WO2013064252A1 - Method for the production of oligomers, oligomers, and use thereof - Google Patents

Abstract

The invention relates to a method for producing oligomers using a condensation reaction, to oligomers, and to the use thereof. The aim of the invention is to propose novel oligomers which, as additives introduced into thermoplastic materials, reduce the brittleness or hardness of said thermoplastic materials while increasing the flame retardant properties thereof. Said aim is achieved by oligomers produced in a method that is characterized in that at least one phosphorous compound having at least one acid function, at least one amide compound having an amide functionality ≥2, and at least one polyhydroxyl compound having a hydroxyl functionality ≥2 are reacted at temperatures ranging from 60 to 250°C within 30 minutes to 8 hours in a condensation reaction. The additives of the invention can be used as additives in thermoplastic polymers.

Description

 Process for the preparation of oligomers, oligomers and their use

The invention relates to a process for the preparation of oligomers by a condensation reaction, to oligomers and their use.

The production of thermoplastic polymers with adjustable hardness by using plasticizers such as phthalates, sebacates, succinates or epoxidized soybean oil is known. In particular, phthalates and some other oligoesters as plasticizers are being banned by new legislation, so that there is a need for new compounds having a softening effect for adjusting the hardness and flexibility of thermoplastics. The same applies to the field of flame retardancy of thermoplastics, where currently in particular organophosphorus compounds and inorganic solids are used. However, the flame retardants which can still be used according to the legislation in the future generally lead to further embrittlement of the plastics, so that a counteraction through the use of plasticizers is required.

Flame retardants or mixtures of different acting components to achieve a high flame retardancy are known. However, these must always be adapted to the changing conditions. This also applies to the flame-retardant plastics that are produced from premixes. So far, several compounds or mixtures of compounds are added to the precursors (compounds or masterbatches) for the flame retardancy of plastics, the components of these mixtures usually having at least one of the necessary for suppressing the fire or the flame propagation effect:

for the production of non-flammable gases for diluting the mixture of gases which cause the combustion, nitrogen compounds, hydrates or water-releasing substances such as metal hydroxides are used;

the increase in the ignition temperature is achieved by additives such as metal oxides, metal hydroxides, poorly combustible organic substances and / or by a change in the structure of the plastic with respect to its commencement of decomposition; The formation of protective tar layers is effected by the addition of red phosphorus, organic or inorganic phosphorus compounds, a special polymer structure, certain metal compounds or addition of polyfunctional hydroxide compounds such as pentaerythritol.

To these mixture components, more are often added to achieve synergies and thus additional flame retardancy. For example, combinations of antimony trioxide and phosphoric esters have often been used to provide a synergistic effect. More recently, metal hydroxides or metal oxides such as magnesium and / or alumina or polyfunctional hydroxides such as pentaerythritol have been used in addition to increase the amount of tar formed and to increase the amount of non-combustible gases formed. More recently, nano-scale components have been increasingly used in the mixtures, although until now it has not been possible to demonstrate their flame-retarding effect (see, for example, E. Hasari et al., Nanocomposites 2002, San Diego, Sept. 23-25, 2002).

Flame retardant compositions are z. B. in DE 10 2004 019 716 A1 from the three components salt of a phosphonic acid or its polymers, at least one polyhydroxy compound in combination with a nitrogen-containing compound for polyester or polyamides described, wherein the three components are mixed separately from the polymers.

GB 2 401 367 A discloses crosslinked oligomers of diorthophosphate diesters having more than four phosphorus atoms by reacting phosphorus pentoxide with tetrahydrofuran and a primary or secondary alcohol or diol including pentaerythritol or timethylolpropane to crosslink urea or melamine-formaldehyde resins, phenolic resins or isocyanates in polyurethanes used.

EP 0 069 500 A1 discloses intumescent flame retardant compositions based on 2,6,7-trioxa-1-phosphobicyclo [2,2,2] octane-4-methanol-1-oxide and a nitrogen compound, such as melamine, ammeiin , Benzoguanamine, guanidine or their salts for vinyl aromatic resins.

