CS201806B1 - Mixed inhibitor - Google Patents

Description

The invention relates to mixed inhibitors which reduce chemical and / or electrochemical corrosion and also the formation of deposits of organic or inorganic origin.

It is known that various corrosion phenomena arise in the extraction, transport, storage, processing, refining and use of natural gas and oil, since natural gas and oil contain water, organic sulfur compounds, inorganic salts and other corrosive substances. Auxiliaries used in oil refining (for example phenol, ammonia, etc.) increase the extent of corrosion, change its character, further support and influence its type by the formation of deposits.

Therefore, every effort is made to increase the service life and operational safety of operating equipment by minimizing corrosion and deposits. One possibility is the use of corrosion retardants, ie corrosion inhibitors.

The most commonly used corrosion inhibitors are high molecular weight organic compounds containing nitrogen and sulfur.

Compounds are described in the following monographs: J. I. Bregmann: Annali de 'University of Ferrara Nuova Serie Sezione v. Chimica Pura ed Applicata 340-382 (1971) and Μ. H. Akstinat: Werkstoffe und Korrosion 21: 4, 273-281 (1970).

Corrosion-inhibiting substances are generally amines (e.g., aniline, cyclohexamine are components of inhibitors) or long-chain amides, as well as derivatives of these compounds, imidazoline derivatives and their salts, quaternary ammonium compounds, thiocarbamide derivatives and others. The use of these compounds is described, inter alia, in the following literature: Korrosia v. Neftegazová Thought 2, 7-9 (1971); Corrosion 7, 6, 189-195 (1951); Corrosion 9, 25 (1953); Zascite Metallov 6, 491 (1970); Material Protection and Performance 7, 29 (1968); British Patent No. 1,031,503; and U.S. Patent Nos. 3,242,094, 2,437,750, 2,925,781, 2,799,658, and 3,437,583. Metal Corrosion Inhibitors, SNTL 1964, 150.

Based on the experience gathered in gas chemistry and petrochemistry, corrosion inhibitors are subject to the following basic requirements: the inhibitor must not cause malfunctions in the process, must not promote water emulsification, must not contain sedimentation or build-up agents, must not contain catalyst poisons (eg heavy metals) , must not have a detrimental effect on the physical, chemical and other properties of the product, it must be compatible with other inhibitors or preparatives, it must maintain its effectiveness even under changed conditions of use, it must always be resistant to oxidation and reduction, it must always be at temperature and pressure conditions use, must have an effect shortly after the addition, it must allow a high degree of inhibition even at low concentrations of inhibitors, local corrosion (eg deep local corrosion) or brittleness, It is intended to prevent the formation of pyrophoric iron sulfide hazardous to fire, or to wash the resulting iron sulfide from the metal surface.

Naturally, economic and labor protection considerations must also be taken into account in addition to the conditions outlined here.

When using an inhibitor, the main factors influencing corrosion must be taken into account, such as: type of metal (construction material), nature and concentration of salts (eg chloride), acids (eg hydrochloric acid, organic acids); excipients (e.g. phenols) and others that are dissolved in the aqueous phase present alongside the hydrocarbon phase, type and amount of dissolved gases (e.g. hydrogen sulfide, carbon dioxide, oxygen), oil: water ratio, aqueous phase pH, temperature, liquid flow rate etc.

The emerging and pending problems are largely dependent on the corrosive effect of the water present and the substances dissolved therein. Therefore, electrochemical corrosion must first of all be taken into account in the temperature and pressure range in which the water is a liquid.

Another condition for the applicability of corrosion inhibitors is the knowledge of both the corrosion mechanism and the mechanism of action of the inhibitor.

Despite the amount of experimental data already available, these questions are still only partially explained. Theories in relation to the mechanism of action of amine-type inhibitors are explained, inter alia, in the following publications: J.I. Bregmann: Corrosion Inhibitor (The MacMillan Co., New York, 1963), page 198; Corrosion 19, 12 (1963); Werkstoffe Korrosion 21: 273 (1970); J. Elekttochem. Soc. 143, 677 (1966); Werkstoffe und Korrosion 9, 765 (1958); European Symposium on Corrosion Inhibitors, Annali Univ. Ferrara 1-71 (1961); 3rd European Symposium on Corrosion Inhibitors, Annali Univ. Ferrara N.

