CH628568A5 - Process for producing cores for insulating materials and use thereof - Google Patents

Description

The present invention relates to a method for producing cores for insulating materials according to the preamble of independent patent claim 1 and to the use of the same according to the preamble of independent patent claim 6.

Since the appearance of foamed plastics (the popular name for this is polystyrene), various studies have been carried out to put these lightweight and heat-insulating materials into practice. As in many countries and institutes, these tests were also carried out in Korea. To date, however, no way has been found to use these materials in insulation materials. This is mainly for economic reasons, because the adhesives required (synthetic resin adhesive, natural adhesives, etc.), which are necessary for the adhesion between the heterogeneous foamed plastics and cement cubes, are expensive and mass production is impossible due to difficulties in production. Even with the adhesives mentioned, there are still some shortcomings, some of which are explained below:

The first deficiency arises from the fact that the slippery surface of the plastic particles cannot be covered with adhesive to the desired degree and the elasticity of the adhesive is greatly reduced and the inorganic, small particles that are attached to the plastic are only very thin overdrawn. This means that the surface layer is only slightly hard and can be damaged or detached as a result of friction or impact on the insulating material, even when it dries out or during transport.

Secondly, it takes a very long time to dry the insulation because the adhesive mentioned coats the cement particles and this prevents water (H20) and carbon dioxide (C02) from penetrating to and from the cement during drying.

Third, if the adhesive dries out, the cement mortar will contract and cause serious volume changes. These changes weaken the strength of the cement. Therefore, attempts have been made to mix the foamed plastic and the cement mortar without the adhesive as a binder. It turned out that this was impossible

Use mixture, except in a special case, because the strength of the scaffold was noticeably weakened due to the low vibration of the scaffold during drying.

All of the above facts were found in tests.

It is therefore an object of the invention to provide an insulating material in which the disadvantages mentioned are eliminated, which is lightweight and in which cheap materials can be used.

According to the invention this is achieved by the features in the characterizing part in independent claim 1. The use is characterized in claim 6.

Exemplary embodiments of the invention are explained in more detail below with reference to the drawing. It shows:

Fig. 1 shows a cross section through an insulation particle with a core made of plastic, an intermediate layer of clay and a coating of cement mortar, and

Fig. 2 shows a detail of a cross section through the particle on an enlarged scale, to illustrate the mixing between clay and cement mortar layer.

According to the proposal, the weakening of the framework mentioned above and the difficulties in production are remedied by using loam suspended in water in a ratio of 50-99% water to loam, according to the conventional method, without synthetic or natural glue and by directly applying this mass to the foamed plastic. The types of clay that show good viscosity and good adhesion are clays (such as ordinary clay, clays of clay, brick clay, kaolin, refractory clay, loess, clay, sea chalk, mixed clay, also «concrete», «latent»). In order to increase the hardness of the insulation material, small amounts of calcium hydroxide, sand, cement or sodium silicate are mixed into the clay. The minerals of the kaolinites, the montmorillonites and the illites, which are composed of small crystals like the components of the viscous clay, show a cohesion that corresponds to a state of equilibrium through the electrostatic attraction or the electrostatic repulsion of the atoms in crystal lattices, such as the ion binding, the covalent bond, the metallic bond and the Van der Waal forces. It is a characteristic of the invention to use the best application of the plasticity and adsorption inherent in the alumina which are viscous due to this cohesion.

According to plasticity theory, particle attraction is an old concept, but it was difficult to see why two particles with the same zero charge can attract each other. However, the diffuse double layer has indicated that an equilibrium distance between individual particles is possible; if they are closer than this, there is a repulsion, but if they are more apart, there is an attraction. It was later believed that Van der Waal's forces were the reason for the attraction between particles (F.H. Norton, Fine Ceramics Technology and Application, pages 140-141, edited by McGraw-Hill, 1970).

Adsorption: The surface of every solid is more active than its interior and therefore tends to attract not only ions but also molecules. In general, the larger and more complex the molecule or ion, the more it is attracted (W.E. Worral, Raw Materials, pages 34-35, edited by Maclaren and Sons Ltd., 1964).

It could be concluded from this that covering air-foamed plastic with cement mortar alone would be possible; Cement mortar coagulates with time, but has a low viscosity. That is why it is difficult to cement cement mortar on air-foamed plastic. Furthermore, its adhesion is destroyed and it is removed from the surface

10th

15

20th

25th

30th

35

40

45

50

55

60

65

3rd

628 568

surface of the plastic peeled off during a slight blow during drying or transport.

