RU118683U1 - Borehole Geophysical Instrument - Google Patents

Abstract

1. Downhole geophysical tool, including a sealed housing with a chassis placed in it with an electronic unit and sensors of geophysical parameters, a heat insulator, radiators, while the electronic unit is electrically connected by means of a logging cable to ground equipment, including a power supply of the downhole tool, and the sensors are connected to the inputs electronic unit, characterized in that an active thermal protection unit is additionally introduced. ! 2. Downhole geophysical tool according to claim 1, characterized in that the thermal protection unit contains a temperature setting device, a thermometer, a comparison unit, a power supply unit, a supply current regulator, a cooler-heater made on the basis of Peltier elements connected in parallel or in series, or in series - in parallel, the input of the power unit is connected by a logging cable with the output of the power supply of the downhole tool, and the outputs are connected to the inputs of the supply current regulator, the outputs of which are connected to the inputs of the cooler-heater, the outputs of the temperature sensor and the thermometer are connected to the inputs of the comparison unit, and the output of the latter is connected with the control input of the supply current regulator, the thermometer output is also connected to one of the inputs of the electronic unit. ! 3. The downhole geophysical tool according to claim 2, characterized in that the Peltier elements are located at the ends of the chassis of the electronic unit and one surface is in thermal contact with the chassis, and the other with radiators in contact with the body of the downhole tool, while the chassis of the electronic unit is separated from this case with a heat insulator. ! 4. Downhole geophysical tool according to claim 3, o�

Description

The invention relates to geophysical instrumentation, and specifically to instruments for geophysical studies of oil and gas wells.

With increasing depth of drilling oil and gas wells, the temperature and hydrostatic pressure in them increase. The temperature at the bottom of such wells reaches 200-250 ° C.

Downhole tools used for geophysical surveys must remain operational under such conditions and provide the necessary measurement accuracy.

Modern electronic components (transistors, microcircuits, etc.) used in electronic blocks of downhole tools are efficient mainly up to temperatures of 120 ° C, so the problem of their thermal protection is urgent.

Known thermoelectric autonomous power source for downhole equipment (RF patent for the invention No. 2235875, IPC E21B 47/12, publ. 09/10/2004), comprising a housing, Peltier elements with electrical leads mounted on the outer surface of the housing and connected to each other in parallel, or in series , or sequentially-in parallel, and an isotopic or chemical source of thermal energy is installed inside the housing. This device is designed to power downhole equipment and does not solve the issues of thermal protection of electronic components of downhole tools.

A well-known downhole device of a telemetric system for measuring downhole parameters of a well during drilling (see RF patent for invention No. 2347904 IPC E21B 47/12, G01D 5/12, publ. 02.27.2009), containing a generator located inside the casing, a device for mounting it, an electronic unit, including a radiator and a chassis connected by an electrical connector, on which inclinometric sensors and electronic equipment are installed.

To provide thermal protection, a remote insert is installed between the chassis and the radiator, and the body of the electronic unit is made up of upper and lower parts, and a heat-insulating layer is applied between them. Between the remote insert and the inner surface of the body of the electronic unit, at least one ring of elastic material is installed to prevent air convection between the radiator and the chassis, and a heat insulator is installed between the remote insert and the radiator.

Due to the thermal insulation of the electronic unit from heat sources, its removal from heat dissipating nodes, the restriction of thermal convection in this downhole tool, the operation mode of electronic components and sensors is facilitated. However, since a passive thermal protection system is used, after a certain time of the device’s stay in the well inside it, the temperature is compared with the ambient temperature and can increase further due to heat generation in the electronic unit and radiator. Therefore, this downhole tool can be operated in wells with a bottom temperature of not more than 120 ° C (maximum operating temperature of the electronic components), that is, it does not have sufficient heat resistance, while a temperature change in the electronic unit leads to an additional temperature measurement error.

A well-known gamma-gamma-ray logging tool adopted for the prototype (see RF patent for utility model No. 41795, IPC E21B 43/25, G01V 5/12, publ. 10.11.2004), which, in particular, contains a housing, a source gamma radiation, gamma radiation detectors, an electronic unit for generating, accumulating and transmitting detector readings via a geophysical cable to ground equipment. For thermal protection of gamma-ray detectors and an electronic unit, a metal dewar vessel is used in which they are placed.

