RU2176653C2 - Hydroinsulating roofing material - Google Patents

Abstract

FIELD: building industry, particularly, hydroinsulation of underground structures, foundations and soft roofing materials. SUBSTANCE: hydroinsulating material is essentially mixture of petroleum slurry containing 60-80 wt.% of paraffins and ceresines and filler which is 0.1-1.0 mm clay fraction or clay filler dust, ratios of components being as follows: petroleum slurry, 50-65; and filler up to 100. Hydroinsulating material has higher water-protective properties and temperature fragility, thus making it possible to solve ecological problem of utilizing petroleum waste such as petroleum slurries. EFFECT: improved properties of the hydroinsulating roofing materials. 2 tbl

Description

 The invention relates to construction, namely to waterproofing materials, and can be used as waterproofing of underground structures, foundations and for soft roofing.

 Known waterproofing material - glassruberoid, including the base, impregnating and coating bitumen layers and mineral sprinkling (GOST 15879-93).

 The disadvantages of this material are high water absorption and low water resistance and fragility.

 Closest to the proposed material is a composition for the manufacture of roofing material (ed. Certificate. USSR N 808442, 04 B 26/26, 1981), including 65-70 wt.% Bitumen and 30-35 wt.% Silt.

 The disadvantages of this composition are high water absorption and low water resistance and fragility.

The proposed waterproofing material is a mixture of oil sludge containing 60-80 wt.% Paraffins and ceresins, and a filler, which is used as a clay fraction of 0.1-1.0 mm or expanded clay dust in the following ratio, wt.%:
Oil sludge - 50-65
Filler - Up to 100
Such a waterproofing material not only improves the waterproofing properties and fragility, but also solves the acute environmental problem of the disposal of oil waste - oil sludge.

 Oil sludge is a mixture of oil, oil products and oil distillation products collected during the treatment of sewage and sewage. These are heavy oil residues having different chemical composition depending on the technological scheme of oil refining and on technological losses in the chain.

This is a heavy viscous liquid with a density of 0.86-0.97 g / cm ³ , having a boiling point of 260-285 ^o C and 50-55% vol. Which boils at 360 ^o C. On average, their composition can vary within the range, wt. .%:
Petroleum products - 10-85
Water - 2-65
Mechanical impurities - 1-30
As petroleum products, they may contain paraffins, ceresins, resins, asphaltenes, aromatic hydrocarbons, acetone naphthenes and benzothiophenes.

Below are the compositions of the oil sludge of the Krasnodar Oil Refinery, which were accumulated in the 1st and 2nd quarters of 2000 (see table. 1)
Waterproofing roofing material is prepared as follows. Oil sludge and filler are placed in a container equipped with a drum or propeller type mixer and stirred at an elevated temperature of 60-95 ^o C for 20-30 minutes. The resulting mass is applied to the roof, foundation, floor or walls and dried at ambient temperature.

 Material quality tests were performed on a sample of roofing material measuring 50x100x10 mm.

 The high performance of waterproofing roofing material is illustrated by the following examples.

Example 1
55 g of oil sludge containing 70 wt.% Paraffins and ceresins and 45 g of 0.5 mm clay fraction were loaded into a drum-type container equipped with a stirrer and placed in a thermostat. With constant stirring, the temperature was raised to 75 ^° C at a speed of 50 ^° C per hour, and upon reaching 75 ^° C, stirring was carried out for 30 minutes. The mass was unloaded from the tank, cooled to room temperature and applied to the desired surface. The prepared sample was tested for water absorption, water resistance and fragility according to GOST 2678-94.

 The test results are presented in table 2.

Example 2
Waterproofing roofing material was prepared according to example 1 with the difference that they took 50 g of oil sludge containing 80 wt.% Paraffins and ceresins, and the clay had a grinding fraction of 1.0 mm

 The test results are presented in table 2.

Example 3
A waterproofing roofing material was prepared according to Example 1 with the difference that they took 65 g of oil sludge containing 60 wt.% Paraffins and ceresins, and the clay had a grinding fraction of 0.1 mm.

 The test results are presented in table 2.

Example 4
Waterproofing roofing material was prepared according to example 1 with the difference that claydite dust was taken instead of clay.

 The test results are presented in table 2.

Example 5
Waterproofing roofing material was prepared according to example 1 with the difference that they took 50 g of oil sludge containing 70 wt.% Paraffins and ceresins, and 50 g of expanded clay dust.

 The test results are presented in table 2.

Example 6
A waterproofing roofing material was prepared according to example 3 with the difference that the oil sludge contained 70 wt.% Paraffins and ceresins, and claydite dust was used instead of clay.

 The test results are presented in table 2.

Example 7 (comparative)
A waterproofing roofing material was prepared according to example 1 with the difference that the amount of paraffins and ceresins in the oil sludge was 58 wt. %

 The test results are presented in table 2.

Example 8 (comparative)
A waterproofing roofing material was prepared according to Example 1 with the difference that the clay grinding fraction was 1.5 mm.

 The test results are presented in table 2.

Example 9 (comparative)
Waterproofing roofing material was prepared according to example 1 with the difference that they took 45 g of oil sludge and 55 g of clay.

 The test results are presented in table 2.

Example 10 (comparative)
Waterproofing roofing material was prepared according to example 1 with the difference that they took 68 g of oil sludge and 32 g of clay.

 The test results are presented in table 2.

Example 11 (prototype)
A composition for the manufacture of roofing material was prepared by mixing 70 g of bitumen and 30 g of silt, heating the mixture to 165 ^° C and stirring for 40 minutes. The resulting composition was cooled and a test sample of 50x100x10 mm was prepared.

 The test results are presented in table 2.

 As can be seen from the data given in the table, the proposed waterproofing material has high quality indicators. However, these indicators are achievable only within the stated limits of the quality of oil sludge, the fraction of clay used and the ratio of components.

 So, for example, when the content of paraffins and ceresins in the oil sludge is lower than the declared limit (pr. 7), the resulting waterproofing material has high water absorption, low water resistance, and low brittle temperature. It should be noted that in the oil sludge was not observed the content of paraffins and ceresins of more than 80 wt.%.

 When using clay fractions above 1.0 mm (pr. 8), the resulting waterproofing material has a high brittle temperature, low water absorption and water resistance.

 When the content of oil sludge in the waterproofing material is lower than the declared limit (pr. 9), the indicators of water absorption and water resistance are reduced, and when the content of oil sludge is higher than the declared limit (pr. 10), no further improvement in the quality indicators is observed.

 Thus, the proposed waterproofing material has high quality indicators, and for cooking using cheap and common components. In addition, the use of such material will solve the problem of disposal of oil sludge.

Claims (1)

Waterproofing roofing material, including a viscous mass of petroleum origin and a filler, characterized in that as a viscous mass use oil sludge containing 60-80 wt.% Paraffins and ceresins, and clay of a fraction of 0.1-1.0 mm is used as a filler or expanded clay dust in the following ratio of components, wt.%:
Oil sludge - 50-65
Filler - Up to 100

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