EP0484480A1 - Fireproofing agent and its use - Google Patents

Abstract

A fire protection agent contains at least one desiccant. Preferably, it further contains at least one carbohydrate or starch as a binder. Phosphate salts, urea, boric acid and aluminum hydroxides are used, for example, as dehydrating agents, while carbohydrates or starches are used as binders.

Description

 Fire protection agents are used: trwenc_3.-u.rier

The present invention relates to a fire protection agent and its use. Fire protection is of increasing importance due to the constantly increasing number of artificial, industrially manufactured raw materials and products. For example, many plastics have excellent technical properties in many disciplines and are also much more interesting in terms of price than any natural alternative materials. However, they cannot be used in many obvious areas of application because they often fail to meet the relevant fire protection regulations. On the other hand, there are also many natural substances and products, such as wood, fibers, yarns or textiles, which are used continuously and whose flammability or combustion properties create immense potential dangers.

The increasing safety awareness of consumers and stricter fire protection regulations make flame protection especially of plastics, for example. increasing requirements. In the wide range of applications Systems in which a flame-proof finish is required occupy a wide space for the polyurethanes. These include PUR foams, especially rigid foams for insulation in the building sector. However, flame protection is also prescribed for block foams, for example for furniture applications or insulation, and for molded foams for the automotive sector. In addition, fabric coatings, adhesives, lacquers, sealants and electro-casting compounds must also meet increasingly stringent fire standards.

Various fire protection agents are known which aim to reduce the flammability of raw materials or products or at least to eliminate their most dangerous properties, in particular their most dangerous reactants, from fires that actually occur. Known possibilities for the flame-retardant finishing of polyurethanes are, for example, the use of radioactive compounds, mostly chlorinated and phosphorized polyols, which react with the isocyanate. Here, the flame retardant is a component of the synthetic resin. A further possibility is to add non-reactive flame retardants, namely compounds which contain liquid halogens and phosphorus. When halogen compounds and antimony trioxide are used, the breaking off of the radial chains formed during the combustion is accelerated in the gas phase. The products of this incomplete combustion largely contribute to an increase in smoke formation. In highly cross-linked systems such as rigid PU foam, trimizing the isocyanate to the isocyanurate (PIR foams) can do a good job Fire behavior can be achieved. PUR flexible foams are increasingly protected by post-impregnation with appropriately equipped dispersions.

Most products known as fire or flame retardants are based on halogens and phosphorus and are therefore toxic. Generally, when polymers are burned, C, CO, CO, and H, 0 are formed. In addition, formed from the conventional halogen-containing ^{'Flammschutzmit¬} stuffs hydrogen halides (HC1, HBr) of antimony trioxide (Sb ₂ 0 ₃₎ with halogens SbOCl and SbCl. ₃ In addition to nitrogen oxides, HCN is also created from nitrogen-containing flame retardants. The conventional flame retardants reduce the complete combustion to CO and H ₂ O and favor the formation of incompletely oxidized decomposition products such as C and CO. The resulting soot increases the smoke density. Other reaction products are highly toxic and corrosive. For example, the acids formed in the fire of halogen-containing or halogen-flame-retardant polymers can cause secondary damage to, for example, electrical or electronic devices, which far exceed the primary damage to the fire.

It is therefore the object of the present invention to provide a halogen-free fire protection agent which can be used universally, as such is more effective than the known agents and, moreover, is not toxic. The object is achieved by a fire protection agent which contains at least one dehydrating agent.

The fire protection agent according to the invention can also contain other components, in particular a carbohydrate or a starch as a binder. In addition, it also proves to be advantageous if it still contains aluminum hydroxide. The following is a compilation or a list with the generic terms of 6 possible main components and their sub-terms, which, taking into account the minimum requirement that at least one dehydrating agent must be present, can theoretically be combined completely freely into a fire protection agent according to the invention.

