RU2240658C2 - Induction-type liquid flow heater (alternatives) - Google Patents

Abstract

FIELD: electrical engineering; heating flows of liquids such as oil; continuous bright annealing of metal.

SUBSTANCE: proposed flow heater of both design alternates has multileg transformer core whose legs carry multiphase primary winding connected to ac supply mains and secondary winding that functions as electricity conducting heat exchanger with inlet and outlet pipes for passing heated liquid. Secondary phase winding of first design alternate is connected in series to form closed circuit made in the form of continuous tube; secondary winding turns made in the form of continuous tube sections constitute series-connected secondary phases of which at least one is differentially connected to other phases and is asymmetrically disposed relative to magnetic flux built up in primary winding. Secondary phase winding in second design alternate is made in the form of three parallel circuits with phases in each of these circuits being connected in series and one of them, differentially connected to other phases, differentially connected phased of primary windings being alternating in each parallel circuit. Effective use of secondary-winding specific heat-transfer surface and of entire spectrum of higher-harmonic currents have made it possible to raise thermal efficiency of heater to 95%.

EFFECT: enhanced intensity of inductive heating and thermal efficiency of heater.

2 cl, 2 dwg

Description

The present invention relates to electrical engineering and can be used to heat liquids in a stream, such as oil.

In addition, instantaneous fluid heaters can be used for bright continuous annealing of metal.

A transformer type electric heating device is known that contains a spatial magnetic circuit with a three-phase primary winding and a short-circuited secondary winding made of straight tubes placed between the terminals of the magnetic circuit with the primary winding and connected at the ends by disks (see RF patent No. 2101882, Mcl. 6 N 05 In 6/10, publ. 10.01.98, "Transformer-type electric heating device"). The secondary winding together with the casing creates a sealed chamber, inside of which there is a magnetic circuit with a primary winding.

In the known electric water heating device, a secondary winding made of straight tubes placed between the rods of the magnetic circuit is located symmetrically with respect to the magnetic circuit with a three-phase primary winding and a three-phase magnetic flux system.

A disadvantage of the known transformer type electric water heating device is the small specific heat transfer surface of the secondary winding. This drawback is due to its structural design and symmetrical arrangement with respect to the magnetic circuit and the three-phase primary winding, in which there are no conditions for the flow of higher harmonics currents in it.

The closest in technical essence and the achieved effect to the claimed technical solutions is a flow-type induction-type fluid heater selected as a prototype, comprising a multi-core ferromagnetic transformer core with a multiphase primary winding connected to the AC mains and a secondary winding being an electrically conductive heat exchanger with inlet and outlet nozzles for the passage of the heated fluid (see RF patent No. 2074529, IPC 6 N 05 V E 21 V 17/10, about published on February 27, 1997, “Induction fluid heater”).

The known instantaneous fluid heater contains a laminated multi-rod (for example, three-phase) ferromagnetic core of a transformer with a multiphase primary winding located on the core rods, connected to the network and insulated from the rods.

The secondary winding of the transformer is a heat exchanger and is made in the form of a hollow chamber with a lower inlet and upper outlet pipes for the passage of the heated fluid.

The camera has through vertical channels with electrically conductive walls, in each of which core rods are installed with a gap.

To intensify the induction heating of a liquid in a known heater, it is possible to use thermal concentrators in the form of electrically conductive circuits closed around the walls of each phase channel (for example, rings). In these rings, part of the energy is converted into heat, and their surface is involved in direct heat exchange with the heated fluid.

The location of the secondary winding, made in the form of a hollow chamber, having vertical through channels with electrically conductive walls, in each of which core rods are installed, with respect to the three-phase primary winding system, to the magnetic circuit and, therefore, to the magnetic flux, is symmetrical.

Such a design and symmetrical arrangement of the secondary winding with respect to the magnetic circuit of the three-phase system is advisable from the point of view of reducing heat transfer from the outer surface of the walls of the phase channels to the primary windings.

The symmetrical arrangement of the secondary winding with respect to the magnetic circuit of the three-phase system and to the magnetic flux of the primary winding does not allow the most complete conversion of the energy consumed from the network into thermal energy and increase the specific heat transfer surface while simplifying the design and reducing the specific material consumption of the secondary winding - heat exchanger.

This is due to the complex structural design of the secondary winding of the heat exchanger and its symmetrical arrangement with respect to the magnetic circuit, which does not ensure the full induction in it of the entire spectrum of higher harmonic currents created by the primary winding, and an increase in the specific heat transfer surface. This design embodiment does not provide an increase in thermal efficiency up to 95% and does not sufficiently intensify the induction heating of the liquid in the heat exchanger.

