RU126265U1 - MASS EXCHANGE DEVICE (OPTIONS) - Google Patents

Abstract

1. Mass transfer plate containing a base with holes for the passage of gas (steam), a receiving device with an overflow bar, a drain device with a drain bar, a switchgear installed on the base along the overflow bar, characterized in that the switchgear is a grate made of longitudinal and transverse stripes, and the length of the grate is at least equal to the length of the overflow bar, the bottom end of the grating is installed on the base, and the longitudinal strip of the grating following its lower ortsom situated above the top edge of the overflow planki.2. Mass transfer plate according to claim 1, characterized in that the extreme longitudinal strip of the upper end of the switchgear is adjacent to the drain strip of the upstream base across the entire width of the drain strip. Mass transfer plate according to claim 1, characterized in that the upper end of the switchgear is installed at a distance of at least equal to one quarter of the distance between the bases of the plates. Mass transfer plate according to claim 1, characterized in that the longitudinal stripes of the grating are installed at an acute angle to the base in the direction from the receiving device. Mass transfer plate according to claim 1, characterized in that the transverse bars of the grating are fan-shaped relative to the center of the grating in the direction from the receiving device. Mass transfer plate containing a base with openings for the passage of steam (gas), a receiving device, a drain device with a drain bar, a switchgear installed on the base along the receiving device, characterized in that

Description

The utility model relates to the design of absorption and distillation columns and can be used in gas, oil, petrochemical and other industries.

Known dish column containing plates, each of which is a base with holes for the passage of steam (gas) with drain pockets for liquid between adjacent plates. Under the outlet openings and at a distance from the loaded plate, there is a distributing device in the form of a deflector with a plurality of holes that deflect the liquid stream in accordance with the diverging flow field. The baffles contribute to the formation of transverse velocity components, so that the longitudinal component of the flow velocity in each plane perpendicular to the direction of the main flow has a substantially constant profile. The outlet openings are made of different sizes, less in the central section than in the neighboring flanks. (RF patent for the invention No. 2233193, IPC 7 B01D 3/20, B01F 3/04, publ. 07.27.2004).

Common features of a known solution and proposed solutions are

- a base with holes for the passage of steam (gas);

- drain pocket;

- Switchgear.

The disadvantages of the known design is the ineffective distribution of the fluid flow exiting from the overflow plate overflow device and falling onto the base of the underlying plate under heavy fluid loads when its gradient at the outlet of the overflow device is higher than the upper point of the deflectors, which reduces the overall efficiency of the plate.

The closest in technical essence and the achieved technical result to the proposed technical solution is a bubble column dish, including a housing in which at least two mass transfer plates are installed for contact between the gas (vapor) and the liquid, each of which includes a base with holes for the passage of gas (steam), a receiving device (pocket) with an overflow bar, a drain device (pocket) with a drain bar, a partition, according to the function performed - a distribution device GUT installed across the flow at the receiving apparatus. The switchgear is symmetrically curved with a bulge towards the receiving pocket with vertical rectangular windows in the lower part and piers touching the side walls of the column, and the height of the device windows is higher than the height of the gas-liquid layer on the plate, and equipped with a lower rail attached to all the piers in the lowest part of the partition, and the partition is mounted on a plate so that the bottom rail is firmly in contact with the base of the plate (RF Patent for invention No. 2060766, IPC ⁶ B01D 3/22, publ. 05.27.1996).

Common features of the known and proposed solutions for the first option are:

- housing;

- at least two base plates with openings for the passage of gas (steam);

- the base of the plate has a receiving device with an overflow bar;

- the base of the plate has a drain device with a drain bar, the lower end of which is installed in the receiver of the underlying base;

- a switchgear mounted on the base of the plate along the overflow bar.

Common features of the known and proposed solutions for the second option are:

- housing;

- at least two base plates with openings for the passage of gas (steam);

- the base of the plate has a receiving device;

- the base of the plate has a drain device with a drain bar, the lower end of which is installed in the receiver of the lower base of the plate;

- a switchgear mounted on a base along the receiving device.

