This invention relates to an apparatus and method for inductive heating of a material located in a channel, wherein a heating assembly is disposed in the material in the channel and includes an interior coil which generates a magnetic flux for inductively heating an exterior sheath of the assembly, and may also inductively couple to and heat the material in the channel.
It is common practice to inductively heat an article (e.g., a solid cylinder or hollow tube) of a magnetizable material, such as steel, by inducing an eddy current in the article. This eddy current is induced by an applied magnetic flux generated by passage of an alternating current through a heater coil wound around the article. The heat inductively generated in the article may then be transmitted to another article, e.g., a metal or polymer material flowing through a bore or channel of an inductively heated steel tube.
Various systems have been proposed which utilize different combinations of materials, structural heating elements, resonant frequencies, etc., for such heating techniques. There is an ongoing need for an apparatus and method for heating a material in a channel which provides one or more of higher power density, tighter temperature control, reduced power consumption, longer operating life, and/or lower manufacturing costs.
In accordance with one embodiment of the invention, a method is provided for heating a material located in a channel. The method includes steps of providing an internal inductive heating assembly in the material in the channel, the heating assembly comprising an exterior sheath disposed in contact with the material and an interior coil inductively coupled to the sheath. The method further includes supplying a signal to the coil to generate a magnetic flux for inductive heating of the sheath, wherein the material is heated by conductive heat transfer from the sheath.
In one embodiment, the coil may also be inductively coupled to the material such that the magnetic flux generates inductive heating of the material (as well as the sheath).
In various applications, the material may be heated from a nonflowable to the flowable state. The nonflowable state may be one or more of a physically rigid solid state and a semi-rigid solid state. The flowable state may be one or more of a liquid state and a semi-solid state. In one embodiment, the material is heated from a semi-rigid state to a flowable state. In another embodiment, the material is heated from a rigid state to a flowable state.
More generally, the material may be heated in order to produce a change in its viscosity.
The method may further include cooling of the material. In one embodiment, the channel is provided in an outer element which conductively cools the material. The heating and cooling may be provided intermittently, at regular periodic or nonperiodic intervals. The signal supplied to the coil may be adjusted to provide an alternating heating and cooling cycle.
In various applications, the material is one or more of a metal and a polymer. The material may be one or more of an electrically conductive, ferromagnetic, electrically nonconductive, thermally insulating, and thermally conductive material.
The configuration of the coil and sheath may be adapted for minimizing heating of the coil in order to maintain the coil temperature within an operating limit.
In various embodiments, the coil and sheath may be in thermal contact enabling transmission of heat from the coil to the sheath. The relative temperatures of the coil, sheath and material may vary. Often the coil will be at a highest temperature, the sheath at a lower temperature, and the material at a lowermost temperature.
The signal supplied to the coil may comprise current pulses providing high frequency harmonics in the coil. This signal is particularly useful in systems having a high damping coefficient which are difficult to drive (inductively) with sustained resonance.
In a further embodiment, a method is provided for heating a material located in a channel. The method includes steps of providing an internal inductive heating assembly in the material in the channel, the heating assembly comprising an exterior sheath disposed in contact with the material and an interior coil inductively coupled to the sheath. The method further includes supplying a signal to the coil to generate a magnetic flux for inductive heating of the sheath and/or the material.
In accordance with another embodiment of the invention, a heating assembly is provided comprising an interior coil, an exterior sheath inductively coupled to the coil, a dielectric material disposed between the coil and the sheath, and a conductor for supplying a signal to the coil to generate a magnetic flux for inductive heating of the sheath.
Preferably, a flux concentrator may be provided to increase the inductive coupling between the coil and the sheath. For example, the flux concentrator may be disposed inside the coil.
These and other features and/or advantages of several embodiments of the invention may be better understood by referring to the following detailed description in conjunction with the accompanying drawings.
A first embodiment of the invention is illustrated in
During a next molding cycle, the nonflowable plug must again be heated to a fluid (flowable) state. For this purpose, an inductive heating assembly (probe heater 10) is positioned in the material in the channel 102, with the closed end 16 of the outer sheath disposed at or near the separation area 106. The probe heater 10 is centrally disposed in the channel 102 and is surrounded by a relatively narrow annular width of open channel area. A plug of material will be formed around the sheath in the area 112 at the gate end of the channel. In order to melt the plug (reduce its viscosity) so that material can again be injected through the gate, a magnetic field (see lines 105) is generated by the interior coil 20 of the probe which is transmitted to one or more of the exterior sheath 52 and the material 100 in the channel for inductive heating of the sheath and/or material respectively. The plug is thus heated and converts back to a fluid state, allowing the material to flow around the exterior sheath and exit through the gate 106.
The probe heater according to the present invention is not limited to specific materials, shapes or configurations of the components thereof. A particular application or environment will determine which materials, shapes and configurations are suitable.
For example, the inductor coil may be one or more of nickel, silver, copper and nickel/copper alloys. A nickel (or high percentage nickel alloy) coil is suitable for higher temperature applications (e.g., 500 to 1,000° C.). A copper (or high percentage copper alloy) coil may be sufficient for lower temperature applications (e.g., <500° C.). The coil may be stainless steel or Inconel (a nickel alloy). In the various embodiments described herein, water cooling of the coil is not required nor desirable.
