RU87100U1 - GAS-LIQUID SEPARATOR - Google Patents

Abstract

The utility model relates to equipment for cleaning gas from liquids and solids and can be used in the oil, gas and other industries, and specifically, when measuring the flow rate of wells in oil fields.

The gas-liquid separator comprises a housing with nozzles for the inlet of the gas-liquid mixture and the outlet of gas and liquid, and a drop eliminator. New is the fact that in the lower part of the casing there is a kinetic energy absorber made in the form of a perforated cone facing the apex of the lower bottom, in addition, the lower part of the casing is equipped with a liquid level meter.

In addition, the profile of the holes made on the surface of the perforated cone is made with a flange facing the upper bottom.

In addition, the profile of the holes made on the surface of the perforated cone is made in the form of truncated cones, facing a large base to the upper bottom.

In addition, guide vanes are installed at the base of the perforated cone. 3 s.p. f-ly, 1 ill.

Description

The utility model relates to equipment for cleaning gas from liquids and solids and can be used in oil, gas and other industries, specifically, when measuring the flow rate of wells in oil fields.

A known gas separator according to the patent of the Russian Federation No. 2091134 (IPC ⁷ B01D 45/12, publ. 09/27/1997), comprising a vertical housing with a raw gas inlet and outlet for separated media, a grill arranged in the housing, made in the form of longitudinal parallel sections containing one or more rows of separation elements, and a drain pipe.

Common signs of the known separator with the proposed are the presence in the separator of a vertical housing with inlet and outlet nozzles and a drop chamber.

A disadvantage of the known design is the inefficient operation of the separator, because the hopper covers a significant part of the passage section of the apparatus, as a result, the hydraulic resistance of the separator increases significantly. In addition, in this design on the canvas, you can set a limited number of separation elements. Therefore, with an increased content of mechanical impurities in the gas, the reliability of the separator and its performance are significantly reduced.

The closest in technical essence and the achieved result to the proposed one is a gas-liquid separator according to the patent of the Russian Federation No. 2153915 (MPK ⁷ B01D 45/00, V01D 19/00, publ. 10.08.2000), containing a housing with nozzles for the entrance of the gas-liquid mixture and the outlet of gas and liquid A droplet eliminator and drainage tubes are placed in the coagulator housing and installed in front of the gas outlet pipe. A distribution box is installed between the base of the coagulator and the wall of the housing, the horizontal element of which is connected to the housing wall, and the vertical element is connected to the base of the coagulator in such a way that the cavity formed by the wall of the housing and the distribution box is connected to the cavity of the gas-liquid mixture inlet pipe. Centrifugal elements are installed on the bases of the coagulator and droplet eliminator.

Common features of the known separator with the proposed are: a vertical housing with nozzles for the inlet of the gas-liquid mixture and the outlet of gas and liquid and a droplet collector.

A disadvantage of the known separator is the insufficiently effective degassing of the separated liquid and, accordingly, the insufficient efficiency of gas and liquid separation, especially in cases of high liquid content in the separated mixture.

The technical problem is to achieve high separation efficiency of the gas-liquid mixture by reducing the entrainment of gas with liquid.

The problem is achieved in that in a gas-liquid separator containing a housing with nozzles for the inlet of the gas-liquid mixture and the outlet of gas and liquid and a droplet eliminator, it is new that a kinetic energy absorber is installed in the lower part of the housing, made in the form of a perforated cone with its apex facing the bottom in addition, the lower part of the housing is equipped with a liquid level meter.

In addition, the profile of the holes made on the surface of the perforated cone is made with a flange facing the upper bottom.

In addition, the profile of the holes made on the surface of the perforated cone is made in the form of truncated cones, facing a large base to the upper bottom.

In addition, guide vanes are installed at the base of the perforated cone.

Placing kinetic energy absorber in the lower part of the separator in the form of a perforated cone facing the bottom of the apex allows you to quench the kinetic energy of the liquid flowing down, transfer it to the film flow regime, intensifying the degassing process and the residence time of the liquid in the degassing zone, in as a result, organizing a smooth flow of fluid into the still bottom of the apparatus.

Placing a perforated cone in the area of the liquid level meter installed in the lower part of the housing prevents the occurrence of a falling jet, which, by inertia, penetrates below the liquid level, carries away the gas phase.

The implementation of the profile of the holes in the form of a flanging or in the form of a truncated cone allows you to portionwise select the liquid from the stream and smoothly divert it down the apparatus.

The supply of the base of the perforated cone with guide vanes allows you to give the flow a rotational movement, thereby organizing a smooth entry of fluid into the still bottom of the apparatus.

Figure 1 shows a General view of the gas-liquid separator, figure 2 - view aa, figure 3 - the holes in the perforated cone according to the first embodiment, figure 4 - the holes in the perforated cone according to the second embodiment.

The separator contains a vertical housing 1, a tangentially located nozzle of the inlet 2 of the gas-liquid mixture, a nozzle of the gas outlet 3 and a nozzle of the liquid outlet 4. A distribution box 5 is placed in the upper part of the housing 1. In the lower (cubic) part, the housing 1 is equipped with a liquid level meter 6. In the lower part of the housing in the region of the liquid level meter 6, a kinetic energy absorber 7 is installed, made in the form of a cone perforated with holes 8. The profile of the hole 8 can be made with a flange 9, facing the upper bottom 10. The profile of the hole 8 can be made in the form of a truncated cone 11, facing a large base to the upper bottom 10. Quencher of kinetic energy 7 It becomes such that the vertex of the cone faces the lower bottom 12. The perforated cone 7 is placed at the bottom of the separator so that the part 7 of the cone is always submerged in liquid bottoms. In the upper part of the housing 1 there is a droplet eliminator 13 containing two blades 14 on which centrifugal separation elements 15 are mounted. At the base of the perforated cone 7, guide vanes 16 are installed. The separator is equipped with drainage pipes 17 for draining the separated liquid.

The gas-liquid flow is fed into the separator through the inlet pipe 2 tangentially and swirls in the cavity between the housing 1 and the distribution box 5. This achieves a preliminary separation of the gas-liquid flow. The liquid in the form of a film flows down the inner wall of the separator into the still part, moving in a spiral. The perforated cone 7 located in the cubic part of the separator provides damping of the energy of the liquid film at different levels of liquid in the cubic part of the separator. This is achieved by changing the direction of fluid movement and the presence of holes 8 in the perforated cone 7, as well as by the concentration of the flow in the central part of the cone 7. Gas after preliminary separation is sent to the droplet eliminator 13, where there are two stages of separation that reduce the secondary entrainment of droplet liquid from the separator. The liquid separated in the centrifugal elements 15 of the drop eliminator 13, under the action of gravity, merges into the bottom part of the separator through the drainage pipes 17.

Claims (4)

1. A gas-liquid separator comprising a housing with nozzles for the inlet of a gas-liquid mixture and an outlet for gas and liquid and a droplet separator, characterized in that a kinetic energy absorber is installed in the lower part of the housing, made in the form of a perforated cone facing the apex to the lower bottom, in addition, the lower part the housing is equipped with a liquid level meter. 2. The gas-liquid separator according to claim 1, characterized in that the profile of the holes of the perforated cone is made with a flange facing the upper bottom. 3. The gas-liquid separator according to claim 1, characterized in that the profile of the holes of the perforated cone is made in the form of truncated cones, facing a large base to the upper bottom. 4. The gas-liquid separator according to claim 1, characterized in that guide vanes are installed at the base of the cone.