CN212832846U - System for improving heat recovery steam production rate of sulfuric acid production dry-suction workshop section - Google Patents

System for improving heat recovery steam production rate of sulfuric acid production dry-suction workshop section Download PDF

Info

Publication number
CN212832846U
CN212832846U CN202021225484.7U CN202021225484U CN212832846U CN 212832846 U CN212832846 U CN 212832846U CN 202021225484 U CN202021225484 U CN 202021225484U CN 212832846 U CN212832846 U CN 212832846U
Authority
CN
China
Prior art keywords
acid
temperature
heat recovery
section
evaporator
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
CN202021225484.7U
Other languages
Chinese (zh)
Inventor
俞向东
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Nanjing Hailu Chemical Technology Co ltd
Original Assignee
Nanjing Hailu Chemical Technology Co ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Nanjing Hailu Chemical Technology Co ltd filed Critical Nanjing Hailu Chemical Technology Co ltd
Priority to CN202021225484.7U priority Critical patent/CN212832846U/en
Application granted granted Critical
Publication of CN212832846U publication Critical patent/CN212832846U/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Images

Classifications

    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P20/00Technologies relating to chemical industry
    • Y02P20/10Process efficiency
    • Y02P20/129Energy recovery, e.g. by cogeneration, H2recovery or pressure recovery turbines

Landscapes

  • Treating Waste Gases (AREA)
  • Drying Of Gases (AREA)

Abstract

The utility model provides a system for improve sulphuric acid production dry-suction workshop section heat recovery steam production rate belongs to the chemical industry field. The system independently sends the lower tower acid of the low-temperature absorption section of the heat recovery tower to a drying or secondary absorption system, and the lower tower acid is not mixed with the lower tower acid of the high-temperature absorption section, so that the lower tower acid temperature of the high-temperature absorption section is increased, the heat brought out by the sulfuric acid sent out by the heat recovery system to the outside is reduced, and the steam production rate of the heat recovery system is increased by about 10-25%.