The power leads supplying the inductor coil may comprise an outer cylindrical supply lead and an inner return lead concentric with the outer cylindrical supply lead. The leads may be copper, nickel, Litz wire or other suitable materials.
The dielectric insulation between the inductor coil and outer ferromagnetic sheath may be a ceramic such as one or more of magnesium oxide, alumina, and mica. The dielectric may be provided as a powder, sheet or a cast body surrounding the coil.
The coil may be cast on a ceramic dielectric core, and a powdered ceramic provided as a dielectric layer between the coil and sheath.
The coil may be cast in a dielectric ceramic body and the assembly then inserted into the sheath.
The sheath may be made from a ferromagnetic metal, such as a 400 series stainless or a tool steel.
The flux concentrator may be provided as a tubular element disposed between the coil and the return lead. The flux concentrator may be a solid, laminated and/or slotted element. For low temperature applications, it may be made of a non-electrically conductive ferromagnetic material, such as ferrite. For higher temperature applications it may comprise a soft magnetic alloy (e.g., cobalt).
The coil geometry may take any of various configurations, such as serpentine or helical. The coil cross-section may be flat, round, rectangular or half round. As used herein, coil is not limited to a particular geometry or configuration; a helical wound coil of flat cross section as shown is only one example.
In a more specific embodiment, given by way of example only and not meant to be limiting, the probe heater may be disposed in a melt channel for heating magnesium. The heater may comprise a tool steel outer sheath, a nickel coil, an alumina dielectric, and a cobalt flux concentrator. The nickel coil, steel sheath and cobalt flux concentrator can all withstand the relatively high melt temperature of magnesium. The nickel coil will generally be operating above its Curie Temperature (in order to be above the melt temperature of the magnesium); this will reduce the “skin-effect” resistive heating of the coil (and thus reduce over-heating/burnout of the coil). The steel sheath will generally operate below its Curie Temperature so as to be ferromagnetic (inductively heated), and will transfer heat by conduction to raise the temperature of the magnesium in which it is disposed (during heat-up and/or transient operation). The sheath may be above its Curie Temperature once the magnesium is melted, e.g., while the magnesium is held in the melt state (e.g., steady state operation or temperature control). The coil will be cooled by conductive transmission to the sheath. Preferably the Curie Temperature of the flux concentrator is higher than that of the sheath, in order to maintain the permeability of the flux concentrator, close the magnetic loop, and enhance the inductive heating of the sheath.
Again, the specific materials, sizes, shapes and configurations of the various components will be selected depending upon the particular material to be heated, the cycle time, and other process parameters.
In various applications of the described inductive heating method and apparatus, it may generally be desirable that the various components have the following properties:
In applications where there is direct coupling of the magnetic field to the material, the desired parameters of the sheath are also desired parameters of the material.
The material in the channel to be heated will also effect the parameters of the assembly components, the applied signal and the heating rates. In various embodiments, the material may include one or more of a metal and a polymer, e.g., a pure metal, a metal alloy, a metal/polymer mixture, etc. In other embodiments the assembly/process may be useful in food processing applications, e.g., where grains and/or animal feed are extruded and cooled.
In various applications, it may be desirable to supply a signal to the coil comprising current pulses having a desired amount of pulse energy in high frequency harmonics for inductive heating of the sheath, as described in Kagan U.S. Pat. Nos. 7,034,263 and 7,034,264, and in Kagan U.S. Patent Application Publication No. 2006/0076338 A1, published Apr. 13, 2006 (U.S. Ser. No. 11/264,780, entitled Method and Apparatus for Providing Harmonic Inductive Power). The current pulses are generally characterized as discrete narrow width pulses, separated by relatively long delays, wherein the pulses contain one or more steeply varying portions (large first derivatives) which provide harmonics of a fundamental (or root) frequency of the current in the coil. Preferably, each pulse comprises as least one steeply varying portion for delivering at least 50% of the pulse energy in the load circuit in high frequency harmonics. For example, the at least one steeply varying portion may have a maximum rate of change of at least five times greater than the maximum rate of change of a sinusoidal signal of the same fundamental frequency and RMS current amplitude. More preferably, each current pulse contains at least two complete oscillation cycles before damping to a level below 10% of an amplitude of a maximum peak in the current pulse. A power supply control apparatus is described in the referenced patents/application which includes a switching device that controls a charging circuit to deliver current pulses in the load circuit so that at least 50% (and more preferably at least 90%) of the energy stored in the charging circuit is delivered to the load circuit. Such current pulses can be used to enhance the rate, intensity and/or power of inductive heating delivered by a heating element and/or enhance the lifetime or reduce the cost in complexity of an inductive heating system. They are particularly useful in driving a relatively highly damped load, e.g., having a damping ratio in the range of 0.01 to 0.2, and more specifically in the range of 0.05 to 0.1, where the damping ratio, denoted by the Greek letter zeta, can be determined by measuring the amplitude of two consecutive current peaks a1, a2 in the following equation:
This damping ratio, which alternatively can be determined by measuring the amplitudes of two consecutive voltage peaks, can be used to select a desired current signal function for a particular load. The subject matter of the referenced Kagan patents/application are hereby incorporated by reference in their entirety.
These and other modifications will be readily apparent to the skilled person as included within the scope of the following claims.