DE2308340C3 - Building material made from porous inorganic material and organic binder - Google Patents

Description

Building materials made from porous fillers held together with a binder are well known. It has already been proposed and tried to use both inorganic and organic porous materials to be processed with organic (synthetic resin) or inorganic (cement) binders to form moldings.

So 7. B. in the French Patent specification 15 20 239 proposed to bind a granulate of foamed polystyrene with cement, sand and optionally synthetic resin, and it is also proposed to use relatively heavy inorganic foamed materials, such as. B. to add pumice or expanded clay, which are known to have bulk weights above 250, mostly 500 to 1000 kg / m '. The granulate made of foamed polystyrene only acts as a pore-forming agent in the concrete matrix, without contributing anything to the strength. Building materials with concrete as a binding agent are relatively heavy, even when porous inorganic materials are added, which, however, have the aforementioned, relatively high bulk weights for lightweight aggregates. In addition, polystyrene is only sparsely wetted by the binder mixture during the production of the concrete, and must therefore be coated with a suitable material, if necessary . B. of organic silicon compounds are provided.

Now one has already tried to get this night * parts to eliminate. For example, it is proposed in French patent specification 1421400. Perlite, thus a very light porous inorganic material, optionally mixed with particles of foamed Polystyrene, with the help of an organic binder, such as. B, phenolic resin, into molded articles TO PROCESS, The very essential question of the quantities * ratios of the individual mixture components becomes i> but only treated very generally by namely preferably 70 to 97.5% by weight of the mixture of perlite (including optionally the Artificial foam particles).

According to the invention, however, a building material 4n is now proposed which consists of

A) 5 to 60, preferably 10 to 30% by weight of a first porous inorganic material with a bulk density below 0.25, preferably below 0.15 g / cm ¹ , and a grain size below 10 mm, preferably below 8 mm, and

B) a) 15 to 80, preferably 20 to 50% by weight of one

second porous inorganic material with a bulk density above P 25, preferably above 0.50 g / cm 'and / or
b) 0.5 to 10, preferably 1 to 5% by weight of a plastic foam with a density of about 8 to about 100, preferably 10 to 40 g / l, and optionally

C) up to 40% by weight rubber granulate, preferably mixed with textile thread

and the organic binder.

The first porous inorganic material with a bulk density of less than 0.25 g / cm 'has proven to be additives such as perlite, vermiculite, or foam glass waste have proven to be useful. As can be seen, has it was found that with lesser amounts of this light inorganic exfoliated material than has been the norm up to now. Since construction material shoes are made of perlite alone fruit an organic binder, and so very high pearlite contents have not proven to be very useful for various reasons, will - how

apparent - proposed according to the invention the combination with a second foamed aggregate.

As such an aggregate, either a second porous inorganic material with a bulk density of over 0.25, preferably over 0.50 g / cm ³ , such as e.g. B. pumice, expanded clay, foam cement waste od. On the other hand, granulated plastic foam can also be used as a second aggregate, especially when the demands for lighter and therefore better insulating elements are paramount. Here, however, the quantitative ratio of the additives has again proven to be particularly important.

The first lightweight porous inorganic material as an essential component for well insulating and yet relatively stable and also heat-resistant elements should not be used in an amount below about 5, it is better not to use less than 10% by weight, since otherwise these desired effects are hardly worth mentioning Dimensions can occur. On the other hand, it has been shown that light inorganic aggregates in quantities above about 60, yes in most In cases of more than 30% by weight, either the bond is insufficient or the better ones Properties that result from the addition of synthetic foam particles and / or something heavier inorganic porous material are to be achieved, are not feasible. Basically similar conditions apply to the specified ^ proportions of the second heavier and therefore stronger porous inorganic material. Has proven to be particularly cheap an expanded clay with a grain size between 3 and 20 mm, preferably between about 7-15 mm.

Ultimately, however, the amount of foam plastic particles has proven to be particularly significant, being the technical and economic effectiveness of the addition of foam plastic particles with smaller additions than 0.5, yes mostly even with amounts below 1% by weight of the total mixture is no longer guaranteed. On the other hand, additional amounts over 10 are used, usually with those above 5% by weight result in such a rapid decrease of that which is generally required of such building materials Property levels that building material compositions lying outside these limits prove to be extraordinary have proven inexpedient.

