RU2320395C2 - High-efficiency liquid-and-gas separator - Google Patents

Abstract

FIELD: separation of gaseous and liquid phases in the field of centrifugal force at equal separation extent both with high and low gaseous or air factor.

SUBSTANCE: separator has vertical cylindrical casing, horizontal closure, inlet, outlet and discharge branch pipes, deflector mounted in the course of rotation of gas-and-liquid stream, vertical separation packet equipped with flat bottom and consisting of flat curved separating plates delimiting slot-type channels in overlap zone and oriented with their vertical curved ends in various directions, tangentially relative to outer and inner diameters of separation packet, and false bottom. There are through openings provided centrally of flat bottom of separation packet and false bottom. Hollow cylinder is mounted in said openings so that its base is disposed on false bottom and upper edge is raised relative to flat bottom surface. Cylindrical vertical disperser with cuts is mounted at the level of outer diameter of lower surface of false bottom. Disk is fixed directly to underside of hollow cylinder.

EFFECT: increased capacity and high separating efficiency of separator.

2 dwg

Description

The invention is intended for the deposition of film, droplet, fine and aerosol liquid and solid particles in the field of centrifugal forces with both high and low gas factors, without reducing the separation efficiency. It is applied in oil and gas, machine-building, chemical and other industries.

Known separator (patent RU 2221625), containing a vertical cylindrical body, horizontal cover, inlet, outlet, drain pipe, deflector, vertical separation package consisting of flat curved and arched plates, which form slotted channels in the lap zone. On the inner surface of the vertical arcuate plate, converging arcuate guide plates located at an angle of 30 ° to the horizontal, collecting and transporting the film fluid from the inner surface of the arcuate plate into the zone of the slotted channel, are located along the gas-liquid flow. To transport the liquid phase from the zone of the slotted channel to the inner surface of the apparatus body, open gutters are provided. A pocket-trap is installed in the upper inner part of the separation bag in the hole of the horizontal cover.

A disadvantage of the known device is that the presence on the inner surface of a vertical arcuate plate of converging arcuate guide plates, as well as the presence of rectangular open grooves, makes the separation bag not technologically advanced in terms of manufacturing. Rectangular open troughs cover part of the live section between the separator body and the separation bag, which leads to an increase in the pressure in the apparatus, the chaotic movement of the gas-liquid mixture in this space and the entrainment of part of the liquid phase into the separation bag. The slot located behind the troughs in the direction of flow is partially blocked. The overlapped part of the gap is not involved in the separation process.

Closer to the proposed engineering solution is a separator (patent RU 2244584), containing a vertical cylindrical body, a horizontal cover, an inlet, outlet, drain pipe, a deflector installed in the direction of rotation of the gas-liquid stream, a vertical separation package consisting of vertical flat curved plates forming slotted channels in the overlapping zone. The ends of the plates are bent and directed in different directions with respect to the outer and inner diameters of the separation bag. The axial line of the inlet pipe is horizontally offset relative to the axial line of the apparatus body. The deflector installed along the rotation of the gas-liquid flow has the maximum allowable cross-section, and along the flow it narrows horizontally and increases in height, while preserving the cross-sectional area. An arcuate plate covering the deflector in its upper part, at the end along the flow direction is directed relative to the horizontal at an angle of 15-30 °. In the direction of rotation of the gas-liquid flow with a gap to the inner side of the housing, a curved plate is installed, which with its lower end extends under the lower cover of the deflector.

A disadvantage of the known device is that, based on the optimal geometric dimensions (the ratio of the diameter of the apparatus to the height of the housing, the diameter of the separation bag, its height, the width of the deflector and other dimensions), worked out and determined by hydrodynamic tests, the distance between the surface of the deflector turned out to be a bottleneck and the outer surface of the separation bag.

In the process of separating the liquid and gas phases in the central part of the rotating stream, a zone of reduced pressure arises, which draws part of the separated air mass inward, thereby affecting the final performance of the separator.

