CN109181295A - Phosphorus nitrogen halogen-free flame-retardant composition and its application of thermal stability are improved using inorganic and alkyl phosphite - Google Patents

Abstract

The invention discloses a kind of phosphorus nitrogen halogen-free flame-retardant compositions that thermal stability is improved using inorganic and alkyl phosphite, and by weight percentage, raw material composition includes: 40~90wt% of diethyl hypo-aluminum orthophosphate；20~50wt% of melamine polyphosphate；0.1~10wt% of zinc compound；0.1~5wt% of alkyl phosphite；Inorganic 0.1~5wt% of phosphite；Shown in the structural formula such as following formula (I) or following formula (II) of the alkyl phosphite, in formula, R is selected from the linear fatty alkyl that aromatic radical or carbon number are 1~6, and Me is selected from zinc, calcium or magnesium.Flame-retardant system disclosed by the invention have the characteristics that high fire-retardance, high heat stability, it is non-migratory, do not corrode equipment.It can be applied in fiberglass reinforced thermoplastic engineering plastic, obtain halogen-free flame-retardant glass fiber enhancing thermoplastic engineering plastic, the component or product of field of electronics can be prepared.

Description

The phosphorus nitrogen halogen-free flame retardants group of thermal stability is improved using inorganic and alkyl phosphite Close object and its application

Technical field

The present invention relates to the technical fields of fire retardant, and in particular to a kind of to utilize inorganic phosphite and alkyl phosphite Compounding improves the phosphorus nitrogen halogen-free flame-retardant composition of thermal stability and the phosphorus nitrogen halogen-free flame-retardant composition is preparing Halogen resistance Fire the application in glass fiber reinforced materials.

Background technique

Fiberglass reinforced thermoplastic engineering plastic is steady because having good rigidity and impact resistance, low warpage properties, high size Qualitative, good appearance, easy processing molding and the performance characteristics such as recyclable and be widely used in field of electronics.? The application in these fields proposes fire-retardant requirement to material, and thermoplastic engineering plastic is combustible material, compound with glass Afterwards, due to the wick effect of glass, so that fiberglass reinforced engineering plastics are easier to burn.Therefore fiberglass reinforced engineering plastics are at this A little fields are in application, need to solve the problems, such as fire-retardant, and the presence of wick effect makes its fire-retardant difficulty bigger.Here heat Plastic engineering plastics refer mainly to polyester and nylon.

Currently, including the basic flame-retardant system of two classes for the fire-retardant of fiberglass reinforced thermoplastic engineering plastic: halogen system resistance Combustion system and non-halogen fire-retardant system.Halogen system flame-retardant system is usually brominated flame-retardant collaboration antimony oxide, a large number of studies show that, Fiberglass reinforced thermoplastic engineering plastic added with bromide fire retardant can produce thick smoke and the harmful substances such as hydrogen bromide in burning, Human body can be caused to suffocate, secondly, the electrical insulating property of halogenated flame retardant is poor, in some fields using also restrained.Therefore, it is Fiberglass reinforced thermoplastic engineering plastic is developed safe and environment-friendly, high performance halogen-free flame-retardant system and is had become a hot topic of research, in recent years There is the novel halogen-free flame retardants or flame-retardant system applied to fiberglass reinforced thermoplastic engineering plastic.

It according to the literature, mainly include that two major classes are basic applied to the halogen-free flame retardants of fiberglass reinforced thermoplastic engineering plastic System: one kind is red phosphorus；Another kind of is phosphorus nitrogen system flame-retardant system.For red phosphorus, although its good flame retardation effect, it faces two Problem: first is that the color of red phosphorus, limits its scope of application, it is generally only to apply in black products；Second is that in process In be easy to produce the violents in toxicity such as hydrogen phosphide, bring environmental protection and safety problem, therefore red phosphorus is not fiberglass reinforced engineering thermoplastic The optimal selection of plastics.For phosphorus nitrogen system flame-retardant system, this is a kind of efficient flame-retardant system, has high flame retarding efficiency, The some defects for avoiding red phosphorus are the hot spots studied at present.

