SU1249305A1 - Strain sensor - Google Patents

Abstract

The invention relates to a measurement technique and can be used to measure deformations in a rock mass. The aim of the invention is to simplify the design and expand the technological capabilities by measuring the deformation when drilling parallel to the adjacent wells. A strain gauge is inserted into the well and the distance between target marks is measured. After drilling parallel to the conjugated wells, the well boundary moves and the sensor is compressed. The target mark, which is pivotally connected to the levers, the second ends of which are connected pivotally with the shaft, is displaced relative to the body. The distance between the slit marks is then re-measured. 1 3. p. F-ly, 2 ill. 1C 4; CO with

Description

The invention relates to a measurement technique and can be used to measure deformations in a rock mass, as well as to measure deformations when drilling parallel to adjacent wells.

The purpose of the invention is to simplify the design and expand the technological capabilities by measuring the strain when drilling parallel to the adjacent wells.

FIG. 1 shows the strain gauge, general view; in fig. 2 - sensor after deformation.

The deformation sensor includes a housing 1 with a slot 2, a rod 3, two bearings 4, two target marks 5 and 6, a spring 7 and two levers 8, fixed pivotally with an axis located in slot 2 at the end of the rod 3 and on the target mark 6.

The strain gauge works as follows.

A strain gauge is inserted in the well and an optomechanical device (not shown) measures the distance between target marks 5 and 6. The difference in counting on target mark 5 and counting on target mark 6 is the distance between the target marks of the strain gauge.

After drilling parallel wells, under the pressure of the rock mass, the well boundary moves (spin deformations occur) and, consequently, the sensor is compressed. As a result, target marks 5 and 6 move one relative to the other (Fig. 2).

The target mark 6 is moved upwards as a result of the pressure of the support of the rod 3 on the ends of the short arms of the levers 8. The displacement f of the target mark 6 is

f AM,

where D / is the amount of deformation of the well; k is the coefficient of increase in deforI. t,

matsii, which is equal to "

/ 1 - the length of the large lever arm 8; / 2 is the length of the small arm of the lever 8. The deformation (spin) is determined by repeated measurement of the distance between the target marks 5 and 6 of the sensor, which is the difference in readings of the readings along the target marks 5 and 6.

The obtained value of the strain value is increased in relation to the true value due to the use of levers with a certain ratio of arms / i // 2.

Claims (2)

Invention Formula . A strain gauge comprising a housing, a stem, one end of which is placed in the housing, two supports arranged coaxially and intended to communicate with the object, one of which is fixed on the second end of the stem, two target marks, one of which is fixed on the second end of the stem, and spring located coaxially the rod, characterized in that, in order to simplify the design and expand the technological capabilities by measuring the deformation when drilling parallel to adjacent wells, it is equipped with two levers, the body is made with a slit, some ends of the levers are interconnected pivotally with an axis placed in the slot, and others with a second target sign, the second support is fixed to the body, and the spring is located between the first target sign and the body. 2. The sensor according to claim 1, characterized in that the target marks are made in the form of rings mounted perpendicular to the stem. fig1 Sostavite.11b I. Nikolaeva Editor M. BlanarTehred I. VeresKorrektor M. Sharoshi Order 4222/39 Circulation 670 Subscription VNIIPI USSR State Committee for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab. 4/5 Branch PPP "Patent, Uzhgorod, st. Project, 4 FIG. g