DE2539660C3 - Insulating material - Google Patents

Description

The invention relates to an insulating material with a porous filler based on silica and bitumen and can be used to protect building structures against heat loss as a thermal protective layer of multilayered Protective panels as well as for thermal insulation of ceiling structures can be used. Farther the invention can be used to insulate refrigerators.

An insulating material according to the preamble is known from AT-PS 288947. From this it is known for thermal insulation layers bitumen and spherical clasparticles from broken glass or other silicic acid containing materials. According to US-PS 3354024 mentioned in AT-PS 288,947 wire? a mixture of e.g. B. borosilicate glass and soot crushed, wetted with a liquid binder, granulated and dried, an aqueous solution of sodium silicate being used as the liquid binder can be. The obtained substance is z. B. covered with a hydrate of alumina and subjected to a heat treatment at temperatures of 1575-1675 "C. The porosity of the granules is achieved by the swelling agent. As a result of heat treatment at high temperatures the granules produced by the process have a bulk density of approx. 6 (K) kg / m · ', whereby the End product becomes very heavy.

A number of insulating materials with a bituminous binder and porous fillers are also known. These include heat protection materials made from perlite and vermiculite bitumen, which are used to protect building structures and to insulate refrigerators. Expanded perlite and expanded perlite with a layer weight of 75 to 200 kg / m 2 serve as fillers. In particular, perlite bituminous materials on the basis of dellite with a maximum particle size of 3 mm and a layer weight of approx. 2 (K) kg / m 'have prevailed. For the production of 1 m 'of material, 1.5 to 2.3 m' of perlite and 150 to 2 (K) kg of bitumen are used. The high consumption of bitumen, caused by a large specific surface of the filler, reduces the useful life of the material and increases its weight. The material produced has the following properties:
Weight of

Products 250 to 450 kp, m '

Thermal conductivity 11.065 to 0.105 kciil m h (irail Flexural strength 1.5 to "" 0 kp απ '.

These parameters meet today's requirements in construction due to the high weight and the high coefficient of thermal conductivity, because it increases the thickness of thermal insulation and structural elements ■> must be.

The invention is based on the object of specifying an insulating material, the components of which by a low weight, a low coefficient of thermal conductivity and sufficient strength are characterized by being worn reduced by the weight and the coefficient of thermal conductivity of the insulating material while maintaining the strength values will.

The object is achieved in that expanded water glass granules with a bulk density of 40 to 80 kg / m ', an average particle size of 2 to 10 mm and a strength of 1 to 4 kp / cm ² are used as the porous filler, with the proportion of which in the insulating material mixture is 70 to 80 percent by weight and the proportion of bitumen is 30 to 20 percent by weight.

The insulating material according to the invention is characterized by a weight of 80 to 150 kp / m ', a coefficient of thermal conductivity of 0.04 to 0.06 kcal / m · h · degrees, a flexural strength of 1.5 to 2.5 kp / cm ² and a water absorption of max. 0.5%, based on the total weight. Accordingly, when replacing perlite with expanded water glass granules, the weight of the products based on a bitumen binder is reduced by 3 times and the coefficient of thermal conductivity by 1.5 to 2 times. The strength values are retained.

Other objects and advantages of the invention will become apparent from the following description of the insulating material and its production and can be seen from Ausführungsbcispiclc.

Expanded water glass granules are used as the porous filler of the insulating material according to the invention. It has been found that it is advantageous to use expanded waterglass granules with an average size of 2 to 10 mm, a layer weight of 40 to 80 kg / cm ² and a strength of 1 to 4 kg / cm 2.

The expanded water glass granules provided by the invention can be manufactured with the aid of known Process are produced. So you can, for example, the expanded water glass granules on the following Win way.

I. stage. A mixture of water glass and a filler, for example triple, lime, sodium fluorosilicate, is added dropwise through a network of aqueous calcium chloride and held until Drops of a layer form on the surface, preventing them from sticking together. The particles obtained are removed from the solution and dried at a temperature of 60 to 95.degree.

II stage. The dried particles are bloomed at a temperature of over 2 (K) "C until granules obtained with ilwn required properties will.

