RU2193169C2 - Remote temperature measuring device - Google Patents

Abstract

FIELD: oil and gas industry; geothermic researches. SUBSTANCE: invention can be used at carrying out geothermic researches included in obligatory complex of geophysical methods of control of operation of underground gas storage at detection of fluid cross flows behind casing string. Improved accuracy of temperature measurements and increased resolving power of remote thermometers are provided owing to use of temperature sensitive elements, pulse converter of temperature sensitive elements signals, armored communication cable, unbalance signals amplifier, voltage stabilizer, surface data processing unit including units of supply, discrimination, processing and recording of pulse signal. Temperature sensitive elements are placed in bridge measuring circuit in opposite arms of bridge, and two other arms of bridge circuit are formed by nonlinear elements - current stabilizing two-terminal networks. Supply diagonal of bridge circuit is connected to voltage stabilizer, and measuring diagonal, to outputs of unbalance signal amplifier, and outlet is connected to input of pulse converter. Output of pulse converter is coupled with surface data processing unit by means of armored cable. EFFECT: improved accuracy of temperature measurements. 1 dwg

Description

 The invention relates to a device for measuring the temperature of remote objects and can be used in geothermal studies, included in the mandatory set of geophysical methods for monitoring the operation of underground gas storages when detecting fluid flows behind the production casing.

 A well-known differential thermometer comprising a housing, an electronic unit installed in it, two temperature transducers, a switch and a reference unit installed in the housing, made in the form of a Dewar vessel with a heat-insulating layer and a heater and a capsule with a reference material placed in it, one of the temperature converters mounted in a capsule with a reference material and connected through a switch to an electronic unit (1).

 A disadvantage of the known downhole differential thermometer is the design complexity, complexity and duration of the measurement process, high power consumption, which, in addition to supplying the measuring circuits, is consumed in the heater.

 A device for measuring the temperature gradient in boreholes is known, which consists of 2 heat-sensitive elements installed in the middle of the end parts of the heat-sensitive probe, made of the same material in thermophysical terms and separated by an insert of material that is dissimilar in thermophysical terms, and the length of the end parts is at least ten of them diameters (2).

 A disadvantage of the known device is the large thermal inertia of the measuring system, which requires a significant investment of time for measurements with a time delay at each measurement point, i.e. (as in the technical solution described above) the temperature measurements are essentially made in point mode.

 Known downhole thermometer on a single-core cable, consisting of a thermistor included in the electronic circuit of a pulse converter - relaxation RC generator, made in the form of a voltage comparator, the first output of which is connected to the cable, and the second output connected through resistance to the midpoint of the resistive voltage divider, connected through a thermistor to the inverting input of the comparator, which is connected through the first capacitor to the cable, and through the second capacitor to the ground bus, and the non-inverting input of the comparator is connected to a resistive divider (3).

 This technical solution served as the basis for the development and serial production of thermometers of the TP-7 type (4), which proved to be quite good when conducting geophysical studies in deep wells filled with water, oil, drilling mud (flushing fluid).

 The main disadvantage of this technical solution is the inability to use it during geophysical research in gas wells due to overheating of sensitive elements in air or gas above ambient temperature, which leads to a change in their calibration characteristics, reduced accuracy and resolution of thermometers.

 It should be noted that the thermophysical characteristics of the fluids filling the working volume of the calibration device and the well of the investigated well vary sharply, and under well conditions, in addition, they do not remain constant (for example, due to fluctuations in the density of the drilling fluid, buffer fluid, or gas moisture content) .

 All this in real operating conditions leads to the appearance of additional measurement errors, which are difficult and almost impossible to take into account.

 In addition to the above, the sensitivity of known remote thermometers in some cases is insufficient.

So, at the Krasnodar UGSF, geophysical studies to determine the technical condition of well 49 showed that the method of thermometry does not determine the gas movement behind the production string from the productive stratum to the earth's surface (there are no significant thermal anomalies). However, in the annular space (between the production casing and the conductor) there were gas accumulations under a pressure of 8.6 kg / cm ² .

