RU148536U1 - CYLINDER SENSOR FOR MEASURING PRESSURE IN ICE FORMATIONS - Google Patents

Abstract

A cylindrical sensor for measuring pressure in ice formations, containing a sensing element in the form of an elastic cylinder, calibration and measuring bellows, characterized in that the sensing element, inside which an electric heater is integrated, is frozen over the entire thickness of the ice, while a fitting with a plug is placed on the top of the cylinder and a micrometer screw resting against a calibration bellows, with the calibration and measuring bellows with a fitting and a micrometer screw located on the ice surface a cover and are closed by a protective casing.

Description

The utility model relates to the field of measurement technology, designed to measure pressure and volumetric relative deformations inside the ice sheet, averaged over the thickness of the ice.

A device for measuring pressure in ice (Altshuler G.G., Smirnov V.N., Shushlebin A.I. Pressure sensor / Auth. Certificate. No. 561887. 1977.). Such a device is made in the form of an elastic hollow ball with three strain gauges located inside the ball.

The disadvantages of the device include the fact that it can only be used to measure pressure in the ice layer in which the sensor is frozen. To measure pressure across the entire thickness of the ice, it is necessary to use a garland of such sensors and average the data obtained over the entire thickness of the ice cover.

The closest in technical essence to the claimed cylindrical sensor for measuring pressure in ice formations is the Sacks-Evertson deformometer (Sacks I. Selwyn, Syuehiro Shigeji, Evtrtson Dale W., Yamagishi Yokichi. Sacks-Evertson Strainmeter, Its Installation in Japan and Some Preliminary Results Concerning Strain Steps. J. Meteorology and Geophysics. Vol. 22, Nos. 3-4, pp. 195-208. November 1971.) for measuring rock deformation in wells during earthquakes. The sensitive element is an elastic cylinder filled with liquid, which is lowered into the well and cemented hard at a given depth. Deformation of the rock is transmitted to the elastic cylinder through the liquid to the bellows, which is connected by a lever to two sensors that convert the movement of the lever into an electric signal: a differential displacement transducer and a recorder in the form of a bimorph piezoceramic plate. These transducers have different dynamic characteristics. The device is calibrated through another bellows in the relative deformation of the borehole walls.

The disadvantages of the above device include the fact that it cannot be used to measure pressure inside the ice sheet, and that it is calibrated to measure the deformation of the well. In addition, such a device does not have a sufficient dynamic range for measuring deformations in such an environment as ice. The use of two sensors with different characteristics simultaneously reduces the reliability of the device and complicates the processing of data. The Sachs-Evertson strain gauge is a disposable embedded device and, after installation in the well, is not removed from it.

The purpose of the proposed design is to expand the scope of the device due to the calibration of the device, both in volumetric relative deformation and pressure, which together characterizes the strength of the medium.

The specified technical result is achieved by the fact that the cylindrical sensor for measuring pressure and relative volumetric deformation in ice formations has a sensitive element in the form of an elastic cylinder, the material of which is selected close in density and elastic characteristics to ice, is filled with hydraulic fluid with a low coefficient of thermal expansion (for example: silicone oil), and the length of the cylinder corresponds to the thickness of the ice. On the upper surface of the sensing element, working and calibration bellows are installed, connected by openings to the sensitive element and a fitting for an exemplary pressure gauge, which is necessary for calibrating the device by pressure. The difference in the size of the bellows provides an increase in the calibration accuracy of the device, since by setting the displacement of the small bellows with the help of a mitrometer screw we obtain more accurate results. A plug-cap with a ring magnet of a magnetically controlled electromechanical displacement sensor is fixed on the working bellows, and on the fluoroplastic casing is an electronic lamp in a protective sheath (Linkov E.M. Magnetron systems for converting seismic vibrations into electric ones. // Izv. AN SSSR. Ser. Geophysics. 1961 No. 9, pp. 1373-1376). The calibration bellows is located in a fluoroplastic cup and is centered using a sliding plug, abuts against the stem of the micrometer screw, which is necessary for calibrating the device in relative deformations. The micrometer screw is secured with a clamp to the fitting. The measuring and calibration part of the device is closed with a protective cap, in which there are two openings, one for outputting a cable for connecting a magnetically-controlled electromechanical displacement sensor to the recorder and the other for inputting a cable connecting the power supply to a heating element installed in an elastic cylinder.

