RU2262035C1 - Method of transfer of viscous oils and petroleum products - Google Patents

Abstract

FIELD: oil producing industry; oil refining industry; petrochemical and chemical industries; transportation of high-viscosity Newtonian and non-Newtonian liquids via pipe lines.

SUBSTANCE: proposed method includes forming coaxial concentric layer of water at inner surface of pipe by adding water to oil and setting the oil and water flows in rotary motion effected by bladed mixers mounted after sections where velocities of flows change by magnitude or direction at angular velocity determined by the following formula:

where ω is angular velocity of bladed mixer rotation; g is free fall acceleration and R is radius of pipe line.

EFFECT: reduction of hydraulic resistance and power requirements due to forming rotary motion of flows behind sections where their velocities change in magnitude or direction.

1 dwg

Description

The proposed solution relates to methods that reduce hydraulic resistance during transportation of high-viscosity Newtonian and non-Newtonian fluids through pipelines, and can be used in the hydrotransport of oils, oils, and liquid refined products in the oil, oil refining, petrochemical, and chemical industries to main, industrial, inter-plant, and intra-factory pipelines.

A known method of pressure hydraulic transport of goods through a pipeline, when compressed air is introduced into the flow of a transporting fluid (Aut. St. USSR No. 224378, B 65 G 51/00, 1975).

The reasons that impede the achievement of a given technical result include the instability of the air boundary layer to the pipe wall, which leads to mixing of the air gap with the main flow of the transported liquid and the creation of a heterophasic liquid-air system, the hydraulic resistance of which increases due to the destruction of the air low-viscosity boundary layer, especially for local hydraulic resistances (turns, compensators, cranes, gate valves, etc.).

A known method of extracting and moving highly viscous petroleum products by forming aqueous dispersions in the presence of salt water with the addition of sulfonated dispersants (RF Patent No. 2190151, F 17 D 1/17, F 15 D 1/02, 1998).

The reasons that impede the achievement of a given technical result include, along with the formation of low-viscosity oil-water emulsions, when oil droplets are surrounded by a film of water, the formation of high-viscosity water-oil emulsions, when water droplets are surrounded by a film of oil. This phase inversion most often occurs behind local resistances (bends, temperature compensators, valves, valves, valves, etc.). This instability of a low-viscosity water-oil emulsion leads to an increase in hydraulic resistance in the entire volume of the pumped liquid, and not only in the layer bordering the pipe, which requires additional energy.

The closest technical solution to the claimed method of moving viscous oils and petroleum products is the method of hydrotransport of highly solidified and viscous oils and petroleum products, which consists in the formation of a coaxial concentric layer of water at the inner surface of the pipe by adding water to the oil and imparting rotational motion to the oil and water flows by screw cutting on the inner surface of the pipe beyond the areas where the flow rates change in magnitude or direction (the so-called resistance, bends, elbows, expansion joints, taps, valves, dampers, etc.), which leads to mixing of water and oil or oil products and increase hydraulic resistance and energy consumption for hydrotransport (Pipeline transport of oil and gas: Textbook for universities / R.A. Aliev, V.D. Belousov, A.G. Nemudrov and others - 2nd ed., Revised and enlarged - M .: Nedra, 1988.- 368 p. S.243).

The reasons that impede the achievement of the desired technical result include the difficulty of making screw threads on the inner surface of the pipe, especially on existing pipelines, filling screw threads with oil or oil products over time, which leads to the termination of the rotational movement of flows, mixing of oil and water and an increase in hydraulic resistance and energy costs.

The objective of the proposed technical solution is to create a stable coaxial concentric layer of water at the inner surface of the pipe beyond the areas where the flow rates change in magnitude or direction.

The technical result of the proposed technical solution is to reduce hydraulic resistance and energy consumption when moving viscous oils and oil products through the pipeline due to the creation of rotational movement of flows beyond the areas where their velocities change in magnitude or direction.

