RU2345813C1 - Heat-and-mass exchanger - Google Patents

Abstract

FIELD: mechanics.

SUBSTANCE: proposed heat-and-mass exchanger is intended for interaction of gas and fluid and can be used for cooling and purification of the contact gas from catalyst dust and steam stripping of hydrocarbons from water condensate in production of styrene by ethyl benzene dehydrogenation. The cylindrical casing top accommodates fluid intake and gas discharge branch pipes while the cylindrical casing bottom has fluid discharge branch pipe and the gas main feed pipeline. Just above the latter, a baffle followed by one or several disks and a device for gas and fluid to interact therein. The said disk feature central bores. Note here that the lower disk bore diameter is smaller than that of the gas feed pipeline, and that the bore diameters of the upper disk are smaller than those of the lower disks. The disks in question have the diameter equal to that the baffle.

EFFECT: higher efficiency of mass-and-heat transfer due to improved gas flow distribution over exchanger diameter.

12 cl, 2 dwg, 1 tbl

Description

The invention may find application in the refining, petrochemical, chemical and other industries. It can be effective to use the invention, in particular, in the production of vinyl aromatic hydrocarbons such as styrene, alpha-methyl styrene, vinyl toluene, divinylbenzene, as well as isoprene, butadiene, etc.

Known scrubber with a regular nozzle for the implementation of heat and mass transfer processes, including dust collection, with countercurrent movement of gas and liquid along the nozzle layer (V.N. Uzhov, A.Yu. Waldberg. Preparation of industrial gases for cleaning. Moscow, Chemistry Publishing House, 1975, p. 85). The scrubber has a gas inlet fitting located in the side wall of the shell of the apparatus body under the nozzle layer. The disadvantage of this apparatus is the low efficiency of heat and mass transfer processes, high hydraulic resistance and the formation of dust deposits on the surface of the nozzle.

Also known is a foam apparatus — a gas scrubber for purifying dust from air in an apatitonefelin concentration plant, including a vertical rectangular section housing containing an air inlet unit in the form of a side fitting (diffuser) and a contact device located above it in the form of one perforated grating (M. E. Pozin, IP Mukhlenov, E. Ya. Tarat. Foam gas scrubbers, heat exchangers and absorbers, Goskhimizdat, 1959, p. 47).

The known apparatus has a low strength box-shaped structure of the casing with flat walls, uneven distribution of the gas stream over the cross section of the contact zone with lateral gas inlet to the apparatus and low heat and mass transfer.

The closest in technical essence to the proposed one is a heat and mass transfer apparatus for the interaction of gas and liquid, used to trap hydrogen fluoride from gases emanating from aluminum electrolysis cells. The known foam apparatus includes a vertical cylindrical body containing in its upper part nozzles for introducing liquid and a nozzle for discharging gas, and in the lower part there are nozzles for discharging liquid and a central pipeline for introducing gas with a chimney, gas distribution located above its upper edge, in series with the gas a lattice and a device for contacting gas and liquid in the form of two perforated annular lattices (IP Mukhlenov, E. Ya. Tarat. Foam mode and foam devices. Publishing house "Chemistry". 1977, p. 27 8). The apparatus also contains a cylindrical distribution box located in the central part of the gratings, from which the irrigating soda solution is discharged between the gas distribution grate and the lower perforated grate. At the inlet to the gas outlet pipe, a spray trap is installed with a drain pipe, the lower end of which is located in the volume of the receiving box for introducing the irrigating soda solution.

This apparatus has a more robust casing, which is ensured by the cylindrical shape of the shell of the casing, better gas distribution when it is supplied through a central pipeline with a chipper and an advantage in the efficiency of heat and mass transfer compared to the foam apparatus discussed above.

At the same time, the device has the following disadvantages.

The gas distribution grill installed on the entire cross section of the apparatus does not provide the necessary uniformity in the distribution of the gas flow in the contact zone (in the installation area of ring-shaped perforated gratings) due to:

- with the supply of a gas stream to the wall zone of the gas distribution grid;

- with uneven supply of gas to the gas distribution grid (in its central part);

- with distortion of the flow of the gas flow distributed over the entire cross section of the apparatus by the bottom of the distribution box before the flow enters the annular contact zone.

The significant uneven distribution of the gas stream in the contact zone largely determines the insufficient level of heat and mass transfer in the apparatus.

In addition, the apparatus has increased hydraulic resistance associated with the use of an irrigated gas distribution grate and a combination of two perforated gratings with a ratio of their free sections in the range of 1 ÷ 1.35.

In connection with these shortcomings, the use of the known foam apparatus in large-capacity processes, such as, for example, the method of producing styrene by dehydrogenation of ethylbenzene (with a diameter of the apparatus to six meters or more), encounters considerable difficulties.

