GB2144957A - Induction heater - Google Patents

Abstract

A travelling wave induction heater comprising a plurality of primary windings (W) and associated core means (P), means to connect successive windings to successive phases of a multi-phase electric supply to provide the primary of the travelling wave induction heater, and an electrically conductive member which provides the secondary of the heater, wherein the secondary (20,21;24,25;36,38;41) has a non-uniform electrical conductivity, the distribution of electrical conductivity being such as to provide a desired distribution of heating in the secondary.

Description

1 GB2144957A 1

SPECIFICATION

Travelling wave induction heater This invention relates to a travelling wave 70 induction heater comprising a plurality of pri mary windings and associated core means, and means to connect successive windings to successive phases of a multi-phase electric supply to provide the primary of the travelling wave induction heater, whereby, in use, a travelling magnetic field is produced and there being an electrically conductive member, in which eddy currents are induced by the mag netic field, and which acts as a secondary of the heater and is thereby heated. Such a heater is referred to hereinafter as being of the kind specified.

In heaters of the kind specified, the heating of the secondary may not be uniform for a uniform primary winding distribution and an object of the invention is to overcome this problem.

According to one aspect of the present invention, this problem is overcome by provid ing a heater of the kind specified in which the secondary has a non-uniform electrical con ductivity, the distribution of electrical conduc tivity being such as to provide a desired distribution of heating in the secondary. 95 The secondary may comprise at least part of a workpiece to be heated.

Alternatively, the secondary may comprise a heating member which, in use, heats a work piece by heat transfer.

The secondary may comprise an element of ferro magnetic material, such as cast iron, soft iron or steel, having at least one opening therein and/or area of different thickness.

The secondary may comprise a component 105 of a relatively high electrical conductivity ma terial such as copper or aluminium or zinc or brass, having at least one opening therein and/or area of lower conductivity and/or area of different thickness.

The component may comprise a single element or be fabricated from a plurality of elements.

The secondary may also comprise an ele- ment of ferro magnetic material such as cast 115 iron, soft iron or steel.

The component may be formed separately from the remainder of the secondary and may be secured thereto. Alternatively it may com- prise a coating applied to the remainder of the secondary, for example by spraying.

Alternatively the component may comprise the whole of the secondary, particularly where the secondary comprises said heating mem- ber.

In one application of the invention the secondary comprises a mould of a moulding apparatus.

The mould may be positioned between a pair of relatively movable press members for the application of pressure to the mould.

Examples of the invention will now be described, with reference to the accompanying drawings, wherein:- Figure 1 is a diagrammatic perspective view of a primary of a heater embodying the invention; Figure 2 is a diagrammatic perspective view of a secondary of a heater embodying the invention; Figure 3 is a diagrammatic cross-section through another embodiment; Figure 4 is an underneath plan view of the secondary of Fig. 3; Figures 5 to 8 are diagrammatic perspective views of the primary of other embodiments; Figure 9 is a diagrammatic side elevation of moulding apparatus embodying the invention; and Figure 10 is a cross-section through a still further embodiment.

Referring to Figs. 1 and 2, a travelling wave induction heater embodying the inven tion comprises a primary core P having a plurality of iron laminations 10 which may be insulated to reduce eddy current effects and clamped together by nut and bolt fasteners 11 to provide a series of adjacent teeth 12 having coplanar pole faces 13. The teeth 12 are insulated in conventional manner and copper wire windings W are formed around the teeth with successive windings being connected to successive phases of a multi-phase supply. In the present example, the multi- phase supply is three-phase. If desired, the supply may be of other than three phase, although three phase supply is preferred as it is readily available. Also if desired, the winding may be any other pattern that produces a travelling field,

The thus formed primary is then embedded in epoxy resin (not shown) in conventional manner and a terminal box (not shown) is provided for connection to the multi-phase supply.

A workpiece is indicated at 20 and, in the present example, comprises a block of steel to be heated. In order that the block of steel is heated uniformly, a sheet of copper is secured to the under surface of the block 20 as indicated at 21. The sheet 21 may be secured to the under surface of the block 20 by any desired means, such as by brazing. The sheet 21 thus provides a component of a secondary so that the sheet 21 and block 20 together comprise the secondary of the travelling wave induction heater of which P is the primary core.