US Pat. No. 6,479,574 B1 describes flame retardant compositions consisting of a polyhydroxy compound, a polyphosphate, a nitrogen-containing compound and a polyacrylate monomer. U.S. Patent 4,241,145 discloses that an intumescent flame retardant composition consists of a cyclic nitrogen compound, a copolycondensed vinyl phosphonate, a phosphorus containing acid, and water.

WO 97/41173 describes flame retardant compositions for polymers which consist of (a) a bicyclic phosphorus compound which may contain one or more pentarylithyrene units, (b) an intumescent flame retardant compound based on nitrogen and phosphorus and (c) a Monophosphate esters such as triphenyl phosphate.

For the production of flame-retardant battery housings according to WO 97/45884 flame retardant compositions based on a homo- or copolymers and ammonium polyphosphate, a polyol, an intumescent, tar-forming additive and melamine, which acts as a propellant.

In WO 2011/019536 A1 thermoplastic elastomers with intumescent flame retardant compositions based on polyphosphates and phosphorus non-containing synergists, eg. As carbon black or metal oxide, and optionally titanium dioxide described.

According to WO 2011/079457 A1, flame-retardant thermoplastics for wire and cable applications consist of polypropylene and one or more elastomers with a flame retardant composition containing nitrogen and phosphorus.

According to DE 37 23 980 A1, flame-retardant adhesive coatings for plastic material are obtained by adding polybrominated diphenyl ethers and optionally antimony trioxide to the adhesive layer, as a result of which the adhesive layers are adjusted to be radiation-resistant and flame-retardant.

According to DE 69 302 904 T2 (WO 93/18914) polyolefin and polyamide layers are flame-retardant adjusted by the addition of phosphonic acid and made of this flame-resistant composite webs. The phosphonic acid esters are monomers having a maximum of three phosphorus atoms in the molecule.

In US Pat. No. 7,049,524 B2, impact-resistant, flameproof cables are described which contain at least one intumescent agent for flame retardancy. This consists of one Phosphorus and a nitrogen compound or a compound containing phosphorus and nitrogen. Phosphorus compounds are phosphates, phosphites, polyphosphates, their organic esters and polyesters, as nitrogen compounds ammonium salts, guanidine, melamine, melamine cyanurates, guadinyl urea and salts thereof. The phosphorus and nitrogen containing compounds are e.g. As phosphates, pyrophosphates or polyphosphates of ammonium. Guanidines, melamine or piperazine, phosphoramide, phosphorylamide, amidophosphonate or phosphonitrile. Preferably, simple organic compounds are used. The amount of compounds used should be 1 to 60%.

According to WO 02/12406 flame-retardant polyurethane systems are described which contain 15 to 59% of an intumescent system and a mineral filler, which can be preferably used for electrical insulation. The intumescent system consists of an acid catalyst, eg. For example, ammonium polyphosphate, a carbon compound, for. As polyols such as dipentaerythritol or phenols, and a nitrogen compound, for. As melamine, guanidine, glycylureas, dicyandiamide, cyanurates or borates of melamine.

The current demands for replacement of all halogen-containing flame retardants and a number of monomeric phosphorus compounds, in particular the previously used frequently tri (haloalkyl) phosphates or triaryl phosphates, due to the legislation have led to the above proposed solutions. However, these are usually mixtures of several compounds consisting of a polyphosphate, a nitrogen compound and a third component, usually an inorganic solid, in some cases of several other components. This makes it necessary to work in compositions always more components exactly.

In addition, these are typically monomers posing further toxicity, VOC, or licensing issues.

It would be desirable if only one component could be used for the production of starting components in the plastics industry for the production of thermoplastic molding materials with sufficient impact resistance, hardness and flame retardancy, with the set exactly for different applications effects in terms of elasticity, hardness, impact resistance and Flame protection through the chemical composition specifically adjustable and easily be incorporated into these plastics. Due to their structure, hard thermoplastics often show a brittle-hard behavior, so that their use in certain areas is limited or even impossible. Many methods are used to reduce brittle hardness and to increase flexibility: e.g. As copolymerization with elastic blocks, random copolymerization with other elastifying monomers, addition of elastomers for the production of blends, mixtures of elastic and brittle-hard plastics in the presence of compatibilizers to avoid inhomogeneities.

