DE2308340A1 - BUILDING MATERIAL - Google Patents

Description

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

So z. B. in the French Patent specification No. 1,520,239 proposed to bind a granulate of foamed polystyrene with cement, sand and optionally synthetic resin, and it is also proposed to be relatively heavy

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inorganic foamed materials, such as. B. to add pumice or expanded clay, which are known to have bulk weights over 250, mostly 500 to 1000 kg / nr. 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 Bind relatively difficult, even when porous inorganic materials are added which, however, have the aforementioned, relatively high bulk weights for lightweight aggregates. In addition, polystyrene is very difficult the preparation of the wet concrete of the binder mixture at ', and must therefore optionally substituted with ^one: coating of a suitable material, eg. B. of organic silicon compounds are provided.

Efforts have now been made to eliminate these disadvantages. For example, it is proposed in French Patent No. 1,421,400, perlite, a very light porous inorganic material, optionally mixed with particles of foamed polystyrene, with the aid of an organic binder, such as. B. phenolic resin to be processed into moldings. The essential question Aehr the proportions of the individual components of the mixture is in this case, however, only very generally handled by namely preferably 70 to 97 * 5 wt -.% Of the mixture of perlite (including where appropriate the Kunstschaumteilchen) are made.

According to the invention, however, a building material is now proposed, the off

A) from about 5 to about 60, preferably 10 to 30 wt -.% Of a first porous inorganic material with a bulk weight of less than 0.25 »g'cm preferably less than 0.15, and a KorngröBe below about 10 mm, preferably less than 8 at the , and , '

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B) a) about 15 to about 8o, preferably 20 to 50 wt -.%

a second porous inorganic material with a bulk density above 0.25, preferably About 0.50 g'cnr and'or

b) about 0.5 to about 10, preferably 1 to 5 wt -.% of a plastic foam with a density of about 8 to about 100, preferably from 10 to 4o g'l, and optionally

C) up to about 40 wt -.% Rubber granules, preferably in admixture with textile thread

and the organic binder.

As the first porous inorganic material with a debris weight under 0.25 g ^ cnr have aggregates such as Perlite, vermiculite, or foam glass waste have proven to be useful. As can be seen, it turned out that smaller amounts of this light, inorganic expanded material can suffice than has hitherto been the norm. Since building material mixtures are made of perlite only with an organic binder, and therefore very high perlite proportions for various reasons than not As can be seen, the combination according to the invention with a second foamed one has proven to be very useful Suggested aggregate.

Either a second porous inorganic material with a bulk density is used as such an additive over 0.25, preferably over 0.50 g'cnr, how z. B. pumice, expanded clay, foam cement waste or the like., especially if you aim for greater stability and fire resistance of the building material. On the other hand, can Granulated plastic foam can also be used as a second aggregate, especially when the Demands for lighter and therefore better insulating

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Elements at the forefront. Here, however, the quantity ratio of the aggregates has again changed highlighted as particularly significant.

The first light, porous inorganic material as an essential component for well insulating and nevertheless relatively stable and also heat-resistant elements should not be used in an amount below about 5 », better not below 10 wt .- #, since otherwise these desired effects would hardly be significant can enter. On the other hand, it has been shown that light inorganic additives in quantities of more than about 60, and in most cases more than 30 Gevr .-% either result in insufficient bonding or the better properties that result from the addition of synthetic foam Particles and / or slightly heavier inorganic porous material are to be achieved, are not feasible. Analogously similar conditions apply to the specified proportions of the second heavier and thus more solid porous inorganic material. An expanded clay with a grain size between about 3 and 20 mm, preferably between about 7-15 mm, has proven to be particularly favorable.

Finally, but especially the amount of plastic foam has proven to be meaningful, the technical and economic effectiveness of the addition of plastic foam with smaller amounts added than 0.5, so often even at levels below 1 percent - is no longer guaranteed% of the total mixture.. On the other hand, is carried out with addition amounts of 10 mostly already with such About 5 wt -.% Of such a rapid decrease of such materials generally required property levels that lie outside these limits building material compositions have proven to be extremely inconvenient.

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The foam plastic used is, for example, polyurethane, preferably a rigid polyurethane foam for use. Polyurethane foams are great chemically and also thermally resistant, so that a building material that contains polyurethane foam is subjected to higher stresses can without causing a destruction of the building material. One then becomes foamed polystyrene particles use if the building material is not subjected to major thermal loads.

