RU2660753C1 - Thermometrical chain (thermic chain) - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: invention relates to the measurement of temperature by means of thermometric electrical sensors and is designed for simultaneous measurement and recording of soil temperature values at several points of the object, depending on its design, in particular in thermometric wells of any type in the field, conducting stationary and laboratory studies of the temperature mode of thawed, frozen, cooled and freezing/thawing soils, arrangement of the network for monitoring the thermal mode of soils with a large number of observation points, including those in fire, explosive and aggressive environments. Proposed device includes temperature sensors that are soldered directly to the wires of the flexible cable, pressed into the molten material based on the polyethylene composition of the same brand as the cable sheath, while forming the flexible, hermetic, monolithic construction, which is equipped with the connector, in the housing of which the electronic circuit board is installed, which contains the service information, including correction factors for each temperature sensor.

EFFECT: increased accuracy of measuring the temperature mode of wells of various types, increased reliability of the device when working in fire, explosive and aggressive environments, as well as increased life of the device and extended range of its use.

9 cl, 2 dwg

Description

The invention relates to the field of temperature measurement by thermometric electric sensors and is intended for the simultaneous measurement and recording of soil temperature values at several points of the object depending on its design, in particular in thermometric wells of any type in the field, stationary and laboratory studies of the melt temperature, frozen, chilled and freezing / thawing soils, organization of a network for monitoring the thermal regime of soils with large m by the number of observation points, including in fire, explosive and aggressive environments.

Temperature is the main characteristic of soil freezing / thawing processes. The development and intensity of manifestation of cryogenic processes, as well as the thermophysical and physico-mechanical properties of thawed, frozen, chilled, freezing and thawing soils depend on the temperature regime of soils, therefore, the study of the temperature regime of soils is the main task in engineering and geological surveys, in the design of engineering structures and foundations and assessment of their sustainability. The variability of the temperature regime of soils must be taken into account when monitoring and developing environmental protection measures in the field of development of permafrost and deep seasonal freezing of thawed soils. In addition, the heterogeneity of the temperature field of soils is used to judge the presence of groundwater, oil and gas condensate, the presence of radioactive decay products, and oxidation processes in oil shale and coal. Also, the presence of a temperature gradient in the soil is an indirect indicator of tectonic activity.

There are various portable and stationary thermal measuring kits containing electric sensors and designed to measure the temperature of soils in previously prepared and well-maintained thermometric wells.

A device is known for thermal logging of wells (RU 2314416 C2, IPC Е21В 47/06, G01K 7/20, published January 10, 2008, Bull. No. 1), containing three identical heat-sensitive sensors placed along the axis of the well at a given distance to measure the second temperature differences, first, second and third. The thermosensitive sensors are identical and include four identical thermosensitive resistors combined into thermosensitive bridges. The difference in the imbalances of the heat-sensitive bridges is proportional to the second temperature difference, and the sum of their imbalances is proportional to the first difference; also all thermosensitive resistors are used to measure the absolute temperature of the medium in which the probe is located. The first temperature difference depends both on the continuous measurement of temperature along the wellbore, and on its local measurements. The second temperature difference depends only on local temperature measurements.

The disadvantages of the device are a narrow scope, low measurement accuracy, redundancy of equipment, the use of indirect methods of measuring one dependence on another.

A device for monitoring temperatures in an extended object (RU 75692 U1, IPC ЕВВ 47/12, G01K 7/14, published 08/20/208, Bull. No. 23), containing a thermal suspension, consisting of sequentially located temperature sensors placed in a protective small-diameter housing, control microcontroller, signal converter, non-volatile memory, real-time clock, solver, initial parameter setting unit, built-in power supply and data transfer interface, as well as equipped with a seal, designed to prevent ambient air from entering the well during the measurement. The casing is made in the form of a removable polymer thick-walled sheath of a self-supporting cable.

The disadvantage of this device is the long time of the thermal reaction due to the presence of a polymer thick-walled shell in which the thermal suspension is located, as well as the low tightness of the thermal suspension in the absence of a polymer thick-walled shell, which leads to a failure of the device in conditions of increased dust and moisture.

