SU507844A1 - A method for predicting the occurrence time of an earthquake - Google Patents

Description

The analyzed gas enters through the inlet devices into the measuring volume enclosed between the valves, one of which is connected to the mercury manometers. By knowing the pressure and the volume at a known temperature, the total amount of the test gas that is fed into the system is determined. Using a titanium reactor, heated to 1OOO-120O With an external electric heater, helium and argon are cleaned from other natural gases. A liquid nitrogen cooled reactor is used for the same purpose. It should be noted that to inject the test gas into the installation system, it is pumped out to a high vacuum (on the order of up to 10 mm Hg) and checked for vacuum tightness and purity. The installation is equipped with a double valve for the measured volume of the reference gas. Dry atmospheric air is used as a reference gas, since the content of argon and gels in it is of constant value. In those cases when the content of helium in the natural gas under study significantly (by several orders of magnitude) exceeds its content in air, a helium balloon is prepared for the installation to prepare a reference gas mixture. In order to develop a method for predicting earthquakes, it is advisable to investigate natural gases coming from seismically active zones of the Earth’s interior, and even better gases coming from the depths above earthquake sources. Research mass spectrometric laboratories were organized near the epicenters of the Dagestan earthquake in 1970 (Shakhmal-Bulak, Chirkei). The first continuous round-the-clock relative measurements of the in-depth gels were performed on natural gas from wells M 2 during August, December 1973. The gels are analyzed on a PTI-7A helium leak detector every 30 Figs. Figure 1 shows a graph of round-the-clock measurements of the depth of the flow of gels, constructed from the obtained values of its relative content in natural gas; in fig. 2 - graphs of changes in the intensity of gas flows preceding the earthquakes. The sensitivity of the instrument was checked regularly every 3-4 hours and kept constant for a month. It can be seen from the graph that the intensity of the gels changes periodically over the course of a day, with two maxima and two minima being noted. This periodicity of changes in the intensity of the depth of the helium flux is due to the sensory-tidal effect in the deep Earths, due to the gravitational influence of the Moon and the Sun on the Earth rotating relative to its axis. The total intensity of the helium flux varies not only during the day, but also during the period of the synodic month. Its maximum values are observed at new moons, and the minimum values are observed at full moons, which is consistent with the nature of the changes in the gravitational forces of the Moon and the Sun to the Earth. When the gravitational influence decreases from the side of the moon and the sun, the intensity of the deep flow of the gels decreases accordingly. Further on, the plots show the areas preceding the earthquakes. These areas are characterized by the fact that there are no periodic tidal phenomena during the half a day. Thus, it was found that the characteristic of the daily tidal phenomena, the periodicity of rocks before the earthquake disappears and is replaced by another course of the depth-flow curve of the gels. FIG. 1, these areas are indicated by hatching. As can be seen in the graphs of FIG. 2, with a single push, approximately an hour before the earthquake, the frequency in the change in the intensity of the gas flow is disturbed, and it is replaced by a curve that characterizes the intensity increase first, then its decrease to the background value. With a single push, the following pattern is observed: about an hour before the push, the periodicity of fluctuations in the intensity of the deep gas flow is disturbed, it turns into a sharp increase in intensity, which then decreases to the average background value. In this case, the time of growth and decrease in the intensity of the gas flow is about a day, and the time of the background value of the intensity of the gas flow that is stabilized lasts about 10 hours. After the push, the frequency fluctuations in the intensity of the gas flow are relatively quickly restored. If the first push is followed by aftershocks, then also approximately for the hour before the first push the frequency fluctuations of the gas concentration are disturbed. But after the first jerk, a sharp increase in the concentration of the gas is observed, and when the maximum value is reached, the aftershocks follow each other.

According to “various types of changes in the concentration of gas flows preceding the earthquakes, we can see that earthquake is the effect not of one, but of two (or several) mecha- nisms operating in the outbreak.

Claims (1)

Formula and goiter The method of predicting the occurrence of an earthquake in a seismically active region, consisting in periodic and mernnia in areas of discontinuity of rock formations in the gaseous and liquid phase concentrations of radiogenic gases, followed by determining the value of their ratios, for example, He / At, which differs with the fact that, in order to increase the exact | t and reliability of the method, at the same time measuring "this is the amount of heat flow and, according to shade fu