The technical result is achieved by the fact that in the method for moving viscous oils and oil products, the formation of a coaxial concentric layer of water near the inner surface of the pipe occurs by adding water to the oil and imparting a rotational movement to the oil and water flows, while the rotational movement is carried out by paddle mixers installed behind the sections, where there is a change in flow velocities in magnitude or direction with an angular velocity determined by the formula

where ω is the angular velocity of rotation of the paddle mixer;

g is the acceleration of gravity;

R is the radius of the pipeline.

Bringing the flows of water and oil or petroleum products into rotational motion with paddle mixers behind the areas where the flow rates change in magnitude or direction (behind the so-called local resistances) allows you to restore the coaxial concentric layer of water at the inner surface of the pipe, which collapses in bends, in compensators, valves, taps, gate valves and other local resistances. In a centrifugal field, when the flow rotates, heavy droplets and water layers that are behind local resistance inside the flow are discarded to the inner surface of the pipe, creating a stable coaxial concentric layer of water. Light droplets and layers of oil or oil products that are behind local resistance at the inner surface of the pipe are discarded by centrifugal forces into the inner layers of the stream.

The decrease in the angular velocity of rotation of the paddle mixer so that it becomes less than the specified lower limit, calculated by the formula (1), does not allow to develop a centrifugal force sufficient to separate heavy drops and layers of water from light drops and layers of oil, and to create a stable coaxial concentric layer water at the inner surface of the pipe.

An increase in the angular velocity of rotation of the paddle mixer so that it becomes greater than the specified upper limit calculated by formula (1) leads to turbulence of the flow, the appearance of vortices in it, breaking the coaxial concentric layer of water into drops, which leads to the formation of an emulsion of water droplets in oil , increase in hydraulic resistance and energy costs for pumping oil or oil products.

The use of paddle mixers allows, in addition to creating a rotational movement of the flow, to inform it of additional pressure for axial movement through the pipeline.

The method is as follows.

Experimental studies were conducted on the movement of oil in a pipeline with an internal diameter of 100 mm in a section of length l = 10 m with a bend at the inlet at an angle of 90 °, in which a paddle mixer with two blades with a diameter of 80 mm and a blade width of 14 mm was installed. The shaft of the paddle mixer was connected to the drive, allowing you to vary the number of revolutions of the mixer. Drive power was measured with a wattmeter.

The main liquid - oil was supplied from the oil tank by a centrifugal pump to the discharge pipe with a diameter of 80 mm, smaller than the diameter of the main pipeline. Water in the annular gap between the main pipeline and the discharge pipe of the centrifugal pump was supplied from the water tank by a centrifugal pump. Oil and water consumption were regulated by valves and controlled by rotameters. The pressure drop over a measured length l = 10 m was determined by a U-shaped differential pressure gauge. The flow of oil and water at the outlet of the pipeline entered the sump tank, where the lower fraction - water, after settling, merged into the water tank, and the upper fraction - oil into the oil tank. The viscosities of oil and water were 72 and 1 cPz, respectively, and the densities were 900 and 980 kg / m ³ .

The drawing shows the installation diagram of the proposed method for moving viscous oils and petroleum products.

The installation includes the linear part of the pipeline 1 with an internal diameter of 100 m and a U-shaped differential pressure gauge 2 for measuring the pressure drop over a measured length l = 10 m of the linear part of the pipeline 1, an elbow 3 with a paddle mixer 4 installed in it with a shaft 5 connected to drive 6, changing the speed depending on the applied voltage. The number of revolutions of the shaft 5 with a paddle mixer 4 is measured by a strobotachometer 7, and the drive power 6 by a wattmeter 8.

The installation contains a tank for oil 9, into which the suction pipe of the centrifugal pump 10 is lowered, and a discharge pipe 11 having a diameter of 80 mm (smaller than the internal diameter of the pipe 1) is mounted axisymmetrically with the linear part of the pipe 1 connected to the elbow 3. To measure the oil flow installed rotameter 12. Oil flow is regulated by a valve 13.