S. Sec. V. 851-874 (1971).

In the case of organic inhibitors, in particular amine inhibitors, their function is primarily understood as the result of adsorption of these compounds on the metal surface. Without wishing to be construed as being dependent on the mechanism of action of the inhibitors, it is nevertheless pointed out that the relationship is closely related to the effect of the inhibitors due to adsorption, namely: the composition of the metal, its surface state (physical, chemical, electrochemical), size and precursor of metal surface charge, chemical composition of inhibitor molecule (aliphatic, aromatic, closed or open chain), chain length, charge of functional groups (eg amine basicity), geometry of inhibitor molecule, its orientation in relation to metal surface in adsorption, solubility of inhibitor, simultaneous adsorption of inorganic ions, especially cations (synergistic effect), inhibitor tendency to form complexes.

The inventive compound inhibitor consists of 30 to 60% by weight of aniline substituted on the nitrogen by a C1-C6 alkyl, a C1-C6 cycloalkyl, a phenyl or a C1-C6 alkylphenyl in the alkyl moiety , together with 70 to 40% by weight of the cyclohexamine substituted on the nitrogen with a C 1 -C 6 alkyl, C 5 -C 7 cycloalkyl, phenyl or C 1 -C 6 alkylphenyl moiety.

Preferably, the inhibitor, such as an aniline or cyclohexylamine compound substituted on the nitrogen, contains C 1 -C 6 alkyl corresponding to isopropyl derivatives. Preferably, the inhibitor also comprises dicyclohexylamine as the N-substituted cyclohexylamine compound, and the N-substituted aniline compound comprises an aniline derivative substituted on nitrogen by a C 1 -C 6 alkyl, preferably N-isopropylaniline. Mixtures containing 30 to 60% by weight of N-isopropylaniline and 70 to 40% by weight of dicyclohexylamine have a particularly good anticorrosive effect.

The mixed inhibitors of the invention may optionally also contain an organic solvent such as low alcohols or ketones. They may also contain emulsifying agents. The amount and the ratio of these components depend primarily on the field of use. In many cases, it is expedient to use the inhibitors in the form of a mixture of pure active ingredients, while in other cases it is preferable to use a mixture of active ingredients diluted with auxiliary substances, for example organic solvents.

The N-substituted aniline derivatives present and the N-substituted cyclohexylamine derivatives present in the mixture increase their effect in a synergistic manner. The effect of the mixture is considerably higher than that expected from the activity of the individual components. A synergistic enhancement of the effect occurs even when an amino compound of another species (e.g. a cyclohexylamine compound) is added in relatively small amounts to one species of the compound (e.g. aniline compound).

The mixed inhibitor according to the invention generally reduces the corrosion rate and, moreover, the risk of local corrosion. Due to its surface-active effect, the inhibitor further has cleaning properties. An important condition for the use of the inhibitors of the invention is that they must always be in excess on the protected metal when dosing.

In the field tests, the inhibitor of the present invention has good anticorrosive properties and technological processes under the conditions of gas chemistry, petroleum chemistry and petrochemistry, as well as where the products of these industries are processed, due to its chemisorption and synergistic action of the amine. it does not cause any disturbances (it does not polymerise, does not contain catalyst poisons, etc.).

In individual cases, it is preferable to admix a fat-in-water emulsifier to the inhibitor mixture. This is particularly useful when the inhibitor would otherwise not dissolve or be emulsifiable in the present environment.

The invention is illustrated by the following examples, but is not limited thereto.

Example 1

An autoclave equipped with a stirrer of 2.5 m ³ is charged with 1000 kg of naphthenic oil produced from spindle oil (viscosity 5.5.10 ^_5 m ² s ^_1 / 20 ° C), 182 kg (1 kM) dicyclohexylamine, 182 kg (1 , 4 kM) N-isopropylaniline, 30 kg (0.1 kM) morpholine and 0.5 kg emulsifier. After stirring the stirrer, the mixture was heated to 75 ° C and stirred at this temperature for 160 minutes. 1395 kg of inhibitor composition are obtained. The composition is primarily suitable for protection against corrosion in urban gas lines and in long-distance gas lines.

