SU373676A1 - VSWNI tt \ 111 ^ [: t - '^' g1Sh - Google Patents

Description

one

The invention relates to the field of seismic exploration, in particular, to devices for processing seismic data and is intended to increase the efficiency of studying the intensity of seismic waves previously extracted by optical filters from a wave pattern of any complexity.

Devices for separating interfering seismic waves are known based on the use of optical systems in which the source of coherent light is a gas laser. These devices make it possible to isolate the waves from the COMPLEX wave pattern and classify them according to the values of apparent velocities, i.e., make it possible to study only the kinematic characteristics of seismic waves.

The absence of existing devices for photoelectrically blocking devices makes it impossible to obtain quantitative data on the change in luminous flux at the output of optical filters; B, which makes it impossible to determine the change in seismic wave intensity and significantly reduces the efficiency of the analysis carried out using optical systems. By "intensity," we mean the integral values of Nvadra; s, the amplitudes of seismic oscillations proportional to the intensity of the light flux corresponding to the portion of the wave being analyzed.

The purpose of the invention is to develop a device that allows to increase the efficiency of studying the dynamic characteristics of seismic waves, as well as making it possible to increase the performance of determining these characteristics in a wave pattern of any complexity.

This goal is achieved by the fact that in the device between the container of the information carrier and the scanning slot an optical system is installed that converts the time section into a two-dimensional spectrum, and in the plane of the two-dimensional spectrum there is a system of wedge-shaped diaphragms.

The drawing shows a block diagram of the proposed device, which consists of the following nodes: a gas laser 1 with a power of up to 5 meters, used as a source of coherent light; a focal length lens 2 of the order of 25 mm for converting a plane-parallel beam from a laser into a light beam diverging to 2-3 °; reservoir 5 for placing a transparent microcopy of the analyzed sesmic section 4; a slit diaphragm 5 intended to limit the light passing through certain parts of a microcopy of a seismic section;

an optical system consisting of two spherical lenses and 7, each of which has a focal length of about 80 cm. The first lens 5 is set at a small distance from the diaphragm 5, and the second lens 7 is set at such a distance from the lens 6 to provide optimal dimensions of the two-dimensional spectrum. The optical system is designed to form a two-dimensional spectrum in its focal plane 8; slit 9 and angular 10 diaphragms for spatial optical filtering of seismic data;

installations for visual monitoring of the optical filtration process, which consists of a sliding mirror, // an acceptable node 12, and a television 13;

Daifragm system 14, which is designed to limit the wave or group of waves, selected by optical filters 9, 10;

slotted diaphragm 15 with a system of micrometer screws for moving the slit along the axis of the in-phase character of the seismic wave under study;

a camera 16 with a mirror 17 for photo-optical recording of the waves allocated for the study, which can be captured on the film 18;

a selenium photocell 19 intended for photoelectric detection of the flux of light passing through the slit of the diaphragm 15;

a photo-compensation amplifier 20 for amplifying the photocurrent developed by the photocell 19;

Registrar 21 photocurrents.

The principle of operation of the proposed device is as follows.

A plane-parallel beam of coherent light from a gas laser is converted by a short-focal lens 2 into a diverging light that is illuminated by tank 3 with a transparent microscopy of seismic section placed in it 4. Aperture 5 limits the area of seismic section that is required. Due to diffraction, secondary light waves, having passed through lenses 6 and 7 of the optical system, form a two-dimensional spectrum in its focal plane 8.

Filters by frequency 9 or by apparent speed 10 select a certain group of waves, the change in the intensity of which must be determined. Allocation process

the waves are controlled by a visual observation system, for which a mirror // is installed in the plane of the reconstructed image of the section, casting the image onto the receiver tube 12, from which the amplified and

the converted signals are sent to the television set 13. After the spatial optical filtering is performed, the mirror 11 is removed.

In the plane of the reconstructed image of the original section, an additional system of diaphragms 14 is installed, which limit the group of waves or a specific wave from the selected group. The slit diaphragm 15 establishes the corresponding slit, on which one or several tracks can be extended (in the case of displacement), and the length corresponds to the time interval being analyzed. The established slit is moved with the help of micrometer screws in the direction along the axis of the hyphasic seismic wave under study, or along any other direction of interest for analysis. The luminous flux corresponding to the position of the slit is reflected from the mirror / 7 of the camera / b and hits on

photocell 19. Wave; which is used for dynamic analysis, can be photographed on film 18

The photocurrents corresponding to the light fluxes are amplified by the Wsi.P1tel 20 and recorded by the recorder 2 /. According to the photoelectric measurements, graphs of the intensity of the seismic waves under study are plotted.

Subject matter

A device for determining the dynamic characteristics of seismic waves, containing ISTO-1NI1K.cohbre: nt1nogo light, the container of the information carrier, the scanning slit and system for ({photoelectric measurements of the intensity of the light flux, characterized in the plane of the reconstructed image of the seismic section has a wedge-shaped diaphragm system installed.