RU2097558C1 - Check of stressed-deformed state in block structure of geosphere, base support, deformation meter and register - Google Patents

Abstract

FIELD: mining industry. SUBSTANCE: mobility of geoblocks of various hierarchical level relative to base one is determined with the use of longitudinal deformation meter with immobile base support and automatic register. Blocks of checked level can be selected both by natural geophysical indications and by computation method. Case of base support houses electromagnets with cores and distance pieces in the form of levers with rests inserted for opposite turn. Deformation meter is manufactured in the form of rod fixed in base support and mobile relative to rod of case with distance piece for installation of case on sedimentary rock or bedrock. Radiation sources are placed into rod, case houses radiation detectors to detect and register movement of checked blocks. Register is manufactured in the form of electron device to determine, convert and store information on displacement value in checked blocks with reference to base one. EFFECT: enhanced authenticity of check of stressed-deformed state in block structures of geosphere. 8 cl, 14 dwg

Description

 The invention relates to mining and can be used to control the stress-strain state in block structures of the geomedium.

A known method of monitoring the stress-strain state of a rock mass, including the allocation of block boundaries, the installation of strain meters in each block and the determination of the mobility of the enclosing rocks, depending on the technological cycle of mining operations [1]
The disadvantages of the method are the lack of criteria for highlighting the boundaries and determining the size of the blocks, the impossibility of allocating the base unit and determining the distances for choosing the location of the strain gauges when monitoring the mobility of geoblocks, the dependence of the measurements on the technological cycle of mining operations.

Closest to the proposed one is a method of controlling the stress state of a rock massif, which consists in measuring the axial deformation of the well between two benchmarks installed within natural blocks of a higher level, the dimensions and location of which are determined when drilling a well with sampling [2]
The disadvantages of the method are the lack of selection criteria for the structure of the controlled blocks, the complexity and inaccuracy of determining the size of the blocks and the location of the boundaries between them by core sampling, the inability to allocate a base unit for setting the reference frame and setting the distances between deformometers used to control the mobility of a group of geoblocks.

 The purpose of the invention is to increase the accuracy and reliability of determining the mobility of geoblocks.

а подвижность блоков определяют путем измерения смещений деформометров относительно базовой опоры.The problem is solved in that in a method for monitoring the stress-strain state of block structures of the geosphere, including determining the boundaries of blocks, measuring strains in them using a device for measuring strains, consisting of strain meters connected to the recorder, and determining and registering the mobility of the blocks, set the rank i controlled blocks allocated to the object block with zero grade, taking it as a base for each controllable unit, determine the size of the base and controlled ^° Δ b shackles ⁱ Δ, each block boundary is determined from the relationship:
ⁱ Δ = ^° Δ • 2 ′ (m),
where i 0, ± 1, ± 2, ± 3, and the deformation is measured in each block relative to the base block, while the support with a fixed rod is installed in the base block, the strain meters are set movably relative to the rod and rigidly fixed inside each block of the ith rank on the distance from each other, determined from the ratio:
l _i = ⁱ Δ + δ _i (m),
where δ _{i the} magnitude of the opening of cracks between adjacent blocks

and the mobility of the blocks is determined by measuring the displacements of the strain meters relative to the base support.

 The rank i of the monitored blocks is set, which allows you to coordinate the selected structure of the monitored object with the installation scheme of strain meters and thereby increase the reliability of measurements.

 A block with a zero rank is isolated on the object, which allows one to determine the block with respect to which strain is measured, and thereby increase the reliability of measurements.

 A block with a zero rank is taken as the base for each controlled block, which allows you to control the deformation of blocks of a given rank at the same time and thereby increase the accuracy and reliability of measurements.

The dimensions of the base ^° Δ and the controlled blocks ⁱ Δ in meters are determined, which makes it possible to distinguish blocks with respect to which mobility is determined, and thereby increase the reliability of measurements.

The boundary of each block is determined from the relation ⁱ Δ = ^° Δ • 2 ⁱ , which makes it possible to distinguish the sizes of blocks of the ith rank, the mobility of which is determined, and thereby increase the accuracy and reliability of measurements.

 Deformations are measured in each block relative to the base unit, which allows you to determine the mobility of the controlled blocks independently and thereby increase the reliability of the measurements.

 In the base unit, a base support with a fixed rod is installed, which allows you to fix the reference point of reference blocks mobility and thereby improve the accuracy and reliability of measurements.