For example, the inhibitor composition may be introduced into the gas distribution network as follows:

a) The inhibitor is mixed with propane (mixing ratio: 1 part by weight of inhibitor to 6 parts by weight of liquefied gas) in metal cylinders, and the resulting mixture is sprayed through a spray nozzle into a pipeline.

b) The inhibitor is introduced into the pipeline by means of a pneumatic high pressure pump. The auxiliary energy required to drive the pump can be drawn from the gas line or from a special network, for example from the compressed air distribution.

Laboratory measurements have shown that using the inhibitor of Example 1, the following protective effect can be achieved:

Inhibitor Speed corrosion (mm / year) Protective effect% No inhibitor 5.25 - Inhibitor according to of Example 1 0.47 91.0

Example 2

The apparatus described in Example 1 is charged with 543 kg (3 kM) of dicyclohexylamine, 405 kg (3 kM) of N-isopropylaniline and 95 kg of spindle oil (viscosity about 5.5, 10 ^-5 m ² s ^-1 / 20 ° C). After stirring the stirrer, the mixture was heated to 75 ° C and stirred at this temperature for 160 minutes. 1043 kg of inhibitor are obtained which can be used in environments with a pH of 4-6 saturated with hydrogen sulfide and / or carbon dioxide containing up to 1 g / l of chloride ions.

By using the inhibitor of Example 2, the following protective effect can be achieved, as evidenced by laboratory experiments:

| Inhibitor Speed corrosion (mm / year) Protective effect % Note No inhibitor 1.3 —7 local corrosion Inhibitor according to of Example 2 0.35 73 steflinoměir- corrosion

Example 3

The autoclave described in Example 1 is charged with 543 kg (3 kM) of dicyclohexylamine, 675 kg (5 kM) of N-isopropylaniline, 30 kg (0.1 kM) of morpholine and 95 kg of spindle oil (viscosity about 5.5.10 * ⁵ m ^2). s ( ^1/20 ° C). After stirring the stirrer, the autoclave was heated to 75 ° C and stirred for 160 minutes. 1343 kg of inhibitor are obtained. This can be used in corrosive solutions of pH 4 to 7, saturated with hydrogen sulfide and / or carbon dioxide, containing up to 3 g / l of chloride ions produced by the extraction and processing of petroleum and natural gas.

According to the results of laboratory measurements, the following protective effect can be achieved with the inhibitor of Example 3:

Inhibitor Speed corrosion (mm / year) Protective effect %> Note No inhibitor 1.4 - local corrosion Inhibitor according to of Example 3 0.56 60.0 uniform corrosion

Example 4

The autoclave described in Example 1 is charged with 182 kg (1 kM) dicyclohexylamine, 18 kg (0.1 kM) dodecylamine, 103 kg (1 kM) diethylenetriamine, 675 kg (5 kM) N-isopropylaniline, 30 kg (0.1 kM) ) of morpholine, 95 kg of spindle oil (viscosity about 5.5.10 ^-5 m ² s ^-1 / 20 ° C), 50 kg of kerosene and 1 kg of emulsifier. After stirring the stirrer, the autoclave was heated to 75 ° C and stirred for 160 minutes. 1154 kg of inhibitor are obtained, which can be used in corrosive solutions of pH 4-8 saturated with hydrogen sulfide and / or carbon dioxide containing up to 5 g / l of chloride ions, which are produced in the petrochemical industry.