With the most use, the phosphorus nitrogen compound system based on diethyl hypo-aluminum orthophosphate, for example, diethyl hypophosphorous acid is answered at present Aluminium compounds melamine Quadrafos (MPP) system, can be with due to the synergistic effect of phosphorus content with higher and phosphorus nitrogen It realizes the highly effective flame-retardant to fiberglass reinforced thermoplastic engineering plastic, product color problem is also not present, while there is very high de-agglomeration Temperature will not generate the hypertoxic gas such as hydrogen phosphide in the high temperature working processes of fiberglass reinforced thermoplastic engineering plastic.But for Phosphorus nitrogen compound system based on diethyl hypo-aluminum orthophosphate, however it remains some disadvantages are mainly manifested in: first is that two kinds of components are in height Certain reaction is had when warm to decompose, and generates a small amount of acidic materials, these acidic materials can be to the metal parts of process equipment The problem of generating corrosion, need replacing component after a certain time, bringing the increase of cost and reduce production efficiency；Second is that nitrogenous Compound MPP is there are certain precipitation, and material is in injection molding process, after being molded the product of certain modulus, the meeting on mold There are deposit, the presence of these deposits will affect the appearance of product, this is to need to stop work to clear up mold, can also reduce production Efficiency, while this precipitation can also cause fire retardant to migrate to product surface, cause fire retardant to be unevenly distributed and be lost, finally make The fire-retardant failure of material is obtained, there are security risks；Third is that the presence of MPP has degradation to thermoplastic polymer, it will be apparent that existing As if the melting means of material becomes larger, and easy to change, the especially impact property decline of material larger to the Effect on Mechanical Properties of material It is more.

As a whole, it is applied to the flame-retardant system of fiberglass reinforced thermoplastic engineering plastic at present, there are color, has Poisonous gas is easily precipitated, has the problems such as burn into degradation, discoloration and material mechanical performance decline, some are that fatal problem cannot then make With some are then to lead to increased costs, efficiency reduction etc..Therefore, it is necessary to develop novel halogen-free flame-retardant system.

Summary of the invention

The present invention is directed to the existing phosphorus based on diethyl hypo-aluminum orthophosphate applied to fiberglass reinforced thermoplastic engineering plastic The defect of nitrogen compounding flame retardant provides a kind of phosphorus nitrogen Halogen resistance that thermal stability is improved using inorganic and alkyl phosphite Fire agent composition, the flame-retardant system have the characteristics that high fire-retardance, high heat stability, it is non-migratory, do not corrode equipment.It can be applied to glass Enhance in thermoplastic engineering plastic, obtains halogen-free flame-retardant glass fiber enhancing thermoplastic engineering plastic, field of electronics can be prepared Component or product.

Specific technical solution is as follows:

A kind of phosphorus nitrogen halogen-free flame-retardant composition improving thermal stability using inorganic and alkyl phosphite, by weight hundred Divide than meter, raw material composition includes:

Shown in the structural formula such as following formula (I) or following formula (II) of the alkyl phosphite:

In formula, R is selected from the linear fatty alkyl that aromatic radical or carbon number are 1~6, and Me is selected from zinc, calcium or magnesium.

Present invention application diethyl hypo-aluminum orthophosphate, by being assisted with MPP, zinc compound and inorganic and alkyl phosphite Together, inorganic and organic phosphite cooperation thermal stabilization phosphorus nitrogen halogen-free flameproof compound system is formed, it is easy to solve existing flame-retardant system Burn into precipitation easy to migrate and the defects of to the destruction of basis material.The novel flame-retardant system can be well adapted for fiberglass reinforced Thermoplastic engineering plastic, the bittern-free flame-proof material being had excellent performance.

It will elaborate below to the present invention.

The present invention is to solve existing for the existing halogen-free flame-retardant system applied in fiberglass reinforced thermoplastic engineering plastic For the purpose of various defects, inventor is had made extensive and intensive studies.For the existing compounding based on diethyl hypo-aluminum orthophosphate Flame-retardant system has investigated new flame-retardant system, as a result, it has been found that in diethyl the flame-proof glass fibre enhancement engineering plastics the problem of In base hypo-aluminum orthophosphate and MPP collaboration system, a small amount of zinc compound and inorganic and organic phosphite collaboration system are added, it can be very It solves these problems well.

The chemical structure of diethyl hypo-aluminum orthophosphate is shown below:

Diethyl hypo-aluminum orthophosphate is characterized in phosphorus content height, good flame resistance, temperature of initial decomposition with higher, water solubility Low, resistance to migration is nonhygroscopic, and more application is in the engineering plastics such as nylon, PBT at present, especially engineering plastics of fiberglass reinforced In.Diethyl hypo-aluminum orthophosphate is used alone, there is no being precipitated, but its flame retardant property is insufficient, therefore also need with it is nitrogenous MPP compounding, can be only achieved fire-retardant ask.It applies at present in the flame-retardant system of glass fiber enhanced nylon substantially with diethyl hypophosphorous acid Aluminium cooperates with MPP system.

