RU72262U1 - PUMP COMPRESSOR PIPE - Google Patents

Abstract

A tubing, on the outer surface of which is coated in the form of a sprayed layer, characterized in that the coating includes C, Mo, Si, Ni, Cu, Cr, B, Mn, AlO, Fe in the following ratio of components, wt.%:

Description

The utility model relates to devices for the extraction of oil, gas and gas condensate, mainly to tubing used in the operation of oil and gas wells for transporting liquids and gases inside the casing, as well as for repair and tripping.

The current state of the oil industry is characterized by a significant deterioration in the operating conditions of downhole equipment.

There are a lot of factors affecting the operation of electric centrifugal pumping installations (UNTsN) and associated tubing: from the well and pump structures to the processes that take place in the formation itself. The combination of all the complications leads to a sharp decrease in the efficiency of the equipment for the extraction and transportation of oil and gas. In this regard, developments aimed at improving the performance indicators of oil and gas production and transportation equipment become relevant.

The main complicating factors leading to a decrease in the efficiency of oil and gas production and transportation equipment include gas, water, the presence of mechanical impurities in the fluid extracted from the reservoir, the presence of aggressive substances in the reservoir fluid, in particular hydrogen sulfide, etc.

Due to the fact that the anhydrous period of operation of wells takes up a small part of the total period, the effect of water on the operation of oil and gas production equipment, including the operation of the tubing string, begins almost from the moment the well begins to operate. The proportion of water in the reservoir fluid is currently in

the vast majority of deposits reaches from 90 to 99%. Such a high water content in the reservoir fluid leads to a number of complications during the operation of the wells.

The high degree of mineralization of the formation fluid, the increased content of hydrogen sulfide in it, as well as the presence of sulfate-reducing and other bacteria leads to intense corrosion of oil and gas production and transportation equipment.

The combination of the high aggressiveness of the formation fluid and electric current during the operation of pumping units leads to the occurrence of electrochemical corrosion of the metal of both the pumping units themselves and the tubing string. Moreover, often the rate of electrochemical corrosion is much higher than the rate of chemical corrosion.

In the process of lowering and lifting the tubing string, its surface is rubbed against the surface of the casing string. Due to the curvature of the wells and the presence of pipe joints, intense local wear of the surface of the tubing occurs. In addition, when the centrifugal pump unit is mounted on the bottom of the tubing string, vibration occurs. This vibration is transmitted to the entire tubing string. As a result of the vibration, the friction of the tubing against the casing pipe occurs. All this leads to abrasive wear on the surface of the tubing. All this enhances the corrosion effect of tubing.

Corrosion protection through the use of metal coatings is the most effective. In this case, metal coatings must have high density, high adhesion, low electrochemical potential with respect to the equipment body, high corrosion resistance, high hardness and

wear resistance, high elasticity. The combination of these properties provides reliable corrosion protection of the coating in the well.

At the same time, the use of metal coatings that do not meet the above requirements do not provide reliable protection against corrosion. For example, the use of thickened and brittle coatings leads to cracking and even peeling. The slightest discontinuities in the coating (microcracks, ulcers, through pores, holes, etc.) are enough to begin intensive corrosion of the entire equipment casing. Moreover, depending on the electrochemical potential, the corrosion process can be even more intense compared to equipment without a metal coating.

Known technical solutions that are aimed at improving corrosion resistance, wear resistance, and as a result, increasing the reliability of oil and gas production and transportation equipment, in particular tubing (see, for example, RU 46031 U1, 10.06.).

In the known technical solution, in particular, it is proposed to apply a coating on the outer surface of the tubing made in the form of a sprayed layer based on alloy steel, including in the first embodiment: Fe, Cr, Ni, Si, Mo, C, in the second embodiment: Cr, Ni, Si, B, C, in the third embodiment, Fe, Cr, Mo, in certain ratios, wt.%, Providing increased corrosion resistance to the surface layers.

However, all these technical solutions do not provide a sufficient degree of increase in corrosion resistance, wear resistance, and tightness of the surface layer of tubing.

The technical problem, the solution of which the claimed utility model is aimed at, is:

1. Improving the corrosion resistance of tubing;

2. Protection against electrochemical corrosion of tubing;

3. Improving the wear resistance of tubing;

4. Improving erosion resistance of tubing;

5. Improving the efficiency of equipment for oil production and transportation.

The problem is solved as follows.

On the outer surface of the tubing, a coating is applied in the form of a sprayed layer, the coating includes: carbon (C), molybdenum (Mo), silicon (Si), nickel (Ni), copper (Cu), chromium ( Cr), boron (B), manganese (Mn), aluminum oxide (Al ₂ O ₃ ), iron (Fe), in the following ratio of components, wt.%:

C - 1.3 ÷ 2.0

Mo - 4.0 ÷ 5.0

Si - 0.5 ÷ 1.5

Ni - 11 ÷ 20

Cu - 0.01 ÷ 0.50

Cr - 23 ÷ 32

B - 0.001 ÷ 0.1

Mn - 0.4 ÷ 1.2

Al ₂ O ₃ - 0.1 ÷ 5

Fe - the rest

The utility model is illustrated by graphic material, where Fig. 1 shows a fragment of a tubing.

The following positions are indicated on the indicated figure:

1. Tubing;

2. The surface of the tubing to be coated;

3. Tubing coating.

The coating with these ingredients, due to its ultra-high density and exceptional corrosion resistance, reliably protects the flow path of the tubing from corrosion and wear resistance, in particular from exposure to hydrogen sulfide.