Due to the high heat-insulating properties of the Dewar vessel, the temperature inside it rises to 120 ° C for 5-6 hours at a temperature in the well of 220 ° C (see A.V. Ivanov, A.I. Klimentiy Thermobar-resistant device of two-probe gamma-gamma-ray logging // NTV “Logger” Tver: Publishing House AIS. 2006. Issue 153. P.50-55). Thus, this downhole tool can be operated in wells with temperatures up to 220 ° C for a limited time (5-6 hours).

However, in this device, the thermal protection system is passive, so the temperature inside the Dewar vessel changes, which leads to a decrease in the measurement accuracy due to the additional temperature error.

The disadvantage is the limited operating time of the downhole tool in high temperature wells.

The objectives of the invention are to increase the heat resistance of the downhole tool, its operational reliability and measurement accuracy at high temperatures in the wells.

The solution to these problems was achieved due to the fact that in the downhole geophysical instrument, which includes a sealed enclosure with a chassis located in it with an electronic unit and sensors of geophysical parameters, a heat insulator and radiators, the electronic unit is electrically connected via a wireline cable to ground equipment that includes a power source downhole tool, and the sensors are connected to the inputs of the electronic unit, an active thermal protection unit is additionally introduced.

The active thermal protection unit contains a temperature setter, a thermometer, a comparison unit, a power unit, a supply current regulator, a cooler-heater based on Peltier elements connected in parallel or in series or in series-parallel. The input of the power unit is connected by a wireline cable to the output of the power source of the downhole tool, and the outputs are connected to the inputs of the power current regulator, the outputs of which are connected to the inputs of the cooler-heater. The outputs of the temperature setpoint and thermometer are connected to the inputs of the comparison unit, and the output of the latter is connected to the control input of the power current regulator. The thermometer output is also connected to one of the inputs of the electronic unit.

Peltier elements are located at the ends of the chassis of the electronic unit and one surface is in thermal contact with the chassis, and the other with radiators in contact with the body of the downhole tool, while the chassis of the electronic unit is separated from the body by a heat insulator, which can serve as a dewar vessel.

The invention is illustrated in figures 1 and 2, where figure 1 shows the structural electrical diagram of a downhole tool, and figure 2 is an example of its design.

Figure 1 shows the electronic unit 1, sensors 2 ... 2 _{n of} geophysical parameters, a logging cable 3, ground equipment 4, a source 5 of a power supply for a downhole tool, an active thermal protection unit 6 containing a temperature setter 7, a thermometer 8, a comparison unit 9, a unit 10 power, power supply regulator 11, cooler-heater 12, made on the basis of elements 13 ... 13 _m Peltier, connected in this case in parallel.

Sensors 2 ... 2 _{n of} geophysical parameters are connected to the inputs of the electronic unit 1, which is electrically connected by a wireline cable 3 to the ground equipment 4 and, in particular, to the power supply source 5 of the downhole tool.

The input of the power supply unit 10 of the active thermal protection unit 6 is connected by a logging cable 3 to the output of the downhole power supply source 5, and the outputs are connected to the inputs of the power current controller 11, the outputs of which are connected to the inputs of the cooler-heater 12.

The outputs of the temperature setpoint 7 and thermometer 8 are connected to the inputs of the comparison unit 9, and the output of the latter is connected to the control input of the power current controller 11. The output of the thermometer 8 is also connected to one of the inputs of the electronic unit.

Figure 2 shows the body 14 of the downhole tool, the chassis 15 of the electronic unit, the heat insulator 16, the flat thermoelectric elements 17 Peltier, radiators 18, screws 19, nuts 20, power supply wire 21.

Sensors of geophysical parameters, boards with electronic components of electronic components and active thermal protection units, not shown in the drawing, are placed on the chassis 15 of the electronic unit.

The chassis 15 is separated from the housing 14 by a heat insulator 16, which can be made of non-conductive material (as in FIG. 2) or in the form of a Dewar vessel.

On the end surfaces of the chassis 15 are flat thermoelectric elements 17 Peltier. On the other side, the Peltier elements 17 are in contact with radiators 18 made of heat-conducting material, which are in contact with the housing 14.

The chassis 15, the Peltier elements 17 and the radiators 18 are connected to each other by screws 19 and nuts 20 made of non-conductive material. Power supply of the Peltier elements 17 is carried out by wires 21.

