RU2523904C1 - Prevention of accidents at oil-and-gas-production wells - Google Patents

Abstract

FIELD: oil-and-gas industry.

SUBSTANCE: proposed method comprises well drilling, core recovery in drilling and core analysis for content of impurities. Note that spectral analysis is made to detect water-oil-insoluble salts of heavy metals and to fix their occurrence depth. Availability of said compounds allows making the conclusion on the location of super reservoirs in deposit. Quantitative content of said impurities in core rock allows making the conclusion on accurate location of interlayers. Said accurate location is used to take measures for prevention of well collapse by reducing the mechanical drilling rate.

EFFECT: simplified core analysis, higher validity, decreased accident rate.

1 dwg, 1 ex

Description

The present invention relates to the oil and gas industry, namely to drilling wells.

A known method for predicting heterogeneities leading to emergencies in the construction of oil and gas wells. It is based on the selection of material from the well, followed by x-ray structural determination of clay minerals, which can be used to judge the intensity of tectonic disturbances causing emergency situations (see Sakhibgareev R.S., Galikeev K.Kh. Impact of discontinuous disturbances on the epigenesis of clay minerals in oil deposits Neocomian West Siberian lowland (Lithology and minerals. 1971 No. 5, pp. 108-119).

The disadvantage of this method is the duration of the analysis and its high cost.

As a prototype adopted a method for predicting emergency situations when drilling according to US Pat. RF №2352966. "A method for predicting emergencies in the construction of oil and gas wells." IPC G01V 9/00, E21B 49/00, E21C 39/00, publ. 04/20/2009

It consists in the fact that while drilling oil and gas wells during the drilling process, rock samples (core) are taken and analyzed. According to the invention, samples of terrigenous rocks are taken from the oil and gas bearing areas of the sedimentary cover adjacent to or located directly above the buried continental rift, they are treated with hydrochloric acid, the fault products are judged on the presence of faults hidden at a great depth, and zones of development of lomontite (zeolite) in terrigenous thicknesses of the cover are identified by the appearance of a gelatinous mass of silica (the product of the interaction of HCl and lomontite), which is used to judge the presence of faults hidden at a depth. The method includes drilling a gas-oil well, selecting core samples during drilling of a well, analyzing them, and taking appropriate measures to prevent emergency situations.

The disadvantage of the prototype is the complexity, duration and high cost of core analysis, which reduces the effectiveness of the method for predicting emergency situations when drilling wells.

It is known that gas-bearing strata (reservoirs) of oil and gas fields are characterized by specific features. They exhibit a significant variation in properties and are subject to various transformations. Their reservoir properties are weakened or enhanced depending on the direction of the physicochemical processes occurring in the natural reservoir. As a result, interlayers of strongly cemented dense rocks are formed, as well as contrasting intervals of loose, weakly bound rocks with properties that differ sharply from the bulk of the rocks. These unconsolidated zones with a thickness of 1-5 m are called super collectors. With the passage of interlayers of super collectors by drilling, the mechanical penetration rate increases by 3-4 times. The lower boundary of the supercollector zone is emphasized by a very hard and strong layer, in which heavy metal compounds are concentrated, the concentration of which is increased compared to previous layers of rocks. When drilling at high speeds, due to an abrupt change in the mechanical properties of the rocks, a sharp blow to the formation with increased strength occurs, the drilling tool fails and an emergency occurs. The intervals of occurrence of super collectors are confined to the zones of ancient oil-water contacts (DVNK), which are reaction zones of intensive transformation of rocks and hydrocarbons into deposits. Any sedimentary rocks contain a number of metallic trace elements distributed according to well-known patterns, significantly different for different deposits. In hydrocarbon deposits, mobile forms of metals are associated with mobile phases of fluids - gas, light oil and water. Sedentary forms of metals enrich sedentary fluids - resins, asphaltenes and solid bitumen. Different metals form different associations in the migration flows in the deposits. The maximum concentration of metals is noted in the bitumen subzones of ancient oil-water contacts. The most restored (pure) forms of metals are found in the gas core of a deposit. The boundaries of super collectors are marked by layers of sedimentary rocks with maximum concentrations of compounds of a number of metallic trace elements.

The objective of the invention is to increase the efficiency of the method for preventing emergencies when drilling oil and gas wells.

