CC BY
12
№ 10 (103)
UNIVERSUM:
ТЕХНИЧЕСКИЕ НАУКИ
октябрь, 2022 г.
ЯО/ - 10.32743/UniTech.2022.103.10.14330
A METHOD FOR REDUCING CORROSION DURING GAS PURIFICATION
FROM SULFUR COMPONENTS
Erali Panoev
Doctoral student
of the Bukhara Engineering and Technological Institute, Republic of Uzbekistan, Bukhara E-mail: chemistry292 7@mail.ru
Malikjon Murodov
Associate Professor of the Bukhara Engineering Technological Institute, Republic of Uzbekistan, Bukhara
Gayrat Bozorov
Professor
of the Bukhara Engineering Technological Institute, Republic of Uzbekistan, Bukhara
Safar Usmonov
Director
of Vocational College of Oil and Gas Industry, Republic of Uzbekistan, Bukhara
СПОСОБ СНИЖЕНИЯ КОРРОЗИИ ПРИ ОЧИСТКЕ ГАЗА ОТ СЕРНЫХ КОМПОНЕНТОВ
Эрали Панове
докторант
Бухарского инженерно-технологического института, Республика Узбекистан, г. Бухара
Маликжон Муродое
доц. кафедры химии Бухарского инженерно-технологического института, Республика Узбекистан, г. Бухара
Бозорое Гайрат
доц. кафедры химии Бухарского инженерно-технологического института, Республика Узбекистан, г. Бухара
Усмонов Сафар
директор
профессионального колледжа нефтяной и газовой промышленности
Республика Узбекистан, г. Бухара
ABSTRACT
At the Gazli Gas Processing Plant, the process of purification of gases from acidic components with metildietanola-min solution leads to the occurrence of corrosion in technological systems. It was therefore tested by gravimetric methods with an anticorrosion inhibitor at a temperature of 120 °C and several different concentrations, and inhibition technology was proposed.
АННОТАЦИЯ
На Газлинском ГПЗ процесс очистки газов от кислых компонентов раствором метилдиэтаноламина приводит к возникновению коррозии в технологических системах. Поэтому он был испытан гравиметрическим методом с антикоррозионным ингибитором при температуре 120 °С и нескольких различных концентрациях и предложена технология ингибирования.
Библиографическое описание: A METHOD FOR REDUCING CORROSION DURING GAS PURIFICATION FROM SULFUR COMPONENTS // Universum: технические науки : электрон. научн. журн. Panoev E. [и др.]. 2022. 10(103). URL: https://7universum. com/ru/tech/archive/item/14330
A UNÎVERSUM:
№ 10 (1031_ЛД ТЕХНИЧЕСКИЕ НАУКИ_октябрь. 2022 г.
Keywords: hydrogen sulfide, carbon dioxide, corrosion, gas condensate, hydrocarbon, inhibitor, methylethanolamine, gravimetrik, sulfur, desorber, TFO (thiosemicarbaside-based inhibitor) desorber, division.
Ключевые слова: сероводород, диоксид углерода, коррозия, газовый конденсат, углеводород, ингибитор, метилдиэтаноламин, гравиметрик, сера, десорбер, десорбер ТФО (тиосемикарбазный ингибитор), разделение.
Introduction
Corrosion damage to metal products, equipment, structures and devices worldwide account for 25-30 % of annually produced metals[1-3].
Therefore, it is possible to study the causes of corrosion in each production plant and achieve high efficiency in protection with anti-corrosion coatings and effective inhibitors suitable for this environment [4-8].
In particular, the main goal of the study was to reduce the corrosion rate at the Gazli GPP. An aqueous solution of methyldiethanolamine 35-40 % is used to purify natural gases from acidic components at the Gazli GPP [8-13].
When cleaning a solution of saturated methyldiethanolamine, H2S and CO2 included in its composition have an aggressive effect on the metal, leading to chemical corrosion of the metal and forming the following mechanisms of corrosion reactions [14-17].
CÛ2(g) ~ CÛ2(l)
C02(l)+H20(l) ~ H2CO3(l) H2C03(l) ~ HC03-(l)+H+(l) HC03-1(l) ~ C032-(l) + H+(l) 2H+(l) +2e' ^ H2(l) H2S(g) ~ H2S(l) H2S(l) ~ HS-(l) + H+ (l) HS-(l) ^S2-+ H+ (l) 2H+(l)+ 2e" ^ H2(g)
The composition of the methyldiethanolamine solution in the desorber of the Gazli Gas Processing Plant is shown in Table 1 below.
When cleaning gases from acid components, corrosive products in instruments and equipment are exposed to hydrogen sulfide, along with moisture, carbon dioxide, and therefore it is necessary to take measures to protect process equipment from corrosion.
Table 1.
