RU2504927C1 - Induction heating device of oil products - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: device includes an induction heater, a magnetoconductive screen, a heat insulating casing, an induction winding enveloping a cylindrical capacity, an AC rectifier and an inverter connected to the induction winding and an inverter control unit, temperature sensors of inlet and outlet flows, which are connected to a temperature comparator that is connected to the inverter control unit and a pump control unit connected to a pump. It is equipped with a bypass pipe, one end of which is located in cross section of an inlet delivery branch pipe, at the inlet of which the pump is fixed mechanically, and the other end is located in cross section of an outlet suction branch pipe with an automatic shutoff-control element connected to the control unit of the shutoff-control element connected to the temperature comparator. With that, the induction heater is located horizontally; the cylindrical capacity is made from non-magnetic material with a vertical wall installed in liquid flow direction, and the cylindrical element is made in the form of a heat exchange tube from ferromagnetic material, which is located inside the cylindrical capacity with a gap and equipped with horizontal heat exchange rods installed inside the tube in a staggered order, heat exchange semi-spheres located on its outer surface in a staggered order, and a temperature sensor installed on outer surface of the heat exchange tube and connected to the temperature comparator.

EFFECT: simpler heater design and improved reliability and automation of the device operation.

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Description

The invention relates to techniques for heating viscous petroleum products for their further transportation through trunk pipelines.

Known induction fluid heater (US Pat. RU No. 2030128, publ. 02.27.1995), which contains a magnetic circuit made in the form of a pipe closed at the ends provided with inlet and outlet pipes, a heating coil placed on the magnetic circuit. The magnetic circuit can be made in the form of a toroid with an internal radial partition, on different sides of which the indicated pipes are placed. The magnetic circuit can be made in the form of a spiral, each annular coil of which is closed to itself.

The disadvantage of this design is that the heating is carried out only in a thin parietal layer of the fluid flow. In addition, there are no additional ribs on the inner surface of the pipe, the presence of which would increase the heat transfer coefficient from the inner surface of the pipe to the heated fluid.

A heat exchanger is known (US Pat. RU No. 211,19629, publ. 09/27/1998), which contains a cylindrical body, a cylindrical element coaxially located inside the body - the rotor, which together with the inner surface of the body forms an annular gap for the passage of the heated fluid, collector chambers, connected to the housing and having paddle wheels for pumping a heated fluid. The outer surface of the housing is covered with heat-resistant electrical insulation, on top of which is a current-carrying winding with magnetic cores. The suction manifold chamber is equipped with a heating chamber in the form of an annular cavity, covering the housing with holes along its perimeter, communicating the discharge chamber with an annular gap. The diameter of the blade wheel exceeds the diameter of the rotor. The apparatus is equipped with a bypass tube with a regulating body, one end of the tube is located in the cross-section of the discharge pipe and is bent opposite to the flow of the heated fluid, and the other end is in the cross-section of the suction pipe and is bent in the direction along the fluid flow going into the device.

The disadvantage of this invention is the need to install a propulsion device for rotating the rotor, which increases the dimensions of the installation as a whole, increases its cost and increases the amount of work during its installation and maintenance.

It is known "Device for induction heating of a liquid in a pipeline" (US Pat. RU No. 2120703, publ. 20.10.1998), adopted as a prototype and which includes a series-connected AC regulator, an induction heater containing at least one induction winding with electrothermal insulation a gasket covering a cylindrical magnetic core having an inlet and outlet nozzles connected to the pipeline, a first temperature sensor mechanically fixed to the inlet pipe of the pipeline. A series-connected AC rectifier and an inverter are introduced into the device as an AC regulator, the output of which is connected to the electric input of the induction heater, and the second input is to the output of the inverter control unit, a second temperature sensor, mechanically fixed to the pipeline input line, the outputs of the first and second temperature sensors connected to the inputs of the temperature comparison unit, one of the outputs of the latter is connected to the input of the inverter control unit, and the second to the input of the control unit catfish, output pump control unit connected to the pump control input. The pump is mechanically fixed on the pipeline between the inlet and outlet lines, and in the induction heater at least one induction winding enclosed in a sealed cylindrical housing with electrothermal insulating gaskets is placed inside the cylindrical magnetically conducting tank, at least one cylindrical and one circular distributor are also fixed inside the tank heated fluid flow, located respectively along the longitudinal and transverse axes of the magnetic cylindrical tank and. Outside, the induction heater is enclosed in a magnetic shield, and then in a heat-insulating casing, and the indicated magnetic conductive capacitance, the housing of the internal induction winding and the flow distributors of the heated fluid are made of sheet ferromagnetic steel. At least one more internal induction winding can be placed in the induction heater, each winding is enclosed in a sealed cylindrical housing, and the windings are mounted concentrically in the magnetic conduit one into another with a gap between them. At least one more internal induction winding can be placed in the induction heater, each winding is enclosed in a sealed cylindrical housing, and the winding is fixed one above the other in the magnetic circuit with a gap between them.

