EP0408627A1

EP0408627A1 - Latex-bound fireproofing material

Info

Publication number: EP0408627A1
Application number: EP89904068A
Authority: EP
Inventors: Heinz Horacek; Hermann Wudy
Original assignee: Chemie Linz GmbH
Current assignee: Chemie Linz GmbH
Priority date: 1988-04-07
Filing date: 1989-04-07
Publication date: 1991-01-23
Also published as: EP0338347A1; HUT55823A; AT392078B; WO1989009808A1; DE58900844D1; ATE72824T1; ATA88988A; FI99021B; ES2038361T3; DK241890D0; HU206739B; AU615293B2; KR900700578A; DK241890A; HU892232D0; JPH03503654A; DE3813252A1; NO904231D0; KR0139292B1; RU1838372C

Abstract

Thermally-expandable fireproofing material containing expanded graphite, an aqueous chloroprenlatex containing carboxyl groups and substances which form a paracrystalline carbon network in the event of fire.

Description

Latex-bound fire protection compound

description

The invention relates to thermally expandable fire protection compositions or fire protection laminates which contain expanded graphite, a chloroprene latex containing carboxyl groups and substances which form a paracrystalline carbon structure in the event of fire, and a process for their production.

Thermally expandable fire protection compositions, which consist of expanded graphite, chloroprene rubber, a phenolic resin, an organic solvent and optionally also aluminum hydroxide and inorganic fibers, are described in AT-PS 360.130, for example. They are particularly effective in preventive fire protection due to their excellent resistance to moisture, frost, warmth, light and industrial climate, as well as their high inflation pressure. When exposed to heat and fire, they expand in the opening to be protected in the event of a fire with a relatively low flowability. As a result, the expanding mass does not avoid obstacles even in an opening that is not completely closed, and due to its high inflation or expansion pressure, which is usually above 2 bar, forms a tightly sealing barrier layer, which prevents further spreading of heat, fire and smoke gases or delayed or completely prevented. This sealing material has high mechanical strength even when expanded. A disadvantage of the production, processing and use of such compositions is their brittleness and low flexibility. A further disadvantage lies in the fact that organic solvents are used in their production, which require increased equipment and labor for solvent recovery and for minimizing environmental pollution and health hazards which may be caused by solvents.

The use of solvent-free fire protection compositions made of expanded graphite and a polymeric binder is described in WO 88/02019. The polymeric binder is either a flexible binder, e.g. B. polyvinyl acetate elastomeric binder, e.g. B. a chloroprene polymer, a thermosetting binder, e.g. B. a formaldehyde resin or a thermosetting binder with the addition of a flexible binder possible. The disadvantage of these fire protection compounds, however, is that, if flexible or elastomeric binders are used, they have sufficient flexibility, which is necessary for easy handling, but that the barrier layer formed after inflation in the event of a fire has insufficient stability and hardness has, which are necessary for an optimal sealing against further fire spread. Fire protection compounds based on thermoset binders are very difficult to process because of their great hardness. The crust formed in the event of fire after swelling is hard, but also cracked and brittle and does not form a sufficiently stable and tight barrier layer.

The object of the invention was to eliminate these disadvantages which occur with the known fire protection compositions and, above all, to obtain less brittle compositions which form a sufficiently stable and hard barrier layer in the event of a fire and in whose production no organic solvents are required. The task was solved with a fire protection compound obtained by combining three specific components.

The present invention accordingly relates to a thermally expandable fire protection composition which is characterized in that it contains expanded graphite, a chloroprene latex with at least 0.3 moles of carboxyl groups per 1 kg of latex solid, in the event of fire a paracrystalline carbon structure, and, if appropriate, further additives.

It proves to be particularly advantageous if the fire protection compositions do not contain organic solvents, but if aqueous latex dispersions are used in the production. Due to the existing residual water content, these fire protection compounds show a more favorable fire behavior than when using organic solvents. Because of the absence of organic solvents, they can be manufactured and processed much more simply and in a much more environmentally friendly manner. The fire protection compositions according to the invention show good elasticity and flexibility primarily because of the content of elastomeric chloroprene polymer, so that they or from them produced laminates or sheets are easy to use, process and handle. Depending on the respective composition of the fire protection compound, very high expansion pressures, preferably above 5 bar, can be achieved in the event of a fire, and thus a particularly effective seal can be achieved. The barrier layer formed after inflation is characterized by its strength, hardness and stability, so that it does not form cracks and is not destroyed by the thermal, mechanical and aerodynamic stresses and fire turbulence in the event of a fire.

