CN212396335U - Sulfur-containing process gas wet desulphurization device - Google Patents

Sulfur-containing process gas wet desulphurization device Download PDF

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CN212396335U
CN212396335U CN202021600195.0U CN202021600195U CN212396335U CN 212396335 U CN212396335 U CN 212396335U CN 202021600195 U CN202021600195 U CN 202021600195U CN 212396335 U CN212396335 U CN 212396335U
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liquid
desulfurization
gas
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tower
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景建龙
王安华
王乐
张礼军
高德辉
陈理
朱代希
余兰金
郑勇
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Sichuan Dkt Energy Technology Co ltd
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Sichuan Dkt Energy Technology Co ltd
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Abstract

The utility model belongs to the technical field of chemical industry, and discloses a wet desulphurization device for sulfur-containing process gas, which is first desulphurization equipment and comprises a desulphurization tower assembly and a first high-efficiency reactor (GXR type reactor), wherein the first high-efficiency reactor is fixedly arranged outside the tower wall of the desulphurization tower assembly; the device can also comprise a second desulfurization device and/or a third desulfurization device and/or a fourth desulfurization device, and the desulfurization of process gases with different loads or sulfur contents is realized through the combination of the multi-stage desulfurization devices, so that the integral desulfurization efficiency is ensured to be more than or equal to 99.9 percent, the desulfurization device of the utility model has compact integral structure, and the occupied area is greatly reduced; smooth airflow flow, reduced resistance, energy saving, consumption reduction, high utilization rate of each part, saving of a large amount of materials and more equipment investment saving.

Description

Sulfur-containing process gas wet desulphurization device
Technical Field
The utility model relates to the technical field of chemical industry, concretely relates to contain sulphur technology gas wet flue gas desulfurization device.
Background
In industrial production systems in industries such as petrochemical industry, natural gas chemical industry, coal chemical industry and the like, sulfur-containing process gas mainly exists in chemical engineering units such as natural gas (including methane) chemical industry, petroleum refining hydrogenation devices, coal tar hydrogenation devices in coal chemical industry and the like, and all contain high-concentration H2S and other sulfur-containing process gases. According to the requirements of sulfur recovery treatment and environmental protection technology, the H in the sulfur-containing process gas needs to be treated2S is purified and the sulfur is recycled.
In particular to the field of coal chemical industry, sulfur-containing process acid gases such as sulfur-containing process gas generated by stripping acid water in a hydrogen sulfide removal tower in a coal tar hydrogenation device, and sulfur-containing process gas generated by regenerating and stripping a solvent in the coal tar hydrogenation device (separated by a stripping separating tank) are separated. Depending on the size of the hydrogenation apparatus, 30X 104~60×104For t/a coal tar hydrogenation unit, the gas of the sulfur-containing process acid gasThe amount is generally 100 to 1000Nm3A difference of about/H, H2The S content is 60-97% (vol%), and the amount of recovered sulfur converted into pure sulfur is about 2000-8000 t/a.
For sulfur-containing process gas in the fields of petroleum, natural gas, biogas, coal chemical industry and the like, the amount of the sulfur-containing process gas is different according to different scales of devices, and H2The S content is varied from 0.1 to 50% (vol%). The recovery of sulfur in large-scale plants ranges from annual production on the order of kilotons to tens of kilotons, and even hundreds of kilotons.
Aiming at the process for recovering sulfur by purifying sulfur-containing process gas, the process for recovering sulfur mainly adopts a Claus method (including an improved superYouguos method and the like). The Claus process for recovering sulfur from process gas generally adopts the processes of conversion, condensation, sulfur separation, sulfur granulation and forming, process gas reheating, Claus tail gas retreatment or alcohol amine absorption system and the like. And the process of the Claus tail gas treatment (such as an alcohol amine absorption system) needs to consume alcohol amine solvent, and simultaneously the solvent needs to be continuously regenerated to consume a large amount of steam, so that new energy consumption is increased, and the operation cost is high. The Claus device is generally applicable to devices with large capacity of more than 1 ten thousand tons per year due to long process, complex process and high requirement on equipment materials, and compared with the comprehensive cost performance, the Claus device is rarely constructed in China and has poor economic rationality for small devices for recovering Claus with the grade of 1 ten thousand tons per year and below.
In recent years, in many of the sulfur-containing process gas desulfurization and sulfur recovery apparatuses for the newly-built independent coal tar hydrogenation apparatuses and the sulfur-containing process gas in the petroleum and natural gas (including biogas) chemical and coal chemical industries, the sulfur recovery amount of the sulfur-containing process gas in many apparatuses is less than 1 million tons/year (mostly about 2000 to 8000 t/a). If the Claus device is adopted, the economic rationality and the comprehensive cost performance are poor, so the Claus method is not suitable to be adopted.
SUMMERY OF THE UTILITY MODEL
To the problem in the background art, the utility model provides a contain sulphur technology gas wet flue gas desulfurization device, through the utility model discloses desulphurization unit's desulfurization is efficient, compact structure, occupation of land are few, have that the air current flows unblocked, the resistance reduces, each part public rate is high, equipment investment province.
In order to achieve the purpose, the utility model provides a technical scheme does:
a sulfur-containing process gas wet desulphurization device is a first desulphurization device and comprises:
the desulfurizing tower assembly is sequentially provided with a process purified gas outlet, a first demisting section, a packed tower, a semi-rich liquid level section, a first gas-liquid separator, a rich liquid level section and a tower seat from the top end to the bottom end; and
the first high-efficiency reactor (GXR type reactor) is fixedly arranged on the outer side of the tower wall of the desulfurizing tower assembly and is communicated with the first gas-liquid separator, the top end of the first high-efficiency reactor is provided with a sulfur-containing process gas inlet, and the inside of the first high-efficiency reactor is provided with a plurality of layers of first atomizing nozzles;
wherein the first gas-liquid separator is used for separating a gas-liquid mixture coming from the first high-efficiency reactor.
Furthermore, the multilayer first atomizing spray heads arranged in the first high-efficiency reactor are 1 layer or 2 layers of liquid high-efficiency atomizing spray heads.
Furthermore, the semi-rich liquid level section comprises an air lifting cap, a liquid receiving disc and a downcomer, and is mainly used for shunting semi-rich liquid at the middle upper part of the desulfurizing tower assembly, wherein one part of the semi-rich liquid is intercepted in the semi-rich liquid level section on the liquid receiving disc, the semi-rich liquid is pumped into the first high-efficiency reactor through a reaction pump to form semi-internal circulation, and the other part of the semi-rich liquid exceeding the semi-rich liquid internal circulation amount overflows to the lower part of the rich liquid level section through the downcomer in the semi-rich liquid receiving disc and the liquid receiving disc higher than the liquid level section to form a liquid seal, so that the redundant semi-rich liquid is ensured to automatically flow into the rich liquid level section, and the gas in the rich liquid level section does not enter the downcomer.
Further, the packed tower comprises 1, 2 or 3 sections of packing absorption sections, wherein the packing is standard regular packing or granular packing (the material is stainless steel, carbon steel, plastic, light porcelain or ceramic, porcelain plastic and the like); a gas-liquid redistributor is arranged at the top of each section of the filler absorption section, and a tower top liquid inlet liquid distributor is arranged at the top of the filler absorption section close to the tower top; the gas-liquid redistributor is generally a groove disc type gas-liquid distributor of an industrial absorption tower; the liquid inlet and liquid distributor at the top of the tower can be a trough disc type gas-liquid distributor, a trough type distributor, a tubular distributor, a distribution tubular spray head distributor and other standard parts.
Furthermore, first defogging section includes first defroster and defogging washing unit, and the in-tower process gas is through packing absorption section and first defroster section back, goes out the desulfurization tower assembly from the top of the tower.
Furthermore, a liquid level meter is installed on the outer side wall of the rich liquid level section, a liquid level control valve is installed on the corresponding liquid outlet pipeline, and the liquid level meter and the liquid level control valve form regulation and control linkage alarm and automatically control the liquid level height.
Further, the apparatus further comprises a second desulfurization device (DGX-type reactor) connected to the first desulfurization device by a pipe, comprising:
the efficient reaction section is internally provided with a plurality of layers of second atomizing nozzles, and the sprayed desulfurization liquid is in countercurrent contact with the process gas to generate desulfurization absorption reaction;
the mixed reaction section is provided with a gas-liquid mixed ejector and a high-efficiency mixer liquid receiving tank barrel, wherein the jet flow speed of the mixed ejector is 10-20 m/s, and the mixed ejector is used for secondary reaction of the process gas and the desulfurization liquid;
a gas-liquid separation section;
the first liquid storage tank section is used for storing the desulfurized liquid after reaction; and
a tower skirt.
