Controllable Preparation of Hyperbranched Polyphosphoramide Coated Carbon Nanotubes and Its Application for Flame Retardancy

doi:10.19491/j.issn.1001-9278.2021.09.009

Abstract

Abstract:

Three types of hyperbranched polyphosphoramide coated carbon nanotubes （CNTs/HBPPA） with different coating thicknesses were prepared through one-step polymerization （A₂+B₃） using carboxylic CNTs （CNT-COOH） as a core material， phosphorus oxychloride （POCl₃） and N， N?diaminodiphenylmethane （DDM） as monomers， and triethylamine as an acid binding and catalytic agent. A series of epoxy （EP） composites with different contents of CNT/HBPPA were then fabricated， and the reinforcing and flame?retarding effects were investigated. It was found that with increasing the mass ratio of CNT to （POCl₃+DDM）（1∶1.5~6）， the there is an increase in the coating thickness of CNT/HBPPA but an reduction in T_5% （the characteristic temperature at 95 wt.% mass loss） and residual char yield. The CNT/HBPPA cross-linked together when the mass ratio increased to 1：6. Among those composite samples， the CNT/HBPPA-3 exhibited optimum reinforcing and flame-retarding effects on the EP composites. The experimental results indicated that the EP composites containing 2 wt% CNT/HBPPA achieved the largest LOI of 28.2 %， highest tensile of 53.28 MPa， and highest impact strength of 11.19 kJ/m² as well as a UL 94 V-1 classification. There are a great number of active groups of -NH₂ dispersed on surface of CNT/HBPPA， leading to better interfacial compatibility with the EP matrix. Therefore， the additives could be distributed more homogeneously and act as the net-shaped skeleton in the EP composites to achieve better flame retardancy and mechanical properties. During the combustion process， the skeleton of CNT/HBPPA potentially cross-linked together to construct a more compact and continuous char layer， which could protect the underlying materials against the heat and combustible volatiles transmission efficiently.

Key words: hyperbranched polyphosphamide, carbon nanotubes, epoxy resin, flame retardancy

CLC Number:

TQ323.5

PENG Fanchang, CHEN Xiaosui, ZHANG Aiqing, ZHOU Hongfu. Controllable Preparation of Hyperbranched Polyphosphoramide Coated Carbon Nanotubes and Its Application for Flame Retardancy[J]. China Plastics, 2021, 35(9): 55-63.