The installation also contains a water tank 14, into which the suction pipe of the centrifugal pump 15 is lowered, and the discharge pipe 16 is connected to the lower part of the pipe branch 11. A rotameter 17 is installed for measuring the water flow rate. The water flow rate is regulated by valve 18. To receive the oil-water flow from pipeline 1, a settling tank 19 with a pipe 20 and a valve 21 for collecting oil and draining it into a tank 8 and a pipe 22 with a valve 23 for water selection is installed and draining it into a container 14.

Installation works as follows. Turn on the oil pump 10 and use the valve 13 to establish the oil flow rate on the rotameter 12. Then turn on the water pump 15 and use the valve 18 to establish the flow rate of water on the rotameter 17. By adjusting the voltage on the drive 6 with a strobotachometer 7, set the required number of revolutions ω of the shaft 5 with a paddle mixer 4. After stabilization of the oil and water flows in the pipeline 1, the pressure drop across the measured length is measured with a U-shaped differential pressure gauge. The spent oil-water stream is poured into a settling tank 19.

After the experiments and the separation of oil and water in the tank-sump 19 open valves 21 and 23 and through pipelines 20 and 22, respectively, oil and water from the tank-sump 19 are poured into the oil tank 8 and the water tank 14.

The oil consumption in all experiments was 4 l / s, the water consumption of 1.1 l / s.

Table
The results of experimental studies on the movement of oil in the pipeline Hydraulic Power Consumption, W Noopa that Way to move resistance, N / m ² linear on rotation of the mixer are common Proposed at blade speed, rad / s 1 ω = 15.3 (less than the lower limit calculated by formula 1) 1024 5.24 0.13 5.37 2 ω = 16.6 (equal to the lower limit calculated by formula 1) 656 3.44 0.15 3,59 3 ω = 19.8 (the average value between the upper and lower values of the angular velocity calculated by formula 1) 504 2,56 0.22 2.78 4 ω = 22.6 (equal to the upper limit calculated by formula 1) 608 3,1 0.28 3.38 5 ω = 23.4 (above the upper limit calculated by formula 1) 988 5.04 0.31 5.35 6 Industrial (oil fills the entire pipeline 1174 6.0 - 6.0 7 According to the prototype (with screw thread of the inner wall of the pipe) 828 4.22 - 4.22

As can be seen from the table, the proposed method for moving oil in the pipe allows, in comparison with the prototype, to reduce the hydraulic resistance by 1.26-1.64 times, and compared to the industrial method (when oil fills the entire pipeline and does not rotate) by 1.78- 2.33 times. The decrease in the angular velocity of rotation of the paddle mixer compared with the lower limit calculated by formula 1, as well as its increase above the upper limit (experiments 1 and 5, respectively, do not give advantages compared to the prototype (experiment 7) both in terms of hydraulic resistance and energy consumption .

As can be seen from the table (experiments 1-5), the energy consumption for the rotation of the mixer is not more than 10% of the energy consumption for moving the liquid through the pipeline. The total energy consumption compared with the prototype is reduced by 1.15-1.34 times, and compared with the industrial method by 1.4-1.53 times.

The use of paddle mixers allows you to create a rotational flow, in contrast to the propeller and turbine mixers, which create an axial and radial flow, respectively, and contribute to the mixing of water and oil.

Thus, the proposed method for moving viscous liquids and oils allows, by creating centrifugal force during the rotation of oil and water flows with paddle mixers behind the areas where the flow velocities change in magnitude or direction, restore the destroyed coaxial concentric ring of water at the inner surface of the pipe, reduce hydraulic pipeline resistance and reduce energy consumption.

Claims (1)

The method of moving viscous oils and oil products, which consists in the formation of a coaxial concentric layer of water near the inner surface of the pipe by adding water to the oil and imparting a rotational movement to the oil and water flows, characterized in that the rotational movement is carried out by paddle mixers installed outside the areas where the speed changes flows in magnitude or direction, with an angular velocity determined by the formula

where ω is the angular velocity of rotation of the paddle mixer; g is the acceleration of gravity; R is the radius of the pipeline.