Furthermore, the multilayer second atomizer that high-efficient reaction section inside was equipped with is 1 layer or 2 layers of liquid high-efficient atomizing nozzle of upwards blowout.
Furthermore, a liquid level meter is installed on the outer side wall of the first liquid storage tank section, a liquid level control valve is installed on the corresponding liquid outlet pipeline, and the liquid level meter and the liquid level control valve form regulation and control linkage alarm and automatically control the liquid level height.
Further, when the apparatus includes the first desulfurization device, and the second desulfurization device, the apparatus may further include a third desulfurization device, where the third desulfurization device includes:
the first special reactor and the gas-liquid separation equipment are connected with the first or second desulfurization equipment through pipelines;
the height-diameter ratio of the first special reactor is 10: 1-5: 1, the lower part of the first special reactor is provided with a gas-liquid inlet mixer, and a first stainless steel corrugated filler is arranged in the first special reactor.
Further, the first stainless steel corrugated packing is structured pore plate corrugated packing of stainless steel with type numbers of 125Y, 250Y, 350Y, 450Y, 500Y and the like, and stainless steel wire mesh corrugated packing of type numbers of BX500, CY700 and the like. Strengthen gas-liquid mass transfer and reaction.
Further, when the apparatus includes a first desulfurization device, a second desulfurization device, a first desulfurization device, a third desulfurization device, and first to third desulfurization devices, a fourth desulfurization device may be further included, and the fourth desulfurization device includes:
the second special reactor and the filler type desulfurizing tower are connected with the desulfurizing equipment through pipelines;
the packed desulfurization tower is sequentially provided with a second liquid storage tank section, a second gas-liquid separator, a packed absorption reaction section, a liquid inlet distributor and a second demister from bottom to top; the height-diameter ratio of the second special reactor is 10: 1-5: 1, and a second stainless steel corrugated filler is arranged in the second special reactor.
Further, the second stainless steel corrugated packing is structured pore plate corrugated packing of stainless steel with type numbers such as 125Y, 250Y, 350Y, 450Y, 500Y and the like, and stainless steel wire mesh corrugated packing of type numbers such as BX500, CY700 and the like. Strengthen gas-liquid mass transfer and reaction.
Furthermore, the superficial gas velocity of the desulfurizing tower combination and the packed desulfurizing tower is 40-80% of the flooding velocity.
The desulfurization process of the sulfur-containing process gas wet desulfurization device comprises the following steps:
when the apparatus comprises only the first desulfurization unit, it is used for H2Desulfurization and purification of sulfur-containing process gas with S content within 0.1(vol%) in various gas amountsAnd (3) treating, wherein the desulfurization process comprises the following steps:
enabling the sulfur-containing process gas to enter a first high-efficiency reactor, and carrying out countercurrent contact with desulfurization liquid sprayed by a first atomizing nozzle to carry out a first desulfurization absorption reaction;
the gas-liquid mixture after the first desulfurization reaction enters a first gas-liquid separator to undergo gas-liquid separation;
the liquid after gas-liquid separation enters a rich liquid level section downwards;
the gas after gas-liquid separation sequentially passes through a semi-liquid-rich liquid level section, a packed tower and a first demisting section upwards and is purified and discharged;
the desulfurization efficiency of the process can reach more than 98.5 percent.
The desulfurization solution contains a catalyst which is a compound containing a cobalt phthalocyanine sulfonate system or an organic complexing agent plus a water-soluble base iron system.
When the device comprises 2 desulfurization devices, the device can be used for gas flow of 5000Nm3More than H, and H2Desulfurizing and purifying the sulfur-containing process gas with the S content of 0.1-0.2 (vol%); or the gas amount is 100 to 200Nm3about/H, H2Desulfurizing and purifying sulfur-containing acid gas with the S content of 60-97% (vol%); the total desulfurization efficiency can reach more than 99 percent.
When the device comprises 3 desulfurization devices, the device can be used for gas flow of 10000Nm3More than H, and H2Desulfurizing and purifying the sulfur-containing process gas with the S content of 0.2-0.5 (vol%); and gas amount is 200-400 Nm3about/H, H2Desulfurizing and purifying sulfur-containing acid gas with the S content of 60-97% (vol%); the total desulfurization efficiency can reach more than 99.5 percent.
Furthermore, when the device comprises 4 desulfurization devices, the device can be used for gas flow of 10000Nm3More than H, and H2Desulfurizing and purifying the sulfur-containing process gas with the S content of more than 0.5 (vol%); and gas amount is 400Nm3Over H, H2Desulfurizing and purifying sulfur-containing acid gas with the S content of 60-97% (vol%); the total desulfurization efficiency can reach more than 99.9 percent.
The utility model has the advantages that:
1. the utility model discloses according to the high low or the high low difference of sulphur content of load forms corresponding single or a plurality of sweetener, reaches single-stage or multistage desulfurization process, guarantees that its whole desulfurization efficiency is greater than or equal to 99.9% (the desulfurization rate that has the same equivalent level desulphurization unit of current conventionality improves the efficiency more than 10%), makes the purified gas satisfy national emission technical requirement. The utility model has compact integral structure and greatly reduced land occupation; smooth airflow flow, reduced resistance, energy saving, consumption reduction, high utilization rate of each part, saving of a large amount of materials and more equipment investment saving.
2. The utility model discloses a set up a plurality of sweetener, improved desulfurization reaction efficiency widely, improved the sulfur capacity of doctor solution, eliminated the stifled problem of conventional desulfurization absorption reaction equipment's sulphur. The desulfurization precision and efficiency of the whole sulfur-containing process gas are ensured, the investment of the whole equipment is reduced, and the economy is better.
3. The utility model discloses an all be filled with regular filler in third and the fourth sweetener, can improve gas-liquid mass transfer reaction rate by a wide margin, make desulfurization efficiency improve by a wide margin to can reduce the desulfurization load that the back level contains sulphur technology gas desulfurizing tower by a wide margin, reduce the equipment size who contains sulphur technology gas desulfurizing tower.
Drawings
FIG. 1 is a schematic view of a desulfurization apparatus according to example 1 of the present invention;
FIG. 2 is a process diagram of a desulfurization unit of example 1 of the present invention;
FIG. 3 is a schematic view of a first desulfurization apparatus in example 2 of the present invention;
FIG. 4 is a schematic view of a second desulfurization apparatus in example 2 of the present invention;
FIG. 5 is a simplified diagram of the desulfurization process of example 2 of the present invention;
FIG. 6 is a schematic view of a third desulfurization apparatus in example 3 of the present invention;
FIG. 7 is a simplified diagram of the desulfurization process of example 3 of the present invention;
FIG. 8 is a schematic view of a fourth desulfurization apparatus in example 4 of the present invention;
FIG. 9 is a simplified diagram of the desulfurization process of example 4 of the present invention;
FIG. 10 is a schematic view of a second desulfurization apparatus in example 5 of the present invention;
FIG. 11 is a schematic view of a desulfurization apparatus and process according to example 5 of the present invention;
FIG. 12 is a schematic view of a desulfurization apparatus and process according to example 6 of the present invention;
FIG. 13 is a schematic view of a desulfurization apparatus and process according to example 7 of the present invention;
fig. 14 is a schematic view of a desulfurization apparatus and process according to embodiment 8 of the present invention.
Detailed Description
In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention.
The embodiment of the utility model provides an in the embodiment desulfurization efficiency do: the amount of H2S removed by this unit (amount of H2S in the sour gas feed-the amount removed by purge to 20 ppm) is a percentage of the amount of H2S in the sour gas feed.
Example 1
The device only comprises a first desulfurization device A, and the structure schematic diagram of the device is shown in figure 1.