The bio graphite used can be produced, for example, by acid treatment of a natural graphite with fuming nitric acid, as described in US Pat. No. 3,574,644 or in H. Spatzek, Carbon 86 (1986).

The chloroprene latex is usually made by copolymerizing chloroprene with acrylic acid or methacrylic acid. Examples of such latices are Skyprene ^(R) (Toyo Soda), Bayprene ^(R) (Bayer), Butaclor ^(R) (Distugil), Denka Chloroprene ^(R) (Druki Kagaku Kogyo), Nairit ^(R) (USSR) or Neoprene ^(R) (Du Pont) in stores.

The fire protection composition usually contains 25 to 60% by weight of expanded graphite, 5 to 25% by weight, calculated as a solid, of a chloroprene latex, 5 to 25% by weight of substances which form a paracrystalline carbon structure in the event of fire, and optionally additives.

Suitable substances that form a paracrystalline carbon structure in the event of fire are, for example, polyacrylonitrile, cellulose or their derivatives, phenol-formaldehyde resins, polyfurfuryl alcohol or polyimides. When heated in the event of a fire, these substances initially crosslink, the strong intermolecular bonds also being retained during further thermal stress, which leads to pyrolytic decomposition and ultimately to the formation of the paracrystalline carbon skeleton. (Chemie-Ing.-Techn. 42 No. 9/10 (1970), pp. 659-669). Three-dimensional cross-linked thermosets, such as phenolic resins, have proven to be particularly suitable. Phenolic resins with tertiary butyl groups, such as. B. p-tert-butylphenol formaldehyde resin 7520E or 7522E from Rousselot, show particularly good results. Additives that modify the fire behavior are, for example, melamine and its derivatives, various graphite salts, cyanuric acid derivatives, dicyandiamide, halogenated hydrocarbons, polyammonium phosphates and guanidine salts. These substances also swell when decomposed when exposed to heat. Since they have a decomposition temperature that is different from expandable graphite, the expansion pressure also increases in the event of a fire, which means that the opening is firmer sealed.

In addition, other additives that primarily improve the strength of the sealant in the expanded state, solidify the crust and increase cohesion, such as. B. inorganic fibers, such as mineral or glass fibers, glass powder, vermiculite, bentonite, silica, silicates, borax, starch, sugar, chlorinated paraffins, aluminum sulfate, aluminum hydroxide or magnesium hydroxide. Flame retardants can also be added, for example halogenated or phosphorus-containing hydrocarbons, such as. B. Tris-chloropropyl phosphate, dibromo neopentyl glycol, or antimony trioxide. Additives that help increase foam formation in the event of flaming are also suitable. Examples include salicylic acid, p-hydroxybenzoic acid, PVC, and nitrogen or sulfohydrazides, triazoles, urea dicarboxylic anhydride and ammonium carbonate.

The fire protection composition according to the invention can be used both as a paste and in the form of plates, strips, tapes or moldings. Fire protection laminates in which the fire protection composition is laminated onto a carrier web, for example a glass fiber fleece, are particularly advantageous and simple to use. For decorative reasons or for example to protect the fire protection compound, the laminates or plates can be covered with a covering layer, for example a plastic film, e.g. B. a PVC film, paper or aluminum sheet, be covered on one or both sides. It is also possible to equip the fire protection laminates or panels with an adhesive layer, which is then advantageously covered with a separating film.

The fire protection compositions according to the invention are produced by mixing and homogenizing expanded graphite, a preferably aqueous latex dispersion containing carboxyl groups, and a paracrystalline dispersion in the event of fire Carbon skeletal substance, e.g. B. a phenol-formaldehyde resin or polyimide resin, and optionally other additives which modify the fire behavior, for example in a kneader, dissolver or mixer. The mass obtained in this way can either be used as such, or it can be applied to a carrier web, for example to a film or a nonwoven (for example with the aid of a doctor blade. After drying, the laminate can be applied to a calender, possibly with Embossing roller are compressed, possibly with simultaneous lamination with a cover layer, for example made of PVC or aluminum.

