UA81148C2 - Appliance for well operation - Google Patents

Abstract

The invention relates to heaters of well products and in particular to prevention of formation of paraffin and hydrate plugs in lifting pipes of wells. Appliance for operation of wells has a tubing string to which heating sections are included. At the ends of the heating sections centralizers are installed. Electric split connectors are placed in the upper centralizer of each heating section. Block of electric power supply and measuring-control block are made multichannel respectively to number of heating sections. Zero wire of electric power supply block, zero output of measuring-control block and outputs of temperature indicators are connected to pipe of tubing string. Each temperature indicator is fixed at outer surface of heating pipe under upper centralizer. The invention prevents loss of fluidity by oil and scale formation in tubing string.

Description

Description of the invention

The proposed invention relates to the oil and gas industry and can be used, in particular, 2 when operating a well with oil containing asphaltenes and resins to prevent loss of fluidity or a well with highly viscous oil to prevent the formation of paraffin and hydrate plugs in pump-compressor pipes of wells.

A known device for preventing the formation of paraffin hydrates in well pipes (AS USSR Mo 1839043, class E 218 37/00,36/04, Byul. Mo11, 1996), which contains a power source and a cable connected to it in the form of a 710 core , covered by an armor cushion, armor made of round steel wires, a polymer sheath placed on top of the double-layered armor of the cable, while the core is made in the form of one insulated core, the electrical resistance of the armor is 2-4 times greater than the electrical resistance of the core core, and the core core connected to the armor for a short time at the lower end of the cable.

This device for preventing the formation of paraffin hydrates in well pipes, as well as the device for 12 operation of the well, which is claimed, contains a power supply unit (source) and a heating element (cable).

However, the implementation of the heating element in the known device in the form of a cable leads to an increase in the size and weight of the device and a decrease in the efficiency due to the need to heat the intermediate heat carrier - formation fluid, as well as due to the fact that the entire well is heated, and those places where the temperature approaches paraffin hydrate formation and those places where the temperature is significantly higher than the temperature of paraffin hydrate formation.

A well-known device for the operation of a well producing high-viscosity oil (U.S.S.R.

Mo1252479, cl. E 218 43/00, Bul. Mo31, 1986), containing a heater, an operating column, pump-compressor pipes, a separator with an additional column of pipes with an open lower end, which is installed parallel to the pump-compressor pipes and equipped with heat-insulating sleeves, a heater made in the form of 29 several serially installed in in the middle of the additional column of heater pipes with a distance between them of no more than Ge) the height of the free convection contour, and the additional column of pipes has perforation holes under the mouth of the well and under each heater, and thermal insulation bushings are placed on the outer surface of the pipe column in places where the heaters are installed.

This device for the operation of the well, which produces oil with high viscosity, as well as the device for the operation of the well, which is claimed, contains a pump-compressor pipe and heating elements. "Her

However, the implementation of heating elements in the known device leads to an increase in the dimensions of the device, a sharp decrease in the efficiency due to the need to heat the intermediate coolant, heat loss on the walls of the operating column, as well as to a large inertia of the device, which negatively affects the operation of the well if it is necessary to change the oil heating temperature. 3o The closest in terms of technical essence is the device for heating the well (Russian Patent Mo2029069, class E so 218 37/00, Byul. Mo5, 1995), which contains a power source located on the surface, electrically connected connected with a heater located inside the well pipes, an automatic thermal control unit connected to a power source and an autonomous current stabilizer connected to the heater, a power source and a control unit, while the heater is made in the form of a folded metal cylinder from two From the electrically connected upper and lower parts of the unequal cross-section of the surface, which on is heated, and c the inner perimeter R. of the well pipe and the outer perimeter Po of the cross section of the upper part of the cylinder

From" are connected by the ratio 0.01 "R./R.i" 1.0, the area 54 of the heated surface and the area Zo of the well pipes are connected by the ratio 0.001 "53/5251.0, the cross-sectional area Zza of the lower part of the heated surface and area 5; of the cross section of the upper part of the heated surface are related by the ratio bo 75 0.15:55/5.50.6, the length from the lower part of the heated surface and the total length of the 4 cylinders are related by the ratio 1.0 "(I and 53)//4x2.0, and the length is !. of the cylinder and the length /5 of the well pipe are connected - by the ratio 1.01 "no 2)/ "2.2, while the autonomous current stabilizer has serially connected blocks - monitoring the burn-through current of the emergency shutdown and the liquid (gas) temperature sensor, and the autonomous block 50 Thermal mode control has sensors for monitoring the minimum allowable value of the volume of liquid supply (gas) and the maximum allowable temperature value, and the first one is connected directly, and the second one is connected to the power source through the emergency shutdown unit.