1. Dehydrating agent

1.1. Phosphate salt

1.1.1. Monophosphoric acid

1.1.2. Monoammonium hydrogen phosphate

1.1.3. Diammonium hydrogen phosphate

1.1.4. Urea phosphate

1.2. urea

1.3. Boric acid

1.3. Aluminum hydroxides

1.4. Aluminum sulfate at-18 hydrate DAB 7 (German Pharmacopoeia 7) 2. Binder

3.1. melamine

3.2. Ammonium hydrogen carbonate stabilizer

4.1. Tripentaerytrite

4.2. Pentaerytrite

4.3. Borates 4.3.1. borax

Binder additives

5.1. PVA copolymer

5.2. bromine

5.3. Silicates

5.4. Phosphates

5.5. antimony

5.6. ammonium

5.7. boron

5.8. halogen

5.9. Additives 6. Synergists

6.1. Dicumyl peroxide

6.2. Tetraphenylbutane

6.3. Tetraphenylbutane hydrazine

6.4. Ferrocene

6.5. Dirnethyl methylphophonate (DMMP)

^• The fire protection agent according to the invention is generally applied by adding it to the substance or product itself and by subsequent treatment of a raw material, semi-finished product or finished product by impregnation. The impregnation can be carried out, for example, by means of an immersion process or by spraying or brushing on the fire protection agent. Depending on the intended use, the specific composition of the fire protection agent can be varied. Basically, a fire protection agent composed according to the invention can be added to any raw material as filler and this can then be processed as usual with the effect that the raw material treated in this way ultimately leads to a product that no longer burns can. The respective exact composition depends on the raw material or product to be treated and on the type of application, for example on whether the fire protection agent is added directly to the raw material to be treated or whether a finished product is subsequently treated with impregnation with the fire protection agent . The most outstanding advantages of the fire protection agent according to the invention are as follows:

1. In the event of fire, plastic foam is prevented from melting.

2. In the event of a fire, the carbonization is promoted in plastic foam, thereby preventing the burning dripping.

3. In the event of a fire, the smoke gas density is reduced by the fire protection agent according to the invention.

4. In plastic foam, the bending tensile strength is only slightly influenced by the fire protection agent, and the tensile strength is practically unaffected.

5. By using the fire protection agent according to the invention, foams according to DIN 4102, class B1, can be produced without problems.

6. The bulk density of a plastic foam is increased by admixing the fire protection agent according to the invention.

7. Compared to other fillers, the fire protection agent according to the invention has better values with regard to arcing strength, hardness, weather resistance and impact resistance.

8. The admixture of the fire protection agent according to the invention improves the rheology, that is to say the flow behavior of a plastic.

9. Due to its polar character, the fire protection agent according to the invention is easily dispersible in water. 10. As a result of its physical and chemical properties, a high filler content (up to 1000 per hundred resin [phr]) of fire protection agents according to the invention is permissible, which means that a correspondingly high level of flame protection can be achieved.

11. The fire protection agent according to the invention is environmentally friendly since it is halogen-free and therefore non-toxic.

12. The fire protection agent according to the invention is also interesting in terms of price, since its cost is approximately half that for the common raw materials for foams.

Particularly advantageous specific components and their composition to form a fire protection agent according to the invention emerge from the dependent product claims. The particular compositions of the components are adapted to the particular substances and products to be protected, as is described in detail below using examples.

A first important area of application of the fire protection agent according to the invention is flame protection in plastics. For this purpose, the fire protection agent advantageously consists of a mixture of a dehydrating agent, binder, propellant, and a stabilizing agent. According to the invention, the dehydrating agent used is urea, a known compound of carbon, nitrogen, hydrogen and oxygen, but also a phosphate salt, for example Monophosphoric acid, Monoammnoiu hydrogen phosphate, Diammnoium hydrogenphosphate or urea phosphate used. Also suitable are boric acid, aluminum hydroxides or, for example, aluminum sulfate 18 hydrate according to German Pharmacopoeia 7. Carbohydrates such as monosaccharides, disaccharides or polysaccharides or starches can be used as binders. Melamine and ammonium hydrogen carbonate can be used as blowing agents, while tripentaerytrite, pentaerytrite or a borate is suitable as stabilizing agent. A fire protection agent composed in this way forms a foam and is advantageously added to the stock solution in a proportion of about 30 percent by weight. The fire protection agent can in principle easily make up to 230 percent by weight, based on the weight of the stock solution. The foaming of the stock solution with the added fire protection agent to the end product must take place below the reaction temperature of the fire protection agent, typically at temperatures between 150 ° C. and 200 ° C. After the mixture has hardened, the pores are closed, as a result of which the oxygen supply to the foamed substance is closed interrupted and as such is flame retardant. An afterglow in the event of a fire is also no longer possible, since the resulting insulation layer prevents the fire from entering the fabric and prevents the supply of oxygen.

