Synergistic effect of 1⁃oxo-4⁃hydroxymethyl-2，6，7⁃trioxa-1⁃phosphabicyclo ［2.2.2］ octane and ammonium polyphosphate on flame retardancy and smoke suppression of epoxy composites

doi:10.19491/j.issn.1001-9278.2024.11.001

Abstract

Abstract:

A series of epoxy composites with different loadings of 1⁃oxo⁃4⁃hydroxymethyl⁃2，6，7⁃trioxa⁃l⁃phosphabicyclo ［2.2.2］ octane （PEPA） and ammonium polyphosphate （APP） and a fixed loading of montmorillonite （MMT） were prepared to enhance their flame⁃retardancy. The synergistic effect of APP and PEPA on the flame⁃retardant properties of the epoxy composites was evaluated by vertical burning experiment， limiting oxygen index， and cone calorimetry. A smoke density test was also carried out to demonstrate the collaborative smoke suppression effect of APP and PEPA. The experimental results indicated that when 15 wt% of APP/PEPA/MMT at a mass ratio 69/25/6 was incorporated into epoxy resin， the resultant epoxy composite obtained an improvement in limiting oxygen index up to 31.5 % and reached the UL94 V⁃0 rating in the vertical burning test. Moreover， its peak heat release rate （HRR） and total smoke release （TSR） decreased by 73.6 % and 70 %， respectively. Based on the HRR， peak HRR， and TSR results obtained from cone calorimetric measurements， PEPA， APP， and their compounds can generate good flame⁃retardant effectiveness in both gas phase and condensed phase. To understand the synergistic mechanisms about the flame⁃retardant and smoke suppression effects deeply， thermal gravimetric analysis coupled with Fourier⁃transform infrared spectroscopy， visual observation， and scanning electron microscopy were conducted to characterize the gas and condensed phases of epoxy composites containing APP and PEPA flame retardants.

Key words: epoxy resin, composite, flame retardancy, ammonium polyphosphate, 1?oxo?4?hydroxymethyl?2，6，7?trioxa?l?phosphabicyclo ［2.2.2］ octane

CLC Number:

TQ322.4

JI Meiyu, ZHAO Yizhe, ZHANG Wenchao, GUO Xiaoyan, YANG Rongjie. Synergistic effect of 1⁃oxo-4⁃hydroxymethyl-2，6，7⁃trioxa-1⁃phosphabicyclo ［2.2.2］ octane and ammonium polyphosphate on flame retardancy and smoke suppression of epoxy composites[J]. China Plastics, 2024, 38(11): 1-7.