 Deformometers are installed movably relative to the rod, which ensures the use of a common reference point for a group of deformometers and allows to increase the accuracy and reliability of determining the mobility of blocks.

в метрах, что позволяет устанавливать деформометры в расчетных точках геосферы и тем самым повышать точность и надежность измерений.Deformometers are rigidly fixed inside each block of the i-th rank at a distance from each other, determined from the relation l _i = ⁱ Δ + δ _i , where δ _{i is the} magnitude of the opening of cracks between adjacent blocks

in meters, which allows you to install strain gauges at the calculated points of the geosphere and thereby increase the accuracy and reliability of measurements.

 The mobility of the blocks is determined by measuring the displacements of the strain gauges relative to the base support, which allows you to measure and record the movement of both a single block and a group of blocks at the same time, thereby increasing the accuracy and reliability of measurements.

 In FIG. 1 shows the block structure of the geosphere, a longitudinal section, and shows the placement of the base support and deformometers in blocks of a controlled level.

 The method is as follows.

Предлагаемый способ может быть осуществлен следующим образом.In the well 1 intersecting the blocks 2, 3, 4, 5, n of the controlled rank and the base block 6 of the zero rank, a base support 7 is installed, which is rigidly connected to the rock of the base unit 6. A rod 8 is rigidly attached to the support 7, on which it is movably mounted deformometers relative to the rod 9. Each deformometer 9 is rigidly fixed in the i-th block of a controlled rank at a distance l _i ≃ ⁱ Δ + δ _i from each other and attached to a common registrar 10. The magnitude of crack opening is determined from the ratio

The proposed method can be implemented as follows.

In the area of planned control by a known method (for example, using the spectral method described by V. N. Oparin. To the basics of borehole geophysical flaw detection. 1: Spectral analysis and defective measures. // Physical and technical problems of mining. 1982, N 6 , pp. 23-33) both by natural geophysical features and by calculations (for example, using the methodology described by VN Oparin, MV Kurleni. On the velocity section of the Earth according to Gutenberg and its possible geomechanical explanation. 1: Zone Surveyor station and hierarchical series of geoblocks // Physicotechnical Problems of Mineral Development 1994, N 2) determine the rank of i controlled blocks 2, 3, 4, n, the mobility of which must be determined, determine the block structure of the geosphere and distinguish blocks of zero rank. As the base block 6 take, for example, the next block of the zero rank following the controlled one. The dimensions of the base ^° Δ and the controlled blocks ⁱ Δ, set in meters, as well as the position of the boundary between them, are calculated using the relation ⁱ Δ = ^° Δ • 2 ⁱ (m). Through the controlled units 2, 3, 4, 5, n and the base unit 6 in a known manner using a drilling rig to build a horizontal well 1.

Подвижность блоков контролируемого ранга определяют путем измерения смещений деформометров 9 относительно штанги 8, жестко соединенной с базовой опорой 7. Результаты измерений фиксируют при помощи регистратора 10.In the well 1, inside the base unit 6, a base support 7 is installed with a rod 8 passing through the controlled units 2, 3, 4, 5, n. Each deformometer 9 is mounted movably relative to the rod 8 and is rigidly fixed inside each controlled unit 2, 3, 4, 5, n at a distance from each other, determined from the relation l _i ≃ ⁱ Δ + δ _i (m), where the crack opening between adjacent blocks is taken by the expression

The mobility of the blocks of a controlled rank is determined by measuring the displacements of the strain gauges 9 relative to the rod 8, rigidly connected to the base support 7. The measurement results are recorded using the recorder 10.

A device for mounting sensors in a well is known, comprising locking cams, a locking device with a piston, connecting rods, a travel stop, an explosive microcharge with a detonator capsule and a loading piston [3]
The disadvantage of this device is the use of a loading piston, fixing devices and micro-charge, which complicates the design, requires the construction of two coaxial wells, complicates multiple installation and limits the use of the device for controlling deformations in block structures of the geosphere.

Closest to the proposed is a device for installing strain gauges in a well, including a housing with covers, a sleeve, a connector with a cable, a nozzle, fixed and movable tubes, expansion and locking rods, a clamp, a stopper, a cable, spring-loaded couplings and sliders [4]
The disadvantage of this device is the use of tubes, clamps, stoppers, locking rods, couplings and a cable to prepare for work, which complicates the design of the device, complicates its operation during repeated use due to the need to cock the mechanism of the spacer rods manually, does not provide basic mounting of sensors along the wellbore when installation in block structures of the geosphere.

