RU2740509C1 - Method for determining optimum depth of charge immersion and constructing model of upper part of the section based on drilling data during seismic survey - Google Patents

Abstract

FIELD: seismic survey.

SUBSTANCE: invention relates to the field of seismic exploration, in particular – for determination of boundaries of zones of low and low speeds of seismic waves propagation during seismic operations. Method, according to which performing experimental work on selection of optimal depth of charge immersion and operation of microseism logs (MSL), characterized in that, in addition, during the test work for determining the optimum depth of charge dipping and during MSL performing continuous recording of drilling parameters, from which the value of specific energy intensity of drilling is calculated and the rock connectivity parameter characterizing the charge charging optimum depth, during the main seismic exploration operations, directly in the process of drilling of each well, determining the optimum depth of the charge according to the selected connectivity parameters, MSL results are used to find a correlation between connectivity parameter and longitudinal wave velocity, drilling data are used to construct high-density models of strength and elastic characteristics of rocks, from which, based on the found correlation relationships, a depth-velocity model of the upper part of the section and a priori static corrections are calculated.

EFFECT: high accuracy and reliability of determining the depth of charge immersion, high accuracy of constructing a depth-velocity model of the upper part of the section, high quality of seismic data.

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Description

The invention relates to the field of seismic exploration, in particular - to determine the boundaries of zones of low and low velocities of propagation of seismic waves during seismic exploration.

As you know, the study of the upper part of the section is carried out in order to determine the optimal immersion depth of the charge (the most favorable conditions for the excitation of oscillations) when conducting seismic surveys on land using an explosive source of excitation, as well as to determine the depth-velocity model (GSM) and calculate static corrections during seismic exploration using any type of excitation source (explosive, vibration, impulse, etc.).

The quality of the seismic material recorded in the field is significantly influenced by inhomogeneities in the upper part of the section: in the zone of low and low velocities (ZMS, ZPS) there is a significant absorption of the seismic pulse energy, especially in the high-frequency part of the spectrum. Significant lateral changes in the velocity in the ZMS and in the power of the ZMS itself lead to distortions of the hodographs of reflected and refracted waves. Information about the structure of the near-surface area allows one to take into account and compensate for the negative effect of the near-surface area both at the stage of seismic exploration due to the immersion of the charge below the bottom of the earth-explosive zone (in conditions favorable for the formation of a seismic pulse), and at the stage of subsequent processing of seismic information (introduction of static corrections, construction of geological and migration transformations).

There is a known method for determining the optimal immersion depth of the charge by conducting experimental work on the choice of the immersion depth of the charge (Instruction on seismic exploration, 2003). The method consists in choosing several observation points with different seismogeological conditions in the area of work. In each of the selected observation points, several wells are drilled to different depths and seismograms are recorded. According to the attributes of the seismic record, the optimum immersion depth of the charge is determined. The disadvantage of this method is the low density of observation due to the high cost of such work.

The closest analogue is a method for determining the optimal immersion depth of the charge and studying the structure of the near-surface area according to the data of inverse microseismic logging (MSC) (Collection of laboratory works on the disciplines: "Exploration geophysics" and "Field geophysics", MB Shmareva. 2013). The method consists in registering a direct wave on the surface of the earth, excited at different depths in a blast hole. A well is drilled at each MSC location, near the mouth of which several geophones are placed at different distances. A probe is lowered into the well, on which garlands of electric detonators are fixed, and their successive explosions are made at different depths. According to the seismogram records of the MSC, the times of the first arrivals of reflected waves are determined, the vertical time is determined by introducing a correction for the distance from the wellhead, the vertical times are averaged for different receiving points, the vertical travel time curve is constructed and the reservoir velocities are calculated. The depth of the sole of the ZMS is determined by a sharp increase in speed. The main result of the MSC work is the depth-velocity model of the VCHR. An additional determination of the optimal depth of immersion of the charge is based on an empirically established pattern, according to which the greatest seismic effect is achieved when the charge is immersed below the low velocity zone (ZMS). The disadvantages of this method are:

- the lack of a reliable theoretical justification for the use of the velocities of reflected waves to determine the depth of immersion of the charge (empirically established relationship is used);

- large error in determining the velocities (velocities for the same depths on the given travel time curves for observation points from different distances in most cases differ significantly);

- data distortion when the MSC pigtails ascend in quicksand conditions;

- high cost, and as a result - low density of such works.

