹏, 邴琳涵, 樊瑜, 林彬泽, 董振峰, 朱志国, 王锐. 碳点的宏量制备及其对聚酰胺66阻燃与力学性能协同增强机制[J]. 纺织学报, 2026, 47(02): 37-46.

WEI Jianfei, WEI Yanying, MA Chaohui, HU Xiaopeng, BING Linhan, FAN Yu, LIN Binze, DONG Zhenfeng, ZHU Zhiguo, WANG Rui. Scalable synthesis of carbon dots from polyethylene terephthalate waste for synergistical enhancement of flame retardancy and mechanical properties of polyamide 66 fibers[J]. Journal of Textile Research, 2026, 47(02): 37-46.

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链接本文: http://www.fzxb.org.cn/CN/10.13475/j.fzxb.20250908101

http://www.fzxb.org.cn/CN/Y2026/V47/I02/37

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样品	T_5%/℃	T_max/℃	800 ℃时的残炭量/%
PA66	381.63	442.76	6.41
PA66/1% rPET-CDs	388.84	440.25	6.25
PA66/2% rPET-CDs	388.32	432.94	8.16
PA66/3% rPET-CDs	382.72	434.52	7.13

样品	LOI值/ %	垂直燃烧测试
样品	LOI值/ %	t₁/s	t₂/s	等级
PA66	25	13.14 ± 4.1	7.86 ± 3.7	V-2
PA66/1% rPET-CDs	26	8.62 ± 4.7	2.48 ± 2.2	V-2
PA66/2% rPET-CDs	28	7.38 ± 3.2	1.74 ± 0.5	V-2
PA66/3% rPET-CDs	29	6.58 ± 2.1	1.66 ± 0.4	V-2

样品	TTI值/s	pHRR值/ (kW·m^-2)	THR值/ (MJ·m^-2)
PA66	94	679.57	102.65
PA66/1% rPET-CDs	88	642.29	103.90
PA66/2% rPET-CDs	74	615.95	105.71
PA66/3% rPET-CDs	103	607.24	105.17

样品	COP/(g·s^-1)	CO₂P/(g·s^-1)
PA66	0.004 8	0.403 2
PA66/1% rPET-CDs	0.005 2	0.360 6
PA66/2% rPET-CDs	0.005 2	0.368 4
PA66/3% rPET-CDs	0.004 7	0.351 8

样品	FGI/ ( kW·m^-2·s^-1)	FPI/ (m²·s·kW^-1)	FRI
PA66	2.77	0.14	-
PA66/3% rPET-CDs	2.25	0.17	1.19

碳点的宏量制备及其对聚酰胺66阻燃与力学性能协同增强机制

Scalable synthesis of carbon dots from polyethylene terephthalate waste for synergistical enhancement of flame retardancy and mechanical properties of polyamide 66 fibers

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样品	纺丝温度/℃
样品	一区	二区	三区	四区	五区
PA66	250	280	285	285	285
PA66/1% rPET-CDs	250	270	270	275	275
PA66/2% rPET-CDs	250	270	270	270	270
PA66/3% rPET-CDs	250	270	270	270	270

牵伸倍数	质量分数/%	线密度/ tex	断裂强度/ (cN·dtex)	断裂伸长率/%
2.5	0	6.89	3.24 ± 0.19	54.62 ± 6.46
	1	6.92	3.34 ± 0.28	67.98 ± 3.27
	2	6.88	3.54 ± 0.24	73.43 ± 3.41
3.0	0	5.84	3.71 ± 0.15	33.00 ± 8.25
	1	5.80	4.50 ± 0.14	40.05 ± 7.44
	2	5.85	4.55 ± 0.20	41.91 ± 3.42
3.25	0	5.36	4.38 ± 0.21	29.15 ± 9.98
	1	5.41	4.58 ± 0.43	31.85 ± 1.72
	2	5.39	4.71 ± 2.25	32.34 ± 1.16

质量分数/%	牵伸倍数	声速取向法取向因子	X射线衍射法取向指数
0	2.5	0.63	0.73
	3.0	0.70	0.74
	3.25	0.75	0.77
1	2.5	0.67	0.84
	3.0	0.72	0.79
	3.25	0.75	0.66
2	2.5	0.63	0.81
	3.0	0.74	0.76
	3.25	0.74	0.71

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