 The purpose of the invention is the provision of remote control and increased reliability of fastening the base support in the well.

 The problem is solved in that in the base support, which includes a housing with covers, a connector with a cable, spacers, sliders, springs and rods connecting the spacers with sliders, the support is equipped with electromagnets installed in the housing with cores, a glass with a Central hole and a longitudinal groove, each core is connected to a slider inserted into the Central hole of the glass with the possibility of reciprocating movement, and each spacer element is made in the form of a rotary about the lever with a stop and a retainer and is installed with the ability to move the stop through a longitudinal groove.

 The base support is equipped with electromagnets with cores installed in the housing, which allows remote control and increases the reliability of fixing the base support when installed in the well, and also simplifies its operation.

 At each end of the case, a glass with a central hole and a longitudinal groove is fixed, which helps protect the electromagnets from damage and thereby increase the reliability of fixing the base support.

 Each core is connected to a slider inserted into the central hole of the glass with the possibility of reciprocating movement, which allows the spacer element to be moved using the core and thereby provides remote control and increases the reliability of fixing the base support in the well.

 Each spacer element is made in the form of a rotary lever with a stop and a retainer and is installed inside the cup with the possibility of moving the stop through a longitudinal groove, which allows you to convert the slide movement into a lever turn until the stop contacts the borehole walls and thereby ensures the reliability of the base support fastening. To exclude accidental displacements of the support along the wellbore, it is advisable to install the levers in such a way that the stops create locking forces in opposite directions.

 In FIG. 2 shows a diagram of a base support; figure 3 view a in figure 2; in FIG. 4 node I in figure 2; in Fig.5 node II in Fig.3; Fig.6 section BB in Fig.5.

 The base support contains two electromagnets 11 installed in a cylindrical housing 12 and attached to it with support washers 13 and screws 14. The electromagnets 11 are isolated from one another by a gasket 15. Inside each electromagnet 11, a stopper 17 of the core 16 is installed. Each the core 18 is inserted with a free end into the electromagnet 11 with the possibility of movement up to the limiter 17. From the opposite end to the core is attached, for example, by a threaded connection, the slider 19.

 Each glass 20 is made with a central hole and a longitudinal groove, mounted on the end of the housing 12 and connected to it with screws 21. A slider 19 is inserted into the central hole of the glass 20. A spring 22 is installed on each slide 19 inside the glass 20, which is held by the bottom of the glass 20 and a protrusion 23. Each slider 19 using a movable rod 24 and the axles 25 is connected to a pivot arm 26, which is equipped with a stop 27 and movably fixed using the axis 28 in the retainer 29. The stop 27 (figure 4) can be made in the form of a segment 30 with an envelope of elliptical shape and s bchatoy notch 31. Osederzhatel 29 secured within cup 20 by means of screws 32. The focus 27 may be moved through the longitudinal slot nozzle 20.

 A centering insert 33 is attached to the free end of each glass 20, attached by screws 34. Outside, caps 35 are attached to the ends, secured by screws 36.

On one of the covers 35, a connector 37 is installed for rigidly connecting the rod to the support and connecting electromagnets 11 to an electric current source (not shown) using conductor 38. On each glass 20, two fixed supporting spikes 39 are installed (Fig. 3). The emphasis 27 of the lever 26 and the spikes 39 are located relative to each other at an angle of 120 ^o C.

 The spike 39 can be made in the form of a cone (figure 3) or a multifaceted prism 40 (figure 5, 6).

 The proposed basic support works as follows.

 After connecting to an electric current source (not shown), the electromagnet 11 retracts the core 18, which moves inside the electromagnet 11 all the way into the limiter 17 and is held in this position until the electromagnet is turned off. When retracting, the core 18 moves the slider 19, which by the protrusion 23 compresses the spring 22 and moves the rod 24. The rod 24 rotates the lever 26, while the emphasis 27 is shifted into the nozzle 20. Then the support is installed in the well using a rod (not shown). At the calculated point, the electromagnet 11 is de-energized, the core 18 is released from the action of electromagnetic forces, the slider 19, under the action of the spring 22, begins to move inside the cup 20 and, by means of the traction 24, turns the lever 26 around the axis 28. The stop 27 of the lever 26 through the longitudinal groove of the cup 20 engages with the wall of the well, providing with the help of spikes 37 a stable connection with the rock. Reliability of support mounting is enhanced by the use of two counter-oriented levers 26, which create locking forces in the opposite direction.