This device for heating the well, as well as the device for operating the well, which is claimed, contains a column of pump-compressor pipes (wells), heaters, a power supply unit (source), located on the surface and electrically connected to the heaters, measuring and controlling unit (autonomous heat control unit) connected to the power supply unit and temperature sensors. (F; However, the absence of connectors, the execution of the heater in the form of a folded metal cylinder from two electrically connected upper and lower parts of unequal cross-section of the heated surface, and the placement of the heater inside the pump-compressor pipes, the execution of the power supply and autonomous unit control of the thermal mode reduces the output of the well in the known device due to the reduction of the cross-section of its trunk and the increase in hydraulic resistance due to the introduction of an electric heater into the well, as well as due to the fact that the inclusion of electric heating of the well reduces the volume of liquid (gas) output through the well to the minimum permissible value leads to the fact that the deposition of paraffins (or hydrates) has already begun in the well on the inner surface of the pump-compressor pipes, which also reduces the passage 65 cross-section of the well and reduces the output of well products, in addition, the known device can be used only in the fountain method of oil production and n e can be applied in other methods of oil production, for example, in methods using pumps.

The proposed invention is based on the task of improving the device for operating a well by means of a new implementation of elements and new connections of the device, which allows to increase the yield of well products due to the prevention of oil fluidity loss and the prevention of the formation of plugs and expands the scope of the method.

The problem is solved by the fact that the well-known device for operating a well, which contains a column of pump-compressor pipes, consisting of interconnected sections of pump-compressor pipes, heaters, a power supply unit located on the surface and connected to the heaters, measuring and control unit and 7/0 temperature sensors, according to the invention, t connectors and 2t centralizers are introduced, t sections of the pump-compressor pipe column are used as heaters, which are made as sections that are heated and installed at the points of the pump-compressor column pipes in which the temperature of the well production is not higher than, for example, by 5-10 degrees, the minimum permissible temperature - the temperature at which the well production, which contains asphaltenes and resins, may lose fluidity, or the formation of deposition /5 on the inner walls of the pipe of paraffins and the like, the centralizers are fixed at the ends of the pipes of each section of the pump-compressor pipes, which is heated, to each connector is placed in the upper center of the corresponding heating section, the power supply unit is made of t-channel, and the measuring and control unit is made with t measuring outputs and with control outputs, the first, second, ... th measuring outputs are measured - of the control unit are connected, respectively, to the first, second, ... th outputs of the power supply unit, to the control inputs of which the control outputs of the measuring and control unit are connected, the outputs of the power supply unit from the first to the th are combined into the power supply the cable connecting the power supply unit to the heated sections, and the zero output of the power supply unit is connected to the zero output of the measuring and control unit and to the pipe of the pump-compressor pipe column, each temperature sensor is fixed with high thermal conductivity and heat resistance glue on the outer surface of the tube of the heated section, under the upper centralizer, each core of the power cable is connected through a corresponding electrical connector to the of the supply path - to the supply bus of the corresponding heated section and to the input (8) of the corresponding sensor, the output of which is connected to the pipe of the heated section, and which is the zero input of the heated section, and the heated section is part of columns of pump-compressor pipes and contains a feeding bus, heating elements that are fixed on the outer surface of the pipe section of the pump-compressor pipes evenly with the help of glue with high thermal conductivity and heat resistance, while the heating elements from the first to the nth form rows of circumference, and the heating elements of rows from the first to the Kth are located along the guides of the outer surface of the pipe of the pump-compressor pipe section, K groups along the (51)th connecting wire, of which the first connecting wire in each group connects the first heating element in the corresponding row with the power bus, the (n'-1)th connecting wire connects the last heating element in the row with -- the pipe of the section of pump-compressor pipes, etc. and connecting wires serially connect the heating elements of the row, dielectric substrates, in which the feeding bus and connecting wires are located on the outer surface of the pipe of the pump-compressor pipe section, a layer of vulcanized silicone rubber, which covers the entire surface of the pump-compressor pipe section and which isolates the sensor and device elements from each other and from the external environment. "

Introduction of t connectors and 2t centralizers into the well operation device, use as s heaters t sections of the pump-compressor pipe column made as heated sections and installed in

