CN108795039A - The halogen-free flame-retardant system and its application that dialkyl dithio hypophosphites is cooperateed with organic phosphite - Google Patents

Abstract

The invention discloses a kind of halogen-free flame-retardant system that dialkyl dithio hypophosphites is cooperateed with organic phosphite, raw material composition includes：Dialkyl dithio hypophosphites 50~95%, organic phosphite 4~40% and zinc compound 1~10%；The dialkyl dithio hypophosphites, shown in structural formula such as formula (I), in formula, R₁、R₂Independently selected from straight chained alkyl or branched alkyl, carbon number is 1~6；M is selected from Mg, Ca, Al, Sb, Sn, Ge, Ti, Fe, Zr, Zn, Ce, Bi, Sr, Mn, Li, Na, K, H or NH₄, m is 1~4.The halogen-free flame-retardant system has the characteristics that high fire-retardance, non-migratory, not etching apparatus, is well adapted for fiberglass reinforced thermoplastic engineering plastic system, obtains the halogen-free flame-retardant glass fiber enhancing thermoplastic engineering plastic of excellent combination property.

Description

The halogen-free flame-retardant system that dialkyl dithio hypophosphites is cooperateed with organic phosphite And its application

Technical field

The present invention relates to the technical fields of fire retardant, and in particular to a kind of dialkyl dithio hypophosphites with it is organic phosphorous The halogen-free flame-retardant system of hydrochlorate collaboration and its application in preparing halogen-free flame-retardant glass fiber enhancing thermoplastic engineering plastic.

Background technology

Fiberglass reinforced thermoplastic engineering plastic is because steady with 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 material fire-retardant requirement, 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.

Include the basic flame-retardant system of two classes currently, for the fire-retardant of fiberglass reinforced thermoplastic engineering plastic：Halogen system hinders Combustion system and non-halogen fire-retardant system.Halogen system flame-retardant system is typically brominated flame-retardant collaboration antimony oxide, and numerous studies show Fiberglass reinforced thermoplastic engineering plastic added with bromide fire retardant will produce the harmful substances such as dense smoke and hydrogen bromide in burning, Human body can be caused to suffocate, secondly, the electrical insulating property of halogenated flame retardant is poor, and the application in some fields is also restrained.Therefore, it is Fiberglass reinforced thermoplastic engineering plastic, which develops safe and environment-friendly, high performance halogen-free flame-retardant system, becomes the hot spot of research, in recent years There is the novel halogen-free flame retardants or flame-retardant system applied to fiberglass reinforced thermoplastic engineering plastic.

According to the literature, the halogen-free flame retardants for being applied to fiberglass reinforced thermoplastic engineering plastic includes mainly that two major classes are basic 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, 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 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, Some defects for avoiding red phosphorus are the hot spots studied at present.

Currently, with the most use, the phosphorus nitrogen compound system based on diethyl hypo-aluminum orthophosphate is answered, for example, diethyl time phosphorus Sour aluminium compounding melamine Quadrafos (MPP) system can due to the synergistic effect with higher phosphorus content and phosphorus nitrogen To realize the highly effective flame-retardant to fiberglass reinforced thermoplastic engineering plastic, product color problem is also not present, while there is very high score Temperature is solved, in the high temperature working processes of fiberglass reinforced thermoplastic engineering plastic, not will produce the hypertoxic gas such as hydrogen phosphide.But it is right In the phosphorus nitrogen compound system based on diethyl hypo-aluminum orthophosphate, however it remains some disadvantages are mainly manifested in：

It is decomposed first, two kinds of components have certain reaction at high temperature, generates a small amount of acidic materials, these acids Matter can generate corrosion to the metal parts of process equipment, need replacing component after a certain time, bring increase and the drop of cost The problem of low production efficiency；Second is that nitrogenous compound MPP, there are certain precipitation, material is in injection molding process, injection molding one After the product of cover half number, there can be deposit on mold, the presence of these deposits can influence the appearance of product, this is desirable It stops work and clears up mold, can also reduce production efficiency, while this precipitation can also cause fire retardant to be migrated to product surface, cause to hinder Combustion agent is unevenly distributed and is lost in, and the final fire-retardant failure for making material, there are security risks；Third, additive amount is big, to material Effect on Mechanical Properties is larger.

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 corrosion and reduction material mechanical performance, some, which are fatal problems, cannot then use, some are then It is to lead to cost increase, efficiency reduction etc..Therefore, it is necessary to develop novel halogen-free flame-retardant system.