The fire protection compositions according to the invention are used for fire protection sealing or sealing off openings in components forming a fire compartment, such as. B. joints between walls, cavities or spaces, wall openings, cable ducts or the like used. Door seals, window seals or other seals that foam up in the event of a fire and seal the upstream slot or opening can also be produced. The connection between glass and frame in fire protection glazing with the aid of the fire protection compositions or laminates according to the invention also results in optimal fire protection. It is also possible to manufacture entire bricks with which openings for cables or pipes are lined and which form a barrier when exposed to fire. In the event of a fire, these materials foam up due to the effects of heat and seal the opening so that the further passage of fire and smoke and thus the further spread of the fire is prevented.

Examples 1-15 and Comparative Example 16

The starting materials listed in Tables 1 and 2 (in parts by weight) were added in a stirred tank in the following order: additives, Al (OH) ₃ , phenolic resin, 50% aqueous chloroprene latex dispersion, expandable graphite, mineral fibers (Inorphil ^(R) 061- 60, GM Langer, FRG). The mass was homogenized for 1 hour in a dissolver with a toothed disc at 30 ° C. and a pH of 10 (adjusted using KOH). The viscosity was about 4 Pas, measured at 30 ° C in a Brookfield viscometer (spindle 7, 20 rpm). The fire protection composition obtained was then knife-coated onto a glass fleece with a basis weight of 50 g / m ² and dried at 190.degree.

The expanded graphite was obtained by acid treatment of a natural graphite with smoking the nitric acid. A tert-butylphenol form dehyde resin, type 7520E from Rousselot, France, was used as the phenolic resin.

Commercially available latex dispersions based on a copolymer of chloroprene and methacrylic acid were used. The carboxyl group content given in Tables 1 and 2 was adjusted by mixing the following latices with different carboxyl group contents:

Neoprene ^(R) 115 (Du Pont): 0.33 mol COOH per 1 kg of 1 solid, Neoprene ^(R) 750 and Neoprene ^(R) 824A: no COOH content, ayprene ^(R) 4R (Bayer): 0.23 Moles of COOH per 1 kg of latex solids. In Comparative Example V 16, a 10% chloroprene solution in toluene was used instead of the aqueous latex dispersion under otherwise identical conditions.

The properties of the fire protection laminates are also shown in Tables 1 and 2. The expansion pressure was measured at 250 ° C. on samples with a diameter of 113 mm, which were placed between two heatable metal plates. The pressure created during inflation was transferred from the lower plate to a force transducer with a pressure display. The inflating material was not delimited on the side and could spread freely in the plane. The head height was measured on samples with a diameter of 50 mm, which were placed in a metal cylinder with a height of 100 mm and an inner diameter of 50 mm. The cylinder with the sample that is over a Stamp was preloaded with 100 g, was heated in an oven at 300 ° C for 10 minutes.

Table 1

(Ingredients in parts by weight)

Example 1 2 3 4 5 6 7 8

Moles of carboxyl per 1 kg of latex solid 0.33 0.33 0.05 0.33 0.05 0.33 0.33 0.33

Latex 21 30 30 27 21 27 27 27

Phenolic resin 3 4 4 4 10 10 4 12

Inorphil ^(R) - 2 2 - 2.1 - - -

Expandable graphite 57 53 53 57 57 48 57 57

Al (OH) ₃ - 11 - - 9.9 - - 4

Additives ³ 19 / A - 11 / B 12 / B - 12 / B 12 / C -

Properties unexpanded ¹ + + - + - + + + inflated ² + + - + - + + +

Thickness (mm) 2.4 2.5 2.8 2.5 2.5 2.4 2.6 2.2

Grammage 2.56 2.02 2.16 2.50 2.50 2.43 2.47 2.05

(kg / m ² )

Inflation pressure (bar) 12.5 6.8 7 8 6 8.5 9.6 8.7

Head height (mm) 19 17 20 20 13 15 13 17

¹ + flexible, - brittle

2 + stable and hard, - unstable A aluminum sulfate B dicyandiamide C melamine Table 2

(Ingredients in parts by weight)

Example 10 11 12 13 14 15 V16

Moles of carboxyl per 1 kg

Latex solids 0.33 0.17 0 0.23 0.33 0.33 0.23 0

Latex 27 27 27 27 25 40 22 55 (toluene)

Phenolic resin 4 4 4 4 6 7 6.5 5

Inorphil ^(R) - - - - 1.4 - 1.5 1.3

Expandable graphite 57 57 57 57 54.6 37 42 29.3

Al (OH) ₃ - - - - 13 5 14 9.4

Additives ³ 12 / D 12 / E 12 / F 12 / G - 11 / H 14 / H -

characteristics

uninflated ¹ + - - - + + - +/- inflated ² + - - - + + - +

Thickness (mm) 2.3 2.5 2.2 2.2 2.5 2.6 2.5 2.5

Area weight 2.79 3.53 2.47 1.84 3.6 2.8 3.0 2.5

(kg / m ² )