The disadvantages of the known design are the high resistance of the switchgear to the fluid flow, compared with the claimed device, as well as the uneven distribution of the fluid flow coming out of the overflow device and falling on the plate base under heavy loads on the liquid, when its gradient at the outlet of the overflow device is higher than the top the edge of the partition, which reduces the efficiency of mass transfer on the plate and the column as a whole.

The technical result is to increase the efficiency of mass transfer of the column, due to the calming and ordering of the entire fluid flow emerging from the overflow device of the base of the plate, as well as its uniform distribution along the base of the plate.

This result is achieved by the fact that, according to the first embodiment, in the known construction of a mass transfer apparatus comprising a body, at least two base plates with openings for the passage of gas (steam), each of which has a receiving device with an overflow bar, a drain device with a drain bar, the lower end of which is installed in the receiving device of the lower base, the switchgear installed on the base along the overflow bar, inlet and outlet nozzles, new is that the distribution stroystvo is a grating formed of longitudinal and transverse strips, and grating length at least equal to the length of the overflow strips, based on trays installed the lower end of the lattice, and longitudinal band grating that follows its end face located above the upper edge of the overflow plate.

This result is also achieved by the fact that according to the second embodiment, in the known design of the mass transfer apparatus comprising a housing, at least two bases with openings for the passage of gas (steam), each of which has a receiving device, a drain device with a drain bar, the lower end of which installed in the receiving device of the underlying base, a switchgear installed on the base along the overflow bar, inlet and outlet pipes, new is that the switchgear is a grating formed of longitudinal and transverse strips, wherein the lattice length at least equal to the length of the receiving device which is designed as a pocket recessed relative to the base plate, wherein the lower end of the lattice mounted on the base, along the edge of the pocket.

In addition, the extreme longitudinal strip of the upper end of the switchgear according to any of the options can be made adjacent to the drain plate of the upstream base of the plate over the entire width of the drain plate.

In addition, the upper end of the switchgear according to any of the options can be installed at a distance of at least equal to one quarter of the distance between the bases of the plates.

In addition, the longitudinal strips of the switchgear according to any of the options can be installed at an acute angle to the base in the direction from the receiving device.

In addition, the transverse strip according to any of the options can be installed fan-shaped relative to the center of the grating in the direction from the receiving device.

The proposed set of features, namely the installation of a switchgear on the base along the overflow device, which is a grate made of longitudinal and transverse strips, according to the first or second option, can provide a calming flow of fluid leaving the overflow device using longitudinal strips, as well as with the help of transverse stripes at the same time it allows you to evenly distribute it along the base of the plate, providing an efficient mass transfer process on the plate and increasing the effect vnost column as a whole.

Performing the length of the grate at least equal to the length of the overflow bar in the first embodiment or equal to the length of the receiving device in the second embodiment ensures the supply of the entire fluid flow to the grate and uniform distribution of fluid across the entire width of the base of the plate

The location according to the first embodiment of the lower end of the grating on the base of the plate, and the location of the longitudinal strip of the grating following its end above the upper edge of the overflow plate allows you to evenly distribute the liquid along the base of the plate, and the location of the upper end of the grating at a distance of at least a quarter of the distance between the bases of the plates allows you to calm and direct the entire fluid flow in a horizontal plane, reducing the gradient of the liquid level at the outlet of the overflow device.

The implementation of the receiving device in the form of a pocket recessed relative to the base of the plate according to the second embodiment, where the lower end of the grating of the switchgear is mounted on the base, along the edge of the pocket, makes it possible to increase the efficiency of the mass transfer plate, since in this case the liquid flow rising from the buried pocket is immediately fed into switchgear, evenly distributed in the longitudinal and cross-section of the grate along the base of the plate.

