WO2004056920A2

WO2004056920A2 - Foamed materials rendered barely combustible using ammonium sulfate and other flameproofing agents

Info

Publication number: WO2004056920A2
Application number: PCT/EP2003/011538
Authority: WO
Inventors: Peter Stein; Jonas Scherble
Original assignee: Röhm GmbH & Co. KG
Priority date: 2002-12-19
Filing date: 2003-10-18
Publication date: 2004-07-08
Also published as: WO2004056920A3; DE10260096A1; AU2003298089A8; TW200417599A; AU2003298089A1

Abstract

The invention relates to a composition for producing polyvinyl chloride foamed materials having reduced inflammability properties, said composition being characterised in that it contains ammonium sulfate.

Description

New, flame-retardant foams using ammonium sulfate and other flame retardants

Field of application of the invention

Foam compositions with reduced flammability

State of the art

The present invention relates to compositions of foams with improved flame behavior based on polyetherimide (PEI), styrene-acrylonitrile copolymers (SAN), polyvinyl chloride (PVC), blends made of PVC and polyurethanes (PU) or phenolic resins. Various methods can be used to produce foams from the materials mentioned, for example by incorporating a blowing agent into the polymer material, by beating a polymer melt, by incorporating hollow spheres (so-called syntactic foams) or by a combination of these processes. The flame behavior of these foams is decisively improved by incorporating the finest possible ground ammonium sulfate (AMSU).

Foams have been known for a long time and are widely used due to their low density and the associated material savings, their excellent thermal and acoustic insulation properties, their mechanical damping and their special electrical properties. For example, foams can be found in packaging, in furniture and mattresses, generally for sound and heat insulation, as buoyancy bodies in watercraft, as filter and carrier material in various industrial sectors and as structural elements in the production of layered materials, laminates, composites or foam composites. For many applications, especially in the construction of aircraft and water vehicles, adequate fire protection of the foams is necessary, as is the case in legal ones Regulations and a number of other regulations is required. Evidence that the foams meet the fire protection requirements is carried out with the aid of a large number of different fire protection tests, which are usually aimed at the use of the foam or the composite body containing it. In general, foams must be equipped with so-called flame retardants in order to pass these fire protection tests. The use of chlorine- or bromine-containing compounds as flame retardants, which are often used in combination with antimony oxides, is widely known. The disadvantage here, however, is that plastics and foams, the flammability of which is reduced as a result, are extremely difficult to recycle, since these halogenated hydrocarbons can hardly be separated from the polymer and dioxins can be formed from these compounds in waste incineration plants. In addition, toxic and corrosive gases such as HCI and HBr are formed in the event of a fire. European patent application EP 347497 also states that halogen and phosphorus-containing low-molecular flame retardants in isocyanate-based foams have only been tested in fire tests on a laboratory scale and not under conditions which correspond to a fire. Because of the disadvantages mentioned above, the general aim is to avoid chlorinated and brominated substances as additives in plastics as far as possible.

Phosphorus compounds are another class of flame retardants with which foams are treated. A particular disadvantage here is that in the event of a fire, as well as with halogen-containing flame retardants, a very high smoke gas density is produced. Because of the toxicity of the smoke gases and the visual impairment caused by the smoke, people in the vicinity of the fire, especially in closed rooms, are endangered and rescue work is made more difficult. In addition, low-molecular compounds, to which many halogen and phosphorus-containing flame retardants count as plasticizers in many plastics. This undesirable effect deteriorates the mechanical properties and thus limits the possible proportion of the flame retardant in the material. The quantity also limits the flame retardancy that can be achieved in this way. In addition, there is a risk with low molecular weight compounds that they will diffuse out of the material over time. As a result, the flame behavior of the material deteriorates, on the one hand, and the flame retardant may possibly enter the environment in an undesirable manner.