The technical solution to the problem is to expand the range of the gas-liquid separator: increase the load in the gas phase without reducing the separation efficiency and increase the pressure loss.

The task is achieved by the fact that through holes are located in the center of the flat bottom of the separation bag and the false bottom, into which a hollow cylinder is mounted, the base of which is mounted on the false bottom, and the upper edge of the cylinder is raised relative to the surface of the flat bottom, a cylindrical mounted on the outer diameter of the lower surface of the false bottom a vertical diffuser with a notch, and a disk is attached directly under the hollow cylinder.

According to the patent and scientific and technical literature, the claimed nature of the totality of features was not found, which allows us to judge the inventive step of the proposal.

Figure 1 shows the liquid-gas separator "STsV-7" (vertical centrifugal separator of the seventh generation).

Figure 2 is a section aa of figure 1

The separator consists of a vertical cylindrical body 1 with an axis 0, a horizontal cover 2 with a cylindrical hole 3, over which an outlet pipe 4 is located, an inlet pipe 5 connected to the housing 1 in its upper part, a deflector 6 installed along the flow rotation and forming a rotational the movement of gas-liquid flow inside the separator. The axis 0 _{1 of the} vertical separation bag 7 is shifted relative to the axis of the apparatus 0 body so that the gap between the deflector 6 and the outer surface of the bag 7 corresponds to the gap on the opposite side, i.e. between the outer surface of the separation bag and the inner surface of the separator housing 1. The bag 7 consists of flat plates 8. The ends of the flat curved plates 8 are directed relative to the inner and outer diameters of the bag. The plates 8 are strengthened along the inner perimeter of the horizontal cover 2 and allow maintaining the same and constant size of the slotted channels in the area of their overlap 9.

In the upper part of the separation bag 7 between the lower outer surface of the outlet pipe 10, the inner surface of the upper part of the plates 8, an annular gap is formed, which together with the inner surface of the horizontal cover 2 formed a pocket-trap 11.

Inside the lower part of the separation plates 8 there is a flat bottom 12, raised relative to the lower edge of the plates 8, having a radial clearance 13 relative to them and connected by means of radial plates 14 at a distance of 0.1-0.15 of the diameter of the separation element with a false bottom 15. Between the housing separator 1 and a false bottom 15, an annular gap 16 is formed.

In the direction of rotation of the gas-liquid flow directly in front of the inlet pipe with a gap to the inside of the apparatus body, exceeding the height of the deflector, a curved plate 17 is installed, which, with its right end, goes under the bottom cover of the deflector.

In the center of the flat bottom 12 of the separation bag and the false bottom 15, there are central holes in which the hollow cylinder 18 is mounted, the base of which is mounted on the false bottom 15, and the upper edge of the cylinder is raised relative to the surface of the bottom 12 using brackets 19 and a ring 20 attached to plates 8, is fixed: cylinder 18, flat bottom 12, false bottom 15. On the outer diameter of the lower surface of the false bottom mounted cylindrical vertical diffuser with notches 21.

A disk 22 is mounted directly under the hollow cylinder 18. The separated liquid phase flows along the walls of the housing 1 into the accumulator tank of the separator 23, from where it is transported to the drain hole 25 along the bottom of the separator 24. A nozzle 26 is installed to the bottom 24 to periodically remove accumulated suspended particles, if any take place.

The separator works as follows.

The gas-liquid mixture is supplied to the apparatus through the inlet pipe 5 located in its upper part. The installation of the inlet pipe, horizontally offset relative to the axial line of the housing, allows you to create a sliding impact on the surface of the deflector 6, installed in the direction of flow rotation, the maximum displacement value is determined by the factor, which should not be used to additionally strengthen the strength of the seam of the part.