The said coating has a set of necessary properties to reliably ensure high tightness of the tubing string for a long period of its operation. This set of coating properties includes:

1. high hydroabrasive wear resistance;

2. high abrasive wear resistance;

3. high resistance to erosion wear;

4. high corrosion resistance;

5. high resistance to electrochemical corrosion;

6. high heat resistance of the coating;

7. high adhesion of the coating;

8. high coating cohesion;

9. high density coating;

10. High elasticity of the coating.

The above set of properties of the proposed coating allows to ensure reliable operation of the tubing string in particularly difficult real conditions of its operation, taking into account the vibration of the string. During the descent and lifting of the tubing string, the coating is ideally sealed. This allows you to extend the life of the tubing string three to five times in relation to the known analogues of protective coatings.

Justification of the chemical composition of the coating and the percentage of alloying elements:

- Carbon - provides increased hardness of the coating. An increase in the carbon content in the coating above the upper target coating results in embrittlement of the coating and, accordingly, microcracks in the coating. As a result, the tightness of the coating is violated. A decrease in the carbon content below a predetermined lower limit entails a decrease in the hardness and wear resistance of the coating, which also (when lowering and raising the tubing string) leads to a violation of the tightness of the coating.

- Molybdenum - increases the corrosion resistance of the coating in the environment of hydrogen sulfide and increases the hardness of the coating. With a decrease in the percentage of molybdenum below the lower specified limit, it leads to a significant decrease in the corrosion resistance of the coating in the environment of hydrogen sulfide. An increase in the molybdenum content above the upper specified limit leads to the formation of a carbide phase and embrittlement of the coating.

- Silicon - increases the fluidity of the coating material during its application. As a result, the introduction of silicon into the coating provides good uniformity of coating, high material utilization, high coating density. The decrease in the silicon content below the lower specified limit leads to a significant decrease in the utilization of the coating and the deterioration of its uniformity. Increasing the silicon content above the upper predetermined limit excessively increases the fluidity of the coating material during its application to the product. This in turn leads to runoff of the material from the surface of the product and, accordingly, to a significant deterioration in the uniformity of the applied coating and its continuity.

- Nickel - improves the corrosion resistance and mechanical properties of the coating material. Nickel combined with copper, molybdenum, chromium and iron provides a very high corrosion

durability. A decrease in the nickel content below the lower predetermined limit leads to a significant increase in the corrosion rate in the environment of hydrogen sulfide. So (according to experimental data) a decrease in the nickel content to 7-8% leads to an increase in the corrosion rate from 3 to 5 times. With increasing nickel content above the upper specified limit, the effect of increasing the corrosion resistance of the coating decreases.

- Chrome is the main chemical element that increases the corrosion resistance of the coating. The decrease in the chromium content below the lower specified limit does not provide sufficient corrosion resistance of the coating in the environment of hydrogen sulfide. With an increase in the chromium content above the upper specified limit, an increase in corrosion resistance occurs less noticeably. However, there is a significant embrittlement of the coating due to the formation of chromium carbide.

- Boron - significantly increases the wear resistance and hardness of the coating. In the specified range of boron content, the optimum combination of wear resistance and hardness of the coating is provided without the effect of embrittlement of the coating.

- Manganese - deoxidizes the coating material in the process of spraying the powder, while lowering the melting temperature of the powder and, as a result, a greater elasticity of the coating is achieved, the adhesion of the coating and its density are increased. The lower limit of the manganese content is due to the need for satisfactory deoxidation of the coating material. With an increase in the manganese content above the upper predetermined limit due to the high carbon content leads to embrittlement of the coating.

- Aluminum - reduces the electrochemical potential of the coating in relation to the body of the product, as a result, the durability of the coating is improved. The use of a mixture of metal powder with Al ₂ About ₃

during the spraying process provides intensive bombardment of the sprayed surface, its hardening hardening directly in the process of coating and thereby achieved a significant increase in adhesion and cohesion. In addition, small particles of Al ₂ O ₃ partially embedded in the coating material increase the hardness and wear resistance of the coating. The lower limit of the content of Al ₂ O ₃ is due to its minimum content in the powder, which ensures reliable bombardment of the surface of the product in order to increase adhesion. The upper limit of the content of Al ₂ O ₃ due to the maximum performance of the coating and the maximum utilization of the material.

- Copper - increases the density of the coating (tightness). However, an excessive increase in the copper content leads to a marked increase in electrochemical corrosion.

- Iron is the basis.

The thickness of the working layer of the coating is dictated on the one hand, by the required resource for corrosion resistance and wear resistance, and on the other hand, by economic feasibility. The greater the corrosion resistance of the coating is required and, accordingly, its resource, the greater is the thickness of the coating. For environments with low aggressiveness, the minimum coating thickness is selected.

To provide increased resistance to electrochemical corrosion in particularly aggressive environments (with a high content of hydrogen sulfide), an increased coating thickness is chosen.

The above factors, due to a significant decrease in the corrosion rate of tubing, provide a significant increase in the time between failures of oil and gas production equipment and, therefore, reduce the number of well repairs, the number of runs and lifts of equipment.

Claims (1)

A tubing, on the outer surface of which is coated in the form of a sprayed layer, characterized in that the coating includes C, Mo, Si, Ni, Cu, Cr, B, Mn, Al ₂ O ₃ , Fe in the following the ratio of components, wt.%: C 1.3 ÷ 2.0 Mo 4.0 ÷ 5.0 Si 0.5 ÷ 1.5 Ni 11 ÷ 20 Cu 0.01 ÷ 0.10 Cr 23 ÷ 32 AT 0.001 ÷ 0.1 Mn 0.4 ÷ 1.2 Al ₂ About ₃ 0,1 ÷ 5 Fe rest