The objective of the present invention is to improve the accuracy and reliability of determining the depth of immersion of the charge, to increase the accuracy of constructing the depth-velocity model of the VChR, to improve the quality of seismic data and the efficiency of field work.

The task is solved as follows.

According to the method for determining the optimal immersion depth of the charge and constructing a VChR model based on drilling data during seismic exploration with conducting experimental work to select the optimal immersion depth of the charge and MSC operations, additionally

- in the process of drilling wells in the course of experimental work to determine the optimal immersion depth of the charge and during the MSC, the drilling parameters are continuously recorded, according to which the value of the specific energy consumption of drilling and the parameters of rock connectivity characterizing the optimal immersion depth of the charge are determined;

- during the main seismic survey directly in the process of drilling each well, the optimal depth of charge immersion is determined, according to the selected connectivity parameters;

- based on the results of the work of the MSC, a correlation dependence between the connectivity and the velocity of longitudinal waves is found;

- based on the drilling data, high-density models of the strength and elastic characteristics of rocks are built, according to which, taking into account the found correlations, the depth-velocity model of the VChR and a priori static corrections are calculated.

A significant difference between the proposed method and the known ones lies in the additional determination of the value of connectivity, which characterizes the strength characteristics of the rock, directly affecting the optimal conditions for the placement of the charge.

Since the redistribution of energy and the formation of a seismic impulse as a result of an explosion occurs in the near zone and depends more on the strength properties of rocks than on elastic, the strength characteristic (connectivity) is more suitable for determining the optimal depth of immersion of the charge.

As you know, regardless of the method of destruction of the rock to the same degree of fragmentation, the destruction energy remains constant, that is, the specific energy consumption of the destruction of the rock is its constant. Since the term "energy intensity" is used to characterize the process of destruction, for the petrophysical characteristics of the rock, the name "connectivity" is more appropriate - the binding energy between the structural grains of the rock. At present, the term "connectivity" is used to qualitatively characterize the degree of connection between mineral grains of terrigenous rocks. For example, loose sand, loose sandstone, cohesive sandstone. For rocks of the same type, connectivity is a quantitative measure that characterizes the defectiveness or weakness of the rock (RU, patent 2050013, GOIV 9/00, 1992.). Since no energy is spent on the destruction of the liquid and gaseous phases, porosity and fracturing directly affect the connectivity, lowering it. When drilling with one bit with drilling parameters that are rationally selected (minimizing the energy consumption of drilling) for each type of drilled rock, the particle size distribution remains practically constant, which ensures that the energy intensity of drilling is consistent with the connectivity parameter.

In practice, the implementation of the method for determining the optimal immersion depth of the charge and constructing a VChR model based on drilling data during seismic exploration is carried out as follows:

To measure the energy consumption of drilling, the drilling rig is equipped with a certain set of sensors and a module for processing and recording numerical data (RU patent 2541977 C2, 2012),

by the indicators of which the energy expended during drilling is calculated, according to the following formula:

where P is the vertical force at the bottom of the well, kN / m; S is the cross-sectional area of the well, m ² ; M - torque of the drilling tool, kN-m; n - rotation frequency, s ^-1 ; v - speed of translational movement of the drilling tool, m / s.

Since in the process of drilling not all energy is spent on the destruction of the rock, the total energy consumption during drilling is estimated by the formula:

E is the total energy spent on drilling,

Er. - the energy spent on the destruction of rock at the bottom,

Et. - energy spent on transportation of cuttings from the bottom hole to the wellhead.

Parameter Et. depending on the drilling method, it is determined as follows:

- during rotary drilling, in order to take into account energy losses that do not go to the destruction of rocks, measurements of energy consumption at idle are periodically carried out;

- during auger drilling, in order to take into account energy losses, energy consumption is measured when drilling a specially prepared well filled with dry cohesive sand. In fact, when drilling loose, cohesive sand, all the energy will be spent only on transporting drill cuttings from the bottom hole to the wellhead. According to the graph of energy intensity versus depth, energy consumption for the transportation of cuttings is determined.