A sulfur-containing process gas wet desulfurization unit a comprising:
the desulfurizing tower combination 100, this desulfurizing tower combination is equipped with from the top to the bottom in proper order: a process purge gas outlet 101; the first demisting section 102 comprises a first demister 102.1 and a demisting flushing device 102.2, and the sulfur-containing process gas in the tower is desulfurized and purified and then is discharged from the top of the desulfurizing tower;
packed tower 103: the packing material comprises 3 sections of packing material absorption sections, wherein the packing material is standard regular packing material or granular packing material (the material is stainless steel, carbon steel, plastic, light porcelain or ceramic, porcelain plastic and the like); and a gas-liquid redistributor 103.1 is arranged at the top of each section of the filler absorption section, and a liquid inlet distributor 103.2 at the top of the filler absorption section close to the top of the tower is arranged. The gas-liquid redistributor 103.1 is generally a groove disc type gas-liquid distributor of an industrial absorption tower; the liquid inlet distributor 103.2 at the top of the tower is a general branch pipe type distribution spray pipe.
Semi-rich liquid level section 104: the device comprises an air lifting cap 104.1, a liquid receiving disc 104.2 and a downcomer 104.3, and is mainly used for shunting semi-rich liquid at the middle upper part of the desulfurizing tower assembly, wherein one part of the semi-rich liquid is intercepted in a semi-rich liquid level section on the liquid receiving disc, the semi-rich liquid is pumped into the first high-efficiency reactor through a reaction pump to form semi-internal circulation, and the other part of the semi-rich liquid exceeding the semi-rich liquid internal circulation amount overflows to the lower part of the rich liquid level section through the downcomer in the semi-rich liquid receiving disc and the liquid level section higher than the liquid receiving disc to form a liquid seal, so that the redundant semi-rich liquid is ensured to automatically flow into the rich liquid level section, and the gas in the rich liquid level section does not enter the downcomer;
a first gas-liquid separator 105, a rich liquid level section 106, and a tower 107; and
first high-efficiency reactor 108 (GXR type reactor): the first high-efficiency reactor is fixedly arranged on the outer side of the tower wall of the desulfurizing tower assembly 100 and is communicated with the first gas-liquid separator 105, the top end of the first high-efficiency reactor is provided with a sulfur-containing process gas inlet 109, and the inside of the first high-efficiency reactor is provided with 1 layer of first liquid high-efficiency atomizing nozzles 110; the first gas-liquid separator 105 is used to separate the gas-liquid mixture coming from the first high efficiency reactor.
The desulfurization process of the device comprises the following steps:
as shown in fig. 2, the sulfur-containing process gas enters the first high-efficiency reactor 108 from the process gas inlet 109, forms a foam-like region with the desulfurization solution sprayed by the first liquid high-efficiency atomizing nozzle 110 in the first high-efficiency reactor 108, and forms a countercurrent turbulent motion with the gas, so that the gas-liquid contact area is increased; then the gas-liquid mixture flows downstream to the first gas-liquid separator 105 at the lower part of the desulfurizing tower assembly 100 for gas-liquid separation, and the separated desulfurizing liquid enters the liquid-rich level section 106 at the lower part of the desulfurizing tower assembly 100. The process gas separated by the first gas-liquid separator 105 upwards passes through a liquid receiving disc 104.2 and a gas lifting cap 104.1 in a semi-rich liquid level section 104 in the middle of the desulfurizing tower assembly 100 and enters a packed tower 103 in the upper middle of the desulfurizing tower assembly 100, and the process gas passes through an inter-segment gas-liquid redistributor 103.1 of each packed section, then passes through a first demisting section 102 on the upper part of the desulfurizing tower assembly 100 and then is discharged out of the desulfurizing tower assembly 100 from a process purified gas outlet 101 on the top of the tower.
The semi-rich liquid at the upper part of the liquid receiving disc 104.2 arranged in the middle of the desulfurizing tower assembly is divided into two parts, wherein one part of the semi-rich liquid is intercepted in a liquid level section with the height of 2 meters on the liquid receiving disc 104.2, the semi-rich liquid on the liquid receiving disc 104.2 automatically flows to a reaction pump through an upper outlet of the disc, and is pressurized and sent to the efficient reactor 200 in front of the desulfurizing tower assembly 100 to form semi-rich liquid internal circulation through the pump; and the other part of semi-rich liquid exceeding the semi-internal circulation volume of the reaction liquid overflows to the lower part of a rich liquid level section 106 at the lower part of the desulfurizing tower assembly to form a liquid seal after passing through an overflow downcomer 104.3 in the liquid tray 104.2 which is 2 meters higher than the liquid level section of the liquid tray, so that the redundant semi-rich liquid is ensured to automatically flow into the rich liquid level section 106, and the process gas on the rich liquid level section 106 cannot enter the downcomer 104.3.
In order to automatically control the liquid level height, an automatic remote transmission liquid level meter and an in-situ liquid level meter are installed on the outer side wall of the rich liquid level section 106, a liquid level control valve is installed on a liquid outlet pipeline at the bottom of the rich liquid level section 106 at the lower part of the desulfurizing tower assembly 100, and the liquid level meter and the liquid level control valve form regulation and control linkage alarm to automatically control the liquid level height. And the rich liquid of the liquid outlet pipe at the bottom is sent to a desulfurization liquid regeneration system from the rich liquid behind the liquid level regulating valve at the bottom outlet.
Example 1 is suitable for H in a sour process gas2The desulfurization purification treatment of various gas quantities with the S content within 0.1(vol%) can lead the desulfurization efficiency to reach more than 98.5%.
Example 2
Compared with the example 1, a second desulfurization device 200 is added, the device comprises a first desulfurization device A and a second desulfurization device 200 (DGX type reactor), and 2 layers of liquid high-efficiency atomizing nozzles are arranged in the first high-efficiency reactor 108 of the first desulfurization device A. Schematic diagrams of the first desulfurization apparatus a and the second desulfurization apparatus 200 are shown in fig. 3 and 4, respectively.
The second desulfurization apparatus 200 is connected to the first desulfurization apparatus a through a pipe, and includes:
the high-efficiency reaction section 201 is internally provided with 2 layers of second atomizing nozzles 201.1 which are liquid high-efficiency atomizing nozzles, and the sprayed desulfurization liquid is in countercurrent contact with the process gas to generate desulfurization absorption reaction; the top is provided with a sulfur-containing process gas inlet 201.2;
the gas-liquid separation section 202 is composed of a conical cover baffle 202.1 and an annular baffle 202.2; and the upper side of the top end socket of the gas-liquid separation section 202 is provided with a process gas purification outlet 202.3;
the mixed reaction section 203 is provided with a gas-liquid mixed ejector 203.1 and a high-efficiency mixer liquid receiving tank cylinder 203.2, the circumference of the upper wall of the high-efficiency mixer liquid receiving tank cylinder 203.2 is provided with 6 phi 80 holes, the jet flow speed of the mixed ejector 203.1 is 10-20 m/s, and the mixed ejector is used for secondary reaction of the process gas and the desulfurization liquid;
a first reservoir section 204 for storing the desulfurized liquid after the reaction; and a tower mount 205.
In order to automatically control the liquid level height, a liquid level meter is installed on the outer side wall of the first liquid storage tank section 204, a liquid level control valve is installed on a corresponding liquid outlet pipeline, and the liquid level meter and the liquid level control valve form regulation and control linkage alarm.
The desulfurization process of the embodiment is as follows:
as shown in fig. 5, the sulfur-containing process gas enters the high-efficiency reaction section 201 from the sulfur-containing process gas inlet 201.2 at the top of the second desulfurization device 200 through a pipeline and flows downward, and forms a foam-like region with the desulfurization solution sprayed by the internal liquid high-efficiency atomizing nozzle 201.1, and forms a specific counter-flow turbulence with the gas, so that the gas-liquid contact area is increased; then the gas-liquid mixture flows downstream to the internal gas-liquid mixing ejector 203.1 to the mixing reaction section 203 and enters the liquid receiving tank 203.2 of the high-efficiency mixer, and the secondary gas-liquid high-efficiency mixing turbulent enhanced reaction is carried out, which is equivalent to two times of enhanced desulfurization enhanced absorption reaction in the same equipment. Then, the gas reacted by the liquid tank cylinder 203.2 in the high-efficiency mixer rises to the conical cover baffle 202.1 of the gas-liquid separation section 202, passes through the annular baffle 202.2, is sent out of the equipment through the process purified gas outlet 202.3, completes primary desulfurization, and enters first desulfurization equipment.