The building material as mentioned as further additive up to about kO wt -.% Rubber granules, preferably in admixture with textile thread, z. B. contained in the form of shredded old tires. In particular, the sound insulation is increased by aggregates of this type, with additional mechanical reinforcement being achieved in the presence of textile thread. Suitable organic binders are, for example, latex, polyester, phenolic resins, melamine resins, polyimides, polyurethanes or the like.

A particularly advantageous embodiment of the building material according to the invention is that the mixture contains about 8-50 wt .-%, preferably about 12-4ö wt .- % of an organic binder. A building material of this composition has the advantage of higher mechanical strength, while at the same time excellent sound insulation properties can be achieved. 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 xlein structure is obtained in the component, sodaQ high strengths can be obtained.

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

If the organic binding agent is a urea-formaldehyde resin, a particularly good wetting of the individual components is made possible, whereby the building material can be manufactured 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 provided in the mixture be, wherein fibers, preferably inorganic nature, z. B. made of glass, asbestos or. Like. But also fleeces, fabrics and grids have proven to be 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 placed in a suitable mold and heated at about 120.degree. C. for about 2 1/2 hours. The building material was then shaped. The determination of the resistance to fire and heat was carried out in accordance with DIN 4102 and 408.

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liter Weight % Perlite
Grain size up to 6 mm 5.6 13.38 Polystyrene
Grain size 2-6 mm 1.3 0.99 Expanded clay
Grain size 7-12 mm 5.6 58.66 Urea formaldehyde resin 0.75 16.60 water 8.54 Amtnonchlorid 15 gr. 0.40 water 60 " 1.57. Heating time 2.5 hours Density g / cmr 0.300 Fire resistance 150 ° C

Compressive strength kp / cm

8.1

The following building materials were manufactured analogously to Example 1,

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Perlite example -% example 3 2, Weight % - 27.5 8th 0, Weight -% , 436 example 0 _. Weight c , 0 0 Weight J 06 example 4th -. Weight -% , 0 0 Weight % example 4th Weight 52 , 0 0, Weight -% Grain size 0-6 mm 2 72 . O, 10.40 example 29.4 0, 11 I50 ^C 24, Oj 10.55 28.0 9, 25th 19th Polyurethane Ltr. Ltr 6th 0 4th 5 53 5 8th 6th 8th C. 15th Perlite rigid foam 5.6 11, 76 5, 0.60 Ltr Ltr. 1, ., 6 , 0 Ltr. 2.52 , 5 Ltr. 2, , 5 21 Grain size up to 6 mm granules 3 11 2.7 5, 0 example 2, 22nd 4, 3 1.5 4, 3 4th Polystyrene Grain size 5-15 mm 1.3 0, 78 1, 46.20 0 1] 49, 45.68 40, example 38 Grain size 2-6 mm ' Urea formal 6th 2, 12th 9 , 4 30th 3, 13th ,8th 3, 5 '8th. Expanded clay dehyde resin 5.6 51, 80 5, 26.20 3, 41.4 23, Ltr. 44, 25.40 43.1 29 11 42 70 Grain size 7-12 mm V / ater 5 8th 5, 11 04 4, 4, Ltr. Urea formal Ammonium chloride 1.12 21, 34 1, 13.56 21.42 Size 12, Size 23, 50 Size 12.82 Size 22.1 Size 15, 10. Size 22nd 40 dehyde resin Water ,
Density g / cm 53 0.61 1, 0.98 1, dd 0, dd 1, 22nd dd 0.61 dd 1.02 1, dd 0, dd 1 70 water Fireproof 11 12th Size 2.46 Size 4.1 2, 3 4, 2.42 4.28 ___ 2, 4th 78 Ammonium chloride kc It 23 size 0, _# 30th dd 5 hours dd , 540 , 486 0.5 4th 479 water 91 "2, 120 630 36 23 536 23 , 478 30th t ^ heating time, 2.5 hours 150 91 2 C. 91 ^150w C 120 150 0 C o Volume weight g / cnr 0, ^ 45 ISO ⁰ C 1 io fire-resistant °° speed 150 ⁰ C 48 10.6 "Compressive Strength 192 example 36 ^ k p / cm 21 -% 150 O
-3 example -% 4th 10 .-% CD
-4 7th 3 Ltr. , 2 Ltr. 11 10.0 34, 43 8th , 45 1 3.0 3, 4th 1 , 9 3 1 1.20 38, 6th 17th , 2 9 3 , 02 19 5 36 , 22 24 Gr 0, 150 95 "3, 0.338 η 150 C