Figures/Tables 16

References 22

1	曹俊，衣惠君，洪臻，等.反应型和添加型含磷阻燃剂阻燃环氧树脂的性能研究［J］.中国塑料，2013，27（9）：81⁃84.
	CAO J， YI H J， HONG Z， et al. Study on the Properties of Flame Retarded Epoxy Resin with Reactive or Additive Flame Retardant Containing⁃phosphorus［J］. China Plastics， 2013， 27（9）： 81⁃84.
2	张群安，杜朝军，史政海，等.环境友好型阻燃剂的合成及性能研究［J］.中国塑料， 2015， 29（11）： 97⁃101.
	ZHANG Q A， DU C J， SHI Z H， et al. Synthesis and Properties of Environment⁃friendly Flame Retardant［J］. China Plastics，2015，29（11）：97⁃101.
3	WU Q， ZHU W， ZHANG C， et al. Study of Fire Retardant Behavior of carbon Nanotube Membranes and Carbon Nanofiber Paper in Carbon Fiber Reinforced Epoxy Composites ［J］. Carbon， 2010， 48： 1 799⁃1 806.
4	XU Z S， DENG N， YAN L，et al. Functionalized Multiwalled Carbon Nanotubes with Monocomponent Intumescent Flame Retardant for Reducing the Flammability and Smoke Emission Characteristics of Epoxy Resins ［J］. Polymers Advanced Technologies， 2018， 29： 3 002⁃3 013.
5	FENG Y Z， HE C E， WEN Y F， et al. Improving Thermal and Flame Retardant Properties of Epoxy Resin by Functionalized Graphene Containing Phosphorous， Nitrogen and Silicon Elements ［J］. Composites Part A， 2017， 103： 74⁃83.
6	JIANG W Z， HAO J W， HAN Z D. Study on the Thermal Degradation of Mixtures of Ammonium Polyphosphate and a Novel Caged Bicyclic Phosphate and Their Flame Retardant Effect in Polypropylene ［J］. Polymer Degradation and Stability， 2012， 97（4）： 632⁃637.
7	WANG Y， XU M J， LI B. Synthesis of N⁃methyl Triazine⁃ethylenediamine Copolymer Charring Foaming Agent and its Enhancement on Flame Retardancy and Water Resistance for Polypropylene Composites ［J］. Polymer Degradation and Stability， 2016， 131： 20⁃29.
8	胡晋，陈小随，彭凡畅，等.超支化聚磷酰胺膨胀型阻燃剂的制备及其协同聚磷酸铵对聚丙烯的阻燃性能研究［J］.中国塑料，2020，34（2）：16⁃22.
	HU J， CHENG X S， PENG F C， et al. Synthesis of a Novel Intumescent Flame Retardant Hyperbranched Polyphosphoramide and its Synergistic Effect on the Flame Retardancy of Polypropylene Composites with Ammonium Polyphosphate ［J］.China Plastic， 2020， 34 （2）： 16⁃22.
9	ZHANG J H， KONG Q H， WANG D Y. Simultaneously Improving the Fire Safety and Mechanical Properties of Epoxy Resin with Fe⁃CNTs via Large⁃scale Preparation ［J］. Journal of Materials Chemistry A， 2018， 6： 6 376⁃6 386.
10	FENG Y Z， LI X G， ZHAO X Y， et al. Synergetic Improvement in Thermal Conductivity and Flame Retardancy of Epoxy/Silver Nanowires Composites by Incorporating “Branch⁃Like” Flame⁃retardant Functionalized Graphene ［J］. Applied Materials & Interfaces， 2018， 10： 21 628⁃21 641.
11	DU B X， FANG Z G. Effects of Carbon Nanotubes on the Thermal Stability and Flame Retardancy of Intumescent Flame⁃retarded Polypropylene ［J］. Polymer Degradation and Stability， 2011， 96： 1 725⁃1 731.
12	YU T， JING N， LI Y. Functionalized Multi⁃walled Carbon Nanotube for Improving the Flame Retardancy of Ramie/poly（lactic acid） Composite ［J］. Composites Science and Technology， 2014， 104： 26⁃33.
13	LIU L B， XU Y， XU M J， et al. Economical and Facile Synthesis of a Highly Efficient Flame Retardant for Simultaneous Improvement of Fire Retardancy， Smoke Suppression and Moisture Resistance of Epoxy Resins ［J］. Composites Part B， 2019， 167： 422⁃433.
14	LI C ， KANG N J ， LABRANDERO S D ， et al. Synergistic Effect of Carbon Nanotube and Polyethersulfone on Flame Retardancy of Carbon Fiber Reinforced Epoxy Composites［J］. Industrial & Engineering Chemistry Research， 2014， 53（3）：1 040⁃1 047.
15	WANG S J， XIN F， CHEN Y， et al. Phosphorus⁃nitrogen Containing Polymer Wrapped Carbon Nanotubes and their Flame⁃retardant Effect on Epoxy Resin ［J］. Polymer Degradation and Stability， 2016， 129： 133⁃141.
16	梁志彬，赵殊，王兴宁，等. 新型水溶性超支化聚酰胺⁃酯的合成［J］. 合成化学， 2012， 20（1）： 32⁃35.
	LING Z B， ZHAO S， WANG X N， et al. Synthesis of Novel Water⁃soluble Hyperbranched Polyamide⁃esters ［J］. Synthetic Chemistry ， 2012， 20（1）： 32⁃35.
17	KUAN S F， CHEN W J， LI Y L， et al. Flame Retardance and Thermal Stability of Carbon Nanotube Epoxy Composite Prepared from Sol⁃gel Method ［J］. Journal of Physics and Chemistry of Solids， 2010， 71： 539⁃543.
18	ZHANG J P， LIU L， LI A. Novel Branched Phosphorus⁃containing Flame Retardant： Synthesis and Its Application ［J］. Industrial & Engineering Chemistry Research， 2016， 55（1）： 10 218⁃10 225.
19	ZHANG L D， JEONG Y I. Crosslinked Poly（ethylene glycol） Hydrogels with Degradable Phosphamide Linkers used as a Drug Carrier in Cancer Therapy ［J］. Macromolecular Bioscience， 2014， 14（3）： 401⁃410.
20	WANG X F， ZHAN J， XING W Y， et al. Flame Retardancy and Thermal Properties of Novel UV⁃curable Epoxy Acrylate Coatings Modified by a Silicon⁃bearing Hyperbranched Polyphosphonate Acrylate ［J］. Industrial & Engineering Chemistry， 2013， 52： 5 548⁃5 555.
21	GU L Q， QIU J H， YAO Y W， et al. Functionalized MWCNTs Modified Flame Retardant PLA Nanocomposites and Cold Rolling Process for Improving Mechanical Properties ［J］. 2018， 161： 39⁃49.
22	SANTANU B， SUMAN K S. Soft⁃nanocomposites of Nanoparticles and Nanocarbons with Supramolecular and Polymer Gels and their Applications ［J］. Chemical Reviews， 2016， 116： 11 967⁃12 028.

