SU1583905A1 - Checking device for af@ lateral micrologging - Google Patents

Abstract

The invention relates to the calibration of borehole geophysical instruments of the lateral micro logging and solves the problem of increasing the accuracy of calibration, reducing its labor intensity and reducing the dimensions of the calibration device. The verification device comprises a tank of non-conductive material filled with a mineralized aqueous solution for accommodating a probe installed in it by means of levers on the instrument body. A non-conductive rod is attached to the screen electrode of the lateral logging tool, on which a non-conductive rod is fixed by means of fixing elements, and a non-conductive screen is fixed to it by means of fixing elements. The screen length exceeds the probe length, and the width is determined by the ratio B≥AC / R + A, where B is the screen width, mm, A is the probe width, mm, C is the maximum distance between the outer surface of the probe and the inner surface of the screen, mm, R is the radius of the outer surface of the probe, mm. 1 il.

Description

The invention relates to the calibration of borehole geophysical instruments of a side microkartage containing a microprobe with current focusing.

The aim of the invention is to improve the accuracy of calibration and reduce the labor intensity of verification.

The drawing shows the Device, a longitudinal section of

A verification device for a lateral micro logging device contains

tank 1, made of non-conductive material and filled with saline water solution 2 to accommodate probe 3 installed by means of levers 4 and 5 on the body of the device 60. Probe 3 is a current focusing probe (side microcarting probe) and includes a non-conductive housing in which a central electrode 7 is mounted, surrounded by at least one screen electrode 80; Electrodes are insulated by one

R

from another non-conductive material of the housing To the screen electrode 8 is attached, for example, by threaded connection rod 9 of non-conductive material, on which are fixed fixing element 10 of non-conductive material, non-conductive screen 11 and fixing element 12, made, for example, in the form of

the nuts. On the case of the device 6 is placed the return electrode 130

To prevent leakage of the currents of the central and screen electrodes of the probe, the nonconductive screen 11 must have appropriate dimensions0 The length of the nonconductive screen 11 must exceed the length of the probe, and the width is determined by the ratio

ace

 + and where b is the width of the screen, mm; a - probe width, mm; c is the maximum distance between the outer surface of the probe and the inner surface of the screen, mm; g - the radius of the outer surface

screen, mm0

To reduce the overall dimensions of the device, tank 1 is made of non-conductive material, which eliminates the leakage of current from the central and e-electrodes to the walls of the tank "I

The device works as follows.

The device is placed in the tank 1 so that the probe 3 and the electrode 1.3 are covered with a mineralized water solution 2, the resistivity of which has been previously measured by a resistivity meter. Rod 9 is connected to the screen electrode 8 and the fixing element 10 is put on it, and then the screen is installed 11 and is fixed with a locking element 12, for example a nut. After that, the device is switched to measurement mode. 0 In the measurement process, the potentials of both electrodes 7 and 8 are equal, as a result of which the current of the central electrode is focused, t, e0 propagates within the expanding beam, perpendicular to the working surface of the probe, and closes on the opposite electrode 13. A non-conducting screen 11 encounters on its way, the current of the central electrode changes its direction and along the screen surface, overcoming the resistance of the screen electrode current, flows to the reverse electrode type 13 As the distance from the working surface to the znzah, the focusing effect of the screen electrode becomes less significant, which reduces the resistance to the current of the central electrode as it flows to the return electrode, and the resistance to the current of the central electrode depends on its trajectory, which is determined by the position of the nonconductive screen in relation to the working surface of the probe The closer the screen is to the working surface of the probe, the greater the resistance is affected by the current of the screen electrode and the more The most measurable resistance. The principle of operation of the proposed calibration device is based on this effect. With the help of a movable non-conducting screen, the same effect is achieved that is achieved by changing the degree of salinity of the solution (since the focusing effect is related to the resistance of the saline solution).

When installing various fixing elements 10, the device registers various resistance values. The number of such measurements is associated only with the number of available measuring plates, but for accurate calibration of the device they must be at least five times. The obtained measurement results are tabulated and taking into account the previously measured the resistivity meter of the solution resistance determines the equipment error „

Claims (1)

Invention Formula 1 "Calibration device for lateral microkartage equipment containing a tank filled with a saline water solution for placing a probe into it in test equipment, characterized in that, in order to improve the accuracy of calibration and reduce labor intensity, the device is equipped with a non-conductive screen located between the outer surface probe and wall of the tank and mouth56