But diethyl hypophosphorous acid with MPP when being used in compounding, although its flame retardant property is preferable, its decomposition temperature can drop It is low, sour gas and ammonia can be released in process, process equipment metal parts can be generated and be corroded, and the migration of MPP Characteristic influences appearance so that there are deposits for die surface, needs periodic cleaning mold, production efficiency is reduced, in addition, MPP pairs Matrix polymer has degradation, will lead to melting means increase, mechanical properties decrease and easy to change.It will be apparent that needing to eliminate Other negative effects in addition to fire-retardant of MPP.

Inventors discovered through research that a small amount of alkane is added in the flame-retardant system that diethyl hypo-aluminum orthophosphate and MPP are cooperateed with Base phosphite and special zinc compound, can play the role of it is heat-staple, solve MPP pyrolytic and to matrix polymerize The degradation of object, avoid burn into be precipitated, discoloration and the problems such as mechanical properties decrease, while the flame retardant property of the system does not have It is affected.

Alkyl phosphite compound with the structural formula as shown in above formula (I) or above formula (II) has very high thermal decomposition Temperature can act synergistically with diethyl hypo-aluminum orthophosphate, keep higher anti-flammability, while water-soluble low, resistance to migration.

Preferably, the R is selected from methyl or ethyl；The molecular weight of R group is smaller, and phosphorus content is higher, to fire-retardant more advantageous.

The alkyl phosphorous acid metal salt the preparation method comprises the following steps:

(1) alkyl phosphite hydrolyzes in acid condition, and alkyl phosphorous acid is made；

(2) alkyl phosphorous acid and metal hydroxides are in acid condition, in an aqueous medium, anti-in 150~180 DEG C of high pressures It answers；

(3) suspension is filtered, washed and is dry, pulverize at 200~240 DEG C to certain partial size.

The alkyl phosphorous acid metal salt being prepared has very high thermal decomposition temperature, can cooperate with diethyl hypophosphites Effect, while water-soluble low, resistance to migration, white in appearance are powdered.

The zinc compound includes zinc borate, zinc stannate, zinc oxide etc..These special zinc compounds have height Decomposition temperature, water-soluble low, not migration precipitation.It can be cooperateed with phosphorus constructed of aluminium, improve anti-flammability, and there is suppression cigarette to make With reduction smoke density.

Inorganic phosphite compound has very high thermal decomposition temperature, can make with diethyl hypo-aluminum orthophosphate cooperative flame retardant With, higher anti-flammability is kept, higher than the flame retarding efficiency of organic phosphite but slightly poor with matrix compatibility, dispersibility is slightly poor, Water-soluble low, resistance to migration simultaneously.The inorganic phosphite includes Arizona bacilli, phosphorous acid magnesium, aluminium phosphite and phosphorous acid Zinc etc..

By inorganic and organic phosphite collaboration, both available diethyl hypophosphites and MPP compound system were high Thermal stability, and can have high mechanical property.Performance indexes is better than the inorganic phosphite or organic phosphorous of exclusive use Hydrochlorate.

After study, to obtain the P-N type compositional flame-retardant applied to fiberglass reinforced engineering plastics of high thermostabilization System, the raw material of the phosphorus nitrogen halogen-free flame-retardant composition, which forms, includes:

Preferably, the average grain diameter D50 of the diethyl hypo-aluminum orthophosphate is 20~50 μm；

The average grain diameter D50 of the melamine polyphosphate is 20~50 μm；

The average grain diameter D50 of the zinc compound is 20~50 μm；

The average grain diameter D50 of the alkyl phosphite is 20~50 μm；

The average grain diameter D50 of the inorganic phosphite is 20~50 μm.

After above-mentioned specific proportions, specific composition raw material is blended, that is, the phosphorus with high high-temp stability is prepared Nitrogen halogen-free flame-retardant composition.