The sheet 21 has a series of rectangular openings 22 formed therein, the longer axes of which extend at right angles to the direction of motion of the field. In Fig. 2 only a small number of openings is shown for clarity. It is found in practice, that by providing the sheet 21 with the openings 22 therein, that 2 the heating of the block 20 is more uniform.

Instead of providing the sheet component 21 with the openings 22, the sheet 21 could be of composite construction comprising a relatively high conductivity copper in a region corresponding to the unapertured parts of the sheet 21 and a material of lesser conductivity, such as iron, in a region corresponding to the apertures 22.

Further alternatively, the sheet 21 could be of different thickness in regions corresponding to the unapertured parts of the sheet 21 and the apertured parts of the sheet 21 to achieve the desired variation in conductivity.

Another embodiment is shown in Figs. 3 and 4 in which the primary P is as described above. The secondary is formed in two components 24 and 25 in facial contact, the component 25 having a relatively low conduc- tivity such as iron or steel as described above, and the component 24 have a relatively high conductivity such as copper, aluminium etc. as described above. Grooves 26 extending at right angles to the direction of motion of the field are formed in the component 24. Moreover, the edges of the component 24 are provided with copper or other low resistivity areas 27 which extend in the direction of motion of the field. These three features can be used singly or in any combination.

The above described embodiments have a primary core in which the pole faces 13 are arranged in a plane and in which the field travels along the plane at right angles to the teeth 12.

Other primary and secondary configurations are possible.

Fig. 5 shows another arrangement in which the primary P, is annular and has annular laminations L, and there being coils C lying in 105 radial slots Q, together with an annular secondary not shown. Such a configuration provides a field which travels around the circumference of the annulus. The operation is the same as in the example described above, and one or more of the refinements shown in Figs. 3 and 4 can be incorporated in the arrangement of Fig. 5.

Fig. 6 shows a further arrangement in which the primary P, is a generally cylindrical '115 configuration with the teeth Q, extending par allel to the central axis of the cylinder and disposed side by side around the cylindrical surface thereof. The secondary (not shown) is of complementary configuration and the field 120 travels around the circumference of the cylin der.

Fig. 7 shows a further arrangement in which the primary P, is again of generally cylindrical configuration but with the teeth Q, extending circumferentially of the cylinder and being disposed axially side by side around the cylindrical surface thereof. The secondary is of complementary configuration and the field tra vels along the axis of the cylinder.

GB 2 144 957A 2 Fig. 8 shows a still further arrangement in which the primary P, is of annular configuration but with the teeth Q, also being annular so that the field travels radially. For clarity, only a segment of the circular cone is shown. Again a secondary of complementary configuration is provided.

The primaries of the embodiments illustrated in Figs. 5 to 8 may extend around only part of a circle instead of the full circle as illustrated. Other primary and secondary configurations are possible other than those illustrated and a primary configuration is selected which is most suitable for the application concerned. For example, to heat tubes for example in an extrusion operation, the confi guration shown in Fig. 6 or Fig. 7 would be selected- In all cases the secondary has a configuration complementary to that of the primary and may, for example, be provided with a series of grooves extending parallel to the pole pieces of the primary and perpendi cular to the direction of movement of the field to provide a desired distribution of heating.

In another arrangement (not shown), the construction is similar to that of a motor with a cylindrically extending stator, but the rotor is replaced by a body part again formed from electrically conductive material and within which the eddy currents are generated. One end of the body part can be closed, so that the arrangement can be used to heat a liquid contained within the body part.

Referring now to Fig. 9, a moulding press comprises a fixed press head 31 and a lower press head 32 movable vertically towards and away from the press head 31. The press head 31 has secured thereto a layer of electrically non-conduc+ive and thermally insulating material 33 and a wear plate 34 of suitable material such as stainless steel. The primary windings of a heater, such as that described with reference to Fig. 1, are mounted on the press head 32 as indicated at 35 and is also provided with a layer of electrically non-conductive thermal insulating material 33a, and a wear plate 34a similar to the wear plate 34.

A mould comprising a plurality of cavities for articles to be moulded is indicated at 36 and is removably engageable between the press heads 31 and 32. In use, the press head 32 is moved upwardly towards the press head 31 to apply pressure to the mould and the windings of the heater 35 are energised so that the mould acts as the secondary of the heater and is thereby heated.

