RU2107703C1 - Petroleum-ground mixture - Google Patents

Abstract

FIELD: building of highways. SUBSTANCE: mixture comprises light dusty loam, hydrocarbon-containing component and water, petroleum slime being used as said hydrocarbon-containing component. Mixture comprises, mass %: light dusty loam, 100; petroleum slime, 10-23; water, 8-10. EFFECT: improved quality of desired product. 2 tbl

Description

 The invention relates to the field of road construction, in particular to compositions of materials of structural layers of pavement, and is intended for use in the construction of roads for the installation of frost protection layers, insulating layers, upper and lower layers of bases for advanced lightweight and transitional types of coatings, lower layers of bases for cement-concrete and asphalt-concrete coatings, for the device of coatings on temporary automobile roads.

 Known oil and soil mixtures for road construction on the basis of carbon-free soils that do not contain readily soluble salts. At the same time, well-known oil and soil mixtures, analogues of the claimed mixture, do not contain active additives of inorganic binders and differ in the type of soil that makes up their base, which can be represented by light sandy loam, light loam, heavy loam, sandy clay. Each well-known oil and soil mixture along with a certain type of soil from these contains a hydrocarbon-containing soil component - crude low-viscosity oil, as well as water [1].

However, low-viscosity crude oil, which is part of the well-known oil and soil mixtures for strengthening the soil, gives the indicated mixtures relatively low absolute values of the compressive strength (2.10 - 5.5 kgf / cm ² ).

 Having a low viscosity, the oil used in the known mixtures has a low adhesive bond strength, as a result of which the hydrophobized particles of soil are poorly bound by oil. As a result of this, the known oil and soil mixtures have low mechanical strength.

 At the same time, having a relatively high degree of hydrophobization as a result of soil consolidation with low-viscosity crude oil, the well-known oil and soil mixtures are practically applicable for road construction, but they have relatively low absolute water resistance indicators (water saturation of 3.6 - 4.0% by volume) and swelling (2.1-2.7%).

 The closest in combination of similar features and the proposed oil and soil mixture is an oil and soil mixture based on carbon-free soil, containing, by weight: light dusty clay loam-100, crude oil-7-10 and water-7-10 [2].

However, this known oil and soil mixture has a low compressive strength (2.2 kgf / cm ² ) also due to the low strength of the adhesive lubricant when bonding hydrophobized soil particles to the low-viscosity crude oil that is part of the mixture, and especially because of the negative effect of dusty particles of soil on the properties of soil already fortified with low-viscosity crude oil.

 This oil and soil mixture, having a relatively high degree of hydrophobization as a result of soil consolidation with low viscosity crude oil, also has practically acceptable values of water resistance and swelling indicators for road construction, but their relatively low absolute values due to the negative effect of dusty particles on the properties of fortified soil: water saturation 3.8% by volume and swelling 2.4% by volume.

 The aim of the invention is to increase the mechanical compressive strength, water resistance and reduce the degree of swelling of the resulting oil soil by increasing the adhesive and cohesive properties of the composition, while ensuring frost resistance of the oil soil.

This goal is achieved in that the known oil and soil mixture contains light dusty loam, a hydrocarbon-containing component and water, as a hydrocarbon-containing component contains oil sludge in the following ratio of mixture ingredients, parts by weight:
Light dusty loam - 100
Oil sludge - 10-23
Water - 8-10
The proposed oil and soil mixture differs from the known use of a different type of hydrocarbon component - oil sludge.

 The achievement of the specified technical result is ensured by the following. Due to the use of oil sludge in a mixture with light dusty loam, there is an increase in the activation of adhesion and cohesion processes to bind hydrophobized particles of soil, especially dusty particles, when it is strengthened with oil sludge due, apparently, to the formation of a new mixed coagulation-crystallization structure, thereby eliminating the negative influence of dusty soil particles on the physical and mechanical properties of the soil in terms of strength, water saturation and swelling is also the most negative.

 From the scientific and technical literature and patent documentation are not known oil and soil mixtures based on light dusty loam and using oil sludge in their composition, which allows us to consider the claimed technical solution as new.

 From the current level of technology it is not known that the use of oil sludge when strengthening soil in the form of light dusty loam, with a significant predominance of dust particles in the particle size distribution of the soil, clearly eliminates the negative effect of these soil particles on the physicomechanical properties of the strengthened soil, which occurs when the use of crude oil to ensure the technical result achieved by this technical solution, which consists in increasing the strength properties, stability and reduce swelling of the soil of the specified type. Therefore, the claimed technical solution has an inventive step.

 The invention is industrially applicable, since it is known to use oil and soil mixtures based on light dusty loam in road construction. In industrial conditions, grinding and mixing of soil with oil sludge, compaction and formation of oil and soil structural layers of pavement from the inventive oil and soil mixture can be carried out by mixing on the road using machines - road milling cutters and graders, mixing on the road and using soil mixing machines, as well as quarries using stationary or mobile mixing plants.

The proposed oil and soil mixture was tested in laboratory conditions. For its preparation, the following ingredients were used in accordance with the claimed method:
soil - light clay dusty loam of the following particle size distribution: sand particles — 37.6%, dust particles — 46.6% and clay particles — 15.8%. Soil moisture at the yield strength - 33.52%; soil moisture at the rolling border - 22.33%; optimal humidity - 16.7%. The number of soil plasticity is 11. The maximum soil density is 1.77 g / cm ³ ;
oil sludge is a waste from the production of oil at oil fields (bottom layer of the oil barn), which consists of centrifugation of a stable multiphase suspension - 58%, water - 20% and heavy oil residue with a high content of solids - 22%. The suspension of oil sludge includes solids-93.9 wt.% And the organic part of 6.1 wt.%, While solids, insoluble in hot hydrochloric acid, make up 76.0 wt.%, Soluble in hot hydrochloric acid - 17.9 wt.%. Insoluble solids are represented by sand, clay material, soluble solids are represented by ferrous salts - 155.5 mg / l and ferric salts - 139.5 mg / l. The organic part is represented by asphaltenes - 1.3 wt.%, Resins - 0.6 wt.% And paraffins - 4.2 wt.%;
technical (tap) water with a hardness of not more than 5 g-equiv / l.