Further, taking into account the obtained parameter of energy losses Ет. determine the connectivity of the rock:

Based on the results of measuring the drilling parameters and the subsequent calculation of the connectivity parameter, a graph of connectivity changes along the wellbore of the drilled well is obtained with a step of 10-50 cm (depending on the step of measuring the primary drilling parameters). To determine the optimal immersion depth of the charge, the effective connectivity in the near field is additionally calculated. The effective connectivity is calculated by averaging the connectivity graph using a moving average weighting function with an averaging base that is selected in direct proportion to the charge weight. All parameters of the averaging filter (weight window, smoothing base, smoothing function) are selected based on the results of experimental work. The selected parameters are entered into the computing unit, and during the execution of the main production seismic survey, the optimal depth of the charge is automatically determined.

The results of empirical studies in open pits during drilling and blasting operations obtained in practice indicate a positive correlation between the energy consumption of drilling and the velocity of longitudinal waves. The correlation coefficient was 0.96, which indicates a very high tightness of the relationship between these parameters (Destruction of rocks during drilling and blasting. YM Dodis, VI Nifadiev. Study guide. Bishkek. 2006). Strength and elastic properties belong to the same category of mechanical properties and complement each other. Elastic properties (longitudinal wave velocity) are an indirect indicator of the strength properties of rocks. The efficiency of using the velocities of longitudinal waves to determine the depth of the charge placement also indicates a close relationship between the strength and elastic properties of the rock, that is, the presence of a high positive correlation between these parameters. This fact makes it possible to solve the second problem - the construction of a VCR model.

After the main seismic surveys, in the presence of MSC data, the correlation dependences between the connectivity parameter and the seismic wave velocity are calculated. Based on the found correlations between the elastic and strength properties of rocks, a VCR model is constructed and a priori static corrections are calculated.

Thus, the proposed method for determining the optimal immersion depth of the charge and constructing a VChR model based on drilling data during seismic exploration provides:

- increasing the reliability of determining the optimal immersion depth of the charge, since the strength characteristic of rocks is used, which is directly related to the conditions of the formation of a seismic pulse. The use of integration methods based on correlations with the use of MSC data allows to further improve the reliability of the results;

- increasing the observation density (lateral resolution) when determining the optimal immersion depth of the charge and building a VChR model in the case of explosive seismic exploration;

- the use of integration methods based on correlations with the involvement of MSC data allows you to build a high-density depth-velocity model (GSM), on the basis of which more accurate a priori static corrections are calculated;

- increasing the economic efficiency of work. The use of this method reduces the number of overdrills in places with poor near-wellbore conditions, since it provides the ability to quickly determine the places where deeper drilling is needed. To implement the proposed method, there is no need to carry out an additional amount of work, since the drilling parameters are recorded automatically and does not affect the productivity of the work;

- improving the quality of field seismic material. It is known that low-density MSC surveys cannot predict local anomalies in the structure of the VChR, which leads to deterioration of the field seismic material. The proposed method does not have these disadvantages, since the structure of the VChR is determined promptly during the drilling process and directly at those observation points where the seismic pulse is excited.

Implementation of the proposed Method for determining the optimal immersion depth of the charge and constructing a VChR model based on drilling data during seismic exploration does not require the use of special equipment. It is enough to use equipment that is already successfully used in engineering geology (RU patent 2541977 C2, 2012.) and in the extraction of minerals in quarries (http://blastmaker.kg/services-and-products/assd-bs-kobus), which meets the criteria of the invention "industrial applicability".

Thus, on the basis of the foregoing, we believe that the task of the invention has been solved in full.

Claims (5)

A method for determining the optimal immersion depth of the charge and building a model of the upper section of the section (UCH) according to drilling data during seismic exploration, according to which experimental work is carried out to select the optimal depth of immersion of the charge and the work of microseismic logging (MSL), characterized in that addition - in the process of conducting experimental work to determine the optimal immersion depth of the charge and during the MSC, the drilling parameters are continuously recorded, according to which the value of the specific energy consumption of drilling and the rock connectivity parameter characterizing the optimal depth of the charge are calculated; - when carrying out the main seismic works, directly in the process of drilling each well, the optimal depth of the charge is determined according to the selected connectivity parameters; - based on the results of MSC work, a correlation dependence between the connectivity parameter and the velocity of longitudinal waves is found; - based on the drilling data, high-density models of the strength and elastic characteristics of rocks are built, according to which, taking into account the found correlation dependences, the depth-velocity model of the VCR and a priori static corrections are calculated.