RU2464109C2 - Method and device to generate pressure oscillations in fluid flow - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: inventions relates to oil production and may be used for increasing recoverable oil. Set of inventions comprises hydro mechanical generator of fluid pressure oscillations in fluid flows by hydro mechanical method. Said method consists in feeding fluid via revolving shaft orifices into fixed sleeve channel. To provide for intermittent fluid flow, axes of channels are aligned while shutting off fluid flow in sleeve channel at preset frequency f is effected by intermittent shifting of shaft channels relative to sleeve channels by revolving shaft at speed ω = f/2n where n is the number of channels in rotating shaft.

EFFECT: recurrence of pressure oscillations, pressure oscillation period and amplitude.

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Description

The invention relates to the oil industry and, in addition, can be used in the chemical industry to obtain emulsions.

A known method of generating pressure fluctuations in the fluid flow, the closest in technical essence and taken as a prototype, implemented by the device (see application No. 4224723/03 of 01/26/1987, publ. 04.12.2003, patent No. 1450448), which consists in the fact that the fluid is fed through the channels of the movable shaft into the channel of the fixed sleeve and to ensure the periodic flow of fluid the axes of the channels are combined, and the interruption of the fluid flow through the channel of the sleeve with a given frequency f is carried out by shifting the channel of the shaft relative to the channel of the sleeve.

This method of generating pressure fluctuations in the fluid flow in the line behind the generator is based on interrupting the flow of fluid through the generator channels due to the displacement of its internal parts relative to each other. The liquid is fed to the inlet of the generator with some excess pressure, and in the case of combining the internal channels, it moves freely through the generator further. In this case, the pressure in the fluid flow in front of and behind the generator remains unchanged. When the internal channels are displaced relative to each other, the fluid flow through the generator stops and the pressure in the channel behind the generator decreases. In this way, pressure fluctuations in the fluid flow behind the generator are ensured.

The movable element of the generator is the shaft channel. The shaft is mounted in a fixed sleeve with the possibility of axial displacement, and a bypass channel is made in the side wall of the sleeve. At a certain position of the shaft, its channel is combined with the bypass channel of the sleeve and the fluid duct is open. With a different position of the shaft, its channel is shifted relative to the bypass channel of the sleeve and the flow of fluid through the generator is stopped.

The disadvantage of the method of generating pressure fluctuations, taken as a prototype, is the uncertainty of the position of the passage channel of the shaft relative to the bypass channel of the sleeve and, as a result, the randomness of the period of pressure fluctuations in the fluid stream behind the generator.

Known hydromechanical oscillator in a fluid stream containing a shaft with radial channels mounted coaxially in the hollow sleeve (see Gadiev S. M. Use of vibrations in oil production. M., Nedra, 1977., p.148).

A hollow shaft with radial through-pass channels is fixedly connected to the hollow body of the device, and the movable sleeve moves along the shaft, making reciprocating movements. The housing, shaft and sleeve in assembled form form two cavities in which the pressure increases alternately, since the sleeve blocks the bypass channels of the shaft emerging from these cavities, and an increase in pressure in one cavity pushes the sleeve out of it and leads to the bypass channel of the other cavity overlapping. In this way, pressure fluctuations in the fluid flowing out of the device are generated.

The disadvantage of this device is the non-periodicity of the generated pressure fluctuations in the fluid flow due to the unsystematic movement of the sleeve along the shaft.

Known hydromechanical oscillator in a fluid flow, the closest in technical essence and taken as a prototype (see application No. 4224723/03 from 01/26/1987, publ. 04.12.2003, patent No. 1450448), containing a movable shaft with through channels, mounted coaxially in a stationary sleeve with a radial bypass channel in the wall.

A movable shaft is coaxially mounted in the hollow cylindrical sleeve with a blind bottom. In the side wall of the sleeve is a bypass through channel. The shaft is centered in the sleeve due to radial struts made in two tiers. On the racks of the inner tier end tides are made. The shaft is spring loaded in the sleeve in the axial direction, but is fixed by struts from radial movement. Between racks free flow of liquid is provided.

The stiffness of the spring connecting the shaft with the sleeve in the axial direction is selected such that, at a certain fluid supply pressure, the shaft moves in the sleeve, blocking the overflow channel by the tides of the struts. When the pressure decreases, the spring pushes the shaft back and the channel opens. This ensures intermittent fluid flow through the generator.