Description

System for improving heat recovery steam production rate of sulfuric acid production dry-suction workshop section
Technical Field
The utility model relates to a chemical industry field, concretely relates to improve system of sulphuric acid production dry-suction workshop section heat recovery steam production rate.
Background
The modern sulfuric acid production mostly adopts a 2-to-2-absorption production process, and S0 is contained in the sulfuric acid produced by an upstream device2The process gas (or the air participating in the conversion reaction) enters a drying system, concentrated sulfuric acid is used for removing water, and then the process gas enters a conversion sectionConvert at once most S02And O2Reacting to form SO3. Containing SO after one conversion3The process gas is sent into a heat recovery system of a dry absorption section for primary absorption, and high-temperature sulfuric acid is used for absorbing SO in the process gas3And recovering heat of the absorption reaction to produce low pressure steam. SO in process gas after primary absorption3The concentration is reduced, the process gas after the primary absorption is sent to a conversion section for secondary conversion, and the rest S0 is2Continued oxidation to produce SO3The process gas after the secondary conversion is sent into a secondary absorption system of a dry absorption working section to absorb SO in the process gas by using sulfuric acid3And more than 99 percent of S0 in the process gas after 2-to-2-conversion absorption2Are all converted into SO3And sulfuric acid is produced after absorption.
Acid mixing pipelines are arranged among the drying system, the heat recovery system and the secondary absorption system, and the acid concentration and the liquid level stability of the systems are maintained by mutually mixing sulfuric acid.
SO after primary conversion3The reaction heat and dilution heat for absorbing and generating the sulfuric acid account for more than 70% of the process generated heat in the whole dry absorption section, a heat recovery system in the dry absorption section adopts a high-temperature absorption process, high-temperature sulfuric acid is used for heating low-pressure feedwater to generate low-pressure steam, a drying and secondary absorption system adopts a low-temperature absorption process, the acid temperature after absorption is low, the absorption heat cannot be utilized, and the absorption reaction heat is carried out of a process system through circulating water.
The main process flow of the heat recovery system of the dry absorption section is as follows: containing SO3The process gas enters a heat recovery tower which is generally divided into two stages, wherein a high-temperature absorption section (lower stage) absorbs most of SO in the process gas by using high-temperature (180 ℃) and high-concentration (99%) sulfuric acid3The process gas after absorption in the high-temperature absorption section enters the low-temperature absorption section (the upper stage) again for reabsorption of sulfuric acid with lower temperature (60 ℃) and lower concentration (98.5%) from the drying or secondary absorption system. The sulfuric acid absorbed by the low-temperature absorption section enters the high-temperature absorption section to be mixed with high-temperature concentrated sulfuric acid, is pumped and pressurized by a high-temperature circulating pump and is sent into an evaporator to generate low-pressure steam, the acid temperature is reduced, then the low-pressure steam enters a mixer to be added with water to reduce the acid concentration, and then the low-pressure steam is sent into a heat recovery tower to circularly absorb SO3(ii) a The acid side outlet of the evaporator is provided with a heat recovery systemThe system is to the acid delivery pipeline of the drying or secondary absorption system, because the acid temperature of the outlet of the evaporator is still higher (180 +/-15 ℃), the external acid delivery pipeline is provided with an evaporator feed water heater for preheating feed water entering the evaporator, the acid temperature is reduced to 160 +/-15 ℃, other heat exchangers can be arranged, the process material is heated by the external sulfuric acid, and the external sulfuric acid is delivered to the drying or secondary absorption system after being cooled, so as to maintain the acid concentration and the liquid level stability of the system. In a sulfuric acid device using sulfur as a raw material, the steam production rate of a heat recovery system in a dry absorption section is generally 0.45 ton of steam per ton of acid; the steam production rate of a sulfuric acid device taking pyrite as a raw material is generally 0.25-0.35 ton of steam per ton of acid.
SUMMERY OF THE UTILITY MODEL
The utility model provides a system for improve sulphuric acid production dry-suction workshop section heat recovery steam production rate to the technical problem that prior art exists.
The purpose of the utility model can be realized by the following technical scheme:
a system for improving the heat recovery steam production rate of a dry absorption section in sulfuric acid production comprises a heat recovery tower, wherein the heat recovery tower comprises a high-temperature absorption section, a gas-liquid separation section and a low-temperature absorption section, and the high-temperature absorption section is connected with the upper part of the high-temperature absorption section sequentially through a high-temperature circulation tank, a high-temperature circulation pump, an evaporator and a mixer;