The closest analogue of the invention is a device (RU 2448335 C2, IPC ЕВВ 47/06, G01K 7/16, published on 04/20/2012, Bull. No. 11), intended for simultaneous measurement of temperature at several points of an object, the location of which is determined by the structure of the object , and containing temperature sensors in series, interconnected by a flexible cable that provides electrical connection to temperature sensors, a connector for connecting a reader, storage, processing and display of data. Each temperature sensor is enclosed in a protective housing.

The disadvantages of the device are insufficient tensile and compressive strength, loss of tightness of temperature sensors during operation, which limits the possibility of using the device in explosive, fire hazardous and aggressive environments, as well as the design complexity due to the installation of an electronic printed circuit board with a correction factor in the housing of each sensor and , accordingly, the impossibility of calibration and verification directly in the well. The disadvantages include the inability to use the device with a PVC or rubber sheath of the cable in the Far North due to the high brittle temperature of the above polymer shells.

Monitoring the temperature regime of thawed, frozen, chilled and freezing / thawing soils requires the use of monitoring methods using temperature measurements using thermometric instruments / devices that must be adapted, reliable from the point of view of metrology, verified from the point of view of fire and explosion safety and have sufficient strength breaking and squeezing, in order to provide automatic and manual measurements at specified intervals along the length and / or depth of the entire object (in particular , Thermometric wells).

With all methods of measuring temperature using electric sensors, temperature measurement is relative, so during installation and throughout the life of the electric sensor, there is a need for temperature calibration and verification of such a sensor. Indeed, such calibration and verification allows you to check the normal operation and / or to evaluate the deviation of the temperature readings of the sensor.

Using the present invention, a technical result is achieved consisting in increasing the accuracy of measuring the temperature regime of various types of wells, in increasing the reliability of the device when working in fire, explosive and aggressive environments, as well as in increasing the service life of the device and expanding the range of its use.

To achieve the claimed technical result in a thermometric braid (thermal braid) (hereinafter referred to as a thermal braid) containing temperature sensors in series connected by a flexible cable and equipped with a connector for connecting to a portable reading device - a logger, according to the invention, temperature sensors are soldered directly to the wires of the flexible cable, pressed using a mold into molten material based on a polyethylene composition of the same brand as the cable sheath Thus, the temperature sensors and cable form a flexible monolithic structure equipped with a connector. The monolithic design ensures reliable tightness of the device and, as a consequence, high strength, fire and explosion safety, as well as the tightness of the sensors throughout the entire life of the heat cutter.

An electronic printed circuit board is installed in the connector housing, containing service information, including the serial number of the braid, information on the location of the sensors along the depth of the well, and correction factors for each temperature sensor. Placing all the necessary information in the connector located in the upper part of the thermocouple allows checking and calibration of the thermocouple directly at the place of operation, for example in a thermometric well.

As a flexible cable, the GSP 0.5 (P274) geophysical wire can be used, the steel-copper cores of which have increased tensile and compressive strength, which is important when operating the braid in the Far North due to the formation of an ice plug at the wellhead. The sheath of the flexible cable is made on the basis of a polyethylene composition 153-10k containing thermal and light stabilizers with a brittle temperature not higher than minus 70 ° C, which ensures high reliability and durability of sealing the device when used in aggressive environments and at especially dangerous objects of the oil and gas complex, and also in the Far North.

To exclude the ingress of ambient air into the borehole, and, consequently, distortion of the temperature field of the borehole due to convection, and to fix the braid in the borehole, a rubber or polymer plug is located between the connector and the first sensor.

In the case of installing a braid in an extended well, a braid can be wound on a coil made of metal or plastic located on a bed with a braking device.

To immerse the braid in a vertical well, the last temperature sensor is equipped with a device for attaching a weighting agent.

To install the braid in a sloping well, the last temperature sensor is equipped with a device for attaching the cable.

In addition, the claimed spit can be used as a probe, that is, to measure the temperature in the surface layer of the soil, for which the spit is placed in a round tube made of stainless steel, while one end of the tube is plugged and pointed, and the other is made in in the form of a pen.

The essence of the invention, “Thermometric braid (thermocosa)" is illustrated by drawings, in which the same or similar elements are provided with the same reference position.

In FIG. 1 is a top view of a braid of the present invention.

In FIG. 2 shows a temperature sensor and a sectional view of the connector of FIG. one.

