RU2286394C2 - Slit-type inductor - Google Patents

Abstract

FIELD: induction heating of thin flat articles in electromagnetic field, in particular, heating of edges of thin 20-50 mm thick slabs and rolling strips.

SUBSTANCE: slit-type inductor has two spirals of inducing wire arranged in spaced apart relation at both sides of slit plane and electrically connected with one another. Axes of spirals of inducing wire are arranged in parallel with plane of slit and spiral cross-sectional plane is oriented perpendicular to plane of slit. Spiral coils may be oval-shaped, with elongated axis of ovals being oriented along plane of slit. Inductor may additionally comprise U-shaped magnetic circuit whose open sides are arranged within spirals of inducting wire. Such an inductor enables selective heating in longitudinal, transverse or mixed magnetic field by selecting switching or winding of coils, respectively.

EFFECT: increased efficiency by regulating heating process and simplified construction of slit-type inductor.

3 cl, 2 dwg

Description

The invention relates to the field of induction heating of thin flat products in an electromagnetic field. In particular, the invention can be used to heat the edges of thin slabs with a thickness of 20-50 mm and strips in modern lines "continuous casting - continuous rolling"; for heating the edges of metal strips in continuous coating lines and in other similar cases when it is necessary to heat long, flat thin products in an electromagnetic field.

The need for local heating of the edges of thin flat long products (strips, slabs, rolled, etc.) arises due to the fact that during the manufacturing process when moving the product from operation to operation, there is an uneven distribution of temperature across the width of the product due to faster cooling of the edges along compared with the bulk of the product. This leads to uneven properties of the finished product. This problem is especially acute in the field of metallurgy in mills for the continuous production of rolled products. Currently, the most effective means of solving it is recognized as the use of additional local edge heating between operations using induction heating using slotted inductors of various designs.

Known slotted inductor with a longitudinal magnetic field [1], which allows you to concentrate the heating in the region of the edges and representing turns of the induction wire located in parallel at a small distance from each other and forming a gap through which the processed flat product, for example a strip, is passed. The turns are made in the form of flat, close to rectangular, frames electrically connected in series. The heating zone in this design is determined by the width of the turns above the edge. Such an inductor is structurally simple enough.

The disadvantage of this inductor is the need to use a sufficiently high current frequency at which the current penetration depth would not exceed 2.5-3 thickness of the product, which leads to a significant increase in the cost of the power source. Wrong frequency selection leads to a sharp deterioration in heating efficiency. In addition, due to the large dispersion fluxes, this type of inductor has a low power factor.

The closest in technical essence to the proposed solution (prototype) is a well-known version of the inductor with a transverse magnetic field for heating the edges of a flat product (strip), the so-called C-shaped inductor [2]. Such an inductor includes a C-shaped magnetic circuit, between which two open parts of which a gap is formed, two spirals (coils) of the induction wire located respectively around the open parts of the magnetic circuit and electrically connected to each other. In this design, the plane of the gap is perpendicular to the open parts of the magnetic circuit, the spirals of the induction wire are located on both sides of the plane of the gap and their axis is perpendicular to it. It is significant that the role of the coils is reduced only to the generation of magnetic flux passing in the magnetic circuit.

The edge of the strip is passed through the slot, the magnetic flux penetrates it across, and the currents induced in the plane of the strip are concentrated at the edge, causing it to heat, and are closed along the bulk of the metal, without leading to noticeable heating, that is, in this case, the power is allocated directly to the edge of the strip.

The main advantage of such an inductor is that heating occurs at a significantly lower frequency than when heated in a longitudinal magnetic field, the inductor’s energy performance (efficiency and power factor) and the possibility of matching it with a power source without an additional transformer are improved by choosing the optimal number of turns.

The disadvantage of this inductor is the need for strict positioning of the magnetic circuit of the inductor relative to the edges of the strip with a sufficiently small gap between the strip and the ends of the magnetic circuit. Such an inductor allows you to very slightly change the width of the heating zone by shifting the entire structure of the inductor relative to the strip due to the concentration of current directly on the edge of the product. This design requires the presence of a magnetic circuit to obtain electromagnetic coupling between the inductor and the strip metal and, therefore, makes the device quite heavy and metal-intensive.