Invention content

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 discloses a kind of Halogen that dialkyl dithio hypophosphites is cooperateed with organic phosphite resistance Combustion system, the halogen-free flame-retardant system have many advantages, such as high fire-retardance, non-migratory, not etching apparatus, the Halogen prepared based on this Flame-proof glass fibre enhances thermoplastic engineering plastic, can prepare the component or product of field of electronics.

Specific technical solution is as follows：

A kind of halogen-free flame-retardant system that dialkyl dithio hypophosphites is cooperateed with organic phosphite, by weight percentage Meter, raw material composition include：

Dialkyl dithio hypophosphites 50~95%；

Organic phosphite 4~40%；

Zinc compound 1~10%；

The dialkyl dithio hypophosphites, shown in structural formula such as following formula (I)：

In formula, R₁、R₂Independently selected from straight chained alkyl or branched alkyl, the carbon number of the straight chained alkyl or branched alkyl is 1 ~6；

M is selected from Mg, Ca, Al, Sb, Sn, Ge, Ti, Fe, Zr, Zn, Ce, Bi, Sr, Mn, Li, Na, K, H or NH₄, m be 1~ 4。

The present invention uses novel dialkyl dithio hypophosphite fire retardant, by being cooperateed with organic phosphite, shape Non-nitrogen containing compounding flame retardant is cooperateed at the multielement based on phosphorus sulphur, solves the existing compositional flame-retardant based on diethyl hypo-aluminum orthophosphate The defects of system is perishable present in flame-proof glass fibre enhancing thermoplastic engineering plastic, precipitation easy to migrate.The novel flame-retardant body System can be well adapted for fiberglass reinforced thermoplastic engineering plastic material, the bittern-free flame-proof material being had excellent performance.

Preferably, in the general formula of the dialkyl dithio hypophosphites, R₁、R₂Independently selected from methyl, ethyl, positive third Base, normal-butyl, isobutyl group, tertiary butyl, n-pentyl, isopentyl, n-hexyl or isohesyl；M is selected from Mg, Ca, Al, Sn, Ti or Zn.

Further preferably, the dialkyl dithio hypophosphites is selected from diethyl-dithio hypo-aluminum orthophosphate or diisobutyl Dithiophosphlic acid aluminium.

The invention also discloses a kind of preparation processes of the dialkyl dithio hypophosphites, to prepare dialkyl disulfides For generation aluminum phosphate, specially：

(1) dialkyl dithio sodium hypophosphite solution is reacted in acid condition with aluminum sulfate solution, obtains dialkyl group The suspension of dithiophosphlic acid aluminum precipitation object；

(2) suspension will be filtered, washed and dry, pulverize to certain grain size at 120 DEG C, obtain dialkyl disulfides For hypo-aluminum orthophosphate combustion inhibitor.

It wherein, can be by commercially available acquisition, or by the following method as the dialkyl dithio sodium hypophosphite of raw material It prepares：

(a) linear alkene exists in initiator with hydrogen phosphide and free radical can occur under certain temperature and pressure Addition reaction generates dialkyl group hydrogen phosphide；

(b) dialkyl group hydrogen phosphide and sulfur reaction are generated into dialkyl dithio hypophosphorous acid；

(c) dialkyl dithio hypophosphorous acid is reacted with sodium hydroxide and generates dialkyl dithio hypophosphorous acid soluble easily in water Sodium salt.

The characteristics of dialkyl dithio hypophosphites is phosphorus content height, the also collaboration of element sulphur, good flame resistance, tool There is a higher temperature of initial decomposition, water-soluble extremely low, resistance to migration is nonhygroscopic, is that a kind of novel can be applied to nylon, polyester etc. In engineering plastics, especially in the engineering plastics of fiberglass reinforced.Dialkyl dithio hypophosphites is used alone, in certain applications Field, flame retardant property still are apparent not enough, therefore also need to and cooperate with component to compound, and can be only achieved fire-retardant requirement.

Inventors discovered through research that in the presence of dialkyl dithio hypophosphites, it is added suitable organic Phosphite, forms the non-nitrogen flame-retardant system based on phosphorus sulphur structure, which has preferable flame-retarding characteristic.

Shown in the general structure of the organic phosphite such as following formula (II) or following formula (III)：

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；

Preferably, the organic phosphite is methylisothiouronium methylphosphite aluminium, ethyl phosphorous acid aluminium, and the molecular weight of R group is smaller, Phosphorus content is higher, to fire-retardant more advantageous.