The disadvantage of the generator, taken as a prototype, is the uncertainty of the position of the shaft in the sleeve and the degree of opening or closing of the bypass channel of the sleeve may be incomplete. This will lead to a decrease in the amplitude of the pressure fluctuation behind the generator.

The technical result is achieved due to the fact that in the method of generating pressure fluctuations in the fluid flow, namely, the fluid is supplied through the channels of the movable shaft into the channel of the fixed sleeve and to ensure the periodic flow of fluid, the axes of the channels are combined, and the interruption of the fluid flow through the sleeve channel with a predetermined frequency f is carried out due to the displacement of the channel of the shaft relative to the channel of the sleeve, the periodic displacement of the channel of the shaft relative to the channel of the sleeve is produced due to the rotation of the movable shaft with ω = f / 2n, where n is the number of channels in a rotating shaft.

In the generator of pressure fluctuations, a movable shaft with through channels is installed coaxially in a stationary sleeve with a radial bypass channel in the wall, and the rotating shaft is made with a radial channel and a shank and installed in the sleeve so that the axis of the channels of the sleeve and shaft are aligned, or in a rotating shaft several through radial channels can be made, the axes of which are located in the same radial plane.

The proposed method for generating pressure fluctuations is as follows.

The hydromechanical generator of pressure fluctuations consists of a steel casing (1) with inlet and outlet fittings (see Fig. 1), in which a bronze sleeve (2) is fixedly mounted, in which, in turn, a movable steel shaft (3) is inserted. The bronze bushing is a hollow body of revolution with two radial through passage channels in the wall, located opposite each other on a common axis. One channel is the inlet, a displacing liquid is fed into it under pressure, and the other channel is the outlet, liquid flows out of it. In the sleeve, central blind drilling with a flat bottom is made, into which a movable shaft with radial through drilling is inserted. On the one hand, a shaft has a flat end, with which the shaft is inserted into the bushing channel, and on the other hand, a shank is made in the form of an inscribed hexagon to which the electric drill drive is attached.

The shaft is tightly inserted into the central channel of the sleeve in such a way that it abuts with its flat end against the flat bottom of the channel and can freely rotate in the channel. In the axial direction, the shaft is fixed, while the radial plane in which the shaft is drilled coincides with the plane in which the radial drillings are made in the wall of the sleeve.

During operation, the shaft rotates, and in a certain position, the channel of the shaft is combined with the bypass channels of the sleeve, providing a through channel for the liquid. In this case, the pressure in the fluid flow in the line behind the generator is equal to the pressure in front of the generator. With further rotation of the shaft, the alignment of the channel of the shaft and the sleeve is broken and the fluid duct closes. The pressure in the line behind the generator decreases. The interruption of the fluid flow through the generator due to the rotation of the shaft with the channel allows the generation of pressure fluctuations in the fluid flow of a strictly defined periodicity.

The simplest design of the movable shaft is presented in figure 2. The shaft is a body of revolution with a shank in the form of an inscribed hexagon and a radial through channel - drilling. The shaft end from the opposite side from the shank is flat. With this end, the shaft abuts against the flat bottom of blind axial drilling in a fixed sleeve. Thus, the position of the shaft in the sleeve in the axial direction is set. With this shaft design, the combination of the shaft channel with the bypass channel of the fixed sleeve occurs twice in one revolution of the shaft. When the shaft rotates at a speed of ω = 1000 rpm, the frequency of the generated pressure oscillations will be f = 2000 Hz.

To reduce the frequency of the generated pressure fluctuations at a constant shaft rotation speed, a shaft design with a broken channel is presented (see figure 3). In the body of the movable shaft, axial blind drilling is made, muffled from the shank side. In the shaft wall, from opposite sides in the axial plane, two blind drills are made to the axial channel, each of which is located in its radial plane. In this case, the bypass channel of the fixed sleeve is of the same shape and the holes of the sleeve channel coincide with the holes of the shaft channel. With this shape of the channel of the shaft and the sleeve, the combination of both the inlet and outlet openings occurs once in one revolution of the shaft. When the shaft rotates at a speed of ω = 1000 rpm, the frequency of the generated pressure oscillations will also be f = 1000 Hz.