As shown in the laboratory measurements, the following protective agent can be obtained with the inhibitor of Example 4:

Inhibitor Speed corrosion (mm / year) Protective effect % Note No inhibitor 1.65 - local corrosion Inhibitor according to of Example 4 0.56 64 uniform corrosion

Example 5

The autoclave described in Example 1 is charged with 175 kg (1 kM) phenylcyclohexylamine, 182 kg (1 kM) dicyclohexylamine, 270 kg (2 kM) N-isopropylaniline, 298 kg (2 kM) N-isobutylaniline, 100 kg kerosene and 2 kg Oxethyl fatty acid emulsifier. After stirring the stirrer, the autoclave was heated to 75 ° C and stirred for 160 minutes. 845 kg of inhibitor are obtained. This can be used alone or in combination with inorganic inhibitors, preferably sodium molybdate, in corrosive solutions with pH values of 4 to 8 saturated with hydrogen sulfide and / or carbon dioxide containing up to 5 g / l of chloride ions produced in the oil or gas industry industry.

Laboratory measurements show that the following protective effect can be achieved when using the inhibitor of Example 5:

Inhibitor Corrosion rate (mm / year) Protective effect % Note No inhibitor 1.65 - local corrosion the inhibitor of Example 5 0.60 60 uniform corrosion inhibitor according to Example 5 + 10 wt. % Na ₂ Mo0 ₄ . H ₂ O 0.45 75 uniform

Example 6

The autoclave described in Example 1 is charged with 543 kg (3 kM) of dicyclohexylamine and 450 kg of a 60% solution of N-isopropylaniline in acetone (2 kM). After the stirrer was connected, the autoclave was heated to 45 ° C. The mixture was stirred for 60 minutes. 993 kg of homogeneous inhibitor solution are obtained.

This inhibitor can be used in corrosion solutions saturated with hydrogen sulphide and carbon dioxide and containing up to 5 g / l of chloride ions, pH values of 4 to 6, which are produced in the oil industry. As laboratory experiments have shown, the following average protective effect can be achieved:

Inhibitor Speed corrosion (mm / year) Protective effect % Note No inhibitor 1.65 - local corrosion Inhibitor of Example 6 (10 ppm) 0.55 67 uniform corrosion

Example 7

The following comparative measurements were made in a solution saturated with hydrogen sulphide and containing 0.8 mg / l chloride ions, pH 4-6:

Inhibitor Speed corrosion (mm / year) Protective effect % Note No inhibitor 1.3 - local corrosion Dicyclohexylamine (10 ppm) 0.87 33 ' uniform corrosion N-isopropylaniline (10 ppm) 0.92 29 local corrosion Inhibitor of Example 2 (10 ppm) 0,35 ' 73

SUBJECT OF THE INVENTION

Claims (7)

SUBJECT OF THE INVENTION Mixed inhibitor, characterized in that it consists of 30 to 60% by weight of aniline substituted on. nitrogen of alkyl of 1 to 6 carbon atoms, cycloalkyl of 5 to 7 carbon atoms, phenyl and / or alkylphenyl of 1 to 6 carbon atoms in the alkyl moiety, together with 70 to 40% by weight of cyclohexylamine substituted on the nitrogen with 1 to 6 carbon atoms , cycloalkyl of 5 to 7 carbon atoms, phenyl and / or alkylphenyl of 1 to 6 carbon atoms in the alkyl moiety. 2. Mixed inhibitor according to claim 1, characterized in that it contains the corresponding isopropyl derivatives as an aniline or cyclohexylamine compound substituted on the nitrogen by a C1-C6 alkyl. 3. Mixed inhibitor according to claim 1, characterized in that it contains 70 to 40% by weight of nitrogen-substituted cyclohexylamine compound and 30 to 60% by weight of nitrogen-substituted aniline compound. 4. The mixed inhibitor of claim 1 wherein the N-substituted cyclohexylamine compound is dicyclohexylamine. 5. Mixed inhibitor according to claim 1, characterized in that the N-substituted aniline compound comprises an aniline derivative substituted on the nitrogen by a C1-C6 alkyl, preferably N-isopropylaniline. 6. Mixed inhibitor according to claim 4 or 5, characterized in that it contains 30 to 60% by weight of N-isopropylaniline and 70 to 40% by weight of dicyclohexylamine. 7. Mixed inhibitor according to claim 1, characterized in that it contains low alcohols or ketones as organic solvent.