In order to meet the different requirement profiles of the various products of the plastics industry, a problem-free, differentiated reworking of the formulation of the composition is appropriate. The basic requirements Components always remain the same, only the composition is varied. In individual cases, the mixtures of the fire retardant advantageously consist of aluminum hydroxide parts, carbohydrates, namely saccharides or another starch, melamines, ammonium hydrogen carbonates, water, di-ammonium hydrogen phosphate with a few parts of the finished product which is to be produced as a fire-protected product. The foam-forming additive consists of two binders, namely aluminum hydroxide parts with starch or saccharides, and a blowing agent, especially ammonium hydrogen phosphate, supported by melamine. By means of suitable chemical reactions, starch can be modified anionically and cationically. The production of molded ceramic fiber parts can be cited as an example of the use of a cationic starch. In this production process, the cationic starch functions multifunctionally as a flocculant, retention agent and binder. The temperature load in drying systems is so high in some starch-bound products that particularly thermostable special starches have to be used. Binders are possible in many variations. Therefore, starch binders can also be adapted to a wide variety of conditions. Starches are used in low-water systems with, for example, low water consumption, low water retention, low gelatinization point, but high binding capacity and high temperature and color stability. Native and modified maize and wheat starches meet these requirements. In addition, synergistic effects in relation to the binding power and Achieve effectiveness through combinations or special modification of strengths. Such modified binders are called system binders, which are matched in their composition to the various requirement profiles of a wide variety of products and process technologies. System binders achieve the best operating results because they enable maximum binding strength with a minimum amount of use due to various mechanisms of action such as gradual gelatinization, minimal water consumption and low drying energy, partial migration (sandwich effect) and, with a cationic property of high fiber affinity. The above-mentioned selection criteria allow the optimum starch binder for the most varied of production processes to be selected in the fire protection agent according to the invention. The complete gelatinization is the most important criterion, because only a completely gelatinized starch has exhausted its maximum binder potential. .Urea-formaldehyde resins (UF), phenolic resins (PF resols and novolaks) and melamine resins (MF) can be combined with specially modified starches in a wide range of mixtures. The resin solution is mixed with an approximately 40% starch suspension for use as a binder for the production of particle board, laminated board, stone and glass fiber boards. Diluted to the usual application concentration and applied to the substrate, the starch breaks down in the subsequent oven drying, becomes film-forming and condenses with the synthetic resin to form a homogeneous film. This film shows up to an exchange rate of approx. 50%, "based on the Dry substance, a bending tensile strength increasing by more than 30%. The water resistance of the film is not reduced with a substitution of 30%, the film strength in the boiling water change test remains unchanged up to a substitution rate of 15% of the dry substance resin against the dry substance starch. Special system binders based on carbohydrates can be tailored to the product to be protected in the fire protection agent according to the invention and adapted to the application profile of the chemical / technical and ceramic industry for complete substitution of sulfide waste liquor. To determine the starch content, the starch is broken down by enzymes or by acid to glucose. The choice of method depends on the type and composition of the sample. Toxic impairments do not appear.

With the exception of the phosphate salts, all of these raw materials mentioned so far are toxic-free and have hitherto been unknown as fire retardants or fire protection additives. Thermal decomposition of a fire protection agent composed in this way takes place only when the flame is open. Such decomposition absorbs considerable amounts of heat, which are thus removed from the combustion process of the plastic. As a result, the plastic is protected from rapid thermal degradation and the formation of combustible decomposition products is stopped. Water vapor is obtained as the decomposition product, which forms an oxygen-displacing protective gas around the plastic. The following recipe notes can be given in tabular form for the flame-retardant finish of standard soft foams. The filler component, like all other additives, is added to the polyol. All numbers of parts refer to parts by weight. The fire protection agent itself is referred to below as filler type ANTIFIRE 601. It consists, among other things, of aluminum oxide, which was broken down from the raw material bauxite with sodium hydroxide solution and then mixed with carbohydrates and starches develops the fire-protective effect.