To increase the frequency of the generated pressure fluctuations at a constant shaft rotation speed, a shaft design with several radial channels located in the same plane is presented. But in the center of the shaft at the intersection of several drillings, the shaft walls remain unacceptably thin. To maintain the strength of the shaft with a radial arrangement of several channels, it is proposed to thicken in this place. The shaft is thickened in the form of a disk located in the radial plane (see figure 4). Changing the diameter of the disk allows you to adjust the fullness of the cycles. With a constant number of shaft channels and an increase in the diameter of the disk, the distance between the channel inlet openings increases, as well as between the outlet openings. The interval between pressure surges on the waveform also increases with an equal period of oscillation.

The proposed method for generating pressure fluctuations in the fluid flow allows you to uniformly interrupt the fluid flow through the generator and to ensure repeatability of the cycles of increase and decrease in pressure in the fluid flow behind the generator, as well as the period and amplitude of pressure fluctuations.

Figure 1 presents a diagram of a hydrodynamic generator of pressure fluctuations in a fluid stream.

Figure 2 presents a diagram of a shaft with one radial channel.

Figure 3 presents a diagram of a shaft with a broken channel.

Figure 4 presents a diagram of a shaft with a bulge and several radial channels in it.

The hydrodynamic generator of pressure fluctuations in the fluid flow consists of the following elements: housing (1) (see figure 1), sleeve (2), shaft (3), union nut (4), sealing sleeve (5), compression nut (6 ), washers (7) and o-ring (8). The steel casing (1), made with two fittings located on the same axis on opposite sides of the part, is machined from a hexagonal bar. In the housing, in the plane of symmetry, central drilling is performed perpendicular to the axis of the fittings. A bronze bushing (2) is inserted into this drilling, clamped on both sides through rubber rings (8) and washers (7) with fine-threaded nuts (6). In the bushing, central blind drilling with a flat bottom and radial through drilling in the wall are made, which are two independent channels of circular cross section located on the same axis. A shaft with flat ends, a hexagonal shank and through radial drilling is inserted into this drilling. The shaft is inserted into the sleeve in such a way that it abuts with a free flat end in the bottom of the sleeve, but has the ability to rotate, and the axis of the channels of the sleeve and shaft coincide. In the sleeve from the side opposite the blind end, the stuffing box seal of the rotating shaft is made, tightened by the union nut (4).

The device operates as follows. The displacing fluid is supplied under pressure through the inlet fitting of the housing to one of the bypass holes of the sleeve. Further fluid movement is prevented by the movable shaft. When the shaft rotates, the through channel is periodically aligned with both channels of the sleeve. In this case, the free duct for the fluid is open. With further rotation of the shaft, its channel is shifted relative to the channels of the sleeve and the fluid duct is closed. The packing gland prevents fluid from escaping outward along the shaft as it rotates.

Claims (4)

1. The method of generating pressure fluctuations in the fluid flow, namely, that the fluid is fed through the channels of the movable shaft into the channel of the stationary sleeve and to ensure the periodic flow of fluid combine the axis of the channels, and the interruption of the fluid flow through the channel of the sleeve with a given frequency f is carried out by displacement the channel of the shaft relative to the channel of the sleeve, characterized in that the periodic displacement of the channel of the shaft relative to the channel of the sleeve is produced due to the rotation of the movable shaft with a speed ω = f / 2n, where n is the number of catch in a rotating shaft. 2. A hydromechanical generator of pressure fluctuations for implementing the method according to claim 1, comprising a movable shaft with through channels installed coaxially in a stationary sleeve with a radial bypass channel in the wall, characterized in that the rotating shaft is made with a radial channel and a shank and is installed in the sleeve such so that the axis of the channels of the sleeve and shaft are combined. 3. The device according to claim 2, characterized in that on a rotating shaft a thickening is made in the form of a disk located in a radial plane, in which several through radial channels are arranged located in one radial plane. 4. The device according to claim 2, characterized in that the axis of the through channel in the rotating shaft is a broken line, and the inlet and outlet of the channel are located in the same axial plane, but in the outlet of the channel are located in the same axial plane, but in different radial planes, and the location of the inlet and outlet openings of the bushing channel is made corresponding to the locations of the inlet and outlet openings of the shaft channel.

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