The primary desulfurization process gas sent by the second desulfurization equipment through the pipeline enters the first high-efficiency reactor 108 from the process gas inlet 109, forms a foam-shaped area with the desulfurization liquid sprayed by the first liquid high-efficiency atomizing nozzle 110 in the first high-efficiency reactor 108, and forms countercurrent turbulence with the gas, so that the gas-liquid contact area is increased; then the gas-liquid mixture flows downstream to the first gas-liquid separator 105 at the lower part of the desulfurizing tower assembly 100 for gas-liquid separation, and the separated desulfurizing liquid enters the liquid-rich level section 106 at the lower part of the desulfurizing tower assembly 100. The process gas separated by the first gas-liquid separator 105 upwards passes through a liquid receiving disc 104.2 and a gas lifting cap 104.1 in a semi-rich liquid level section 104 in the middle of the desulfurizing tower assembly 100 and enters a packed tower 103 in the upper middle of the desulfurizing tower assembly 100, the process gas passes through an inter-segment gas-liquid redistributor 103.1 of each packed section, then passes through a first demisting section 102 on the upper part of the desulfurizing tower assembly 100 and then is discharged out of the desulfurizing tower assembly 100 from a process purified gas outlet 101 on the top of the tower, and desulfurization is completed.
This example 2 is suitable for gas flow of 5000Nm3More than H, and H2The desulfurization purification treatment of various sulfur-containing process gases with the S content within 0.1-0.2 (vol%) has the desulfurization efficiency of over 99%.
Example 3
In contrast to example 2, the second desulfurization unit was replaced with a third desulfurization unit 300, i.e., the apparatus comprised the first desulfurization unit and the third desulfurization unit, which is schematically illustrated in fig. 6.
The third desulfurization apparatus 300 includes: the first special reactor 301 and the gas-liquid separation device 302 are connected with the first desulfurization device through pipelines. The lower part of the first special reactor 301 is provided with a gas-liquid inlet mixer 301.1, and the gas-liquid inlet mixer 301.1 is of a branch type branch pipe distributor type which is general in industry; the height-diameter ratio of the first special reactor 301 is 6:1, and the inside of the first special reactor is provided with regularly arranged 450Y stainless steel regular pore plate corrugated packing 301.2 to strengthen gas-liquid mass transfer and reaction; the gas-liquid separation equipment 302 is a wire mesh demister, and is internally provided with B400 stainless wire mesh corrugations 302.1.
The desulfurization process of the embodiment is as follows:
as shown in fig. 7, the sulfur-containing process gas enters the bottom side of a first special reactor 301 through a pipeline, enters a first special reactor 301 together with a desulfurization barren solution entering the bottom, enters a gas-liquid mixer 301.1 of a branch-type branch pipe together with the sulfur-containing process gas and the desulfurization barren solution, is mixed and then enters the first special reactor 301, the mixture of the sulfur-containing process gas and the desulfurization barren solution is fully turbulent mass transfer mixed on a 450Y stainless steel regular corrugated plate packing 301.2 of the first special reactor 301 to perform a strong absorption desulfurization reaction, the reacted gas-liquid mixture is sent to a gas-liquid separation device 302 through a pipeline for separation, and the separated liquid is sent to a desulfurization solution regeneration system through a liquid-rich main pipe through a liquid level regulating valve through a bottom outlet; the separated gas is sent to first desulfurization equipment from an outlet pipe at the top after passing through a wire mesh demister 302.1, and primary desulfurization is completed;
the primary desulfurization process gas sent by the third desulfurization device 300 through the pipeline enters the first high-efficiency reactor 108 from the process gas inlet 109, forms a foam-shaped region with the desulfurization liquid sprayed by the first liquid high-efficiency atomizing nozzle 110 in the first high-efficiency reactor 108, and forms countercurrent turbulence with the gas, so that the gas-liquid contact area is increased; then the gas-liquid mixture flows downstream to the first gas-liquid separator 105 at the lower part of the desulfurizing tower assembly 100 for gas-liquid separation, and the separated desulfurizing liquid enters the liquid-rich level section 106 at the lower part of the desulfurizing tower assembly 100. The process gas separated by the first gas-liquid separator 105 upwards passes through a liquid receiving disc 104.2 and a gas lifting cap 104.1 in a semi-rich liquid level section 104 in the middle of the desulfurizing tower assembly 100 and enters a packed tower 103 in the upper middle of the desulfurizing tower assembly 100, the process gas passes through an inter-segment gas-liquid redistributor 103.1 of each packed section, then passes through a first demisting section 102 on the upper part of the desulfurizing tower assembly 100 and then is discharged out of the desulfurizing tower assembly 100 from a process purified gas outlet 101 on the top of the tower, and desulfurization is completed.
The closed circulation and internal circulation of the desulfurization solution in the first desulfurization apparatus 100 are as follows: the rich liquid separated from the first gas-liquid separator 105 at the lower part of the desulfurizing tower assembly 100 enters the rich liquid level section 106 and is mixed with a part of semi-rich liquid from the liquid receiving tray 104.2. The desulfurized semi-rich liquid reacted by the packed tower 103 on the upper part of the desulfurizing tower assembly 100 automatically flows to a liquid receiving disc 104.2 in the tower, and the semi-rich liquid of the liquid receiving disc is divided into two parts. One part of the reaction liquid is sent to a reaction liquid pump through an outlet pipe on the liquid disc 104.2, and is sent to a first liquid high-efficiency atomizing nozzle 110 in a first high-efficiency reactor 108 through a pump outlet pipe after being pressurized to be sprayed out to react with the process gas, so as to form the internal circulation of the reaction liquid; and the other part of the semi-rich liquid of the liquid receiving disc 104.2 flows to the bottom of the semi-rich liquid level section 104 of the desulfurizing tower assembly 100 through an overflow weir 2 meters higher than the liquid receiving disc 104.2 to form a liquid seal, and after the semi-rich liquid and the rich liquid separated from the reaction liquid circulating in the first high-efficiency reactor 108 in the first gas-liquid separator 105 are mixed in the rich liquid level section 106, the mixed rich liquid is sent to a desulfurizing liquid regeneration system through a rich liquid main pipe after passing through a liquid level regulating valve at the bottom outlet of the desulfurizing tower assembly 100.
This example 3 is suitable for gas flow of 5000Nm3More than H, and H2The desulfurization purification treatment of various sulfur-containing process gases with the S content within 0.1-0.2 (vol%) has the desulfurization efficiency of over 99%.
Example 4
In contrast to example 2, the second desulfurization unit was replaced by a fourth desulfurization unit, i.e., the apparatus comprised the first desulfurization unit and the fourth desulfurization unit, and the schematic diagram of the fourth desulfurization unit is shown in fig. 8.
The fourth desulfurization apparatus 400 includes a second special-purpose reactor 401 and a packed desulfurization tower 402, and is connected to the first desulfurization apparatus through a pipe.
The height-diameter ratio of the second special reactor 401 is 7.2:1, the lower part of the second special reactor is provided with a gas-liquid inlet mixer 401.1, and the gas-liquid inlet mixer 401.1 is of a branch type branch pipe distributor type which is common in industry; the inside is provided with regular BX500 stainless steel wire net corrugated regular packing 401.2 for strengthening gas-liquid transmission and reaction.
The packed desulfurization tower 402 is sequentially provided with a second liquid storage tank section 402.1, a second gas-liquid separator 402.2 at the lower part of the tower, a packed absorption reaction section 402.3, a branch pipe type liquid inlet distributor 402.4 and a second demister 402.5 at the top of the tower from the bottom end to the top end, wherein the packed absorption reaction section 402.3 is filled with bulk packing or structured packing for enhancing gas-liquid mass transfer.
The desulfurization process of the embodiment is as follows:
as shown in fig. 9, the sulfur-containing process gas enters the bottom side of the second special reactor 401 through a gas pipeline, and enters the second special reactor 401 through a liquid inlet pipe and a flow meter with the barren solution sent by the regeneration system, the process gas and the desulfurized barren solution enter the second special reactor 401 and then are fully stirred, mass-transferred and mixed on the high-efficiency filler 401.2 for strong absorption desulfurization reaction, the gas-liquid mixture after the reaction is sent to the second gas-liquid separator 402.2 at the lower part of the filler-type desulfurization tower 402 through a pipeline, the liquid flows into the second liquid storage tank section 402.1 under the action of gravity, and the rich solution outlet at the bottom of the tower is sent to the desulfurization solution regeneration system through a liquid level regulating valve rich solution main; the separated gas upwards enters a filler reaction absorption section 402.3 of the filler type desulfurization tower 402, the gas and the barren solution which flows downwards after being uniformly distributed by a branch pipe type liquid inlet distributor 402.4 are in countercurrent contact on the surface of the high-efficiency filler of the absorption section to carry out desulfurization reaction of mass transfer absorption, and the second demister 402.5 at the top of the purified gas tower after the reaction removes mist foam and then is sent to first desulfurization equipment through a gas outlet pipe to complete primary desulfurization.