The composition of the methyldiethanolamine solution for gas treatment of the Gazli GPP
Technology department H2S mg/m3 Purified solution (methyldiethanolamine) Saturated solution (methyldiethanolamine)
Concentration С% CO2 Mole/ mole H2S Mole/ mole Concentration С% CO2 Mole/ mole H2S Mole/ mole mg pH
1 4 9.5 0.05 0.02 9.3 0.27 0.03 0.007 8.2
2 5 33.8 0.04 0.06 33.4 0.27 0.12 0.007 8.3
3 4 7.1 0.03 0.02 6.9 0.51 0.02 0.003 7.9
4 7 33.8 0.01 0.06 33.4 0.27 0.12 0.004 8.0
5 7 33.1 0.01 0.05 32.7 0.28 0.09 0.007 8.4
6 10 40.0 0.02 0.01 39.5 0.17 0.11 0.004 7.8
Desorbers at the Gazli GPP are made of steel 09G2S and 12X18H10T, and the corrosion rate is high, mainly due to the absence of alloying elements in steel 09G2S. It is for this reason that the studies considered measures to reduce the corrosion rate of steel grade 09G2S.
It is noteworthy that the corrosion properties of 09G2S steels under the action of C02 and H2S gases were not considered. Alloys containing 09G2S steel in the presence of dissolved hydrogen sulfide and carbon dioxide in various media have a significant effect on the formation kinetics and composition of corrosion products. The question of the joint influence of these two factors on the development of corrosion processes is still open.
Based on this, studies of the corrosion process were carried out in time, temperature, pH and various concentrations of the medium.
Research method
0n the basis of the given data, studies of laboratory work on the gravimetric method of corrosion rate according to SST 9.905-82 were carried out. Then 0.5 l of a saturated solution of methyldiethanolamine (pH of the medium <6.8) is transferred into the flask. After thorough cleaning and drying, a plate made of 09G2S steel with an area of 22 cm2 is weighed on an analytical balance and placed in a solution. At a temperature of 120 °C and 360 h without inhibitors and inhibitor solutions, tests were carried out. A corrosion inhibitor of the TF0 brand (thiosemicarbazidebased inhibitor) was used as an inhibitor (Fig. 2).
№ 10 (103)
UNIVERSUM:
ТЕХНИЧЕСКИЕ НАУКИ
октябрь, 2022 г.
Figure 2. Laboratory instrument for the gravimetric study of corrosion inhibitors
1-heater; 2-flask; 3-metal plate; 4-refrigerator; 5-thermometer; 6-where the product falls
The metal plate is then cleaned with grinding paper and weighed on an analytical balance. The results are recorded and calculated using the following formula.
1).К
_ (Ш1-Ш2),
Lgrav
S^T
2). y =
_Wo_.
Winh;
3). z =
Wo-Wjnh Wo
100%
According to these formulas, the rate of corrosion (Kgrav), the coefficient of braking (y) and the degree of protection from corrosion (Z).
where: mi- is the mass of the metal plate at the beginning of the study, g: mi - is the mass of the metal plate after exposure, g: Wo - is the decrease in the mass
of the metal in an inert solution, Winh- is the decrease in the mass of the metal in the solution under consideration, S - is the surface of the metal plate, cm2: ti-exposure time, hour.
Table 2.
Results obtained by the gravimetric method on plates made of steel 09G2S in solution with and without inhibitors
Inhibitor concentration, mg/l Mass of the metal plate m1, g Mass of metal plate m2, g Am = m1- m2, г Corrosion rate, g/m2^s. (u=Am/S'i) Y Z, %
0 16.0163 15.9283 0.0880 0.1111 - -
25 16.0531 16.0223 0.0308 0.0388 2.85 65.0
50 16.0816 16.0607 0.0209 0.0263 4.21 72.2
75 16.0621 16.0530 0.0091 0.0114 9.67 89.6
100 16.0389 16.0343 0.0046 0.0058 19.13 94.7
As a result of the research, the image of metal plates in inhibitory and non-inhibitory media with an AD106-C microscope approaching 80 times is shown in Figure 3.
№ 10 (103)
UNIVERSUM:
ТЕХНИЧЕСКИЕ НАУКИ
октябрь, 2022 г.
Figure 3. Microscopic view of 09G2S metal samples in a) inhibitor and b) inhibitor solutions
According to the results of gravimetric analysis, it was found that with inhibitor a) there is no corrosion of the inhibitor complex in the steel sheet, and without inhibitor b) the solution has uneven corrosion, wounds and pits on the metal sheet.
Based on the results of the study, a technological scheme was developed for the use of a new type of corrosion inhibitor TFO in technological devices in order to sharply slow down corrosion in gaseous media. (Figure 4).
Figure 4. Technology of application of anticorrosive corrosion inhibitor TFO, which occurs during amine gas purification from acidic components
1-MDEA solution saturated with acidic components; 2-capacity for corrosion inhibitor; 3-diaphragm pump; 4-desorber; 5-reboys; 6-flare gases; 7-purified MDEA; 8-water vapor
In Scheme 4, since desorber 1 is the main corrosion site, corrosion inhibitor TFO 3 with a saturated solution of methyldiethanolamine, which must be regenerated in reboiler 2, is fed into the desorber by diaphragm pump 4.