The problem solved by the invention is the creation of a heater that combines the advantages of a slit inductor with a longitudinal magnetic field and a C-shaped inductor with a transverse magnetic field and provides more control over the heating process.

The technical effect that provides the solution to the problem is that in the proposed design, the heating of the object is carried out not only due to the total magnetic flux generated by the two coils, but also due to the external fields of each coil. Moreover, if the edge is heated mainly due to the total magnetic flux, then in general, the heating zone is determined by the width of the inductor above the strip edge, if it is possible to control the width of the heating zone by choosing the necessary coil displacement relative to the product, while significantly simplifying the entire heating device and reducing its metal consumption and good features coordination with the power source by selecting the number of turns of the coils.

The proposed design of the inductor also allows heating in a longitudinal or transverse magnetic field by selecting the appropriate connection or winding of the inductor coils. When connecting the coils to two power sources, it is possible to produce heating in a mixed field, for example, by adding a component of the longitudinal magnetic field to the transverse magnetic field. This leads to an expansion of the possibilities of regulating the heating process.

The ability to control the width of the heating zone makes it possible to install both inductors and the bulk of the product when both inducers are installed on both sides of the workpiece with two inductor widths over the edge equal to almost half the width of the product. This eliminates the use of other inductors for heating the total mass of the product.

The specified result is achieved by the fact that in the known slotted inductor, including two spirals of the induction wire located at a distance from each other on both sides of the plane of the gap and electrically connected to each other, in contrast to the known axis of the spirals of the induction wire are parallel to the plane of the gap, and the plane the cross section of the spiral is oriented perpendicular to the plane of the gap. The coils of the spiral can have an oval shape, the long axis of which is oriented along the plane of the gap.

The inductor may further comprise a U-shaped magnetic circuit whose open sides are located inside the spirals of the induction wire.

The present invention is new, since at the present time similar slotted inductors are not known, characterized by a given set of features.

The main difference of the proposed device is a new mutual arrangement of structural elements. This difference leads to the achievement of the specified technical effect. Additional differences in the embodiments provide additional benefits.

The essence of the proposed solution lies in the fact that the differences in the proposed design provide the ability to control the width of the heating zone by selecting the required shift of the coils relative to the product, if it is possible to match the inductor with the power source by choosing the optimal number of turns of the coils. In this design, the induced current is concentrated under the inductor due to the proximity effect.

In addition, in this design of the inductor with the same polarity and the same connection of the coils (the current in the coils flows in one direction), a longitudinal field is created, otherwise a transverse field. When connecting coils to two power sources (or to one source with two outputs) and, providing a phase shift of the current between the upper and lower coils, it is possible to produce heating in a mixed field, for example, by adding a component of the longitudinal magnetic field to the transverse magnetic field.

Thus, by selecting the appropriate connection or winding of the inductor coils in this design, it is possible to heat in a longitudinal, transverse or mixed magnetic field of your choice.

The execution of the turns of the coil oval with a long axis, oriented along the plane of the slit, is preferred. In this case, the ratio of the size of the coil in the direction of the long axis and the size of the coil in the direction of the short axis 2: 1 is optimal. This leads to an optimal combination of heating with a common magnetic field and an external field of coils.

In the presence of an additional U-shaped magnetic circuit, the open sides of which are located inside the turns of the coil, the electromagnetic coupling between the inductor and the product is improved, which leads to a decrease in current and an increase in the efficiency of the inductor. In addition, in comparison with the prototype, the magnetic circuit is protected from the radiation of a heated body by water-cooled coils and therefore it is in more favorable operating conditions.