The objective of the present invention is to increase the efficiency of heat and mass transfer in the apparatus while improving the uniformity of the distribution of the gas flow in the contact zone and reducing hydraulic resistance.

A heat and mass transfer apparatus for the interaction of gas and liquid is proposed, comprising a vertical cylindrical body with nozzles for introducing liquid and a nozzle for discharging gas in its upper part, nozzles for discharging liquid and a central pipeline for introducing gas with a chipper and a device for contacting gas and liquid above it - at its bottom. Between the upper edge of the gas supply pipe and the chipper one or more disks are installed having a diameter equal to the chipper diameter, each with a central hole, while the diameter of the hole at the lower disk is less than the diameter of the gas supply pipe, and at the upstream disks the diameter of the hole is less than in the downstream.

The specified chipper can be made in the form of a flat disk or in the form of a cone with the top pointing up, and can also be perforated.

It is preferable to install the disk or disks in the apparatus at the same distance from the upper edge of the gas supply pipe, from each other and from the bump, the specified distance being:

where H is the distance from the upper edge of the pipeline for introducing gas to the lower disk, the distance between the disks, the distance from the upper disk to the chipper, m;

F _Tr - the cross-sectional area of the pipeline for introducing gas, m ² ;

- сумма диаметров отверстий дисков и диаметра трубопровода для ввода газа, м;

- the sum of the diameters of the holes of the disks and the diameter of the pipeline for gas input, m;

n = 1 ÷ 5 - the number of disks;

K = 0.5 ÷ 1.0 - coefficient.

A device for the interaction of gas and liquid can be made in the form of two perforated annular gratings, between which in the central part there is a distribution box of cylindrical shape. At the same time, a spray trap with a drain pipe is installed at the inlet to the gas outlet pipe. It is preferable that the free cross section of the lower grill was 1.4 ÷ 3.5 times larger than the free cross section of the upper grill, and the ratio of the diameters of the chipper and the distribution box is within 1: 0.5 ÷ 1.5.

The distance between the grilles can be 0.1 ÷ 0.4 of the diameter of the apparatus.

The lower end of the drain pipe of the spray trap is preferably located in the volume of the distribution box.

The distribution box may be provided with a drain pipe, the lower end of which is located below the upper edge of the gas inlet pipe.

As a device for the interaction of gas and liquid can also be installed, for example, a layer of regular mass transfer nozzles, a package of gratings, a package of plates or a combination of gratings and nozzles. At the same time, a liquid distributor is connected above the device, connected to the nozzles for introducing liquid.

The distance between the chipper and the device for the interaction of gas and liquid can preferably be 1 ÷ 0.4 of the diameter of the apparatus.

The proposed heat and mass transfer apparatus for the interaction of gas and liquid can be used in various processes of the petrochemical and chemical industries, for example, in the production of styrene by dehydrogenation of ethylbenzene.

Figure 1 shows a diagram of one of the variants of the claimed apparatus - a foam apparatus for cooling and purifying contact gas from catalyst dust and stripping hydrocarbons from water condensate in the process of obtaining styrene by dehydrogenation of ethylbenzene.

The apparatus has a vertical cylindrical body 1, a central pipeline for introducing gas 2 with disks located centrally along the upper edge 3 and axially symmetrical to the apparatus body with disks with central holes 4 and 5, a chipper 6, perforated annular gratings 7 and 8. The space between the upper edge of the central the gas inlet pipe and the chipper is divided by disks into three chambers 9, 10 and 11. The apparatus also contains a cylindrical distribution box 12 located in the central part of the grids hney edge 13 for liquid overflow from the top grating. At the entrance to the pipe for gas outlet 14, a spray trap 15 is installed with a drain pipe 16, the lower end of which 17 is located in the volume of the distribution box. The distribution box is equipped with a drain pipe 18, the lower end of which 19 is located below the liquid level in the bottom part of the apparatus. The apparatus has a nozzle 20 for introducing liquid, an annular receiving box 21 with an annular overflow threshold 22 on the upper grill, a nozzle 23 for measuring the liquid level in the bottom part of the apparatus, a nozzle 24 for draining the liquid, a nozzle 25 for removing fluid from the apparatus, and hatches 26 for cleaning and repair of the device.