The application of the invention also discloses the described phosphorus nitrogen halogen-free flame-retardant composition with high high-temp stability, it is specific public A kind of halogen-free flame-retardant glass fiber reinforced materials, including substrate, fiberglass reinforced body, fire retardant and other processing aids are opened；

The fire retardant includes the phosphorus nitrogen halogen-free flame-retardant composition with high high-temp stability；

The phosphorus nitrogen halogen-free flame-retardant composition of the high high-temp stability, is to confer to the function of high molecular material flame retardant property Property auxiliary agent, to reach relevant standard requirements, account for entire material system weight percent be 10~30%.

Preferably, the halogen-free flame-retardant glass fiber reinforced materials, by weight percentage, raw material composition includes:

The substrate is selected from nylon or polyester；

Preferably, the substrate is selected from nylon or polyester.Nylon base includes fatty polyamide, semi-aromatic polyamides Amine, such as nylon 6, nylon66 fiber, nylon MXD 6, nylon 12 and the high-temperature nylons such as nylon 46,4T, 6T, 9T, 10T, 12T；Polyester Substrate includes PBT and PET.

Further preferably, when the substrate is nylon, the phosphorus nitrogen halogen-free flame-retardant composition, by weight percentage Meter, raw material composition include:

The alkyl phosphite is selected from methylisothiouronium methylphosphite aluminium, and inorganic phosphite is selected from aluminium phosphite, methylisothiouronium methylphosphite The weight ratio of aluminium and aluminium phosphite is 1:1~4；

In terms of raw material gross weight, the additive amount of the fire retardant is 15~25%.

When the substrate is polyester, the phosphorus nitrogen halogen-free flame-retardant composition, by weight percentage, raw material composition packet It includes:

The alkyl phosphite is selected from methylisothiouronium methylphosphite aluminium, and inorganic phosphite is selected from aluminium phosphite, methylisothiouronium methylphosphite The weight ratio of aluminium and aluminium phosphite is 1:1~4；

In terms of raw material gross weight, the additive amount of the fire retardant is 15~20%.

Using the above-mentioned halogen-free flameproof for preferably constituting and being prepared with the phosphorus nitrogen halogen-free flame-retardant composition of content as fire retardant Glass fiber enhanced nylon or polyester, in the case where keeping excellent flame retardant properties, mechanical properties, polymeric matrix material does not occur Apparent degradation.

Halogen-free flame-retardant glass fiber reinforced materials are prepared, flame-retardant system is also needed to be dispersed in material.Pass through band plus glass Each component is completed melt blending in an extruder, and squeezes out and make by the double screw extruder of fine mouth and fire retardant powder feed inlet Grain.

Compared with prior art, the present invention has the advantage that

The invention discloses a kind of phosphorus nitrogen halogen-free flameproofs that thermal stability is improved using the collaboration of inorganic and alkyl phosphite The inorganic and alkyl phosphorous acid of specific proportions is added in the flame-retardant system that diethyl hypo-aluminum orthophosphate and MPP are cooperateed in agent composition Salt composite and zinc compound, then it is blended after, the phosphorus nitrogen halogen-free flame-retardant composition with high thermal stability is prepared, Which overcome the defects of existing flame-retardant system, may be used as the halogen-free flame-retardant system of fiberglass reinforced engineering plastics, can prepare new The halogen-free flame-retardant glass fiber applied to electric and electronic field of type enhances proprietary material.

Specific embodiment

Raw material:

(1) diethyl hypo-aluminum orthophosphate, 8003, Jiangsu Li Side new material Co., Ltd

(2) MPP, Melapur 200 is purchased from BASF

(3) zinc borate, Firebrake 500 are purchased from Borax

(4) nylon66 fiber, EPR27, table mountain mind horse

(5) glass, ECS301UW, Chongqing Polycomp International Co., Ltd

(6) antioxidant, 1098, BASF

(7) silicone, middle indigo plant morning twilight

(8) PBT, 211M, Changchun chemistry

(9) methylisothiouronium methylphosphite aluminium, Jiangsu Li Side new material Co., Ltd

(10) inorganic aluminium phosphite, Jiangsu Li Side new material Co., Ltd

Embodiment 1

Compounding flame retardant is applied in fiberglass reinforced engineering plastics, follows these steps and test method investigates fire retardant Performance.

1, the mixture of halogen-free flame-retardant system

The compounding flame retardant each component and other auxiliary agents for being added in machine and weighing up in advance according to the ratio are stirred in height, starts high-speed stirring It mixes, stirs 10min, complete the mixture of halogen-free flame-retardant system, discharge.

