RU119255U1 - COMBINED ADSORBER FOR HIGH-TEMPERATURE CLEANING OF MULTICOMPONENT GAS FROM TWO TYPES OF GAS CONNECTIONS - Google Patents

Abstract

1. Combined adsorber for cleaning a multicomponent gas from two types of gaseous compounds, containing a vertical cylindrical casing with two adsorption devices for gas cleaning installed in it, respectively, the first of which along the gas to be cleaned is located in the central axial part of the casing and constitutes the first adsorption zone in which the cleaned the gas moves in an ascending vertical direction, and the second - in the annular space that encompasses the central axial part and constitutes the second adsorption zone, in which the gas to be cleaned moves radially from the center to the periphery, and the first adsorption apparatus is a shell filled with a solid adsorbent with an inlet a branch pipe for supplying the gas to be cleaned in the lower part and outlets for it in the upper part, and the second - an annular box filled with a solid adsorbent with inlet and outlet openings for the gas to be cleaned in the lateral cylindrical walls an annular space is provided between the first and second adsorption apparatuses for bypassing the purified gas from the upper part of the first adsorption apparatus to the inlet of the second adsorption apparatus, between the second adsorption apparatus and the cylindrical wall of the body there is an annular collector for collecting the purified gas and discharging it through at least one outlet pipe in its lower part, and in the upper part of the second adsorption apparatus there is a horizontal row of inclined guide annular plates, characterized in that the shell of the first adsorption apparatus�

Description

The technical field to which the utility model relates.

The utility model relates to contact mass transfer reaction separation apparatus for purification of multicomponent gas and can be used to purify synthesis gas from hydrogen sulfide and organosulfur compounds.

State of the art

Known is a combined adsorber selected as a prototype of a utility model for purifying multicomponent gas from two types of gaseous compounds, comprising a vertical cylindrical body with two gas purification adsorption apparatus installed in it, respectively, the first of which is located in the central axial part of the body along the gas being purified and makes up the first zone adsorption, in which the gas to be cleaned moves in an upward vertical direction, and the second in the central axial part of the con centered on the annular space and constitutes the second adsorption zone in which the gas to be cleaned moves radially from the center to the periphery, the first adsorption apparatus being a shell filled with solid adsorbent with an inlet for supplying the gas to be cleaned in the lower part and its outlet openings in the upper parts, and the second is an annular box filled with solid adsorbent with inlet and outlet openings for the gas to be cleaned in the cylindrical side walls of the box, between the first and second adsorption apparatuses provide an annular space for transferring the gas to be purified from the upper part of the first adsorption apparatus to the inlet of the second adsorption apparatus, an annular manifold is provided between the second adsorption apparatus and the cylindrical wall of the housing for collecting purified gas and discharging it through an outlet pipe in its lower part, and in the upper part of the second adsorption apparatus there is a horizontal row of inclined guide ring plates (US 5593475, B01D 53/04, 1997).

The disadvantages of this known adsorber include the relatively low productivity associated with insufficiently intensive mass transfer between the solid adsorbent and the adsorbed substances of the gas being purified. For a given gas cleaning performance in combination with the requirement of a high concentration of absorbed gas components, this leads to the need for a significant increase in the dimensions of the apparatus with a corresponding increase in metal consumption and large volumes of adsorbent loaded into it.

Utility Model Disclosure

The objective of the utility model is to increase the capacity of the adsorber for given dimensions or for a given performance, to reduce its dimensions and consumption of solid adsorbent, and the technical result achieved is to increase the mass transfer rate between the solid adsorbent and the gas to be cleaned, as well as the possibility of reusing solid adsorbent.

The indicated tasks and the technical result achieved are ensured by the fact that in the combined adsorber for purification of multicomponent gas from two types of gaseous compounds, it contains a vertical cylindrical body with two gas purification adsorption devices installed in it respectively, the first of which is located in the central axial part of the body and constitutes the first adsorption zone in which the gas to be cleaned moves in an upward vertical direction, and the second in the enveloping center the axial part of the concentric annular space constitutes the second adsorption zone in which the gas to be cleaned moves radially from the center to the periphery, the first adsorption apparatus being a shell filled with solid adsorbent with an inlet for supplying the gas to be cleaned in the lower part and outlet openings for in the upper part, and the second - an annular box filled with solid adsorbent with inlet and outlet openings for the gas to be cleaned in the cylindrical side walls of said box, between the first and second adsorption apparatus there is provided an annular space for transferring the gas to be purified from the upper part of the first adsorption apparatus to the inlet of the second adsorption apparatus, an annular manifold is provided between the second adsorption apparatus and the cylindrical wall of the housing for collecting the purified gas and discharging it through at least one outlet pipe in its lower part, and in the upper part of the second adsorption apparatus a horizontal row of inclined guides is installed According to a useful model, the annular plates, the shell of the first adsorption apparatus has the shape of a truncated cone with a small base adjacent to the inlet pipe, a distribution sieve plate is installed in the cross section of the said base to create a fluidized bed of adsorbent in the first adsorption apparatus, the outlet openings in the upper part of the said shell are grooved with the direction of the glazed tongue down and out, the shells are inclined in the space of the second adsorption apparatus below the upper row x guide ring plates additional installed at least two more horizontal rows of similar plates.