Results and its discussion
Changing the concentration of the TFO inhibitor had a high impact on the anticorrosion efficiency and corrosion rate, which was reflected in the results obtained. For example, at a temperature of 120 °C, the corrosion rate in a metal plate without inhibitors was 0.1111 g/(cm2-h), and the corrosion rate decreased to 0.0058 mg/(cm2-h) when the inhibitor concentration reached 100 mg/l.
Correspondingly, the anti-corrosion efficiency of the inhibitor was 94.7 %, the braking coefficient was 19.13%.
This is due to the fact that at high temperatures the adsorption capacity of the inhibitor is lower than the
desorption capacity, and an increase in temperature breaks the electrostatic bonds between the inhibitor and iron atoms on the surface of the steel sample. The results of this study showed that the TFO inhibitor is a good effective inhibitor in amine gas cleaning, and the use of 0.1% corrosion inhibitor against corrosion in gas cleaning from sulfur compounds showed high efficiency.
Conclusion
It can be concluded from the article that the concentration of the corrosion inhibitor TFO of 0.1% turned out to be quite effective when cleaning gases with methyldiethanolamine solutions to reduce the corrosion rate in devices and technological systems under the influence of acidic components.
№ 10 (103)
UNIVERSUM:
ТЕХНИЧЕСКИЕ НАУКИ
октябрь, 2022 г.
References:
1. Reglament Gazliyskogo gazopererabativayutshego zavoda. TR 20982991 -07:2020.[in Russian].
2. Panoev E.R., Mirzaev E.E., Xayitova D.F., J.J. Jamolov Vidi korrozionnix prosessov, prichini IX klassifikasii i proisxojdeniya, metodi zatshiti ot nix // France international scientific-online conference: "Scientific approach to the modern education system" colletions of scientific works. Part 3. Paris 2022. -P. 74-78. [in Russian].
3. Panoyev E.R., Do'stov H.B. Gazlarni oltingugurt birikmalaridan tozalashda desorber qurilmalarida yuzaga kelayotgan korroziya jarayonini gravimetrik usulida tadqiq qilish // fan va texnologiyalar taraqqiyoti. Ilmiy-texnikaviy jurnal. -Buxoro: 2021.-№4, -B. 111-119.
4. Panoyev E.R., Do'stov H.B., Axmedov V.N. Problemi korrozii v kislix komponentnix sistemax i sposobi ee umensheniya // Universum: texnicheskie nauki. -Moskva: 2021. - № 12(93). -S. 47-50. [in Russian].
5. Usmonov X.R. U., Tilloev L.I., Ruziev A.T. (2021). Fraktsionniy sostav maslyanoy chasti iz otxodnogo jyoltogo masla. Universum: texnicheskie nauki, (5-5 (86)), 14-16. [in Russian].
6. Panoyev E.R., Temirov A.H., Akhmedov V.N.The corrosion problem in the oil and gas industry// Polish science journal -№ 10(43). 2021.-P. 247- 250.
7. Do'stov H.B., Obidov H.O., Panoev E.R. Uchqir gazni oltingugurtdan tozalash qurilmasida korroziya tezligini pasaytirish tadbiri // fan va texnologiyalar taraqqiyoti. Ilmiy-texnikaviy jurnal.№4 -Buxoro: 2020. -B. 84-89.
8. Dustov X.B. Panoev E.R., Dustov A.X. Vliyanie plastovoy vodi na skorost korrozii // Innovasionnie puti resheniya aktualnix problem razvitiya pitshevoy i neftegazoximiicheskoy promishlennosti materiali mejdunarodnoy nauchno-prakticheskoy konferentsii. 1-tom. Buxoro: 2020. -S. 369-371. [in Russian].
9. B.B. Olimov, V.N. Akhmedov, G.A. Gafurova. Application of derivatives of diatomic phenols as corrosion inhibitors. Euro Asian Conference on Analytical Research (Germany) ISBN: 978-1-913482-99-2. 2021. 15 October. p. 136-138.
10. Olimov B.B., Gafurova G.A., Kudratov O.X. Production and properties of corrosion inhibitors in the oil and gas industry // Universum: ximiya i biologiya: elektron. nauchn. jurn. 2022. 2(92). URL: https://7universum.com/ru/nature/archive/item/13009.[in Russian].
11. Olimov B., Akhmedov V., Gafurova G. Production and use of corrosion inhibitors on the basis of two-atomic phenols and local raw materials // Universum: ximiya i biologiya: elektron. nauchn. jurn. 2021. 11(89). URL: https://7universum.com/ru/nature/archive/item/12473. [in Russian].
12. Olimov B.B. [i dr.]. Synthesis and properties of nitrogen-retaining corrosion inhibitors//Universum: ximiya i biologiya: elektron. nauchn. jurn. 2022. 4(94). URL: https://7universum.com/ru/nature/archive/item/1330. [in Russian].
13. Olimov B.B., Yoldosheva N.J. Gravimetric study of the mechanism of action of corrosion inhibitors used in the oil and gas industry //Mejdunarodniy nauchno-obrazovatelniy elektronniy jurnal "Obrazovanie i Nauka v XXI veke". Vipusk. - №. 19. [in Russian].