Fabric variant 1 variant 2

Standard polyether polyol (branched polyether modified with ethylene oxide) 100 parts 100 parts water 3.5 parts 3.5 parts

Tin II catalyst 0.19 parts 0.19 parts Dabco 33 LV foaming catalyst 0.12 parts 0.12 parts polysiloxane stabilizer 0.8 parts fire retardant (ANTIFIRE 601) 20-30 parts Cl and P-containing polyol (13, 5% P; 20% Cl) 20 parts toluenediisocyanate (TDI) 44.2 parts 44.2 parts

With the above compositions of a soft foam, the following characteristic data result for these two variants: Characteristics of variant 1 variant 2

Bulk density when using

70 parts ANTIFIRE 601 approx. 36 approx. 60

Oxygen index 18 25

Burning speed MVSS 90 0

(MVSS is a fire standard for automotive applications)

Adding ANTIFIRE 601 as a filler increases the viscosity. However, this increase in viscosity can be significantly reduced by adding special additives, for example dimethyl methylphonophonate (DMMP).

Another method for the flame-retardant treatment of open-cell PUR calibration foams is the subsequent treatment in aqueous binders containing the fire retardant. This method avoids the problems of handling higher-viscosity polyol dispersions, but only protects the material up to a penetration depth of approx. 10 to 20 mm and makes the use of special machines necessary. When the fire retardant is used, the binder must not be dried and crosslinked at temperatures above 200 ° C., since otherwise the hydroxide will already thermally decompose and the flame retardant effect will be reduced. Crosslinking the binder significantly increases the flame retardancy that can be achieved. The mechanical properties of the foam can be changed in accordance with the binder and the thickness of the application. The impregnation agents used must ensure good wetting of the foam. When using more suitable The soaking depth can be increased by up to a few centimeters. For example, PUR foam of class B1 according to DIN 4102 can be achieved without problems if polychloroprene latexes are used for the impregnation. The latex is cross-linked using the usual methods (S, ZnO, MgO). The addition of a wetting agent for better dispersion is recommended. A foam equipped in this way is particularly suitable, for example, for upholstery material. A recipe that brings good mechanical properties with very good flame resistance is, for example, as follows:

Share of fabric

Water 10 parts

* Ammonium acrylate dispersant 0.5 parts

ANTIFIRE 601 70 parts

PVAL (10%) ^** 5 parts

PVAC (60%) ^*** 20 parts

Proof of supply:

: Additol XM-330 from Höchst AG, BR Germany: Mowiol N 29-99 from Höchst AG, BR Germany: Mowilith DC-20 F from Höchst AG, BR Germany

In the case of a cold-curing molded foam with the following composition, for example an oxygen index of 33% 0 and a burning rate of 0 mm / s were determined in accordance with MVSS 30 (MVSS is a fire standard for motor vehicle applications): Share of fabric

ANTIFIRE 601 50th parts sb ₂ or ₃ 7 parts

Cl (from flame retardant containing chorus) 15 parts

The bulk density is 50 to 60 kg / m, the tensile strength 80 to 90 kPa, the elongation about 110% with a tensile strength of approx. 200 N / m.

The following recipe can be specified for an HR molded foam system for the automotive industry:

Share of fabric

High molecular weight polyether polyol with primary hydroxyil groups as a compound with catalysts and H ₂ 0 100 parts

Chlorine and phosphorus-containing polyol

13.5% P and 20% Cl 10 parts

ANTIFIRE 601 70 parts

Tolylene diisocyanate-methylene diphenyl diisocyanate mixture (TDI-MDI mixture) 45 parts

This foam has an oxygen index of approx. 30% 0 according to MVSS 30 and the best flame protection imaginable. Since processing with normal high-pressure machines is limited to a viscosity of approximately 3 to 3.5 Pas (Pascal seconds), processing with filler machines must be carried out for higher viscosities. NEN done. With this formulation, there is little separation of the polyol after 24 hours of standing. However, there is no hard sediment. The viscosity can be further reduced by adding suitable additives.

The following recipe is suitable for the production of insulating foams, which can be used, for example, as impact protection walls in sports halls:

Share of fabric

100 parts polyester foam

ANTIFIRE 601 100 pieces

A monium polyphosphate. 15 parts

Bromine-phosphorus compound with 42% Br,

3.6% P 15 parts

Sb ₂ 0 ₃ 6 parts

Zinc borate 6 parts

This foam complies with the DIN 4102, class B1 and has

3 a bulk density of approx. 300 kg /.