Natural Ivw. l-rdolln tiimina into consideration.

Research has shown that the cheapest (ichall of the constituents in (iew .- '/ f like it follows:

puffed Wassemlasgianalien 70 Itis SO

Bitumen M) up to 20.

In the "common conditions" they graze

Particles of the filler are coated with the binder, and after the binder has solidified, that wins Material has sufficient strength for formwork, transport and assembly. The addition of a The amount of bitumen that is less than 20% by weight leads to a sharp decrease in the strength of the Insulating materials. If the bitumen is added in an amount greater than 30% by weight, the weight increases of the products, and the heat protection properties deteriorate.

The manufacturing technology of the insulating material includes the following operations.

1. Preparation of the components: heating the bitumen to 150-180 ° C and the puffed Water glass granules at a temperature of 60 to 80 ° C.

2. Prepare a mixture from the mentioned ingredients.

3. Shapes.

When producing the insulating material, the temperature of the mixture should not be below 110 to 130 ° C. Here, the expanded water glass granules are enveloped by the bitumen binder. After this Forming, the insulating material solidifies as it cools down.

The insulating material produced according to this method has a weight of 80 to 150 kp / m \, a coefficient of thermal conductivity of 0.04 to 0.06 kcal / m · h - degrees and a flexural strength of 1.5 to 2.5 kp / cm ² .

Example I.

A mixture is prepared based on 64 kg of expanded water glass granules and 16 kg of spaces per 1 m ^{3 of} product. Samples of various dimensions are made from the mixture according to the technology mentioned.

The thermal conductivity of the insulating material obtained is 0.04 kcal / mh · degree, the weight is 80 kp / cm 'and the strength is 1.5 kp / cm ² .

Example 2

A mixture is prepared starting from 70 kg of expanded water glass granules and 20 kg of bitumen per 1 m 'of product. The mixture becomes musu

ster made. The coefficient of thermal conductivity is 0.04 kcal / m · h · degrees, the weight is 90 kp / cm ³ and the strength is 1.65 kp / cm ² .

Example 3

A mixture is prepared based on 76 kg of expanded water glass granules and 24 kg of bitumen per 1 m _{3 of} product. Samples are made from the mixture. The coefficient of thermal conductivity is 0.04 kcal / m · h · degrees, the weight 100 kp / m ³ and the strength 1.9 kp / cm ² .

Example 4

A mixture is prepared based on 82 kg of expanded water glass granules and 28 kg of bitumen per 1 m ^{1 of} product. Samples are made from the mixture and tested. The weight is 110 kp / cm ³ , the coefficient of thermal conductivity 0.045 kcal / m - h ■ degrees and the strength 2.0 kp / cm ² .

Example 5

A mixture is prepared based on 85 kg of expanded water glass granules and 30 kg of bitumen per 1 m ^{3 of} product. Samples are made from the mixture and tested. The weight is 115 kp / m ³ , the coefficient of thermal conductivity 0.045 kcal / m · h · degrees and the strength 2.1 kp / cm ² .

Example 6

A mixture is prepared based on 93 kg of expanded water glass granules and 37 kg of bitumen per 1 m ^{3 of} product. Samples are made from the mixture and tested. The weight is 130 kp / m ³ , the coefficient of thermal conductivity 0.05 kcal · h · degrees and the strength is 2.35 kp / cm ² .

Example 7

A mixture is prepared from 105 kg of expanded water glass granules and 45 kg of bitumen per 1 m ^{3 of} product. Samples are made from the mixture and tested. The weight of the insulating material is 150 kp / m ³ , the coefficient of thermal conductivity 0.06 kcal / m · h degrees and the strength 2.5 kp / cm ² .

Claims (1)

Claim: Insulating material with a porous filler based on silica and bitumen, characterized in that expanded water glass granules with a bulk density of 40 to 80 kg / cm ³ , an average particle size of 2 to 10 mm and a strength of 1 to 4 kp / cm ^{2 are used as the porous filler} can be used, the proportion of which in the insulating material mixture is 70 to 80 percent by weight and the proportion of bitumen is 30 to 20 percent by weight.