A device for registering places of deformation of a rock mass, including strain transformers in the form of electrical resistances made of thin tubes with conductive material deposited on them, and a recorder made in the form of numbered indicator elements [5]
The disadvantage of this device is the use of electrical resistances made of thin tubes coated with conductive material, and indicator elements, which leads to the destruction of the transducer during deformation of the array and does not allow to determine and record the strain amplitude.

Closest to the proposed is a device for photoelectric strain measurement, including a housing with channels, a rod, photocells connected by a metal tape, a light source, a prism, a spring, an adjusting screw and a recorder [6]
The disadvantages of the device are the connection of photocells with a metal tape, adjustment of the design range with the adjusting screw, and fixing the rod with a locking screw, which requires additional adjustment to the design range of measurements when moving the device, does not allow measuring the strain amplitude, limits sensitivity and complicates the operation of the device.

 The purpose of the invention is to increase the accuracy, sensitivity and reliability of measurements.

 The problem is solved in that in the deformometer including the housing and the rod installed in it, the radiation sources and receiver and the spacer assembly, the housing is mounted movably relative to the rod, the rod is provided with side holes, each radiation source is placed inside the rod opposite the side hole, the radiation receiver is made in in the form of a line of sensitive elements equipped with an electronic output and fixed in the housing opposite the side holes of the rod, and the spacer assembly consists of a support element, an eccentric with zhinoy and the movable rod with a hinge joint at each end extending through the support member and the housing parallel to the rod, wherein the eccentric is mounted in the support member, which is rigidly attached to the housing.

 The housing is mounted movably relative to the rod, which provides a displacement of the strainmeter both relative to the rod and relative to the base support, rigidly connected to the rod, and thereby improves the accuracy and reliability of measurements.

 The rod is provided with side holes, and each radiation source is placed inside the rod opposite the side hole, which allows you to create radiation from the source in the form of a pointed beam with minimal scattering and thereby increase the accuracy and sensitivity of measurements.

 The radiation receivers are made in the form of a line of sensitive elements equipped with an electronic output and mounted in the housing opposite the side holes of the rod, which allows you to set sensitive elements with a given interval relative to each other, provides electrical signals from sensitive elements and thereby increases the accuracy, sensitivity and reliability of measurements .

 The spacer assembly is made in the form of a support element, an eccentric with a spring, and a movable rod with a hinge at each end passing through the support element and the housing parallel to the rod, the eccentric mounted in the support element, which is rigidly attached to the housing, which allows each to be fixed in the rock mass deformometer individually and thereby increase the accuracy and reliability of measurements.

 To increase the reliability and stability of the fastening of the deformometer in rocks, it is advisable to carry out the support element in the form of a disk with support spikes, and for fastening in sedimentary rocks in the form of a multifaceted prism.

 To increase the accuracy and sensitivity of measurements, it is advisable to perform each radiation source in the form of a radiative LED, and receivers in the form of a monolithic line of photosensitive elements.

 7 shows a strain meter, a longitudinal section; in Fig. 8 a section BB in fig. 7; in Fig.9 section GG in Fig.7; figure 10 section DD in figure 7; in FIG. 11 section EE in figure 10; in Fig.12 section FJ in Fig.7; in Fig.13 is the same as in Fig.8 (option).

 The strain gauge comprises a cylindrical body 41, inside of which a rod 42 passes, made in the form of a pipe with side holes 43. A hinge connector 44 is installed at each end of the rod 42, radiation sources 45 are rigidly fixed inside the rod 42 against the side holes 43 and connected to the rod 42 by plates 46 and screws 47. Opposite the side holes 43 of the rod 42 on the board 48, radiation detectors 49 are installed in the line. The board 48 is rigidly mounted inside the housing 41 using screws 50 (figure 10). An insert 51 is inserted from each end into the housing 41 and is attached to the housing 41 by screws. Outside, each end of the housing 41 is closed by a lid 52.

 The spacer assembly comprises a support element 53 in which a rotary sleeve 54 is mounted with an eccentric 55 fixed thereon. A flat coil spring 56 is installed along the profile of the eccentric 55. Through the sleeve 55, the support element 53 and the housing 41, a movable rod 57 provided with parallel to the rod 42 a swivel 58 mounted at each end. Each support element 53 is rigidly attached to the housing 41 by means of struts 59.