Inflation pressure (bar) 12 13 8.6 8.8 13 10 8 3

Head height (mm) 12 19 13 17.5 19 17 12 18

1 + flexible, - brittle, +/- little flexible

2 + stable and hard, - unstable

3D strength E borax

F guanyl urea sulfate G guanidine phosphate H guanidine carbonate Example 17:

Small fire test with laminates according to Example 13 and V 16

In order to demonstrate the effective sealing of an opening with the fire protection compound according to the invention, two 20 cm long PVC pipes with an outer diameter of 16 cm and a wall thickness of 3.5 mm were each with 230 g of a 15 cm wide fire protection laminate according to Example 13, the on the fleece side was additionally laminated with a 0.05 mm thick aluminum foil, the expanded graphite coming to rest on the pipe side. The wrapped pipes were packed in a zinc sheet sleeve and inserted into a bore (22 cm diameter) of a 10 cm thick lightweight concrete slab (Ytong ^(R) ). The tubes protruded 5 cm from the hole on both sides of the plate.

Two similarly wrapped pipes were inserted into two further holes of the same weight in the lightweight concrete slab, but a fire protection laminate according to comparative example V 16 was used instead of the fire protection laminate according to the invention. The somewhat less flexible laminate showed small tears and slight breaks when it was wrapped.

The lightweight concrete slab was then installed in a small fire chamber based on DIN 4102 and flamed from one side up to a temperature of around 1000 ° C according to the standard temperature curve. The fire protection compounds began to expand after about 4 minutes due to the heat, whereby all 4 PVC pipes were softened and compressed. The partitions with the laminates according to Example 13 were completely closed after 13 and 14 minutes, those with the laminates according to Comparative Example V 16 after 13 and 17 minutes, respectively, so that no more smoke, fire or soot escaped to the outside. After 40 minutes, the outwardly protruding pipe stubs of the partitioning according to the invention began to break apart, while the pipe ends of the partitioning began to melt in accordance with the comparative example. After 60 minutes, the pipe stumps were completely broken off or melted off, the temperature of the expanded foam according to Example 13 was 290 ° C., that of the expanded foam according to Comparative Example V 16 at 310 and 370 ° C. The experiment was stopped after 80 minutes without flame or flue gas breakthroughs being ascertainable. It was also found that when the fire protection composition according to Example 13 was used on the side facing away from the fire, the temperature during the fire test was 20-80 ° C. lower than when the conventional fire protection composition according to Comparison Example V 16 was used.

The hardness of the expanded foam according to Example 13 was measured after cooling by means of a compressive strength test on a 4045 lasting device in accordance with DIN 53421 and was 0.2 N / mm ² (60% compression).

Claims

1. Thermally expandable fire protection composition, characterized in that it contains expanded graphite, a chloroprene latex with at least 0.3 moles of carboxyl groups per 1 kg of latex solid, in the event of fire a paracrystalline carbon-forming substance, and optionally further additives.

2. Fire protection composition according to claim 1, characterized in that an aqueous latex dispersion was used for its production and that it contains no organic solvent.

3. Fire protection composition according to claim 1 or 2, characterized in that the chloroprene latex is composed of a copolymer of essentially chloroprene and acrylic acid or methacrylic acid.

4. Fire protection composition according to one of claims 1 to 3, characterized in that the substance forming a paracrystalline carbon structure in the event of fire is a phenolic resin.

5. Fire protection composition according to one of claims 1 to 4, characterized in that it calculates 25 to 60% by weight of expanded graphite, 5 to 25% by weight of a chloroprene latex as a solid, and 5 to 25% by weight in the event of fire forming a paracrystalline carbon structure Contains substances.

6. Fire protection laminate, characterized in that a fire protection composition according to one of claims 1 to 5 is applied to a carrier web.

7. Fire protection laminate according to claim 6, characterized in that the fire protection composition is covered with a cover layer.

ü. A process for the production of a protective edge material or a fire protection laminate according to one of Claims 1 to 7, characterized in that expanded graphite, a preferably aqueous latex dispersion containing carboxyl groups, and a paracrystalline carbon structure in the event of fire forming substance, and optionally other additives mixed with good homogenization, the resulting mass is optionally applied to a carrier web and the laminate formed is optionally laminated with a cover layer.