SU1102918A1 - Core meter - Google Patents

Abstract

1. CORNOMETER, containing, the base on which the cup is installed. an azimuthal and zenith wellbore angles input unit associated with a decision block, a visible corners of a structural element on a core input block, including a structural element form copying unit and a structural element visible angle calculation unit associated with it, characterized in that, in order to increase the accuracy of measuring the azimuth and angle of incidence of a structural element on the core, the copying unit of the structural element form on the core is made as a set of rods that are arranged along Cored oil surface of the glass with the possibility of axial movement along it. (L 1c with as

Description

2. A core meter according to claim 1, characterized in that a node for converting the position of rods into an electrical signal is used as a node for calculating the visible angles of a structural element, the outputs of which are connected to an analog switch, the output of which is connected to a storage unit through an analog-to-digital converter connected with an arithmetic logic unit connected to the output of the control unit, two

the other outputs of which are connected to a storage unit and an analog switch.

3. Corenometer on PP. I and 2, characterized in that an arithmetic logic unit is used as a decisive unit associated with the display unit, the control unit and the storage unit, the inputs of which are connected to another output of the control unit and the input unit of azimuth and zenith angles.

one

The invention relates to mining, and more specifically to devices for determining the elements of the occurrence of rocks by oriented core, obtained by drilling geological exploration wells.

A well-known coremeter contains a base on which a cup is installed, a movable yoke, a stand, a form copying unit of a structural element on a core in the form of a measuring plane with a triangular notch to which the display device is attached, which contains a compass and a drop angle angle frame, and the base has an input unit azimuth and zenith angles in the form of the corresponding shchkal 1.

However, the measuring plane does not allow to measure the angle and azimuth of the fall of the rock layers with the necessary accuracy, and sometimes it is not at all able to perform its task due to the fact that there is no upper (or upper and lower) point of inflection on the trace of the measured element. and, moreover, the trace between the points of inflection is often significantly different from the linear. Accuracy is also reduced by the fact that with the introduction of the values of azimuth and zenith angle of the well, as well as the reading of the azimuth and angle of incidence of the rock layers, information distortion may be associated with the subjectivity of the reference.

Closest to the invention is a core meter containing the base on which the cup is installed, the input block for the azimuth and zenith angles of the well, associated with the decisive block, the input block for the values of the visible angles of the structural element on the core, including the copying unit of the structural element shape and with it the node for calculating the significant visible angles of the structural element, the display unit 2.

With the known device it is impossible to measure with the necessary accuracy the elements of the bedding of rocks due to the greater degree of subjectivity in the linearization by the copying unit of the tracks, especially with their complex drawing, and also because of the possibility of a certain displacement of elastic

elements in the imposition of the core and error input and read information. In addition, there are operational inconveniences (also associated with unproductive time losses) arising from

installing the core at a predetermined position according to the inclinometric data, as well as when working with the copying unit due to its almost inevitable “fitting to the trail to be covered (with repeated dilution of the m holders, fixing of the elastic elements with the clips, etc.). The purpose of the invention is to increase the accuracy of measurement of the azimuth and angle of incidence of the structural element on the core.

The goal is achieved by the fact that

in the coremeter, the copying unit of the structural element form on the core is made in the form of a set of rods that are placed along the inner surface of the glass with the possibility of axial movement along it.

As a node for calculating the visible angles of the structural element, a rod-to-electrical conversion unit is used, the outputs of which are connected to an analog switch, the output of which is connected via an analog-to-digital converter to a storage unit that is bi-directionally connected to an arithmetic unit connected to the output of the control unit, two the other outputs of which are connected to a storage unit and an analog switch.

An arithmetic-logic block is used as a decision block. It is connected with the display unit, the control unit and the storage unit, the inputs of which are connected to another output of the unit.

control unit and input values of the azimuth and zenith angles.

FIG. 1 shows a kernometer, a general view in the initial position in the axonometric projection (zero bar is shaded for consistency); in fig. 2 - coremeter (in the operation of calculating the azimuth and angle of incidence of the structural element); in fig. 3 - structural electrical circuit of the coremeter.

The core meter consists (Fig. 1) of the base 1, in which the block 2 of inputting the values of the azimuthal and zenith angles of the well in the form of a numeric keypad (containing also the keys for controlling the operation of the coremeter) are located) display unit 3 with the information displayed in digital form. On the base, a cylindrical cup 4 is fastened in which the copying unit of the structural element form on the core in the form of rods 5. are located circumferentially with equal schag (for example, 10 °), and a clip (for example, collet type; not shown) for securing the core. The rods, in the initial position somewhat protruding above the glass, have the possibility of axial movement along it with fixation in any position. One of the rods, conventionally called zero, is labeled (in Figs. 1 and 2, it is truncated). The base also contains a node for calculating the values of the visible angles of the structural element and (Fig. 2), consisting of an analog switch 6 (Fig. 3), the output of which through an analog-to-digital converter 7 is connected to a storage unit 8, two-sided connected with the arithmetic logic unit 9 connected to the output of the control unit 10, the other two outputs of which are connected to the storage unit and the input of the analog switch, the other inputs of which are connected to the outputs of the terminal 11 i (i.e., their lifting heights from the initial position) into an electrical signal, which is a set of displacement sensors, e.g. rheostatic, associated with the rods 5.