In order that the uniform heating of the mould is achieved, the lower surface 37 of the mould adjacent the heater primary 35 has sprayed thereon a layer of copper of high electrical conductivity to provide a component 38 of the secondary which defines a rectangular pattern having rectangular openings therein, similar to the openings 22 in the plate 2 1. This pattern of high electrically 3 GB2144957A 3 conductive material ensures that a uniform heating of the mould is achieved.

If desired, instead of spraying the high electrically conductive material on the mould, the component 38 could be provided with a separately formed sheet of the same configu ration which may be secured to the mould in any desired manner.

In a further embodiment of the invention illustrated in Fig. 10, a heater comprises a primary 40 of the same construction as the primary 10 described with reference to Fig. 1.

Permanently mounted on the primary 40 is a secondary component 41 of copper and ther mally insulated from the primary by a layer of 80 non-electrically conductive thermally insulat ing material 42. The secondary component 41 is made as a sheet of high electrical conductive material such as copper and is provided with rectangular openings 43. A wear plate, such as of stainless steel 4-4 is provided over the secondary component 41.

In use, a workpiece to be heated is placed on top of the wear plate 44 and is heated primar ily by heat transfer from the secondary com ponent 41. By virtue of providing the open ings 43 in the secondary component 41, a uniform heating effect is achieved in the work piece. The secondary component 41 may be of any other configuration as described above 95 in embodiments described with reference to Figs. 1 to 4.

The secondary components may be of the same external configuration as described above but have a different pattern of opening or other region(s) of lower electrical conductiv ity therein, determined empirically to achieve a desired heating distribution. If desired, a secondary may be made of the same material, e.g. cast iron, soft iron or steel, throughout its extent, the distribution of electrical conductiv ity being achieved by providing openings or regions of reduced thickness in the secondary, for example, of any of the configurations described hereinbefore in connection with the preceding embodiments.

The features disclosed in the foregoing de scription, or the following claims, or the ac companying drawings, expressed in their spe cific forms or in terms of a means for perform ing the disclosed function, or a method or process for attaining the disclosed result, or a class or group of substances or compositions, as appropriate, may, separately or any combi nation of such features, be utilised for realis ing the invention in diverse forms thereof.

Claims (16)

1. A heater of the kind specified in which the secondary has a non-uniform electrical conductivity, the distribution of electrical con ductivity being such as to provide a desired distribution of heating in the secondary.

2. A heater according to Claim 1 wherein the secondary comprises at least part of a workpiece to be heated.

3. A heater according ato Claim 1 wherein the secondary comprises a heating member which, in use, heats a workpiece by heat transfer.

4. A heater according to any one of the preceding claims wherein the secondary cornprises an element of ferro magnetic material, having at least one opening therein and/or area of different thickness.

5. A heater according to any one of the preceding claims wherein the secondary cornprises a component of a relatively high electricat conductivity material such as copper or aluminium or zinc or brass, having at last one opening therein and/or area of lower conductivity and/or area of different thickness.

6. A heater according to Claim 5 wherein the component comprises a single element.

7. A heater according to Claim 5 wherein the component is fabricated from a plurality of elements.

8. A heater according to any one of Claims 5 to 7 wherein the secondary also 90 comprises an element of ferro magnetic ma- terial such as cast iron, soft iron or steel.

9. A heater according to any one of Claims 5 to 8 wherein the component is formed separately from the remainder of the secondary and secured thereto.

10. A heater according to any one of Claims 5 to 8 wherein the component cornprises a coating applied to the remainder of the secondary. 100

11. A heater according to Claim 10 wherein the coating is applied by spraying.

12. A heater according to any one of Claims 5 to 8 wherein the component cornprises the whole of the secondary. 105

13. A heater according to any one of the preceding claims wherein the secondary cornprises a mould of a moulding apparatus.

14. A heater according to Claim 13 wherein the mould is positioned between a pair of relatively movable press members for the application of pressure to the mould.

15. A heater substantially as hereinbefore described with reference to and as shown in the accompanying drawings.

16. Any novel feature or novel combina- tion of features disclosed herein and/or shown in the accompanying drawings.

Printed in the United Kingdom for Her Majesty's Stationery Office, Dd 8818935, 1985. 4235. Published at The Patent Office. 25 Southampton Buildings, London, WC2A lAY, from which copies may be obtained.