2, the extruding pelletization of material

Each area's temperature setting of double screw extruder in predetermined temperature, after temperature stablizes 20min, it is added from hopper poly- Object matrix is closed, by adding glass fiber opening to be added, fire retardant powder is fed glass by powder charging aperture, start host and feeder, Complete the extruding pelletization of material.The material for having made grain is sent into feed bin by blast system, and dries.

3, the application and test of material

The material dried is molded by the standard sample of various testing standard defineds in injection molding machine, and carries out correlation The test of material property.It is primarily upon following performance indicator:

A, fire-retardant

It is tested according to UL94V0 testing standard.

B, resistance to migration experiment

The plastic sample that will be prepared, is put into climatic chamber, is arranged 85 DEG C of temperature, relative humidity 85%, range estimation is seen Examine the state of the specimen surface after 168 hours.

C, corrosion experiment

One metal block is set on die head, and high-temperature material passes through 25Kg material granulation in die head and metal block contact, test The waste of metal afterwards, loss is higher, and corrosion resistance is poorer.Think that corrosion is acceptable if etching extent < 0.1%.

D, Mechanics Performance Testing

Impact strength is tested by ASTM D256, impact property is lower, and polymeric matrix degradation is more obvious.

E, melt index is tested

Test condition: 280 DEG C/2.16Kg, by melting means size come the palliating degradation degree of comparative polymers.

Each material and proportion are shown in Table 1 in embodiment 1, and obtained testing of materials the results are shown in Table 1.

Embodiment 2

Implementation process is same as Example 1, except adjustment methylisothiouronium methylphosphite aluminium and aluminium phosphite ratio in addition to, other materials and Proportion is shown in Table 1, and obtained material the results are shown in Table 1.

Embodiment 3

Implementation process is same as Example 1, except adjustment methylisothiouronium methylphosphite aluminium and aluminium phosphite ratio in addition to, other materials and Proportion is shown in Table 1, and obtained material the results are shown in Table 1.

Embodiment 4

Implementation process is same as Example 1, except adjustment methylisothiouronium methylphosphite aluminium and aluminium phosphite total amount in addition to, other materials and Proportion is shown in Table 1, and obtained material the results are shown in Table 1.

Embodiment 5

Implementation process is same as Example 1, except adjustment methylisothiouronium methylphosphite aluminium and aluminium phosphite total amount in addition to, other materials and Proportion is shown in Table 1, and obtained material the results are shown in Table 1.

Comparative example 1

Implementation process is same as Example 1, other than without using methylisothiouronium methylphosphite aluminium and aluminium phosphite.Other materials and match Than being shown in Table 1, obtained material the results are shown in Table 1.

Comparative example 2

Implementation process is same as Example 1, other than without using methylisothiouronium methylphosphite aluminium.Other materials and proportion are shown in Table 1, institute Obtained material the results are shown in Table 1.

Comparative example 3

Implementation process is same as Example 1, other than without using aluminium phosphite.Other materials and proportion are shown in Table 1, acquired Material the results are shown in Table 1.

Comparative example 4

Implementation process is same as Example 1, in addition to account for fire retardant total for the ratio of methylisothiouronium methylphosphite aluminium and inorganic aluminium phosphite Outside the 10% of weight.Other materials and proportion are shown in Table 1, and obtained material the results are shown in Table 1.

Table 1

Embodiment 6

Implementation process is same as Example 1, and nylon66 fiber is used instead PBT.Other materials and proportion are shown in Table 2, obtained material Material the results are shown in Table 2.

Embodiment 7

Implementation process is same as Example 2, and nylon66 fiber is used instead PBT.Other materials and proportion are shown in Table 2, obtained material Material the results are shown in Table 2.

Embodiment 8

Implementation process is same as Example 3, and nylon66 fiber is used instead PBT.Other materials and proportion are shown in Table 2, obtained material Material the results are shown in Table 2.

Embodiment 9

Implementation process is same as Example 4, and nylon66 fiber is used instead PBT.Other materials and proportion are shown in Table 2, obtained material Material the results are shown in Table 2.

Embodiment 10

Implementation process is same as Example 5, and nylon66 fiber is used instead PBT.Other materials and proportion are shown in Table 2, obtained material Material the results are shown in Table 2.

Comparative example 5

Implementation process is identical as comparative example 1, and nylon66 fiber is used instead PBT.Other materials and proportion are shown in Table 2, obtained material Material the results are shown in Table 2.