The adjacency of the extreme longitudinal strip of the upper end of the switchgear to the drain plate of the upstream base of the plate over the entire width of the drain plate, according to the first option and the second option, allows you to direct the entire fluid flow through the switchgear under any fluid loads.

The arrangement of the longitudinal stripes of the grating according to the first and second variant at an acute angle to the base in the direction from the receiving device, i.e. in the direction of fluid movement from the receiving device to the base, it allows to calm the fluid flow at high fluid loads, thereby reducing the liquid level gradient at the base of the plate in the area of its exit from the overflow device, which also increases the efficiency of the mass transfer process on the plate.

The installation of transverse strips of the grid fan-shaped relative to the center of the grid in the direction from the overflow bar, i.e. in the direction of movement of the liquid from the receiving device to the base, according to the first and second embodiment, it allows you to evenly distribute the liquid throughout the base of the plate.

Thus, the claimed combination of features provides an increase in the efficiency of mass transfer of the column as a whole.

Figure 1 shows the mass transfer apparatus in a perspective view, figure 2 is a longitudinal section, according to the first embodiment, figure 3 is a section along aa, figure 4 is a mass transfer apparatus according to the second embodiment, figure 5 shows the implementation of the device according to dependent clause 5 of the formula.

The mass transfer apparatus according to the first embodiment (see FIG. 1) includes a base plate 1 with holes for the passage of gas (steam) 2 installed in the housing 3 of the apparatus. Openings for the passage of gas (steam) 2 can be provided with valves, caps and other contact elements. On the one hand, to the base of the plate 1 is adjacent a receiving device 4 having an overflow bar 5, and on the other hand, a drain device 6 having a drain bar 7, the lower end of which is installed in the receiving device 4 of the underlying plate. On the base of the plate 1 along the overflow bar 5, a switchgear 8 is installed, which is a grating consisting of longitudinal strips 9 and transverse strips 10. The length of the switchgear 8 is at least equal to the length of the overflow bar 5. At the base of the plate 1, the lower end of the distribution device 8, and the longitudinal strip 9, following its lower end, is located above the upper edge of the overflow bar 5. The upper end of the switchgear 8 can be installed at a distance of "h", at least th least equal to one quarter of the distance «H» between the base plates 1 adjacent plates (see Fig. 5). The extreme longitudinal strip 9 of the upper end of the switchgear 8 can be made adjacent to the drain plate 7 of the upstream base of the plate 1 over the entire width of the drain plate 7 (see figure 2).

According to the second option (see figure 4), the mass transfer apparatus also includes a base plate 1 with openings for the passage of gas (steam) 2, installed in the housing 3 of the apparatus. On the one hand, a receiving device 4 adjoins the base of the plate 1, which is made in the form of a pocket 11 buried relative to the base of the plate 1, and on the other hand, a drain device 6 having a drain bar 7, the lower end of which is installed in the buried pocket 11 of the underlying plate . The distribution device 8, which is a grill described above in the device according to the first embodiment, has a length of at least equal to the length of the recessed pocket 11, while the lower end of the distribution device 8 is installed on the base of the plate 1, along the edge of the pocket 11, and the upper end switchgear 8 can be installed at a distance "h" of at least one quarter of the distance "H" between the bases 1 of the nearby plates. The extreme longitudinal strip 9 of the upper end of the switchgear 8 can be made adjacent to the drain plate 7 of the upstream base of the plate 1 over the entire width of the drain plate 7.

Longitudinal strips 9 according to the first embodiment and the second embodiment can be installed at an acute angle "α" to the base of the plate 1 in the direction from the receiving device 4 (Fig. 5).

In addition, the transverse strip 10 can be installed fan-shaped relative to the center of the grating in the direction from the receiving device 4 as in the first embodiment, and in the second embodiment of the mass transfer plate (figure 3).

Mass transfer apparatus operates as follows.