The disadvantage is the difficulty in manufacturing and maintenance. The design of the device does not allow, in case of failure of the internal induction winding, to replace it without opening and emptying the cylindrical container. In addition, the pump used in the device is intended only for the initial acceleration of the warm layers of the liquid by forced thermal convection when the heating is turned on, which does not allow using it in the steady state operation of the device for pumping large volumes of liquid.

The technical result is to simplify the design of the heater, as well as improving the reliability of the device.

The technical result is achieved in that a device for induction heating of petroleum products, including an induction heater, enclosed in a magnetic shield, and then in a heat-insulating casing, and containing an induction winding with an electrothermal insulation gasket covering a cylindrical container containing a cylindrical element and having an input and output branch pipe, AC rectifier and inverter connected to the induction winding and inverter control unit, sensors t the inlet and outlet flow temperatures connected to the temperature comparison unit, which is connected to the inverter control unit and the pump control unit connected to the pump, is equipped with a bypass pipe, one end of which is located in the section of the inlet discharge pipe, at the input of which the pump is mechanically fixed, and the other the end is in the cross section of the outlet suction pipe, with an automatic locking and regulating organ connected to the control unit of the locking and regulating organ connected to the temp comparison unit r, and the induction heater is located horizontally, the cylindrical tank is made of non-magnetic material with a vertical wall installed in the direction of fluid movement, and the cylindrical element is made in the form of a heat transfer pipe made of ferromagnetic material, which is located inside the cylindrical tank with a gap and is equipped with horizontal heat exchange rods installed inside the pipe in a checkerboard pattern, by heat-exchange hemispheres located on its outer surface in a checkerboard pattern row, and a thermal sensor mounted on the outer surface of the heat exchange pipe and connected to the temperature comparing unit.

The block diagram of the device is presented in figure 1. Schematic diagram of the induction heater is presented in figure 2. Figure 3 shows a cross section of an induction heater

The device comprises a rectifier 1, an inverter 2, an induction winding 3 of the induction heater 4 connected in series. The rectifier 1 is connected to an external electric network, from which the induction heater 4 is powered. The device contains an inverter 5 control unit, the input of which is connected to the output of the temperature comparison unit 7. Output the inverter control unit 5 is connected to the inverter 2 input. The temperature comparison unit 7 has 3 inputs and 3 outputs: the inputs are electrically connected to the outputs of the temperature sensor 6, the input temperature sensor flow 8 and temperature sensor of the output stream 9, and the outputs with the control unit of the inverter 5, the control unit of the pump 10 and the control unit of the shut-off and regulating body 11. The output of the pump control unit is connected to the control input of the pump 12, which supplies liquid to the induction heater 4 The output of the control unit of the locking regulatory body 11 is connected to the input of the automatic locking regulatory body 13.

The induction heater 4, located horizontally, contains a cylindrical tank 14 made of non-magnetic material in the form of a thick-walled pipe with a vertical wall 15 installed in the direction of fluid motion, and a cylindrical element coaxially located inside the tank 14, made in the form of a thin-walled heat-exchange pipe 16 of ferromagnetic material. The wall 15, made of non-magnetic material, allows you to change the direction of movement of the fluid flow, thereby providing a countercurrent system. Between the cylindrical tank 14 and the heat exchange tube 16, an annular space is formed for the passage of the heated fluid. The heat exchange pipe 16 is placed inside the cylindrical tank 14 with a gap of at least 20 mm. An electrothermal insulation strip 17 is laid along the outer surface of the cylindrical container 14, then a current-conducting induction winding 3 is fixed. A magnetically conducting shield 18 made of magnetodielectric and a heat-insulating casing 19, which reduces heat loss to the environment, are located on top of the induction heater 4.

