RU73803U1 - GAS VORTEX VALVE SEPARATOR - Google Patents

Abstract

The utility model is designed to capture fine and aerosol liquid and solid particles from a gas stream, and is used in the oil, gas, chemical and other industries.

This achieves automatic maintenance of a constant gas flow velocity at the outlet of the deflector (and, therefore, efficiency) in a wide range of gas productivity (flow), that is, in a wide range of flow parameters at the inlet to the separator.

The separator contains a vertical cylindrical body, upper and lower bottoms, inlet, outlet and drain pipes, a separation bag, a false bottom, a deflector located at the inlet pipe, and limited by the inner surface of the separator body wall, a curved wall, upper and lower covers of the deflector. At the same time, an elastic plate is cantilevered at the exit from the deflector to the curved wall, partially overlapping the deflector outlet at an acute angle to the gas stream exiting from it. The elastic plate is able to deviate to the axis of the separator under the action of the flow coming out of the deflector.

3 cp, 3 ill.

Description

The utility model is designed to capture fine and aerosol liquid and solid particles from a gas stream, and is used in the oil, gas, chemical and other industries.

A group of separators is known among gas separators (RF patent No. 2064326 for the invention, IPC 6 B01D 45/12, 1996 [1]; RF patent No. 2136350 for the invention, IPC 6 B01D 45/12, 1999 [2]; RF patent No. 2188062 for invention, IPC 7 B01D 45/12, 2002 [3]; RF patent No. 2221625 for the invention, IPC 7 B01D 45/12, 2004 [4]; RF patent No. 52731 for utility model, IPC B01D 45/12, 2006 [5 ]; RF patent No. 2244584 for an invention, IPC 7 B01D 45/12, 2005 [6]; RF patent No. 55636 for a utility model, IPC B01D 45/02, B01D 45/16, B01D 45/18, 2006 [7]) containing a vertical cylindrical body, inlet and outlet nozzles, a deflector, a separation element with vertical slots bubbled channels and the axial disc disposed below the separating element.

The disadvantage of these devices is the inefficient design of the input gas-liquid mixture into the space around the separation element. As you know, the parameters (including geometric dimensions) of vertical vortex-type gas separators are determined based on a given range of productivity (flow). It is well known that for these separators [1-7], the efficiency is satisfactory if the flow rate varies within ± 20% (L.M. Milshtein, S.I. Boyko, E.P. Zaporozhets Oil and gas separation technology. Moscow, Nedra, 1991. [8]). In most applications, this condition is met for at least a satisfactory period of time. However, in cases where this condition ceases to be fulfilled, it is necessary to replace the separator with another, whose characteristics correspond to a change in flow rate. Such a replacement leads to the consumption of materials and additional labor costs.

To ensure the efficient operation of vortex-type vertical gas separators, the design of introducing a gas stream into the separator should provide such a flow rate at the outlet of the deflector that is favorable for the purpose of separation of the flow by inertial forces when it is swirling around the separation package. Moreover, the mentioned flow velocity at the outlet of the deflector is determined by the cross-sectional area of the deflector outlet in accordance with the equation

continuity of the medium (ρ ₁ S ₁ V ₁ = ρ ₂ S ₂ v ₂ ), where ρ is the density of the medium, S is the cross-sectional area of the channel, and v is the flow velocity of the medium. In this case, the flow rate at the outlet of the deflector v is determined from the relation

where Q is the flow rate and S is the cross-sectional area of the deflector outlet. From this relation it follows that, with a constant cross-sectional area of the outlet of the deflector S, which takes place in analog separators [1–7], the flow rate at the outlet of the deflector is directly proportional to the flow rate. This circumstance also causes a change in the efficiency of the separators [1-7] with a change in performance (flow). With a decrease in flow rate Q, the flow rate at the outlet v of the deflector decreases, lesser inertial forces act on the particles of impurities and droplet moisture, a smaller part of them reaches the walls of the separator, i.e., the degree of separation of the flow decreases. This leads to a decrease in the efficiency of the separator.

The technical problem to which the claimed utility model is directed is to expand the range of performance (flow) values at which the separator efficiency remains unchanged.

The technical result provided by the claimed utility model is to automatically maintain a constant gas flow rate at the outlet of the deflector in a wide range of gas productivity (flow), that is, in a wide range of flow parameters at the inlet of the separator. The indicated constancy of the gas flow velocity at the outlet of the deflector ensures the same separator efficiency for both small flow rates and medium and large ones. This allows you to effectively use the same separator when changing, including significant, flow parameters at the inlet to the separator.