According to the first option (see Fig. 1), the fluid flow enters the base of the plate 1 from the overlying cloth from the receiving device 4, flowing through the overflow bar 5, enters the switchgear 8, where when interacting with the longitudinal strips 9 and transverse strips 10, the fluid flow calms down, at the same time evenly distributed on the base of the plate 1, on which the liquid is in contact with the gas entering the base of the plate 1 through the holes for the passage of gas (steam) 2, after which the fluid flow passes through the drain GCC 7 into the drain device 6 and further to the underlying plate.

When performing the extreme longitudinal strip 9 of the switchgear 8 adjacent to the drain plate 7 of the overlying plate 1, the fluid flow (especially at high loads) coming from the overflow device 6, all passes through the switchgear 8, not having the ability to flow through the top of the switchgear 8.

When the upper end of the switchgear 8 is located at a distance of at least one quarter of the distance between the bases of the plates 1, the fluid flow at high loads forms a gradient, all passes through the switchgear 8.

In the case when the longitudinal strips 9 of the dispenser 8 according to any of the options are installed at an acute angle to the base of the plate 1 in the direction from the receiving device 4, the fluid flow passing through the dispenser 8 is effectively calmed, forming a relatively uniform layer of liquid on the plate.

In the case when the transverse strips 10 according to any of the options are mounted fan-shaped relative to the center of the dispenser 8 in the direction from the receiving device 4, the fluid flow passes through the dispenser 8 to the walls of the apparatus body 3, eliminating the possibility of formation of stagnant zones.

According to the second option (see figure 4), the fluid flow, rising from the pocket 11, flowing through its end, immediately enters the switchgear 8, and immediately at the base of the plate 1, the fluid flow is calmed down and uniformly distributed along the base of the plate 1. Next the mass transfer process occurs, as described above, in the case of the mass transfer apparatus according to the first embodiment.

Claims (10)

1. Mass transfer plate containing a base with holes for the passage of gas (steam), a receiving device with an overflow bar, a drain device with a drain bar, a switchgear installed on the base along the overflow bar, characterized in that the switchgear is a grate made of longitudinal and transverse stripes, and the length of the grate is at least equal to the length of the overflow bar, the bottom end of the grating is installed on the base, and the longitudinal strip of the grating following its lower ortsom situated above the top edge of the overflow plate. 2. Mass transfer plate according to claim 1, characterized in that the extreme longitudinal strip of the upper end of the switchgear is adjacent to the drain plate of the upstream base across the entire width of the drain plate. 3. Mass transfer plate according to claim 1, characterized in that the upper end of the switchgear is installed at a distance of at least one quarter of the distance between the bases of the plates. 4. Mass transfer plate according to claim 1, characterized in that the longitudinal stripes of the grating are installed at an acute angle to the base in the direction from the receiving device. 5. Mass transfer plate according to claim 1, characterized in that the transverse bars of the grating are fan-shaped relative to the center of the grating in the direction from the receiving device. 6. Mass transfer plate containing a base with openings for the passage of steam (gas), a receiving device, a drain device with a drain bar, a switchgear installed on the base along the receiving device, characterized in that the switchgear is a grating made of longitudinal and transverse strips, while the length of the grating is at least equal to the length of the receiving device, which is made in the form of a pocket recessed relative to the base of the plate, with the lower end of the grating at installed on the base, along the edge of the pocket. 7. Mass transfer plate according to claim 6, characterized in that the extreme longitudinal strip of the upper end of the switchgear is adjacent to the drain strip of the upstream base across the entire width of the drain strip. 8. Mass transfer plate according to claim 6, characterized in that the upper end of the switchgear is installed at a distance of at least one quarter of the distance between the bases of the plates. 9. Mass transfer plate according to claim 6, characterized in that the longitudinal stripes of the grating are installed at an acute angle to the base in the direction from the receiving device. 10. Mass transfer plate according to claim 6, characterized in that the transverse bars of the grating are fan-shaped relative to the center of the grating in the direction from the receiving device.

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