task

In view of the prior art specified and discussed herein, it was an object of the present invention to provide compositions for the production of polymer foams with reduced flammability, low smoke development (e.g. FAR 25.853 (c) and AITM 2.0007), and low heat development (e.g. FAR 25.853 ( c)) to be specified. Furthermore, the foams should not contain any toxic and / or odor-causing cleavage products, as is the case, for example, when using some phosphorus compounds as flame retardants. For the reasons mentioned above, it was an object of the invention to provide compositions for foams whose flame behavior is improved without the use of halogenated flame retardants. Furthermore, the invention was based on the object of specifying the most cost-effective flame retardant for the foams mentioned. It was therefore an object of the present invention that the flame retardant used for the finishing should be as harmless to health as possible and should not have any negative effects on the processability of the finished foam. solution

The stated object can be achieved by means of foams whose flame retardant properties are improved by solid ammonium sulfate (AMSU) in the finest possible distribution.

The use of AMSU as a flame retardant in isocyanate-based foams has been described, for example, in German patent application DE 2542048. The foams described there were made self-extinguishing by means of the finely ground AMSU. A foam containing 19% by weight of AMSU burned for a short time after being removed from a Bunsen burner flame and then went out. At 20.9% by weight of AMSU, the foam went out immediately after being removed from the flame. Also described in European patent application EP 347497 flame-retardant, polyurethane-based foams. The advantage of using AMSU as a flame retardant is clearly evident from the examples given there: By increasing the AMSU content from 15 to 39% by weight of the total material, the LOI according to ASTM D-2863 could be increased from 24 to 30. Further examples of AMSU-containing polyurethane foams can be found in US 3737400. Burning length and time of the rigid foam samples discussed there decreased to zero due to the incorporation of 15.5% by weight of AMSU and more.

German patent application No. 10241855.1 describes AMSU as a flame retardant for PMI foams. A PMI foam made from 75 parts by weight of AMSU as a flame retardant on approx. 110 parts by weight of other material with a density of 82 kg / m ³ showed a heat release of HR = 71.0 kWmin / m ² or HRR = 64 .2 kW / m ² according to FAR 25.853 (c). The smoke density test according to FAR 25.853 (c) was also passed. In contrast, a foam of comparable density without AMSU flame retardant with HR = 102.0 kWmin / m ² or HRR = 106.0 kW / m ^{2 released} significantly more heat and also showed poorer smoke gas development. Compared to other flame retardants, the use of AMSU has the following advantages: It is cheap and can be worked into materials inexpensively as an insoluble solid. Since it is completely non-toxic, people are not endangered neither in handling nor in processing. For the same reason, there are no additional risks when processing foams equipped with AMSU, for example due to dust. AMSU is used in large quantities as a fertilizer. The entry of small amounts of AMSU into the environment is therefore ecologically harmless. There are also no additional problems with the disposal of waste materials due to the use of foams equipped with AMSU, ie the disposal of waste materials is possible using the usual disposal methods. As an inorganic solid, AMSU is not soluble in the plastic matrix. This gives the additional great advantage over soluble flame retardants that it does not act as a plasticizer. In the event of fire, the use of AMSU in PVC gives the additional advantage that the toxic hydrogen chloride gas formed from PVC is bound by the ammonia released from AMSU. Even in the event of a fire, ammonium sulfate is characterized by its non-toxic properties, in particular the smoke density is particularly low.