 It follows from the foregoing that the application of the method of thermometry using well-known serial thermometers is inefficient, because firstly, they do not have stability of calibration characteristics and sufficient accuracy of measurements in a gaseous medium, and secondly, they do not have sufficient sensitivity, for example, to detect gas gaps in an annular space and evaluate the effectiveness of repair and insulation works to eliminate annular overflows.

 This is confirmed by the fact that for these purposes at the Osipovichi underground gas storage it was necessary to measure temperature conditions with an accuracy of no lower than 0.03 K with a sensitivity of about 0.002 K (5).

 Similar problems are common to all underground gas storages.

 The closest in technical essence to the claimed device for remote temperature measurement is a downhole electrothermometer type TEG-36 on a single-core cable, consisting of a downhole projectile with two thermosensitive elements made in the form of active resistances and included in the frequency-dependent circuit of a pulse converter - RC generator, made according to the scheme of the Wien-Robinson bridge and a recording device on the surface, and the recorder has at the output a device for measuring the period to oscillations of the RC generator (6).

 The practice of its use has shown that it has the same disadvantages - insufficient measurement accuracy and sensitivity, because The functions of obtaining information and converting it into a form convenient for transmission via a communication channel are combined and, to obtain an acceptable sensitivity, a large level of power dissipated by heat-sensitive elements is required.

 The objective of the present invention is to increase the accuracy of measurements while increasing the sensitivity of the device.

 The essence of the present invention lies in the fact that the known device for remote temperature measurement, including thermosensitive elements, a signal transducer of thermosensitive elements during the period of electrical vibrations, an armored communication cable with an information extraction unit including a power source, processing electrical vibrations and recording information, according to the invention, additionally contains an amplifier for unbalance signals and a voltage stabilizer, while thermally sensitive elements They are included in the measuring circuit made in the form of a Winston bridge, the supply diagonal of which is connected to the newly introduced voltage regulator, and the measuring circuit is connected to the inputs of the unbalance signal amplifier, the output of which is connected to the central core of the logging cable through a pulse converter of signals of thermosensitive elements (for communication with ground a block for extracting and processing information), the thermally sensitive elements being included in the opposite shoulders of the bridge, and the other two shoulders of the bridge circuit are formed neural elements - current-stabilizing bipolar.

Sign - heat-sensitive elements are included in the measuring circuit, made in the form of a Winston bridge, allows:
- compensate the voltage in the measuring diagonal to zero at the beginning of the range of measured temperatures and obtain greater stability of "zero", since the bridge balance is maintained even with fluctuations in the supply voltage (that is, to ensure high stability of the temperature-voltage conversion characteristics);
- change the boundaries of the measurement range and measure the actual temperature increments, without using other heat-sensitive elements and without changing their parameters.

 The sign is that the thermally sensitive elements are included in the opposite shoulders of the bridge circuit, doubles the increment of the unbalance voltage of the bridge, ceteris paribus (the same supply voltages and temperature changes) and makes it possible to reduce the supply voltage of the bridge circuit, reduce the intrinsic heat emission of the thermally sensitive elements, their overheating relative to the ambient temperature, and, therefore, improve measurement accuracy.

 The sign - the other two shoulders of the bridge circuit are formed by non-linear elements - current-stabilizing two-terminal devices can reduce the change in currents flowing through the thermosensitive elements when the ambient temperature changes due to changes in their resistance, increase the sensitivity and linearity of the characteristics of the conversion of temperature into electrical voltage.

 The use of an unbalance signal amplifier makes it possible to increase the increment of the output voltage of the bridge (where K is the gain of the differential signal) at the same temperature changes and obtain the set sensitivity of the device even at an even lower supply voltage.

 In addition, simultaneously with amplification of the imbalance signals by a factor of K, common-mode interference and interference are suppressed, which, in turn, allows you to remove the heat-sensitive elements at a considerable distance from the other nodes and, in each case, constructively arrange them in the most favorable conditions, excluding their overheating above ambient temperature by other elements of the electronic circuit.

 Figure 1 presents the structural diagram of the proposed device.

