RU1774005C - Compound for well acid treatment and method of making it - Google Patents

Abstract

The inventive for acid treatment of wells using a composition containing, wt.%: Corrosion inhibitor

Description

with C

The invention relates to the field of exploitation of oil producing wells, and in particular, to methods for restoring and increasing well productivity. Its most effective application is in the removal of organic (asphaltene-tar-paraffin deposits) and inorganic (carbonate) deposits, impacts on rocks containing carbonates, and reduction of water inflows due to hydrophobization of source reservoirs.

A composition for acid treatment of wells is known, consisting of hydrochloric acid, surfactant and benzene. The disadvantage of the composition is the strong corrosiveness with respect to metal and cement stone, leading to the rapid destruction of the filter zone of the well support.

A known method of preparing compositions for acid treatment of wells by mixing hydrochloric acid with a surfactant (OP-U) and

benzene. The composition obtained by this method exhibits strong corrosion activity with respect to metal and cement stone. A known composition consisting of hydrochloric acid, corrosion inhibitor B-2 and surfactant OP-10. However, it also has strong corrosion activity, which leads to the destruction of the filter zone of the well support.

A known method of preparing a composition of hydrochloric acid, X-corrosion inhibitor B-2 and surfactant OP-10, which consists in mixing the components. However, it also has strong corrosion activity, which leads to the destruction of the filter zone of the wells. The aim of the invention is to increase the anticorrosive properties of the composition with respect to cement stone and metal.

The goal is achieved by the fact that in the composition, including hydrochloric acid,

VI VJ

J

ABOUT

about

ate

corrosion inhibitor and surfactant, as a surfactant use nonionic surfactant-hydroxyethylated alkyl phenol (neonol) or a mixture of neonol with alkylaryl sulfonate (sulfonol) in the ratio (1-5} :( 1-2) in the following ratio of components, wt.% :

corrosion inhibitor 10-30

neonol or mixture

neonol 4-7

with sulfonol in the ratio (1-5) :( 1-2)

hydrochloric acid

(5-15% on) the rest

Reagents SNPCH-6002, SNPCH-6013 or SMAD-1 are used as a corrosion inhibitor, the corrosion inhibitor being mixed with neonol or a mixture of neonol and sulfonol and the resulting mixture is introduced into hydrochloric acid.

The reagent SNPCH-6002 (TU 6-12-10-114-82) is a compositional composition, it is an odorless dark brown liquid. It is intended for the treatment of oxygen-containing mineralized water.

Reagent SNPCH-6013- (Catalog of physicochemical and toxicological properties of chemical products used in technological processes of oil production and enhanced oil recovery. M., 1988. p. 142). Composition containing fatty acids, amines, dark brown liquid. Designed to protect against corrosion in mineralized hydrogen sulfide-containing waters.

Reagent SMAD-1 (TU 38-101.614-76) - is a solution of oxidized petrolatum in diesel fuel, is used as a lubricating additive to drilling fluids.

Neonol AFE-Yu, AFd-12 (monoalkylphenols based on propylene trimers, ethoxylated according to TU 38.103625-87) is a non-ionic surfactant.

The compositions are prepared as follows.

The prototype composition (No. 1) is prepared by mixing hydrochloric acid, a corrosion inhibitor B-2, and a surfactant OP-10.

Formulations 2-6 are prepared by mixing hydrochloric acid and the corresponding reagent. The compositions, in addition to Examples 7-10, are prepared by mixing a corrosion inhibitor with neonol or a mixture of neonol and sulfonol and introducing the resulting mixture into hydrochloric acid.

In Examples 7-10, the order of input of the components is changed. To identify the anti-corrosion effect from the use of the composition, samples of cement stone obtained from Portland cement PTSH (GOST 1581-85) and steel samples St-4sp are used, which after initial weighing

they are placed in the test composition at 60 ° C and after 3 hours (cement) or 3 days (steel) they are weighed again and the degree of destruction of the samples is calculated by the difference. A limiting concentration of hydrochloric acid of 15% is used in the studies.

Examples of specific performance. PRI me R 1 (prototype). 97.4 g of 15% hydrochloric acid, 2.5 g of corrosion inhibitor B-2 and 0.1 g of OP-10 are mixed. b the resulting mixture is placed a cement stone sample weighing 10.0 g and a steel sample weighing 5.4 g. After 3 hours, the cement stone sample is dried and weighed. The weight was 6.62 g, i.e. sample failure is

0 33.8%. After 3 days, the steel sample is dried and weighed. The weight was 5.07 g, i.e. sample failure is 6.1%.