ANTIFIRE 601 can also be easily processed with polyurethane glue. For this purpose, suitable formulations for the respective area of application have to be processed, since the adhesives have to meet certain standards not only in combination with other materials. In addition to the actual flame retardancy of the adhesive, it is also a question of its thickness and the equipment of the materials to be joined. As a guideline, it can be stated that about 100 to 200 parts of ANTIFIRE 601 are used on polyol. Polyurethanes for fabric coatings have the advantage of better mechanical properties than the commonly used PVC. Difficulties caused by plasticizer migration cannot occur with this material. In the event of a fire, there are no corrosive gases. On the other hand, the flame retardant finishing of these fabric screeds is much more difficult than with PVC, since its halogen also provides flame protection for the polyester fabric. With a formulation with, for example, approx. 70 parts of ANITFIRE and 10 parts of phosphorus and nitrogen-containing flame retardants, oxygen indices of approx. 28% 0 ₂ can be achieved in the coatings without the addition of corrosive and toxic products. By coating the easily combustible polyester fabric, the oxygen index in the composite is reduced to approximately 18% 0 ₂ . This value is sufficient to achieve the classification according to DIN 4102, class B1. Flame protection according to DIN 75200 (German industrial fire standard for motor vehicle applications) is also possible with this formulation. One-component solvents containing solvents such as polyurethane, lacquers and two-component coatings can also be made flame-resistant with ANTIFIRE 601. An important area of application for this is, for example, the waterproof coating and the flame protection of fine-pored PUR foams. Because very high filler concentrations cannot be used here, additional flame retardants such as Cl and Br-containing compounds, including the addition of PVC powder, may be required. The formulations can be varied in accordance with the foam in order to achieve an optimal bond. These materials point a high weather resistance and are therefore suitable for outdoor applications such as for roof PUR casting compounds, for cable fittings, for casting components etc. In addition, they are characterized by high volume resistances and high heat resistance. For outdoor insulators, good weather resistance is obtained when using cycloaliphatic polyurethanes, which, unlike EP resins, are resistant to hydrolysis. In addition to good flame resistance, ANTIFIRE 601 lends these materials good arc and tracking current resistance, as well as good high-voltage arc resistance and a corresponding dielectric strength. Especially with regard to the arc resistance, ANTIFIRE 601 is superior to all other fillers. When using silanized products, the good bond results in better resistance to water storage and thus an improvement in the dielectric strength in the creep test. Since usually very high concentrations of fillers (approx. 70% of the total amount) are used, it is advisable to use a mixture of three components which gives an optimum in terms of viscosity and sedimentation behavior. A mixture of 400 parts of ANITFIRE consisting of 3 components is advantageous. When an additional 4 parts of silane are added, viscosities of approx. 70 Pas are achieved in cycloaliphatics with the mixture standing for 60 hours without sedimentation. The filler is predried here, with the addition of zeolite paste, stirred into the isocyanate and the polyol is added as the hardener. A recipe consists of, for example

Share of fabric

Isocyanate (Baymidur VP KL 3-5001) 100 parts

Polyol (Baygal VP KU 6598) 50 parts

ANTIFIRE 601 components 300 parts achieve the following values, for example:

Heat resistance according to Mertens approx. 138 ° C

Flexural strength approx. 96 MPa

(MPa = N / mm ² )

Arc resistance approx. 400 sec.

Oxygen index approx. 32% 0-

The addition of aluminum hydroxide (A1 ₂ 0 ₃ ) can additionally increase the hardness, the flexural strength and the impact strength.

The following recipe notes can be given in tabular form for the flame-resistant finishing of rigid polyurethane foams. The filler component, like all other additives, is added to the polyol.

Fabric variant 1

Standard polyether polyol (branched polyether modified with ethylene oxide) 100 parts Frigen 11 S 10 parts