 Example. Samples of the inventive oil and soil mixture with a different quantitative ratio of its constituent ingredients were prepared as follows.

The soil was dried to an air-dry state, its moisture was determined by drying the soil samples in a thermostat to a constant mass at a temperature of 105 ^o C. After that, oil and soil mixtures were prepared by mixing the soil of oil sludge and water, in appropriate quantitative proportions, without heating, for 5 min in a laboratory paddle mixer KP-118. In total, seven oil and soil mixtures were made. Data on the quantitative content of the ingredients in these investigated compositions of the inventive mixture are given in table 1. Then, samples of a size of 50.5 x 50.5 mm in a hollow metal cylindrical shape with two inserts for compaction of the mixture were made from each prepared oil and soil mixture. Samples were made from each mixture in a series of 3 pieces to determine each specific (one) indicator of the physicomechanical properties of the oilfield from the oilfield mixture. In the manufacture of each sample, the mixture in the form was placed under load for compaction at the rate of 300 kg / cm ² for 3 min on an IP-500 hydraulic press.

After compaction of the mixture, the mold with each sample was mounted on a special stand and the sample was squeezed out under pressure from the mold. All samples were kept in air at a temperature of +20 ^o C for 7 days. Then, on 3 dry non-saturated samples of 7 days old, aged at a temperature of +20 ^o C, each of the seven oil and soil mixtures tested oil soils for an indicator of compressive strength on an IP-100 hydraulic press. Then, 3 dry samples of 7 days of age of each oil and soil mixture were taken, placed in a thermostat and kept for 2 hours at a temperature of +50 ^o C. After that, these dry samples of oil and soil were tested for compressive strength on a hydraulic press -one hundred. The next series of 3 samples of each oil and soil mixture was subjected to capillary water saturation through a layer of wet sand in a bath with a hydraulic shutter for 3 days. The capillary water saturation index was taken as the amount of water absorbed by the sample, expressed as a percentage of the initial volume of the sample. Then, the compressive strength of water-saturated samples of oil soils was determined on an IP-100 hydraulic press.

 The swelling value of a subsequent series of 3 test samples of each oil and soil mixture was determined by the increment of the volume of each sample after capillary water saturation, expressed as a percentage, relative to its initial volume.

Then, a series of 3 samples of 28 days of age for each oil and soil mixture was taken and their frost resistance was determined at the end of 25 cycles of alternate freezing and thawing. Each cycle consisted of placing the samples in the freezer for 4 hours at a temperature of minus 20 ^o C, then immersing the samples in wet sand for 4 hours and placing the samples again in the freezer. After 25 cycles of freezing and thawing of oil samples, their compressive strength was determined on an IP-100 press.

 The coefficient of frost resistance was determined by the ratio of the compressive strength of samples that have passed the specified number of freeze-thaw cycles to the water saturation strength of 7-day-old samples before undergoing freeze-thaw cycles.

 Preparation of the proposed mixture in various experimental and claimed quantitative ratios of ingredients, production of samples from the mixtures obtained, capillary water saturation of samples, determination of the strength of dry and water-saturated samples under compression, determination of swelling and frost resistance of samples was carried out in accordance with the requirements of the current Instructions for the use of soils reinforced with cementitious materials , for the device of the bases and coverings of automobile roads and airfields. SN 25-74-M .: Stroyizdat, 1975.

 Data on the physicomechanical properties of oil soils obtained from the known and claimed oil and soil mixtures are given in Table 2.

The data of table 2 show that the inventive oil and soil mixture in comparison with the known oil and soil mixture has higher absolute values of the physicomechanical properties of the oil and soil obtained from it. These values correspond to the claimed composition of the oil and soil mixture with the following quantitative ratio of ingredients, parts by weight:
Light dusty loam - 100
Oil sludge - 10-23
Water - 8-10
Optimum is the following composition of the mixture, parts by weight:
Light dusty loam - 100
Oil sludge - 14
Water - 10
These quantitative ratios of the claimed composition of the oil and soil mixture provide, when using the invention, the achievement of the obtained technical result. This is expressed in the fact that the oil strength obtained from the inventive oil and soil mixture, in comparison with the oil soil from the known oil and soil mixture, the mechanical strength of non-saturated samples is 1.2-2 times higher, the mechanical strength of water-saturated samples is 1.9 - 3.8 times higher , water resistance is higher by 2.6-4.1 times, swelling is lower by 3 - 5.3 times. The inventive composition of the oil and soil mixture provides high frost resistance of the resulting oil soil (coefficient of frost resistance of 0.74-0.83). Such an increase in the physicomechanical properties of the oil soil in comparison with the known oil soil is achieved without the use of any inorganic active additives, such as cement and lime, in the inventive oil and soil mixture.

 The proposed oil and soil mixture is a material for producing an oil soil with higher physical and mechanical properties for use in various structural layers of road pavement - frost protection layers, upper and lower base layers, insulating layers, coatings.

Claims (1)

An oil and soil mixture containing light dusty loam, a hydrocarbon-containing binder and water, characterized in that the mixture contains oil sludge as a hydrocarbon-containing binder, which is a waste from the production of oil at the oil fields in the form of a bottom layer of an oil field barn, with the following components, wt.h. :
Light loam - 100
Oil sludge - 10 - 23
Water - 8 - 10o

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