The essence of the utility model is that the gas vortex-type separator comprises a vertical cylindrical body, upper and lower bottoms, an inlet, outlet and drain pipe, a separation bag, a false bottom, a deflector located at the inlet pipe, and limited by the inner surface of the separator body wall, curved wall, upper and lower covers of the deflector. At the same time, an elastic plate is cantilevered at the exit from the deflector to the curved wall, partially overlapping the deflector outlet at an acute angle to the gas stream exiting from it. Resilient

the plate is able to deviate to the axis of the separator under the action of the flow coming out of the deflector.

It is preferable to make an elastic plate of a material based on rubber and stick it to the curved wall of the deflector from the side of the separation package. It is advisable to rigidly fix the reflective plate to the curved wall of the deflector, which forms, together with the inner wall of the housing and the curved wall of the deflector, a trap pocket open from below.

The figure 1 shows a diagram of a separator, a longitudinal section (section BB of figure 2); figure 2 is a diagram of the separator, a cross section (section aa of figure 1); figure 3 - diagram of the separator, a cross section, example 2.

The gas vortex type separator (Fig. 1) contains a vertical cylindrical body 1, upper 2 and lower 3 bottoms, inlet 4, outlet 5 and drain 6 nozzles, deflector 7, separation bag 8, false bottom 9.

The inlet pipe 4 is rigidly fixed in the cylindrical housing 1 of the separator.

The deflector 7 is located at the inlet pipe 4 and is designed to form a rotational (vortex) movement of the gas stream inside the separator. The deflector 7 also prevents the flow of gas into the axial zone of the separator without prior separation.

The deflector 7 is limited by the inner surface of the wall of the separator housing 1, the upper 10 and lower 11 of the deflector covers 7, rigidly fixed to the wall of the housing 1, as well as the curved wall 12. The curved wall 12 is rigidly fixed to the wall of the separator housing 1 and to the adjacent faces of the covers (10, 11) deflector 7.

At the outlet of the deflector 7 along its entire height, an elastic plate 13 is placed vertically cantilevered to the curved wall 12 of the deflector (Fig. 2). The elastic plate 13 blocks the outlet of the deflector 7 at an acute angle to the gas stream exiting from it. The elastic plate 13 is made with the ability to deviate to the axis of the separator under the action of the gas flow coming out of the deflector 7. The elasticity and size of the plate 13 is calculated mainly in such a way as to ensure the value of the effective outlet cross section of the deflector 7 is directly proportional to the flow rate of the gas stream through this section. This, in accordance with expression (1), provides a constant value of the velocity at the outlet of the deflector 7, and, therefore, a constant value of the efficiency of the inertial separation stage in the space between the separation package 8 and the wall of the separator body 1.

All other things being equal, the indicated means the invariance of the efficiency of the entire separator.

A drain pipe 6 is located in the lower bottom 3 of the separator.

The separation package 8 is made of a cylindrical shape and contains a flat curved separation plate 15 located in its forming surface, and forming identical and constant size slotted channels 16 in the lap zone (Fig. 2). Flat curved plates 15 are rigidly fixed in the lower part to the lower axial disk 17 (Fig. 1). The disk 17 is rigidly fixed to the finger 18, the end of which is located without a gap in the hole of the false bottom 9, located with an annular gap to the vertical housing 1, and rigidly fixed to the housing 1 using the L-shaped plates 19. In this case, the separation package 8 is located in the axial the separator zone so that the axis of the separation package 8 is parallel to the axis of the cylindrical body 1 of the separator and offset relative to it.

Above the lower axial disk 17 is located the upper axial disk 20, connected to it by means of radial plates 21. The plates 21 are also designed to eliminate the rotational effect of the gas flow below the zone of their location.

Examples of specific performance.

Example 1

The elastic plate 13 is made of a material based on rubber and glued to the curved wall 12 of the deflector 7 from the side of the separation package 8.

Example 2

A reflective plate 22 is rigidly fixed to the curved wall 12 of the deflector 7 (Fig. 3). The inner wall of the housing 1, the curved wall 12 of the deflector 7 and the reflective plate 22 form a trap pocket 23 open from the bottom. The pocket 23 is designed to divert moving fluid and solids pressed by a centrifugal force from the vortex from the inner wall of the separator housing 1 and transport them to the lower cumulative part of the separator.