The heat exchange tube 16 is provided with horizontal heat exchange rods 20 mounted staggered inside it. This arrangement of the rods 20 in comparison with other possible options gives the maximum thermal effect from their use (due to the support of the heat exchange rods 20 of the flow turbulence process, which leads to the intensification of the heat transfer process between the liquid medium and the heat exchange rods 20) and, at the same time, not prevents the free flow of fluid. Heat transfer rods 20 are made of ferromagnetic material.

The heat exchange pipe 16 is also equipped with a temperature sensor 6 mounted on the outer surface of the pipe 16, and heat exchange hemispheres 21 located on its outer surface in a checkerboard pattern. The heat exchange hemispheres 21 are made of ferromagnetic material. The installation of heat-exchange hemispheres 21 provides turbulization of the fluid flow in a thin near-wall layer of the pipe 16, which allows to intensify the heat transfer process. The installation of heat-exchange hemispheres 21 is recommended when the gap between the pipe 16 and the cylindrical tank 14 from 30 mm and above.

Thus, the induction heating element in the device is formed by a combination of nodes — a magnetic shield 18, an induction winding 3, a heat exchange pipe 16 with heat exchange rods 20 and hemispheres 21.

The temperature sensor 6 is mounted on the upper generatrix of the outer cylindrical surface of the pipe 16 and serves to control the temperature of the liquid in a thin near-wall layer of the pipe 16.

The inlet discharge pipe 22 and the outlet suction pipe 23 are equipped with a bypass pipe 24 with an automatic shut-off and regulating body 13, one end of which is located in the cross section of the discharge pipe 22, and the other end is in the cross section of the suction pipe 23. The bypass pipe 24 allows multiple pumping through the device heated fluid for quick heating. Automatic shut-off and regulating body 13 allows you to change the volume of the return flow over a wide range.

At the inlet of the discharge inlet pipe 22, the pump 12 is mechanically fixed. During operation of the induction heater 4, the pump 12 continuously pumps the heated fluid.

The cross-sectional area of the annular space between the heat exchange pipe 16 and the cylindrical tank 14 should be equal to the cross-sectional area of the cavity of the pipe 16, and should also provide the required throughput of the device. Recommended external diameters of the heat transfer pipe 16 and the corresponding diameters of the cylindrical tank 14 are presented in the table in figure 4. The length of the cylindrical tank 14 is determined by the required amount of heating of the pumped liquid, but should be at least 1.5 m.

The presence of a countercurrent system, due to which the heated fluid passes twice along the induction heater 4 — first, along the inner cavity of the heat exchanger pipe 16, then in the opposite direction along the annular annular space created by the heat exchange pipe 16 and the cylindrical tank 14 — minimizes the dimensions of the induction heater (horizontal linear size ) and increase the efficiency of its work.

The device operates as follows. Induction heater 4 is connected to an electrical network in 220V / 380V using a rectifier 1, which converts alternating electric current into direct current. The inverter 2 converts the direct current to high-frequency alternating current and supplies it to the induction winding 3 of the induction heater 4. The oil product, under the pressure created by the pump 12, enters the inlet discharge pipe 22. At the same time, the high-frequency current is supplied to the induction winding 3. By supplying a high-frequency current flowing in the induction winding 3, a high-frequency alternating magnetic field is created around the winding 3. The magnetic screen 18 reduces the magnitude of the magnetic flux scattering, which increases the efficiency of the device.

Since the frequency of changes in the magnetic field is very high, eddy currents are induced in the ferromagnetic material of the heat transfer pipe 16 at a shallow depth, which minimizes the wall thickness of the heat transfer pipe 16. The heat transfer pipe 16 is made of sheet ferromagnetic steel, which solves the problem of reducing the metal consumption, the weight of the induction heater, and also reduces the thermal inertia of the device. The cylindrical tank 14 is made of non-magnetic steel, which allows to reduce the heating value of the tank 14 as a result of exposure to an alternating magnetic field, and thereby reduce the amount of heat loss to the environment. The wall thickness of the cylindrical container 14 should provide sufficient strength and reliability of the device.

Further, in the heat exchange pipe 16, the process of heating the pumped oil product begins by flowing around the hot horizontal heat exchange rods 20 of ferromagnetic material horizontally located on its axis and the smooth inner surface of the heat exchange pipe 16. The pipe 16 and heat transfer rods 20 release heat energy as a result of exposure to high-frequency alternating magnetic field inducing in the ferromagnetic material of the heat exchange pipe 16 and heat transfer rods 20 heating eddy currents.