The proposed solution is not obvious, since it does not follow explicitly from the existing level of technology. This is due to the fact that currently conducting full-scale studies of thermophysical processes that occur during induction heating under the described production conditions is almost impossible - ultra-expensive, technically very difficult, requires the withdrawal of complex production equipment from the continuous operation mode, etc. Therefore, it is effective to use methods of mathematical modeling. However, it is impossible to develop a mathematical model that describes all the possible uses of induction heating, therefore, to solve each specific production problem, it is necessary to develop a specific model. This is very difficult, since for various production situations there are a lot of specific, specific and different ones that determine the process of initial conditions and parameters. Therefore, the existing designs of inductors are far from universal and force for each new task to seek its solution most often by modeling.

The proposed inductor combines the advantages of a slotted inductor with a longitudinal magnetic field with the advantages of a C-shaped inductor with a transverse magnetic field and at the same time provides very wide possibilities for choosing a heating option (in a longitudinal, transverse, mixed field). Thus, the inductor according to the invention is more versatile, as it allows you to solve a wider range of technological problems (easily adapts to changes in technological problems).

The invention is illustrated in figures 1, 2, which show:

figure 1 is a schematic illustration of the proposed slotted inductor and the location of the heated metal strip,

figure 2 - distribution of specific power across the width of the strip for various designs of inductors.

In figure 1:

1 - spiral (coil) of the induction wire,

2 - axis of the coil of the induction wire,

3 - plane of the slit,

4 - U-shaped magnetic circuit,

5 - a heated strip of metal,

6 - the gap between the heated strip and the coil of the inductor,

7 - shift of the strip in the slit of the inductor.

In figure 2:

2A is a curve of the distribution of temperature along the width of the strip when heating the edges in a C-shaped inductor (prototype),

2b is a curve of the temperature distribution over the width of the strip when heating the edges in the proposed slotted inductor with a magnetic circuit (invention),

2c is a curve of the temperature distribution over the width of the strip when the edge is heated in a slotted inductor (analog).

The inductor according to the invention consists of two spirals 1 of the turns of the induction wire, the axes 2 of which are parallel to the plane 3 of the slit of the inductor, and the section planes are perpendicular to plane 3. The given variant of the inductor includes a U-shaped magnetic circuit 4, around the open branches of which there are spiral coils 1. Heated a strip of metal 5 is installed in the slit of the inductor relative to the spiral 1 with a gap of 6 and a shift of 7 relative to the distant (remote from the edge of the strip) end of the spiral 1.

Figure 2 shows the results obtained by testing the proposed inductor in a sheet rolling mill for heating the edges of the strip of rolled steel 1400 mm wide, 30 mm thick. The speed of the strip is 1 meter per second. With an inductor power of 2 MW, it is necessary to directly heat the edge of the strip at 70-80 ° C. In addition, to ensure the necessary energy reserve for subsequent transportation to the rolling mill, it is necessary to warm up 200-300 mm of the strip edge.

From the data shown in FIG. 2, it can be seen that the inductor according to the invention (2b), unlike the analogue (2c) and the prototype (2a), provides simultaneous heating of both the edge itself and the zone close to the edge of the strip. This improves the quality of the rental and the operating conditions of the rolls of the rolling mill.

Thus, the above data clearly demonstrate the advantages of the invention.

Information sources

1. Sukhotsky A.E., Ryskin S.E. Inductors for induction heating. - L .: Energy, 1974, p. 252.

2. Gorbatkov SA, Kuvaldin AB, and others. Chemical apparatuses with induction heating. - M .: Chemistry, 1985, p.22, Fig. 1.7 g (prototype).

Claims (3)

1. A slotted inductor comprising two spirals of the induction wire located at a distance from each other on both sides of the plane of the slit and electrically connected to each other, characterized in that the axis of the spirals of the induction wire are parallel to the plane of the slit, and the plane of the cross-section of the spirals is oriented perpendicular to the plane cracks. 2. The slotted inductor according to claim 1, characterized in that the turns of the spiral are oval in shape, the long sides of which are oriented along the plane of the slit. 3. The slotted inductor according to claim 1 or 2, characterized in that the inductor further comprises a U-shaped magnetic circuit, the open sides of which are located inside the spirals of the induction wire.

Images