The implementation of the structural elements of the claimed utility model is not limited to the above examples.

The inventive gas separator vortex type operates as follows.

The gas to be cleaned (crude gas) is fed into the apparatus through the inlet pipe 4. The deflector 7 smoothly changes the direction of gas movement and forms its vortex movement around the separation package 8.

The gas flow exiting from the deflector 7 acts on the elastic plate 13, deflecting it to the axis of the separator and thereby forming an effective section S of the outlet of the deflector 7, which is directly proportional to the flow rate Q. This, in accordance with expression (1), ensures a constant velocity of particles exiting deflector 7, regardless of the flow rate Q.

In the space formed by the wall of the housing 1 and the separation package 8, the bulk of the liquid and mechanical impurities are released from the gas stream. Liquid droplets and a mechanical impurity are discarded by centrifugal force on the walls of the separator housing 1 and, under the influence of gravitational forces, move along this wall in a downward spiral in the direction of rotation of the gas stream. Reaching the plane of the false bottom 9, the liquid and mechanical impurities pass through the annular gap between the housing 1 and the false bottom 9, and are transported to the drain pipe 6.

A finely divided droplet liquid that has not settled on the wall of the housing 1 enters the outer surface of the flat curved plates 15 and is transported by gas flow through the slotted channels 16 to their inner surface. Descending along the inner surface of the plates 15, liquid particles, approaching the lower edges of these plates 15, slide off them and fall on the surface of the false bottom 9, from where they are transported through the annular gap between the housing 1 and the false bottom 9 to the drain pipe 6.

The cleaned gas stream is sent to the outlet pipe 5.

In the claimed utility model, the claimed technical result: “automatic maintenance of a constant gas flow rate at the outlet of the deflector in a wide range of gas productivity (flow), that is, in a wide range of flow parameters at the inlet of the separator” is achieved due to the fact that the gas vortex separator type contains a vertical cylindrical body, upper and lower bottoms, inlet, outlet and drain pipes, a separation bag, a false bottom, a deflector located at the inlet pipe, and ogre nychenny internal surface of the wall of the separator housing, a curved wall, the upper and lower covers of the deflector. At the same time, at the exit from the deflector to the curved wall, an elastic plate is cantilevered, partially overlapping the outlet of the deflector under

acute angle to the gas stream exiting from it. The elastic plate is able to deviate to the axis of the separator under the action of the flow coming out of the deflector.

The inventive gas vortex-type separator can be manufactured at a machine-building enterprise.

INFORMATION SOURCES.

1. RF patent No. 2064326 for the invention, IPC 6 B01D 45/12, 1996.

2. RF patent No. 2136350 for the invention, IPC 6 B01D 45/12, 1999.

3. RF patent No. 2188062 for the invention, IPC 7 B01D 45/12, 2002.

4. RF patent No. 2221625 for the invention, IPC 7 B01D 45/12, 2004.

5. RF patent No. 52731 for a utility model, IPC B01D 45/12, 2006.

6. RF patent No. 2244584 for the invention, IPC 7 B01D 45/12, 2005.

7. RF patent No. 55636 for utility model, IPC B01D 45/02, B01D 45/16, B01D 45/18, 2006.

8. L. M. Milshtein, S. I. Boyko, E. Z. Zaporozhets Oil and gas separation technology. Moscow, Nedra, 1991.

Claims (4)

1. The gas vortex type separator containing a vertical cylindrical body, upper and lower bottoms, inlet, outlet and drain pipes, a separation bag, a false bottom, a deflector located at the inlet pipe and bounded by the inner surface of the separator body wall, a curved wall, upper and lower deflector covers, characterized in that at the outlet of the deflector to the curved wall, an elastic plate is cantilevered, partially overlapping the deflector exit at an acute angle to the gas outlet otoku and made with the ability to deviate to the axis of the separator under the action of the flow coming out of the deflector. 2. The separator according to claim 1, characterized in that the elastic plate is made of a material based on rubber. 3. The separator according to claim 2, characterized in that the elastic plate is glued to the curved wall of the deflector from the side of the separation package. 4. The separator according to any one of claims 1 to 3, characterized in that a reflective plate is rigidly fixed to the curved wall of the deflector, forming together with the inner wall of the housing and the curved wall of the deflector a trap pocket open from below.