Contact gas enters the apparatus through pipeline 2, is divided by two disks 4, 5 and chipper 6 into three radially directed flows. Due to the fact that the pressure in front of the disks in the chambers 9, 10 and 11, respectively, is different from each other (successively drops), the rate of gas flow out from the downstream chambers is higher than the rate of outflow from the upstream chambers. In this regard, the lower stream flows into the near-wall zone of the apparatus, and the upper one flows into its central part. These flows do not intersect, are formed in the axial direction in the annular space and enter evenly into the annular space between two perforated gratings, which ultimately ensures uniform distribution of the gas flow in this zone. Having passed sequentially perforated gratings 7 and 8, the contact gas through the spray trap 15 and the pipe 14 is directed to the stage of condensation and the release of styrene. The water condensate obtained at the condensation stage is sent to the proposed heat and mass transfer apparatus through the nozzle 20 and the annular receiving box 21. The stream of water condensate uniformly irrigates the upper perforated grate 8 through the annular overflow threshold 22 at the periphery of the grate, passes the grate in the radial direction, cross to the contact gas flow, and through the drain threshold formed by the upper edge 13 of the distribution box 12, the drain pipe 18 enters under the level of a layer of water condensate in the bottom part of the apparatus ata, from where through the nozzle 25 it is directed to the purification and use of ethylbenzene in the dehydrogenation process.

The upper perforated grill 8 operates in a foam mode, i.e. with intensive turbulization of a gas-liquid system with its transformation into a mobile unstable, but dynamically stable foam due to the kinetic energy of the gas. In the claimed range of the ratio of the free section of the lower and upper grilles (1.4 ÷ 3.5) with the claimed location of the drain pipes of the spray trap and the distribution box, the upper grill operates in a liquid-free mode, and the lower grill 7 remains “dry” and works as a distribution for gas. This combination of operating modes of the grids at a distance between the grids of 0.1 ÷ 0.4 from the diameter of the casing of the apparatus and with a ratio of the diameters of the chipper and the distribution box of 0.5 ÷ 1.5 provides an increase in the uniformity of the distribution of flows in the contact zone and a high level of heat and mass transfer at low differential pressure on the gratings in the claimed embodiment of the heat and mass transfer apparatus.

To achieve a more uniform distribution of the gas flow in the apparatus section, the distances from the upper edge of the gas supply pipe 3 to the lower disk 4 between the disks 4 and 5 and from the upper disk 5 to the chipper 6 can be made the same. The determination of the magnitude of this distance from the above ratio for calculating the distance H is carried out taking into account the requirement of dividing the gas stream flowing from the gas inlet pipe into three equal flows directed to the chambers 9, 10 and 11. This requirement is fulfilled by ensuring equal central area the holes of the upper disk 5 and the areas of the rings conventionally formed in the projection along the apparatus axis (along the gas flow) by the circles of the central holes of the upper and lower disk, as well as the central hole The holes of the lower disk and the gas inlet pipe. The area of the Central hole of the upper disk F ₁ = _1/3 F _Tr , and the lower disk F ₂ = _2/3 F _Tr and, accordingly, the diameters of the Central holes of these disks will be 0.577 and 0.816 of the diameter of the pipeline for gas entry.

So, for example, with a pipe diameter of 1.4 m (F _Tr = 0.785 · 1.4 ² = 1.54 m ² ), the diameter of the central hole of the upper disk will be ~ 0.577 · 1.4 = 0.81 m, and for the lower disk ~ 0.816 · 1.4 = 1.14 m. In this case, the distance H (in accordance with the above ratio for calculation) will be: 0.72 · 1.54 / 1.4 + 1.14 + 0.81 = 0.33 m.

The increase in the number (n) of installed disks over 5 unreasonably complicates the design. At the same time, a decrease in the K coefficient in the given ratio for calculation to a value less than 0.5 leads to an unjustified increase in the hydraulic resistance of the apparatus, and an increase in K above 1.0 leads to an excessive increase in the dimensions and metal consumption of the apparatus.

The effectiveness of the inventive heat and mass transfer apparatus in design options using a layer of a regular mass transfer nozzle, a packet of gratings, a package of plates or a combination of gratings and nozzles as a device for gas and liquid interaction also increases due to a significant improvement in the distribution of gas flows.

Figure 2 presents a variant of the use of the inventive heat and mass transfer apparatus in the technological scheme of the process for producing styrene by dehydrogenation of ethylbenzene. The table shows the material balance of the heat and mass transfer apparatus, demonstrating the efficiency of the apparatus in the process. The technology involves the dehydrogenation of ethylbenzene in the presence of water vapor in the reactor system 27, the use of contact gas heat in a waste heat boiler 28 with the generation of water vapor used in the dehydrogenation process, cooling and purification of the contact gas from catalyst dust and the stripping of hydrocarbons from the process water condensate in a heat and mass transfer apparatus 29. The circuit also contains a condensation unit 30, from which the resulting water condensate is sent to irrigate the heat and mass transfer apparatus 29, in which gas is cooled from 180 ÷ 250 ° С to 70 ÷ 90 ° С due to evaporation of part of the water condensate, it is cleaned of catalyst dust with a hydraulic resistance of the apparatus of not more than 300 ÷ 500 mm water column. At the same time, stripping of hydrocarbons contained in the initial aqueous condensate is carried out. The stripped hydrocarbons are returned to the contact gas, and the water condensate containing the minimum amount of impurities (see the stream from ap.29 to ap.31 in the table) is sent to the purification unit of the water condensate 31 to prepare it for reuse in the process. Two-stage condensate purification in the proposed heat and mass transfer apparatus 29 and in unit 31, for example, by filtering the condensate from trapped dust and subsequent condensate rectification in the presence of an extractant (benzene-toluene fraction) allows to obtain the purity of the water condensate (see stream from ap.31 to ap. 28 and into the water circulation system in the table), sufficient to use it as a feed for waste-heat boilers with obtaining secondary water vapor directed to dilution during ethylbenzene dehydrogenation.