and a branch is further arranged on an acid pipeline connected with the evaporator and the mixer, the branch is connected with the drying or secondary absorption system sequentially through at least one heat exchange device, and the liquid output end of the gas-liquid separation section is also connected with the drying or secondary absorption system.
The utility model discloses among the technical scheme: the heat exchange equipment at least comprises an evaporator feed water heater.
The utility model discloses among the technical scheme: the branch is connected with the upper parts of the acid circulating tank, the acid circulating pump, the acid cooler and the drying tower or the secondary absorption tower in turn through the evaporator water supply heater.
The utility model discloses among the technical scheme: and the liquid output end of the gas-liquid separation section is connected with the acid circulation tank.
The utility model discloses among the technical scheme: the acid side of the acid cooler is also provided with an output end which is connected with the upper part of the low-temperature absorption section.
The utility model discloses among the technical scheme: the output end of the evaporator feed water heater is connected with the evaporator.
A method for increasing steam production using the first described system, the method comprising:
a method for improving the heat recovery steam production rate of the dry absorption section in the sulfuric acid production by using the system comprises the step of adding SO3The process gas enters a high-temperature absorption section of the heat recovery tower, and SO is contained in the process gas3Part of the sulfuric acid is absorbed by high-temperature sulfuric acid with the concentration of 99 percent, the acid temperature of a tower under the high-temperature absorption section is raised to 205 +/-15 ℃, high-temperature concentrated acid is boosted by a high-temperature circulating pump and then sent to an evaporator to be heated by low-pressure feed water to generate low-pressure steam, the acid temperature is reduced to 190 +/-15 ℃ after being discharged from the evaporator, part of sulfuric acid discharged from the evaporator is sent to a mixer to adjust the concentration of the sulfuric acid to 99 percent, and then the sulfuric acid is sent to the high-temperature absorption section to circularly3Preheating the rest (10-40%) of sulfuric acid out of the evaporator by an evaporator feed water heater, feeding the sulfuric acid into feed water of the evaporator, reducing the acid temperature to 170 +/-15 ℃, and cooling the rest of sulfuric acid by equipment and then sending the cooled sulfuric acid to a drying or secondary absorption system;
the process gas enters a low-temperature absorption section after being absorbed by a high-temperature absorption section of a heat recovery tower, and is used for spraying and absorbing the residual S0 in the process gas from a sulfuric acid spray system with the drying or secondary absorption system temperature of 60 ℃ and the concentration of 98.5 percent3The acid temperature rises to 150 +/-15 ℃, a gas-liquid separation section is arranged at the lower part of the low-temperature absorption section, the separation section separates the process gas at the outlet of the high-temperature absorption section from the lower tower acid of the low-temperature absorption section, and the separated lower tower acid of the low-temperature absorption section is sent to a drying or secondary absorption system through a pipeline.
The utility model has the advantages that:
the low-temperature absorption section of the existing heat recovery tower adopts sulfuric acid with the temperature of about 60 ℃ and the concentration of about 98.5 percent for absorption, and the aim is to ensure a heat absorption system S03The absorption rate of the lower tower acid is increased to 150 ℃ after the lower tower acid is absorbed by the low temperature section, the lower tower acid at the low temperature section in the heat recovery tower directly enters the high temperature absorption section, and the sulfuric acid after the two-stage absorption is mixed is sent into the high temperature absorption section by the high temperature circulating pumpThe temperature of the lower tower acid of the low-temperature absorption section is lower than the temperature of the outlet acid of the evaporator (190 +/-15 ℃) and lower than the temperature of the outlet acid of a feed water heater of the evaporator (170 +/-15 ℃) and does not contribute to steam production, but the lower tower acid of the low-temperature absorption section needs to be heated by the absorption reaction heat of the high-temperature absorption section, namely the lower tower acid of the low-temperature absorption section is heated to the outlet temperature of the feed water heater of the evaporator (170 +/-15 ℃) from 150 +/-15 ℃ and then is sent to a drying or secondary absorption system, so that the steam production rate of a heat recovery system is reduced. The invention reduces the heat brought out by the sulfuric acid sent from the heat recovery system to the drying or secondary absorption system through independently sending the lower tower acid of the low-temperature absorption section of the heat recovery tower or the lower acid of the low-temperature absorption tower to the acid serial pipeline of the drying or secondary absorption system or the outlet of the evaporator, thereby improving the steam production rate of the heat recovery system at the dry absorption section by about 10 to 25 percent.
Drawings
FIG. 1 is a schematic view of a first apparatus of the present invention.