 The housing 41 with support elements 53 is mounted movably relative to the rod 42 in the longitudinal direction. The rod 57 is mounted rotatably inside the housing 41.

 The supporting element 53 can be made in the form of a disk with supporting spikes 60 (Fig. 8) or in the form of a multifaceted prism 61 (Fig. 13).

 The radiation source 45 can be made in the form of a radiating LED 62 (Fig), and the receivers 49 are made in the form of a monolithic line of photosensitive elements.

 The proposed deformometer works as follows.

 The housing 41 of the strain gauge is mounted on the rod 42, which is connected to the base support 6 (Fig. 1) using the hinge connector 44 and is fixed at the calculated point of the wellbore. When installed in the well, the protrusions of the eccentrics 55 must be turned inward, i.e. to the rod 42, so as not to impede the movement of the strainmeter along the wellbore. To fix the strainmeter in the well, the rod 57 is rotated around its axis. The eccentrics 55, when deployed, come into contact with the wall of the well and move the supporting elements 53 and the housing 41 in the transverse direction until the studs 60 abut against the walls of the well. For a uniform preload, each eccentric 55 is equipped with a spring 56, which, when the calculated force is reached, bends, providing a reversal of the opposite eccentric. In the case of installation in sedimentary rocks, it is advisable to use a multifaceted prism 61 as a supporting element, which provides a more efficient grip.

 In the case of installing a group of strain meters, each subsequent module is connected using the hinge connector 44 on the rod 42 and the swivel 58 on the rod 57. After installation in the well and connected to the recorder, the device is ready for operation.

 Direct measurements consist in the fact that each radiation source 45 through the hole 43 sends a pointed beam to the line of receivers 49. Since the base support 7 (Fig. 1) is fixed motionless in the base unit 6 and is rigidly connected to the rod 42 (Fig. 7), and the casing 41 of the strainmeter is installed relative to the rod 42 and is fixedly mounted in the i-th controlled unit, which is separated by cracks from the base unit 6, then in the case of longitudinal movements of the controlled unit relative to the base unit 6, the casing 41 of the deformometer along the rod 42. Accordingly, the line of receivers 49 is shifted relative to the holes 43, which will be recorded and decoded in the recorder in the form of a signal proportional to the displacement of the monitored unit.

Known recorder containing an electronic voltage meter and calibration schedule [6]
The registrar's disadvantage is the use of a voltage meter and a calibration graph, with which deformations are determined by the voltage difference, which complicates the operational processing and accumulation of information with large volumes of measurements.

Closest to the proposed one is a recording unit containing amplifiers, a recording device, a comparator, peak detectors, a counter, a trigger, a recording signal shaper, an analyzer, an analog-to-digital converter, a memory subunit, LEDs for indicating the address, controls and a remote indication unit for gas discharge indicators [7]
The disadvantage of the display unit is the presence of an amplifier, an analog-to-digital converter, a recording device, a memory subunit, a remote display unit, LEDs for indicating the address, which does not allow registering deformations in a group of geoblocks, requires conversion of the positional binary address code to decimal for visual control, and reduces accuracy measurements, limits the reliability of recording information and complicates the operational work with the device.

 The purpose of the invention is to increase the processing efficiency and reliability of the accumulation of information when measuring strains in a group of geoblocks.

 The problem is solved in that in the recorder, which includes a power supply unit, a measuring probe containing an amplifier, transmitter and radiation receiver, and a registration unit, consisting of an indication unit, an operating mode shaper and a memory subunit, the measuring probe is equipped with request signal shapers and control pulses, address decoder, binary counter and series-connected switch, comparator, write pulse generator, data storage register and encoder, the registration unit is equipped with a gene a clock pulse generator, an address shaper, a signal decoder, a multiplexer, a data logger, an encoder and a tape recorder, a transmitter in the form of a radiation source connected to a power source, the receiver is made in the form of a line of sensitive elements, and the memory subunit is made in the form of random access memory, while in the measuring probe, the output of the line of sensitive elements is connected to one of the inputs of the switch, to the second input of which one of the outputs of the binary counter is connected, the second and third the outputs of which are connected respectively to the input of the driver of control pulses and to the second input of the data storage register, the outputs of the driver of control pulses are connected respectively to the input of the radiation receivers and to the second input of the driver of recording pulses, to the third input of which one of the outputs of the driver of the recording signal is connected, to the input which is connected to the output of the address decoder, and the second, third and fourth outputs of the query signal generator are connected respectively to the third input of the register data storage, to the second input of the encoder and to one of the inputs of the amplifier, to the information input of which the output of the encoder is connected, the output of the amplifier is connected to the information input of the decoder of the signal of the registration unit, the inputs of the binary counter and decoder of the address are connected respectively to the output of the clock generator of the registration unit and the output of the address shaper, and in the registration unit, the signal decoder, random access memory, multiplexer, data storage register and display unit are connected sequentially, and to their second inputs, to the third inputs of the multiplexer and random access memory and to one of the inputs of the address shaper, the outputs of the shaper of operating modes are connected, the second output of the clock generator is connected to its input, and its third input is connected to the second input of the address shaper, and the second output of the data storage register through the encoder is connected to the tape recorder.