Downhole geophysical instrument operates as follows. The downhole tool is powered from a ground power source 5. When lowering the device to the bottom, it heats up under the influence of ambient temperature, and the temperature inside it rises. The temperature inside the downhole tool is measured by a thermometer 8, the output signal of which is supplied to one of the inputs of the comparison unit 9 of the active thermal protection unit 6. At the second input of the comparison unit 9, a pre-set signal from the temperature setter 7 is received, which is equivalent to the nominal temperature inside the downhole tool, for example, 100 ° C.

At the same time, information about the temperature from the output of the thermometer 8 is supplied to one of the inputs of the electronic unit 1 and then to the ground equipment 4.

The cooler-heater 12 of the active thermal protection unit 6 is made using Peltier elements, the operation of which is based on the thermoelectric Peltier effect.

It consists in the fact that when an electric current flows through a circuit consisting of two dissimilar metal conductors soldered together, one junction of the circuit is heated, and the second is cooled. For flat Peltier elements, one surface of the plate is the first junction, and the other the second junction.

When passing current through the Peltier element in the forward direction, its surface is cooled adjacent to the end face of the chassis 15 of the electronic unit (Fig. 2), and the surface in contact with the radiator 18 is heated. When passing current in the opposite direction, the opposite picture is observed.

When the temperature inside the downhole tool is less than the nominal set by the setter 7, then the supply current controller 11, controlled by the signal from the output of the comparison unit 9, supplies the current generated by the supply unit 10 to the cooler-heater 12 in reverse polarity. The chassis 15 of the electronic unit is heated by 13 ... 13 _m Peltier elements and the temperature inside the electronic unit rises. When the temperature inside the device rises above the set nominal temperature, the power current controller 11 switches the polarity of the current supplying the cooler-heater 12 directly and the chassis 15 starts to cool, which leads to a decrease in temperature to its nominal value.

Thus, as a result of the automatic control system of the active thermal protection unit 6, the temperature inside the downhole tool is almost equal to the nominal temperature set by the setter 7, for example, 100 ° C.

The process of establishing the temperature is controlled on the surface by the operator. After reaching the nominal temperature when lifting the downhole tool from the bottom of the well, the geophysical parameters are measured using sensors 2 ... 2 _n . Information from the sensors 2 ... 2 _n enters the electronic unit 1 and after the necessary transformations is transmitted via a wireline 3 to the ground equipment 4.

The whole process of measuring geophysical parameters is carried out at a constant temperature inside the downhole tool, which eliminates additional temperature error and improves the accuracy of measurements. The downhole tool can work indefinitely in high-temperature wells, while the electronic components are not overheated and operate in lightweight thermal mode.

A prototype of a downhole geophysical instrument was developed and manufactured, the test results of which confirmed the effectiveness of the proposed technical solutions.

Thus, the technical result of the invention is the high heat resistance of the downhole tool, operational reliability and improved measurement accuracy.

Claims (4)

1. A downhole geophysical instrument, including a sealed enclosure with a chassis located therein with an electronic unit and sensors of geophysical parameters, a heat insulator, radiators, and the electronic unit is electrically connected via a wireline cable to ground equipment that includes a power source for the downhole tool, and the sensors are connected to the inputs electronic unit, characterized in that an additional block of active thermal protection is introduced. 2. The downhole geophysical instrument according to claim 1, characterized in that the thermal protection unit comprises a temperature setter, a thermometer, a comparison unit, a power unit, a supply current regulator, a cooler-heater based on Peltier elements connected in parallel or in series or in series - in parallel, and the input of the power unit is connected by a wireline cable to the output of the power source of the downhole tool, and the outputs are connected to the inputs of the power current controller, the outputs of which are connected to the inputs of the heat-cooler STUDIO outputs setpoint temperature and thermometer are connected to the inputs of the comparing unit and the output of the latter is connected to the control input of the power supply current regulator, thermometer and an output coupled to one input of the electronic unit. 3. The downhole geophysical instrument according to claim 2, characterized in that the Peltier elements are located at the ends of the chassis of the electronic unit and one surface is in thermal contact with the chassis, and the other with radiators in contact with the body of the downhole tool, while the chassis of the electronic unit is separated from this case with a heat insulator. 4. The downhole geophysical instrument according to claim 3, characterized in that the heat insulator is made in the form of a Dewar vessel.