 The object of the invention is therefore to propose novel oligomers which reduce the brittleness or hardness of these thermoplastics as additives when introduced into thermoplastics and simultaneously increase their flame retardancy.

 Surprisingly, it has now been found that certain oligomers based on an oligophosphoric acid as well as various OH and NH-functional monomers give highly viscous to elastic products which can be used very well as elasticizing additives and at the same time significantly reduce the brittle hardness even in low concentration a significant improvement in the flame retardant occurs. These oligomers are obtained by a condensation reaction of suitable hydroxyl compounds, amides with phosphoric acid, if appropriate in the presence of phosphorus pentoxide and / or inorganic oligo- or polyphosphates.

According to the invention, the object is achieved with oligomers which are prepared by a process which is characterized in that at least one phosphorus compound having at least one acid function, at least one amide compound having an amide functionality -.2 and at least one polyhydroxyl compound having a hydroxyl functionality -Ϊ 2nd

be reacted at temperatures between 60 and 250 ° C within 30 minutes to eight hours in a condensation reaction.

The object is also achieved by using oligomers which can be prepared according to any one of claims 1 to 11, with essentially no terminal hydroxyl and / or amino groups.

Furthermore, the object is achieved with the use of oligomers, according to claims 12 to 16, as an additive with intumeszierender flame retardant effect for thermoplastic polymers, as an additive for flexibilization of thermoplastic polymers and as an additive for flexibilized and flameproof shrink tubing.

Advantageous developments are specified in the subclaims. Thus, the reaction is carried out at a reduced pressure between 10 and 500 mbar. It is advantageous in this context, the application of a reduced pressure, since thereby the reaction time and the temperature and thus ultimately the use of energy can be reduced.

As phosphorus compound are advantageously phosphoric acid, phosphorus pentoxide, sodium dihydrogen phosphate, ammonium polyphosphate or potassium hydrogen phosphate, as amide phthalimide, urea or substituted mono- or oligoureas preferably with aromatic substituents and as polyhydroxy compound sorbitol, xylitol, pentaerythritol, microcrystalline, microfibrillated or nanofibrillated cellulose, glycerol, trimethylolpropane, Glucoside, glucose or sucrose reacted.

A development of the invention is characterized in that it is reacted in the presence of catalysts and / or additives which do not intervene in the reaction.

A further embodiment of the invention is characterized in that as additives 0.01 to 10 wt .-% based on the total amount of the reaction components to be used nanoscale metal oxides, metal hydroxides or metal oxide of the 2nd and / or 3rd main and / or subgroup of the Periodic Table be used.

It is inventively advantageous that the reaction by the addition of the reaction components in the reactor with progressing heating up to the target temperature of the condensation, application of negative pressure over a portion of the condensation time or the total condensation time and recovery of the oligomers from the reactor without further workup he follows.

A further advantageous development is characterized in that nanosize oligourea dispersions are added to the reaction mixture as sole or partial reaction components as the amide compound.

In a further embodiment of the invention further additives or reaction components such as inorganic compounds such as metal oxides and / or metal hydroxides, graphene, natural or synthetic phyllosilicates, graphite and / or phosphates in micronized or nanoscale form are added in an additional step. In a further development, mixtures of the oligomers and thermoplastic polymers aluminum oxide, aluminum hydroxide, alumina hydrate or mixtures thereof are added.

In a further embodiment of the process, the desired pH values or further properties are set by an additional step of the condensation or addition with or of certain compounds.

In a further development, the oligomers are characterized in that they by a

Composition of

 20 to 35% carbon,

 8 to 12% hydrogen,

 10 to 19% phosphorus,

 10 to 20% nitrogen and

 12 to 22% oxygen

are characterized.