The preparation method of the organic phosphite is：(1) organic phosphite hydrolyzes in acid condition, is made organic Phosphorous acid；(2) organic phosphorous acid and metal hydroxides are in acid condition, anti-in 150~180 DEG C of high pressures in aqueous medium It answers；(3) suspension is filtered, washed and is dry, pulverize at 200~240 DEG C to certain grain size.

The organic phosphite being prepared has very high heat decomposition temperature, can be assisted with dialkyl dithio hypophosphites Same-action, while water-soluble low, resistance to migration.

Moreover, it has been found that introducing the zinc compound that a small amount of high temperature resistant is not precipitated in above-mentioned system, can further increase Corrosion-resistant and thermal stability, and anti-flammability is provided, there is not yet the problem of precipitation.Preferably, the zinc compound is selected from boron Both sour zinc and/or zinc stannate have high decomposition temperature, water-soluble low, not migration precipitation.It can be assisted with phosphorus sulphur structure Together, anti-flammability is improved, and with suppression cigarette effect, reduces smoke density.

To further increase cooperative flame retardant effect, in the compound system, dialkyl dithio hypophosphites be it is powdered, Average grain diameter D50 is 20~50 μm；Organic phosphite is powdered, and average grain diameter D50 is 20~50 μm；Zinc compound is Powdered, average grain diameter D50 is 20~50 μm.

The invention also discloses halogen-free flame-retardant glass fiber enhancing engineering thermoplastic prepared by the halogen-free flame-retardant system is added to mould Material, by weight percentage, raw material composition includes：

The base material is selected from polyamide or polyester.

The polyamide includes fatty polyamide, semiaromatic polyamide composition, such as nylon 6, nylon66 fiber, nylon MXD 6, Buddhist nun Dragon 12 and the high-temperature nylons such as nylon 46,4T, 6T, 9T, 10T, 12T.

The polyester includes PBT or PET.

When the base material is selected from polyamide, preferably raw material composition includes：

Further preferably, the raw material composition of the halogen-free flame-retardant system includes：

Dialkyl dithio hypophosphites 70~80%；

Organic phosphite 13~23%；

Zinc compound 3~7%.

Further preferably, the base material is selected from PA66, and the organic phosphite is selected from methylisothiouronium methylphosphite aluminium, zinc compound choosing From zinc borate, dialkyl dithio hypophosphites is selected from diisobutyl dithiophosphlic acid aluminium.

When the base material is selected from polyester, raw material composition includes：

Further preferably, the raw material composition of the halogen-free flame-retardant system includes：

Dialkyl dithio hypophosphites 50~80%；

Organic phosphite 15~45%；

Zinc compound 3~8%.

Further preferably, the base material is selected from PBT, and the organic phosphite is selected from methylisothiouronium methylphosphite aluminium, zinc compound choosing From zinc borate, dialkyl dithio hypophosphites is selected from diisobutyl dithiophosphlic acid aluminium.

Thermoplastic engineering plastic is enhanced by the halogen-free flame-retardant glass fiber that above-mentioned formula is prepared, can reach UL94 V0 (1.6mm) flame retardant rating, and have the advantages that not etching apparatus, without be precipitated.

The invention also discloses the preparation method that the halogen-free flame-retardant glass fiber enhances thermoplastic engineering plastic, each raw material is blended Afterwards, flame-retardant system is dispersed in base material, then passes through band plus the twin-screw extrusion of glass fiber opening and fire retardant powder feed inlet Machine, each component complete melt blending, and extruding pelletization in an extruder.

Compared with prior art, the invention has the advantages that：

The invention discloses the phosphorus sulphur multielement being made of dialkyl dithio hypophosphites and organic phosphite collaborations Non-nitrogen flame-retardant system is compounded, has many advantages, such as high fire-retardance, non-migratory, not etching apparatus, may be used as fiberglass reinforced thermoplasticity work The halogen-free flame-retardant system of engineering plastics, preparing the novel halogen-free flame-retardant glass fiber applied to electric and electronic field enhances engineering thermoplastic Plastics proprietary material.

Specific implementation mode

Raw material：

(1) preparation of diisobutyl dithiophosphlic acid aluminium

The sulphur of diisobutyl the dithiophosphlic acid sodium water solution 1392g and concentration 30wt% of compound concentration 20wt% respectively Desalted water 1500g is added into reactor, and the sulfuric acid solution 75g of concentration 25wt% is added by sour aluminum solutions 228g, is warming up to 80 DEG C, start to synchronize dropwise addition diisobutyl dithiophosphlic acid sodium water solution and aluminum sulfate solution in proportion into reaction kettle, obtain Diisobutyl dithiophosphlic acid aluminum precipitation object, is added dropwise to complete for 2 hours, keeps the temperature 1 hour, is then filtered, washed, dries, obtain Diisobutyl dithiophosphlic acid aluminium fire retardant 254g (yield 97%).