For example, polyurethane, preferably a rigid polyurethane foam, is used as the foam plastic Use. Polyurethane foams are chemically and also thermally very resistant, so that a building material. the polyurethane foam contains, can be subjected to higher stresses without thereby the building material is destroyed. Foamed polystyrene particles will then be used if the building material is not subjected to any major thermal stress.

As mentioned, the building material can be used as a further additive Up to 40% by weight of rubber granulate, preferably mixed with textile thread, e.g. in the form of shredded old tires Art, in particular, the sound insulation is increased, with an additional one if textile thread is present mechanical reinforcement is achieved. Examples of organic binders are latex, polyester, Phenolic resins, melamine resins, polyimides, polyurethanes or the like. In question.

A particularly advantageous embodiment of the building material according to the invention consists in that the mixture 8-50 wt .-%, preferably 12-40 wt .-% contains an organic binder. A building material of this composition has the advantage of being more mechanical Strength, while at the same time achieving excellent properties in terms of sound insulation IQ can. However, the thermal insulation can be said to be good even with such a high proportion of the binder.

If the perlite is surrounded on all sides by the binding agent, a particularly favorable small structure is created in the component obtained so that high strengths can be obtained.

If the organic binder is in unfoamed form, the individual components of the The building material is particularly strongly bound to one another and at the same time the building material can be produced easily, since no complex devices are required.

If the organic binder is a urea-formaldehyde resin, particularly good wetting of the enables individual components, whereby the building material can be produced particularly easily and at the same time has high strengths.

In order to increase the mechanical strength of the building material, reinforcement inserts can be used in the mixture be provided, wherein fibers, preferably inorganic nature, z. B. off Glass, asbestos or the like, but also nonwovens, fabrics and grids have proven particularly suitable.

The invention will now be explained in more detail below with the aid of examples.

Example 1: Perlite, polystyrene and expanded clay were mixed dry according to the recipe below, after which an intimate mixing was carried out with the resin and the hardener. This mixture was then introduced into a suitable mold, heated about 2 '/ ₂ hours at about 120 C. The building material was then shaped. The determination of the resistance to fire and heat was carried out in accordance with DIN 4102 and 4108.

Perlite 5.61 wt .-% Grain size up to 6 mm 13.38 in Polystyrene 1.31 Grain size 2-6 mm 0.99 Expanded clay 5.6 1 Grain size 7-12 mm 58.66 55 Urea formaldehyde resin 0.75 water I 16.60 Ammonium chloride 15 g 8.54 water 60 g 0.40 60 Heating time 1.57 Clearing weight, g / cm ³ 2.5 hours Fire resistance O ₂ J100 Compressive strength, kp / cm ² 150 ⁰ C 65 8.1