Thermometric braid (thermocosa) contains sequentially located temperature sensors 1 connected by a flexible cable 2, and is equipped with a connector 3. According to the invention, temperature sensors 1 are soldered directly to the wires of flexible cable 2, pressed using a mold into a molten material based on a polyethylene composition of the same brands like the cable sheath so that the temperature sensors and the cable form a flexible, hermetic monolithic structure. In the upper part of the braid there is a connector 3 for connecting to an information reader (logger), in which a printed circuit board 4 with electronic components is installed. On the circuit board 4 recorded service information, including correction factors for all temperature sensors. A rubber sealant is installed in connector 3 on the side of the connection to the information reader (logger) to seal the connection, and a collet clip with sealant is installed at the outlet of cable 2 from connector 3. The last temperature sensor 5 has a shape different from that of other sensors, which allows you to attach a device (not shown) to it for immersion / placement of the braid in any type of well. Between the connector 3 and the first temperature sensor 1, a rubber plug 6 is installed for fixing the braid in the well. Cork 6 can be made of polymeric materials.

The cross-sectional shape of the protective shell of the sensor 7 is round.

Thermocosa carries out simultaneous measurement and registration of soil temperature at several points of the object, depending on its design, at various distances, with a certain step, using a reader (logger).

Wells of any type in various soils (thawed, frozen, chilled, freezing / thawing) can act as an object.

Thermocosa of the present invention operates as follows.

Thermocosa is placed in the object, connector 3 is located in a place accessible for connection to an information reader (logger). Temperature sensors 1 measure the temperature of the object, convert the measured signal into a digital form. The measurement results from temperature sensors 1 and correction factors from the electronic circuit board of the connector are sent to an information reader (logger), where the data are read and processed and transmitted to the indicator of the reader and PC using the appropriate program. Thermocosa is powered by an information reader (logger).

Thus, the proposed device provides multi-zone temperature measurement with the ability to calibrate and verify on-site, in particular in thermometric wells of any type — vertical and / or sloping, has increased resistance to rupture and compression, and maintains the tightness of electrical temperature sensors throughout the life of . In addition, it can be used as a probe for measuring the temperature of the surface soil layer.

Claims (9)

1. Thermometric braid (thermocosa), containing sequentially located temperature sensors connected by a flexible cable, and equipped with a connector for connecting to a portable reader - a logger, characterized in that the temperature sensors are soldered directly to the flexible cable wires, pressed into molten material based on polyethylene compositions of the same brand as the cable sheath, forming a flexible hermetic monolithic structure, which is equipped with a connector in the housing of which is installed A printed circuit board containing service information, including correction factors for each temperature sensor. 2. Thermometric braid (thermocosa) according to claim 1, characterized in that the GSP 0.5 (P274) geophysical wire enclosed in a sheath based on a polyethylene composition 153-10k containing thermal and light stabilizers with temperature can be used as a flexible cable fragility not higher than minus 70 ° C. 3. Thermometer spit (thermocosa) according to claim 1, characterized in that for sealing the wellhead and fixing the thermometer spit in the well between the connector and the first sensor is a rubber plug. 4. Thermometric spit (thermocosa) according to claim 1, characterized in that for sealing the wellhead and fixing the thermometric spit in the well between the connector and the first sensor is a polymer plug. 5. Thermometric spit (thermocosa) according to claim 1, characterized in that for installation in an extended well, a thermometric spit is wound on a coil made of plastic, located on a frame with a brake device. 6. Thermometric braid (thermocosa) according to claim 1, characterized in that for installation in an extended well thermometric braid is wound on a coil made of metal, located on a frame with a braking device. 7. Thermometric spit (thermocosa) according to claim 1, characterized in that for installing a thermometric spit in a vertical well, the last temperature sensor has a device for attaching a weighting agent. 8. Thermometric braid (thermocosa) according to claim 1, characterized in that for installing a thermometric braid in a sloping well, the last temperature sensor has a device for attaching a cable. 9. The thermometric spit (thermocosa) according to claim 1, characterized in that for measuring the temperature in the surface layer of the soil, the thermometric spit is placed in a round tube made of stainless steel, while one end of the tube is plugged and pointed, and the other is made in the form pens.

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