After tested, 350 DEG C of the initial decomposition temperature of product, solubility is 0.02% in water；

(2) MPP, Melapur 200 is purchased from BASF；

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

(4) nylon66 fiber, EPR27, table mountain god horse；

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

(6) diethyl hypo-aluminum orthophosphate, 8003, Jiangsu Li Side new materials Co., Ltd；

(7) antioxidant, 1098, BASF；

(8) silicone, middle indigo plant morning twilight；

(9) PBT, 211M, Changchun chemistry；

(10) methylisothiouronium methylphosphite aluminium, Jiangsu Li Side new materials Co., Ltd.

Embodiment 1

Halogen-free flameproof compound system is applied in glass fiber enhanced nylon, follows these steps and test method investigates fire retardant Performance.

(1) mixture of halogen-free flame-retardant system

It is stirred in height and the compounding flame retardant each component weighed up in advance according to the ratio and other auxiliary agents is added in machine, start high-speed stirring It mixes, stirs 10min, complete the mixture of powder, discharge.

(2) extruding pelletization of material

Each area's temperature setting of double screw extruder in predetermined temperature, after temperature stablizes 20min, Buddhist nun is added from hopper Dragon, by adding glass fiber opening to be added, the powder of step (1) mixture is fed glass by powder charging aperture, starts 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) application with 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：

Fire-retardant experiment

It is tested according to UL94V0 testing standards.

Resistance to migration experiment

The halogen-free flame-retardant glass fiber prepared is enhanced into nylon sample, is put into climatic chamber, 85 DEG C of temperature is set, relatively Humidity 85%, the state of specimen surface of the visual observations after 168 hours.

Corrosion experiment

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

Mechanics Performance Testing

By ASTM D638 test tensile strengths and press ASTM D256 impact strengths.

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

Embodiment 2

Implementation process is same as Example 1, keeps fire retardant systems total amount constant, adjusts diisobutyl dithiophosphlic acid The ratio of aluminium and methylisothiouronium methylphosphite aluminium.Other materials and proportioning are shown in Table 1, and obtained material the results are shown in Table 1.

Embodiment 3

Implementation process is same as Example 1, keeps fire retardant systems total amount constant, adjusts diisobutyl dithiophosphlic acid The ratio of aluminium and methylisothiouronium methylphosphite aluminium.Other materials and proportioning are shown in Table 1, and obtained material the results are shown in Table 1.

Embodiment 4

Implementation process is same as Example 1, keeps flame-retardant system total amount constant, diisobutyl dithiophosphlic acid aluminium accounting It remains unchanged, adjusts the ratio of other two components.Other materials and proportioning are shown in Table 1, and obtained material the results are shown in Table 1.

Comparative example 1

Implementation process is same as Example 1, in addition to using diethyl hypo-aluminum orthophosphate to replace diisobutyl dithiophosphlic acid Outside aluminium.Other materials and proportioning are shown in Table 1, and obtained material the results are shown in Table 1.

Comparative example 2

Implementation process is same as Example 1, other than not using zinc borate.Other materials and proportioning are shown in Table 1, obtained Material the results are shown in Table 1.

Comparative example 3

Implementation process is same as Example 1, other than only using diisobutyl dithiophosphlic acid aluminium and zinc borate, does not make With methylisothiouronium methylphosphite aluminium.Other materials and proportioning are shown in Table 1, and obtained material the results are shown in Table 1.

Comparative example 4

Implementation process is same as Example 1, other than only using diisobutyl dithiophosphlic acid aluminium.Other materials and match Than being shown in Table 1, obtained material the results are shown in Table 1.

Comparative example 5

Implementation process is same as Example 1, in addition to flame-retardant system uses the compound system of diethyl hypo-aluminum orthophosphate and MPP. Other materials and proportioning are shown in Table 1, and obtained material the results are shown in Table 1.

Table 1

Embodiment 5

Implementation process is same as Example 1, and nylon66 fiber is replaced with PBT.Other materials and proportioning are shown in Table 2, obtained Material the results are shown in Table 2.

Embodiment 6

Implementation process is same as Example 2, and nylon66 fiber is replaced with PBT.Other materials and proportioning are shown in Table 2, obtained Material the results are shown in Table 2.