The following building materials were manufactured analogously to Example 1,

5 2.5 Wt% X ' Wt% 0.338 ⁰ C Wt% 23 3 08 8th Wt% 13th 2.5 Wt% 340 - Wt% 0.536 9 14th 2 1.6 Wt% 5 6th Wt% - Wt% 0.486 6th Wt% 0.552 11th X 0.479 16 2.5 X 11.72 34.3 ISO Examples 33.5 29.4 16.65 11.06 150 ⁰ C 24.4 10.55 0.478 1 28.0 150X 9.19 150 150 Examples 12th 5.61 11.01 5.21 1 11.01 5.01 4.41 150 C 4.41 10.01 5.51 Examples 0.76 7th 3.8 4.29 2.7 2.44 4th 1.53 2.43 2.52 10.6 1.5 2.21 Wt% 2 9.11 1.31 Wt% 3.01 2.61 3.01 2.61 3.81 Wt% 3.81 4.51 Wt% 1.31 11.34 Perlite 51.78 10.01 10.40 5.01 49.22 45.68 9.54 40.38 25.2 Grain size up to 6 mm 5.61 38.1 3.01 - 5.61 41.4 55.8 44.4 4.31 43.1 4.31 1.06 Polystyrene 21.80 3.01 0.60 1.81 5.21 2.51 23.30 2.41 5.01 1 25.40 1.83 29.70 1.81 4.45 5.51 Grain size 2-6 mm 1.31 19.6 38.11 1.51 21.42 17.8 23.3 1.13 22.1 1.51 Expanded clay 11.34 0.9 - 46.20 0.98 0.781 5.01 12.04 1.171 1.17 12.82 1.02 15.40 '(, 17 1 50.40 Grain size 7-12 mm 5.61 0.53 1.201 3.5 19.6 36 g 4.1 9.16 0.50 48 g 4.3 0.61 150 g 4.28 40.00 0.70 36 g 42.9 Urea- 2.12 0.92 30 g 26.20 150 g 0.436 0.43 1.121 2.22 192 g , 540 23 g 2.42 30 g 2.78 150 g 22.80 Formaldehyde resin 1.121 Hours. 3.58 120 g 16g 1.72 0 24 g 91g 30.20 120 g 22.2 24 g water 0.545 24 g - 13.56 64 g Hours. 94 g - 1.02 94 g 11.70 Ammonium chloride 150 95 g 22 g 0.61 23 g 15th 15.70 4.22 0.55 water 23 g 21 88 g 2.46 91g Wt% 0.62 2.15 Heating time 91g - 2.5 hours 10.82 5.01 g 2.48 Hours. Volume weight, g / cm ³ 0.630 2.5 hours Fire resistance 2.19 10 2.61 Compressive strength, kp / cm ² 27.5 11.0 48.20 5.01 1.51 Perlite 23.70 1.81 Grain size 0-6 mm Polyurethane 12.24 1.81 hard foam granulate 0.58 31g Grain size 5-15 mm 2.27 124 Urea- 5 hours 36 g Formaldehyde resin water Ammonium chloride water Volume weight, g / cm ³ Fire resistance Perlite Grain size up to 6 mm Polyurethane hard foam granulate Grain size 5-15 mm Expanded clay j grain size 7-12 mm ί urea J formaldehyde resin ; water Harder water Heating time

7th Wt% 0.355 Weight - ⁰ /. 23 08: 13th Wt% 8.01 18th wt .-% 340 Wt% 19th Wt% 8th 15th Weight% 20th Wt% 16 Wt% 21 Wt% - - 150 ⁰ C 5.01 11.22 3944 g 5.01 9.36 7.661 6.41 15.27 7.451 6.41 13.49 7.741 6.41 12.1 continuation Examples - 0.495 3851g 4775 g 4410 g 12th Examples 4.01 3.50 150 ⁰ C 4.01 2.88 0.499 0.640 - - 0.570 - 17th 8.1 14th 150 ° C 150 ° C 21.9 27.5 10.6 GR 4.51 44.90 4.51 37.10 5.51 58.40 5.51 51.34 5.51 46.0 weight Volume weight, g / cm ³ 1.171 24.6 1.81 31.40 0.721 16.10 1.08 i 21.40 1.441 25.5 Fire resistance Compressive strength, kp / cm ² 12.82 16.20 8.34 11.05 13.0 24 g 0.59 31g 6.64 15 g 0.40 22 g 0.52 29 g 0.67 94 g 2.36 124 g 2.52 58 g 1.53 87 g 2.31 116 g 2.43 2.5 hours 2.5 hours 2.5 hours 2.5 hours 2.5 hours Perlite 6.851 7.251 7.45 1 7.151 7.451 Grain size up to 6 mm 3919 g 4631g 3608 g 3884 g 4219 g Polyurethane 0.577 0.639 0.485 0.542 0.566 hard foam granulate 150 ⁰ C 150 ° C 150 ⁰ C 150 ° C 150 ° C Grain size 5-15 mm 10 Resin outflow 8.7 11.9 19.9 Expanded clay Grain size 7-12 mm Urea- Formaldehyde resin water Harder water Heating time GR weight Volume weight, g / cm ³ Fire resistance. Compressive strength, kp / cm ²

Perlite grain size up to 6 mm expanded clay grain size 7-15 mm urea-formaldehyde resin Water hardener water heating time GR

Volume weight, g / cm ³ fire resistance

Examples Wt% 23 Wt% 24 Weight - ⁰ , 22nd 18.6 23.2 20.3 41.8 9.01 34.2 9.01 30.0 8.01 24.0 3.01 26.1 3.01 30.5 4.01 12.32 1.081 13.4 1.441 15.5 1.081 0.57 0.63 0.75 2.81 22 g 2.47 29 g 2.92 22 g 2.5 hours 87 g 2.5 hours 116g 2.5 hours 87 g 3331g 3541g 3715 g 0.443 0.503 0.489 above 150 ° C above 150 ⁰ C above 150 ° C

