RU2771862C1 - Device for removing oil products from the water surface - Google Patents

Abstract

FIELD: water surface cleaning.

SUBSTANCE: invention relates to a technique for cleaning the water surface from liquid contaminants, mainly from oil products. The device for collecting oil products from the water surface includes a cylindrical cup open from above, a means for creating a vortex funnel with a drive for its rotation, and a means for pumping out collected oil products. At the same time, the means for creating a vortex is made in the form of the aforementioned glass, equipped with means for moving it along the height, and the drive for its rotation is provided with a control unit. The output of the control unit is connected to the cup rotation drive, and its inputs are connected to the density meters of water and the collected oil product, the viscosity meters of water and oil product, the oil layer thickness meter and the means for measuring the depth of immersion of the top edge of the cup from the "water-oil" interface. The end face of the receiving branch pipe of the means for pumping out oil products is located below the upper end of the cup by the value H/2, where H is the height of the cup.

EFFECT: efficiency improvement.

1 cl, 4 dwg

Description

The invention relates to a technique for cleaning the water surface from liquid contaminants, mainly from oil products.

A device for collecting oil from the surface of the water is known, including a floating housing, a swirler with a vertical drive shaft and an exhaust pump and an oil intake pipe connected to it, installed coaxially with the swirler shaft (SU 1654449 [1]). The disadvantage of the known device is low efficiency, due to the fact that the device does not provide control means for optimal placement of the oil inlet pipe, which in turn leads either to the capture of a large amount of water in the pumping device, or to leaving the oil product on the water surface.

A device for collecting oil products from the surface of the water is known, including a floating body with a drive swirler and an oil receiving cup with a suction pipe located in the center of the swirler (RU 2010090 [2]). The ability of the receiver to sink below the level of contamination provides an opportunity to optimize the cleaning of the water surface, however, the absence of controls for the level of immersion reduces the effectiveness of the device.

A device for collecting oil products from the surface of the water is known, including a vortex chamber with an inlet and outlet for the collected oil, a drive for its rotation, a swirler, floats, a power frame, a container for collecting the collected oil, a pipeline, a pump (RU 2213180 [3]). The design of the device assumes the presence of a means of vertical movement of the vortex chamber and a system for automatically maintaining the required gap between the oil mirror and the plane of the top of the truncated profiled funnel, the design features of which and the means of implementation are not specified. Describing this device, the authors indicate that the efficiency of collecting spilled oil (petroleum products) using the proposed device mainly depends on the kinematic characteristics and positioning of the vortex chamber relative to the surface of spilled oil products, i.e. on the angular velocity of rotation of the vortex chamber and the size of the gap between the oil mirror and the plane of the inlet to the funnel. The optimal values of these parameters depend on the physical and chemical parameters of the spilled oil product, on the state of the surface on which the oil product is spilled, on weather conditions, etc. The optimal values of the speed of rotation of the vortex chamber and the size of the gap between the mirror of the collected oil product and the plane of the hole at the top of the funnel must be selected experimentally for each specific case during the setup of the device.

Thus, the disadvantages of the known device include not only the complexity of the design and its operation, but also the low efficiency due to the lack of means for optimizing the operating conditions of the device, depending on the operating conditions and on the physical and chemical parameters of the spilled oil product and water, on which the oil product is spilled.

Closest to the claimed in its design is a device for collecting oil products from the surface of the water, including a swirler to form a funnel on the water surface, a cylindrical glass open at the top and a device for collecting and pumping the collected oil products into a separate container (SU 458136 [4]).

The disadvantage of the known device is its low efficiency, due to the lack of means for optimizing operating modes.

The inventive device for collecting oil products from the surface of the water is aimed at improving the efficiency of collecting oil products.

This result is achieved by the fact that the device for collecting oil products from the surface of the water includes a cylindrical cup open from above, a means for creating a vortex funnel with a drive for its rotation, and a means for pumping out the collected oil products. At the same time, the means for creating a vortex is made in the form of the aforementioned glass, equipped with means for moving it along the height, and the drive for its rotation is provided with a control unit. The output of the control unit is connected to the cup rotation drive, and the inputs are connected to the density meters of water and the collected oil product, the viscosity meters of water and oil products, the thickness gauge of the oil layer and the means for measuring the depth of immersion of the upper edge of the cup from the "water-oil" interface, while the end the receiving branch pipe of the oil pumping means is located below the upper end of the cup by the value H/2, where H is the height of the cup.