Comparative example 6

Implementation process is identical as comparative example 2, and nylon66 fiber is used instead PBT.Other materials and proportion are shown in Table 2, obtained material Material the results are shown in Table 2.

Comparative example 7

Implementation process is identical as comparative example 3, and nylon66 fiber is used instead PBT.Other materials and proportion are shown in Table 2, obtained material Material the results are shown in Table 2.

Comparative example 8

Implementation process is same as Example 6, in addition to the ratio of alkyl aluminium phosphite and aluminium phosphite is increased to account for it is fire-retardant Outside the 11.8% of agent weight toatl proportion.Other materials and proportion are shown in Table 2, and obtained material the results are shown in Table 2.

Table 2

Claims (10)

1. a kind of phosphorus nitrogen halogen-free flame-retardant composition for being improved thermal stability using inorganic and alkyl phosphite, feature are existed In by weight percentage, raw material composition includes:

Shown in the structural formula such as following formula (I) or following formula (II) of the alkyl phosphite:

In formula, R is selected from the linear fatty alkyl that aromatic radical or carbon number are 1~6, and Me is selected from zinc, calcium or magnesium.

2. the phosphorus nitrogen halogen-free flame retardants group according to claim 1 for improving thermal stability using inorganic and alkyl phosphite Close object, which is characterized in that the R is selected from methyl or ethyl.

3. the phosphorus nitrogen halogen-free flame retardants group according to claim 1 for improving thermal stability using inorganic and alkyl phosphite Close object, which is characterized in that the zinc compound is selected from least one of zinc borate, zinc stannate, zinc oxide.

4. the phosphorus nitrogen halogen-free flame retardants group according to claim 1 for improving thermal stability using inorganic and alkyl phosphite Close object, which is characterized in that the inorganic phosphite in aluminium phosphite, zinc phosphite, Arizona bacilli, phosphorous acid magnesium extremely Few one kind.

5. the phosphorus nitrogen halogen-free flame retardants group according to claim 1 for improving thermal stability using inorganic and alkyl phosphite Close object, it is characterised in that:

The average grain diameter D50 of the diethyl hypo-aluminum orthophosphate is 20~50 μm；

The average grain diameter D50 of the melamine polyphosphate is 20~50 μm；

The average grain diameter D50 of the zinc compound is 20~50 μm；

The average grain diameter D50 of the alkyl phosphite is 20~50 μm；

The average grain diameter D50 of the inorganic phosphite is 20~50 μm.

6. a kind of halogen-free flame-retardant glass fiber reinforced materials, which is characterized in that raw material composition includes substrate, reinforcement, fire retardant and adds Work auxiliary agent, which is characterized in that the fire retardant includes any phosphorus nitrogen halogen-free flame retardants combination according to claim 1~5 Object；

In terms of raw material gross weight, the additive amount of the fire retardant is 10~30%.

7. halogen-free flame-retardant glass fiber reinforced materials according to claim 6, which is characterized in that by weight percentage, raw material Composition includes:

8. halogen-free flame-retardant glass fiber reinforced materials according to claim 6, which is characterized in that the substrate is selected from nylon or poly- Ester.

9. halogen-free flame-retardant glass fiber reinforced materials according to claim 6 or 7, which is characterized in that the substrate is nylon, institute Phosphorus nitrogen halogen-free flame-retardant composition is stated, by weight percentage, raw material composition includes:

The alkyl phosphite be selected from methylisothiouronium methylphosphite aluminium, inorganic phosphite be selected from aluminium phosphite, methylisothiouronium methylphosphite aluminium with The weight ratio of aluminium phosphite is 1:1~4；

In terms of raw material gross weight, the additive amount of the phosphorus nitrogen halogen-free flame-retardant composition is 15~25%.

10. halogen-free flame-retardant glass fiber reinforced materials according to claim 6 or 7, which is characterized in that the substrate is polyester, The phosphorus nitrogen halogen-free flame-retardant composition, by weight percentage, raw material composition includes:

The alkyl phosphite be selected from methylisothiouronium methylphosphite aluminium, inorganic phosphite be selected from aluminium phosphite, methylisothiouronium methylphosphite aluminium with The weight ratio of aluminium phosphite is 1:1~4；

In terms of raw material gross weight, the additive amount of the phosphorus nitrogen halogen-free flame-retardant composition is 15~20%.