Figures/Tables 12

References 28

1	杨晨，唐晓东，李晶晶，等.双酚 A 型环氧树脂合成技术进展［J］. 中国塑料，2023，37 （2）： 106⁃112.
	YANG C， TANG X D， LI J J， et al. Research progress in synthetic technology of bisphenol⁃A epoxy resin ［J］. China Plastics， 2023， 37（2）： 106⁃112.
2	Lu L G， Zeng Z J， Qian X D，et al. Thermal degrada‐tion and combustion behavior of flame⁃retardant epoxy resins with novel phosphorus‐based flame retardants and silicon ［J］. Particles Polymer Bulletin， 2019， 76（7）： 3 607‐3 619.
3	Huo S Q， Wang J， Yang S， et al. Flame retardant performance and mechanism of epoxy thermosets modified with a novel reactive flame retardant containing phosphorus， nitrogen， and sulfur ［J］. Polymers for Advanced Technologies， 2018， 29（1）： 497‐506.
4	Yang G， Wu W⁃H， Wang Y⁃H， et al. Synthesis of a novel phosphazene⁃based flame retardant with active amine groups and its application in reducing the fire hazard of epoxy resin ［J］. Journal of Hazardous Materials， 2019， 366： 78⁃87.
5	Jin F L， Li X， Park S J. Synthesis and application of epoxy resins： A review ［J］. Journal of Industrial and Engineering Chemistry，2015，29：1⁃11.
6	Mao Y W， Cai H P， Gao L H，et al.A P/N additive to optimise the flame retardancy， low dielectricity and mechanical properties of EP composites［J］.Reactive & Functional Polymers，2023，193：105762.
7	Jiang J W， Huo S Q， Zheng Y， et al.A novel synergistic flame retardant of hexaphenoxycyclotriphosphazene for epoxy resin［J］. Polymers，2021，13（21）：3648.
8	Shi Y Q， Fu T， Xu Y J，et al.Novel phosphorus⁃containing halogen⁃free ionic liquid toward fire safety epoxy resin with well⁃balanced comprehensive performance［J］.Chemical Engineering Journal，2018，354：208⁃219.
9	Zhang Y， Cui Y L， He J Y，et al.Novel exploration of the flame retardant potential of 1⁃oxo-4⁃hydroxymethyl-2，6，7⁃trioxa-1⁃phosphabicyclo 2.2.2 octane⁃functio nalized metallophthalocyanines in epoxy composites［J］.Polymer Degradation and Stability，2022，204：110094.
10	Yang W J， Wu Q J， Zhou Y， et al.Multifunctional phosphorus⁃containing porphyrin dye for efficiently improving the thermal， toughness， flame retardant and dielectric properties of epoxy resins ［J］. Progress in Organic Coatings，2024，186：107967.
11	Cheng H X， Guo J H， Ye Y， et al.Molecular design and properties of intrinsic flame⁃retardant P⁃N synergistic epoxy resin ［J］. Journal of Applied Polymer Science，2023：54885.
12	Chai M Z， Liu L， Zhang P B， et al.Long shelf life， intrinsically flame retardant， transparent， high⁃performance one⁃component epoxy resin based on phosphorus⁃containing imidazole derivatives［J］. Polymer Degradation and Stability，2023，218：110587.
13	Huo S Q， Yang S， Wang J， et al.A liquid phosphorus⁃containing imidazole derivative as flame⁃retardant curing agent for epoxy resin with enhanced thermal latency， mechanical， and flame⁃retardant performances ［J］. Journal of Hazardous Materials，2020，386：121984.
14	Tang S， Qian L， Qiu Y， et al.High⁃performance flame retardant epoxy resin based on a bi⁃group molecule containing phosphaphenanthrene and borate groups ［J］. Polymer Degradation and Stability，2018，153：210⁃219.
15	Wang D， Liu Q， Peng X， et al.High⁃efficiency phosphorus/nitrogen⁃containing flame retardant on epoxy resin ［J］. Polymer Degradation and Stability，2021，187：109544.
16	Yu M， Zhang T， Li J， et al.Enhancing toughness， flame retardant， hydrophobic and dielectric properties of epoxy resin by incorporating multifunctional additive containing phosphorus/silicon ［J］. Materials & Design，2023，225：111529.
17	Doan H T， Nguyen N T， Hac N T， et al.Synthesis and synergistic effect of cuprous（I） oxide nanoparticles and polyethyleneimine modified ammonium polyphosphate on enhancing the flame resistance of epoxy resin ［J］.Materials Research Express，2023，10（11）： 115002.
18	Yang H， Qin Y， Liang D， et al.Preparation of a novel flame retardant based on phosphorus/nitrogen modified lignin with metal⁃organic framework and its application in epoxy resin ［J］. Journal of Thermal Analysis and Calorimetry，2023，148（22）：12 845⁃12 857.
19	Shi Y C， Wang G J.The novel epoxy/PEPA phosphate flame retardants：Synthesis， characterization and application in transparent intumescent fire resistant coatings［J］.Progress in Organic Coatings，2016，97：1⁃9.
20	Zhao C S， Jiang Y S， Fu W， et al. Development of an epoxy⁃based self⁃intumescent fire protective coating containing an appropriate mass ratio of APP and Cu₂O ［J］. Journal of Coatings Technology and Research，2023，25： 547–558.
21	Wang X， Hu Y， Song L， et al.Effect of a triazine ring⁃containing charring agent on fire retardancy and thermal degradation of intumescent flame retardant epoxy resins ［J］. Polymers for Advanced Technologies，2011，22（12）：2 480⁃2 487.
22	黎瑶，沈文涛，许苗军. 钠基蒙脱土协效阻燃，抑烟环氧树脂［J］.塑料，2023（1）：11⁃14.
	LI Y， SHEN W T， XU M J. Synergistic flame retardancy and smoke suppression of sodium montmorillonite for epoxy resin thermosets［J］.Plastics，2023（1）：11⁃14.
23	Qin P， Yi D， Hao J， et al.Fabrication of melamine trimetaphosphate 2D supermolecule and its superior performance on flame retardancy， mechanical and dielectric properties of epoxy resin［J］. Composites Part B： Engineering，2021，225：109269.
24	Oliwa R， Heneczkowski M， Oleksy M，et al.Epoxy composites of reduced flammability ［J］.Composites Part B：Engineering，2016，95：1⁃8.
25	Huo S Q， Song P A， Yu B， et al.Phosphorus⁃containing flame retardant epoxy thermosets： Recent advances and future perspectives ［J］. Progress in Polymer Science，2021，114：101366.
26	Ye X M， Zhang X L， Jiang Y Y，et al.Controllable dimensions and regular geometric architectures from self⁃assembly of lithium⁃containing polyhedral oligomeric silsesquioxane： Build for enhancing the fire safety of epoxy resin［J］.Composites Part B⁃Engineering，2022，229：109483.
27	Zhong X， Yang X， Ruan K， et al.Discotic liquid crystal epoxy resins integrating intrinsic high thermal conductivity and intrinsic flame retardancy ［J］. Macromolecular Rapid Communications，2021，43（1）： 2100580.
28	Hou B， Zhang W， Lu H，et al.Multielement flame⁃retardant system constructed with metal POSS⁃organic frameworks for epoxy resin［J］.ACS Applied Materials & Interfaces，2022，14（43）：49 326⁃49 337.