The deflector 6 prevents the flow of gas into the axial zone of the separation package 7 without prior separation of the gas suspension. The use of a baffle with a variable cross-section (at the beginning it increases its cross-section to the maximum permissible value, after which it tapers horizontally and increases in height, while maintaining the cross-sectional area in the widest possible section) allows you to: minimize pressure loss in this area by maintaining the speed due to the preservation of the living cross section, remove horizontally at the outlet of the deflector the gas-liquid flow from the slotted channels of the separation bag 7, and uniformly Reduce the load in the liquid phase and at the same time, “press” the liquid phase to the inner surface of the separator housing due to the minimum deflector clearance at the outlet and surface tension, which ultimately improves the separation process.

In the space formed by the wall of the housing 1 and the plates 8, the bulk of the liquid is released from the gas stream. Drops of liquid are discarded by centrifugal force on the walls of the separator housing 1 and under the influence of gravitational forces along the rotation of the gas stream in a downward spiral are transported through an annular gap 16 to the drain pipe 25.

A finely divided droplet liquid that has not settled on the housing 1 enters the outer surface of the vertical plates 8 and is transported by a gas stream through the tangential inlet slots, falling onto their inner surface.

Since the tangential gaps do not narrow downstream, the pressure loss to local resistances is reduced, which will generally affect the pressure loss in the apparatus.

The use of plates 8, the curved ends of which are directed in opposite directions with respect to the inner diameter of the separation package, allows a liquid film moving along the rotation of the gas stream to be transported from the end of one plate to the beginning of another, while maintaining a tangent trajectory of its movement relative to the breakdown of the plates the inner diameter of the separation bag.

The presence of the rotational movement of the gas (air) stream inside the separation package creates a zone of reduced pressure in the central part of the rotating air mass, as a result of which, if there is a hollow cylinder, the previously stationary cleaned stream starts moving and is transported through cylinder 18 to the outlet, thereby increasing productivity and the movement of the gas-liquid flow between the apparatus and the outer surface of the separation bag in a downward spiral. The bulk of the gas (air) in a downward spiral enters the separation bag, part rushes through the annular gap 16 towards the storage tank 23. Passing through the slot 21, the flow loses centrifugal force and is sucked into the hollow cylinder in a calm state. The mass of the gas-liquid flow rushes downward into the separation package in a spiral, and is divided into 3 layers: directly at the wall — directed downward, then an insignificant layer “fixed” and the next - the main layer directed upward. The presence of the first layer with the direction of the axial velocity vector downward allows dropping (depending on the mode) dew, drops, film downward, avoiding additional guides that remove particles of the liquid phase in a spiral downward.

Descending along the inner surface of the plates 8, the liquid particles, approaching the lower edge, slide off and fall onto the surface of the false bottom 15, from where they are transported through the annular gap 16 in the direction of the drain pipe 25.

Thus, the implementation of the proposed small-sized high-performance separator allows you to:

1) increase the separator productivity in the gas phase, transporting additional flow through the hollow cylinder;

2) since the energy was laid in order to obtain a zone of reduced pressure, the presence of a hollow cylinder through which the gas flow went does not cause additional pressure losses in the separator;

3) the shift of the axes 0 and 0 ₁ allows the separator to successfully operate in the discharge of gas-liquid devices and liquid-gas (i.e., the same design successfully covers two types of separators).

Claims (1)

A separator comprising a vertical cylindrical body, a horizontal cover, an inlet, outlet, drain pipe, a deflector installed in the direction of rotation of the gas-liquid stream, a vertical separation package with a flat bottom, consisting of flat curved separation plates forming slotted channels in the lap zone and their vertical curved ends directed in different directions with respect to the outer and inner diameters of the separation bag, a false bottom, characterized in that the center is flat through the bottom of the separation package and the false bottom, through holes are made in which a hollow cylinder is mounted, the base of which is mounted on the false bottom, and the upper edge of the cylinder is raised relative to the surface of the flat bottom, a cylindrical vertical diffuser with notches is mounted along the outer diameter of the lower surface of the false bottom, and directly a disk is attached under the hollow cylinder.

Images