Perlite example Weight % 3.58 0.355 example , 2 16.65 example , 0 10.82 example example Weight % Grain size up to 6 mm 12th 33.5 15th 16 5 11.34 Polyurethane Ltr. 150 ⁰ C 13th 14th Ltr. Wt. % Ltr rigid foam 9.1 - Ltr. Wt. % , 6 2.44 Ltr. Wt. % , 6> 2.19 5.0 9.54 5, granules 4.29 5 5 3 1.06 Grain size 5-15 mm Expanded clay 3.0 , 2 55.8 , 0 48.20 2.6 1.83 1, Grain size 7-12 mm __ 2 2 5 50.40 Urea formal , 78 17.8 , 17 23.70 dehyde resin 38.11 5.0 40.00 5, 17 22.80 water - 5 9.16 5 12.24 Harder 1.1 19.6 Size 0.43 Gr 0.58 1.8 30.20 1, 11.70 water 22 Gr 0.92 0 1.72 1 2.27 Gr 0.55 Heating time 88 " 2.5 hours 2.5 hours 15.70 2.15 CJ GR 8.0 ltr. 7.66 ltr. 31 Gr 0.62 24 2.5 hours ο Weight 1, 16 3944 gr 24 3851 gr L24 "2.48 94 7.74 ltr CD Volume weight g / cnr __ 64 0.495 94 0.499 2.5 hours 4410 gr OO Fire resistant 7.45 ltr. 0.570 CJ speed 150 ⁰ C 150 ⁰ C 4775 gr «* 3 Compressive strength
kp / cm 8.1 21.9 0.640 O 10.6 «J 150 ⁰ C CD
«J 27.5

■ ! CO Perlite Example] 0 2.5 Jew. -% Size 0.577 C. example example 19th Weight % example - - Weight % example I. O Grain size up to 6 mm 1? 11.22 18th 4 15.27 20th 5, 4 13.49 21 M. co Polyurethane Ltr 150 Ltr. Wt .- # Ltr Ltr Ltr. Wt. % C. 00 rigid foam 5, 0 10 5.0 9.36 6, 6, 1, 6.4 12.1 I. granules 3.50 - __ - "- - ^ Grain size 5-15 mm O Expanded clay 4, 5 4.0 2.88 - _ - - 22nd - - —_ __ 797 Grain size 7-12 mm 44.90 5 58.40 87 5 51.34 Urea formal 17th - - __ dehyde resin 4, 24.6 4.5 37.10 5, 72 16.10 08 21.40 5.5 46.0 water Harder 1, Size 12.82 1.8 31.40 0, 8.34
Size 0.40 11.05 1.44 25.5 water Il 0.59 1.53 Gr 0.52 Heating time 2.36 16.20 2.5 hours 2.31 13.0 ' GR 24 Hours. 31 Gr 6.64; 15th 7.45 ltr. 2.5 hours 29 Gr 0.67 Weight -x
Volume weight p; / cnr 94 6.85 ltr. 124 "2.52 58 3608 gr 7.15 ltr. 116 "2.43 Fire resistant 3919 2.5 hours 0.485 3884 gr 2.5 hours kcit 7.25 ltr. 0.542 7.45 ltr. Compressive strength
kp / cm 4631 gr 150 ⁰ C 4219 gr 0.639 8.7 150 ⁰ C 0.566 11.9 150 ⁰ C 150 ⁰ C Resin outflow 19.9

Example 22 example
23

example
24

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

Ltr. Wt .- # Ltr. Ge v / , 2 Ltr. -% 0 8.0 18.6 9.0 2Y ,1 9 »0 20.3 5 4.0 41.8 3.0 34 , 4
, 63
, 47
• 3.0 30, 5
75
92 1.08 24.0 1.08 26 1.44 30, 12.32
22 gr 0.57
87 "2.81
2.5 hours
3331 gr 13th
22 Gr 0
87 "2
2.5 hours
3541 gr C. 15,
29 size 0,
116 "2,
2.5 hours
3715 gr 0.44? 0.503 0.489 above 150 ° C over 150 ° above 150 ° C example example example 25th 26th 27

