CC BY
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№ 11 (89)
ноябрь, 2021 г.
PETROCHEMISTRY
DOI - 10.32743/UniChem.2021.89.11.12473
PRODUCTION AND USE OF CORROSION INHIBITORS ON THE BASIS OF TWO-ATOMIC PHENOLS AND LOCAL RAW MATERIALS
Bobir Olimov
assistant of the Department of Chemistry of the Bukhara Institute of Engineering-Technology,
Uzbekistan, Bukhara E-mail: chemistry292 7@mail.ru
Vokhid Akhmedov
associate Professor of the Department of Chemistry of the Bukhara Institute of Engineering-Technology,
Uzbekistan, Bukhara E-mail: vohid7@mail.ru
Gulnoz Gafurova
Assistant of the Department of Chemistry of the Bukhara Institute of Engineering-Technology,
Uzbekistan, Bukhara
ПРОИЗВОДСТВО И ПРИМЕНЕНИЕ ИНГИБИТОРОВ КОРРОЗИИ НА ОСНОВЕ ДВУХАТОМНЫХ ФЕНОЛОВ И МЕСТНОГО СЫРЬЯ
Олимов Бобир Баходирович
ассистент кафедры химии Бухарского инженерно-технологического института, Республика Узбекистан, Бухара E-mail: chemistry292 7@mail.ru
Ахмедов Вохид Низомович
доц. кафедры химии Бухарского инженерно-технологического института, Республика Узбекистан, Бухара E-mail: vohid7@mail.ru
Гафурова Гулноз Алихоновна
ассистент кафедры химии Бухарского инженерно-технологического института, Республика Узбекистан, Бухара
ABSTRACT
The main part of corrosion inhibitors used in the oil and oil refining industry are complex organic compounds belonging to different classes. Soluble corrosion inhibitors in hydrocarbons are most effective for use in the oil and gas industry because they have a high protective effect and easy interaction with construction materials.
АННОТАЦИЯ
Основную часть ингибиторов коррозии, применяемых в нефтяной и нефтеперерабатывающей промышленности, составляют сложные органические соединения, относящиеся к разным классам. Растворимые ингибиторы коррозии в углеводородах наиболее эффективны для использования в нефтегазовой промышленности, поскольку они обладают высоким защитным действием и легко взаимодействуют со конструкционно материалами.
Keywords: inhibitor, diatomic phenols, monoethanolamine, corrosion rate, corrosion inhibitor effectiveness
Ключевые слова: ингибитор, двухатомные фенолы, моноэтаноламин, скорость коррозии, эффективность ингибитора коррозии.
Библиографическое описание: Olimov B., Akhmedov V., Gafurova G. PRODUCTION AND USE OF CORROSION INHIBITORS ON THE BASIS OF TWO-ATOMIC PHENOLS AND LOCAL RAW MATERIALS // Universum: химия и биология : электрон. научн. журн. 2021. 11(89). URL: https://7universum. com/ru/nature/archive/item/124 73
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Corrosion of metals is a complex process that leads to the absorption of metals as a result of their transition to an oxidized state with the disappearance of their specific properties. Due to mechanism of corrosion processes, there are the following types of corrosion of metals [1-6]:
• chemical corrosion is the result of the interaction of the metal surface with the environment;
• contact (electrochemical) corrosion occurs as a result of interaction of these - metals with galvanic elements and electrolytes;
And also microbiological corrosion, which is carried out as a result of the action of microorganisms.
The generally accepted laws of corrosion mechanism are all related to aqueous solutions. In this case, corrosion is considered an electrochemical process that occurs in the anode areas of the metal surface, where it occurs when iron ions pass into the solution:
Fe0 - 2e- = Fe2+
In order for electrochemical corrosion to occur, the system must contain an oxidizer that pulls excess electrons from the metal surface. Basically, the role of oxidizer is performed by water-soluble oxygen or H+ cations. When the concentration of hydrogen cations sharply decreases, the cathodic return of oxygen becomes the main reaction:
2H+ + 2e- = H2
У2 O2 +H2O +2e" = 2OH-
Corrosion inhibitors are chemical compounds or their compositions, and a small amount in an aggressive environment also slows the corrosion rate of metals. The advantage of corrosion inhibitors over other
methods of protection is its relative simplicity, low material consumption and low labor costs, the ability to simultaneously protect underground and surface metal structures, as well as access to any part of the corrosion environment [7-11].
The protective properties of organic compounds are significantly improved if they contain two pairs of undistributed electrons, and with the inclusion in the molecule of different functional groups containing heteroatoms, which can be electrodonated. At the junction of the protective property, the heteroatom is placed in the following sequence: O, N, S. Alternatively, in different functional groups, the electrodonuclear function of heteroatom changes [12-13].
The reaction is carried out in a three-stringed tube equipped with a thermometer and a mixer, monoethanolamine and formalin are placed in the tube in a ratio of 1:1,5 molars. The reaction mixture is mixed without heating for 30 minutes, after which the tube is connected to the refrigerator and the water is drained by means of a vacuum pump. Then add 1 mole vinyl ether of diatomic phenol from 95-98°C and mix for 14 hours. Control of the process flour is carried out depending on the solubility of the reaction product in an 8% aqueous solution of hydrochloric acid. The resulting reaction mass is dissolved in benzene and separated, after which the resulting benzene solution is washed 3-4 times with water. The reaction yield is 91%. The brutto formula of the substance is C13H17O3N and molecular mass 235 g/mole. Separated from the reaction mass, water contains 10-20% monoethanolamine and formaldehyde.
The results of the study showed that during the condensation of vinyl ethet of diatomic phenol with formaldehyde and monoethanolamine, only when formaldehyde is used in paraform form, it is formed according to the following scheme:
RO
OH + HCOH +NH2CH2CH2OH
-H2O
RO
\ //
OH
R = H2C=C-C
CH2
CH2NHCH2CH2OH
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The resulting product is a viscous light yellow color in organic solvents and acid solutions. Based on the reresinous substance, insoluble in water, but well soluble sults obtained, the study on the development of corro-
sion inhibitors shows the prospects.
Table 1.
Dependence of AMKI corrosion inhibitor on the concentration of anti-corrosion characteristics
Sample S, 10-4 m2 t, hour Mass, m0, г Mass, m, г Am=m0-m, г Inhibitor concentration, % Corrosion rate, m/S2*c Z, % Y
1 17 72 6,635 6,052 0,583 - 4,763 - -
2 17 72 6,618 6,435 0,183 0,001 1,496 68,6 3,18
3 17 72 6,756 6,611 0,144 0,01 1,181 75,2 4,03
4 17 72 6,698 6,618 0,079 0,05 0,652 86,3 7,3
5 17 72 6,652 6,577 0,074 0,03 0,609 87,2 7,8
6 17 72 6,682 6,637 0,0448 0,1 0,366 92,3 12,98
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Figure 3. Dependence of corrosion inhibitor effectiveness on AMKI concentration
In conclusion, favorable conditions for the synthesis of aminomethylated and sulfomethylated corrosion inhibitors based on vinyl ether of diatomic phenols were identified and experimental data were presented. It was shown that the mechanism of corrosion protection of organic compounds containing sulfo and amino group
fragments is fundamentally different from the mechanism of action of other inhibitors. The use of inhibitors synthesized in water circulation systems of oil drilling and refining enterprises maintains a high level of protection in hydrogen sulfide and emulsified hydrocarbon systems.
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