A further advantageous embodiment is characterized in that the oligomers have a pH in the range of 4 to 11, a sum of hydroxyl number and amine number between 1 and 35, a molecular weight of 5000 to 1,000,000 and a viscosity of 10 to 200,000 Pas 25 ° C have.

In a further embodiment, the oligomers are characterized in that they have a pH in the range of 5 to 9, a sum of hydroxyl number and amine number between 2 and 30, a molecular weight of 5000 to 1,000,000 and a viscosity of 20 to 20,000 Pas at 25 ° C.

In a further development, the oligomers contain 20 to 45 parts of a mixture of phosphoric acid, phosphorus pentoxide and / or ammonium polyphosphate, 20 to 65 parts of urea or phthalimide and 3 to 40 parts of microcrystalline or fibrillated cellulose, the amounts always complementing to 100 parts.

As oligomers, substances with 3 to 10 recurring structural units are designated on the basis of the customary international definition. Due to different molecular weights of the starting materials, no binding molecular weight limits can be specified for such oligomers. Assuming that the molecular weight of the monomers is between 50 and 500, the molar mass range can be between 150 and 5,000. In case of according to the invention oligomeric phosphoric acid (ester-amides) is taken to the fact that a Oligophosphatkette is formed, but which may be interrupted by amide or ester groups. The complex structure can therefore only be approximately described by the following formula:

R '"R" "

 O / N O / N

XR- (O-P) _n -Y-R'-Z- (P-O),

 O / N O / N

 R '"R" where X is an optionally substituted by amine, amide or ester groups, linear or branched aliphatic, araliphatic or aromatic chain, Y, optionally substituted, amide nitrogen or oxygen, Z, optionally substituted, amide nitrogen or oxygen, R "a, optionally different from X, substituted by amine, amide or ester groups linear or branched aliphatic, araliphatic or aromatic chain, R '" one, optionally of R, R', R "different, if necessary by amine, amide or ester groups substituted, linear or branched aliphatic, araliphatic or aromatic chain, R "" one, optionally of R, R ', R "or R'" different, possibly by amine, amide or ester groups substituted, linear or branched aliphatic, araliphatic or aromatic chain.The structure of the formed oligomeric phosphoric acid (ester-amides) is complex and can not be determined even by means of FTIR unambiguously The end groups (hydroxyl or optionally substituted Uierte amino groups) can be determined as the sum (see embodiments).

The oligomers of the invention are not uniform products due to the manufacturing process but mixtures of at least two compounds, but usually from a variety of compounds of different structure and size. The size of the molecules is determined both by the composition of the reaction mixture and by the reaction conditions. Thus, the degree of condensation is determined by the duration of the reaction, the reaction temperature and the pressure during the reaction; the longer the reaction time, the higher the degree of condensation and thus the molecular weight and the viscosity. It is advantageous in this context, the application of reduced pressure, since thereby the reaction time and the temperature and thus ultimately the use of energy can be reduced. The reduced pressure is the range of 500 to 10 mbar, in particular 150 to 10 mbar. Another possibility for influencing the molar mass and thus the viscosity is the reaction of existing reactive groups with compounds which can react with them. So z. B. by the reaction of the free hydroxyl and / or amino groups with monoisocyanates a virtually complete implementation of these groups and thus a freedom of the reaction products of such groups can be achieved. If di- and / or polyisocyanates are used, the molar mass can be further increased by this procedure. This can then be used to obtain oligomers without functional groups of very high viscosity. These can reach a state like an elastomer.

The viscosity of the oligomers is in addition to their flame retardant effect an essential property. The viscosity can be only a few Pas; These products are liquid to viscous and are preferably used in reacting systems. The viscosity can also be many 1000 Pas, d. H. barely flowable to include elastomeric products. These are preferably used in thermoplastics and act in these flame retardant as well as plasticizing. By adjusting the viscosity over the reaction conditions, it is possible according to the invention to produce a precisely matching oligomer mixture or oligomer mixture for each application.

