RU2460933C1 - Device for oil heating during drainage - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: device includes reservoir; microwave energy source with waveguide in the area of drain instrument; radiotransparent plate fixed in open end of waveguide; radar absorbent material in the form of a strip, which is fixed on spiral metal band on external lower side; metal screen located above radar absorbent material; shell; gap; reduction gear; bars for attachment of shell and spiral metal band to driven wheel of reduction gear; shaft connected to drive wheel of reduction gear and with electric drive through gland in reservoir wall. Surface of strip of radar absorbent material and external edge of spiral metal band are located in side plane of conditional flattened cone. Plane of spiral metal band is perpendicular to rotation axis of conditional cone. Lower edge of strip of radar absorbent material and upper edge of spiral metal band is separated with a gap. Lower smaller base of conditional cone is located near drain instrument.

EFFECT: reduction of costs.

Description

The invention relates to the oil, oil refining, energy industries, in particular to thermal effects on oil and oil products when they are drained from storage.

A device for heating oil during discharge, containing a reservoir, a source of microwave energy, a waveguide, a drain device (see, for example, RF patent No. 2103211, class B65D 88/74, F17D 1/18. Bochkarev DA, Vasiliev E .G., Eremeev AG Method of heating thickened products in the container and device for its implementation. Publ. January 27, 1998).

The reasons that impede the achievement of the technical result indicated below when using the known device include the fact that the entire volume of oil in the tank is heated in the known device. However, the heating rate with increasing time for a changing oil temperature is exponentially much less than the speed at the beginning of heating. Therefore, the total heating time increases.

The closest device of the same purpose to the claimed invention by the totality of features is a device for heating oil during discharge, containing a reservoir, a microwave energy source, a waveguide, a radar absorbing material, a metal screen, a drain device, a radiolucent gasket, gaps between the radar absorbing material (see, for example, RF patent No. 2171954, class F17D 1/18 Monolakov VA, Yudin VV, Farisey IA Method for heating oil during discharge. Publish. 08/10/2001 Bull. No. 22), adopted as a prototype.

For reasons that impede the achievement of the following technical result of the known device adopted as a prototype, the temperature of the oil flow at the inlet to the drain device in the cross section is the same in the known device.

The invention consists in the following. Oil heated by a known device in the reservoir with a microwave energy source in front of the drain device has the same layer temperature in the cross section of the drain device. The drain rate is determined by the temperature of the oil along the walls of the drain device. So, when transporting oil through pipelines, the outer shell of the pipeline is heated, which leads to minimal expenditure of heating energy without loss of transportation speed.

To obtain a given temperature distribution in the tank, it is necessary to redistribute the power of the microwave energy source in the tank before the oil enters the drain device so that the power that heats the oil with the formation of a sliding layer along the walls of the drain device is greater, and the power directed to heat the oil flow in the center of the drain was less.

Selective heating of oil in front of the drain device can be accomplished by constructive solutions by giving the radar absorbing material heated by the absorbed microwave energy a predetermined shape, for example a side surface of a truncated cone. The surface of the radar absorbing material is made with gaps for the passage of microwave energy into the internal volume of the cone for heating the generated central oil flow. The base of the cone is open for free passage of oil and the smaller base of the cone is located in close proximity to the drain device. The emitter of the microwave energy source is made in the form of a segment of the waveguide, the output of which is sealed with a radio-transparent material and is located in close proximity to the radio-absorbing material. The relationship between the temperature of the oil inside the volume bounded by the radar absorbing material and the temperature of the oil of the sliding layer along the walls of the radar absorbing material is achieved by selecting the gap and the dielectric characteristics of the radar absorbing material, namely, the relative permittivity ε and the dielectric loss tangent tgδ, which determine the heating power absorbed by the material . The temperature at the center of the oil flow bounded at the edges by the radar absorbing material should be lower than the temperature of the oil along the walls of the radar absorbing material.

Since the radiation power in the propagation medium decreases with distance from the microwave energy source, for uniform heating, the radar absorbing material rotates around the axis of symmetry. The rotation is carried out by an electric drive with a gearbox. The electric drive is connected to the drive wheel of the gearbox by a shaft through an opening in the tank body. An oil seal at the passage of the shaft in the hole ensures the tightness of the reservoir.

The radar absorbing material is made in the form of a spiral strip and is attached by rods to the driven gear wheel in the lower part of the base and to the casing in the upper part of the base. The fastening of the radar absorbing material between the bases is carried out to the spiral metal tape along the edge from the outer lower side, the outer edge of the spiral metal tape lying in the plane of the lateral surface of the truncated cone, and the plane of the spiral tape perpendicular to the axis of rotation of the cone. Between the lower edge of the strip of radar absorbing material and the upper edge of the spiral metal strip, a gap is made for heating the oil with microwave energy inside the cone. Oil enters the inside of the cone through the upper shell and through the gap, thereby ensuring the flow of oil to the drain device at any level in the tank.

As a result of rotation, the oil inside the volume limited by the radar absorbing material is carried away by a spiral metal tape to the drain device. The inner edge of the spiral metal strip remains cold, thus providing the necessary adhesion of the spiral metal strip to the oil inside the cone to force the oil to move to the drain device. By selecting the angular rotation speed of the spiral metal strip, you can change the amount of oil supplied to the drain device. Increasing the rotation speed, the amount of oil being drained also increases, which will lead to cooling of the oil flow in the center of the drain device and vice versa. Thus, it is possible to achieve the optimal ratio between the drain rate and the angular velocity of rotation. All metal parts of the device are grounded to exclude eddy currents.