 Providing the probe with shapers of the request signal and control impulses of the address and a binary counter allows you to synchronize the polling sequence of the measuring probes in the group and provides address data transfer, which increases the processing efficiency and reliability of information storage when measuring strains in geoblocks.

 Providing the probe with serially connected commutator, comparator, and recording pulse generator allows you to compare the electrical signal of the measured parameter with the reference signal and generate a binary-decimal code of the measured parameter, which increases the efficiency of data processing when measuring deformations of geoblocks.

 The supply of the probe with the register provides the selection and storage of the current value of the measured parameter until a request for information transfer to the registration unit, which increases the reliability of data storage during strain measurements.

 Providing the probe with an encoder provides the conversion of the encoded data to a form convenient for transmission to the registration unit, which increases the efficiency of transmitting information about deformations of geoblocks.

 The supply of the registration unit with a clock generator and an address generator allows you to synchronize the sequence of polling of measuring probes in time and provides targeted data reception, which increases the efficiency of processing and reliability of information storage when accumulating data on geoblock deformations.

 The supply of the recording unit with a signal decoder, a multiplexer and a data storage registrar converts the data received from the measuring probes into a binary code, allows you to remember the data in the register and transfer this data to a memory subunit, which ensures the speed of processing and reliability of storage of information about deformations of geoblocks.

 The supply of the registration unit with an encoder and a tape recorder provides the conversion of encoded data to a form convenient for recording on a long-term storage medium, which increases the reliability of long-term storage of data on deformations of geoblocks.

 The implementation of the transmitter in the form of a radiation source connected to a power source eliminates the mechanical connection between the strainmeter body and the rod and allows you to continuously send a beam to the radiation receiver, which ensures the efficiency of information processing during deformation of geoblocks.

 The implementation of the receiver in the form of a line of sensitive elements allows you to continuously monitor the deviation of the beam when moving the strainmeter body in case of deformation of the i-th geoblock relative to the base geoblock, since the radiation source is connected to the base geoblock by a rod and base support, and the receiver, mounted in the strainmeter body, by the support element is rigidly connected to the i-th geblock, which ensures the efficiency of processing information about deformations of geoblocks.

 The implementation of the memory subunit in the form of random access memory allows you to accumulate and pre-process data on the deformations of the controlled group of geoblocks in a given time interval, which ensures the efficiency of processing and reliability of storage of information about the deformation of geoblocks.

 On Fig shows a functional diagram of the registrar.

 The registrar contains a measuring probe, which includes a radiation transmitter 63 installed inside the rod 42 (Fig. 7), a radiation receiver 64 installed on the board 48 inside the housing 41 (Fig. 7) of the i-th strainmeter, and a recording unit 65, which is placed in a separate housing 10. The registration unit 65 is connected to the radiation receiver 64 using a cable 66 and connectors 67 and is connected to the power supply unit 68.

 The radiation transmitter 63 comprises a radiation source 69, the input of which is connected to a power source 70. The output of the radiation source 69 is a pointed beam 71.

 The radiation receiver 64 is made in the form of a line of 72 sensitive elements having a common control input connected galvanically to the output of the control pulse generator 73. The information inputs of the line 72 of sensing elements are in optical communication with the radiation source 69 by means of a highly directional beam 71, and a common information output is connected to one of the inputs of the switch 74.

 The output of the switch 74 is connected to the input of the comparator 75, the output of which is connected to one of the inputs of the shaper 76 of the recording pulses, and its second input is connected to the output of the shaper 73 of the control pulses. The output of the shaper 76 of the recording pulses is connected to one of the inputs of the register 77 data storage. The output of the data storage register 77 is connected to the input of the encoder 78, the output of which is connected to the information input of the amplifier 79. The second input of the switch 74, the control input of the control pulse generator 73 and the second input of the data storage register 77 are connected respectively to the first, second, and third outputs of the binary counter 80 .