The figure shows a diagram of a cylindrical sensor for measuring pressure in ice formations. The sensitive element of the device (working chamber) is a cylinder 1 filled with hydraulic fluid 2. On the upper surface of the sensitive element 1 are located the working 3 and calibration 4 bellows. Both bellows 3 and 4 are connected by openings to the working chamber 1 through inserts 5 and 6 with sealing glands 7 with screws 8. The difference in the size of the bellows is selected in such a way as to increase the accuracy of calibration of the device. An insert plug 9 and an annular magnet 10 are spring-loaded on a working bellows 3, spring-loaded with a spring 11, and an electronic lamp 13 in a protective sheath 14 is mounted on a fixed PTFE casing 12. The calibration bellows 4 is located in the fluoroplastic cup 15 and is centered by means of a sliding plug 16, abuts against the rod of the micrometer screw 17, which is attached to the fitting 19 by a clamp 18. To calibrate the device, an exemplary liquid pressure gauge (not shown) is installed on the fitting 19 instead of the plug 20. The electronic lamp 13 in a protective sheath 14 is removed from the collet clamp 21 and a rigid rod is inserted instead of it (not shown in FIG.), Which abuts against the bottom of the plug-in plug 9 of the working bellows 3 and prevents it from deforming to expansion. After that, compressing the calibration bellows 4 with a micrometer screw 17, calibrate the micrometer according to the model pressure gauge. After that, the pressure gauge is replaced with a plug 20, and instead of the rod, an electronic lamp 13 is inserted in the protective shell 14 and the entire device is calibrated using the micrometer screw 17 using the through channel method, connecting the electronic lamp 13 with cable 22 to the recorder. The bellows are closed by a removable protective cap 23, which is screwed through the gasket 25 to the upper surface of the sensor element 1. Through the cap there is a hole with a plug 26 for outputting the cable 22 and a hole with a plug 27 for adjusting the micrometer screw 17 without removing the protective cap 23. In addition In addition, a cable 28 is passed through the plug 27, through which power is supplied to the heater 29, which makes it possible to remove the device from the ice cover after measurements.

A cylindrical sensor for measuring pressure in ice formations works as follows. A hole of the required diameter is drilled through the entire thickness of the ice sheet. A sensor element in the form of a cylinder 1 is inserted into this well in such a way that the measuring and calibration part of the device located under the cap 23 remains on the ice surface. After freezing of the sensitive element 1, the protective cap 23 is removed, a magnetically controlled electromechanical sensor is connected to the power supply, consisting of a movable ring magnet 10 mounted on the insert-plug 9, and a stationary electronic lamp 13 in the protective sheath 14 mounted on the fluoroplastic casing 12 using a collet clamp 21. Next, the calibration of the device. For this purpose, an exemplary liquid manometer (not shown in FIG. 1) is installed on the fitting 19 instead of the plug 20. The electronic lamp 13 in the protective sheath 14 is removed from the collet clamp 21 and a rigid rod (not shown in FIG. 1) is inserted, which abuts into the bottom of the insert-plug 9 of the working bellows 3 and does not allow it to deform to expand. After that, compressing the calibration bellows 4 with a micrometer screw 17, calibrate the micrometer according to the model pressure gauge. After that, the pressure gauge is replaced with a plug 20, and instead of the rod, an electronic lamp 13 is inserted in the protective shell 14 and the entire device is calibrated using the micrometer screw 17 using the through channel method, connecting the electronic lamp 13 with cable 22 to the recorder. The measuring and calibration part of the device is closed with a removable protective cap 23, which is screwed through the gasket 25 to the upper surface of the sensor element 1. Through a cable 22 passing through the plug 26, the signal is transmitted to the recorder. The plug 27 allows access to the micrometer screw 17 without removing the protective cap. Using a screwdriver, tighten the micrometer screw 17 and restore the working range of the magnetically controlled electromechanical sensor if necessary, which ensures the expansion of the dynamic range of the entire device. To remove the cylindrical sensor from the ice cover, a cable 28, passing through the plug 27, is supplied with power to the heating element 29 located inside the sensing element 1. The hydraulic fluid is heated and the device is melted. After that, the cylindrical sensor is removed from the ice.

Tests of the device model were carried out in laboratory conditions and showed the operability and reliability of the cylindrical sensor for measuring pressure in ice formations.

The technical and economic effect of the application of the proposed device will manifest itself:

- the possibility of measuring the pressure averaged over the thickness of ice and relative volumetric deformation characterizing the strength properties of ice in the areas of construction and operation of hydraulic structures;

- in the study of natural processes in the ice cover associated with prognostic signs of ice destruction during the interaction of ice formations during drift, impacts on the bottom soil and coast;

- in the reliability and ease of operation of the device in the field.

Claims (1)

A cylindrical sensor for measuring pressure in ice formations, containing a sensing element in the form of an elastic cylinder, calibration and measuring bellows, characterized in that the sensing element, inside which an electric heater is built in, is frozen over the entire thickness of the ice, while a fitting with a plug is placed on the top of the cylinder and a micrometer screw resting on a calibration bellows, with the calibration and measuring bellows with a fitting and a micrometer screw located on the ice surface a cover and are closed by a protective casing.

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