The angle of inclination of the generatrix of the shell of the first adsorption apparatus to the axis of the cone can be (20 ... 40) °, the angle of inclination to the vertical axis of the adsorber of the guide ring plates in each row of the second adsorption apparatus is (40 ... 50) °, the second adsorption apparatus can be equipped with annular conical bottom with a slope from the periphery to the center at an angle of the generatrix of the cone to the central vertical axis of the adsorber equal to (35 ... 50) ° and with at least one pipe in the lower part for unloading the sorbent, the adsorber body can be sleep It is equipped with a cooling jacket with at least one nozzle for inlet and at least one nozzle for outlet of the refrigerant.

Brief Description of the Drawings

Figure 1 schematically shows an adsorber according to a utility model in longitudinal section; figure 2 - node B of figure 1 with the image of a slotted hole; figure 3 - adsorber according to a utility model in cross section along aa of figure 1.

Detailed description of utility model

The combined adsorber for the purification of multicomponent gas from two types of gaseous compounds (in this example, for the purification of synthesis gas from hydrogen sulfide and organosulfur compounds) contains a vertical cylindrical body 1 (Figs. 1, 3) with two adsorption gas purification devices installed in it. The first adsorption apparatus 2 along the cleaned gas is located in the Central axial part of the housing 1 and forms the first adsorption zone in which the cleaned gas moves in an upward vertical direction. The second adsorption apparatus 3 is located in the annular space concentrating on the central axial part and constitutes a second adsorption zone in which the gas to be cleaned moves radially from the center to the periphery. The first adsorption apparatus 2 is a shell 5 filled with solid adsorbent 4 (FIG. 1) with an inlet pipe 6 for supplying a gas to be cleaned in the lower part and outlet openings 7 (FIGS. 1, 2, 3) for it in the upper part. The second adsorption apparatus 3 is an annular box 8 filled with solid adsorbent (not shown) with inlet and outlet openings for the gas to be cleaned in the cylindrical side walls of the box 8. An annular space 9 is provided between the first adsorption apparatus 2 and the second adsorption apparatus 3 (FIG. .1, 3) for transferring the gas to be purified from the upper part of the first adsorption apparatus 2 to the inlet of the second adsorption apparatus 3. Between the second adsorption apparatus 3 and the cylindrical wall oh the case 1 is provided with an annular collector 10 (figure 1) for collecting purified gas and discharging it through the outlet pipes 11 in its lower part, and in the upper part of the second adsorption apparatus 3 there is a horizontal row of inclined guide ring plates 12. The shell 5 of the first adsorption apparatus 2 has the shape of a truncated cone with a small base adjacent to the inlet pipe 6. A cross-sectional sieve plate 13 is installed in the cross section of this base to create a fluidized bed in the first adsorption apparatus 2 adsorbent 4. Outlets 7 in the upper part of the shell 5 are grooved (Fig. 2) with the direction of the grooved tongue 14 downward and outward of the shell 5. In the space of the second adsorption apparatus 3 below the upper row of inclined guide ring plates 12, an additional one is installed in this example two horizontal rows of similar plates. The angle α of inclination of the generatrix of the shell 5 of the first adsorption apparatus 2 to the axis of the corresponding cone is α = (20 ... 40) °. The angle β of inclination to the vertical axis of the adsorber of the guide ring plates 12 in each row of the second adsorption apparatus 3 is β = (40 ... 50) °. The second adsorption apparatus 3 is equipped with an annular conical bottom 15 with a slope from the periphery to the center at an angle γ of the generatrix of the cone to the central vertical axis of the adsorber equal to γ = (35 ... 50) ° and with at least one nozzle 16 in the lower part for unloading the sorbent. The adsorber housing 1 is equipped with a cooling jacket 17 (FIGS. 1, 3) with at least one nozzle 18 for input and at least one nozzle 19 for outputting the refrigerant. To load the sorbent in the adsorption apparatus 2 and 3, respectively, nozzles 20 and 21 are provided (Fig. 1).