And at the points of the column of pump-compressor pipes, where the temperature of the well production is higher, for example, by 5-10 °C? degrees, the minimum permissible temperature, fixing the centralizers at the ends of the pipes of each section of pump-compressor pipes that is heated, placing connectors in the upper centralizers of the corresponding section that is heated, making the power supply unit t-channel, and the measuring and control unit with t

Go! measuring outputs and with control outputs, connecting the corresponding measuring outputs of the measuring and control unit with the corresponding outputs of the power supply unit, combining the outputs of the unit - power supply from the first to the th in the power cable, connecting the zero outputs of the power supply unit and - measuring - of the control unit with a pump-compressor pipe, installation of temperature sensors on the outer surface of the pipe of the heated section, under the upper centralizer, connecting each core of the power pi cable through the appropriate electrical connector to the power input of the corresponding heated section and to the input of the corresponding sensor, the output of which is connected to the pipe of the heated section and which is the zero input of the section, allows you to constantly heat the well production at M points of the wellbore by heating the pipes of individual sections of pump-compressor pipes, and thereby prevent the loss of fluidity of the products that has in its composition asphaltenes and resins, and the formation of paraffin wax x and hydrate plugs in pump-compressor pipes, which leads to an increase in product output due to an increase in the borehole cross-section and due to

F) decrease in the viscosity of the well production when heated. In addition, the proposed device for the operation of a well can be used for any methods of oil production, because the passage of the well is not blocked by any devices and does not require the well to be stopped for the introduction of the heater, as is required by known methods.

The drawings show:

Fig. 1 - a diagram of a well and a diagram of a device for operating a well; Fig. 2 - diagram of a section of a pump-compressor pipe that is heated; Fig. 3 - cross-section of the device along A-A, which shows the centralizer.

On Fig! the diagram of the well is given, which includes the mouth 1, a string of casing pipes 2, a column 65 of pumping and compression pipes 3, which are placed in a string of casing pipes 2, a layer of products 4, a pressure gauge 5, mounted in the upper end of a string of pumping and compression pipes 3, a plume 6 with a shut-off valve 7, connected to a string of pump-compressor pipes C and a device for operating a well containing a string of pump-compressor pipes 3, consisting of ordinary sections 8 and specially equipped heated sections 9-1, 9-2 ,..., 9-t, at the upper end of the pipe From each section 8 and 9-1, 9-2, ..., 9-t an internal thread is cut, and at the lower end an external thread is cut, with the help of which all sections 8 and 9-1, 9-2, ..., 9-t are connected in a column of pump-compressor pipes 3, and centralizers 10, which are welded to the ends of the corresponding pipes From sections that are heated, 9-1, 9- 2, ..., 9th and center them in the casing column 2, power supply unit 11, measuring and control unit 12, the first, second, ... and th measuring outputs which are connected, respectively, to the first, second, ... and th outputs of the power supply unit 11, to the control inputs of which the control 7/0 outputs (M-outputs) of the measuring and control unit 12 are connected, the outputs of the power supply unit 11 from the first th are combined into a power cable 13, and the zero output of the power supply unit 11 is connected to the zero output of the measuring and control unit 12 and to the pipe C, electrical connectors 14-1, 14-2, ..., 14-t, installed in the upper centers of 10 corresponding heating sections, 9-1, 9-2,..., 9-t, temperature sensors 15-1, 15-2, 2. 15-t (see Fig. 2), each of which with the help of glue with high thermal conductivity and heat resistance is fixed on the outer surface of the pipe C of the corresponding heated section, 9-1, 9-2,..., 9-t under its upper center 10, each the core of the power cable 13 is connected through the corresponding electrical connector 14-1, 14-2,..., .14th to the power input - the power bus of the corresponding heated section, 9-1, 9-2,... , 9-t and to the input of the corresponding sensor 15-1, 15-2, ..., 15-t, the output of each of which is connected to the pipe C of the corresponding heated section, 9-1, 9-2, ., 9-t, i.e. pipe C is the zero input of sections that are heated, 9-1, 9-2,..., 9-t.