样品	LOI/%	UL94	t₁/s	t₁/s	熔滴滴落
EP/0	23.0	—	>60	—	否
EP/PEPA94	26.5	—	>60	—	是
EP/APP94	27.8	V⁃0	0	0	否
EP/APM29	28.3	V⁃0	0	0	否
EP/APM49	29.2	V⁃0	0	0	否
EP/APM69	31.5	V⁃0	0	0	否
EP/APM89	35.0	V⁃0	0	0	否

样品	LOI/%	UL94	t₁/s	t₁/s	熔滴滴落
EP/0	23.0	—	>60	—	否
EP/PEPA94	26.5	—	>60	—	是
EP/APP94	27.8	V⁃0	0	0	否
EP/APM29	28.3	V⁃0	0	0	否
EP/APM49	29.2	V⁃0	0	0	否
EP/APM69	31.5	V⁃0	0	0	否
EP/APM89	35.0	V⁃0	0	0	否

样品	TTI/s	p⁃HRR/ kW·m^-2	THR/ MJ·m^-2	TSR/ m²·m^-2	MeanSEA/ m²·kg^-1	MeanCOY/ kg·kg^-1	MeanCO₂Y/ kg·kg^-1	残炭率/%
EP/0	46	823	76	3 773	666	0.05	0.97	2.51
EP/PEPA94	37	392	63	2 300	743	0.09	1.30	22.20
EP/APP94	35	505	43	1 143	559	0.07	1.35	48.85
EP/APM29	39	238	53	1 881	606	0.10	1.17	21.76
EP/APM49	42	259	57	1 476	494	0.09	1.30	24.11
EP/APM69	41	217	36	1 131	479	0.06	1.16	26.18
EP/APM89	39	406	53	1 577	595	0.10	1.30	33.23

样品	TTI/s	p⁃HRR/ kW·m^-2	THR/ MJ·m^-2	TSR/ m²·m^-2	MeanSEA/ m²·kg^-1	MeanCOY/ kg·kg^-1	MeanCO₂Y/ kg·kg^-1	残炭率/%
EP/0	46	823	76	3 773	666	0.05	0.97	2.51
EP/PEPA94	37	392	63	2 300	743	0.09	1.30	22.20
EP/APP94	35	505	43	1 143	559	0.07	1.35	48.85
EP/APM29	39	238	53	1 881	606	0.10	1.17	21.76
EP/APM49	42	259	57	1 476	494	0.09	1.30	24.11
EP/APM69	41	217	36	1 131	479	0.06	1.16	26.18
EP/APM89	39	406	53	1 577	595	0.10	1.30	33.23

样品	T_{5 %}/℃	T_max/℃	R_max/%·min^-1	800 ℃残炭率/%
EP/0	368.8	415.5	-17.05	12.44
EP/PEPA94	310.7	357.3	-11.39	25.12
EP/APP94	308.3	350.2	-9.63	27.80
EP/APM29	319.1	354.1	-15.44	31.87
EP/APM49	318.9	356.1	-15.57	27.49
EP/APM69	324.2	354.3	-15.21	31.24
EP/APM89	319.0	355.8	-14.89	31.43