Journal of Textile Research ›› 2025, Vol. 46 ›› Issue (06): 168-177.doi: 10.13475/j.fzxb.20241201101

• Dyeing and Finishing Engineering • Previous Articles     Next Articles

Preparation and properties of flame retardant polyacrylonitrile filament fabrics by layer-by-layer self-assembly method

DING Yuan1,2, ZHAO Yunxia1,2, JIN Gaoling3, YANG Tao3, XU Jing1,2(), KE Fuyou1,2, CHEN Ye1,2   

  1. 1. College of Materials Science and Engineering, Donghua University, Shanghai 201620, China
    2. State Key Laboratory of Advanced Fiber Materials, Donghua University, Shanghai 201620, China
    3. China Chemical Fibers Association, Beijing 100020, China
  • Received:2024-12-06 Revised:2025-03-06 Online:2025-06-15 Published:2025-07-02
  • Contact: XU Jing E-mail:gemini69@126.com

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Abstract:

Objective Polyacrylonitrile (PAN), is widely used in high-value-added applications, particularly in the development of domestically produced PAN filaments for the shielding covering layer of cable core materials. Cables are predominantly installed in buildings and densely populated areas, making them vulnerable to fire caused by factors such as increased loads, wire short-circuiting, and other electrical faults. During combustion, toxic gases, including hydrogen cyanide (HCN) and carbon monoxide (CO), are released, posing significant risks to human life and property safety. Consequently, enhancing the flame retardant properties of PAN filament fabrics has become a critical research focus in the industry.

Method In order to obtain the environmentally friendly flame retardancy of PAN fabrics, flame retardant polyacrylonitrile filament fabrics were prepared by using PAN filament fabrics as the substrate and constructing on it a ternary self-assembled flame retardant system using phytic acid (PA)/polyethyleneimine (PEI)/3-aminopropyltriethoxysilane (APTES), adopting the layer-by-layer self-assembly method. The surface morphology and macromolecular structure of the flame retardant modified fabrics, as well as their thermal stability and flame retardant properties were investigated.

Results The results showed that after self-assembly of PA/PEI/APTES layers, the flame retardant elements such as phosphorus (P), nitrogen (N) and silicon (Si) were effectively introduced on the surface of the PAN fabric, whereas the untreated PAN fabric had only the presence of C, N and O elements on its surface. The new P element was added on the surface of PAN-PEI fabrics, and the P content was increased to 8.81%, and the H2PO4/PO4 characteristic peaks at 133.8 eV were observed after self-assembly. The characteristic signal of Si element appeared in the XPS spectra when increasing APTES from 1.0% to 3.0%. The characteristic peak of H2PO4/PO4 was also observed. After further introduction of APTES, the Si element was increased from 1.13% to 3.78% when increasing APTES concentration from 1.0% to 3.0%, while the N and P elements were slightly decreased. The residual carbon of the fabrics before and after flame-retardant modification increased from 0 to 13.1% at 900 ℃, the limiting oxygen index (LOI) of the fabrics increased from 17.4% to 27.5%, the sustained ignition and negative ignition time of the fabrics reached 0 s. The total smoke release was decreased by 63.6% from 1.1 to 0.4 m2, and the heat release rate was reduced by 18.9%. The fabrics exhibited excellent performance after PA/PEI/APTES alternating assembly.

Conclusion A ternary flame retardant system of PA/PEI/APTES was constructed using layer-by-layer self-assembly technology, and the flame retardant polyacrylonitrile filament fabrics were successfully prepared, which is expected to be applied to shielding wrapping layers of internal cores of cables as well as to some application environments that do not need to be washed. Compared with the untreated PAN fabrics, the self-assembled flame retardant modified fabrics showed an increase in LOI value from 17.4% to 27.5%, a decrease in the maximum value of heat release rate by 18.9%, and a decrease in the total smoke release by 63.6%, which demonstrated that the flame retardant and smoke inhibition properties of the flame retardant modified fabrics were greatly improved.

Key words: polyacrylonitrile, flame retardant, layer-by-layer self-assembly, phytate, cable material, 3-aminopropyltriethoxysilane

CLC Number: 

  • TS195.17

Fig.1

PAN fabric pretreatment and self-assembly mechanism"

Fig.2

SEM images of fabrics before and after layer-by-layer self-assembly"

Fig.3

SEM images (a) and N,P,Si elemental distribution (b) of fabrics before and after layer-by-layer self-assembly"

Fig.4

Infrared spectra of fabrics before and after layer-by-layer self-assembly"

Tab.1

Surface element content of fabrics before and after layer-by-layer self-assembly %"

样品名称 Si N P C O
PAN 4.66 78.48 15.49
PAN-PEI 8.39 8.81 45.65 37.15
PAN-1Si 1.13 8.73 7.94 50.75 31.46
PAN-2Si 3.37 8.17 7.68 48.23 32.56
PAN-3Si 3.78 7.19 7.33 47.26 34.44

Fig.5

XPS spectra of fabrics before and after layer-by-layer self-assembly.(a)Full spectra;(b)P 2p narrow spectra;(c) Si 2p narrow spectra"

Fig.6

Thermogravimetric curves of fabrics in air before and after layer-by-layer self-assembly. (a)TG curves;(b)DTG curves"

Tab.2

Thermal performance parameters of fabrics before and after layer-by-layer self-assembly"

样品名称 T5%/℃ T1max/℃ T2max/℃ T3max/℃ 900 ℃时的
残炭量/%
PAN 294 311 380 655 0
PAN-PEI 297 302 411 722 1.9
PAN-1Si 293 302 412 705 3.8
PAN-2Si 284 298 400 773 8.2
PAN-3Si 272 303 396 816 13.1

Fig.7

Combustion mechanism of PA/PEI/APTES ternary flame retardant system"

Tab.3

Data of limiting oxygen index and vertical combustion of fabrics before and after layer-by-layer self-assembly"

样品名称 LOI值/% 损毁长度/mm 阴燃时间/s 续燃时间/s
PAN 17.4 300
PAN-PEI 21.8 200
PAN-1Si 21.3 300
PAN-2Si 24.0 148 0 0
PAN-3Si 27.5 65 0 0

Fig.8

Vertical combustion photographs of fabrics before and after layer-by-layer self-assembly"

Fig.9

Fabric heat release rate (a), total heat release rate (b), smoke release rate (c), and total smoke release (d) curves before and after layer-by-layer self-assembly"

Fig.10

Digital photographs of charcoal layer after conical calorimetry test"

Fig.11

SEM images of surface of charcoal layer"

Fig.12

Raman spectra of fabric residual carbon before and after layer-by-layer self-assembly"

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