The primary desulfurization process gas sent by the fourth desulfurization device 400 through the pipeline enters the first high-efficiency reactor 108, forms a foam-shaped region with the desulfurization liquid sprayed by the first liquid high-efficiency atomizing nozzle 110 in the first high-efficiency reactor 108, and forms countercurrent turbulence with the gas, so that the gas-liquid contact area is increased; then the gas-liquid mixture flows downstream to the first gas-liquid separator 105 at the lower part of the desulfurizing tower assembly 100 for gas-liquid separation, and the separated desulfurizing liquid enters the liquid-rich level section 106 at the lower part of the desulfurizing tower assembly 100. The process gas separated by the first gas-liquid separator 105 upwards passes through a liquid receiving disc 104.2 and a gas lifting cap 104.1 in a semi-rich liquid level section 104 in the middle of the desulfurizing tower assembly 100 and enters a packed tower 103 in the upper middle of the desulfurizing tower assembly 100, the process gas passes through an inter-segment gas-liquid redistributor 103.1 of each packed section, then passes through a first demisting section 102 on the upper part of the desulfurizing tower assembly 100 and then is discharged out of the desulfurizing tower assembly 100 from a process purified gas outlet 101 on the top of the tower, and desulfurization is completed.
This example 4 is suitable for gas flow at 5000Nm3More than H, and H2The desulfurization and purification treatment of various sulfur-containing process gases with the S content within 0.1-0.2 (vol%) can reach the desulfurization efficiency of 9More than 9 percent.
Example 5
Compared with the example 2, the third desulfurization device is added, and only 1 layer of second atomizing spray heads is arranged inside the high-efficiency reaction section in the second desulfurization device, that is, the device comprises the first desulfurization device, the second desulfurization device and the third desulfurization device (the same as the third desulfurization device in the example 3), all the desulfurization devices are connected through the pipeline, the structure of the second desulfurization device is shown in fig. 10, and the device and the process schematic diagram of the embodiment are shown in fig. 11.
In the present embodiment, the first high-efficiency reactor 108 of the first desulfurization device 100 is internally provided with 2 layers of liquid high-efficiency atomizing nozzles; the second desulfurization device 200 is composed of a high-efficiency reaction section 201, a gas-liquid separation section 202, a mixing reaction section 203, a first liquid storage tank section 204 and a tower base 205, wherein the high-efficiency reaction section 201 is provided with 2 layers of liquid high-efficiency atomizing nozzles 201.1; the height-diameter ratio of the first special reactor 301 in the third desulfurization device 300 is 6:1, and the regular arrangement 450Y stainless steel wire mesh corrugated regular packing 301 is arranged in the third desulfurization device to reinforce the gas-liquid transmission quality and the reaction.
The desulfurization process of the embodiment is as follows:
the sulfur-containing process gas enters the efficient reaction section 201 from a sulfur-containing process gas inlet 201.2 at the top of the second desulfurization device 200 through a pipeline and flows downwards, a foam-shaped area is formed by the sulfur-containing process gas and desulfurization liquid sprayed by the internal 2-layer liquid efficient atomizing spray head 201.1, and the sulfur-containing process gas and the gas form specific countercurrent turbulence, so that the gas-liquid contact area is increased; then the gas-liquid mixture flows downstream to the internal gas-liquid mixing ejector 203.1 to the mixing reaction section 203 and enters the liquid receiving tank 203.2 of the high-efficiency mixer, and the secondary gas-liquid high-efficiency mixing turbulent enhanced reaction is carried out, which is equivalent to two times of enhanced desulfurization enhanced absorption reaction in the same equipment. Then, the gas after the reaction of the high-efficiency mixer by the liquid tank cylinder 203.2 rises to the conical cover baffle 202.1 of the gas-liquid separation section 202, passes through the annular baffle 202.2, and is sent out of the equipment through the process purified gas outlet 202.3 to finish primary desulfurization, and then enters the third desulfurization 300 equipment.
The process gas of the primary desulfurization enters the bottom side part of a first special reactor 301 from a second desulfurization device 200 through a pipeline, enters the first special reactor 301 together with the desulfurization barren solution entering the bottom, the sulfur-containing process gas and the desulfurization barren solution enter a gas-liquid mixer 301.1 of a branch-type branch pipe, are mixed and then enter the first special reactor 301, the mixture of the sulfur-containing process gas and the desulfurization barren solution is fully turbulent and mass-transfer mixed on a 450Y stainless steel regular orifice plate corrugated packing 301.2 of the first special reactor 301, and is subjected to a strong absorption desulfurization reaction, the gas-liquid mixture after the reaction is sent to a gas-liquid separation device 302 through a pipeline for separation, and the separated liquid is sent to a desulfurization solution regeneration system through a liquid-rich main pipe through a liquid level regulating valve through a bottom outlet; and the separated gas is sent to the first desulfurization device from the top outlet pipe after passing through the wire mesh demister 302.1, so that secondary desulfurization is completed.
The secondary desulfurization process gas sent by the third desulfurization device 300 through the pipeline enters the first high-efficiency reactor 108 from the process gas inlet 109, forms a foam-shaped region with the desulfurization liquid sprayed by the first liquid high-efficiency atomizing nozzle 110 in the first high-efficiency reactor 108, and forms countercurrent turbulence with the gas, so that the gas-liquid contact area is increased; then the gas-liquid mixture flows downstream to the first gas-liquid separator 105 at the lower part of the desulfurizing tower assembly 100 for gas-liquid separation, and the separated desulfurizing liquid enters the liquid-rich level section 106 at the lower part of the desulfurizing tower assembly 100. The process gas separated by the first gas-liquid separator 105 upwards passes through a liquid receiving disc 104.2 and a gas lifting cap 104.1 in a semi-rich liquid level section 104 in the middle of the desulfurizing tower assembly 100 and enters a packed tower 103 in the upper middle of the desulfurizing tower assembly 100, the process gas passes through an inter-segment gas-liquid redistributor 103.1 of each packed section, then passes through a first demisting section 102 on the upper part of the desulfurizing tower assembly 100 and then is discharged out of the desulfurizing tower assembly 100 from a process purified gas outlet 101 on the top of the tower, and desulfurization is completed.
This example 5 is suitable for gas volume of 10000Nm3More than H, and H2Desulfurizing and purifying the sulfur-containing process gas with the S content of 0.2-0.5 (vol%); and gas amount is 200-400 Nm3about/H, H2The sulfur-containing acid gas with the S content of 60-97% (vol%) is subjected to desulfurization purification treatment, and the desulfurization efficiency can reach more than 99.5%.
Example 6
Compared with the example 2, a fourth desulfurization device is added, that is, the device comprises a first desulfurization device, a second desulfurization device and a fourth desulfurization device (the same as the fourth desulfurization device in the example 4), all the desulfurization devices are connected through pipelines, and the device and the process schematic diagram are shown in fig. 12.
In the present embodiment, the first high-efficiency reactor 108 of the first desulfurization device 100 is internally provided with 2 layers of liquid high-efficiency atomizing nozzles; the second desulfurization device 200 is composed of a high-efficiency reaction section 201, a gas-liquid separation section 202, a mixing reaction section 203, a first liquid storage tank section 204 and a tower base 205, wherein the high-efficiency reaction section 201 is provided with 2 layers of liquid high-efficiency atomizing nozzles 201.1; the height-diameter ratio of the second special reactor 401 in the fourth desulfurization device 400 is 7.2:1, the inside of the second special reactor is provided with regular BX500 stainless steel wire mesh corrugated structured packing which is arranged regularly, gas-liquid mass transfer and reaction are enhanced, the filled desulfurization tower 402 is sequentially provided with a second liquid storage tank section 402.1, a second gas-liquid separator 402.2, a packing absorption reaction section 402.3, a branch pipe type liquid inlet distributor 402.4 and a second demister 402.5 at the top from the bottom to the top, wherein the packing absorption reaction section is filled with bulk packing or regular packing which is used for enhancing gas-liquid mass transfer.