The hydrocarbon portion of the products condensed in the condensation unit 30 is directed to the styrene separation and purification unit 32.

The hydrocarbon portion of the products condensed in the condensation unit 30 is directed to the styrene separation and purification unit 32.

Table Material balance of heat and mass transfer apparatus. Component Name Contact gas, kg / h Water condensate, kg / h entrance Exit entrance Exit From the condensate treatment unit Stream name From ap. 28 to ap. 29 From ap.29 to ap.30 From ap.30 to ap.29 From ap.29 to ap.31 From ap.31 to ap.28 and to the water circulation system Hydrogen 348 348 Methane 46 46 Ethylene 22 22 Carbon dioxide 374 374 Benzene 181 259 79 one Toluene 517 556 40 2 Paraffins 2 2 0 Ethylbenzene 11655 11671 17 one 0.1 Styrene 17163 17191 29th 0.57 0.1 Xylenes fifteen fifteen A-methylstyrene 9 9 Heavy residue 47 47 Total 30379 30540 165.27 4.57 0.2 Water vapor (water) 56846.5 61774 62427,72 57,500.22 57500 Total 87,225.5 92314 62592,99 57,504.79 57,500.2

Claims (12)

1. Heat and mass transfer apparatus for the interaction of gas and liquid, comprising a vertical cylindrical body with nozzles for introducing fluid and a nozzle for discharging gas in its upper part, nozzles for discharging fluid and a central pipeline for introducing gas with a chipper and a device for the interaction of gas and liquid above it - in its lower part, characterized in that between the upper edge of the gas inlet pipe and the chipper one or more disks are installed, having a diameter equal to the diameter of the chipper, with a central each verst, while the diameter of the hole in the lower disk is less than the diameter of the pipeline for gas input, and in the upstream disks the diameter of the hole is smaller than in the lower ones. 2. The apparatus according to claim 1, characterized in that the chipper is made in the form of a flat disk or in the form of a cone with a vertex pointing up. 3. The apparatus according to claim 2, characterized in that the chipper is perforated. 4. The apparatus according to claim 1, characterized in that the disks are installed at the same distance from the upper edge of the pipeline for introducing gas, from each other and from the chipper, while the specified distance is:

where H is the distance from the upper edge of the pipeline for introducing gas to the lower disk, the distance between the disks, the distance from the upper disk to the chipper;
F _Tr - the cross-sectional area of the pipeline for introducing gas, m ² ;

- the sum of the diameters of the holes of the disks and the diameter of the pipeline for gas input, m;
n = (1 ÷ 5) - the number of disks;
K = (0.5 ÷ 1.0) - coefficient. 5. The apparatus according to claim 1, characterized in that the device for the interaction of gas and liquid is made in the form of two perforated annular gratings, between which in the central part there is a distribution box of a cylindrical shape, and a spray catcher with a drain pipe is installed at the inlet to the gas outlet pipe while the free cross section of the lower grill is 1.4 ÷ 3.5 times larger than the free cross section of the upper grill, and the ratio of the diameters of the chipper and the distribution box is within 1: (0.5 ÷ 1.5). 6. The apparatus according to claim 5, characterized in that the distance between the gratings is 0.1 ÷ 0.4 of the diameter of the apparatus. 7. The apparatus according to claim 5, characterized in that the lower end of the drain pipe of the spray trap is located in the volume of the distribution box. 8. The apparatus according to claim 5, characterized in that the distribution box is provided with a drain pipe, the lower end of which is located below the upper edge of the gas inlet pipe. 9. The apparatus according to claim 1, characterized in that a layer of a regular mass transfer nozzle is installed as a device for the interaction of gas and liquid. 10. The apparatus according to claim 1, characterized in that as a device for the interaction of gas and liquid, a package of gratings or plates is installed. 11. The apparatus according to claim 1, characterized in that as a device for the interaction of gas and liquid, a combination of gratings and nozzles is installed. 12. The apparatus according to claim 1. characterized in that the distance between the chipper and the device for the interaction of gas and liquid is 0.1 ÷ 0.4 of the diameter of the apparatus.

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