With a symmetric arrangement of the secondary winding of a three-phase system, the odd and zero components of magnetic fluxes are equal to zero, the heat transfer surfaces, in which induction of currents from the odd and zero components of magnetic fluxes are possible, do not participate in heating, since currents do not flow in them.

In addition, the flow-through induction-type fluid heater contains several separately located through vertical channels between which stagnant zones are formed in which local overheating of the heated medium is possible.

To eliminate stagnant zones and enhance circulation of the heated fluid inside the chamber, a known heater must be equipped with an additional pump.

Due to the complex design, the heater is not technologically advanced.

The disadvantages of the known instantaneous flow fluid heater of the induction type are:

- insufficiently intense induction heating of the liquid due to the impossibility of the full use of the specific heat transfer surface of the secondary winding and the incomplete use of the entire spectrum of the higher harmonics currents throughout its design;

- low thermal efficiency, less than 95%, compared with the proposed options for instantaneous heater;

- the complexity of constructive and technological solutions;

- increased overall dimensions.

The technical result of the proposed inventions consists in eliminating the indicated disadvantages of the prototype, namely, in intensifying induction heating of the liquid by time parameters and increasing the thermal efficiency to 95% due to more complete use of the specific heat transfer surface of the secondary winding and more complete use of the entire spectrum of higher harmonics currents in the design heat exchanger, in simplifying the design and increasing manufacturability.

The technical result is achieved by the following solutions. In a flow-through fluid heater of an induction type according to the first embodiment, comprising a multi-core ferromagnetic core of a transformer with a multiphase primary winding connected to the AC mains and a secondary winding being an electrically conductive heat exchanger with inlet and outlet nozzles for passing the heated fluid, according to the invention, a secondary phase the winding is connected in series in a closed loop made by a continuous tube, turns of the secondary winding, execution ennye a continuous tube sections form a series-connected secondary phase of at least one of which is enabled and the other oppositely disposed asymmetrically to the magnetic flux produced in the primary winding.

In a flow-type induction-type fluid heater according to the second embodiment, comprising a multi-rod ferromagnetic transformer core with a multiphase primary winding connected to the AC mains and a secondary winding being an electrically conductive heat exchanger with inlet and outlet nozzles for passing the heated fluid, according to the invention, a secondary phase the winding is made in the form of three parallel branches, in each of which the phases are connected in series, and one of them is dinene is opposed to another, and in each parallel branch, the counter-switched phases of the secondary windings alternate.

In the flow-type induction-type fluid heater according to the first embodiment, the serial connection of the secondary phase winding asymmetrically covering the primary winding in a closed loop made by a continuous tube makes it possible to induce in the continuous tube the entire spectrum of higher harmonic currents induced by the forward, reverse, and zero sequences of the magnetic flux generated primary windings. This allows you to more fully use the specific heat transfer surface of the secondary winding and to intensify the induction heating of the liquid in all sections of the continuous tube of the heat exchanger.

An asymmetric circuit makes it possible to exist in a closed circuit of the secondary winding, which is an electrically conductive heat exchanger, asymmetric components of magnetic flux that would not exist if the secondary winding were symmetrically positioned relative to the magnetic flux generated in the primary winding.

The turns of the secondary winding, which are sections of a continuous tube, form serially connected secondary phases. The inclusion of at least one of the secondary phases counter to the other phases ensures the asymmetry of this phase to the magnetic flux generated in the primary winding.

The implementation of the secondary phase winding connected in series in a closed loop in the form of a continuous tube allows you to simplify the design of the fluid heater, reduce weight and size, and improve the manufacturability of its manufacture.

In the second embodiment, the flow-through induction-type fluid heater contains a secondary phase winding made in the form of three parallel branches, the phases in each of which are connected in series.

One of the phases is connected counter to the other, which allows you to create an asymmetry of the components of the magnetic fluxes. The asymmetric connection scheme of one of the phases makes it possible to exist in a closed circuit of the secondary winding, which is an electrically conductive heat exchanger, asymmetric component of the magnetic fluxes of the primary winding.

This makes it possible to use the entire spectrum of higher harmonics currents induced by the forward, reverse, and zero sequences of the magnetic flux generated by the primary windings along the entire length of the tube to heat the liquid.

