SU1704118A1 - Method of pit seam seismic prospecting - Google Patents

Abstract

The invention relates to mine geophysics methods and is intended for the primary conditions of occurrence of predominantly coal seams. The purpose of the invention is to increase the geological efficiency of the method. The method includes the excitation of seismic waves on the source profile in one mine workout and the registration of transmitted waves in another mine workout with movement of receivers and sources along profiles with a given pitch and seismic recording processing to isolate exploration objects. In the method, the pre-selected information passing waves and on an object similar to the one to be explored and excavated by mining workings, parametric measurements of the selected informative waves are performed along a linear seismic profile passing through the said object. The value of the limiting angle r of the incidence of informative waves on the object of intelligence is determined. The receivers are placed with a pitch Dx L-tg g / n-1. where L is the distance between workings; n is the channel of the recording seismic station. In this case, the excitation is carried out with a step equal to the distance between the reception points, within the section of the profile limited by azimuth viewing angles from the outermost receivers, in the arrangement equal to the limiting angles r of the incidence of informative waves. 1 ill., VI 2

Description

The invention relates to methods for mine geophysics, in particular seismic prospecting, and is intended for prospecting the conditions of occurrence, mainly coal seams and zones of increased rock pressure (PGD) in them, and can be used in other mining industries.

The aim of the invention is to increase the geological efficiency of the method.

The drawing shows a fragment of the observation system.

The drawing shows parallel stratum mine workings 1 and 2. The multichannel distribution (SP) of receivers 3, the line of excitation points (PV). including three blocks 4-6 equidistant from each other

hectares of exploration points, exploration objects, for example, breaking faults of 1.1 and 8.8 in the interval between mine workings, as well as seismic traces of 9 PV-SP of equidistant observations (RUN), explaining the principles of seismic records sorting during the processing of observation materials.

The method is implemented as follows.

Depending on the geological task assigned to the seismic prospecting, the type of informative seismic waves is chosen (for example, if the object of exploration is a rupture fault, then depending on the thickness of the coal seam and the amplitude of the rupture, the lateral SH-waves and channel waves of polarization L are informative. if the object of exploration is postgenetic erosion - lateral longitudinal P, SV - transverse waves and channel waves of polarization of the relay; the same waves are informative also for reconnaissance of watered zones in the roofs of the coal seam or fractured roofs).

At a site similar to explored and opened by mining or explored by other methods (for example, drilling exploration), the speed of the selected informative is determined by known methods, for example, by the method of longitudinal profiling. waves along the linear seismic profile passing through this object: VIP.S - to the object from the point of excitation; V2P, s - on the object.

Calculate the value of the limiting angle of incidence g depending on the type of informative waves used (Vi N / 2):

/ V2P Gpad agS5Sh (-),

/ rn "A arcsln (-),

0) (2)

Calculate the distance between the receiving points.

L tqi- (3)

Dx

rounded the value of Dx to the nearest smaller integer number (n is the channel of the recording seismic station).

An observation scheme is constructed, and then, depending on the exploration task in the field, an observation system determined by geometrical constructions is the length of the excitation line as a section of the profile in the mine workout 1, limited by azimuth viewing angles from the extreme receivers in the arrangement equal to the limiting angles falling t infor

waves The length of the arrangement is taken equal to

5 (p-1) -Dx (A) and then the length of the excitation line Q, consisting of three blocks 4-6, the length of each of which is equal to the length of the receiver array S and contains an equal number of PVs, is

(n- 1) + (Zp- 1) Dx (5)

10 The PV line is symmetrical with respect to the arrangement 3. The step of moving the arrangement of receivers along the profile is assumed to be equal to the length of the arrangement, positioning it without overlapping at a distance x from the previous one.

The first arrangement of receivers 3 is installed on the profile in the mine work 2 and the position of the excitation points is determined in the mine work 1

20 distance Dx from each other (with the excitation points of the high waves in three blocks, each with a length equal to the length of the receivers S, 36).

Consistently from point PV to point PV

25 along the source profile in the mine workout 1, seismic waves are excited and recorded after being received by the seismic station.

The excitation of reservoir waves begin

30 from the outermost (for example, to the left) PV of the block 4. and then sequential excitation of the formation waves in the PV of block 4. Then 5 and 6 and with each excitation, receive and record the transmitted seismic 35 waves with accumulation on the magnetic carrier with using a digital seismic prospecting station (for example, a mine 12-channel. digital, summing seismic SSS-1 Druzhba). Total on

40 each arrangement of the joint venture is processed 36 PW and receive 36 seismic records of passing waves. The source is a mechanical blow to the exposure of the coal seam or a blow to the bottom of the hole, a test in the central plane of the coal seam, a sledgehammer through a metal pin 5 placed in the hole or borehole drummer. The entire stretch of excavated floor, limited to strike

50 seismic rays from the first PF in block 4 to the last PF in block 6 are covered with a dense network of seismic rays.

After the first section has been completed, the alignment 3 is transferred to a new position.

55 7 at a distance equal to the length of the arrangement without overlap, and is located at a distance Dx from the previous one. Similarly, the sequence of operations in the first section of the excavation field is excited

formation waves successively in the new position of the PW excitation lines, which also move symmetrically to the arrangement of receivers. After the second section has been worked out, the spread is transferred to the next 5 position. The combination of the arrangements of the joint venture and the blocks of UW within the excavation floor forms a system of observations.