The results of adhesion experiments in which alumina and cement mortar cover the surface of air-foamed spherical plastic are as follows:

Trial 1

The surface of air-foamed, spherical plastic is coated with cement mass, which was produced by mixing 30 g cement and 18 g water, and with clay mass from a mixture of 30 g ordinary clay from Korea and 19 g water, and gradually it becomes with Cement mortar-coated surface of the plastic particles and the clay-coated surface of the plastic particles coated with another cement paste.

The cement may have viscosity properties during the coagulation process, but these viscosity properties do not give sufficiently firm adhesion to the surface of the plastics during the first hydration process, whereas the clay has a viscosity and adheres to the surface of the plastic during the first hydration process and therefore has excellent surface adhesion properties. The second coating of cement mortar on the surface of the plastic covered with clay was possible.

Trial 2

In order to prove the above experiment, viscosity tests of cement mass and clay mass were carried out (flow tests by H. Wagner) and adhesion tests were carried out in water. These gave the following results:

Viscosity test

H. Wagner flow test on a slope inclined at 45 °

Glass surface

Pattern flow length

Cement paste cement + water 17 cm

30 g + 15 cm3

Cement + water 33 cm

30 g + 18 cm3

Loam mass of clay + water 1 cm

30 g + 15 cm3

Clay + water 15 cm

30 g + 18 cm3

Adhesion test in water

Two types of air-foamed, spherical plastic particles were coated with cement mortar and clay, according to experiment 1, and were placed in water, the degree of detachment being observed. The cement mortar adhering to the plastic was removed as soon as it was immersed in water. With clay on the plastic, a slight detachment only appeared after about 10-20 minutes.

The above results of tests show that a clay mass with a high viscosity and water absorption property has an excellent adhesion to plastic.

Referring to Figures 1 and 2, air foamed plastic

1 covered with clay by means of known machines or immersed in clay, clay layer 2 was formed. If lightweight strength is required, combustible clay and, with a light weight and heat insulation properties, cement mortar is applied to the surface of the layer of noise 2 to form the cement layer 3.

Between the clay layer 2 and the cement mortar layer

3 a part of the cement mortar penetrates into the clay layer and thus the two layers are strongly mixed and form a solidified, mixed layer 4.

According to the procedure described above, the damage caused by using another adhesive, such as synthetic or natural adhesive, will be completely remedied. In addition, hardness and adhesive forces of adhesive intermediate layers are good. In addition, the manufacture and supply of insulation materials becomes cheap due to the use of clay as a mass, which is readily available and is available in quantities all over the world.

example 1

To produce a lightweight, heat-insulating material, 80 percent by weight of viscous clay, 10 percent by weight of cement powder, 4 percent by weight of sand, 4 percent by weight of calcium hydroxide and 2 percent by weight of sodium silicate were mixed with one another and a sufficient amount of water (about 60 percent by volume of the mixture) was added and mixed again until a paste formed.

Portland cement addition to the above paste prevents the loosening of the strength of the clay layer when water is absorbed, and calcium hydroxide also prevents the weakening of the strength by preventing excessive water adsorption. Sand and sodium silicate reduce shrinkage during drying. They can be used well in accordance with the viscosity of the clay.

The paste obtained by the above method was first applied to the surface of the air foamed plastic particles, e.g. by means of a dispersing machine, and then the clay layer was covered with cement mortar, either with the same or with a different dispersing machine. After curing, the end product (insulation material) was obtained.

Example 2

To produce a lightweight insulation material, 96 percent by weight of viscous clay was mixed with 2 percent by weight of sand and 2 percent by weight of sodium silicate and stirred with enough water (about 60 percent by volume) to form a paste. With this paste, a first coating was applied to the surface of air-blown plastic by means of a known dispersing machine, then combustible clay was applied by means of the same or another machine. After drying, the insulation material was fired.

Example 3

In order to make a viscous paste from clay with insufficient viscosity, clay with insufficient viscosity is mixed with fine, inorganic material, e.g. Kaolin, chalk, diatomaceous earth, calcium hydroxide, stone powder, coal ash etc., mixed with about 50% by weight clay with good viscosity, then enough water (about 70% by volume of the total mass) added and stirred, or 20% by weight cement and 4 percent by weight of sodium silicate was added and enough water (about 70 percent by volume of the mass) was added and mixed to form a paste.