The heated section, 9th (Fig. 2), where and - 1, 2, ..., t, is part of the column of pump-compressor pipes C and contains the power bus 16, which is the power input of the heated section, 9th, connected to the connector 14- and located along the guide outer surface of the pipe From the section 9th, the pipe From the section 9-Her is its zero input, heating elements 17-1-1, 17-1-2,. ..,..17-1-p, 17-2-1,. .17-2-2,..., 17-2-p,..., 17-K-1, 17-K-2, ...,..17-K-p, sch about what with the help glue with high thermal conductivity and heat resistance is fixed on the outer surface of the pipe from the 9th section evenly, while the heating elements from the first to the nth will form rows along the circumference, and i) the heating elements of the first to Kth rows are located along the guides of the outer surface pipes from section 9, connecting wires 18-I-1, 18-1-2, ..., 18-I-(p-1), where r-1, 2, .., K, with which the connecting wire 18-i-1 connects the first heating element 17-I-14 in the th row with the power bus 16, the connecting wires so z 18-i-2,.... 0.18-i -n serially connect the heating elements of the i-th row 17-I-1, 17-i-2, 0. 17-I-n, the connecting wire 18-g-(pi1) connects the last in g- in the same row, the heating element 17-i-n with the pipe of section C, - dielectric substrates 19, in which the supply bus 16 and "- connecting wires 18-1-1, 18-1 are located on the outer surface of the pipe of section C -2, ..., 18-1-p, 18-2-1, 18-2-2, ...,.0.18-2-p, ..., 18-K-1, 18-K-2, .., 18-K-p, layer 20 of vulcanized silicone rubber, which covers the entire surface of the pipe from section 9 and which isolates --

From the sensor 15 and the elements of the device from each other and from the external environment, the ends of the layer of silicone rubber 20 are placed with a seal under the centralizers 10 placed at the ends of the pipe from the section 9. The power bus 16 and the input of the sensor 15 are connected to the electrical connector 14 on one side, and the corresponding core of the power cable 13 is connected on the other side. Thus, one of each sensor 15 is connected through an electrical connector container 14 and the corresponding core of the power cable 13 with the output of the measuring and control unit 12, which corresponds to the section that is heated 9, and the output of each sensor 15 is connected through the pipe C to the zero (common) with the output of the measuring and control unit 12.

Centralizer 10 - Fig. 3 is a base 21 made in the form of a sleeve with an inner diameter of 1-2 mm; larger than the outer diameter of the pump-compressor pipe 3, stops 22 are welded to the outer side surface of the base 21 along the radius, for example, four stops that are separated from each other by an angle of 902. The length of the stops 22 is chosen so that when installing a column of pump-compressor of pipe C with centerers 10 welded to it, stops 22 did not reach the inner wall of casing pipe 2 by 3-5 mm. The electrical connector of the 14th pin is installed inside one of the stops 22 of the centralizer 10, which is installed at the upper end of the pipe 3. If necessary, for example, in the case when it is necessary to install two heated sections in series at the heating point, on the upper section , which is heated, you can install a connector in both centralizers 10.

Covering with a layer of silicone rubber is carried out in the process of manufacturing the heated section. To do this, after installing and mounting on the surface of the pipe all the necessary elements of the device and the sensor, the section is filled with silicone rubber and vulcanized. When pouring, silicone rubber covers the entire surface of the pipe and all elements installed on it. After vulcanization, all elements and the sensor are reliably isolated from each other by vulcanized silicone rubber. In addition, vulcanized silicone rubber is also a reliable heat-insulating coating and protects all device elements and the sensor from overheating up to the permissible temperature.

The column of pump-compressor pipes Z is installed vertically to the surface of the earth, therefore, the upper end of the pump-compressor pipe section is considered to be the end located closer to the ground surface, and the centralizer welded to the upper end of the pump-compressor pipe section is considered to be the upper concentrator.

The power supply unit 11 is a t-channel controlled source of alternating current, in which any channel can be turned on or off according to the command received at its input, regardless of whether other channels are turned on or off. In addition, each channel of the power supply unit 11 is adjustable, that is, it allows you to adjust the power of the channel within the established limits.

The measuring and control unit 12 is a t-channel device for controlling the power supply unit 11th for measuring the temperature at t points of the column of pump-compressor pipes Z along the wires of the power supply network. 65 The measuring and control unit 12 is automatically connected to the core of the power cable 13 corresponding to the temperature sensor 15, from which the temperature value must be obtained, with a given period or according to the commands given by the operator, and performs temperature measurement at the place of installation of the sensor. If unit 12 works automatically, then the received temperature value is compared with the maximum set value and with the set value. If the measured temperature is equal to or greater than the maximum set value, then the power supply unit 11 receives a signal to turn off the corresponding channel and reduce the power of this channel of the power supply unit 11, and if it is equal to or less than the specified value, then the power supply unit 11 receives a signal to turn on the corresponding channel. If the operation of the well is controlled by the operator, then he determines the moments of turning off, reducing power and turning on the channels of the power supply unit 11 based on the indicators of the indicator of the measuring and control unit 12 and performs these actions. 70 The well operation device works as follows.

