RU2164575C1 - Device for measurement of ground cryosaltfluctuation displacement - Google Patents

Abstract

FIELD: devices for measurement of ground cryosaltfluctuation displacement; applicable in measurement of ground deformation on slopes in regions of cryolite zones. SUBSTANCE: essence of the invention consists in installation of two bench marks into ground, hollow rods with plates and marks. Tubes are fitted on hollow rods to prevent freezing of rods together with overlaying heaving ground. Deformations are measured by means of rods and flexible cords attached to marks. EFFECT: higher accuracy of measurement of ground displacement values in depth in region of cryolite zone. 1 dwg

Description

 The invention relates to construction, and in particular to devices for measuring soil deformations on slopes, and can be used to determine the mechanism, dynamics and patterns of development of cryogenic heaving, precipitation, cryosolifluction, the knowledge of which is necessary for the design and normal operation of engineering structures.

 There is a known differential heinometer installation (DPU) containing two rappers, a block, rods with plates, and the rods are located in tubes (see Guidelines for the stationary study of cryogenic physical and geological processes. Scientific ed. S.E. Grechishchev and V.L. Non-Evening. -M .: VSEGINGEO, 1979, 72 pp.).

 The disadvantage of the differential heaving unit is its limited functionality, which does not allow measuring the full range of soil deformations on slopes in the cryolithozone area.

 The closest analogue to the claimed invention is a differential solifluction-diffuser unit (DSPU) containing two rappers, a block, rods with plates, the rods being located in the tubes, grades, measuring cords (see Petrov BC and others. Complex geocryological study of the territory of the Udokan GOK Report, Chita, 1984.- 127 pp.).

 The disadvantages of the differential solifluction-borehole installation are: inaccuracy in measuring the magnitude of displacement deformations, due to the fact that the length of the measuring cord during normal deformations (heave-sediment, swelling-shrinkage) changes without the participation of soil displacement deformations on slopes; inaccuracy in measuring the magnitude of displacement strains caused by the fact that the length of the measuring cord changes not only with displacement strains of the soil layer containing the grade, but also with displacement strains of the soil layer located between the bottom edge of the tube and the plate; the inaccuracy in measuring the magnitude of displacement strains caused by the fact that the part of the measuring cord located between the bottom edge of the tube and the plate during the course of normal deformations takes a complex configuration, since the tube experiences normal deformations from all overlying layers of heaving soil, and the plate only from one.

 The present invention improves the accuracy of measuring the magnitude of the displacement of soils along the depth of the deforming layer, necessary for their reliable forecast and the correct choice of methods for managing them during the economic development of the permafrost zone.

The specified technical result is achieved by the fact that in the known differential solifluction-diffuser unit (containing two rappers, a block, rods with plates, the rods are located in tubes, grades, measuring cords, thin tubes are used as rods, while their ends located beneath the plates, bent at an angle of 90 ^o , and the measuring cords are located in the hollow space of thin tubes.

 Using a thin tube as a rod and placing a measuring cord in its hollow space eliminates the inaccuracy in the measurements of displacement strains caused by the development of normal strains (when applying the prototype, the error reached 400%). This result is achieved in that the magnitude of the bias deformations is fixed by changing the length of the measuring cord relative to the upper edge of the thin tube, which is involved in normal deformations, and not relative to the fixed block, as in the prototype. Therefore, changes in the length of the measuring cord during the development of normal deformations, without the participation of displacement deformations, do not occur.

 In addition, the inaccuracy in measuring the magnitude of the displacement deformations caused by the action on the measuring cord of a deforming layer of soil located between the bottom edge of the tube worn on the rod and the plate is eliminated.

 Bending the lower end of a thin tube (with filling it with technical vaseline) allows you to reduce the amount of friction of the measuring cord on its wall to values that can be neglected. As practice has shown, the adhesion of the measuring cord to the bottom edge of the straight (without bending the lower end) thin tubes is so great that the marks do not participate in displacement deformations.

 The installation of benchmarks along the slope and the parallel mounting of the beam lead to an increase in the accuracy of measuring normal deformations of soils on the slope.

 The drawing shows a section of a device for measuring cryosolifluctural displacement of soils.

 The design of the device (see drawing) includes two non-bulging benchmarks 1, a block 2 attached to them, thin tubes 3 with plates 4, tubes 5 worn on rods to prevent them from freezing with overlying heaving soil, grades 6, measuring cords 7, load 8 The soil surface and the thawing boundary are designated 9 and 10, respectively.

 A device for measuring cryosolification fluctuation of soils works as follows.

 Deformations of heaving-precipitation, swelling-shrinkage of soils lead to the vertical movement of thin tubes 3. Making measurements from their top edge to the marks on block 2, we find the values of normal deformations in depth.

 Deformations of soil displacement on the slopes lead to a shift of grades 6 and a change in the length of the measuring cords 7. Measuring the distances from the marks on the cords 7 to the top edge of the tubes 3 and from the marks on the block 2 to the marks on the thin tubes 3, we find the magnitude of the deformations of the soils at a given depth .

 Having the values of heaving-precipitation, swelling-shrinkage, displacement along the depth of the deforming layer, we determine the values of the constituent factors of cryosolifluction of soils, namely cryogenic desorption, hydrogenic desorption and viscoplastic flow.

 The use of a device for measuring cryosolifluctional displacement of soils will improve the accuracy of measuring the values of soil displacement in depth in the cryolithozone area.

Claims (1)

A device for measuring cryosolifluctional displacement of soils, containing two reference points, a block, rods with plates, moreover, the rods are located in the tubes, grades, measuring cords, characterized in that thin tubes are used as rods, while their ends located under the plates are bent under angle of 90 ^o , and the measuring cords are located in the hollow space of thin tubes.