The base also contains a decisive unit consisting of an arithmetological unit 9 (Fig. 3) associated with the display unit 3, the control unit 10 and the storage unit 8, the inputs of which are connected to another output of the control unit and the input unit 2 of the azimuth and zenith values corners.

Measurements using a coremeter are carried out as follows. A core with a marker marked on it in advance using a marker on the bottom track of the apsidal plane is fixed in the collet clamp of cup 4, aligning the previously indicated mark with the longitudinal axis of the zero rod (Fig. 1).

After that, the rods are lifted (Fig. 2) until their upper ends align with the trace of the structural element (the constant ends of the upper ends are structurally provided to the cylindrical surface of the core, which eliminates the alignment error due to parallax). The rods that are not possible to combine with the track (for example, due to the absence of the latter on the line of movement of the rods) are left in the initial position.

After the rods are installed at the desired position, i.e. copying the shape of the structural element, using block 2, parameters necessary for the calculations are entered into the storage unit 8, i.e. the values of the azimuthal X and zenith J3 angles (not shown) of the well ( according to inlinometric measurements). Then, by pressing the corresponding key, the program for calculating the azimuth and angle JL of a structural element (not shown) is started.

In this case, the node for calculating the visible angles Y, and Ji of the structural element begins to work as follows.

At the command of the control unit through the switch 6, the outputs of the block 11 are serially connected to the analog-to-digital converter 7 and the values of the signals from displacement sensors, proportional to their height from the initial position and digitized, are stored in the storage unit 8. After storing the signals from all sensors on the commands of the control unit arithmetic-logic unit, operating with data on the height of the rods from their original position (and the position of the rods remaining in the original m position is ignored in height) and

5, the angular distance of each rod from the zero and core diameter (this information is permanently stored in the storage unit), by some mathematical method, for example, the method of successive approximations, determine the parameters of such an ellipse (i.e. a linearized trace), the points of which are optimal are connected with the points of the real trace of the structural element on which the upper ends of the rods are located.

5 After calculating the visible angles Y, and 2. characterizing the position of the ellipse, according to the commands of the control block, the decision block, operating with the values Y,, U, dL, and

P calculates the azimuth If, and the angle I falling of the structural element according to a specific algorithm, for example, by the formulas

4, ,, cig (Sha

Where

inp tq ЗГ1 ± Г90-) cosjb

L- arctg -.

The values 1 | d and L are output to the display unit 3.

The use of the copy unit as a set of movable rods located along the Glass Circle provides for an objective copying of the trajectory of a trace of any complexity (including without a trace of inflection points, n1 closed, etc.).

The use of the proposed kernometer makes it possible to measure the position of the element under study with maximum accuracy, since it uses mathematical methods to process the input and calculated data in digital form using a program that has the advantages of analytical methods. For example, the fall-off azimuth detection error of 30 ° allowed by the existing designs of corenometers allows the proposed design to be reduced at least 10 times, which increases the information content of the oriented core and, as a result, the quality of geological exploration. Working with the device does not require reproducing the position of the core on the face on the surface, which shortens the measurement time and improves operational convenience (which is especially important in field conditions).

Claims (3)

1. KERTSOME'GR, containing, the base on which the glass is mounted, a unit for inputting the values of the azimuthal and zenith angles of the well associated with the decisive unit, a unit for inputting the values of the visible angles of the structural element on the core, including a copying unit of the shape of the structural element and the associated unit calculating the values of the visible angles of the structural element, an indication unit, characterized in that, in order to increase the accuracy of measuring the azimuth and angle of incidence of the structural element on the core, a copy node of the shape of the structural element on ke The wrench is made in the form of a set of rods that are placed on the inner surface of the glass with the possibility of axial movement along it. SU „„ 1102918 2. Cernometer by π. 1, characterized in that as a node for calculating the visible angles of the structural element, a block is used to convert the position of the rods to an electrical signal, the outputs of which are connected to an analog switch, the output of which is connected via an analog-to-digital converter to a storage unit, bilaterally connected to an arithmetic-logical unit, connected to the output of the control unit, the other two outputs of which are connected to the storage unit and the analog switch. 3. The coremeter according to paragraphs. 1 and 2, characterized in that the arithmetic-logical block is used as the decisive block _? associated with the display unit, the control unit and the storage unit, the inputs of which are connected to another output of the control unit and the input unit of the values of the azimuthal and zenith angles.