 The radiation receiver 64 also includes an address decoder 81, the output of which is connected to the input of the request signal generator 82. The first, second, third and fourth outputs of the query signal generator 82 are connected respectively to the third inputs of the recording pulse generator 76 and the data storage register 77, with the second input of the encoder 78 and the control input of the amplifier 79.

 The registration unit 65 comprises a clock generator 83, the first, second, and third outputs of which are connected respectively to the input of the binary driver 84 of the operating modes and the second input to the driver 85 of the addresses. The outputs of the address generator 85 through a cable 66 and connectors 67 are connected to the inputs of the address decoder 81, and the information input of the signal decoder 86 is connected to the output of the amplifier 79. The output of the signal decoder 86 is connected to the first input of the random access memory 87, the output of which is connected to the first input of the multiplexer 88 The output of the multiplexer 88 is connected to the first input of the register 89, the first output of which is connected to the first input of the display unit 90, and the second output is connected to the input of the encoder 91. The output of the encoder 91 is connected to the input 92. agnitofona generator 84 outputs the mode connected to the first input of the address 85, the second inputs of the decoder 86 a signal, the random access memory 87, multiplexer 88, register storage 89 and display unit 90 and the third inputs of the random access memory 87 and multiplexer 88.

 Block 65 registration allows you to connect and process information from a group of measuring probes containing transmitters 63 and receivers 64 of radiation.

 The proposed recorder operates in manual and automatic control modes.

 The manual control mode allows you to set the number of polled measurement channels (measuring probes in the group), determine the time interval between channel polls, set the operation mode with a tape recorder, and monitor information about array deformations by the indicator.

 The automatic control mode allows you to poll the specified measurement channels, accumulate measurements on each channel, overwrite information from random access memory to a tape recorder.

 The measuring probe operates in two modes: measurement mode and data transfer mode. When shifts of the ith geoblock occur, the line 72 of sensitive elements moves relative to the beam 71 generated by the radiation source 69. The sensitive element of the line, to which the pointed beam 71 hits, converts the radiation into an electrical signal, which through the switch 74 is fed to a comparator 75, where a comparison is made with the reference signal.

 When the signals coincide, the number of the interrogated sensitive element of the line 72 is determined. The frequency of the survey and the scanning order of the elements of the line 72 are set by the control pulse generator 73.

 The signal from the comparator 75 is supplied to the shaper 76 of the recording pulses, where it is converted in a form convenient for recording in the storage register 77. The signal generated as a result of moving the ruler 72 relative to the beam 71 is accumulated in the form of a binary code in the data storage register 77, where it is stored until a request signal arrives from the registration unit 65.

 The operation of the registration unit 65 consists in periodically interrogating a group of measuring probes and accumulating the received information. The polling sequence is set by the generator 83 clock pulses and the shaper 84 modes of operation. The request signal of measurement data from the i-th probe is generated by the address generator 85, from where it is transmitted to the decoder address decoder 81, where the control signal is decrypted and starts the operation of the request signal generator 82. In this case, information from the register 77 is transmitted to the encoder 78, where it is converted into a serial code convenient for transmission over the communication channel. The serial code through the amplifier 79 and the communication cable 66 is transmitted to the signal decoder 86 of the registration unit 65, where it is converted to a parallel binary code and stored in the random access memory 87. At the same time, the measurement address determined by the generator 84 of the operation modes is fixed.

 When filling in random access memory 87, the moderator 84 includes a tape recorder 92 for overwriting information. In this case, the data from the random access memory 87 through the multiplexer 88 are transferred to the register 89, from where using the encoder 91 are converted into a serial code and recorded on the tape recorder 92 for storage and further processing.

 Visual control of the data is provided by the display unit 90, which allows to display the operating mode, the address of the measurement channel and the measurement data on this channel.

 Work in automatic mode allows continuous monitoring of the state of geoblocks in the rock mass. The capabilities inherent in the registrar circuit allow you to use a computer to process information. The operation of the device does not require highly qualified personnel and can be carried out by one person, the bulk of the work associated with the installation of the device, and operation in automatic mode requires only periodic monitoring.