Wherein: 1 is a heat recovery tower, 2 is a high-temperature circulating tank, 3 is a mixer, 4 is an evaporator feed water heater, 5 is a high-temperature circulating pump, 6 is an evaporator, 7 is a drying tower or a secondary absorption tower, 8 is an acid circulating tank, 9 is an acid circulating pump, and 10 is an acid cooler.
Detailed Description
The present invention will be further explained with reference to the following embodiments, but the scope of the present invention is not limited thereto:
referring to fig. 1, a system for increasing the heat recovery steam production rate of a dry absorption section in sulfuric acid production comprises a heat recovery tower 1, wherein the heat recovery tower 1 comprises a high-temperature absorption section, a gas-liquid separation section and a low-temperature absorption section, and the high-temperature absorption section is connected with the upper part of the high-temperature absorption section sequentially through a high-temperature circulation tank 2, a high-temperature circulation pump 5, an evaporator 6 and a mixer 3;
and a branch is further arranged on an acid pipeline connected with the evaporator 6 and the mixer 3, the branch is sequentially connected with the drying or secondary absorption system through at least one heat exchange device, and the liquid output end of the gas-liquid separation section is also connected with the drying or secondary absorption system. The heat exchange equipment at least comprises an evaporator feed water heater 4. The branch is connected with the upper parts of an acid circulating tank 8, an acid circulating pump 9, an acid cooler 10 and a drying tower or a secondary absorption tower 7 in sequence through an evaporator feed water heater 4. And the liquid output end of the gas-liquid separation section is connected with an acid circulation tank 8. The acid side of the acid cooler 10 also has an output connected to the upper portion of the low temperature absorption section. The output end of the evaporator feed water heater 4 is connected with the evaporator 6.
A method for increasing steam production using the system of figure 1, the method comprising:
containing SO3The process gas enters a high-temperature absorption section of a heat recovery tower 1, and SO in the process gas3Part of the sulfuric acid is absorbed by high-temperature sulfuric acid with the concentration of 99 percent, the acid temperature of the tower under the high-temperature absorption section is raised to 205 +/-15 ℃, high-temperature concentrated acid is boosted by a high-temperature circulating pump 5 and then sent to an evaporator 6 to be heated by low-pressure water supply to generate low-pressure steam, the acid temperature is reduced to 190 +/-15 ℃ after being discharged from the evaporator 6, part of the sulfuric acid discharged from the evaporator 6 is sent to a mixer 3 to adjust the concentration of the sulfuric acid to 99 percent, and then the sulfuric acid is sent to the high-temperature absorption section3The rest (10-40%) of the sulfuric acid out of the evaporator 6 is preheated by the evaporator feed water heater 4 and enters the feed water of the evaporator, the acid temperature is reduced to 170 +/-15 ℃, and the rest of the sulfuric acid is cooled by equipment and then is sent to a drying or secondary absorption system;
the process gas enters a low-temperature absorption section after being absorbed by a high-temperature absorption section of a heat recovery tower 1, and is used for spraying and absorbing the residual S0 in the process gas from a sulfuric acid spray system with the drying or secondary absorption system temperature of 60 ℃ and the concentration of 98.5 percent3The acid temperature rises to 150 +/-15 ℃, a gas-liquid separation section is arranged at the lower part of the low-temperature absorption section, the separation section separates the process gas at the outlet of the high-temperature absorption section from the lower tower acid of the low-temperature absorption section, and the separated lower tower acid of the low-temperature absorption section is sent to a drying or secondary absorption system through a pipeline.
According to the technical scheme shown in figure 1, the low-temperature heat recovery system for preparing acid by pyrite is characterized in that the flow rate of lower tower acid of a low-temperature absorption section is about 135000kg/h, the temperature of upper tower acid of the low-temperature absorption section is 60 ℃, the temperature of the acid after absorption is increased to 145 ℃, and when the prior art is adopted, the temperature of sulfuric acid from an outlet of an evaporator feed water heater to a drying or secondary absorption system is about 175 ℃, namely the heat recovery system is equivalent to the heat recovery system135000kg/h of sulfuric acid in the lower tower of the low-temperature absorption section is sent out of the system after being heated from 145 ℃ to 175 ℃. By adopting the technology, the lower tower acid (the temperature is 145 ℃) of the low-temperature absorption section is separately sent to the drying or secondary absorption system, so that the temperature of the lower tower acid of the high-temperature absorption section is increased, the heat output from the heat recovery system to the drying or secondary absorption system is reduced, and the output heat is reduced, namely Q & ltcm & gtdelta & t & gt & lt 1.6x135000x (175 & ltaconurus & gt 145 & lt 6.48x10 & gt6kj/h, according to the heat balance, the part of heat can produce 0.6MPa (g) more low-pressure saturated steam about 2785kg/h, so that the steam production rate is improved by 15 percent.