The desulfurization process of the embodiment is as follows:
the sulfur-containing process gas enters the efficient reaction section 201 from a sulfur-containing process gas inlet 201.2 at the top of the second desulfurization device 200 through a pipeline and flows downwards, a foam-shaped area is formed by the sulfur-containing process gas and desulfurization liquid sprayed by the internal 2-layer liquid efficient atomizing spray head 201.1, and the sulfur-containing process gas and the gas form specific countercurrent turbulence, so that the gas-liquid contact area is increased; then the gas-liquid mixture flows downstream to the internal gas-liquid mixing ejector 203.1 to the mixer reaction section 203 to enter the mixer liquid receiving tank 203.2 to carry out secondary gas-liquid high-efficiency mixing turbulent enhanced reaction, which is equivalent to carrying out two times of enhanced desulfurization enhanced absorption reaction in the same equipment. Then, the gas after the reaction of the high-efficiency mixer by the liquid tank cylinder 203.2 rises to the conical cover baffle 202.1 of the gas-liquid separation section 202, passes through the annular baffle 202.2, is sent out of the equipment through the process purified gas outlet 202.3, completes the primary desulfurization, and enters the fourth desulfurization equipment 400.
The process gas which finishes the primary desulfurization enters the bottom side part of a second special reactor 401 from a second desulfurization device 200 through a gas pipeline, enters the second special reactor 401 with barren liquor sent by a regeneration system through a liquid inlet pipe and a flowmeter, the process gas and the desulfurized barren liquor enter a gas-liquid mixer at the lower part of the second special reactor 401 and are mixed together to enter high-efficiency filler, the mixture is fully stirred and mass-transferred on the surface of the filler to be mixed for strong absorption desulfurization reaction, the gas-liquid mixture after the reaction is sent to a second gas-liquid separator 402.2 at the lower part of a filler type desulfurization tower 402 through a pipeline, liquid flows into a second liquid storage tank section 402.1 under the action of gravity, and a rich liquor outlet at the bottom of the tower is sent to a desulfurization liquor regeneration system through a liquid level regulating valve and a rich liquor main pipe; the separated gas upwards enters a filler reaction absorption section 402.3 of the filler type desulfurization tower 402, the gas and the barren solution which flows downwards after being uniformly distributed by a branch pipe type liquid inlet distributor 402.4 are in countercurrent contact on the surface of the high-efficiency filler of the absorption section to carry out desulfurization reaction of mass transfer absorption, and the second demister 402.5 at the top of the purified gas tower after the reaction removes mist foam and then is sent to a first desulfurization device through a gas outlet pipe to complete secondary desulfurization.
The secondary desulfurization process gas sent by the fourth desulfurization device 400 through the pipeline enters the first high-efficiency reactor 108 from the process gas inlet 109, forms a foam-shaped region with the desulfurization liquid sprayed by the first liquid high-efficiency atomizing nozzle 110 in the first high-efficiency reactor 108, and forms countercurrent turbulence with the gas, so that the gas-liquid contact area is increased; then the gas-liquid mixture flows downstream to a first gas-liquid separator 105 at the lower part of the desulfurizing tower assembly 100 for gas-liquid separation, the separated desulfurizing liquid enters a liquid-rich liquid level section 106 at the lower part of the desulfurizing tower assembly 100, is mixed with a part of semi-rich liquid from a liquid receiving disc 104.2, passes through a liquid level regulating valve at the bottom outlet of the desulfurizing tower assembly 100, and is sent to a desulfurizing liquid regeneration system. The other part of the liquid receiving disc 104.2 in the tower is sent to a reaction liquid pump through an outlet pipe on the liquid receiving disc 104.2, and is sent to an efficient atomizing nozzle 110 in the I-type efficient reactor 108 through a pump outlet pipe after being pressurized to be sprayed out to react with process gas to form internal circulation of reaction liquid; the process gas separated by the first gas-liquid separator 105 upwards passes through a liquid receiving disc 104.2 and a gas lifting cap 104.1 in a semi-rich liquid level section 104 in the middle of the desulfurizing tower assembly 100 and enters a packed tower 103 in the upper middle of the desulfurizing tower assembly 100, the process gas passes through an inter-segment gas-liquid redistributor 103.1 of each packed section, then passes through a first demisting section 102 on the upper part of the desulfurizing tower assembly 100 and then is discharged out of the desulfurizing tower assembly 100 from a process purified gas outlet 101 on the top of the tower, and desulfurization is completed.
This example 6 is suitable for gas volume of 10000Nm3More than H, and H2Desulfurizing and purifying the sulfur-containing process gas with the S content of 0.2-0.5 (vol%); and gas amount is 200-400 Nm3about/H, H2The sulfur-containing acid gas with the S content of 60-97% (vol%) is subjected to desulfurization purification treatment, and the desulfurization efficiency can reach more than 99.5%.
Example 7
Compared with the example 3, a fourth desulfurization device is added, namely the device comprises the first desulfurization device, the third desulfurization device and the fourth desulfurization device (the same as the fourth desulfurization device in the example 4), all the desulfurization devices are connected through pipelines, and the device and the process schematic diagram are shown in fig. 13.
In the present embodiment, the first high-efficiency reactor 108 of the first desulfurization device 100 is internally provided with 2 layers of liquid high-efficiency atomizing nozzles; the height-diameter ratio of the first special reactor 301 in the third desulfurization device 300 is 6:1, and 450Y stainless steel structured pore plate corrugated packing is arranged in the third special reactor to strengthen gas-liquid mass transfer and reaction; the height-diameter ratio of the second special reactor 401 in the fourth desulfurization device 400 is 7.2:1, the inside of the second special reactor is provided with regular BX500 stainless steel wire mesh corrugated structured packing which is arranged regularly, gas-liquid mass transfer and reaction are enhanced, the filled desulfurization tower 402 is sequentially provided with a second liquid storage tank section 402.1, a second gas-liquid separator 402.2, a packing absorption reaction section 402.3, a branch pipe type liquid inlet distributor 402.4 and a second demister 402.5 at the top from the bottom to the top, wherein the packing absorption reaction section is filled with bulk packing or regular packing which is used for enhancing gas-liquid mass transfer.
The desulfurization process of the embodiment is as follows:
the sulfur-containing process gas enters the bottom side part of a first special reactor 301, enters the first special reactor 301 together with the desulfurization barren solution entering the bottom, enters a gas-liquid mixer 301.1 of a branch-type branch pipe, is mixed and then enters the first special reactor 301, the mixture of the sulfur-containing process gas and the desulfurization barren solution is fully stirred and mass-transferred and mixed on a corrugated packing 301.2 of a 450Y stainless steel regular pore plate of the first special reactor 301 to carry out strong absorption desulfurization reaction, the reacted gas-liquid mixture is sent to a gas-liquid separation device 302 for separation through a pipeline, and the separated liquid is sent to a desulfurization solution regeneration system through a liquid level regulating valve and a rich solution main pipe through a bottom outlet; the separated gas passes through a wire mesh demister 302.1; and sending the mixture to a fourth desulfurization device through an outlet pipe at the top of the separator to finish primary desulfurization.
The process gas which finishes the primary desulfurization enters the bottom side part of a second special reactor 401 through a gas pipeline by a third desulfurization device, enters the second special reactor 401 with lean solution sent by a regeneration system through a liquid inlet pipe and a flowmeter, is mixed in a gas-liquid mixer at the lower part of the second special reactor, then enters high-efficiency filler, is fully stirred and mixed on the surface of the filler to carry out strong absorption desulfurization reaction, the gas-liquid mixture after the reaction is sent to a second gas-liquid separator 402.2 at the lower part of a filler type desulfurization tower 402 through a pipeline, liquid flows into a second liquid storage tank section 402.1 under the action of gravity, and a rich solution outlet at the bottom of the tower is sent to a desulfurization solution regeneration system through a liquid level regulating valve and a rich solution main pipe; the separated gas upwards enters a filler reaction absorption section 402.3 of the filler type desulfurization tower 402, the gas and the barren solution which flows downwards after being uniformly distributed by a branch pipe type liquid inlet distributor 402.4 are in countercurrent contact on the surface of the high-efficiency filler of the absorption section to carry out desulfurization reaction of mass transfer absorption, and the second demister 402.5 at the top of the purified gas tower after the reaction removes mist foam and then is sent to a first desulfurization device through a gas outlet pipe to complete secondary desulfurization.