Claims (8)

1. A method for monitoring the stress-strain state in block structures of the geosphere, including determining the boundaries of blocks, measuring strain in them using a device for measuring strain, consisting of strain meters connected to a register, and determining and registering the mobility of the blocks, characterized in that they set the rank i controlled blocks allocated to the object block with zero grade, taking it into, determine the size of the base ^° Δ and controlled units as the base for each controlled unit to the boundary of ⁱ Δ Each unit requires is determined by the relation
ⁱ Δ = ^° Δ • 2 ′, m,
where i 0, ± 1, ± 2, ± 3,
and the deformation is measured in each block relative to the base unit, while the base support is installed in the base unit with a fixed rod, the strain gauges are set movably relative to the rod and rigidly fixed inside each block of the ith rank at a distance from each other, determined from the relation
l _i = ⁱ Δ + δ _i , m,
where δ _i - the magnitude of the opening of cracks between adjacent blocks

and the mobility of the blocks is determined by measuring the displacements of the strain meters relative to the base support.  2. Basic support, including a housing with covers, a connector with a cable, spacers, sliders, springs and rods connecting spacers with sliders, characterized in that it is equipped with electromagnets installed in the housing with cores, a glass with a central a hole and a longitudinal groove, each core is connected to a slider inserted into the Central hole of the glass with the possibility of reciprocating movement, and each spacer element is made in the form of a rotary lever with emphasis and holder and installed with the ability to move the stop through the longitudinal groove of the glass.  3. The support according to claim 2, characterized in that the levers are installed with the possibility of oncoming turn, and each emphasis is made in the form of a segment with a notch and an envelope of elliptical shape.  4. A strainmeter including a housing and a rod installed therein, radiation sources and receiver, and a spacer assembly, characterized in that the housing is movably mounted relative to the rod, the rod is provided with side holes, each radiation source is placed inside the rod opposite the side hole, the radiation receiver is made in the form linearly sensitive elements equipped with an electronic output and mounted in the housing opposite the side holes of the rod, and the spacer assembly consists of a support element, an eccentric with a spring and movably a rod with a hinge joint at each end extending through the support member and the housing parallel to the rod, wherein the eccentric is mounted in the support member, which is rigidly attached to the housing.  5. Deformometer according to claim 4, characterized in that the supporting element is made in the form of a disk with supporting spikes.  6. Deformometer according to claim 4, characterized in that the supporting element is made in the form of a multifaceted prism.  7. A strain meter according to claim 4, characterized in that each radiation source is made in the form of an LED, and the receivers are made in the form of a monolithic line of photosensitive elements.  8. A recorder including a power supply unit, a measuring probe containing an amplifier, transmitter and radiation receiver, and a recording unit consisting of a display unit, an operating mode shaper and a memory subunit, characterized in that the measuring probe is equipped with request signal and control pulse shapers, a decoder addresses, binary counter and connected in series by a switch, a comparator, a pulse shaper, a data storage register and an encoder, the registration unit is equipped with a clock generator pulses, by a shaper of addresses, a signal decoder, a multiplexer, a data storage register, an encoder and a tape recorder, the transmitter is made in the form of a radiation source connected to a power source, the radiation receiver is made in the form of a line of sensitive elements, and the memory subunit is made in the form of random access memory, when in the measuring probe, the output of the line of sensitive elements is connected to one of the inputs of the switch, to the second input of which one of the outputs of the binary counter is connected, the second and the third outputs of which are connected respectively to the input of the driver of control pulses and to the second input of the data storage register, the outputs of the driver of control pulses are connected respectively to the input of the radiation receiver and to the second input of the driver of recording pulses, to the third input of which one of the outputs of the driver of the request signal is connected, to the input of which is connected to the output of the address decoder, and the second, third and fourth outputs of the request signal shaper are connected respectively to the third input the data storage wizard, to the second input of the encoder and to one of the inputs of the amplifier, to the information input of which the encoder output is connected, the output of the amplifier is connected to the information input of the decoder signal of the registration unit, the inputs of the binary counter and decoder addresses are connected respectively to the output of the clock generator of the registration unit and with outputs of the address generator, moreover, in the registration unit, a signal decoder, random access memory, multiplexer, data storage register and display unit with are connected sequentially, and to their second inputs, to the third inputs of the multiplexer and random access memory and to one of the inputs of the address shaper, the outputs of the shaper of operating modes are connected, the second output of the clock generator is connected to its input, and its third output is connected to the second input of the address shaper , and the second output of the data storage register through the encoder is connected to the tape recorder.

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