A device for remote temperature measurement includes:
- measuring circuit 1, made in the form of a bridge with heat-sensitive elements Rt ₁ and Rt ₂ included in the opposite shoulders of the bridge circuit;
- power supply voltage stabilizer 2;
- amplifier signal imbalance 3;
- ballast resistor 4 voltage stabilizer 2;
- pulse converter 5 (voltage-frequency converter, analogue to time, analogue to code, analogue to digital, etc.);
- communication capacitor 6 of the output of the pulse transducer 5 with an armored (logging) cable 7;
- load resistor 8 of the logging cable 7 from the side of the information processing unit (ground panel), a coupling capacitor 9 of the logging cable 7 with the information processing unit (not shown in Fig. 1).

 Pulse converter 5 has no features (not considered here) and can be anything - ("voltage-frequency", "analog - time", "analog - code", "analog - digit", etc.).

 The device operates as follows.

When the supply voltage Upit is supplied from the ground panel, the measuring bridge 1 with resistors Rl, R2, the thermosensitive elements Rt ₁ and Rt _{2 is} powered from the voltage regulator 2. If all the resistors of the bridge circuit are equal, Rt ₁ = Rt ₂ = R1 = R2, the measuring bridge is balanced and the voltage supplied to the input of the amplifier signal imbalance 3 is equal to zero.

Suppose for simplicity of reasoning that Rt ₁ = Rt ₂ = R1 = R2 = 1000 Ohms, and the voltage at the output of stabilizer 2 is 10.0 volts. Then, at the junction point of Rt ₁ and R1 (as well as at the junction of Rt ₂ and R2), the voltage relative to the common wire (housing) will be 5.0 V.

If, when the temperature-sensitive elements Rt ₁ and Rt ₂ change, their resistance changes upward by 100 Ohms, then the voltage drop across the resistor R1 will decrease by 0.2381 V (from 5.0 to 4.7619 V), and on the resistor Rt ₂ - will increase by 0.2381 V (from 5.0 to 5.2381 V).

Thus, the potential difference between these points while changing the temperature of the thermosensitive elements Rt ₁ and Rt ₂ included in the opposite shoulders of the bridge circuit will double (amount to 0.4762 instead of 0.2381 volts), which will increase the sensitivity of the bridge measurement circuit also twice.

 A further increase in its sensitivity is provided by an unbalance signal amplifier 3, amplifying the differential signals by a factor of K while suppressing common mode interference. Using instead of resistors R1 and R2 non-linear elements - current-stabilizing two-terminal devices can reduce the change in currents flowing through thermosensitive elements when the ambient temperature changes due to a change in their resistance, increase the sensitivity and linearity of the characteristics of the conversion of temperature into electrical voltage.

 The specified set of elements and functional units is necessary on the one hand, and on the other hand, sufficient to solve the problem.

 Therefore, it is possible (ceteris paribus) to repeatedly reduce the supply voltage of the bridge circuit, reduce the overheating of thermosensitive elements in air and gas, increase the stability of the conversion characteristics, the accuracy of temperature measurement and the resolution of remote thermometers operating not only in liquid but also in gaseous medium.

Sources of information
1. A.S. SU 1430513, class E 21 B 47/06, op. 1988 year

 2. A.S. SU 1479633, class E 21 B 47/06, op. 1989 year

 3. A.S. SU 991190, class G 01 K 7/16, op. 1983 year

 4. Prospect VDNH: Thermometers borehole TP7-651, TP7-341. VNIIOENG 3252. T-09312 from 04/03/84. Shooting gallery 500 copies Zach 135. Moscow, st. Shukhov, 17.

 5. The journal "Gas industry", 12, 1997, pp. 39-41.

6. A.S. 143937, cl. 21g, 30 ₀₁ , op. 1962 - prototype.

Claims (1)

 A device for remote temperature measurement, containing thermosensitive elements, a pulse converter of signals of thermosensitive elements, an armored communication cable, a ground-based information processing unit, including power supply, isolation, processing and recording of a pulse signal, characterized in that it further comprises an unbalance signal amplifier and a voltage stabilizer while the thermosensitive elements are included in the bridge measuring circuit in the opposite shoulders of the bridge, and two other Shoulder bridge circuit formed nonlinear elements - tokostabiliziruyuschimi bipole, wherein the feed diagonal of the bridge circuit is connected to a surge protector and the measurement - to the inputs of the unbalance signal amplifier whose output is connected to the input of a pulse converter, whose output is connected via an armored cable with the ground information processing unit.