From the eddy currents due to the electrical resistance of the ferromagnetic material, the heat exchange tube 16, the heat exchange rods 20, and also the hemispheres 21 are heated.

At the exit of the heat exchange tube 16, the fluid flow is directed into the hemispherical wall 15. Further, the liquid moves in the opposite initial direction along the annular annular space created by the pipe 16 and the cylindrical tank 14, while heating up from the outer wall of the pipe 16 and the heat-exchange hemispheres 21 welded to it.

The heated liquid under pressure exits through the suction pipe 23 located in the lower part of the cylindrical tank 14. This location of the suction pipe 23 contributes to the removal of accumulations (various solid fractions of the oil product) that can accumulate along the lower generatrix of the cylindrical container 14.

If the temperature comparison unit 7 registers, by means of the temperature sensor 6, the temperature of the pipe wall heating 16 exceeding the boiling point of the light fractions contained in the oil product, the corresponding signal is transmitted from the temperature comparison unit 7 to the inverter control unit 5, after which the inverter control unit 5 s using the inverter 2 reduces the power of the induction heater 4 by reducing the current supplying the induction winding 3. This algorithm allows you to minimize zmozhnost an emergency, thereby increasing the reliability of the device.

To regulate in real time the temperature of the oil at the outlet of the induction heater inside the suction pipe 23 and discharge pipe 22, a temperature sensor for the output stream 9 and a temperature sensor for the input stream 8 are installed. The temperature comparison unit 7 receives signals from the temperature sensor of the input stream 8 and the temperature sensor of the output stream 9, compares them and, on the basis of this, transmits a signal to the control unit of the inverter 5 about the need to increase or decrease the current heating power of the oil product by the induction heater 4.

In the case when it is required to carry out rapid heating of the oil product to a high temperature, but the temperature comparison unit 7 registers the maximum heating temperature (close to the boiling point of light oil fractions) of the pipe 16, heat transfer rods 20 and hemispheres 21, from the temperature sensor 6, for the given oil product temperature 7 sends a corresponding signal about the need to increase the temperature of the output stream to the control unit of the locking and regulating body 11, which, in turn, opens a -automatic shut-off and regulating body 13 by a certain amount. At the same time, if it is necessary to maintain or increase the volume of pumped oil product per unit time, the temperature comparison unit 7 transmits to the pump control unit 10 a signal about the need to increase the supply of pump 12. After that, the heated oil product is circulated in the induction heater 4 due to its multiple passage through the bypass pipe 24, which leads to accelerated heating of the oil to the desired temperature.

The horizontal location of the induction heater 4 allows you to operate it in industrial buildings having small dimensions in the vertical direction, as well as facilitate the installation and maintenance of the device.

The magnetic shield 18, the electrothermal insulation strip 17 and the heat-insulating casing 19 in the device perform an energy-saving function.

Thus, the device provides increased reliability while simplifying its design and reducing the dimensions and weight of the heater.

Claims (1)

A device for induction heating of petroleum products, including an induction heater enclosed in a magnetic shield, and then in a heat-insulating casing and containing an induction winding with an electrothermal insulation gasket covering a cylindrical container containing a cylindrical element and having an input and output pipe connected to the pipeline, an AC rectifier and inverter connected to the induction winding and the inverter control unit, input and output temperature sensors, soy internal with a temperature comparison unit, which is connected to the inverter control unit and the pump control unit connected to the pump, characterized in that it is equipped with a bypass pipe, one end of which is located in the cross section of the inlet discharge pipe, at the input of which the pump is mechanically fixed, and the other end - in the cross section of the outlet suction pipe, with an automatic locking and regulating body connected to the control unit of the locking and regulating body connected to the temperature comparison unit, while The heater is arranged horizontally, the cylindrical tank is made of non-magnetic material with a vertical wall installed in the direction of fluid movement, and the cylindrical element is made in the form of a heat transfer pipe made of ferromagnetic material, which is located inside the cylindrical tank with a gap and is equipped with horizontal heat exchange rods installed inside the pipe in a checkerboard order, heat-exchange hemispheres, located on its outer surface in a checkerboard pattern, and thermal sensor a person installed on the outer surface of the heat exchanger pipe and connected to the temperature comparison unit.

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