The secondary desulfurization process gas sent by the fourth desulfurization device 400 through the pipeline enters the first high-efficiency reactor 108 from the process gas inlet 109, forms a foam-shaped region with the desulfurization liquid sprayed by the first liquid high-efficiency atomizing nozzle 110 in the first high-efficiency reactor 108, and forms countercurrent turbulence with the gas, so that the gas-liquid contact area is increased; then the gas-liquid mixture flows downstream to a first gas-liquid separator 105 at the lower part of the desulfurizing tower assembly 100 for gas-liquid separation, the separated desulfurizing liquid enters a liquid-rich liquid level section 106 at the lower part of the desulfurizing tower assembly 100, is mixed with a part of semi-rich liquid from a liquid receiving disc 104.2, passes through a liquid level regulating valve at the bottom outlet of the desulfurizing tower assembly 100, and is sent to a desulfurizing liquid regeneration system. The other part of the liquid receiving disc 104.2 in the tower is sent to a reaction liquid pump through an outlet pipe on the liquid receiving disc 104.2, and is sent to an efficient atomizing nozzle 110 in the I-type efficient reactor 108 through a pump outlet pipe after being pressurized to be sprayed out to react with process gas to form internal circulation of reaction liquid; the process gas separated by the first gas-liquid separator 105 upwards passes through a liquid receiving disc 104.2 and a gas lifting cap 104.1 in a semi-rich liquid level section 104 in the middle of the desulfurizing tower assembly 100 and enters a packed tower 103 in the upper middle of the desulfurizing tower assembly 100, the process gas passes through an inter-segment gas-liquid redistributor 103.1 of each packed section, then passes through a first demisting section 102 on the upper part of the desulfurizing tower assembly 100 and then is discharged out of the desulfurizing tower assembly 100 from a process purified gas outlet 101 on the top of the tower, and desulfurization is completed.
This example 7 is suitable for gas volume of 10000Nm3More than H, and H2Desulfurizing and purifying the sulfur-containing process gas with the S content of 0.2-0.5 (vol%); and gas amount is 200-400 Nm3about/H, H2The sulfur-containing acid gas with the S content of 60-97% (vol%) is subjected to desulfurization purification treatment, and the desulfurization efficiency can reach more than 99.5%.
Example 8
Compared with example 7, a second desulfurization device (the same as the second desulfurization device in example 2) is added, that is, the device comprises a first desulfurization device, a second desulfurization device, a third desulfurization device and a fourth desulfurization device, all the desulfurization devices are connected through pipelines, and the device and process schematic diagram is shown in fig. 14.
In the present embodiment, the first high-efficiency reactor 108 of the first desulfurization device 100 is internally provided with 2 layers of liquid high-efficiency atomizing nozzles; the second desulfurization device 200 is composed of a high-efficiency reaction section 201, a gas-liquid separation section 202, a mixing reaction section 203, a first liquid storage tank section 204 and a tower base 205, wherein the high-efficiency reaction section 201 is provided with 2 layers of liquid high-efficiency atomizing nozzles 201.1; the height-diameter ratio of the first special reactor 301 in the third desulfurization device 300 is 6:1, and 450Y stainless steel structured pore plate corrugated packing is arranged in the third special reactor to strengthen gas-liquid mass transfer and reaction; the height-diameter ratio of the second special reactor 401 in the fourth desulfurization device 400 is 7.2:1, the inside of the second special reactor is provided with regular BX500 stainless steel wire mesh corrugated structured packing which is arranged regularly, gas-liquid mass transfer and reaction are enhanced, the filled desulfurization tower 402 is sequentially provided with a second liquid storage tank section 402.1, a second gas-liquid separator 402.2, a packing absorption reaction section 402.3, a branch pipe type liquid inlet distributor 402.4 and a second demister 402.5 at the top from the bottom to the top, wherein the packing absorption reaction section is filled with bulk packing or regular packing which is used for enhancing gas-liquid mass transfer.
The desulfurization solution in each desulfurization device is provided with five branch pipes 501, 502, 503, 504, 505 (wherein the fourth desulfurization device 400 is two pipes, and 1 is respectively provided for the second special reactor 401 and the packed desulfurization tower 402) from the regenerated lean solution header pipe 500, and is respectively connected with the first special reactor 301 in the second desulfurization device 200 and the third desulfurization device 300, the second special reactor 401 and the packed desulfurization tower 402 in the fourth desulfurization device 400, and the desulfurization tower assembly 100 in the first desulfurization device is respectively connected through the branch pipes; the reacted rich liquid is respectively provided with a rich liquid outlet in the gas-liquid separation equipment 302 in the bottom of the desulfurizing tower assembly 100, the efficient reaction section 201 in the second desulfurizing equipment 200, the third desulfurizing equipment 300 and the packed desulfurizing tower 402 in the fourth desulfurizing equipment, and the rich liquid is sent to the regeneration system through the corresponding liquid level outlet pipelines respectively.
In the present embodiment, the five branch pipes 501, 502, 503, 504, 505 of the lean solution header pipe 500 are provided with lean solution flow meters 506, 507, 508, 509, 510; the liquid level meter 511, 512, 513, 514 are installed on the lateral wall of the gas-liquid separation equipment 302 among the first desulfurization equipment and the material filled type desulfurization tower 402 among the desulfurization tower assembly 100 among the first desulfurization equipment, the high-efficient reaction section 201 among the second desulfurization equipment 200, the third desulfurization equipment in the gas-liquid separation equipment and the fourth desulfurization equipment, install liquid level control valve 515, 516, 517, 518 on the liquid outlet pipeline that corresponds, the liquid level meter forms the control chain with the liquid level control governing valve and reports to the police, reach the effect of automatic control liquid level height.
The desulfurization process of the embodiment is as follows:
the sulfur-containing process gas enters the efficient reaction section 201 from a sulfur-containing process gas inlet 201.2 at the top of the second desulfurization device 200 through a pipeline and flows downwards, a foam-shaped area is formed by the sulfur-containing process gas and desulfurization liquid sprayed by the internal 2-layer liquid efficient atomizing spray head 201.1, and the sulfur-containing process gas and the gas form specific countercurrent turbulence, so that the gas-liquid contact area is increased; then the gas-liquid mixture flows downstream to the internal gas-liquid mixing ejector 203.1 to the reaction section of the mixer and enters the liquid receiving tank 203.2 of the high-efficiency mixer to carry out secondary gas-liquid high-efficiency mixing turbulent enhanced reaction, which is equivalent to carrying out two times of enhanced desulfurization enhanced absorption reaction in the same equipment. Then, the gas after the reaction of the high-efficiency mixer by the liquid tank cylinder 203.2 rises to the conical cover baffle 202.1 of the gas-liquid separation section 202, passes through the annular baffle 202.2, and is sent out of the equipment through the process purified gas outlet 202.3 to finish primary desulfurization, and then enters the third desulfurization 300 equipment.
The process gas of the primary desulfurization enters the bottom side part of a first special reactor 301 from a second desulfurization device 200 through a pipeline, enters the first special reactor 301 together with the desulfurization barren solution entering the bottom, the sulfur-containing process gas and the desulfurization barren solution enter a gas-liquid mixer 301.1 of a branch-type branch pipe, are mixed and then enter the first special reactor 301, the mixture of the sulfur-containing process gas and the desulfurization barren solution is fully turbulent and mass-transfer mixed on a 450Y stainless steel regular orifice plate corrugated packing 301.2 of the first special reactor 301, and is subjected to a strong absorption desulfurization reaction, the gas-liquid mixture after the reaction is sent to a gas-liquid separation device 302 through a pipeline for separation, and the separated liquid is sent to a desulfurization solution regeneration system through a liquid-rich main pipe through a liquid level regulating valve through a bottom outlet; the separated gas passes through a wire mesh demister 302.1; and sending the mixture to a fourth desulfurization device through an outlet pipe at the top of the separator to complete secondary desulfurization.