Claims (6)

1. The utility model provides a system for improve sulphuric acid production dry-suction workshop section heat recovery steam yield which characterized in that: the system comprises a heat recovery tower (1), wherein the heat recovery tower (1) comprises a high-temperature absorption section, a gas-liquid separation section and a low-temperature absorption section, and the high-temperature absorption section is connected with the upper part of the high-temperature absorption section sequentially through a high-temperature circulation tank (2), a high-temperature circulation pump (5), an evaporator (6) and a mixer (3);
and a branch is further arranged on an acid pipeline connected with the evaporator (6) and the mixer (3), the branch is sequentially connected with the drying or secondary absorption system through at least one heat exchange device, and the liquid output end of the gas-liquid separation section is also connected with the drying or secondary absorption system.
2. The system of claim 1, wherein: the heat exchange equipment at least comprises an evaporator feed water heater (4).
3. The system of claim 2, wherein: the branch is connected with the upper parts of an acid circulating tank (8), an acid circulating pump (9), an acid cooler (10) and a drying tower or a secondary absorption tower (7) in sequence through an evaporator water supply heater (4).
4. The system of claim 3, wherein: and the liquid output end of the gas-liquid separation section is connected with an acid circulation tank (8).
5. The system of claim 1, wherein: the acid side of the acid cooler (10) is also provided with an output end which is connected with the upper part of the low-temperature absorption section.
6. The system of claim 2, wherein: the output end of the evaporator feed water heater (4) is connected with the evaporator (6).
CN202021225484.7U 2020-06-29 2020-06-29 System for improving heat recovery steam production rate of sulfuric acid production dry-suction workshop section Active CN212832846U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202021225484.7U CN212832846U (en) 2020-06-29 2020-06-29 System for improving heat recovery steam production rate of sulfuric acid production dry-suction workshop section

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202021225484.7U CN212832846U (en) 2020-06-29 2020-06-29 System for improving heat recovery steam production rate of sulfuric acid production dry-suction workshop section

Publications (1)

Publication Number Publication Date
CN212832846U true CN212832846U (en) 2021-03-30

Family

ID=75178038

Family Applications (1)

Application Number Title Priority Date Filing Date
CN202021225484.7U Active CN212832846U (en) 2020-06-29 2020-06-29 System for improving heat recovery steam production rate of sulfuric acid production dry-suction workshop section

Country Status (1)

Country Link
CN (1) CN212832846U (en)

Similar Documents

Publication Publication Date Title
CN103318850A (en) Low-temperature waste heat recovery system for pyrite and metallurgical off-gas acid making device
CN220317417U (en) Heat recovery device for sulfuric acid system dry suction section and sulfuric acid production line
CN103896219B (en) A kind of device and method improving ore deposit or smelt gas acid preparing heat organic efficiency
CN212832846U (en) System for improving heat recovery steam production rate of sulfuric acid production dry-suction workshop section
CN212843102U (en) System for improving heat recovery steam production rate of sulfuric acid production dry-suction workshop section
CN212832847U (en) System for improving heat recovery steam production rate of sulfuric acid production dry-suction workshop section
CN111704114A (en) Method for improving steam production rate of heat recovery system in dry absorption section of sulfuric acid production
WO2019192173A1 (en) Acid generation energy recovery device and method for so3-containing gas
CN212843103U (en) System for improving heat recovery steam production rate of sulfuric acid production dry-suction workshop section
CN105111042B (en) The steam expansion method of system for methanol synthesis and the system for methanol synthesis
CN213865376U (en) Waste heat recovery system of series flash evaporator on delivery high-temperature sulfuric acid pipeline
CN104058368A (en) Process and system for producing hydrogen by converting hydrocarbon-containing tail gas
CN213865377U (en) Waste heat recovery system of parallelly connected flash vessel on delivery high temperature sulphuric acid pipeline
CN110721554B (en) Comprehensive utilization method for pentaerythritol production wastewater and formaldehyde acetaldehyde
CN214536091U (en) Waste heat recovery system with flash evaporator
CN203625040U (en) Device for improving steam yield of low-temperature residual-heat recycling system for sulfuric acid
CN203612956U (en) Low-temperature waste heat recovery system used in pyrite and smelting exhaust gas acid preparing device
CN203602362U (en) Device for using heat energy of diammonium phosphate neutralizing tail gas
CN217921493U (en) System for improving gypsum or smelting flue gas acid-making low-temperature heat recovery steam yield
CN112723319A (en) High concentration of SO2Method for preparing sulfuric acid by flue gas separation pre-conversion
CN203754422U (en) Device for increasing heat recovery efficiency in process for preparing acid from mine or smelting gas
CN210710749U (en) S03Device for recovering waste heat of absorbing sulfuric acid
CN112539405A (en) Method for improving recovery steam yield of acid making dry absorption waste heat of ore or smelting flue gas
CN218210930U (en) Acid-absorbing waste heat recovery device of acid making system
CN210710751U (en) S03Device for recovering waste heat of absorbing sulfuric acid

Legal Events

Date Code Title Description
GR01 Patent grant
GR01 Patent grant