Distinctive features of the proposed device are:

- implementation of the means for creating a vortex funnel in the form of a cylindrical glass, equipped with a drive for its rotation;

- the glass is provided with a means of its movement in height;

- the rotation drive is equipped with a control unit, the output of which is connected to the cup rotation drive, and the inputs are connected to water and collected oil density meters, water and oil product viscosity meters, an oil product layer thickness meter and a means for measuring the depth of immersion of the top edge of the cup from the water-to-oil interface. oil product";

- the end face of the receiving branch pipe of the means for pumping out the oil product is placed below the upper end of the cup by the value H/2, where H is the height of the cup.

The authors experimentally found that the rotation of the glass in the form of a hollow cylinder leads to the formation of a vortex funnel inside the volume of the cylinder. And it is known from the prior art (see [2], [3], [4]) that if oil products are present on the surface of the water, then the separation of water and oil fractions in the vortex occurs. Thus, there is no need for means, in the form of screws, jet pumps, etc., specially designed to create a vortex funnel, which simplifies the design.

The supply of the glass with a means of moving it in height allows you to install it submerged to a depth that will provide the most optimal operating conditions for the device, which will positively affect its efficiency.

It was also found that the shape and dimensions of the oil part of the composite vortex depend on a number of parameters - the thickness of the oil layer on the water surface, the density and kinematic viscosity of the water and the removed oil products. Various petroleum products and oils were used in the experiments - sunflower oil, a mixture of sunflower oil and diesel fuel in equal proportions, oil, diesel fuel.

As a result of analytical processing of experimental data, it was possible to establish empirical dependences of the optimal modes of implementation of the method, depending on the properties of the oil product and the state of the aquatic environment of the reservoir, on the surface of which this oil product is located. In particular, it was found that the optimal immersion depth h of the upper edge of the glass from the "water-oil" interface, it is advisable to determine by mathematical dependencies:

where h is the depth of immersion of the upper edge of the cup from the water-oil interface, m;

H - cup height, m;

, - плотность воды, кг/м³;

, - water density, kg / m ³ ;

- плотности нефти, кг/м³;

- oil density, kg/m ³ ;

- кинематическая вязкость воды, м²/c;

- kinematic viscosity of water, m ² / s;

- кинематическая вязкость нефти, м²/c,

- kinematic viscosity of oil, m ² / s,

and the optimal angular frequency of rotation of the cup ω can be determined from the dependence:

- радиус стакана, м;where

- glass radius, m;

- толщина слоя нефтепродукта на поверхности воды, м;

- thickness of the oil product layer on the water surface, m;

- гравитационное ускорение, м/c².

- gravitational acceleration, m/s ² .

And in order to ensure optimal operating conditions of the device and its high efficiency, it is necessary to obtain data on the parameters included in the above mathematical expressions. Therefore, the device is equipped with water and oil product density meters, water and oil product viscosity meters, oil product layer thickness meter and a means for measuring the depth of immersion of the upper edge of the glass from the water-oil product interface. The corresponding data is sent to the control unit, processed, and the generated control action is fed to the cup rotation drive.

Empirically, it was found that the optimal location of the end face of the receiving pipe of the oil pumping means in the oil part of the composite vortex, (the end of the receiving pipe of the means of pumping out oil products is located below the upper end of the glass by the value H/2, where H is the height of the glass) when the pump is running, leads to the selection only oil from the compound vortex and transporting it to the collection point through a flexible hose. The emerging shortage of oil in the composite vortex is immediately replenished with oil from the surface, which leads to a continuous collection of oil products from the surface of the water.

The essence of the proposed device is illustrated by an implementation example and graphic materials. In FIG. 1 shows a schematic diagram of the implementation of the device. In FIG. Figure 2 shows typical shapes of a composite vortex at various speeds of rotation of the glass and various oil products. In FIG. 3 shows a block diagram of the device. In FIG. 4 schematically shows the mechanism for moving the glass vertically.

The device contains a hollow cylindrical cup 1, which is equipped with a drive for its rotation 2 with its control unit 3. The drive can be selected from among the known ones, and a computer equipped with appropriate software can be used as a control unit. The inputs of the control unit are connected to the density meters of water and the collected oil product 4, the viscosity meters of water and oil product 5, the thickness gauge of the oil layer 6 and the means for measuring the depth of immersion of the upper edge of the cup from the water-oil product interface 7. In addition, means are provided for moving glass in height so that you can adjust the depth of its immersion. For example, it can be a vertically movable bracket 9 with a device fixed on it, equipped with a mechanism 10 for its vertical movement, which is fixed on the carrier vessel 11. All nodes and blocks that make up the proposed device are selected from known ones.