Embodiment 7

Implementation process is same as Example 3, and nylon66 fiber is replaced with PBT.Other materials and proportioning are shown in Table 2, obtained Material the results are shown in Table 2.

Embodiment 8

Implementation process is same as Example 4, and nylon66 fiber is replaced with PBT.Other materials and proportioning are shown in Table 2, obtained Material the results are shown in Table 2.

Comparative example 6

Implementation process is identical as comparative example 1, and nylon66 fiber is replaced with PBT.Other materials and proportioning are shown in Table 2, obtained Material the results are shown in Table 2.

Comparative example 7

Implementation process is identical as comparative example 2, and nylon66 fiber is replaced with PBT.Other materials and proportioning are shown in Table 2, obtained Material the results are shown in Table 2.

Comparative example 8

Implementation process is identical as comparative example 3, and nylon66 fiber is replaced with PBT.Other materials and proportioning are shown in Table 2, obtained Material the results are shown in Table 2.

Comparative example 9

Implementation process is identical as comparative example 4, and nylon66 fiber is replaced with PBT.Other materials and proportioning are shown in Table 2, obtained Material the results are shown in Table 2.

Comparative example 10

Implementation process is identical as comparative example 5, and nylon66 fiber is replaced with PBT.Other materials and proportioning are shown in Table 2, obtained Material the results are shown in Table 2.

Table 2

。

Claims (9)

1. a kind of halogen-free flame-retardant system that dialkyl dithio hypophosphites is cooperateed with organic phosphite, which is characterized in that press Weight percent meter, raw material composition include：

Dialkyl dithio hypophosphites 50~95%；

Organic phosphite 4~40%；

Zinc compound 1~10%；

The dialkyl dithio hypophosphites, shown in structural formula such as following formula (I)：

In formula, R₁、R₂Independently selected from straight chained alkyl or branched alkyl, the carbon number of the straight chained alkyl or branched alkyl is 1~6；

M is selected from Mg, Ca, Al, Sb, Sn, Ge, Ti, Fe, Zr, Zn, Ce, Bi, Sr, Mn, Li, Na, K, H or NH₄, m is 1~4.

2. the halogen-free flameproof body that dialkyl dithio hypophosphites according to claim 1 is cooperateed with organic phosphite System, which is characterized in that the R₁、R₂Independently selected from methyl, ethyl, n-propyl, normal-butyl, isobutyl group, tertiary butyl, n-pentyl, Isopentyl, n-hexyl or isohesyl；

The M is selected from Mg, Ca, Al, Sn, Ti or Zn.

3. the halogen-free flameproof that dialkyl dithio hypophosphites according to claim 1 or 2 is cooperateed with organic phosphite System, which is characterized in that the average grain diameter D50 of the dialkyl dithio hypophosphites is 20~50 μm.

4. the halogen-free flameproof body that dialkyl dithio hypophosphites according to claim 1 is cooperateed with organic phosphite System, which is characterized in that shown in the general structure of the organic phosphite such as following formula (II) or following formula (III)：

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；

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

5. the halogen-free flameproof body that dialkyl dithio hypophosphites according to claim 1 is cooperateed with organic phosphite System, which is characterized in that the zinc compound is selected from zinc borate and/or zinc stannate, and average grain diameter D50 is 20~50 μm.

6. a kind of halogen-free flame-retardant glass fiber enhances thermoplastic engineering plastic, which is characterized in that including any according to Claims 1 to 5 The halogen-free flameproof compound system, by weight percentage, raw material composition includes：

The base material is selected from polyamide or polyester.

7. halogen-free flame-retardant glass fiber according to claim 6 enhances thermoplastic engineering plastic, which is characterized in that percentage by weight Than meter, raw material composition includes：

The base material is selected from polyamide；

The raw material of the halogen-free flame-retardant system forms：

Dialkyl dithio hypophosphites 70~80%；

Organic phosphite 13~23%；

Zinc compound 3~7%.

8. halogen-free flame-retardant glass fiber according to claim 6 enhances thermoplastic engineering plastic, which is characterized in that percentage by weight Than meter, raw material composition includes：

The base material is selected from polyester；

The raw material of the halogen-free flame-retardant system forms：

Dialkyl dithio hypophosphites 50~80%；

Organic phosphite 15~45%；

Zinc compound 3~8%.

9. enhancing thermoplastic engineering plastic according to any halogen-free flame-retardant glass fiber of claim 6~8, which is characterized in that institute It states organic phosphite and is selected from methylisothiouronium methylphosphite aluminium, zinc compound is selected from zinc borate.