The purpose of the proposed device is to maintain the temperature of the well production all the way from the hole to the surface of the earth higher than the minimum permissible temperature, that is, the temperature at which the loss of fluidity of the well production, which has asphaltenes and resins in its composition, is possible, or is possible the beginning of the formation and deposition on the inner walls of the pipe of paraffins and the like, which is achieved by constant heating of the products in those places of the column of pump-compressor pipes 3, in which the temperature of the well products during its rise from the hole to the surface of the earth approaches the minimum permissible temperature.

In advance, the minimum permissible temperature is determined based on the formation temperature, the flow rate of the well, and other characteristics of the well and its products. Calculating the temperature of the well production, a graph of the decrease in the temperature of the well production as it rises from the layer to the mouth is constructed, depending on the distance from the well blowout. According to the graph, the distance from the wellhead is determined, and according to it, the first distance from the surface of the earth to the point at which the temperature of the well products is higher, for example, by 5-10 degrees, than the minimum permissible temperature. The obtained point is the first point from the wellbore, at which it is necessary to heat the production of the well, therefore, the first heating section from the wellbore must be installed here.

The temperature at which the product leaves the heated section is calculated based on the temperature at which the product reached the heating point, the electric power of the section being heated, the permissible distance to the next heating point, and other parameters. If the product comes out of the i) heated section with a temperature below the set one, then either one more heated section is added at this point, or a higher capacity section is selected. Further, based on the temperature at which the product leaves the heated section and other characteristics of the well and its products, a graph is made of the decrease in the temperature of the well product as it rises from the first heating point to the surface of the earth, depending on the distance from this point. According to the graph, the distance from the first heating point is determined, and according to it - the second - the distance from the surface of the earth to the point at which the temperature of the well production will be higher, for example, by 5-10 KK dn degrees, the minimum permissible temperature. The obtained point is the second point from the wellbore, at which it is necessary to heat the production of the well, therefore, the second section from the wellbore must be installed here, which (87) is heated. Thus, all M heating points are determined, i.e., the points at which the production must be heated with of the well, so that it reaches the surface of the earth without loss of fluidity by well products containing asphaltenes and resins, or without the formation of paraffins, hydrates, etc. The number of heating points, depending on the characteristics of the well, its products and heaters, can be from one to several. Based on the obtained distances from the heating points to the surface of the earth, the places in the column of pump-compressor pipes 3 are determined, in which it is necessary to install heated sections 9 when assembling the column. At the same time, it is possible that with c the number of heating points - M and the number of heated sections - t will not be equal (t »M) due to the fact that in some heating points of one heated section, the 9th can be not enough to heat products to required set temperature and then set two or more heated sections in series.

The maximum set temperature value is chosen based on the fact that the temperature on the surface of the section 9 pipe is not higher than 50-6095 of the maximum permissible temperature that vulcanized silicone rubber can withstand. The specified value of the temperature of the heating is selected based on the fact that the production of the well having a temperature equal to this value reaches the next heating point - with a temperature exceeding, for example, by 5-10 degrees the minimum permissible temperature. Set - the amount of power reduction of the power supply unit 11 channel is determined from the graph of the 5-year decrease in the temperature of the well production as it rises from the layer to the mouth, depending on the distance from the blowout of the well, built according to the actual values of the formation temperature, the flow rate of the well, and other characteristics of the well and its production at the time when it became necessary to reduce the power of the power supply unit 11 channel.

During the installation of a column of pump-compressor pipes Z in the places previously determined by the calculation of the thermal regime of the well, heatable sections, 9th, are installed. After installing a column of pump-compressor pipes C in the well, it is started, and after filling the well with products (iF) the device for operating the well is started - include sections that are heated (9th pump-compressor pipes 3. After turning on all sections that heat up, the 9th begin to monitor the temperature on their surfaces with the help of the measuring and control unit 12 and sensors 15. because the production of the well, entering the column of pump-compressor pipes 3, rises along it, while its temperature decreases, but at the first heating point it has not yet decreased to the minimum allowable temperature. At the first heating point, the temperature of the well production rises to a set value, which is set by the electric power of the heated section, to this heating point. Further, during the rise, the temperature of the well production decreases again, but to the next heating point it is not yet 65 It has dropped to the minimum acceptable temperature.At the point on heating, the temperature of the well production rises again to the set value. This process is repeated until the product reaches the surface of the earth, where it arrives at a given temperature. Thus, in the process of extracting well products, its temperature is maintained above the minimum permissible temperature, and therefore loss of fluidity and the formation of plugs do not occur.