Silicon oil 1.76 parts

* Dabco 33 LV catalyst 1.18 parts

Termethylene butanidiamine (TMBDA) 0.51 parts

ANTIFIRE 601 0-200 parts

Isocyanate (MDI) 133 parts

* available from Mondey or Air Products

Fabric variant 2

Voranol RN 490 100 parts

Tegostag B 1048 1 part

DMCHA 3.5 parts

.K 11 3.5 parts

ANTIFIRE 601, methyl methylphonate (DMMP) X, Y parts

Preliminary round M 269 130 parts

In the event of a fire, considerable amounts of heat are absorbed by the decomposition of ANTIFIRE 601 and thus removed from the process of burning the plastic. The plastic is protected from rapid thermal degradation and the formation of combustible decomposition products is stopped. The water vapor generated during the decomposition forms an oxygen-displacing protective gas. On the surface of the plastic, a layer is created from the charred products further progress of the combustion is prevented. Due to the low percentage of oxygen ^" a density of 100 to 200 kg / m is achieved. Both polyol and isocyanate are mixed with the specified amounts of ANTIFIRE 601 in order to be able to process the high filling quantities. Dirnethyol methylphophonate (DMMP) is a well-suited synergist to ANTIFIRE 601. For processing, ANTIFIRE 601, like other additives, is preferably only added to the polyol component. Each addition of filler causes an increase in the viscosity of the polyol a good reduction in smoke density is achieved in the event of a fire using ANTIFIRE 601. Since the flame-retardant equipment of ANTIFIRE 601 is based, among other things, on the fact that a protective layer of char products protects the plastic from further decomposition, it works best in the systems with polyurethanes , which is characterized by a pronounced carbonization behavior favor the formation of a closed protective layer. Compared to other PUR materials, rigid foams show a comparatively good charring behavior due to their stronger cross-linking. Trimerization of the isocyanate component gives the even more crosslinked PIR foams, which are notable for very good fire behavior, but are difficult to produce technically and are inexpensive to produce. In practice, therefore, there is an increasing tendency to use PU-PIR foams mixed by partial trimerization, so-called PUIR foams, which combine the good fire behavior of the PIR foams with the simple Connect the handling of PUR foams. Bei¬ by a conflation of 90 parts ANTIFIRE 601 and 10 parts of DMMP can ^• here reduced the percentage of trimerized isocyanate and an inexpensive flame retardant can be achieved. Polyol and ANTIFIRE 601 can be mixed using a high-shear mixer or kneader. The change in the reaction times when adding fillings is of great importance for the processing. The start time generally remains the same, while the tack-free time and the rise time are increased by approximately 20% when 50 parts of ANTIFIRE 601 on polyurethane are added. The density of the foam increases due to the higher density of the filler, namely with ANTIFIRE 601 with 37 phr by 1 to 5 times. By changing the reaction times, the pore structure is also changed to a small extent. The density is related to polyol depending on the ANTIFIRE 601 concentration. The thermal conductivity of rigid PU foams is the most important criterion for use in the construction sector. When up to 100 parts of ANTIFIRE 601 are added, the thermal conductivity changes only slightly with respect to PUR. The pressure test of rigid foams shows one with increasing ANTIFIRE 601 content

Hardening and embrittlement.

2

The modulus of elasticity [N / mm] can be increased by adding DMMP, which is called

Softener works, are reduced. This effect is particularly pronounced at high ANTIFIRE 601 contents. The bending tensile strength is only slightly dependent on the ANTIFIRE 601 content. The tensile strength does not change with the addition of ANTIFIRE 601. Reduction of density and Thermal conductivity, the addition of approx. 1% castor oil, based on the proportion of filler, can be recommended. If the PUR foam should not be able to catch fire due to generally accessible sources of ignition and should also not be allowed to melt or drip while burning, two options are recommended:

1. Foam with modified polyols and ANTIFIRE 601 can be used, or

2. Hydrophilic foam with a very high content of ANTIFIRE 601 is used.

In the first case, these are polyols (PHD) with polyurea dispersions, which form a solid crust during the fire and do not drip. By adding about 70 to 120 parts of ANTIFIRE 601, this tendency towards crust formation is significantly increased and a foam results, in which there is no fire behavior. Approx. 7% Cl and 7% P can be added as an additive.

In the second case, a foam is used which is based on the reaction of a polymer. Here, ANTIFIRE 601 can achieve 55% oxygen indices. The filler is added to the isocyanate. The mechanical properties can be varied over a wide range by varying the additives.

A further application of the fire protection means according to the invention consists in the flame-retardant treatment of wood, textiles, papers and cardboards, but also carpets, foils, cellulose, cellulose and similar products. For such applications The fire protection agent consists of twists and turns of at least one phosphate salt as a dehydrating agent and at least one carbohydrate as a binder, and optionally of borates and is used as an impregnating agent for the aftertreatment.