Despite the enormous advantages of AMSU as a flame retardant, no foams based on PVC, blends made of PVC and PU, PEI and SAN have been described in the literature known hitherto other flame retardants has been improved. The incorporation of AMSU offers the possibility of achieving very good flame protection for all of the foams mentioned. The effect of ammonium sulfate is similar to that of ammonium polyphosphate. It is based on the decay of the crystalline Compound in ammonia and sulfuric acid at a higher temperature. The released sulfuric acid has a pyrolyzing effect, while the released ammonia gas dilutes the flammable gases and therefore has an extinguishing effect. This can be read, for example, in JP 08325574, which describes combinations of flame retardants which also contain ammonium sulfate, among other things. The compositions described there are suitable for casting resins. Combinations of other flame retardants with ammonium polyphosphate are also deposited, for example, in patent CN 1197103. Other applications described in the literature which are flame-retardant with ammonium sulfate include textile applications (Khattab, MA; Gad, AM; El-Samanoudi, AHJ Appl. Polym. Sc .: Appl. Polym. Symp. (1994), 55, 87-96; Basch, Avraham; Lewin, Menachem, Text. Res. J. (1973), 43 (11), 693-4), and also extinguishing agents for forest fires (WO 9858039; US 3409550). AMSU is used as a flame retardant for paper (JP 11228968), for wood (JP 11105011; DE 19748751; Hsieh, Tang-Chou, Tai-wan Lin Yeh Shi Yen So Pao Kao (1970), No. 188, 22 pp .; Zakl. Konserw. Drewna, Pr. Inst. Technol. Drewna (1969), 16 (3), 115-28) and for polymeric materials such as polystyrene (JP 05086254) and polyethylene, polypropylene or their copolymers (AU Vasil'ev, Yu. V .; Ryabinina, LI; Fil'bert, DV, USSR, Sin.Volokna (1969), 69-71.Editor (s): Pakshver, AV Publisher: lzd., "Khimiya", Moscow, USSR., JP 48055942 ; JP 47034541) is used. Ammonium sulfate has also already been used as a flame retardant additive in polyurethane foams (US 5948148, US 3737400, Solodovnik, PI; Mel'nikov, VM; Putnins, E., USSR, Razrab. Metodov Tepl. Zashch. Inzh. Sooruzh. Krainem Sev. (1983 ), 133-41.Editor (s): Ivanov, NS Publisher: Yakutsk.Gos.Univ., Yakutsk, USSR.).

Claims

1. Composition for the production of polyvinyl chloride foams with reduced flammability, characterized in that the composition comprises ammonium sulfate.

2. Composition for the production of foams from mixtures of polyvinyl chloride and polyurethanes with reduced flammability, characterized in that the composition comprises ammonium sulfate.

3. Composition for the production of foams made of poly (styrene-co-acrylonitrile) with reduced flammability, characterized in that the composition comprises ammonium sulfate.

4. Composition for the production of foams from mixtures of polyetherimide with reduced flammability, characterized in that the composition comprises ammonium sulfate.

5. Composition for the production of foams based on phenolic resins with reduced flammability, characterized in that the composition comprises ammonium sulfate.

6. Composition according to at least one of claims 1-5, characterized in that the composition has 1 to 300 wt.% Ammonium sulfate based on the polymer.

7. The composition according to at least one of claims 1-5, characterized in that the composition in the preferred case has 5 to 200 wt.% Ammonium sulfate based on the polymer.

8. The composition according to at least one of claims 1-5, characterized in that the composition in the particularly preferred case has 25 to 100 wt.% Ammonium sulfate based on the polymer.

9. Composition according to one of claims 1 to 8, characterized in that at least 90% of the ammonium sulfate used has a grain size of less than 100 m.

10. Composition according to one of claims 1 to 8, characterized in that in the preferred case at least 90% of the ammonium sulfate used has a grain size of less than 10 microns.

11. The composition according to claims 1 to 10, characterized in that the composition contains further flame retardants.

12. The composition according to claim 11, characterized in that at least one of the further flame retardants is a phosphorus compound.

13. The composition according to claim 7, characterized in that the phosphorus compound is selected from the phosphines, phosphine oxides, phosphonium compounds, phosphonates, phosphites and / or phosphates.

14. The composition according to claim 13, characterized in that the phosphorus compound used is dimethyl methyl phosphonate, recorcinol bis-diphenyl phosphate, or ammonium polyphosphate.

15. The composition according to any one of claims 1-14, characterized in that hollow spheres have been incorporated into the composition and the resulting foam is therefore one of the syntactic foams.

16. The composition according to any one of claims 1-15, characterized in that the foam is reinforced with fibers.

17. Shaped body made of a foam according to one of claims 1-16.

18 layer material (sandwich) containing a layer of a foam according to any one of claims 1-17.

19. automobile, rail, water, or aircraft, characterized in that it consists entirely or in part of a foam according to at least one of claims 1-17.