According to the invention oligomeric phosphoric acid (ester-amides) having at least four repeating -POP units in the chain and a substitution on the phosphorus atom by hydroxyl compounds having the hydroxyl functionality ä2 and a Amidfunktionalilät 2 are obtained by a condensation reaction, which is controlled so that the oligomer one still low number of free hydroxyl groups, which is expressed by a hydroxyl number between 1 and 100 mg KOH / g. In addition, these oligomers have a viscosity at 25 ° C between 100 Pas and 1 million Pas, so they are highly viscous to viscoelastic. In another embodiment, the oligomers may be solids having a glass transition or melting point between 45 and 150 ° C, preferably between 50 and 120 ° C, more preferably between 60 and 90 ° C.

When incorporated in thermoplastic polymers, the oligomers according to the invention advantageously develop a flexibilizing or softening effect, so that the hardness and brittleness of thermoplastic polymers can be adjusted by their use as an additive. Furthermore, they have an elasticizing effect in thermoplastics, whereby they can be adjusted more elastically and thus a higher impact resistance is achieved and excellent flame retardant, by which the thermoplastic material additionally flame retardant is equipped without a further component is required.

 These effects are further enhanced by the use according to the invention of nanoscale components. As such nanoscale components come into question

inorganic compounds, in particular nanoscale aluminum oxide, aluminum hydroxide, magnesium hydroxide, boehmite, bentonite, layer silicates, mica or mixtures and / or surface-treated such compounds and / or exfoliated such compounds,

Organic compounds, in particular nanoscale oligoureas, nanoscale oligourethanes, nanoscale oligocyanurates, nanoscale oligoisocyanurates, nanoscale oligophosphoramides, nanoscale oligophosphines, nanoscale oligophosphinamides or mixtures thereof.

 The invention will be explained in more detail below with reference to exemplary embodiments.

embodiments

example 1

A phosphoric acid (ester-amide) is prepared by adding a 10 liter stainless steel reactor with propeller stirrer, nitrogen inlet, reflux condenser and condenser, and solid and liquid reaction component dosing with 2.16 kg 85% phosphoric acid, 0.66 kg phosphorus pentoxide and 3.50 kg of urea is charged. The mixture is heated to 95 ° C with stirring. Once the reaction temperature is reached and the reflux of water begins, 0.86 kg of sorbitol are added. After completion of the addition, the temperature is slowly increased to 120 ° C and distilling off the resulting water of reaction. After 3.5 hours, the amount of distillate drops noticeably. At this time, the temperature is slowly increased further to 146 ° C, whereby further water of reaction is distilled off. A total of 0.67 kg of water are distilled off. After 5 hours of reaction, the temperature is lowered with stirring to 70 ° C and the reaction product, an oligomeric phosphoric acid (ester-amide), removed via the bottom valve. The data obtained are:

Hydroxyl number: 8.5 mg KOH / g

Amine number: 2.1 mg KOH / g

Viscosity (25 ° C): 1260 Pas Example 2

A phosphoric acid (ester-amide) is prepared by adding a 10 l stainless steel reactor with propeller stirrer, nitrogen inlet, a combination reflux condenser and condenser, and solid and liquid reaction component dosers with 2.05 kg of 85% phosphoric acid, 0.60 kg of phosphorus pentoxide and 3.75 kg of dimethylurea is charged. The mixture is heated to 95 ° C with stirring. Once the reaction temperature is reached and the reflux of water begins, 0.80 kg of xylitol are added. After completion of the addition, the temperature is slowly increased to 120 ° C and distilling off the resulting water of reaction. After 3.0 hours, the amount of distillate drops noticeably. At this time, the temperature is slowly further increased to 142 ° C, whereby further water of reaction is distilled off. A total of 0.55 kg of water are distilled off. After 5.5 hours of reaction, the temperature is lowered with stirring to 70 ° C and the reaction product, an oligomeric phosphoric acid (ester-amide), removed via the bottom valve. The data obtained are:

Hydroxyl number: 4.8 mg KOH / g

Amine number: 1.6 mg KOH / g

Viscosity (25 ° C): 1540 Pas

Example 3

A phosphoric acid (ester-amide) is prepared by adding a 10 l stainless steel reactor with propeller stirrer, nitrogen inlet, a combination reflux condenser and condenser, and solid and liquid reaction metering devices with 2.15 kg 85% phosphoric acid, 0.60 kg phosphorus pentoxide and 3.60 kg of urea is charged. The mixture is heated to 95 ° C with stirring. Once the reaction temperature is reached and the reflux of water begins, 0.20 kg of glycerol and 0.80 kg of microcrystalline cellulose are added. After completion of the addition, the temperature is slowly increased to 120 ° C and distilling off the resulting water of reaction. After 4.0 hours, the amount of distillate decreases noticeably. At this time, the temperature is slowly further increased to 142 ° C, whereby further water of reaction is distilled off. A total of 0.67 kg of water are distilled off. After 6.5 hours of reaction, the temperature is lowered with stirring to 70 ° C and the reaction product, an oligomeric phosphoric acid (ester-amide), removed via the bottom valve. The data obtained are:

Hydroxyl number: 6.6 mg KOH / g Amine number: 2.7 mg KOH / g

Viscosity (25 ° C): 2420 Pas

Example 4

A phosphoric acid (ester-amide) is prepared by adding a 10 l stainless steel reactor with propeller stirrer, nitrogen inlet, a combination reflux condenser and condenser, and solid and liquid reaction metering devices with 2.15 kg 85% phosphoric acid, 0.60 kg phosphorus pentoxide , 0.55 kg of phthalimide and 3.0 kg of urea is charged. The mixture is heated to 105 ° C with stirring. Once the reaction temperature is reached and the reflux of water begins, 0.20 kg of glycerol and 0.75 kg of microcrystalline cellulose are added. After completion of the addition, the temperature is slowly increased to 130 ° C and distilling off the water of reaction formed. After 4.0 hours, the amount of distillate decreases noticeably. At this time, the temperature is slowly further increased to 150 ° C, whereby further water of reaction is distilled off. A total of 0.59 kg of water are distilled off. After 7.5 hours of reaction, the temperature is lowered with stirring to 70 ° C and the reaction product, an oligomeric phosphoric acid (ester-amide), removed via the bottom valve. The data obtained are:

Hydroxyl number: 4.4 mg KOH / g

Amine number: 5.6 mg KOH / g

Viscosity (25 ° C): 4440 Pas

Example 5

A phosphoric acid (ester-amide) is prepared by adding a 10 l stainless steel reactor with propeller stirrer, nitrogen inlet, a combination reflux condenser and condenser, and solid and liquid reaction metering devices with 2.15 kg 85% phosphoric acid, 0.60 kg phosphorus pentoxide 0.45 kg of guanidine and 3.20 kg of urea is charged. The mixture is heated with stirring to 115 ° C. Once the reaction temperature is reached and the reflux of water begins, 0.20 kg of glycerol and 0.80 kg of sorbitol are added. After completion of the addition, the temperature is slowly increased to 130 ° C and distilling off the water of reaction formed. After 3.0 hours, the amount of distillate drops noticeably. At this time, the temperature is slowly increased further to 146 ° C, whereby further water of reaction is distilled off. A total of 0.62 kg of water are distilled off. After 5 hours Reaction time, the temperature is lowered with stirring to 70 ° C and the reaction product, an oligomeric phosphoric acid (ester-amide), removed via the bottom valve. The data obtained are:

Hydroxyl number: 3.9 mg KOH / g

Amine number: 5.5 mg KOH / g

Viscosity (25 ° C): 5660 Pas

Example 6

A phosphoric acid (ester-amide) is prepared by adding a 10 liter stainless steel reactor with propeller stirrer, nitrogen inlet, pressure reducer, reflux condenser and condenser, and solid and liquid reaction component dosing with 2.15 kg 85% phosphoric acid, 0.66 kg of phosphorus pentoxide, 0.50 kg of methylurea and 3.30 kg of urea. The mixture is heated with stirring to 1 10 ° C. Once the reaction temperature is reached and the reflux of water begins, 0.10 kg of glycerol and 1.08 kg of pentaerythritol are added. After completion of the addition, the temperature is slowly increased to 140 ° C and distilling off the water of reaction formed. After 3.0 hours, the amount of distillate drops noticeably. At this point, the pressure in the reactor is slowly reduced to 100 mm, after which the temperature is slowly increased further to 140 ° C. The volatile reaction products are collected in a cold trap (dry ice cooling). A total of 0.75 kg of volatile reaction products are distilled off. After 6.5 hours of reaction, the temperature is lowered with stirring to 70 ° C and the reaction product, an oligomeric phosphoric acid (ester-amide), removed via the bottom valve. The data obtained are:

Hydroxyl number: 1, 0 mg KOH / g

Amine number: 1, 5 mg KOH / g

Viscosity (25 ° C): 25,800 Pas

Glass transition temperature: -27 ° C

Example 7

250 g of the reaction product from Example 1 are heated to 75 ° C. with stirring. 6 g of molten 4,4'-diphenylmethane diisocyanate are slowly added to the oligomer mixture. The mixture is then for 5 hours at 80 ° C. stirred to 120 ° C. Then it is poured onto a PTFE plate. An elastomeric oligomer is obtained with the following data:

Hydroxyl number: undetectable

 Amine number: not detectable

 FTIR spectrum: no OH groups detectable

 Glass transition: -9 ° C

Example 8

250 g of the reaction product from Example 1 are heated to 75 ° C. with stirring. 5.6 g of phenyl isocyanate are added slowly to the mixture of oligomers. The mixture is then stirred for 3 hours at 80 ° C to 100 ° C. Then it is poured onto a PTFE plate. A highly viscous oligomer is obtained with the following data:

Hydroxyl number: undetectable

 Amine number: not detectable

 FTIR spectrum: no OH groups detectable

 Glass transition: -17 ° C

 Viscosity: 12,500 Pas

Example 9

A phosphoric acid (ester-amide) with integrated nanoscale particles is prepared by adding a 10 liter stainless steel reactor with propeller stirrer, nitrogen inlet, a combination reflux condenser and condenser, and solid and liquid reaction metering devices with 2.25 kg 85% phosphoric acid, 0 , 75 kg of phosphorus pentoxide, 0.75 kg of an oligourea based on 4,4'-diphenylmethane diisocyanate, which was obtained by aminolysis of a polyurethane flexible foam and separation of the heavy urea phase (see DE 10 2006 034613) and 3.00 kg of urea becomes. The mixture is slowly heated to 120 ° C with stirring. Once the reaction temperature is reached and the reflux of water begins, 0.30 kg of trimethylolpropane and 0.75 kg of pentaerythritol are added. After completion of the addition, the temperature is slowly increased to 145 ° C and distilling off the resulting water of reaction. At this point, 125 g of nanoscale alumina hydroxide (particle diameter maximum 13 nm) is added. After 3.0 hours, the amount of distillate drops noticeably. It is at this time, the temperature continues slowly increased to 146 ° C, whereby further water of reaction is distilled off. Thereafter, the reaction mixture is stirred for 20 minutes at 140 ° C and 220 mbar, whereby a small amount of volatile components are obtained. A total of 0.66 kg of water are distilled off. After 6 hours of reaction, the temperature is lowered with stirring to 70 ° C and the reaction product, an oligomeric phosphoric acid (ester-amide), removed via the bottom valve. The data obtained are:

Hydroxyl number: 3.1 mg KOH / g

Amine number: 2.6 mg KOH / g

Viscosity (25 ° C): 7580 Pas

Claims

claims

1.A process for the preparation of oligomers by a condensation reaction,

characterized in that

at least one phosphorus compound having at least one acid function,

at least one amide compound having an amide functionality 2 and

at least one polyhydroxyl compound having a hydroxyl functionality of 2. 2

be implemented at temperatures between 60 and 250 ° C within 30 minutes to eight hours.