样品	温度/℃			700 ℃ 残炭率/%
样品	T_{5 %}/℃	T_max1/℃	T_max2/℃	700 ℃ 残炭率/%
CNT	613.0	-	-	91.8
HBPPA	218.1	219.4	311.6	47.7
CNT/HBPPA?1.5	255.4	260.5	-	77.5
CNT/HBPPA?3	277.8	255.5	337.3	61.9
CNT/HBPPA?6	220.2	236.9	315.0	58.9

样品	温度/℃			700 ℃ 残炭率/%
样品	T_{5 %}/℃	T_max1/℃	T_max2/℃	700 ℃ 残炭率/%
CNT	613.0	-	-	91.8
HBPPA	218.1	219.4	311.6	47.7
CNT/HBPPA?1.5	255.4	260.5	-	77.5
CNT/HBPPA?3	277.8	255.5	337.3	61.9
CNT/HBPPA?6	220.2	236.9	315.0	58.9

样品名称	UL 94等级
样品名称	1 %	2 %	3 %
纯EP	无等级	-	-
EP/CNT?COOH	无等级	无等级	无等级
EP/CNT/HBPPA?1.5	无等级	无等级	V?2
EP/CNT/HBPPA?3	V?2	V?1	V?1
EP/CNT/HBPPA?6	V?1	V?1	V?1

样品名称	UL 94等级
样品名称	1 %	2 %	3 %
纯EP	无等级	-	-
EP/CNT?COOH	无等级	无等级	无等级
EP/CNT/HBPPA?1.5	无等级	无等级	V?2
EP/CNT/HBPPA?3	V?2	V?1	V?1
EP/CNT/HBPPA?6	V?1	V?1	V?1

样品	热降解温度		700 ℃残炭率/%
样品	T_{5 %}/℃	T_max/℃	实验值	理论值
EP	294.9	379.9	19.7	-
EP/2 %CNT?COOH	364.3	383.7	21.0	21.1
EP/2 %CNT/HBPPA?1.5	357.3	383.3	21.2	20.8
EP/2 %CNT/HBPPA?3	353.6	381.2	22.0	20.5
EP/2 %CNT/HBPPA?6	352.0	379.3	23.2	20.5