The alternation in each parallel branch of the on / off phases of the secondary windings creates an asymmetry of the constituent magnetic fluxes in the second and third phases of the closed loop of the secondary winding, which makes it possible to more fully use the specific heat transfer surface of the secondary winding, to increase the proportion of energy spent on heating the continuous tube, which is the secondary winding, to intensify the induction heating of the liquid in all parts of the heat exchanger, to improve the energy performance of the inventive flow heater .

The claimed technical solutions underwent laboratory tests, the results of which revealed the possibility of a more complete use of the specific heat transfer surface of the secondary winding, increase of thermal efficiency up to 95% while simplifying the design and manufacturability, and reducing overall dimensions.

According to the authors, the distinguishing features of the claimed technical solutions of the induction-type flow-through fluid heater satisfy the criterion of “inventive step”, since at the date of the application, identical devices with such distinctive features were not found in available sources of scientific and technical information, as well as patent documentation new, positive effect, unusual for known instantaneous heaters.

The claimed technical solutions of the flow heater can be made on standard equipment of engineering plants.

Therefore, the proposed technical solutions meet the criterion of "industrial applicability".

The essence of the proposed technical solutions is illustrated by drawings.

Figure 1 shows a schematic diagram of a flow-through fluid heater of an induction type according to the first embodiment of the claimed technical solutions.

Figure 2 shows a schematic diagram of a flow-through fluid heater induction type according to the second embodiment of the claimed technical solutions.

The flow-through fluid heater of the induction type according to the first embodiment contains (see Fig. 1) a three-core ferromagnetic core 1 of a transformer with a three-phase primary winding 2 located on the rods made of copper or aluminum wire connected to an alternating current main and a secondary winding 3, which is an electrically conductive heat exchanger made of copper, with inlet and outlet pipes for the passage of the heated fluid. The primary winding 2 is connected in a star circuit with zero. The secondary phase winding 3, made by a continuous tube, is connected in series in a closed loop according to an open triangle circuit.

The turns of the secondary winding 3, which are continuous parts of the conductive tube, form serially connected secondary phases, at least one of which is connected counterclockwise and is located asymmetrically to the magnetic flux generated in the primary winding 2.

The induction-type flow-through fluid heater according to the second embodiment comprises a multi-core ferromagnetic core 1 of a transformer with a three-phase primary winding 2 located on the rods and connected to an alternating current main, and a secondary winding 3, which is an electrically conductive heat exchanger with inlet and outlet pipes for the passage of the heated fluid. The secondary phase winding 3 is connected in series in a closed loop made by a continuous tube.

The turns of the secondary winding 3 form a series-connected secondary phases, at least one of which is connected counterclockwise and is located asymmetrically to the magnetic flux generated in the primary winding 2.

In each parallel branch, the oncoming phases of the secondary windings alternate.

The inventive instantaneous fluid heater induction type (two options) is operated as follows.

To connect a flow heater to the transformer oil preparation line, the primary winding is connected to a three-phase current network, and transformer oil flows through the secondary winding, which is heated to 80 ° C.

As a result of research, it was found that the proposed flow-through induction-type fluid heater (two options) allows, in comparison with the prototype:

- to intensify the induction heating of the liquid according to time indicators;

- increase the value of thermal efficiency to 95% due to a more complete use of the specific heat transfer surface of the secondary winding and a more complete use of the spectrum of currents of higher harmonics in the design of the heat exchanger;

- to simplify the design and increase the manufacturability of the manufacture of heater devices.

Claims (2)

1. A flow-through induction-type fluid heater containing a multi-rod ferromagnetic core of a transformer with a multiphase primary winding connected to the AC mains and a secondary phase winding being an electrically conductive heat exchanger with inlet and outlet nozzles for passing the heated fluid, characterized in that the secondary the phase winding is connected in series in a closed loop made by a continuous tube, the turns of the secondary winding being continuous the other parts of the tube form series-connected secondary phases, one of which is connected counter-to the other and is located asymmetrically to the magnetic flux created by the primary winding. 2. A flow-through induction-type fluid heater containing a multi-rod ferromagnetic core of a transformer with a multiphase primary winding connected to the AC mains and rods of the secondary phase winding, which is an electrically conductive heat exchanger with inlet and outlet nozzles for passing the heated fluid, characterized in that the secondary the phase winding is connected in series in a closed loop made by a continuous tube, consists of three branches, in each of which The basics are connected in series, and one of them is connected opposite to the other and is located asymmetrically to the magnetic flux created by the primary winding, and in each branch the counter-switched phases of the secondary windings alternate.

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