2. The method according to claim 1,

characterized in that

the reaction is carried out at a reduced pressure between 10 and 500 mbar.

3. The method according to claim 1 or 2,

characterized in that

phosphoric acid, phosphorus pentoxide, sodium dihydrogen phosphate, ammonium polyphosphate or potassium hydrogen phosphate are reacted as the phosphorus compound.

4. The method according to any one of claims 1 to 3,

characterized in that

as amide compound phthalimide, urea or substituted mono- or oligoureas are preferably reacted with aromatic substituents.

5. The method according to any one of claims 1 to 4,

characterized in that

as polyhydroxyl compound sorbitol, xylitol, pentaerythritol, microcrystalline, microfibrillated or nanofibrillated cellulose, glycerol, trimethylolpropane, glucosides, glucose or sucrose.

6. The method according to any one of claims 1 to 5,

characterized in that

in the presence of catalysts and / or unreactive additives is reacted.

7. The method according to claim 6,

characterized in that

as additives 0.01 to 10 wt .-% based on the total amount of the reaction components to be used nanoscale metal oxides, metal hydroxides or metal oxide hydroxides of the 2nd and / or 3rd main and / or subgroup of the Periodic Table.

8. The method according to any one of claims 1 to 7,

characterized in that

the reaction is carried out by the addition of the reaction components in the reactor with continued heating up to the target temperature of the condensation, application of negative pressure over a part of the condensation time or the entire condensation time and the recovery of the oligomers from the reactor without further workup.

9. The method according to any one of claims 1 to 8,

characterized in that

nanoscale oligourea dispersions may be added as the sole or partial reaction components to the reaction mixture as the amide compound.

10. The method according to any one of claims 1 to 9,

characterized in that

in an additional step further additives or reaction components such as inorganic compounds such as metal oxides and / or metal hydroxides, graphene, natural or synthetic phyllosilicates, graphite and / or phosphates are added in micronized or nanoscale form.

11. The method according to any one of claims 1 to 10,

characterized in that

 Mixtures of the oligomers and thermoplastic polymers alumina, aluminum hydroxide, alumina hydrate or mixtures thereof may be added.

12. The method according to any one of claims 1 to 11,

characterized in that

be adjusted by an additional step of condensation or addition with or of certain compounds of the desired pH or other properties.

13. Oligomers,

Preparable according to one of claims 1 to 12, having substantially no terminal hydroxyl and / or amino groups.

14. Oligomers according to claim 13,

characterized in that

she through a composition of

 20 to 35% carbon,

 8 to 12% hydrogen,

 10 to 19% phosphorus,

 10 to 20% nitrogen and

 12 to 22% oxygen

are characterized.

15: Oligomers according to Claim 13 or 14,

characterized in that

they have a pH in the range of 4 to 11,

a sum of hydroxyl number and amine number between 1 and 35,

a molecular weight of 5000 to 1,000,000 and

a viscosity of 10 to 200,000 Pas at 25 ° C

exhibit.

16. Oligomers according to one of claims 13 to 15,

characterized in that

they have a pH in the range of 5 to 9,

a sum of hydroxyl number and amine number between 2 and 30,

a molecular weight of 5000 to 1,000,000 and

a viscosity of 20 to 20,000 Pas at 25 ° C

exhibit. 7. Oligomers according to one of claims 13 to 16,

characterized in that

they contain

20 to 45 parts of a mixture of phosphoric acid, phosphorus pentoxide and / or ammonium polyphosphate, 20 to 65 parts urea or phthalimide and

 3 to 40 parts of microcrystalline or fibrillated cellulose,

whereby the quantities always supplement to 100 parts.

18. Use of the oligomers,

according to claims 13 to 17,

as an additive with intumescent flame retardancy for thermoplastic polymers.

19. Use of the oligomers,

according to claims 13 to 17,

as additives for the flexibilization of thermoplastic polymers.

20. Use of the oligomers,

according to claims t3 to 17,

as additives for flexible and flame-retardant shrunken hoses.