To prevent emergency situations, it is necessary to identify interlayers of super collectors, their identification and determination of rock properties. To do this, the rock is examined for the presence in the boundary zones of water-oil-insoluble compounds of heavy metals, such as Cu, Mn, Sr, Pb, V, Co, Bi, Ti, Ni, Ga. Compounds of these metals are carried by migration flows of hydrocarbons. There is a clear connection between the places of their deposition with the formation of boundary zones of interlayers. As our studies showed (Fig. 1), a redistribution of these compounds during the formation of the deposit and their accumulation at the lower boundaries of the super collector interlayers are noted along the section of the hydrocarbon deposit, which leads to an increase in the strength characteristics of the rocks in these zones. When these zones are reached by the drilling device, provided that the drilling speed remains constant, an emergency occurs, i.e. breakage of the drilling tool. To prevent them, it is necessary to determine the location of these boundaries along the depth of the well.

The technical result consists in simplifying the analysis of the core, because the recommended spectral method for studying the rock is characterized by universality, simplicity, accessibility and does not require large masses of the analyzed core samples, as well as drilling large diameter wells for sampling (A. Rusanov, Fundamentals of the quantitative spectral analysis of ores and minerals. - M., 1971). Spectral analysis refers to high-precision, sensitive and informative methods and allows for a qualitative and quantitative assessment of core composition for the presence of heavy metal elements present even in minimal quantities, which leads to a significant increase in the efficiency of reducing emergency situations on a drilling tool; reduced drilling time by eliminating emergency downtime.

The problem is solved in that when drilling a well, core sampling is carried out, samples are examined by spectral analysis for the presence of oil-insoluble impurities in the core rock, namely compounds of heavy metals. In this case, the depth is fixed at which a sharp increase in their concentrations is noted, many times exceeding the background values. By the increased concentration of impurities in the core, an increase in hardness and drillability of the rock is judged and, accordingly, an action is taken to prevent an accident, reducing the mechanical drilling speed of the well.

The graphs (Figure 1) show the results of a spectral study of core samples from wells No. 2 and No. 10 of the Karachaganak gas condensate field, namely, the change in the concentrations of metals such as Cu, Mn, Sr, Pb, Bi, Ti, Ni along the depth of the well and the depths are highlighted at which their concentrations reach maximum values and rock drillability deteriorates.

Example 1

In the process of testing the method, based on data from neighboring wells, zones of possible accidents were identified for well No. 10 of the Karachaganak field. At a depth of 3515 m, an increase in the speed of penetration by a ST grade bit with an axial load of 100 kN to 28 m / h began. Starting from 3579 m, the driving speed was reduced to 8 m / h. At a depth of 3825 m, the mechanical drilling speed dropped sharply to 1 m / h. After studying the core from a depth of 3515-3825 m, the Mn content in the amount of 0.26% wt. After conducting physical and chemical studies, this interval is interpreted as the zone of location of the easily drilled supercollecting rock. Starting from a depth of 3820 m, an increase in the speed of penetration with a CT bit to 34 m / h began. Upon reaching a depth of 3823 m, the drilling speed was reduced to 6 m / h. At a depth of 3825 m, a very dense layer of rocks with high strength properties was encountered; an emergency failure of the bit did not occur. Studies of the raised core showed an increased N1 content in the amount of 0.26% wt. at a depth of 3825 m. After conducting physical and chemical studies, the interval 3820-3825 m was interpreted as a zone of the location of a super collector with good drillability and weak strength properties. By reducing the mechanical drilling speed when approaching a depth of 3825 m, the accident was avoided.

When testing the method at the Karachaganak and Orenburg deposits, research wells were drilled and cores were extracted, spectral studies of core rocks for the presence of heavy metal impurities in them were carried out. Visual diagrams of changes in the concentrations of metals such as Cu, Mn, Sr, Pb, Bi, Ti, Ni along the depth of the well are constructed. These tests made it possible to determine the boundaries of interlayers with increased hardness, since the depths of the rocks containing high concentrations of impurities were recorded, and hazardous depths of the rocks were identified at which the rocks drilled at high speeds end, and due to the large amount of sediment deposited at this depth water-oil-insoluble compounds of metal metals of the rock get the properties of hardening and resist destruction by their bit. In order to avoid damage to the drilling tool at the locations of these interlayers, a decrease in the drilling speed was provided when the drilling tool approached them. Moreover, after passing through these zones, the drilling speed was returned. T.O. accidents of the drilling tool were prevented and the total time of emergency downtime during well drilling was reduced, and the cost of drilling was also reduced.

Claims (1)

A method for preventing emergencies when drilling oil and gas wells, including drilling a well, selecting core samples during drilling and analyzing for impurities, characterized in that, in order to prevent accidents with drilling tools, the rock is analyzed for impurities of oil-insoluble compounds of heavy metals in it , by their presence they judge the location of super collectors in the deposits, by the amount of impurities they judge the hardness of the rock and the location leading to accidents with drilling tools entom solid layers in the rock and take measures for preventing accidents in a borehole, e.g. reduced penetration rate.

Images