Example 2. 80.0 g of 15% hydrochloric acid and 20.0 g of an SNPX5 6002 inhibitor are mixed. Cement stone samples weighing 10.0 g and steel weighing 6.2 g are mixed into the mixture. After 3 hours, the cement stone sample is dried and weighed. The weight was 6.27 g, i.e. sample failure

0 is 37.3%. After 3 days, the steel sample is dried and weighed. The weight was 5.81 g, i.e. sample failure is 6.3%.

Examples 3-6 were carried out similarly.

5 example 2.

Example 7. 80.0 g of 15% acid and 5 g of neonol are mixed, and 15.0 g of the SNPCH-6002 inhibitor are added to the resulting mixture. Cement stone samples weighing 10.0 g and steel weighing 5.8 g were placed in the resulting mixture. After 3 hours, the cement stone sample was dried and weighed. The weight was 6.58 g, i.e., the destruction of the sample was 34.2%. After 3 days, the sample was dried and weighed. The weight was 5.44 g, i.e. sample failure is 6.2%.

Example 80.0 g of 15% acid and 15.0 g of the SNPCH-6002 inhibitor are mixed, and 5.0 g of neonol are added to the resulting mixture.

0 Samples of cement stone weighing 10.0 g and steel weighing 6.3 g are placed in the resulting mixture. After 3 hours, the sample of cement stone is dried and weighed. The weight was 6.45 gh i.e. sample failure is

5 35.5%, after 3 days, the steel sample is dried and weighed. The weight was 5.91 g, i.e. sample failure is 6.2%.

Example 9. The components are mixed in the sequence as in Example 7.

Example 10. The components were mixed in the sequence as in Example 6.

Example 11. 5.0 gneonol was mixed with 10.0 g SNPCH-6002 and the resulting mixture was added to 85.0 g 15% hydrochloric acid. Samples of cement stone weighing 10.0 g and steel weighing 5.1 g were placed in the resulting mixture. After 3 hours, the sample of cement stone was dried and weighed. Weight was 10.0 g, i.e. destruction is 0%. After 3 days, the steel sample is dried and weighed. The weight was 5.04 g, i.e. sample failure is 1.2%.

Examples 12-32 were carried out analogously to example 11.

As can be seen from the table, individually, each of the corrosion inhibitors (approx. 2-4) acts similarly to the B-2 inhibitor (protopi) and has the same anti-corrosion effect.

Also, individually surfactants (approx. 5,6) do not have a noticeable anti-corrosion effect.

The best anticorrosive effect (the absence of destruction of cement stone, the destruction of steel within 0.3-1.2%) while maintaining 100% destruction of salt deposits, have compositions prepared with the contents of the components and the method specified in the formula (examples 11-22 )

Changing the order of introduction of the components (Examples 7-10) or decreasing their content in the mixture less than specified in the formula (Examples 23, 24, 27, 28, 30, 31) leads to a decrease in the anticorrosion properties.

An increase in the content of components more than indicated in the formula (Examples 25.26, 29, 32) leads only to an increased consumption of reagents.

A change in the ratio of neonol-sulfonol with an increase in the content of neonol (examples 26, 29) leads to an increased consumption of the reagent, and with an increase in the content of sulfonol (approx. 30, 31), a decrease in the anticorrosive effect.

When using formulations prepared with the contents of the components and the method indicated in the formula, a synergistic effect takes place.

Claims (3)

1. The composition for the acid treatment of wells, including hydrochloric acid, a corrosion inhibitor and a surfactant, characterized in that, with In order to increase the anticorrosion properties of the composition with respect to cement stone and metal while maintaining the salt-solvent activity and reducing labor costs for the repair of well supports, non-ionic surfactant, ethoxylated alkylphenol (neonol) or a mixture is used as a surfactant neonol with alkylarylsulfonate (sulfonol) in a ratio of 1: 1-5: 2 in the following ratio of components, wt.%: Corrosion Inhibitor 10-30 Neonol or a mixture of neonol with sulfonol in the ratio 1: 1-5: 24-7 5-15% hydrochloric acid 2. The composition according to p. 1, characterized in that, as a corrosion inhibitor corrosion inhibitors SNPCH-6002 or SNPCH-6013 or lubricant additive CM AD-1 are used. 3. A method of preparing a composition for acid treatment of wells by mixing its components, characterized in that the corrosion inhibitor is mixed with neonol or a mixture of neonol and sulfonol, then the resulting mixture is introduced into hydrochloric acid. Por doc gadfly reagents  - hydrochloric acid corrosion inhibitor + PA8 f - hydrochloric acid pouch + surfactant corrosion inhibitor