For example, to measure the density of water, the “AUTO MD3051A51H8 Liquid Density Meter”, commercially available from Yantal Auto Instrument Making Co., can be used. Ltd." (China), or the TOYE TY-C1000-2F80-M4SF22 liquid or liquid mixture density meter, commercially produced by Zhengzhou Winbell Measurement And Control Technology Co. Ltd."

(China), or the Aipuxin APXRD806 Radar Water Density Meter, commercially available from Shandong Aipuxin Automation Instruments Co. Ltd." (China). To measure the density of the collected oil product, the “AUTO MD3051A51H8 Liquid Density Meter”, commercially produced by Yantal Auto Instrument Making Co., can be used. Ltd." (China), or the TOYE TY-C1000-2F80-M4SF22 liquid or liquid mixture density meter, commercially produced by Zhengzhou Winbell Measurement And Control Technology Co. Ltd." (China), or the Shelok YY-886 fork-type density meter, commercially produced by Xi’an Yunui Instrument Co. Ltd." (China), since they allow online measurements of the density of a wide class of liquids, including aggressive ones. To measure the viscosity of water and oil products, it is advisable to use the device "Rotational viscometer (according to Brookfield) Roravisc me-vi HELI Complete", commercially produced by IKA-WERKE (Germany), or the device "Vibrating viscometer SV-10A", commercially produced by AND (Japan). ), or the Rotational Viscometer TQC Vr3000, commercially produced by Thermoimport Quality Control (Netherlands), as they allow measuring the dynamic viscosity of a wide class of liquids online. As a hydrostatic pressure sensor, you can use the device "Hydrostatic pressure sensor GP-M010", commercially produced by Keyence (Japan), or the device "Submersible hydrostatic level sensor (pressure of the liquid column) OVEN PD100I-DGO.016-167-1.5.2" , commercially produced by OvenKomplektAvtomatika (Russia), or the Hydrostatic Pressure Converter DI / G-26, commercially produced by Izmerkon (Russia), as they provide measurement of hydrostatic pressure under the water surface at the point of immersion and recalculation using firmware of the measurement result in the value of the immersion depth. To measure the thickness of the oil layer, the instrument "Radiometric gauge of the thickness of the oil layer on the surface of the water" KTS RMK-I, commercially produced by SUE NPP Polet (Russia), or the instrument "Ultrasonic gauge of the oil layer on the water and earth surfaces KT" can be used. -3C”, serially produced by the State Unitary Enterprise NPP “Polyot” (Russia), since, based on the firmware of their own software, they provide measurement of the thickness of the oil layer spilled on a known surface.

The device is used as follows. At the site of the spill of oil products on the surface of the reservoir, the hollow cup 1 is immersed to a certain depth using the means 8 and using the measuring instruments 4,5,6, and 7 included in the device, the parameters necessary to calculate the optimal operating conditions are determined. The measurement results are sent to the control unit 2, which, in accordance with the program available in it, makes the necessary calculations and sets the required immersion depth using means 8. Based on the calculation, a command action is generated on the rotation drive 2 of the cup 1, which is set into rotation at the calculated speed.

Since the means for measuring the parameters of liquids and the depth of immersion of the cup, introduced into the device, work online, when they change, the control unit promptly makes changes to the modes of rotation of the cup and its immersion depth.

As a result, only the collected oil product without water impurities or with a minimum amount of it enters the oil product pumping means.

Claims (1)

A device for collecting oil products from the surface of the water, including a cylindrical cup open from above, a means for creating a vortex funnel with a drive for its rotation and a means for pumping out the collected oil products, characterized in that the means for creating a vortex is made in the form of the mentioned cup, equipped with means for moving it along the height, while its rotation drive is equipped with a control unit, the output of which is connected to the rotation drive, and the inputs are connected to water and collected oil density meters, water and oil product viscosity meters, an oil layer thickness meter and a means for measuring the depth of immersion of the upper edge of the cup from the water-product interface ”, while the end of the receiving pipe of the means for pumping out the oil product is located below the upper end of the glass by the value H / 2, where H is the height of the glass.

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