The processing of seismic observations on a computer is carried out in the following sequence.

The seismic records are sorted according to equidistant observations, as a result of which 15 synthesized RUS seismograms are obtained, each of which is a time section characterizing the conditions of seismic waves passing between the mine workings. 20

By introducing kinematic corrections, all the RUN seismograms lead to a comparable form (to the length of the conversion seismic beam, which is taken by the finest seismic beam), and also introduces 25 corrections for the directivity of sources and receivers of seismic waves in their optimal frequency range.

Band-pass filtering is performed, looking over the optimal null-phase 30 detection filters, and analyzing the results, which determine the optimal frequency ranges of informative seismic waves of various types: lateral longitudinal P and SH or 35 SV-transverse. and interference stratum waves K, distinguish the directions of seismic rays from which irregular waves are recorded, roughly estimate the azimuthal angles of discontinuity, 40 crossed by passing waves, and the optimal time windows for recording informative waves.

Dynamic or seismic wave analysis 45 (SWAN) is performed by interval, which is used to obtain sets of kinematic or dynamic parameters of informative seismic waves. Summary tables of informative parameters of seismic waves and coordinates of 50 points of excitation and reception of seismic waves are compiled.

By processing a set of seismic rays using reconstructive tomography, a detailed picture of the distribution of informative parameters of seismic waves of various types in the field plan is reconstructed, and anomalies under conditions of coal bedding are identified.

The reservoir, which is interpreted in conjunction with a priori geological information about the studied area, determines the position in terms of exploration objects.

Analyzing the set of seismic rays passing through the identified objects of isolation, taking into account the obtained tomograms and tables of parameters, determines the quantitative parameters of the objects of exploration, for example, the values of stratigraphic amplitudes.

If at reception multicomponent registration of various (PS K) wave field components is carried out, then depending on the type of seismic waves taken as informative, according to the results of studies after the selection of seismic records, the degree of disturbance of the coal seam may be assessed by faults and their quantitative parameters, but also the presence of violations of coal seams of other types, such as erosion, deposits on an uneven basement bed, pinches, changes in dip angles (at this Om informative are the parameters of the lateral transverse and stratum waves (VA). fracture (stability) of coal-bearing rocks and their water content (the informative are the parameters of lateral longitudinal and transverse waves and reservoir waves of the Relay), a. also, the qualitatively stressed state of the massif in the interval between the workings (informative - the formation waves of the wave).

Thus, the redundancy of information obtained during the implementation of the method allows, using the seismic scanning method, as a result of research to obtain complete information about the disturbance of the section of the excavation floor: to reveal the existing faults, determine their spatial position and parameters (amplitude), t . most fully solve the task posed to the mine seismic prospecting. This greatly extends its geological efficiency. Repeated seismic rays overlapping the excavated field using the summing seismic station (for example, FSS-1 Druzhba) for registering wave fields allows to completely reject the use of charges of explosives in SMEs of excavation fields with a width of up to 250 m as a source of formation waves of explosive waves. on thin coal seams and use for this purpose mechanical sources of seismic waves that have no restrictions on the use of

mines hazardous from sudden coal and gas emissions, i.e. extend the functionality of the method.

The formula of the invention The method of mine seam prospecting, including the excitation of seismic waves within a given area on the source profile in one mine workout, the registration of passing information waves by the placement of receivers in another mine workings with moving the receiver array and sources along profiles with a given step and processing seismic recordings, distinguished by the fact that, in order to increase geological efficiency by optimizing the conditions of passage nformativnyh waves through the object exploration in the range between workings previously depending on the type of target type selected informative extending waves k obe ones. similar to be explored and opened mine workings, performed -

Parametric measurements of the speed of the selected informative waves along the linear seismic profile, passing through the aforementioned object, which determine the limit value of the angle of inflow of the informative waves per survey object, while the receivers are calculated in steps

Oh

L tgif n - 1

where L is the distance between the workings, n is the channel of the recording from the bridge, and the excitation of seismic waves is carried out with a step equal to the distance between the reception points, in the front of the section of the profile, limited by the azimuth viewing angles from the extreme receptacles equal to the limiting angle of informative waves, occasional / informative waves in the optimal total range of their registration and parameters determine the presence and scope of intelligence objects in the interval between BI flows.

Claims (1)

Claim A method of mine formation seismic exploration, including the excitation of seismic waves within a given area on the source profile in one mine, recording informative waves by arranging receivers in another mine with moving the arrangement of receivers and sources along profiles with a given step and processing seismic records to identify seismic objects, characterized in that, in order to increase geological efficiency by optimizing the conditions for the passage of informative waves through the reconnaissance object in the interval between the workings, preliminary, depending on the type of reconnaissance object, the type of informative transmitted waves at the object is selected. similar to the subject to be explored and uncovered by the mine workings, parametric measurements of the velocity of the selected informative waves are performed along the molar seismic profile, passing through the said obj which determine the limit value! the angle of the inflow of informative waves is not a reconnaissance, while the receivers expand with a step where L is the distance between the workings η is the channel of the recording <bridge, and seismic waves are excited with a step equal to the distance between the points of reception, in the pre section of the profile, limited the azimuthal viewing angles from the extreme receivers in the arrangement equal to the limiting angle of incidence of informative waves, separated / informative waves in the optimal total recording range and n parameters judge the presence and position of reconnaissance objects in the interval between in bi Botko.