The process gas which completes the secondary desulfurization enters the bottom side part of a second special reactor 401 through a gas pipeline by a third desulfurization device, enters the second special reactor 401 with lean solution sent by a regeneration system through a liquid inlet pipe and a flowmeter, is mixed in a gas-liquid mixer at the lower part of the second special reactor, then enters high-efficiency filler, is fully stirred and mixed on the surface of the filler to carry out strong absorption desulfurization reaction, the gas-liquid mixture after the reaction is sent to a second gas-liquid separator 402.2 at the lower part of a filler type desulfurization tower 402 through a pipeline, liquid flows into a second liquid storage tank section 402.1 under the action of gravity, and a rich solution outlet at the bottom of the tower is sent to a desulfurization solution regeneration system through a liquid level regulating valve and a rich solution main pipe; the separated gas upwards enters a filler reaction absorption section 402.3 of the filler type desulfurization tower 402, the gas and the barren solution which flows downwards after being uniformly distributed by a branch pipe type liquid inlet distributor 402.4 are in countercurrent contact on the surface of the high-efficiency filler of the absorption section to carry out desulfurization reaction of mass transfer absorption, and the second demister 402.5 at the top of the purified gas tower after the reaction removes mist foam and then is sent to a first desulfurization device through a gas outlet pipe to finish tertiary desulfurization.
The third desulfurization process gas sent by the fourth desulfurization device 400 through the pipeline enters the first high-efficiency reactor 108 from the process gas inlet 109, forms a foam-shaped region with the desulfurization liquid sprayed by the first liquid high-efficiency atomizing nozzle 110 in the first high-efficiency reactor 108, and forms countercurrent turbulence with the gas, so that the gas-liquid contact area is increased; then the gas-liquid mixture flows downstream to a first gas-liquid separator 105 at the lower part of the desulfurizing tower assembly 100 for gas-liquid separation, and the separated desulfurizing liquid enters a liquid-rich level section 106 at the lower part of the desulfurizing tower assembly 100; the process gas separated by the gas-liquid separator 105 in the tower upwards passes through a liquid receiving disc 104.2 and a gas lifting cap 104.1 in a semi-rich liquid level section 104 in the middle of the desulfurizing tower assembly 100 and enters a desulfurizing tower filling section 103 in the upper middle of the desulfurizing tower assembly 100, the process gas passes through all the filling sections, an inter-section gas-liquid redistributor 103.1 and a tower top liquid inlet liquid distributor 103.2, then passes through a tower top demisting section 102 at the top of the desulfurizing tower assembly 100 and then is discharged out of a desulfurizing tower from a process purified gas outlet 101 at the top of the desulfurizing tower to complete desulfurization and purification, and the purified gas qualified by desulfurization is sent out of a system for use.
The semi-rich liquid at the upper part of the liquid receiving disc 104.2 arranged in the middle of the desulfurizing tower assembly is divided into two parts, wherein one part of the semi-rich liquid is intercepted in a liquid level section with the height of 2 meters on the liquid receiving disc 104.2, the semi-rich liquid on the liquid receiving disc 104.2 automatically flows to a reaction pump through an upper disc outlet, and is pressurized by the pump and sent to a first efficient reactor 108 in front of the desulfurizing tower assembly 100 to form semi-rich liquid internal circulation; and the other part of semi-rich liquid exceeding the semi-internal circulation volume of the reaction liquid overflows to the lower part of a rich liquid level section 106 at the lower part of the desulfurizing tower assembly to form a liquid seal after the overflow downcomer 104.3 in the liquid tray 104.2 is 2 meters higher than the liquid level section of the liquid tray, so that the redundant semi-rich liquid naturally forms a liquid level of 2 meters and automatically flows into the rich liquid level section 106, and the process gas on the rich liquid level section 106 cannot enter the downcomer 104.3.
Wherein the catalyst in the desulfurization solution is a compound containing cobalt phthalocyanine sulfonate or an organic complexing agent plus a water-soluble base iron system; the superficial gas velocity of the sulfur-containing process gas in the packed desulfurizing tower 402 and the desulfurizing tower assembly 100 is 40-80% of the flooding velocity.
This example 8 is suitable for gas flow in 10000Nm3More than H, and H2Desulfurizing and purifying the sulfur-containing process gas with the S content of more than 0.5 (vol%); and gas amount is 400Nm3Over H, H2The sulfur-containing acid gas with the S content of 60-97% (vol%) is subjected to desulfurization and purification treatment, and the total desulfurization efficiency can reach more than 99.9%.
When a plurality of kinds of desulfurization equipment exist in each embodiment, the front and back sequences of each desulfurization equipment and the corresponding process can be interchanged, and the corresponding purification treatment process of the high-efficiency wet desulfurization of the sulfur-containing gas is realized by the desulfurization device and the process of the embodiment; utilize various desulphurization unit and technology of the embodiment of the utility model to carry out H in the purified gas after desulphurization purification treatment2S can be below 20 ppm.
The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, many modifications and improvements can be made without departing from the inventive concept, and all of them belong to the protection scope of the present invention.

Claims (8)

1. A sulfur-containing process gas wet desulphurization device is characterized in that the device is a first desulphurization device and comprises:
the desulfurizing tower assembly is sequentially provided with a process purified gas outlet, a first demisting section, a packed tower, a semi-rich liquid level section, a first gas-liquid separator, a rich liquid level section and a tower seat from the top end to the bottom end; and
the first high-efficiency reactor is fixedly installed on the outer side of the tower wall of the desulfurizing tower assembly and communicated with the first gas-liquid separator, a sulfur-containing process gas inlet is formed in the top end of the first high-efficiency reactor, and a plurality of layers of first atomizing nozzles are arranged inside the first high-efficiency reactor.
2. The apparatus of claim 1, wherein the semi-rich level section comprises an aeration cap, a catch tray, and a downcomer, wherein a portion of the semi-rich in the semi-rich level section is used as a desulfurization solution for the first high efficiency reactor and another portion overflows through the downcomer to the rich level section.
3. The apparatus of claim 1, wherein the packed tower comprises 1, 2 or 3 packed absorption sections, each packed absorption section is provided with a gas-liquid redistributor at the top, and a liquid-liquid distributor at the top of the packed absorption section near the top of the tower is provided with a liquid-liquid distributor at the top of the tower.
4. The apparatus as set forth in claim 1 wherein said first demister section comprises a first demister and a demister flushing device.
5. The apparatus of claim 1, further comprising a second desulfurization device connected to said first desulfurization device by a conduit, comprising:
the high-efficiency reaction section is internally provided with 1 layer or 2 layers of second atomizing nozzles, and the sprayed desulfurization liquid is in countercurrent contact with the process gas to generate desulfurization absorption reaction;
the mixed reaction section is provided with a gas-liquid mixed ejector and a high-efficiency mixer liquid receiving tank cylinder and is used for secondary reaction of the process gas and the desulfurization liquid;
a gas-liquid separation section;
the first liquid storage tank section is used for storing the desulfurized liquid after reaction; and
a tower skirt.
6. The apparatus of claim 1 or 5, further comprising a third desulfurization device, the third desulfurization device comprising:
the first special reactor and the gas-liquid separation equipment are connected with the first or second desulfurization equipment through pipelines;
wherein, the lower part of the first special reactor is provided with a gas-liquid inlet mixer, and the inside of the first special reactor is provided with a first stainless steel corrugated filler.
7. The apparatus of claim 1 or 5, further comprising a fourth desulfurization device, the fourth desulfurization device comprising:
the second special reactor and the filler type desulfurizing tower are connected with the desulfurizing equipment through pipelines;
the packed desulfurization tower is sequentially provided with a second liquid storage tank section, a second gas-liquid separator, a packed absorption reaction section, a liquid inlet distributor and a second demister from bottom to top; and a second stainless steel corrugated packing is arranged in the second special reactor.
8. The apparatus of claim 6, further comprising a fourth desulfurization device, the fourth desulfurization device comprising:
the second special reactor and the filler type desulfurizing tower are connected with the desulfurizing equipment through pipelines;
the packed desulfurization tower is sequentially provided with a second liquid storage tank section, a second gas-liquid separator, a packed absorption reaction section, a liquid inlet distributor and a second demister from bottom to top; and a second stainless steel corrugated packing is arranged in the second special reactor.
CN202021600195.0U 2020-08-05 2020-08-05 Sulfur-containing process gas wet desulphurization device Active CN212396335U (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN111773895A (en) * 2020-08-05 2020-10-16 四川省达科特能源科技股份有限公司 Sulfur-containing process gas wet desulphurization device and process

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN111773895A (en) * 2020-08-05 2020-10-16 四川省达科特能源科技股份有限公司 Sulfur-containing process gas wet desulphurization device and process

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