The operation of the adsorber according to the utility model

Prior to operation, adsorbents 2 and 3 are charged via adsorbents 20 and 21 with the corresponding adsorbents that selectively act on hydrogen sulfide and organosulfur compounds. Natural iron-manganese sorbents can be used for the first apparatus 2, and adsorbents based on red clay and zinc oxides, the composition of which depends on the composition and concentration of the purified gases, can be specially prepared for the second apparatus 3. The synthesis gas to be cleaned is introduced into the first adsorption apparatus 2 through the lower nozzle 6. Passing through the distribution sieve plate 13, the gas to be purified fluidizes the solid particles of the adsorbent of the first adsorption zone in which hydrogen sulfide is absorbed. Purified from hydrogen sulfide, the synthesis gas enters through the perforated openings 7 from the upper part of the adsorption apparatus 2 to the adsorption apparatus 3. In this case, the downward-facing tongues 14 of the perforated openings 7 deflect the gas flow along the inner perforated cylindrical wall of the apparatus 3, through which it is cleaned through its entire height the gas enters the second adsorption zone, where it reacts with the adsorbent of this zone at the same temperature as the adsorbent of the first zone. Then the synthesis gas is discharged through the perforated holes of the outer cylindrical wall of the annular box 8 of the apparatus 3, passing through the annular collector 10 into the outlet pipe 11. In the annular space of the box 8 of the second adsorption apparatus 3, guide ring plates are installed to organize the ordered gas flow and prevent adsorbent caking. 12 in several rows along the entire height of the apparatus. To replace the adsorbent of the second adsorption zone, the bottom 15 of the annular box 8 of the apparatus 3 has a bias towards the central axis of the adsorber, which facilitates the discharge of the spent adsorbent through the nozzles 16. If necessary, the adsorbents of the first and second adsorption zones are regenerated with an oxygen-containing gas at a higher process temperature than the operating temperature in the adsorber at about 250 ° C, which occurs due to the thermal effect of the regeneration reaction. The heat is removed from the adsorber during the regeneration of adsorbents by a refrigerant (water) circulating through the cooling jacket 17.

Thus, according to the utility model, the adsorber allows the effective purification of synthesis gases from hazardous components of sulfur compounds simultaneously in a vertical and horizontal current, under conditions of fluidization and filtration regimes, accelerating mass transfer processes, which provides a significant increase in its efficiency.

Claims (5)

1. A combined adsorber for purifying multicomponent gas from two types of gaseous compounds, comprising a vertical cylindrical body with two gas cleaning adsorption apparatuses installed respectively in it, the first of which is located in the central axial part of the body along the gas being purified and constitutes the first adsorption zone in which the gas to be cleaned the gas moves in an upward vertical direction, and the second - in the annular concentric concentric ring covering the central axial part and is second th adsorption zone, in which the gas to be cleaned moves radially from the center to the periphery, the first adsorption apparatus is a shell filled with a solid adsorbent with an inlet pipe for supplying the gas to be cleaned in the lower part and exhaust openings for it in the upper part, and the second one is filled a solid adsorbent annular box with inlet and outlet openings for the gas to be cleaned in the side cylindrical walls of the box, between the first and second adsorption devices is provided but an annular space for bypassing the gas to be purified from the upper part of the first adsorption apparatus to the inlet of the second adsorption apparatus, between the second adsorption apparatus and the cylindrical wall of the housing, an annular manifold is provided for collecting the purified gas and discharging it through at least one outlet pipe in its lower part, and in the upper part of the second adsorption apparatus there is a horizontal row of inclined guide ring plates, characterized in that the shell of the first adsorption apparatus the ata has the shape of a truncated cone with a small base adjacent to the inlet pipe, a cross-section sieve plate is installed in the cross section of the base for creating a fluidized bed of adsorbent in the first adsorption apparatus, the outlet openings in the upper part of the said shell are grooved with the direction of the slotted tongue down and out of the shell, and in the space of the second adsorption apparatus below the upper row of inclined guide ring plates of the additional installed at least still two horizontal rows of similar plates. 2. The adsorber according to claim 1, characterized in that the angle of inclination of the generatrix of the shell of the first adsorption apparatus to the axis of the cone is (20 ... 40) °. 3. The adsorber according to claim 1, characterized in that the angle of inclination to the vertical axis of the adsorber of the guide ring plates in each row of the second adsorption apparatus is (40 ... 50) °. 4. The adsorber according to claim 1, characterized in that the second adsorption apparatus is equipped with an annular conical bottom with a slope from the periphery to the center at an angle of the generatrix of the cone to the central vertical axis of the adsorber equal to (35 ... 50) °, and with at least one nozzle in the lower part for unloading the sorbent. 5. The adsorber according to claim 1, characterized in that its housing is equipped with a cooling jacket with at least one nozzle for input and at least one nozzle for output of the refrigerant.