Ltr. Gr wt. % , Ltr. Gr weight % 12.0 IO86 48.31 12.0 IO86 34.28 12.0 IO86 26.2

Perlite grain size up to 6 mm Polystyrene 1.4 35 1.66 grain size 2-6 mm Urea-For- 0.82 695 30.80 maldehyde resin

Water 355 15.84

Hardener 17 grams of water 66 "1.4 35 1.14

1.4 35 1.97

1.481256 39.60 j 2.16 1930 44.2

20.20

940 22.7

Heating time

Volume weight g / cnr Compressive strength kp / cm Fire resistance

2.5 hours 0.222

120 ° C 0.80; 30 Gr 30 0.95 ^! 43 Gr 43 1.06 2.55H8 "118 3.73 172" 172 4.34

2.5 hours
0.390

12.5

2.5 hours 0.434

18.8

150 ⁰ C

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example example 5ew .- # example 28 29 28.51 30th Ltr. / Weight .- $ Ltr. ( Ltr. Wt. % Perlite 10.8 31.58 9.5 3.42 9.5 21.68 Grain size up to Dulul
Polystyrene 2.7 2.19 4.1 4.1 2.63 Grain size 2-6 mm 41.60 Urea For 21.31 maldehyde resin 1.48 40.60 1.48 1.41 2.16 46.40 water 20.90 3.90 23.90 Harder 30 gr 0.96 30 gr Hours. 43 Gr 1.69 water 118 "3.81 120 " Ltr. 172 "4.34 Heating time 2.5 hours 2.5 2.5 hours GR 6.82 ltr. 6.98 7 * 65 ltr. Volume weight g / cnr 0.417 0.3 & 0.412 Compressive strength
kp / cra lo 16 17th Fire resistant speed 150 ° c I50 150 ° C.

The building materials according to the invention have a particularly high Frost resistance. All listed building materials were subjected to the following test: The building material was immersed in water submerged, and after complete soaking, removed from the water and stored at -20 C for 3 days. Then the building material was quickly heated to 60 C and dried. The mechanical properties corresponded to those of the components, which have not been subjected to a frost test.

Despite the high frost resistance, however, it may be desirable at the same time or after the construction material has been manufactured this with an outer layer, e.g. B. made of hard PVC or a plaster, for example with an organic binder such as Melamine resin, polyvinyl alcohol, phenolic resin, polyester or the like. To be provided.

- patent claims -

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Claims (8)

Claims 1. Building material made of porous inorganic material and optionally Plastic foam, both in lump form, which pieces are held together by an organic agent, characterized in that the mixture of A) from about 5 to about 60, preferably 10 to JO wt -.% Of a first porous inorganic material having a bulk density below 0.25, preferably below 0.15 g crn ^, and a grain size of less than about 10 mm, preferably less than 8 mm , and B) a) about 15 to about 80, preferably 20 to 50 wt -.% a second porous inorganic material with a bulk density above 0.25, preferably above 0.50 g / cnr and 'or b) about 0.5 to about 5, preferably 1 to 5 wt .- # a plastic foam with a density of about 8 to about 100, preferably 10 to 40g / l, as well as, if applicable C) up to about 40 wt -.% Rubber granules, preferably consists in a mixture with textile yarn and the organic binder. 2. Building material according to claim 1, characterized in that the foamed plastic is polyurethane foam, preferably Rigid polyurethane foam is. 3 building material according to claim 1 or 2, characterized in that that as a second inorganic material bleached clay with «A grain size of about etv; a 2 nto, preferably between 7 and 15 mm is provided. 309837/0797 - lh - 4. The building material of any one of claims 1 to J>, characterized in that the mixture comprises about 8-50 weight -% of an organic binder -.%, Preferably about 12 - 40 wt.. 5. Building material according to one of claims 1-4, characterized in that the perlite is bound on all sides is surrounded. 6. Building material according to one of claims 1-5 »characterized» that the organic binder in non-foamed Form. 7. Building material according to one of claims 1-6, characterized in that the organic binder is a urea-formaldehyde resin. 8. Building material according to one of claims 1-7 »characterized in that that reinforcement inserts are embedded in the mixture. GERMAN SEMPERIT GESELLSCHAFT M.B.H. t, 309837/0797