In the process of producing products, its pressure and flow rate will decrease, which leads to a decrease in the transfer of heat from the flow of well products, and therefore the temperature of the products entering the heated section of the 9th pump-compressor pipes 3 will increase, and the temperature of the products will also increase outputs of heated sections. When, when measuring the temperature, it is found that the temperature at the output of any section 9 has exceeded the maximum set value, the measuring and control unit 12 sends a signal to the 7/0 control inputs of the power supply unit 11 to turn off the power supply channel of the section that is being heated , the 9th pump-compressor pipes 3, the temperature at the outlet of which exceeded the maximum set value, after switching off, the power of the ith channel of the power supply unit 11 is reduced by the set value. After that, when the measuring and control unit 12 detects that the temperature at the outlet of this section, which is heated, of the 9th pump-compressor pipes C has decreased to the specified value, a signal is sent to the control inputs of the /5 power supply unit 11 to turn on this section, which heats up, 9 pump-compressor pipes

Q. Next, the process of extracting the well production continues similarly to the above, only the temperature of the well production at the heating point, in which the power of the heating channel was reduced, will be close to the value of this temperature at the beginning of the well operation.

Claims (2)

The formula of the invention 1. A device for the operation of a well, containing a column of pump-compressor pipes, consisting of interconnected sections, heaters, a power supply unit located on the surface and connected to water heaters, a measuring and control unit and temperature sensors, which differs in that it has t detachable connections and 2t centralizers used as heaters t sections of the pump-compressor pipe string, which are made as (o) sections that are heated and installed in those places of the pump-compressor pipe string, in which the temperature well production is higher than the minimum permissible temperature, at which the flowability of the well production containing asphaltenes and resins is possible, or the formation and precipitation of paraffin on the inner walls of the paraffin pipe, etc., is possible, the centralizers are fixed at the ends of the pipes of each section of the pump of compressor pipes, which is heated, each removable connection is placed in the upper center " of the corresponding section, which is heated, the power supply unit i is made of t-channel, and the measuring-control unit is made with t measuring outputs and with control outputs, the first, second, ... and th measuring outputs of the measuring-control unit are connected respectively to the first, second, . .. and th outputs of the z5 power supply unit, to the control inputs of which the control outputs of the measuring and control unit are connected, the outputs of the power supply unit from the first to the th are combined into a power cable connecting the power supply unit to the sections , which are heated, and the zero output of the power supply unit is connected to the zero output of the measuring and control unit and to the pipe of the pump-compressor pipe column, each temperature sensor is fixed on the outer surface of the pipe of the section that is heated by means of glue with high thermal conductivity and heat resistance , under the upper centralizer, each core of the power cable is connected through the corresponding electrical connector to the power input - the power bus of the corresponding heated section and to the input of the corresponding sensor, the output of which is connected to the pipe of the heated section and which is the zero input. :with" 2. The device according to claim 1, which is characterized by the fact that the heated section is part of the pump-compressor pipes and has a feeding bus, heating elements that are fixed on the outer surface of the pipe of the pump-compressor pipe section with the help of glue with high thermal conductivity and heat resistance evenly, while the heating elements from the first to the nth form rows in a circle, and the heating elements of the first to Kth rows are located along the guides of the outer surface of the pipe section of the pump-compressor pipes, K groups according to (n-1)th - a connecting wire, of which the first connecting wire in each group connects the first in the corresponding row - a heating element with a power bus, the (n'-1)th connecting wire connects the last in the row heating 5p an element with a pipe section of the pump-compressor pipe section, other connecting wires are connected in series with each other - heating elements of the row, dielectric substrates on which the nutrients are located on the outer surface of the section of the pump-compressor pipe section on the tire and connecting wires, a layer of vulcanized silicone rubber, which covers the entire surface of the pump-compressor pipe of the section, which isolates the sensor and the device elements from each other and from the external environment. F) name) 60 b5