RU135357U1 - CONTROL AND MEASURING COMPLEX FOR RESEARCHING THE TECHNICAL CONDITION OF EXISTING WELLS - Google Patents

Abstract

The utility model relates to the field of oil and gas production and can be used to study the quality of cementing of existing wells. The technical result obtained from the implementation of the utility model is to increase the reliability of information obtained using a control and measuring complex (CFC) about the near-wellbore space and the quality of cementing behind two or more columns of an existing well. This technical result is achieved due to the fact that in the well-known KIC containing a logging system with a set of geophysical modules connected to each other via butt nodes, a set of geophysical modules is performed in the form of modules of spectrometric modifications of radioactive logging: gamma-ray logging, neutron logging, neutron gamma - logging, neutron-neutron logging, in particular for chlorine and pulsed neutron logging. The use of this KIK allows not only quality control of cement stone in the annular and annular spaces, but also the identification of technogenic accumulations of gas in the voids and cavities of the cement stone (1 n.p. and 1 s.p. f-ly; 3 ill.).

Description

The utility model relates to the field of oil and gas production and can be used to study the quality of cementing of existing wells.

Known instrumentation complex (KIK) for similar purposes, containing a logging system with two modules. In the first upper module are sensors for flow, pressure, temperature, gamma-ray logging and couplings locator. In the second lower module are sensors for humidity, electrical resistance and hot-wire anemometer, forming a module of the composition of the well fluid / RF Patent No. 21515, cl. ЕВВ 47/00, 2002 /.

The disadvantage of the analogue is the lack of modules for the implementation of spectrometric methods of gamma, neutron-gamma and neutron-neutron logging, as well as pulsed methods of neutron-gamma and neutron-neutron logging.

The absence of these modules as part of the KIK makes it impossible to diagnose the technical condition of columns and cement stone without losing the opportunity to study dynamic processes in annular and annular spaces.

Known KIK for the study of the technical condition of existing wells, containing a logging system with a set of geophysical modules connected to each other through the butt nodes / RF Patent No. 61342, class. ЕВВ 47/00, 2007 /.

The disadvantage of this KIK is the lack of modules for the implementation of spectrometric, radioactive methods, such as gamma, neutron-gamma and neutron-neutron logging methods, as well as pulsed neutron-gamma and non-neutron-neutron logging methods. This limits the reliability of the geological and geophysical information obtained using the KIK about the near-wellbore space and the quality of cement behind two or more columns of an existing well.

Known KIK for researching the technical condition of existing wells, containing a logging system with a set of geophysical modules connected to each other through docking nodes, including a spectrometric radioactive logging module, made in the modification of neutron-neutron logging (email: http: // www. tpg.ru/rnain.php?eng=&pid= ^: 8 & id = 5b).

This CFC is taken as a prototype.

The disadvantage of the prototype is the absence in its composition of a complex of neutron-neutron logging for chlorine and the modification of pulsed neutron-neutron logging, which reduces the reliability of the information obtained using CFC.

The technical result obtained from the implementation of the utility model is the elimination of the listed disadvantages of the prototype, i.e. increasing the reliability of information obtained using CFC information about the near-wellbore space and the quality of cementing behind two or more columns of an active well by assessing the quality of cement by chlorine using pulsed neutron-neutron logging.

This technical result is achieved due to the fact that in the well-known KIC for studying the technical condition of existing wells, containing a logging system with a set of geophysical modules connected to each other through docking nodes, and including a spectrometric radioactive logging module, made in the modification of neutron-neutron logging, spectrometric neutron logging module is made in the form of spectrometric modification of neutron-neutron logging for chlorine.

In addition, the module of spectrometric radioactive neutron-neutron logging for chlorine is made in the form of spectroscopic modification of pulsed neutron-neutron logging.

The utility model is illustrated by drawings: figure 1 presents a diagram of the downhole part of the KIK; figure 2, 3 are diagrams of lithological sections of the existing wells obtained with its help.