The metal screen is designed to reduce the boundaries of the volume of heated oil, thereby reducing the drain time.

The technical result that can be obtained by carrying out the invention is to reduce the time of oil discharge at a constant microwave source power due to the formation of a temperature gradient in a limited volume of the tank in the cross section of the oil flow in the immediate vicinity of the drain device. A sliding oil layer forms at the edges of the stream with a temperature exceeding the temperature at the center of the stream.

The specified technical result in the implementation of the invention is achieved by the fact that in a known device for heating oil during discharge, containing a reservoir; microwave energy source; a waveguide connected to the output of the microwave energy source and directed by the open end into the internal volume of the tank; radar absorbing material; a metal screen located above the radar absorbing material; a drain device in the bottom wall of the tank and located in close proximity to the waveguide from the side of the open end; a radiolucent plate fixed at the open end of the waveguide; the gap, the feature is that an electric drive is additionally introduced into it; shaft; stuffing box; shell; gearbox with drive and driven wheels; rods; a spiral metal tape, the outer edge of the spiral metal tape lying in the plane of the lateral surface of the truncated cone and the plane of the spiral metal tape perpendicular to the axis of rotation of the cone, and the smaller lower base of the cone is located in the immediate vicinity of the drain device; and the radar absorbing material is fixed along the edge of the spiral metal strip from the outside bottom side in the form of a strip; and the plane of the strip of radar absorbing material lies in the plane of the lateral surface of the truncated cone, and the lower edge of the strip of radar absorbing material and the upper edge of the spiral metal tape separates the gap; and the rods fasten the shell located in the upper larger base of the cone, and a spiral metal tape with radar absorbing material to the driven gear wheel, and the gear drive wheel is connected by an electric drive shaft through an oil seal in the tank wall.

The figure shows a diagram of a device for heating oil during discharge. The device comprises a reservoir 1, a microwave energy source 2, a waveguide 3, a radar absorbing material 4, a metal screen 5, a drain device 6, a radiolucent plate 7, a gap 8, a spiral metal strip 9, rods 10, a shell 11, a gearbox 12 with a driven wheel 12.1 and drive wheel 12.2, electric drive 13, shaft 14, oil seal 15.

The device operates as follows.

When you turn on the microwave energy source, the radiation through the waveguide 3 through the insulating radiolucent plate 7 enters the internal volume of the tank 1 with oil. The metal screen 5 reduces the penetration of microwave energy beyond the allocated volume limited by the metal screen 5, the bottom of the tank 1 and the surface of the radar absorbing material 4, which is opposite from the waveguide. The drive 13 is turned on, which drives the drive wheel 12.1 of the gearbox 12 to rotate the shaft 14. The stuffing box 15 prevents oil leakage in the hole for the shaft 14 in the wall of the tank 1. The drive wheel 12.2 rotates the driven wheel 12.1 and the shell 11 and the spiral metal tape 9 mounted on it with rods 10 with radar absorbing material 4. A spiral metal tape 9 is simultaneously attached to the shell 11. Oil with low temperature from the total volume of the tank 1 enters the inside of the volume bounded by the radio-absorbing material through the gaps 8 and through the shell 11. The radio-absorbing material 4 is heated by the energy of the microwave source 2 and transfers heat to the boundary a layer of oil near its surface. The heated oil layer begins to drain to the walls of the drain device 6. Inside the volume closed by the radar absorbing material 4, the oil is heated to a lower temperature than the surface of the radar absorbing material 4 and is carried away by a spiral metal tape to the drain device 6. As a result, a layer is formed in the drain device 6 oil with improved slip along the walls and a stream of less heated oil in the center. The discharge time with a constant heating power decreases, since the temperature of the moving oil layer increases. By selecting the angular velocity of rotation of the gearbox 12, it is possible to achieve the maximum rate of oil drainage from the reservoir 1. The optimal drainage speed is adjusted by changing the angular velocity of rotation of the gearbox 12. An increase in speed leads to a decrease in the temperature of the oil inside the volume limited by the radar absorbing material 4 and to a decrease in the speed of drainage. A decrease in the speed of rotation of the gearbox 12 leads to an increase in the temperature of the oil inside the volume limited by the radar absorbing material 4, but to a decrease in the rate of discharge. By selecting the angular velocity of rotation of the gearbox 12, it is possible to achieve the maximum rate of oil discharge from the tank 1.

Claims (1)

A device for heating oil during discharge, containing a reservoir; microwave energy source; a waveguide connected to the output of the microwave energy source and directed by the open end into the internal volume of the tank; radar absorbing material; a metal screen located above the radar absorbing material; a drain device in the bottom wall of the tank and located in close proximity to the waveguide from the side of the open end; a radiolucent plate fixed at the open end of the waveguide; the gap, characterized in that it additionally introduced an electric drive; shaft; stuffing box; shell; gearbox with drive and driven wheels; rods; a spiral metal tape, the outer edge of the spiral metal tape lying in the plane of the lateral surface of the truncated cone and the plane of the spiral metal tape perpendicular to the axis of rotation of the cone, and the smaller lower base of the cone is located in the immediate vicinity of the drain device; and the radar absorbing material is fixed along the edge of the spiral metal strip from the outside bottom side in the form of a strip; and the plane of the strip of radar absorbing material lies in the plane of the lateral surface of the truncated cone, and the lower edge of the strip of radar absorbing material and the upper edge of the spiral metal tape separates the gap; and the rods fasten the shell located in the upper larger base of the cone, and a spiral metal tape with radar absorbing material to the driven gear wheel, and the gear drive wheel is connected by an electric drive shaft through an oil seal in the tank wall.

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