Three special mixtures have proven to be advantageous:

1. urea monophosphoric acid as a dehydrating agent, a polysaccharide or a wax malt starch as a binding agent, and borax as a stabilizing agent.

2. Diammonium hydrogen phosphate and boric acid as a dehydrating agent and a polysaccharide or another carbohydrate as a binder.

3. Monoammonium hydrogen phosphate and urea phosphate as a dehydrating agent, a polysaccharide or another carbohydrate as a binder, and borax as a stabilizing agent.

A particularly suitable mixture is given below:

Share of fabric

Diammonium hydrogen phosphate 20 parts

Urea phosphate 20 parts

Borax 10 parts

Thickness 12 parts

Water remaining parts

Such a fire protection agent according to the invention is hereinafter referred to as ANTIFIRE 501. By decomposing the ANTIFIRE 501 fire retardant at temperatures above its reaction temperature creates inert gases that prevent the entry of oxygen. Furthermore, the flame-retardant property of the treated substance is achieved in that its flammable materials undergo dehydration at the high fire temperatures. The materials treated with the fire protection agent ANTIFIRE 501 according to the invention therefore do not burn or ^' immediately extinguish themselves after the ignition flame has been removed. Even afterglow is not possible since no oxygen can get to the material. The fabrics are treated with the fire protection agent ANTIFIRE 501 by spraying them on the fabric or by immersing the fabric in the fire protection agent ANTIFIRE 501 and soaking it. The flame-retardant active substance content is determined quantitatively after the treated material has dried by determining its weight gain. Because the material experiences almost no handle influence during the treatment, the fire protection agent ANTIFIRE 501 according to the invention can also be used in the cellulose and cellulose industry. The binder added to the fire protection agent achieves a high level of compatibility with many substances.

The fire protection agent according to the invention is distinguished by precisely defined quality properties such as high purity, constant distribution, low water content, low electrolyte content and a defined specific surface. Especially surface-treating ANTIFIRE 501 types allow easy dosing and incorporation. In addition can ANTIFIRE improve the processing, especially the rheology (flow behavior) and have a positive effect on the mechanical properties of the end products. In addition to the ANTIFIRE product as a halogen-free, non-corrosive and physiologically harmless flame retardant, special aluminum hydroxides can be used as coating pigments and fillers in the cardboard and paper industry.

Claims

Claims

1. Fire protection agent containing at least one dehydrating agent and a carbohydrate or a starch as a binder.

2. Fire protection agent according to one of the preceding claims, which contains aluminum hydroxide.

3. Fire protection agent according to one of the preceding claims, which contains at least one phosphate salt as a dehydrating agent.

4. Fire protection agent according to one of the preceding claims, which contains aluminum sulfate 18 hydrate DAB 7 as a dehydrating agent.

5. Fire protection agent Fire protection agent according to one of the preceding claims, which contains monoammonium hydrogen phosphate and urea phosphate as the phosphate salt.

6. Fire protection agent according to one of the preceding claims, which contains at least one borate.

7. Fire protection agent according to one of the preceding claims, which contains urea monophosphoric acid as the phosphate salt, borax as the borate and a polysaccharide as the carbohydrate or wax malt starch as the starch.

8. Fire protection agent according to one of the preceding claims, which contains diammonium hydrogen phosphate as the phosphate salt, boric acid as the borate and a polysaccharide or any carbohydrate.

9. Fire protection agent according to one of the preceding claims, which contains a monosaccharide, disaccharide and / or polysaccharide as the carbohydrate.

10. Fire protection agent according to one of the preceding claims, which also contains a blowing agent and / or a stabilizing agent.

11. Fire protection agent according to claim 10, wherein the blowing agent is melamine and / or ammonium hydrogen carbonate, the stabilizing agent is tripentaerytrite and / or pentaerythritol and the dehydrating agent is urea and / or monoammonium hydrogen phosphate and / or diammonium hydrogen phosphate.

12. Use of the fire protection agent according to one of the preceding claims for incorporation into raw materials and products by admixture as a filler or for subsequent impregnation of raw materials and products by means of impregnation, coating, spraying or brushing.

13. Use of the fire protection agent according to one of claims 1 to 11 for admixture as a filler in plastics, in particular in polyurethanes.