KIK contains a logging system that includes its traditional components: a hoisting device (not shown), a cable cable 1 connected at one end to a downhole tool 2, which includes a set of geophysical (measuring) modules 3, 4, 5 located in well 6. At the other end, the cable 1 is connected to a processing and recording apparatus located on the surface of the earth (not shown).

Modules 2, 3, 4 are interconnected via universal docking units 7, 8, allowing you to attach an additional number of measuring modules to them for measuring various geophysical parameters.

A feature of this CFC is the presence in the measuring complex, in addition to the module (s) of spectrometric radioactive logging, which (which) can be performed in the form of spectrometric modifications of gamma-ray logging, neutron logging, neutron gamma-ray logging, and also the neutron-neutron logging module for chlorine.

Chlorine neutron-neutron logging can be performed in pulsed modification.

As shown by long-term studies, the methods of spectrometric gamma-ray logging and other nuclear-geophysical methods, implemented using the presented KIK, allow reliable information about the near-wellbore space and the quality of cementing for two or more columns of existing wells.

The simplest task is to assess the quality of the cement stone and to identify the man-made gas behind the production casing (EC).

Figure 2 shows the results of spectrometric studies performed to assess the degree of destruction of the cement stone behind the EC and the identification of technogenic accumulations of gas.

Well measurements were performed twice: first in a gas-filled well through a tubing, and then six months after shutting down and killing the well.

The idea of the lithology of the section, obtained using CFC, are presented in figure 2 in the column "Lithology by GIS".

The lithological model makes it possible to most vividly assess the possibility of partial entry of gas from underlying reservoirs into water-saturated reservoirs.

When determining the presence of cement stone behind the EC in the research interval (538-749 m), filling the annular space with cement stone was assessed as partial, sometimes complete. Moreover, in the range of 730-750 m, according to the data of spectrometric neutron gamma-ray logging, gas filling of voids in a cement stone was observed.

The annular space cementing quality was estimated using gamma-ray spectrometric data and neutron measurement results. The determinations made by different methods as a whole over the studied interval do not contradict each other.

Figure 2 also shows the results of comparing the density parameters of spectrometric neutron gamma-ray logs obtained with different instruments in a gas-filled wellbore with a tubing and in a stopped well without tubing with a polymer solution. Simultaneous research data by various methods showed high correlation coefficients, which indicates good reliability of the results and the possibility of conducting studies to assess the quality of annular space cementing through tubing in a working well.

Figure 3 presents the results of determining the quality of cement for EC according to measurements of neutron-neutron logging of a centered device. The quality of the cement following the EC columns (the “liner” and the technical column) was evaluated using an in-depth complex of chlorine neutron-neutron logs and spectrometric gamma-ray neutron logs.

Based on the results obtained, it was found that the spaces:

- behind production and mechanical columns - completely filled with cement;

- behind the shank - partially filled with cement in the range of 712-640 m; completely filled with cement in the range of 640-474 m.

Using pulsed neutron logging, it is possible to carry out not only spatial, but also temporary analysis of the state of the near-wellbore space and the quality of cementing behind two or more columns of existing wells.

Based on the results of the use of spectrometric modifications of gas-physical modules of radioactive logging to assess the filling of the annulus and annulus of the well, it can be concluded that this complex is the most informative and technologically advanced in the conditions of a multicolumn construction and a gas-filled wellbore and allows monitoring the state of cement stone in the annulus and annulus spaces.

This achieves the set technical result.

Claims (2)

1. A control and measuring complex for investigating the technical condition of existing wells, comprising a logging system with a set of geophysical modules connected to each other through docking nodes, and including a spectrometric radioactive logging module, made in the modification of neutron-neutron logging, characterized in that the spectrometric neutron-neutron logging module is made in the form of a chlorine-based spectrometric modification of neutron-neutron logging. 2. The control and measuring complex according to claim 1, characterized in that the module of spectrometric radioactive neutron-neutron logging for chlorine is made in the form of spectroscopic modification of pulsed neutron-neutron logging.

Images