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Examples Wt% 26th Wt% 27 Wt% 25th

Perlite 12.01 1086 g 48.32 12.01 1086 g 34.28 12.0 1 1086 g 26.2 Grain size up to 6 mm Polystyrene 1.41 35 g 1.66 1.41 35 g 1.14 1.41 35 g 1.97 Grain size 2-6 mm Urea- 0.821 695 g 30.80 1.481 1256 g 39.60 2.161 1930 g 44.2 Formaldehyde resin water 355 g 15.84 646g 20.20 940 g 22.7 Harder 17g 17 g 0.80 30 g 30 g 0.95 43 g 43 g 1.06 water 66 g 66 g 2.55 118g 118g 3.73 172 g 172 g 4.34 Heating time TCC * ^
£.) J LHU 1 CO * ,!
£. ^ J LJtU. OC Dt-J
£ .- ^ J JIU Volume weight, g / cm ³ 0.222 0.390 0.434 Compressive strength, kp / cm ² 12.5 18.8 Fire resistance 120 ⁰ C 150 ° C

Examples Wt% 29 Wt% 30th Wt% 28

Perlite 10.81 31.58 9.51 28.51 9.51 21.68 Grain size up to 6 mm Polystyrene 2.71 2.19 4.11 3.42 4.11 2.63 Grain size 2-6 mm Urea- 1.481 40.60 1.481 41.60 2.161 46.40 Formaldehyde resin water 20.90 21.31 23.90 Harder 30 g 0.96 30 g 1.41 43 g 1.69 water 118 g 3.81 120 g 3.90 172 g 4.34 Hftizzeit 2.5 hours 2.5 hours 2.5 hours GR 6.821 6,981 7.651 Raumi; e weight, g / cm ³ 0.417 0.382 0.412 Compressive strength, kp / cm ² 18th 16 17th Fire resistance 150 ° C 150 ⁰ C 150 ° C

The building materials according to the invention have a particularly high frost resistance. All the building materials listed were subjected to the following test: The building material was immersed in water and, after it was completely soaked, removed from the water and stored at -20 ° C for 3 days. The building material was then quickly ^{heated to 60 °} C. and dried. The mechanical properties corresponded to those of the components that were not subjected to a frost test

were subjected.

Despite the high frost resistance, however, it may be desirable at the same time or after manufacture

of the building material this with an outer layer, z. B.

made of Ilart-PVC or a plaster, for example with

vinyl alcohol, phenolic resin, polyester or the like.

Claims (7)

Patent claims: 1. Building material made of porous inorganic material and, if necessary, plastic foam, both in lumpy form, which with an organic binder, in particular urea-formaldehyde resin, are held together, characterized in that the mixture of A) 5 to 60, preferably 10 to 30% by weight of a first porous inorganic material such as perlite, vermiculite, foam glass waste, with a bulk density below 0.25, preferably below 0.15 g / cm ³ , and a grain size below 10 mm, preferably less than 8 mm, and B) a) 15 to 80, preferably 20 to 50% by weight a second porous inorganic material, such as pumice, expanded clay, foam cement waste, with a bulk density of more than 0.25, preferably more than 0.50 g / cm ³ ? n and / or b) 0.5 to 5, preferably 1 to 5% by weight of a plastic foam with a volume weight from about 8 to about 100, preferably from 10 to 40 g / l, and optionally r> C) up to 40% by weight rubber granules, preferably in a mixture with textile thread and the organic binder. 2. Building material according to claim 1, characterized in that the foamed plastic is polyurethane foam, is preferably rigid polyurethane foam, 3. Building material according to claim 1 or 2, characterized in that the second inorganic material Expanded clay with a grain size over 2 min, preferably between 7 and 15 mm is provided 4. Building material according to one of claims 1 to 3, characterized in that the mixture is 8-50 Contains% by weight, preferably 12-40% by weight, of an organic binder 5. Building material according to one of claims 1 -4, characterized in that the perlite Jiseite of Binder is surrounded. 6. Building material according to one of claims 1 -5, characterized in that the organic binder is in unfoamed form 7. Building material according to one of claims 1-6, characterized in that reinforcement inserts in the mixture are embedded.