This mass was applied to the surface of plastic.

Example 4

94% by weight of combustible clay, 4% by weight of calcium hydroxide and 2% by weight of sodium silicate are mixed and about 50% by volume of water, based on the mixture, is added to the mixture and a paste is mixed with it. After the surface of the plastic particles was covered with this paste, the mass was allowed to dry to obtain an insulating material.

Insulation materials made by the above procedure

5

10th

15

20th

25th

30th

35

40

45

50

55

60

65

628 568

have a state in which air is filled inside, and therefore they have elasticity such as car tires. Accordingly, these insulation materials are used in the end products similar to the iron bars and retain excellent strength.

In particular, the weight of these products is reduced by 20-30 cc of the total weight.

Manufacturing and transportation costs for these products are also lower due to the lower weight.

If products are made using these insulating materials, they have a lower adsorption rate in the presence of moisture, and they prevent a change in weight when building a structure to a high degree, even in heavy rain. Structural strength and poor weight distribution are prevented by uniformly mixing the insulation materials with cement mortar. Cracks in winter are avoided because surface condensation due to sudden changes in temperature in winter is prevented.

Destruction due to contraction and expansion is avoided by the elasticity of the insulating material. The efficiency in terms of thermal insulation properties is high, which means that fuel can be saved for heating in cold regions in winter and electricity for air conditioning systems in summer or in warm areas. Sealing materials against water, such as cement, sand, gravel and concrete iron, can be saved in buildings according to the insulation material used. Because the proposed insulation dampens vibrations, no silencers are required. In buildings that are built using these insulating materials, the heat flow between the interior and exterior of the room is interrupted, and they have a good damping efficiency and are therefore good for health.

The result of compression tests on cement bricks made using these insulation materials is as follows:

Class A

Cement mortar made by mixing cement and sand at a mixing ratio of 1: 4 and adding water was mixed with 40% by weight of insulating material. This mixture was then molded to form bricks and was then dried. The average weight of a brick was 1.8 kg (the average weight of common bricks is 2.4 kg) and thus a weight saving of 25'V in total weight was achieved.

class B

Cement mortar, produced by mixing cement and 10 sand in a ratio of 1: 7 and adding water, was mixed with 50% by weight of insulating material, the insulating material not being cured. Bricks were formed with the mixture and hardened. The average weight of a brick was 1.6 kg instead of 2.4 kg for ordinary 15 bricks, so a weight saving of 35% was achieved.

Test data

Test institute: National Construction Laboratories of Korea 20 Subject: cement bricks made of insulating material according to the invention.

Sample No. Sample size Break load cm Compression force kg / cm2

Class A

Br-1

21 x 9.8 x 5.9

99

Br-2

21.1 x 10.2 x 5.8

88

Br-3

21.1 x 9.9 x 5.8

124

Br-4

21 x 10 x 5.9

123

Br-5

21.1 x 9.9 x 5.9

153

class B

Br-1

20.7 x 9.7x5.9

34

Br-2

20.8 x 9.7 x 6.1

29

Br-3

20.7 x 9.9 x 5.8

3't

Br-4

20.9 x 9.8 x 5.9

36

Br-5

20.6 x 9.8 x 5.9

59

1 sheet of drawings

Claims (6)

628 568 1. A process for the production of cores for insulating material from a lightweight filler, characterized in that air-foamed spherical core material is coated with a liquid adhesive mixture, which adhesive mixture contains 50-99% viscous clay and water. 2. The method according to claim 1, characterized in that the adhesive mixture contains 0-30% Portland cement, 0-6% sand, 0-10% calcium hydroxide and 0-4% sodium silicate. 2nd PATENT CLAIMS 3. The method according to claim 1, characterized in that a fine inorganic material, such as kaolin, chalk, diatomaceous earth, calcium hydroxide, stone powder, coal ash, is present in the adhesive. 4. The method according to any one of claims 1-3, characterized in that the coated cores are coated with combustible clay and fired. 5. The method according to any one of claims 1-3, characterized in that the coated cores are covered with a cement mortar mixed in the ratio cement: sand = 1: 3 to 1: 6. 6. Use of the cores produced by the method according to claim 1 for heat-insulating lightweight building panels in buildings.